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Evolution SL Unit 5 Ecology – Paper 1 and 2 HL Option D – Paper 3 Introduction to Evolution Assessment Statement 5.4.1 5.4.2 5.4.3 5.4.4 5.4.5 5.4.6 5.4.7 5.4.8 Define evolution Outline the evidence for evolution provided by the fossil record, selective breeding of domesticated animals and homologous structures State that populations tend to produce more offspring than the environment can support Explain that the consequence of the potential overproduction of offspring is a struggle for survival State that the members of a species show variation Explain how sexual reproduction promotes variation in species Explain how natural selection leads to evolution Explain two examples of evolution in response to environmental change; one must be antibiotic resistant bacteria Theories of Evolution For many centuries, people accepted the species they saw around them have always been there. However, in the 18th century, the finding of many different strange species in other parts of the world, did people start to question. Fossils were also discovered, and inquiring minds wanted to know. One was Jean Baptiste de Lamarck (1744-1829). He suggested that all species were created by a higher power, but they undergo change over time. His summary of how this occurred was, “inheritance of acquired characters”. What this means is that the behaviour of the individual determines the character that its offspring inherit. (ex. a giraffe) The problem with this is that we have been making physical changes to animals (ie. cropping ears in dogs) but the changes do not carry over to their offspring. Next – Darwin – Wallace – Natural Selection Russel Wallace (1823-1913) and Charles Darwin (1809-1882) both suggested the alternative idea of natural selection, or a ‘struggle for existence’, as a mechanism for change over a period of time. Darwin and Wallace had studied the works of others, and both had travelled to far corners of the world. Wallace went to South America and Indonesia. Darwin, who we have all heard of, took the HMS Beagle to South America and the Galapagos Islands. Both published works, but the better known and controversial ‘On the Origin of Species’, was published by Darwin in 1859. Natural Selection could be explained using Lamarck’s example of the giraffe. The giraffe is always reaching for leaves, but the giraffe with the long neck gets more food than the one with the short neck. The long necked giraffe will be more successful in reproduction and the genes for the long neck are passed on. The mutation for the longer neck is random, just as the shorter neck, but as competition for leaves increases, the longer necked giraffes will have more accessibility to food resources. As a result, the short necked giraffe will probably die of starvation and not pass on its genes. Other evidence for selection, is in the breeding of dogs and the evolution of the horse. With the dog, humans have created many different breeds in a relatively short time. This is called artificial selection. (ex. agriculture) Fossils have been found showing that 53 million years ago, the ancestor of the horse was a small herbivore probably living in the forest. It had four toes on its front feet and three toes on its hind feet. Over time, the animal started to live on a grassy plains, grew bigger and number of toes reduced until the horse just has one (nail is the hoof). This allowed the horse to run faster, which is important if you are on an open plain with predators. Fossil records also show this. (Ex. Peppered Moth, Biston betularia) Other Theories of the Origin of Life Special Creation or Creationism Panspermia – life from elsewhere came to Earth Evidence for Evolution Evolution describes the changes in the gene pool of a species over time. These changes are the result of mutations, natural selection and genetic drift. Evolution – the process of cumulative change in the heritable characteristics of a population Over time, if enough changes occur in a population, a new species can arise. The members of the new population will be different enough from the pre-existing one they came from that they will no longer be able to interbreed. Such a process is rarely observable during a human lifetime. The three areas we will look at to provide evidence for the theory of evolution by natural selection are: 1. Fossil Records 2. Artificial Selection 3. Homologous Anatomical Structures 1. Fossil Records Fossils can tell us a lot about the past. Fossil – any form of preserved remains from a living organism. Some examples are: Mammoths frozen in Siberia Mummies in acidic swamps in Scandinavia Insects in amber Bones in rock Fossils are only formed in some circumstances. Most individuals do not leave a fossil after death. A fossil has to be formed when an organism dies and gets buried in sedimentary silt. It will decay slowly and leave a space in the silt. The gap becomes solid and is filled the exactly the same as the organism left behind. The silt may solidify, becoming sedimentary rock and in it is the fossil. To see how old fossils are and their forms, carbon dating is used, usually Carbon 14 and potassium 40, which are isotopes. (More on this later) Palaeontologists have discovered the following: Overall, life, which existed more than 500 million years ago, was very different from life today. Although the planet Earth has had extensive oceans for most of its existence, fish fossils have only been found in rocks 500 million years old or younger (less than 15 % of the history of life) Although most of the top predators today are mammals such as bears, orca whales, big cats wolves and the like, none of them existed at the time of the dinosaurs or before Apart from organisms such as certain types of sharks, cockroaches or ferns, many living organisms today have no identical form in the fossil record. One conclusion that can be drawn from observing fossils is that life on Earth is constantly changing. For example, in some cases, as for the example of the horse, we see macroevolution. The first fossils of the ancestors of the modern horse are 53 million years old. They had 4 toes on the front foot and 3 toes on the back. Their eyes were halfway up their head, between the nose and ears and the teeth structure showed it ate leaves, not grass. This early horse was known as Eohippus, which means dawn horse. Fossils in the upper strata of sedimentary rocks (younger fossils) show the horse grew larger, one of its toes grew bigger and the others reduced. We also see that the vegetation changes from thick forests to grasslands, due to fossils of early vegetation. The eyes grew closer to the back of the head, closer to its ears, to improve its peripheral vision to be able to watch for predators while they grazed. The teeth also became bigger and stronger to promote grazing. Many fossils of horses that do not have these features have been found, but the evidence is that they became extinct (ie. they could not outrun predators, attain food, etc.). They were eventually replaced by species that were better suited to the environment. The only line that continued into our time, was Equas, the modern horse. 2. Artificial Selection The fossil record is not complete, but breeding domesticated animals provides a good record of recent changes in heritable characteristics. By watching mating of males and females, and the offspring, breeders select the desirable traits they want. After practicing selective breeding for hundreds of dozens of years, certain varieties of animals had unique combinations of traits not seen before. The evidence is that small changes are occurring over time, which is driven by humans or is artificial. If evolution can be controlled artificially, then it could also be natural. 3. Homologous Structures Comparative Anatomy concentrates on studying homologous structures. Two structures are homologous if they come form the same origin though they may look different now and have different functions. Analogous structures are those that have the same functions, but come from differ origins. For example, the wing of a bird and a wing of an insect are both used for flying, but the wing of the bird used to be a limb and the wing of the insect comes from a fold in the skin. This tells us that there is not a common ancestor here. Examples of homologous structures are the arm of a human, the wing of a bat and flipper of a seal. They all have the same pentadactyl limb. This means they have the same basic patterns of bones, including five digits. The pentadactyl limb is used differently in different mammals, but the common structure could lead to the conclusion that there is a common ancestor. We can also look at physiological evidence, by looking at the functions of parts of organisms or rudimentary structures (ie. pelvis in a whale). We have seen that the wastes from birds and reptiles have the same chemical makeup and the hormones from sheep and pigs are also present in humans!! We can also look at Embryology, which is the study of organisms in early stages of development. Scientists have discovered a similarity between the embryos of different species and it is theorized that this similarity is due to their evolution from a common ancestor. There is also a theory that every organism repeats its own evolutionary development as the embryo develops. Mechanism of Evolution - The Idea behind Evolution and Neo Darwinism Darwin and Wallace suggested a process. This process is known as natural selection. It works by over production of offspring and the presence of natural variation. Too many offspring Populations tend to produce more offspring than the environment can support. The production of offspring involves the expenditure of energy and resources. This over production of offspring leads to intra-species competition and survival of the individuals best suited to that particular environment. Example, trees have active compounds that ward off insects. Competition can also lead to adaptive behaviours. Natural Variation within a Population Sexual Reproduction promotes variation in species. Darwin knew nothing of Mendel’s work, like most scientists of the time. They believed in blended inheritance, which would lead to less variation. Neo-Darwinism restates the essential concepts of evolution in terms of Mendelian and Post-Mendelian Genetics. Creating gametes by meiosis involves the separation of the homologous pairs of chromosomes. Since this process is random, a gamete has a mixture of paternal and maternal chromosomes. Two gametes from different individuals fuse to create a new organism. Since gametes from one individual differ, this mixing will lead to further variation. To summarize, variation arise via: random assortment of chromosomes crossing over of segments of chromosomes result in new combinations of genes, different than the parental combinations random fusion of gametes in sexual reproduction additional variations arise due to mutations, either chromosomal or gene As a result of all of these, the individual offspring of parents are not identical and show variations in their characteristics. If the variations are successful, the organism will be successful. Variety may be caused by: Mutations Sexual Reproduction – random splitting of cells during meiosis will determine the genetic variety. Natural Selection and Favourable Heritable Variations Sexual reproduction and/or mutations, leads to variations of a species. Variation is nondirectional or random. The selection process is dictated by the environment and leads to differential survival. The result is that the individuals best adapted to a particular environment will survive. They will be able to get the most food, find the best shelter, find a mate, reproduce and care for their offspring as well as not be eaten by other species. Since most environments are different, the “best adapted” may be different too. Also, environments may change. This can happen gradually or suddenly, due to a natural disaster, for example. As a result, the criteria for the “best adapted will also change. This process of natural selection can lead to changes in the species. It can also lead to speciation. When two groups of a species are in different environments and they cannot interbreed, selection pressure will be different and eventually they will become different species (adaptation) due to their natural environment. This is what Darwin noticed in the many species of finches in the Galapagos Islands. Sometimes the idea of natural selection is summarized in the phrase “survival of the fittest”, and not “the strong survive”, although these words were not used by Charles Darwin. Natural Selection Summarized 1. 2. The favourable characteristics are expressed in the phenotypes of some of the offspring These offspring may be better able to survive and reproduce in a particular environment; others will be less able to compete successfully to survive and reproduce. Examples of Evolution in response to Environmental Change If a species cannot adapt to the changing environment, then the species will die out. As the dinosaurs did not find a way to deal with the climate becoming colder, they did not survive. Their place was taken by the homeothermic, or warm-blooded mammals. 