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What is Evolution? The process of change in the traits of populations over time. Process by which species' characteristics change over generations. Traits must have genetic basis. Evolution does not occur within an individual. Evolution does not occur within a generation. What is Evolution? Evolution occurs primarily through natural selection Natural Selection is the process that determines which individuals within a species will reproduce and pass their genes to the next generation. Proposed by Charles Darwin in his book “On the Origin of Species” published in 1859 Genes— Distinct pieces of DNA that determine an individual’s characteristics. Population—All organisms of the same kind found within a specific geographic region. (have the potential to interact) Species— Those organisms potentially capable of reproducing naturally among themselves, and producing viable offspring. Natural selection can occur when: * Individuals within a species show genetically determined variation in traits -this variation makes some individuals better at surviving and reproducing than others * More offspring are produced than survive to reproduce *Offspring with a particular trait survive better than do those without that trait *Over several generations, the frequency of that trait increases in the population FLOW CHART FOR EVOLUTION Potential for rapid reproduction Relatively constant resources and population size over time Competition for survival and reproduction Variability in structures and behaviors NATURAL SELECTION: On the average, the better adapted organisms leave the most offspring Observation Conclusion based on observation Some variability is inherited EVOLUTION: The genetic makeup of the population changes over time, driven by natural selection Evolution in action Pepper Moths in England two forms: light and dark Prior to 1845, most moths light colored Light colored ones could blend in with lichens on trees Evolution in action Pepper Moths in England Increasing pollution led to soot-covered trees without lichens Light colored moths easy for birds to see on soot-covered tree, dark colored moths harder to see By 1950, most moths black Before 1845 Environment changes, now more black moths and fewer white moths survive to adulthood Several more generations later Several generations later TIME 1950 Several more generations later Evolution in action Resistance to herbicides Evolution in action Resistance to antibiotics •Evolution does not just happen on long time scales •Evolution is important for real-word issues: agricultural, conservation, health * Disease dynamics * Invasive species issues * Antibiotic and pesticide/herbicide resistance Coevolution: When two or more species interact closely they can influence each other’s evolutionary direction. In tightly coevolved interactions, evolutionary change in one species will lead to evolutionary change in other or the second species may go extinct. Red Queen Hypothesis Lewis Carroll's Through the Looking Glass: “in this place it takes all the running you can do, to keep in the same place." Example: host / parasite coevolution Abiotic – Non-living factors Biotic – living portion of the environment What are some biotic factors that contribute to this differential survival and reproduction? Interactions among organisms 1. Predation 2. Competition 3. Parasitism 4. Commensalism 5. Mutualism Interactions among organisms 1. Predation One animal consumes another (positive for consumer, negative for prey) Types of predators Active predators: chase & overpower prey Sit-and-wait predators: motionless until prey close enough to strike Sit-and-wait predator Antlion HOW DO VULNERABLE ORGANISMS PROTECT THEMSELVES? The bombardier beetle The best defense is a good offense - chemical warfare A monarch caterpillar Many prey items have traits that reduce predation Cryptic Coloration: blend in with environment A moth Florida treehopper insects The leafy sea dragon A desert plant Cryptic Coloration a.k.a. camouflage The sand dab Nightjar bird Living stone plants Warning or aposematic coloration The South American poison arrow frog Many prey items have traits that reduce predation Warning Coloration: aposematic coloration conspicuous to convey threat Startle coloration the false-eyed frog The peacock moth caterpillar larva of the swallowtail butterfly ADAPTIVE COLORATION AND MIMICRY Types of Mimicry • 1. Batesian mimicry: mimic species resemble an unplatable or venomous species (the model) • 2. Mullerian mimicry: all mimic species have similar warning coloration. All mimics are usually toxic or harmful and function as both model and mimic. Batesian Mimicry: defenseless species (mimic) is protected from predation by its resemblance to a species that is dangerous (the model); Henry Walter Bates was an English biologist who described a type of mimicry in tropical butterflies in the 1850's. fly (bee mimic) bumble bee coral snake monarch butterfly mountain king snake viceroy Naïve Blue Jay and a Monarch Butterfly Batesian Mimicry in Plants: Stinging Nettle (model) and the Yellow Archangel (the mimic) Visual and behavioral mimicry the snowberry fly a jumping spider Mullerian Mimicry: Two or more distasteful or harmful organisms resemble each other; each serve as model and mimic. Fritz Muller was a German zoologist who described a different type of mimicry in 1878. Interactions among organisms 1. Predation Predator benefits (+) from food Prey is harmed (-) by being eaten Predation is a (+ / - ) relationship Interactions among organisms 2. Competition Competition: organisms compete for the same limited resource Ex. light, food, mates, habitat, etc. Competition is a (- / - ) relationship Intraspecific competition — Members of same species competing for resources Beetle vs. Beetle Fungus vs. Fungus Interspecific competition: Members of different species competing for resources May lead to competitive exclusion Interactions among organisms 3. Parasitism One organism (parasite) living in or on another organism (host), from which it derives nourishment Ex. Tapeworm Parasitism is a (+ / - ) relationship 3. Parasitism (+,-) Ectoparasites—Live on host’s surface (e.g., Fleas, lice, some molds) 3. Parasitism (+,-) Endoparasites—Live inside host. (e.g., worms, protozoa, bacteria, fungi) Ex. Heartworm Parasitoid Nest Parasitism Adult cowbirds don’t build nests Cowbird Common Yellow-throat Vectors: animals that carry parasite from one host to another Examples: Malaria, Lyme Disease, West Nile Virus, Bubonic Plague Malaria carrying mosquito Interactions among organisms 4. Commensalism —One organism benefits, while the other is unaffected. Remora and shark Commensalism is a ( + / 0 ) relationship 4. Commensalism (+,-) Interactions among organisms 5. Mutualism - Both species benefit. Acacia and ants *Tree provides sugar solution that the ants eats *Ants defends tree against grazers 5. Mutualism (+,+) Summary of 5 major Interactions Individual 1 + Individual 2 - Competition - - Parasitism + - Commensalism + Neutral Mutualism + Predation + How have people change these interactions? 1) Introduced species 2) Habitat destruction Introduction of novel predators and parasites can devastate natural communities. Over 2,000 species of birds have gone extinct on islands as a result of habitat loss and the introduction of predators and parasites. Hawaii: Habitat loss, malaria, rats and mongoose Points to know: 1. Know what evolution is and how is operates. Understand coevolution. 2. Know the 5 main types of species interactions. 3. Understand who benefits from each type of interaction (one or both participants) 4. Understand how humans may influence these interactions. On-Line Sources of Information used to create this presentation • http://www.uta.edu/biology/alie/1282/Lecture2.pp t#260,6,SUMMARY OF EVOLUTION • http://www.life.uiuc.edu/ib/105/lectures/06_EcolI nter.ppt#429,1,Slide