* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Mrs. Ashley`s PowerPoint Chapter 5 Evolution and
Survey
Document related concepts
Transcript
Chapter 5 Evolution of Biodiversity Earth is home to a tremendous diversity of species • • • Ecosystem diversity- the variety of ecosystems within a given region. Species diversity- the variety of species in a given ecosystem. Genetic diversity- the variety of genes within a given species. Biological Diversity Biological Diversity Number, variety and variability of Earth’s organisms- 1.9 million identified Consists of three components: Genetic diversity (below) Species richness Ecosystem diversity Functional Diversity The biological and chemical processes such as energy flow and matter recycling needed for the survival of species, communities, and ecosystems. Heat Chemical nutrients (carbon dioxide, oxygen, nitrogen, minerals) Heat Solar energy Heat Decomposers (bacteria, fungi) Heat Ecological Diversity The variety of terrestrial and aquatic ecosystems found in an area or on the earth. Producers (plants) Consumers (plant eaters, meat eaters) Genetic Diversity The variety of genetic material within a species or a population. Heat Species Diversity The number and abundance of species present in different communities. Fig. 4-2, p. 82 How Do New Species Evolve? • Speciation: one species splits into two or more species • Geographic isolation: happens first; physical isolation of populations for a long period • Reproductive isolation: mutations and natural selection in geographically isolated populations lead to inability to produce viable offspring when members of two different populations mate • • Species richness- the number of species in a given area. Species evenness- the measure of whether a particular ecosystem is numerically dominated by one species or are all represented by similar numbers of individuals. Evolution is the mechanism underlying biodiversity • • • • Evolution- a change in the genetic composition of a population over time. Microevolution- evolution below the species level. Macroevolution- Evolution which gives rise to new species or new genera, family, class or phyla. Natural Selection = the process by which traits that enhance survival and reproduction are passed on more frequently to future generations than those that do not Creating Genetic Diversity • • • • Genes- physical locations on chromosomes within each cell of an organism. Genotype- the complete set of genes in an individual. Mutation- a random change in the genetic code. Phenotype- the actual set of traits expressed in an individual. Evolution by artificial and natural selection • • Evolution by artificial selection- when humans determine which individuals breed. Evolution by natural selection- the environment determines which individuals are most likely to survive and reproduce. Darwin’s theory of evolution by natural selection • • • • • Individuals produce an excess of offspring. Not all offspring can survive. Individuals differ in their traits. Differences in traits can be passed on from parents to offspring. Differences in traits are associated with differences in the ability to survive and reproduce. • • • • Evolution by Random Processes Mutation- occur randomly and can add to the genetic variation of a population. Genetic drift- change in the genetic composition of a population over time as a result of random mating. Bottleneck effect- a reduction in the genetic diversity of a population caused by a reduction in its size. Founder effect- a change in a population descended from a small number of colonizing individuals. Speciation and extinction determine biodiversity • Allopatric speciation- when new species are created by geographic or reproductive isolation. • Sympatric speciation- the evolution of one species into two species in the absence of geographic isolation, usually through the process of polyploidy, an increase in the number of sets of chromosomes. Sympatric speciation • Sympatric speciation = species form from populations that become reproductively isolated within the same area • Feed in different areas, mate in different seasons • Hybridization between two species • Mutations The pace of evolution Evolution shapes ecological niches and determines species distributions • • Range of tolerance- all species have an optimal environment in which it performs well. The limit to the abiotic conditions they can tolerate is known as the range of tolerance. Fundamental niche- the ideal conditions for a species. Niches • • • Realized niche- the range of abiotic and biotic conditions under which a species lives. This determines the species distribution, or areas of the world where it lives. Niche generalist- species that live under a wide range of conditions. Niche specialist- species that live only in specific habitats. Adaptive Radiation Emergence of numerous species from a common ancestor introduced to new and diverse environmentshappens when a niche opens due to changes Example: Hawaiian Honeycreepers Natural selection acts on genetic variation • • • Directional selection = drives a feature in one direction Stabilizing selection = produces intermediate traits, preserving the status quo Disruptive selection = traits diverge in two or more directions If the environment changes, a trait may no longer be adaptive Coevolution • Evolutionary change One species acts as a selective force on a second species Inducing adaptations that act as selective force on the first species Example: Wolf and Moose Acacia ants and Acacia trees Yucca Plants and Yucca moths Lichen 1. 2. 2. 3. • • • Convergent Evolution Species from different evolutionary branches may come to resemble one another if they live in very similar environments Example: 1. Ostrich (Africa) and Emu (Australia). 2. Sidewinder (Mojave Desert) and Horned Viper (Middle East Desert) Scientific Importance of Genetic Diversity Genetic Engineering Incorporation of genes from one organism into a different species Provided: New vaccines More productive farm animals Agricultural plants with desirable characteristics Depends on genetic diversity (cannot create genes) Important to protect this diversity Why we need diversity Example contributions to human life: Food Clothing Shelter Pollination of crops Antibiotics and medicines Biological processes (nitrogen fixation) Understanding evolution is vital • It alters the genetic makeup of a population • It is important for understanding antibiotic and pesticide resistance, agricultural issues, production, medicines, etc. • Organisms adapt to their environment and change over time Evidence of Evolution • 1. Biogeography • 2. Fossil Record • 3. Taxonomy • 4. Homologous Structures • 5. Comparative Embryology • 6. Molecular Biology The Fossil Record • Fossils- remains of organisms that have been preserved in rock. Much of what we know about evolution comes from the fossil record. Science Focus: Species Richness on Islands • Species equilibrium model, theory of island biogeography • • • Rate of new species immigrating should balance with the rate of species extinction Island size and distance from the mainland need to be considered Edward O. Wilson The Five Global Mass Extinctions • Mass extinction- when large numbers of species went extinct over a relatively short period of time. • • • Earth has had several mass extinctions Background extinction rate = extinction usually occurs one species at a time Mass extinction events = five events in Earth’s history that killed off massive numbers of species at once • 50-95% of all species went extinct at one time Humans are causing the sixth mass extinction event • • • Resource depletion Population growth Development Adaptive Radiation-- new species evolve during recovery period following mass extinction Mass Extinctions Date of the Extinction Event Percent Species Lost 65 mya (million years ago) 85 Dinosaurs, plants (except ferns and seed bearing plants), marine vertebrates and invertebrates. Most mammals, birds, turtles, crocodiles, lizards, snakes, and amphibians were unaffected. 213 mya 44 Marine vertebrates and invertebrates 248 mya 75-95 Marine vertebrates and invertebrates 380 mya 70 Marine invertebrates 450 mya 50 Marine invertebrates Species Affected The Sixth Mass Extinction • • • Scientists feel that we are in our sixth mass extinction, occurring in the last two decades. Estimates of extinction rates vary widely, from 2 % to 25% by 2020. In contrast to previous mass extinctions, scientists agree that this one is caused by humans. Characteristics of Endangered Species Extremely small (localized) range Requiring a large territory Living on an island Having a low reproductive success Small population size Low reproductive rates Requiring specialized breeding areas Having specialized feeding habitats Endangered & Extinct Species Endangered & Extinct Species Earth’s Biodiversity Hotspots Causes of Loss of Biodiversity • Habitat Loss • Invasive species • Climate change • Pollution • Overharvesting