1. Multiple Antibiotic Resistance in Bacteria Penicillin is not effective over the entire field of micro-organisms pathogenic to humans. During the 1950’s, the search for antibiotics to fill this gap resulted in a steady stream of them, some with a much wider antibacterial range than penicillin (broad spectrum antibiotics). Some were capable of coping with those micro-organisms that are inherently resistant to penicillin or that have developed resistance through exposure to penicillin. Many diseases caused by bacteria have been successfully treated with penicillin and other antibiotics. However, since WWII, when the use of antibiotics became widespread, many disease-causing bacteria have developed resistance against antibiotics. There are strains of bacteria causing tuberculosis, which are resistant to all known antibiotics. The same applies for cholera, as there is only one effective antibiotic available. This means that is you become infected with these bacteria, treatment with antibiotics will not cure you and the disease may become fatal. Staphylococcus aureus is a common bacterium found living on the skin. This species is usually harmless but, in certain circumstances, can invade your blood stream, infect tissues in the kidneys or bones and could become fatal. These days, strains of S. aureus exist which are resistant to all known antibiotics. These MRSA bacteria (methycillinresistant Staphylococcus aureus) are of grave concern to hospitals all over the world. The resistance to antibiotics is probably caused by spontaneous mutation. As a result, the bacterium produces penicillinase, for example, an enzyme, which breaks down penicillin. If the bacteria are exposed t penicillin, the one without resistance will be killed. However, those with resistance will survive and, due to lack to competition, grow rapidly. The genetic information for antibiotic resistance is often found on plasmids, which can be spread rapidly over a population and can even cross into other species of bacteria. This is likely to occur when a small dose of antibiotics is used for a short time. It will kill some of the bacteria, but not all and may lead to the creation of some bacteria that have some resistance. The next time antibiotics are used, these bacteria are less vulnerable and some more may survive. Repeated use of small doses of antibiotics can produce very resistant strains. This explains why doctors always insist on patients finishing the course of antibiotics even if they are feeling better. Overuse of antibiotics in medicine, the cattle industry and antibiotic soaps have led to a rise in antibiotic strains. 2. The Peppered Moth (biston betularia) This moth is found in England, near Manchester (boo United!!!). Before 1848, trees on which they rested were covered with off-white lichen. The moths were white, and therefore camouflaged from predation by birds. Occasionally a black moth would appear, and due to its high visibility, would have a high possibility of falling prey. Due to coal base industry, the trees became covered with soot and the white moths were easily spotted and eaten. The dark (melanic) form now had an advantage and became predominant (95%) in certain areas in 1950. Reduce use of coal has now made the trees green (covered in algae) and both forms are common. This is called balance polymorphism. This is a short termed example of evolution. 3. Heavy Metal tolerance in plants This is a phenomenon associated with those plants able to survive and even flourish on the bare waste tips and spoil heaps found at mining sites. Heavy metals, such as, copper, zinc, lead and nickel may be present as ions dissolved in soil moisture at concentration that generate toxic conditions for plants normally present on the surrounding unpolluted soil. Some heavy metal ions are essential for normal plant growth when present in trace amounts, but in mining spoils, the levels are exceeded. For many years, the areas around mines were largely bare of all plant life, even when surrounding, unpolluted soils have dense vegetation cover. Seeds from these plants regularly fall on spoil heap soil, but plants fail to establish themselves. However, careful observations of spoil heaps have shown some plant species have evolved tolerance. One example is the grass Agrostis tenuis (Bent Grass), populations of which are tolerant of toxic concentrations of copper. A variety of biochemical and physiological mechanisms have evolved in tolerant species, including: the selective ability to avoid uptake of heavy metal ions the accumulation of ions that enter in insoluble compounds in cell walls by formation of stable complexes with wall polysaccharides transport of toxic ions into the vacuoles of cells, the membranes of which are unable to pump them out again, so avoiding interactions with cell enzymes. The evolution of this form of tolerance has been demonstrated in several species of terrestrial plants, and also in species of seaweeds, now tolerant of copper-based antifouling paints frequently applied to the hulls of ships. This is also a fear associated with the genetically modified Round-up resistant wheat. Evolution – The Origin of Life Assessment Statement D.1.1 Describe four processes needed for the spontaneous origin of life on Earth D.1.2 Outline the experiments of Miller and Urey into the origin of organic compounds State that comets may have delivered organic compounds to Earth Discuss possible locations where conditions would have allowed the synthesis of organic compounds Outline two properties of RNA that would have allowed it t play a role in the origin of life State that living cell may have been preceded by protobionts, with an internal chemical environment different from their surroundings Outline the contribution of prokaryotes to the creation of an oxygen rich atmosphere Discuss the endosymbiotic theory for the origin of eukaryotes D.1.3 D.1.4 D.1.5 D.1.6 D.1.7 D.1.8 Biologists believe that organic evolution by natural selection accounts for the major steps in evolution. These are macroevolution – major developments such as the origin of the eukaryotic cell, the origin of multicellular organisms, and the origin of vertebrates from nonvertebrates; and microevolution – the relatively minor changes that arise and lead to the appearance of new, but closely related species. There are several theories as to how life originated on our planet. None have been proven, but there is one that is accepted as the “hypothesis of evolution” or theory of evolution. This is called the Big Bang. The Big Bang Theory, Experiments and Theories The Earth is one of the smallest planets grouped in the Solar System around a central star, the Sun. The fact that the planets all revolve in the same plane supports the theory that the Sun and planets were all formed from the condensation of a single revolving disc of matter. It is likely the Earth originated from masses of molten rock that collided and coalesced. With cooling, a crust formed but the restless surface was initially continuously disturbed as other matter collided. Heat from impacts and from the decay of radioactive elements such as uranium was probably sufficient to melt matter and keep it molten. In the liquid state, the bulk of heavy elements, particularly iron, formed the Earth’s liquid core of dense matter. Radioactive elements, though present in small amounts, have had enormous effects on the Earth’s geological evolution and they continue to keep the interior hot. The surface of the Earth eventually cooled to 100 °C and below, and an atmosphere developed. The gravitational field on Earth was strong enough to retain this atmosphere, unlike that of the Moon. The major constituents of the atmosphere would have been: nitrogen, water vapour and carbon dioxide; smaller amounts of methane, ammonia, carbon monoxide, sulphur dioxide, hydrogen sulphide and hydrogen cyanide. These are all products of the effects of heat on the lighter chemical elements of the crust, and of lightning and ultra-violet radiation. (The arrival of comets was a possible alternative source for some of the gases, particularly water vapour.) The atmosphere was virtually without oxygen – in fact, any trace of free oxygen would have immediately reacted with the large quantity of iron present. The rock of the Earth’s crust is a relatively thin layer. It is divided into huge plates that move about on the surface, and where they meet, one or both turn under and become part of the mantle layer below. As the Earth continued to cool, the water vapour in the atmosphere condensed and returned to the surface as rain, forming rivers and lakes. Seas formed. Now the process of erosion began to mould the landscape, and the eroded debris became the first sedimentary rocks. Question – Why do those fossils found in the lowest strata in sedimentary rocks, bear the least resemblance to present day forms? At this point there was still no life on Earth. It was speculated that the atmosphere was probably a reducing atmosphere (gaining electrons), because metals in old rocks are found in their oxidized forms (ie. Fe+2 and Fe+3). It is possible to form organic molecules in a reducing atmosphere but is difficult to do it in an atmosphere that contains oxygen, because oxygen wants to lose electrons. Life in the form of living cells may have developed spontaneously in evolving conditions similar to those described above. If so, the following steps would have been involved: the non-living synthesis of simple organic molecules, such as sugars and amino acids; the assembly of these molecules into polymers; the development of self-replicating molecules, such as nucleic acids; the packaging of these molecules within membranous sacs, so that an internal chemistry can develop, different from the surrounding environment. Other people have speculated there must have been oxygen in the atmosphere as without ozone, the Earth would have been bombarded with UV radiation, killing all life. Also, living organisms synthesize the proteins and nucleic acids needed inside cells using enzymes. There had to be a way to make organic molecules outside a cell. Hypothesis and Experiment A – Stanley Miller and Harold Urey Experimental evidence of how simple organic molecules might have arisen from the ingredients thought to be present at the time before there was life on Earth was produced by S. L. Miller and H. C. Urey in 1953. They set up a reaction vessel in which particular environmental conditions could be reproduced. Here, strong electric sparks (simulating lightning) were passed through mixtures of methane, ammonia, hydrogen and water vapour for a period of time. They discovered that amino acids were naturally formed (some of them known to be components of cell proteins, such as adenine and ribose) as well as other compounds. This approach confirmed that organic molecules can be synthesised outside cells, in the absence of oxygen. The experiment has subsequently been repeated, sometimes using different gaseous mixtures and other sources of energy (UV light, in particular), in similar apparatus. The products have included amino acids, fatty acids, and sugars such as glucose. In addition, nucleotide bases have been formed, and in some cases, simple polymers of all these molecules have been found. To summarise, we can see how it is possible that a wide range of organic compounds could have formed on the pre-biotic Earth, including some of the building blocks of the cells of modern organisms. What environments could organic compounds formed? As will be mentioned later, comets, are chunks of ice wandering through space. As they travel, they could have carried organic molecules to Earth. If this was the case, for which we have no conclusive proof, what environments would be favourable to form or sustain early organic molecules? In space By studying the spectral lines of distant clouds of cosmic dust particles, astronomers claim to have revealed the presence of glycine, which is the simplest amino acid. Organic molecules could form in space and be carried by comets, as the above observation suggests. Lab experiments, which recreate the low pressure, low temperature environment in space, have been able to synthesize amino acids. Francis Crick, the codiscoverer of the structure of DNA, was a modern supporter of a suggestion that organic molecules, the essential precursors of living cells, may have emerged on another planet or moon and ‘hitched a ride’ to Earth on a comet. The idea that life did not originate on Earth but arrived in some form from an extraterrestrial source is known as panspermia (Greek for‘all seeds’ – it was a Greek philosopher who 2500 years ago proposed that all life originated from combinations of tiny seeds pervading the cosmos). Currently, this idea is being researched by astrobiologists and planetary geologists in America. NASA scientists have confirmed that early in the history of our Solar System, conditions essential for life were present elsewhere. For example, on Mars, water flowed intermittently, and life may have existed there. Also, Europa, the fourth-largest moon of Jupiter, appears to possess liquid water under an icy surface. Titan, the largest satellite of Saturn, is rich in organic compounds. The expanse of interplanetary space has been crossed in ways that may have transportedorganic matter. For example, about 30 meteorites found on Earth originated from Mars. Biological matter is more likely to survive travel in the interior of meteorites, either in the form of RNA alone or assembled with ribosomes in ‘protein factories’. As yet, though, there is no evidence it happened. In alternating wet and dry environments So how did DNA come about, if it didn’t hitch a ride to Earth? Currently DNA can replicate, but it needs enzymes to do this. The DNA is transcribed into RNA and the RNA makes the proteins needed to make the DNA. Which came first – the chicken or the egg? One suggestion is the Catalytic Action of Clay assisted in the formation of polypeptides from amino acids, as made by Katchalsky, Cairns – Smith and Bernal The basis for this idea is as follows: 1. 2. 3. 4. 5. 6. 7. 8. 9. Some clays can grow by attracting molecules to themselves. They will then repeat a lattice-like organization over and over again. Amino acids may have stick to the clay lattice and have been incorporated into it. They may have been attached to each other as well. Some clay particles may have become a template for a protein. If the protein product was a weak enzyme it may have speeded up the process of protein synthesis with clay as a template. Then the clay template for this particular enzyme would make more protein than another template whose product was not an enzyme. Then nucleotides could have been attracted by the clay template, or the template with the attached proteins, and could have polymerized (into RNA) and come to act as a co-enzyme. The more successful template is the one where the enzyme and co-enzyme work together to produce more of themselves. Eventually, the co-enzyme (nucleotide polymer, RNA) could become the template for protein synthesis. However, no one has yet been able to synthesise DNA and globular proteins in any of the reported experiments repeating Miller and Urey’s demonstration of how biological important molecules could be synthesised in the pre-biotic world. Near volcanoes A third possibility is when a volcano erupts, the force can be destructive, but it spews out water vapour, other gases and various minerals which could be used to form organic mater. The rich sources of raw materials plus the warmth of the vocanic activity could have provided conditions favourable to the formation of amino acids and sugars. In deep oceans Organic molecules could have been formed around hydrothermal vents – places where hot water comes out of the ocean floor, like an under water geyser. Some times the vents are called “black smokers” because the water coming out of them contains so many dark minerals that is looks like smoke. It has been observed that entire communities live around these vents, such as meter long white and red tube worms which absorb the minerals and pas them on to symbiotic bacteria. The bacteria make food from the minerals and nourish the tube worms. Even though there is no sunlight, life flourishes here, making the hypothesis of life originating her plausible. The Role of RNA in early life So what may have filled the roles of DNA and enzymes in the origin of life? A possible answer was found in the unexpected by-product of genetic engineering experiments involving in vitro investigation of the enzymes required to patch and join short lengths of RNA (a process that genetic engineers call splicing). These experiments showed, to everyone’s surprise, that when the naturally occurring protein enzymes that catalyse RNA patching (obtained from cells) were omitted from the reaction mixtures, the RNA fragments still spliced on their own. It had been assumed that the RNA-patching enzyme (a protein) was the essential catalyst. This was the first demonstration that short lengths of RNA, as well as being ‘information molecules’, also function as enzymes. These catalytic RNA molecules have been named ribozymes. Perhaps short lengths of RNA filled the dual roles of information molecules and enzymes in the evolution of life. Now we have experimental evidence that short lengths of RNA can also function as enzymes, although they may rarely do so in modern cells. In present day eukaryotic cells, messenger RNA (mRNA) carries the genetic code between nucleus and the site of protein synthesis, the ribosomes (themselves another form of RNA). Other RNA, known as transfer RNA (tRNA) brings the amino acids to the ribosome for the building of the protein. However, the enzymes that catalyse the chemical reactions involved throughout are proteins. Further investigations show ribozymes to be fairly inefficient enzymes – slow and unpredictable at times, but that they work satisfactorily with polynucleotide substrates. They can catalyse simple replications, although they do this in an error-prone way, on occasions. Thus, ribozymes may catalyse the formation of DNA, for example. The discovery of ribozymes completes the story of a possible and credible route from the prebiotic soup to living things, simply because this form of RNA is an information molecule that both replicates and may function as enzymes. Keep in mind, all the series of events described above are not entirely random. The conditions on Earth made some processes more likely than others to occur. Hypothesis – Membrane Formation from the Primordial DNA – Fox and Oparin The first cells were prokaryotes. This we know from the fossil record. Were they preceded by a ‘lower’ or lesser level of organisation – some form of protobiont? A limited number of lipid molecules, once formed, arrange into a monolayer on the surface of water. When more lipids become available, the whole re-forms into lipid bilayers – the basis of plasma membranes today. If such bilayers formed and linked up into microspheres that surrounded a small amount of the pre-biotic soup of polymers and monomers, perhaps these were the fore-runners of cells? Fox did an experiment in which he heated amino acids without water and produced long protein chains. When the water was added and the mixture cooled, stable microspheres formed. Microspheres were able to accumulate certain compounds inside them so that they became more concentrated inside than outside. They also attracted lipids, forming a lipid protein layer around them. Microspheres might be dubbed ‘membrane systems with a distinctive internal chemistry’, for the contents have the potential to develop a chemical environment different from the surroundings. Also observed are structures called coacervates. These are formed from dilute solutions of two substances each having large polymer molecules carrying opposite charges. The two most commonly studied are gelatine and gum arabic. At certain concentration, these separate into sol (liquid) and gel (solid) phases. Each phase contains both polymers but at different concentrations. However, both contain large amounts of other molecules in solution. Complex coacervates have been observed, one gel droplet within another. If such droplets came into existence and contained enzymes, they would form a model for the biochemistry of the cell. The Russian biochemist Oparin (1894–1980), who pioneered the chemical approach to the origin of life, attached great importance to coacervates in the evolution of life. A prokaryote cell differs from these models in a number of ways. For example, attached to the plasma membrane in the prokaryote cell is a single circular chromosome of DNA, known as a nucleoid. Also, a cell wall of complex chemistry is secreted outside the membrane barrier to the cell contents. However, both protobionts and the first prokaryotes could have survived nutritionally on the organic molecules of the pre-biotic soup. In this early life environment, with a wealth of simple organic molecules surrounding simple cells, digestion and respiration would have demanded only limited enzymic machinery. Biochemical sophistications would have to evolve with time – if life originated in this manner. Hypothesis – Prokaryotes and Endosymbiotic Theory and where the Oxygen could have come from Did they contribute to our atmosphere? Some of the earliest prokaryote fossils contain cells very similar to modern cyanobacteria (modern prokaryotes that are photosynthetic). They are present in large mounds known as stromatolites, fossilized examples of which are common, and of which there are also still living examples. Stromatolites are formed in shallow waters, the mounds built of layer upon layer of bacterial mats. The earliest fossil stromatolites date from some 3500 million years ago. In stromatolite mounds, the outer layer is of filamentous cyanobacteria – photosynthetic bacteria that absorb light, produce carbohydrates, and release oxygen. Below is a layer of purple bacteria that also absorb light and also manufacture carbohydrate, but do so without releasing oxygen. Further below is a layer of other bacteria that are saprotrophic. Some are able to fix atmospheric nitrogen into combined nitrogen of amino acids, for example. The combined components of stromatolites are a biochemically able assortment. In the beginning the theory is that the bacteria were anaerobic. As the food stores became scarce, the bacteria that produced their own food, has an advantage. Photosynthetic prokaryotes began the process by which free oxygen accumulated in the Earth’s atmosphere. With free oxygen in the atmosphere, the formation of an ozone layer in the upper atmosphere commenced. Once formed, the ozone layer began to reduce the incidence of UV light reaching the Earth’s surface. Terrestrial existence (rather than life restricted to below the water surface) became a possibility. The oxygen, which was possibly toxic to the anaerobes, killed off a large population. Meanwhile other prokaryotes, more akin to modern aerobic bacteria, simply ‘fed’ on the organic molecules available in their environment. However, these bacteria had evolved aerobic respiration (only possible as a result of the free oxygen from photosynthetic cyanobacteria, now present in the atmosphere) and so had the enzymes not only of glycolysis, but also of the Krebs cycle and terminal oxidation. Eukaryotic cells are only 1.5 billion years old. We know that the first cells were prokaryotes. It is likely that some larger prokaryote cells came to contain their chromosome (whether of RNA or DNA) in a sac of infolded plasma membrane. If so, a distinct nucleus was now present. But how might the other organelles have originated? Remember, membranous organelles are a feature of eukaryotes, in addition to their discrete nucleus. Is it possible the early cells acted as a primordial habitat – a possible origin for mitochondria and chloroplasts? Lynn Margulis suggested independent prokaryotes developed a symbiotic relationship with another prokaryote (mitochondria, chloroplasts) Both mitochondria and chloroplasts contain a ring of DNA double helix, just like that contained by a prokaryote. They also contain the small ribosomes, like those of prokaryotes. These features have caused some evolutionary biologists to suggest that some organelles are descendants of freeliving prokaryotic organisms that came to inhabit larger cells. It seems a fanciful idea, but not an impossible one. Present day prokaryotes are similar to fossil prokaryotes, some of which are 3500 million years old. By comparison, the earliest eukaryote cells date back only 1000 million years. Thus eukaryotes must have evolved, surrounded by prokaryotes that were longestablished organisms. It is possible that, in the evolution of the eukaryotic cell, prokaryotic cells (which at one stage were taken up into food vacuoles for digestion) came to survive as organelles instead. If so, with time they would have become integrated into the biochemistry of their host cell. This concept is known as the endosymbiotic origin of eukaryotes. Species and Speciation Assessment Statement D.2.1 Define allele frequency and gene pool D.2.2 State that evolution involves a change in allele frequency in a population’s gene pool over a number of generations D.2.3 Discuss the definition of the term species D.2.4 Describe three examples of barriers between gene pools D.2.5 Explain how polyploidy can contribute to speciation D.2.6 Compare allopatric and sympatric speciation D.2.7 Outline the process of adaptive radiation D.2.8 Compare convergent and divergent evolution D.2.9 Discuss ideas on the pace of evolution, including gradualism and punctuated equilibrium D.2.10 Describe one example of transient polymorphism D.2.11 Describe sickle-cell anemia as an example of balanced polymorphism As was stated earlier, “New” or Neo-Darwinism is a restatement of the concepts of evolution by natural selection in terms of Mendelian and post-Mendelian genetics. Neo-Darwinism looks at: 1. Mutations as changes that are due to chance, but occur with predictable frequency. 2. Variations in populations are due to recombination of alleles. 3. Adaptations (or micro-evolutionary steps) may occur as a result of an allele frequency in a population’s gene pool. a. Evolution of one species into another species involves the accumulation of the advantageous alleles in a gene pool. b. The process of speciation 4. Polyploidy 5. Allopatric and Sympatric Speciation 6. Adaptive Radiation 7. Convergent and Divergent Evolution 8. The pace of evolution is controlled by gradualism and punctuated equilibrium 9. Transient Polymorphism 10. Balanced Polymorphism Allele Frequency and Gene Pools Gene Pool – all of the genetic information present in the reproducing members of a population at a given time. It can be thought of as a reservoir of genes from which the population can get its various traits. Allele Frequency – is a measure of the proportion of a specific variation of a gene in a population. The allele frequency is expressed as a proportion or a percent, and can be calculated by the Hardy-Weinberg equation (more later). For example, it is possible that a certain allele if present in 25% of the chromosomes studied in a population. One quarter of the loci for that gene are occupied by that allele. Keep in mind it is not the same as the number of people who show a particular trait. Evolution and alleles Gene pools are generally relatively stable over time but not always. Mutations are changes to genes or chromosomes due to chance, but with predictable frequencies. Because they happen, it is believed they play a role in evolution. Old alleles disappear and the last organism carrying the allele dies. Some alleles are disadvantageous and are not as frequent and those that are advantageous tend to be more frequent. We know from our Genetics unit that homologous chromosomes pair up during meiosis and then cross over. With 3 chromosomes, the possible gametes are 8 (23 = 8). This allows for variation. The changes caused by variation are said to be non-directional, because every change has an equal chance of occurring. If and when the change is made, the environment determines if the change is beneficial or not. If it is beneficial, the individual will live to pass on its genes, thus increasing the percentage of the allele in the population or gene pool. NO CHANGE IN ALLELE FREQUENCY = NO EVOLUTION Some examples we have already mentioned, such as Down’s Syndrome and Klinefelter Syndrome. As a result, we get some variation, due to the mutation. Another example is the Peppered Moth, which was mentioned earlier. The colour is determined by the alleles present for one gene. Originally there was a balanced polymorphism, or having multiple alleles for a gene in a population, which usually expresses different genotypes. In the case of the moth, the dark allele was rarely present, as it was selected against. As was mentioned previously, the lichens were growing in fewer numbers, and as a result the bark on trees became darker. The selection then favoured the dark species, and the dark allele in the species increased (transient polymorphism). Since the air pollution decreased, the light coloured morph and the allele for the light colour now increases in the population. Another example is PKU or phenylketouria. It is a genetic disease caused by the presence of a homozygous recessive allele. A PKU individual cannot produce a certain enzyme to break down phenylalanine to tyrosine. Phenylalanine levels build up which are harmful to the brain. This can lead to brain damage. Once they eat a diet with little phenylalanine, they can eat normally. The above examples show that, at some point in time, the normal allele mutated and a new allele was created. The new allele was not favourable but some individuals passed on the allele. The moth example can be summarized below: Defining Species Present-day flora and fauna have arisen by change from pre-existing forms of life. Most biologists believe this. This process has been variously called ‘descent with modification’, ‘organic evolution’, and ‘microevolution’, but perhaps speciation is appropriate here because it emphasizes that species change. A species is a group of organisms: of common ancestry (PHYLOGENY) that closely resemble each other structurally and biochemically and are distinct from other species which are members of natural populations that are actually or potentially capable of breeding with each other to produce fertile offspring, and which do not interbreed with members of other species. There are challenges to the definition The last part of this definition cannot be applied to self-fertilizing populations or to organisms that reproduce only asexually. Such groups are species because they look very similar (morphologically similar). They behave and respond in similar ways, with bodies that function similarly (they are physiologically similar). Sometimes members of separate by similar species reproduce and succeed in producing offspring. A horse and a zebra form a zebroid as the parents are equines. They do not have the same number of chromosomes, which is one of the reasons the offspring are infertile. Does being infertile mean they are not part of the species? What about two populations which could potentially interbreed, but do not because they are living in different niches or are separate by long distances? But however we define the term, since species may change with time (mostly a slow process), there is a time when the differences between members of a species become significant enough to identify separate varieties or subspecies. Eventually these may become new species. All these points are a matter of judgment. So a population of garden snails might occupy a small part of a garden, say around a compost heap. A population of thrushes (snail-eating birds) might occupy several gardens and surrounding fields. In other words, the area occupied by a population depends on the size of the organism and on how mobile it is, for example, as well as on environmental factors (e.g. food supply, predation, etc.). The boundaries of a population may be hard to define. Some populations are fully open, with individuals moving in or out, from nearby populations. Alternatively, some populations are more or less closed – that is, isolated communities almost completely cut off from neighbours of the same species. Obviously, the fish found in small lakes are a good example of the latter. Speciation and Barriers between Gene Pools Speciation, the evolution of new species, requires that allele frequencies change with time in populations. Some of the processes known to bring about significant change, leading to the eventual appearance of a local population of organisms that are a new species, unable to breed successfully with members of the population from which they originated are due to isolation. Speciation by isolation A step towards speciation may be when a local population becomes isolated from the main bulk of the population, so the local gene pool is completely cut off and permanently isolated. The result is reproductive isolation within the original population. Even when reproductive isolation has occurred, many generations may elapse before the composition of the gene pool has changed sufficiently to allow us to call the new individuals a different species. However it does happen, and isolation that is effective in leading to genetic change can occur in space (geographical isolation), time (temporal isolation) and as a product of behaviour (behavioural isolation). A. Geographical isolation This is the consequence of the development of a barrier within a local population. Today, both natural and human-imposed barriers can occur abruptly, sharply restricting movement of individuals (or their spores and gametes, in the case of plants) between divided populations. Before separation, individuals shared a common gene pool, but after isolation, ‘disturbing processes’ like natural selection, mutation and random genetic drift may trigger change. Genetic drift is random change in gene frequency in small isolated populations. For example, a new population may form from a tiny sample that became isolated and separated from a much larger population. While numbers in the new population may rapidly increase, the gene pool from which they formed might have been totally unrepresentative of the original, with many alleles lost altogether. The outcome of these processes may be marked divergence between populations, leading to their having distinctly different characteristics. Geographic isolation also arises when motile or mobile species are dispersed to isolated habitats – as, for example, when organisms are accidentally rafted from mainland territories to distant islands. The 2004 tsunami generated examples of this in Southeast Asia. Violent events of this type have surprisingly frequently punctuated world geological history. Another example would be in the Galapagos Islands. The iguana lizard here had no mammal competition when it arrived on the Galapagos. It became the dominant form of vertebrate life, and was extremely abundant when Darwin visited. By then two species were present, one terrestrial and the other fully adapted to marine life. The latter is assumed to have evolved locally as a result of pressure from overcrowding and competition for food on the islands (both species are vegetarian) driving some members of the population out of the terrestrial habitat. B. Temporal isolation This is illustrated when two very closely related species occupy the same habitat and differ only in the time of year that they complete their life cycles. Reproductive isolation may develop in this situation within a local population so that some members produce gametes at distinctly different times of the year from others; thus, two distinctive gene pools start to evolve. Examples of the outcome of temporal isolation include two members of the genus Pinus found in Californian forests. C. Behavioural isolation This type of isolation results when members of a population acquire distinctive behaviour routines in their growth and development, courtship or mating process that are not matched by all individuals of the same species. An example occurs in the imprinting behaviour of the young of geese, swans and other birds. When chicks of these species hatch out of the egg, the adult birds are in the vicinity, caring for them. The young imprint the image of their parents as they relate to and learn from them. They associate socially only with their own species (or variety), and as adults, they will eventually only bond with and breed with their own species. Imprinting became apparent when a goose chick, on hatching, was placed with swan adults as parents. The goose, when an adult, bred with a swan, and the offspring was an infertile ‘Gwan’. Clearly, the swan and goose are related species that have evolved apart for long enough for their progeny to be infertile, but not long enough to exclude the formation of a hybrid. (Konrad Lorenz) Other examples of behavioural isolation are demonstrated by closely related species of fish, including in guppies (Poecilia spp.) with different, distinctive body markings by which pairs select their mates, and in four species of gull of the Canadian arctic (Larus spp.) with distinctive plumage by which they are identified during breeding periods. D. Hybrids There are many challenges for hybrids. The majority of hybrids are infertile. Eventually one generation will not come to be. In summary, species do not evolve in a simple or rapid way. The process is usually gradual, taking place over a long period of time. In fact, in many cases speciation may occur over several thousand years. Complex though it is, we can recognize that all cases of speciation require ‘isolation’. Allopatric and Sympatric Speciation A deme is the name we give to a small, isolated population. The individuals of a deme are not exactly alike, but they resemble one another more closely than they resemble members of other demes. This similarity is to be expected, partly because the members are closely related genetically (similar genotypes), and partly because they experience the same environmental conditions (which affect their phenotype). The ways demes become isolated have been discussed already. Reviewing these, we see they fall into two groups, depending on the way isolation is brought about. Isolating mechanisms that involve special separation are known as allopatric speciation (literally ‘different country’). An example might occur in a land dwelling species when sea level rise. The populations could be cut off from one another. As sea levels dropped again many years later, each could have evolved so differently that they could no longer interbreed. Isolating mechanisms involving demes in the same location are known as sympatric speciation (literally ‘same country’). An example could be moths which, produce pheromones to attract a mate. If there is a mutation in the pheromone and it is slightly different, it might attract new mates. The interbreeding would breed a new type of moth that produces that specific pheromone. Within a certain number of generations, the new combinations of alleles would produce a new species of moth. So, isolation may result from a deme becoming spatially separated from the rest of the local population, or it may occur within a local population. Either way, natural selection may come to act differently on the demes and, if this continues over a large number of generations, complete divergence may be the final outcome. Polyploidy Haploid cells contain one set of chromosomes (n). Diploid cells are 2n. Polyploidy refers to the situation in which a cell contains three or more sets of chromosomes (3n, etc.) This arises when cell division does not completely separate the copies of chromosomes. In plants, this is more common, the extra sets of chromosomes lead to more vigorous plants which produce bigger fruit or food storage organs that are more resistant to disease. The consequence is the replication errors become more common. If one population is triploid and the other is tetraploid, the evolution of each will be different and then they will eventually become separate species. Adaptive Radiation Adaptive radiation occurs when many similar but distinctive species evolve relatively rapidly from a single species or from a small number of species. This happens as variations in the population allow certain members to exploit a slightly different niche in a more successful way. By natural selection and the presence of one or more of the barriers described above, new species evolve. Lemurs are an example. Without competition from apes or monkeys, on the islands, the species was able to proliferate. Large numbers of offspring meant a greater chance of phenotypic diversity. They are not found in areas with other primates and have adapted and show variations in their behaviours (some are nocturnal, dinural, live in trees or on the ground). Fossils have been found in other areas, but not the lemur. Why? Because they were not successful competing with their cousins. This would explain why you see prosimians (lemurs) or anthropoids (apes and monkeys). Some lemurs are endangered as they come in contact with recently evolved anthropoids, humans. Another example is the Darwin Finches. (see handout) Convergent and Divergent Evolution (VERY IMPORTANT) One species can have various splits over time creating a greater diversity between species. In some cases, the branches of the phylogenic tree can become so far apart that the species that were once closely related do not physically resemble each other. This is called Divergent Evolution. In other cases, it is possible to have two organisms with very different phylogenies but look quite similar. This is called Convergent Evolution. Each type of evolution of organisms is to allow it to fill a niche, or a place in an ecosystem. If the environment is favorable for a certain form or behavior, the successful organisms will change to fill that niche, and be able to survive and continue the gene pool. Diagram Examples Divergent 1. Adaptive radiation is one example of divergent evolution. The red fox and the kit fox provide and example of two species that have undergone divergent evolution. The red fox lives in mixed farmlands and forests, where its red color helps it blend in with surrounding trees. The kit fox lives on the plains and in the deserts, where its sandy color helps conceal it from prey and predators. The ears of the kit fox are larger than those of the red fox. The kit fox's large ears are an adaptation to its desert environment. The enlarged surface area of its ears helps the fox get rid of excess body heat. Similarities in structure indicate that the red fox and the kit fox had a common ancestor. As they adapted to different environments, the appearance of the two species diverged. 2. Darwin’s finches – as the finches were cut off from one another due to geographical isolation (allopatric speciation), the finches changed over time to survive in their environments. 3. Marsupials had one common ancestor. A possum, kangaroo, koala and a wombat are all marsupials, but they look very different from each other. As they adapted to their environment, they changed over time. Convergent 1. Fish, sharks and whales, all swim, but they do this in order to survive in their environments. A fish and a whale are bony, while a shark is cartilaginous. Fish and sharks have gills, while a whale has lungs. They are only similar due to their environments. We have more in common with whales than fish do, even though they look similar. 2. Types of plants have adapted to desert environments. The resemblance of the cactus, which grows in the American desert, to the euphorbia, which grows in the African deserts is very similar. Both have fleshy stems armed with spines. These adaptations help the plants store water and ward off predators, but they are two totally different species 3. This can also refer to how some animals use certain molecules. The use of bioluminescence by marine organisms, bacteria and fungi is an example of convergent evolution. The use of haemoglobin is another. Coevolution is the joint change of two or more species in close interaction. Predators and their prey sometimes coevolve; parasites and their hosts often coevolve; plant-eating animals and the plants upon which they feed also coevolve. One example of coevolution is between plants and the animals that pollinate them. In tropical regions bats visiting flowers to eat nectar. The fur on the bat's face and neck picks up pollen, which the bat transfers to the next flower it visits. Bats that feed at flowers have a slender muzzle and a long tongue with a brushed tip. These adaptations aid the bat in feeding. Flowers that have coevolved with bats are light in color. Therefore, bats, which are active at night, can easily locate them. The flowers also have a fruity odor attractive to bats. In all types of evolution, it is the process of natural selection that allowed the organisms to adapt to their environment in the ways in which they did. Divergent and convergent evolution and coevolution are different ways organisms adapt to the environment. These are examples of how the diversity of life on earth is due to the ever-changing interaction between a species and its environment. Pace of evolution: gradualism versus punctuated equilibria Since geologists estimate the age of the Earth as being 4500 million years, and that life originated about 3500 million years ago (mya), the timescale over which evolution has occurred has seemed almost unimaginably long. The fossil record provides evidence of the long evolutionary history of most major groups. This observation of evolution by natural selection as being an exceedingly gradual process is known as gradualism. From the theory of evolution by natural selection we might expect species to only gradually disappear, and be replaced by new species at a similar slow rate. Instead, this may not have always been the case. Some new species have appeared in the fossil record relatively quickly (in terms of geological time), and then have tended apparently to remain unchanged or little changed, for millions of years. Sometimes, periods of stability were followed by periodic mass extinctions, all evidenced by the fossil record. Some say the fossil record looks like this because we have a partial (distorted) fossil record, when compared to the numbers of organisms that have lived. This is quite possible; we have no way of being certain the fossil record is fully representative of life in earlier times. This is a possible explanation. However, two evolutionary biologists, Niles Eldredge and Stephen Gould, proposed an alternative explanation. They argue that the fossil record for some groups is not significantly incomplete, but rather, accords with their hypothesis of the origins of new species, which they called punctuated equilibria. This hypothesis holds that: When environments become unfavourable, populations attempt to migrate to more favourable situations. If the switch to adverse conditions is very sudden or very violent, then a mass extinction occurs. Major volcanic eruptions or major meteor impacts can throw so much detritus into the atmosphere that the Earth’s surface is darkened for many months, cooling the Earth and killing off much plant life. Populations at the fringe of a massive disturbance may be sheltered or protected from the worst effects of extreme conditions, and survive. Members of these populations may become small, isolated reproductive communities, from which repopulation eventually occurs. The surviving group(s) may have an unrepresentative selection of alleles of the original genepool. If one becomes the basis of a repopulation event and adapts to the new conditions quickly, then abrupt genetic changes may occur. This phenomenon is known as the founder effect. The successful organisms will fill the niche that was left void by the sudden movement or extinction of the original species. So there are alternative proposals for the ways natural selection has operated in practice in the establishment of life in geological time. In fact, gradualism and punctuated equilibria may not be alternatives; both may have contributed to the pattern of life on Earth in geological time. The only way to say which is the preferred pattern is to look at fossil records. Proponents of gradualism point to the fact that some species have lived for millions of years with little or no change, like a shark or a cockroach. Critics point to fossils that show massive extinctions and are incomplete. Critics of punctuated equilibrium argue that the jumpy effect of this theory could simply be and artifact of the incompleteness of the fossil record. One difficulty of supporting either claim is the only evidence used is fossil evidence. Pigmentation, behavior or mating calls cannot be fossilized. Another argument is just because a fossil looks like a modern day organism, does not indicate the latter is a direct descendent of the former or that the two species would have been able to reproduce together. Transient polymorphism and Balanced Polymorphism Transient polymorphism Within a population, there is often more than one common form. Different versions of a species are referred to as polymorphisms (many shapes) and can be the result of a mutation. When one form changes to another due to the environment, and then changes back over time, this is called Transient polymorphism. An example is the Peppered Moth, or Biston betularia. Balanced Polymorphism When two or more alleles are stabilized by natural selection, this is called balanced polymorphism. Sickle Cell anaemia is an example. As mentioned before, the dominant allele, if in the homozygous form means the person has normal blood cells. This means that the person is susceptible to malaria. If the person has both the recessive alleles, the person will have anaemia, but are very resistant to malaria. To be heterozygous means you have anaemia but are more resistant to malaria. Because of this paradox, the allele frequency for the sickle cell trait is relatively stable and therefore shows balanced polymorphism. Two pressures of selection maintain this balance. On the one hand, the sickle cell trait should be selected against because it can be debilitating or lethal. On the other hand, there is a selection for it because having it gives people more resistance to malaria. The balance is reached in heterozygous individuals who tend to be more fit for survival in zones plagued by malaria but do not suffer severe anaemia. Human Evolution Assessment Statement D.3.1 Outline the method for dating rocks and fossils using radioisotopes, with reference to 14C and 40K D.3.2 D.3.3 Define half-life Deduce the approximate age of materials based on a simple decay curve for a radioisotope Describe the major anatomical features that define humans as primates Outline the trends illustrated by the fossils of Ardipithecus ramidus, Australopithecus, including A. afarensis, and A. africanus, and Homo, including H. erectus, H. neanderthalensis and H. sapiens State that, at various stages in hominid evolution, several species may have coexisted Discuss the incompleteness of the fossil record ant the resulting uncertainties about human evolution Discuss the correlation between the change in diet and increase in brain size during hominid evolution Distinguish between genetic and cultural evolution Discuss the relative importance of genetic and cultural evolution in the recent evolution of humans D.3.4 D.3.5 D.3.6 D.3.7 D.3.8 D.3.9 D.3.10 Humans are known as Homo sapiens (modern man). The full classification is: Kingdom: Phylum: Subphylum: Class: Subclass: Order: Suborder: Family: Genus: Species: Animalia Chordata Vertebrata Mammalia Eutheria Primates Anthropoids Hominidae Homo Sapiens The fossil record, allows us to look at common morphology and deduce common ancestry. The relatedness of organisms is investigated by comparative biochemical studies, particularly of mitochondrial DNA, which in each generation is passed from mother to offspring unchanged. This type of DNA undergoes a steady rate of mutation – it changes as a function of time alone. The degree of difference between mitochondrial DNA samples discloses how recently groups of organisms shared a common ancestor. Dating Rocks and Fossils Fossils can tell us a lot about the past. Fossil – any form of preserved remains from a living organism. Some examples are: Mammoths frozen in Siberia Mummies in acidic swamps in Scandinavia Insects in amber Bones in rock Fossils are only formed in some circumstances. Most individuals do not leave a fossil after death. A fossil has to be formed when an organism dies and gets buried in sedimentary silt. It will decay slowly and leave a space in the silt. The gap becomes solid and is filled the exactly the same as the organism left behind. The silt may solidify, becoming sedimentary rock and in it is the fossil. To see how old fossils are and their forms, carbon dating is used, usually Carbon 14 and potassium 40, which are isotopes. Isotopes are atoms of the element that have different numbers of neutrons. Therefore, they are unstable and will spontaneously change into one or more atoms to other elements, often emitting some radiation. The time taken for this change is determined by the kind of isotope. After a period of time, at a fixed interval, the radioactive decay will be half of what it was before. This is called half-life. For C14, the half-life is 5730 years. Using C14 Most carbon is C12, but due to cosmic radiation C14 is formed at a low, steady rate. While alive, organisms absorb carbon in the ratio of C12 / C14 present in the environment around them. After death, accumulation of radioactive (and other) atoms stops. Meanwhile, C14 steadily breaks down: half-life of 5.6 X 103 years C 14 N14 So the ratio of C14: C12 in a fossil decreases with age; the less C14, the older the fossil. This technique gives good dates for fossils of the last 60 000 years. Using the ratio of K40:Ar40 Rocks do not eat or photosynthesize. Some contain no carbon at all. Instead we use potassium – 40. The pyroclastic rocks flowing out of volcanoes may contain radioactive isotopes such as potassium-40, which decays to argon-40, as shown: K40 half-life of 1.3 X 109 yrs Ar40 (gas) In hot lava, argon gas boils away into the atmosphere. Once lava has solidified by cooling, which occurs quickly after volcanic eruptions, the argon gas that is then formed by radioactive decay is trapped in the rock. By measuring the ratio of K40: Ar40 in lava deposits, the exact ages of the lava and the approximate age of the sedimentary rocks (and their fossils) below and above lava layers are estimated. This technique spans the whole of geological time back to the Cambrian period (580 million years ago), but it is too slow to give reliable results over the most recent half million years. Determining the age of a fossil or rock. You look at the percentage of Carbon – 14 or potassium – 40 left in the fossil or rock. If there is 50% left, that means there has been 5730 years past for C14. For 25%, that would be double the half-life or 11 460 years. Another way, is to look at a decay curve and see where the amount of remaining C14 falls on the curve to estimate the time. Humans as Primates Humans belong to the mammalian order Primates. This order contains three distinctive groups of animals, namely the apes (which includes the genus Homo), the monkeys, and the prosimians (a name meaning ‘before the monkeys’). These are mostly tree-dwelling species with grasping hands and feet. The range of animals that constitute the Primates and how they are related are summarized below. Apart from humans, who have achieved worldwide distribution, most primates live in tropical and sub-tropical regions. An interesting feature of primates is their relatively unspecialized body structure, combined with some highly sophisticated behavior patterns. Why are humans defined as primates? To the biologist, humans are primate mammals. By this we mean that humans show many of the characteristics of other mammals, the general characteristics common to other primates, and many of the features shown by the great apes to which we are most closely related. Major features, which describe humans, as primates are adaptations to tree life. They are the opposable thumb, acute vision (stereoscopic vision), mobile arms and shoulder girdle and a skull modified for upright posture. Having an opposable thumb means you can manipulate objects and be able to grasp. Mobile arms, allows movement in three planes and transfer weight via the arms. This is very important for tree dwellers and for movements above the head. Also, living in trees means you can see further. As a result, the eyes are places more forward, on a flat front. This gives a smaller field of vision, but more acute and the overlap of vision allows for good depth perception and judgment of distance. Along with this is color vision. The positioning of the magnum foramen (mentioned later in these notes), allows for the spinal column to insert into the skull in a more upright position, lessening the curvature of the spine and allowing primates to walk upright. Origins of Humans – Trends in hominid and human fossils The earliest fossils which we confidently identify as anthropoids (apes) have been found at many sites in Africa. They date from about 35 million years ago (mya). Humans clearly demonstrate one form of anthropoid body organization, so we can say the human story has taken about 35 million years to unfold. There are some similarities and some major differences between all the hominid skulls that have been unearthed. The details to pay close attention to are summarized below. One key area is the foramen magnum. It is the hole where the skull is attached to the spinal column. In modern humans the hole is in the center of the base of the skull, giving rise to the theory of walking upright. In apes, the hole is further back to accommodate the spinal column in an animal that walks on four legs. There is some discussion as to what a hominid is. It can only refer to those bipedal primates, which are direct ancestors of modern humans. The chronological order of some of the species of hominid for which have been found is below. Fossils of Hominidae have lead to several speculations about evolution. 1. Ardipithicus ramidus a. Lived approximately 5.8 – 4.4 mya in Ethiopia. This species is believed to be very close to the split between the line of organisms, which became more human-like and the line, which became more chimpanzee-like. Most of the fossils are teeth and therefore, it is difficult to be sure. From what has been found, the Ardipithicus ramidus was very similar to a chimpanzee with a few hominid features. The molars show more ape-like characteristics, as the length is greater than the breadth. The canines are more hominid, as they are shorter and not as sharp as ape canines. 2. Australopithecines (southern ape) lived about 4 mya. They had 500 cm3 brains and walked upright. a. The first species was A. afarensis from the Afar desert (4-2.8 mya) found in Ethiopia and Tanzania. (Lucy skeleton) It had a tall lower jaw, fairly large molar teeth and a projecting face. The cranial capacity was 380 – 430 cm3. b. Later came africanus (3-2 mya) found in South Africa. It is thought to be the same species as afarensis as features are similar and walked upright. It had a tall, thick lower jaw, large molars and a projecting face. The cranial capacity was 435 – 530 cm3. c. Later was A. robustus (2-1.4 mya) in South Africa. They were larger and heavily built. 3. Then came the Homo genus. They were from around 2 mya and had larger brains (600 cm3) and walked upright. a. First was H. habilis (handy man). It is thought he arose from A. afarensis 2 mya in East Africa and used simple tools. It had a flatter face, larger molars but the cranial capacity was still only about 600 cm3. b. Homo erectus was from Africa. It is thought it migrated to other parts of the world and had a larger brain than H. habilis. H. erectus spread to Asia and Europe. However, it is believed that H. sapiens evolved at one place in Africa and from their spread out over the world. It has a smaller jaw, a receding forehead, large brow ridges and smaller molars. Its cranial capacity was 1000 cm3. c. H. neanderthalensis, which lived in Eurasia from 200 000 to 30 000 years ago. The species survived several ice ages. It has a smaller jaw, a lower forehead, smaller brow ridges and smaller molars than the previous species. They had larger brains than modern humans, with a cranial capacity of up to 1600 cm3. d. Next was H. sapiens, which came to Europe. The first subspecies was Cro-Magnon man, who looked a lot like modern humans and though to have used the first language. H. sapiens lived around 140 000 to 70 000 years ago in Africa and Asia as well. They had a high forehead, no brow ridges, a flat face, small molars and a very small jaw. This species developed cave paintings, tools and weapons. The cranial capacity was similar to today’s humans of 1300 cm3. Based upon where the skulls were found and dating, we can see that many species may have coexisted. As the Homo sapiens developed, so were the homo neaderthalenis. The incompleteness of the Fossil Record Anthropologists disagree about the origin of modern humans from time to time. They use evidence from fossil remains, from artifacts like stone tools that can be associated with particular hominids, and the record in animal bones that surrounded their habitations and which indicate diet. Fresh evidence of these types is frequently discovered, and existing data are sometimes reinterpreted. Re-interpretation occurs in the light of new biochemical evidence or the development of new analytical techniques. For example, until quite recently, another theory about the origin of modern humans vied with the current ‘out of Africa’ theory. The alternative was a multiregional model, in which H. sapiens emerged wherever populations of H. erectus had become established, in Africa, Europe and Asia. This made H. neanderthalensis only one example of an archaic hominid form, intermediate between H. erectus and modern humans. According to this model, there was ongoing genetic exchange between populations of various archaic forms until H. sapiens emerged and replaced all others. Currently, the body of evidence is increasingly against this theory. Controversy will continue because of the inevitable incompleteness of the fossil record. Fossilization is an extremely rare, chance event. This is because predators, scavengers and bacterial action normally break down dead plant and animal structures long before they can be fossilized. Of the relatively few fossils formed, most remain buried, or if they do become exposed, are often overlooked or may be accidentally destroyed before discovery. Nevertheless, numerous fossils have been found, and as more hominid fossils are discovered, so our knowledge may change and our understanding of our past be advanced. This is yet one more branch of science where the frontier of knowledge is entirely open. You can follow the debate from now on. Brain Size So why did the brain develop? Some think because the environment was so diverse, a larger brain was needed to deal with the challenges, and therefore, larger brains were selected as an advantage. Habilines were the first hominids to be associated with tools – they used large pebbles, chipped in at least two directions, as sharpened implements to crush, break and cut. Their additional brain capacity had resulted in advanced manual dexterity. It was applied to the making and using of simple tools (selected strong stones) to chip pebbles, for a purpose. Using tools to make tools (i.e. the development of a tool industry) is what distinguishes hominid toolmakers from all other tool-users in the living world. Skull endocasts (casts of the inside of the brain case of the skull) show that the areas of the brain associated with speech and language are significantly developed, so we can assume that cultural evolution was also under way. This was also the first hominid to use fire consistently, which will have aided the colonization of areas so far north of equatorial Africa, and also with its habit of eating meat. By modern human standards, H. erectus had a marked brow-ridge and protruding jaws, but the pronounced sexual dimorphism of earlier hominids was reduced – adult males were now only about 20–30% larger than females. The brain size of Neanderthals was larger than that of modern humans. This may reflect the requirements of controlling the large musculature, because they were heavier and more muscular than H. sapiens. The latter are more slightly built, but taller and longerlimbed. Humans were hunter–gatherers but compared with many of the competing wild animals, not especially strong or fast. Scavenging would have been a major source of nutrients, at least initially. Only with the development of agriculture and other advances in technology (e.g. brewing, cheese making) did humans move into circumstances in which population sizes grew significantly, and they could start to dominate their environment and become secure. The issue of the actual diet at each stage may have been a critical factor. This is because brains are metabolically expensive. Our brains make up 2% of our body mass but respire about 20% of our energy budget. The human brain is about three times the size of that of an equivalently sized ape. We may conclude that the expansion in the brains that we have noted in the succeeding species of Homo will have demanded enhanced energy supplies. This means that human evolution must have been increasingly dependent on a reliable supply of protein and fat. However, it is not dependent on advanced hunting skills, at least not from the outset. Hominids will have discovered that the long bones of herbivorous mammals (discarded by the large carnivorous mammal hunters around them) were a rich source of bone marrow. Bone marrow is rich in protein and fat and could be accessed by nothing more sophisticated than a heavy blow from a rock onto the bone shaft, held against a hard place. Bipedalism Parts of skulls of this genus have been uncovered in various locations (including at Taung, in 1924), prior to the discovery of a new hominid fossil, first known as Lucy, at Hadar in Ethiopia in 1974. Lucy is identified as Australopithecus afarensis. She was ape-like in that she had the same limited brain capacity as ape species of the period, but hominid-like in that she was a powerful, upright walker (the pelvis was of characteristically human form) and had no long muzzle. We now recognize that upright walking (known as bipedalism) was an early stage in the evolution of the hominids. The Lucy fossil was laid down 3 mya. We are confident about bipedalism at this time, because of the discovery of the footsteps at Laetoli, imprinted in volcanic ash, 3.6 mya. The soft ash was presumably moistened by rain (no additional prints added), immediately baked into hard rock, and then buried by soil blown in. The footsteps were discovered in 1976. Two adults had walked in line, in a northerly direction, with a youngster who later ran off to one side. Being volcanic ash, this trace fossil can be dated precisely by the potassium:argon ratio method. One advantage of bipedalism (perhaps the chief advantage, initially) is as a mechanism to prevent the head region of the body overheating at the high midday temperatures of equatorial latitudes. Being upright does not expose as much surface area to the sun. Australopithecines lived in mosaic environments: part tropical rainforest, part woodland and tree-savannah, part scrub. Wherever they lived, no doubt they preferred to shelter at times of greatest temperature. But they may have often needed to travel to new venues, visit water holes, or scavenge and collect food at times when faster and stronger predatory animals were most likely to be resting. If so, being bipeds gave them an advantage. Another critical advantage of bipedalism is that hands are freed for obtaining and carrying food. Apes breed slowly, producing few offspring at a time. A male ape that had mastered bipedalism could improve his mate’s reproductive capacity by feeding her, thus freeing her to concentrate on the production and rearing of young. The genes of apes with a tendency for bipedalism will have had a better chance of replication in future generations. This would have been particularly effective in male–female pairs, rather than in troops of primates where males invested time and energy maintaining dominance over the females. On this account, hominids would have tended to be monogamous apes with lessened sexual dimorphism (males the same size as females). Genetic vs. Cultural Evolution Genetic evolution refers to the changes in allele frequencies that result in changes in individuals and therefore in populations, brought about by natural selection. In outline, these are due to: Genetic variations, which arise via mutations, random assortment of paternal and maternal chromosomes in meiosis, recombination of segments of maternal and paternal homologous chromosomes during crossing over that occurs in meiosis in gamete formation, and the random fusion of male and female gametes in sexual reproduction. When genetic variation has arisen in organisms, it is expressed in their phenotypes. Some phenotypes are better able to survive and reproduce in a particular environment, and natural selection operates to determine the survivors and the genes that are perpetuated in a population. In time, this process may lead to new varieties and new species. By cultural evolution we refer to the development of the customs, civilization and achievements of people. The development and transmission of human culture has a biological basis. Key to this was the extension of the period of parental care, delayed onset of puberty, and the resulting long period of childhood when the next generation of a population are trained and schooled as they develop essential survival skills – all features of the evolution of the genus Homo. The development of language is the most important human characteristic central to the evolution of culture. Endocasts give a slight impression of the areas of the brain that developed and were enlarged (the chief neural machinery for speech in most modern humans is found in the left hemisphere). Also critical is the position of the vocal folds in the neck. On both counts it seems likely that only Neanderthals and H. sapiens achieved the structures necessary for elaborate vocal communication. In particular, the high palate and high larynx found in H. sapiens allowed a greater range of resonance for complex word sounds. Once established, verbal communication allowed advantageous developments (for example, in the form of new ideas) to be passed on rapidly. The potential speed of development of this form of cultural evolution contrasts markedly with change brought about by slow inherited accumulation of advantages by genetic evolution. Today’s latest cultural-sharing breakthroughs – the Internet and the human genome project – are cases in point. The developments in tool technology were also dependent on the development of a large brain. Compared to the achievements of the Habilines in this, from about 35 000 years ago, modern humans made spectacular advances. Bone and antler were added to the list of raw materials, and advances in the skills of fashioning stone flakes and blades into finely worked scrapers, chisels, drills, arrowheads and barbs were spectacular. Tool-kits comprised items for engraving and sculpture. Functional implements like spears became decorated with life-like animal carvings. The latter point relates to human use of the brain, powers of detailed observation, and manual dexterity, all of which underpin cultural development. Homo sapiens as observers and artists achieved incredible feats at the earliest phase of their development. We have a remarkable record of the artistic skills of our first human ancestors in the cave paintings from this period that have been discovered. The drawings, produced by human communities from 25 000 to 10 000 years ago, show contemporary animals in scientific detail. The pictures demonstrate perspective representation. The relative importance of genetic and cultural evolution is quite obvious. Genetic evolution has given rise to the diversity of living things, including human beings. However, this is a process that has taken thousands of millions of years. The special features that humans have developed, mostly unique to them, have been the basis of cultural evolution. For example, with the development of agriculture and other technologies, humans have changed their immediate environment with the creation of settlements and then gone on to evolve communal living. Enlarged populations have been both necessary to the new way of life, and sustained by it. Rules and laws have succeeded basic customs, and individuals have acquired rights and responsibilities. Consequently, the conditions for genetic evolution have been progressively sidelined as the processes of cultural evolution have taken over. Brain Size and Evolution Taxonomy The Science of Classification Assessment Statement 5.5.1 5.5.2 5.5.3 5.5.4 5.5.5 Outline the binomial system of nomenclature List seven levels in the hierarchy of taxa – kingdom, phylum, class, order, family, genus and species, using an example from two different kingdoms for each level Distinguish between the following phyla of plants, using simple external recognition features; bryophyta, filicinophyta, coniferophyta and angiospermophyta Distinguish between the following phyla of animals, using simple external recognition features; porifera, cnidaria, platyhelminthes, annelida, mollusca, and arthropoda Apply and design a key for a group of up to eight organisms Classification is an essential tool in Biology as there are many organisms to name. The process of classification involves giving every organism an agreed name and the arranging of organisms into groupings of apparently related organisms. Overall, we see a scheme of the overall diversity of living things. Classification also attempts to reflect any evolutionary links. The Binomial System The binomial system of nomenclature was invented by Carolus Linnaeus in the 18th Century. It is still used today and is based on the idea that every species has a Latin name, made up of two parts. The first part of the name is the genus or the generic name based upon a noun. The second name is the species, or the specific name, based upon an adjective. For example: The Scheme of Classification The science of classification is taxonomy. “Taxa” is the general word for groups or categories. Biological classification is the invention of biologists, based upon the best evidence at the time. There are 7 categories for naming: Kingdom – largest and most inclusive grouping Phylum / division – organisms constructed on a similar plan Class – a grouping of orders within a phylum Order – a group of apparently related families Family- a group of apparently related genera Genus - a group of similar and closely related species Species – a group of organisms capable of interbreeding to produce fertile offspring There are 5 kingdoms to classify organisms. They are: 1. Prokaryotes – unicellular organisms lacking nuclei and other membrane bound organelles. DNA is mainly circular and is not organized in chromosomes. Examples are bacteria and cyanobacteria 2. Protista – unicellular and multicellular eukaryotic organisms that may be autotrophic or heterotrophic and may live in salt or fresh water. Examples are Euglena and Paramecium 3. Fungi – Eukaryotic filamentous or unicellular. Filamentous fungi grow a mycelium from which mushrooms or toadstools grow. They are heterotrophic and they feed by absorption of nutrients. Their cells have chitin in the cells walls, as opposed to cellulose. Examples are yeasts and mushrooms. 4. Plantae – Eukaryotic, multicellular, phosynthetic organisms. The cells walls contain cellulose, and most cells contain chlorophyll. Examples are mosses, ferns, flowering plants. 5. Animalia - Eukaryotic, multicellular, heterotrophic organisms that are often motile, and feed by ingestion. Examples are humans and jellyfish. Below are some examples. Distinguishing Between the Phyla 1. Plantae phyla To distinguish between the four phyla, two categories can be used: Vegetative characteristics such as leaves and stems Reproductive characteristics Bryophytes (mosses, liverworts) are non-vascular as the have no true xylem or phloem do not produce seeds or flowers, but spores which are transported by water (which is the reason they are found in moist environments Filicinophyta (ferns and horsetails) are vascular but reproduce by spores Coniferophyta (cedars, junipers, fir, pine trees) Vascular, woody stems and leaves are in the form of needles or scales All species of conifer use wind to help them reproduce by pollination Produce seed cones with seed scales Angiospermophyta Vascular stems Produce seeds that are not all pollinated by wind, and use insects, birds and other animals Use flowers to reproduce and fruit hold the seeds. 2. Animalia Phyla All of the six phyla are invertebrates (they have no backbone) Porifera (sponges) Simple marine animals that are sessile (stuck in place) No mouth or digestive tract Feed by pumping water though their tissues to filter out food Have no muscle of nerve tissue and no distinct internal organs Cnidaria (corals, sea anemones, jellyfish, sea jellies, hydra) Some are sessile, others are free swimming To digest food, they catch it in their tentacles and have a gastric pouch with only one opening. ALL have stinging cells call nematocysts Platyhelminthes (flatworms) Only one body cavity a gut with an opening for food to enter and waste to exit No heart or lungs Flat shape to have cells close to surface for gas exchange by diffusion Annelida (earthworms, leeches and polychaetes) Segmented worms, as their bodies are divided up into sections, separated by rings Bristles on their body Gastric tract with a mouth at one end and the intestines have an opening at the other end where wastes are released Mollusca (snails, clams, and octopi) Many produce a shell and are not segmented Gastric tract with a mouth at one end and the intestines have an opening at the other end where wastes are released THEY WILL NOT SHARE!!! Arthropoda (insects, spiders, scorpions, and crustaceans (crabs, shrimp)) Have a hard exoskeleton, made of chitin Segmented bodies The Dichotomous Key The process of naming unknown organisms in ecological fieldwork is time consuming. Often comparisons are made using books with illustrations and information that provide us with clues about habitat and habits, which we can use to identify organisms. Alternatively, the use of keys may assist in the identification of unknown organisms. The advantage is that it requires careful observation. The structural features of organisms, allows us to understand how different organisms may be related. Steps in Key Construction A dichotomous key is a method for determining the identity of something (like the name of a butterfly, a plant, a lichen, or a rock) by going through a series of choices that leads the user to the correct name of the item. Dichotomous means “divided in two parts”. At each step of the process of using the key, the user is given two choices; each alternative leads to another question until the item is identified. It is like playing “Guess Who” or 20 Questions. For example, a question in a dichotomous key for trees might be something like, “Are the leaves flat or needle-like?” If the answer was “needle like”, then the next question might be something like, “Are the needles in a bunch or spread along the branch?” Eventually, when enough questions have been answered, the identity of the tree is revealed. Below are several leaves of several trees. Also there is a Spider Key and a Couplet Key. Each is acceptable. You will construct a key with the above fictional animals. When you construct a key, keep the following in mind: 1. 2. 3. 4. 5. 6. 7. Use constant characteristics rather than variable ones. Use measurements rather than terms like “large” and “small”. Use characteristics that are generally available to the user of the key, rather than seasonal characteristics or those only in the field. Make the choice a positive one – something “is” instead of “is not”. If possible, start both choices of a pair with the same word. If possible, start different pairs of choices with different words. Precede the descriptive terms with the name of the part to which they apply. When you are done, move on to the assignment on Constructing a Dichotomous Key. Mathematics of Population at Equilibrium Hardy-Weinberg Principle Assessment Statement D.4.1 Explain how the Hardy-Weinberg equation is derived D.4.2 Calculate allele, genotype and phenotype frequencies for two alleles of a gene, using the Hardy-Weinberg equation State the assumptions made when the HardyWeinberg equation is used D.4.3 We have noted that in any population, the total of the alleles of the genes located in the reproductive cells of the individuals make up a gene pool. A sample of the alleles of the gene pool will contribute to form the genomes (gene sets of individuals) of the next generation, and so on, from generation to generation. When the gene pool of a population remains more or less unchanged, then we know that population is not evolving. However, if the gene pool of a population is changing (i.e. the proportions of particular alleles are altered – we say ‘disturbed’ in some way), then evolution may be going on. How can we detect change or constancy in gene pools? The answer is, by a mathematical formula called the Hardy–Weinberg formula. Independently, this principle was discovered by two people in the process of explaining why dominant characteristics don’t take over in populations, driving out the recessive form of that characteristic. For example, at the time, people thought (wrongly) that human eye colour was controlled by a single gene, and that an allele for blue eyes was dominant to the allele for brown eyes. They wanted to answer the question, “Why doesn’t the population become blue-eyed?”. Hardy and Weinberg came up with an idea that is all factors remain the constant in a population, the gene pools composition will remain the same as well. To test this, field studies need to be done to determine the relative percentage of phenotypes in population. An example was the Peppered Moth. Studying the amounts of white vs. dark began in 1959. Keep in mind this was the time when the pollution was greatest. The results were as follows: - 1959 – 94% of moths were dark 1969 – 90% of moths were dark 1979 – 79% of moths were dark 1989 – 40% of moths were dark 1994 – 19% of moths were dark This could also be calculated using the Hardy-Weinberg Principle. It is a mathematical model for calculating allele frequency for a gene with two (or three) alleles. The formula For 2 alleles of a gene: - Use B for dominant, and its frequency in the population is p (a number between 0 –1) - Use b for recessive, and its frequency in the population is q (a number between 0 –1) - A gene must have an allele, with the options either B or b. No other options are available, so if B is present, it frequency is 1, and b is 0, therefore p + q = 1 (1+0) - Each gene has two alleles, so if the frequency of B is p, then BB is p2 - If the frequency of b is q, then bb is q2 - If you have Bb, the frequency is 2pq - Since genotypes must be one of the three, the percentage in a population will be: p2 + 2pq + q2 = 1 This is the Hardy-Weinberg equation. In order to be used, the following conditions need to be observed. - Large population Random mating occurs No directional selection (no advantage) No allele specific mortality No mutations No immigration or emigration Example 1 In a certain population of Drosophila, 64 individuals are found to have red eyes (wild type) and 36 are found to have white eyes. Find the allele frequency for each allele and the genotype and phenotype frequency. Questions using the Hardy-Weinberg equation 1. Suppose a recessive genetic disorder occurs in 9% of the population. Determine what percentage of the population is heterozygous for this disorder. 2. For a hypothetical moth population, suppose that 60% of the moths are white coloured and 40% are dark coloured, with white being dominant. Three years later, the percentages are 65% white and 35% black. What does this shift say about the dark phenotype? 3. In a population of mosquitoes, the frequency of the recessive allele for vestigial wings is 30%. Predict how many flies would be expected to have normal wings in a population of 125. Phylogeny and Systematics Assessment Statement D.5.1 D.5.2 D.5.3 D.5.4 D.5.5 D.5.6 D.5.7 D.5.8 D.5.9 D.5.10 Outline the value of classifying organisms Explain the biochemical evidence provided by the universality of DNA and protein structures for the common ancestry of living organisms Explain how variations in specific molecules can indicate phylogeny Discuss how biochemical variations can be used as an evolutionary clock Define clade and cladistics Distinguish, with examples, between analogous and homologous characteristics Outline the methods used to construct cladograms and the conclusions that can be drawn from them Construct a simple cladogram Analyse cladograms in terms of phylogenetic relationships Discuss the relationship between cladograms and the classification of living organisms One of the objectives of classification is to represent how living and extinct organisms are connected, which means natural classification. Phylogeny is the study of the evolutionary past of a species. Species which are the most similar are most likely to be closely related, whereas those which show a higher degree of difference are considered less likely to be closely related. There are several values to classifying this way. 1. We can identify unknown organisms, as other similar organisms are grouped together using a key. 2. We can see how organisms are related in and evolutionary way. By looking at organisms, which have similar anatomical features, it is possible to see relationships on their phylogenetic tree. DNA evidence confirms the anatomical evidence for placing organisms in the same group. 3. It allows for the prediction of characteristics shared by members of a group. Biochemical Evidence for common ancestry Biochemical evidence, including DNA and other protein structures, has brought new validity and confirmation to the ideas of a common ancestor. The fact that every known living organism on Earth uses DNA as its main source of genetic information is compelling evidence that all life came from a common ancestor. All the proteins found in living organisms use the same 20 amino acids to forms their polypeptide chains. Genetic engineering has provided some evidence of this. Amino acids can have two possible orientations: left-handed and right-handed, depending on how the atoms are attached. All the living organisms on Earth have lefthanded amino acids and none are right-handed, leading to the belief that there is a common ancestor. Traditionally, looking for similarities has been done using morphology. More attention recently to molecular differences is now the area of study. Although the same components are used to make DNA and protein in all organisms, the sequence of these components may be different. If we compare the amino acid sequences of haemoglobin in humans, cats and earthworms, we see that cats and humans have greater similarities that humans and earthworms. This shows two trends: 1. The more similar the biochemical evidence, the more interrelated the species are 2. The more similar the evidence, there is less time since the two species had a common ancestor (ie. The ancestor of earthworms lived a longer time ago than the ancestor of cats and human. 3. Changes in the DNA sequences of genes from one generation to another are partly due to mutations and the more differences there are between two species, the les closely related they are. Here is an imaginary example of DNA sequence from four different species. 1. 2. 3. 4. AAAATTTTCCCCGGGG AAAATTTACCCCGGGG AAAATTTACCCGCGGG AACATCTTCCACGCTG It is clear that species 1 and 2 have the fewest differences between them and we can conclude that they are more closely related. Since this evidence is not conclusive on its own, it is often used together with other data, such as palaeontological data. The evolutionary clock The principle is you study similar molecules in different species and determine how much difference there is between the molecules. The more difference there is, the longer the time span since the two species had a common ancestor. Differences in polypeptide sequences accumulate steadily and gradually over time, as mutations occur from generation to generation in a species. The changes can be used as a kind of clock to estimate how far back in time two related species split from a common ancestor. This is called the evolutionary clock. Commonly used proteins are haemoglobin, cytochrome c (a respiratory protein which is part of the electron transport chain) and nucleic acids. We count up the number of base pairs, which do not match. Using haemoglobin show that humans are more closely related to chimps rather than gorillas or gibbons. Using cytochrome c, we see that humans have identical molecules, while rhesus monkeys only differ by one amino acid. Humans and rhodospirillium (bacteria) or yeast (fungi) have identical amino acid sequences in part of the cytochrome c molecule!!! Number of differences in the Beta Haemoglobin Chain compared to Human Haemoglobin. Imagine comparing certain DNA sequences form three species A, B and C. Between the DNA samples from A and C there are 83 differences. Between A and B, there are only 26 differences. We can conclude that A is more closely related to B than C. There has been more time for DNA mutations to occur since the split between A and C than since the split of A and B. One technique, which has been successful in measuring differences in biochemical studies, is DNA hybridization. We take one strand of DNA from species A and a homologous strand from B and fuse them together. Where the base pairs connect, there is a match; where they are repelled and do not connect, there is a difference in the DNA sequence. This can be taken further. If we see that 83 differences is approximately three times more than 26 differences, we can conclude that the split between species A and C happened about three times further in the past that the split between species A and B. We can express this in a cladogram. There are two forms, which we will look at in a little bit. Percentage difference in DNA A B C C B A Time in mya Keep in mind this clock is not a consistent “tick-tock” like the clock on the wall. Mutations happen at varying rates. The above is an estimation of the events. Again this is all compared to morphological data and radioisotope dating. Clades and Cladistics Cladistics – a system of classification, which groups taxa together according to the characteristics, which have most recently evolved. It is the concept of common descent that decides into which group an organism belongs. It is therefore an example of natural classification, where primitive and derived traits are looked at as to how many are shared. Clade – a monophyletic group. This means it is a group composed of the most recent common ancestor of the group and all its descendents. It could be made up of several species. Comes from the Greek work ‘klados’ meaning ‘branch’. To decide how close a common ancestor is, researchers look at how many primitive and derived characteristics the organisms share. Primitive traits (plesiomorphic traits) are characteristics which have the same structure and function and which evolved early on in the organism’s development. Derived traits (apomorphic traits) are characteristics which have the same structure and function, but which evolved more recently as modifications of a previous trait. A primitive trait would be plants with vascular tissue in leaves but a derived trait are the flowers, which developed after the leaves in angiosperms. Analogous and homologous characteristics To put organisms in the appropriate clades, two types of characteristics considered are analogous and homologous characteristics. Homologous – are characteristics from the same part of the common ancestor. Pentyldactal limbs are examples. Eyes are another example. Analogous – are characteristics which may have the same function but do not have the same structure. All animals with wings fly, but they are not in the same clade due to the structural differences between a fly wing, and a bird’s wing. How cladograms are made To represent the findings of cladistics in a visual way, a cladogram is used. It is a diagram, in which nodes are used to separate species and organisms, which have diverged from the common ancestor and form a clade. The cladogram below takes into account skeletal structures and that bats and dolphins are placental mammals. The way to construct a cladogram is to look at biochemical differences or morphological differences. 1. Make a list of the organisms involved 2. Make a list of as many possible characteristics, which each organism possesses. 3. From the list many traits will clearly be derived characteristics a. Examples are: i. Eukaryotic ii. Backbone iii. Amniote egg iv. Limbs v. Hair vi. Opposable thumbs vii. Multicellular viii. Segmented body ix. Jaws x. Placenta xi. Mammary glands 4. Once the list has been established, there will be one, which is common to all the organisms being studied. The ancestral trait is considered the primitive characteristic. Morphologically, would be eukaryotic or multicellular. In biochemical data, it might be a certain sequence to base pairs. 5. You make a table like below, showing the derived characteristics. 6. You make the cladogram with the first branch form the bottom belonging to the organism with the fewest derived traits. The organism with the most derived characteristics goes to the top of the last branch. Why are cladograms constructed? To show the evolutionary relationships between organisms. It can be concluded that organisms whose branches start at the bottom of the cladogram are the earliest ones to have evolved and the ones at the top are the ones, which have evolved most recently among the organisms considered in the cladogram. Each time there is a point where the branch forks into two, a split occurred between species to develop into two lineages. This splitting point is called a node and it shows where a new species and a new clade, was founded. This makes the assumption that only one branching off can happen at any one time, generating two species where there was previously one. One of the basic ideas behind cladistics is the concept of parsimony. This refers to the preference for the least complicated explanation for a phenomenon. It would be unlikely that a species would take two steps to evolve, if one step is possible. To confirm the common ancestry from a cladogram, which is based on morphological evidence, another should be made using biochemical data for the same organisms. The two cladograms should be identical. Construct a Cladogram The organisms are paramecium, flatworm, shark, hawk, koala, camel, human Characteristics are eukaryotic, multicellular, have a vertebral column, produce an amniote egg, have hair, have a placenta, have one opposable thumb on each forelimb. Construct your cladogram Analyze What was the primitive characteristic? For each node, list the characteristic to put the organism in each clade. Cladograms and classification Cladistics attempts to find the most logical and most natural connections between organisms to reveal their evolutionary past. Every cladogram drawn is a working hypothesis. It is open for testing and falsification. This makes cladistics scientific but changes are new evidence arises. Each time a derived characteristic is added to the list shared by organisms in a clade, the effect is similar to going up one level in the traditional hierarchy of the Linnaean classification scheme. Hair is what defines a mammal, so any species with hair is a mammal. What about feathers? If an organism has feathers, is it automatically a bird? In traditional classification, birds occupy a class of their own, but this is where cladistics comes up with a surprise. When preparing a cladogram, it becomes clear that birds share a significant number of derived characteristics with a group of dinosaurs called the theropods. This suggests that birds are an offshoot of dinosaurs rather than a separate class of their own. Since birds are one of the most well documented classes of organisms on Earth, this idea was controversial. Some derived characteristics are: Fused clavicle (wishbone) Flexible wrists Hollow bones Characteristic egg shell Hip and leg structure, notably with backward pointed knees Following parsimony, it would be more likely that birds evolved from dinosaurs that they evolved from another common ancestor. This is where cladistics is clearer than the Linnaean system. In cladistics, the rules are always the same concerning shared derived characteristics and parsimony. In the Linnaean system, apart from the definition of species, which we have already seen can be challenged, the other hierarchical groupings are not always clearly defined: what makes a class a class and a phylum a phylum? Biologists now increasingly adopt cladistics as a useful tool for determining natural classification and evolutionary connections.
