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Option D: Evolution D2: Species and Speciation

This text discusses the concepts of allele frequency and gene pool in evolution, the definition of species, and various barriers between gene pools such as geographic, ecological, temporal, behavioral, mechanical, and gametic isolation.

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Option D: Evolution D2: Species and Speciation

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  1. Option D: Evolution D2: Species and Speciation

  2. D 2.1Defineallele frequency and gene pool. • gene pool– • allele frequency–

  3. D 2.2Statethat evolution involves a change in allele frequency in a population’s gene pool over a number of generations. • Evolution of populations is best understood in terms of allele frequencies • If the allele frequencies remain constant from generation to generation, then the population is not undergoing any evolutionary change and is in • Evolution can be defined as (change in the genetic makeup of populations over time)

  4. D 2.3 Discuss the definition of the term species. • Biological species concept • defined by Ernst Mayr • population whose members can • reproductively compatible Distinct species:songs & behaviors are different enough to prevent interbreeding Diverse, but same species Eastern Meadowlark Western Meadowlark

  5. D 2.4 Describe three examples of barriers between gene pools. • Species are created by a series of evolutionary processes • populations become isolated – reduces gene flow • geographically isolated • reproductively isolated • isolated populations evolve independently • Gene flow = the migration of breeding individuals between populations causing a corresponding movement of alleles

  6. geographic isolation ecological isolation temporal isolation gametic isolation mechanical isolation behavioral isolation D 2.4 Describe three examples of barriers between gene pools. PRE-reproduction barriers - obstacle to mating or to fertilization if mating occurs

  7. D 2.4 Describe three examples of barriers between gene pools. Geographic isolation • Species occur in different areas • . • allopatric speciation • “other country” Harris’s antelope squirrel inhabits the canyon’s south rim (L). Just a few miles away on the north rim (R) lives the closely related white-tailed antelope squirrel

  8. D 2.4 Describe three examples of barriers between gene pools. Ecological isolation • Species occur in same region, but • reproductively isolated 2 species of garter snake, Thamnophis, occur in same area, but one lives in water & other is terrestrial • lions & tigers could hybridize, but they live in different habitats: • lions in grasslands • tigers in rainforest

  9. D 2.4 Describe three examples of barriers between gene pools. Temporal isolation • Species that breed • reproductive isolation • sympatric speciation • “same country” Eastern spotted skunk (L) & western spotted skunk (R) overlap in range but eastern mates in late winter& western mates in late summer

  10. D 2.4 Describe three examples of barriers between gene pools. Behavioral isolation • Unique • identifies members of species • attract mates of same species  • courtship rituals, mating calls • reproductive isolation Blue footed boobies mate only after a courtship display unique to their species Video clip of courtship: http://www.youtube.com/watch?v=PLhOKC6ZDpI

  11. Recognizing your own species courtship songs of sympatricspecies of lacewings courtship display of Gray-Crowned Cranes, Kenya http://www.youtube.com/watch?v=luViM0V--EI&feature=related firefly courtship displays

  12. D 2.4 Describe three examples of barriers between gene pools. Mechanical isolation • Morphological (form & structure) differences can prevent successful mating • reproductive isolation Plants Even in closely related species of plants, the flowers often have distinct appearances that attract different pollinators. These 2 species of monkey flower differ greatly in shape & color, therefore cross-pollination does not happen.

  13. D 2.4 Describe three examples of barriers between gene pools. Mechanical isolation Animals • For many insects, male & female sex organs of closely related species do not fit together, preventing sperm transfer • lack of “fit” between sexual organs: hard to imagine for us… but a big issue for insects with different shaped genitals! I can’t even imagine!

  14. D 2.4 Describe three examples of barriers between gene pools. Gametic isolation • Sperm of one species may not be able • biochemical barrier so sperm cannot penetrate egg • receptor recognition: lock & key between egg & sperm • chemical incompatibility • sperm cannot survive in female reproductive tract Sea urchins release sperm & eggs into surrounding waters where they fuse & form zygotes. Gametes of different species— red & purple —are unable to fuse.

  15. D 2.4 Describe three examples of barriers between gene pools. POST-reproduction barriers • Prevent hybrid offspring from developing into a • reduced hybrid viability • reduced hybrid fertility • hybrid breakdown Horse + Zebra = Zebroid liger

  16. D 2.4 Describe three examples of barriers between gene pools. Reduced hybrid viability • Genes of different parent species may interact & impair the hybrid’s development Species of salamander genus, Ensatina, may interbreed, but most hybrids do not complete development & those that do are frail.

  17. D 2.4 Describe three examples of barriers between gene pools. Reduced hybrid fertility • Even if hybrids are vigorous, they may be sterile • chromosomes of parents may differ in number or structure & meiosis in hybrids may fail to produce normal gametes Mules are vigorous, but sterile Horses have 64 chromosomes (32 pairs) Donkeys have 62 chromosomes (31 pairs) Mules have 63 chromosomes!

  18. D 2.4 Describe three examples of barriers between gene pools. Hybrid breakdown • Hybrids may be fertile & viable in first generation, but when they mate offspring are feeble or sterile In strains of cultivated rice, hybrids are vigorous but plants in next generation are small & sterile. On path to separate species.

  19. D 2.5 Explain how polyploidy can contribute to speciation. • Changes in chromosome number may cause instantaneous speciation • polyploidy – • may occur when a fertilized egg duplicates its chromosomes but does not divide into two daughter cells – all subsequent divisions may be normal and all cells are now tetraploid

  20. D 2.5 Explain how polyploidy can contribute to speciation. • caused by nondisjunction – • most tetraploid plants are healthy and vigorous and can go through meiosis • gametes produced can only – • cannot fuse with • gametes from original • parents • occurs in plants because • plants can http://www.youtube.com/watch?v=SbrVw1jrZxE

  21. D 2.5 Explain how polyploidy can contribute to speciation. • Autopolyploids (auto= self) are polyploids with multiple chromosome sets derived from a single species • Autopolyploids form following fusion of 2n gametes

  22. D 2.5 Explain how polyploidy can contribute to speciation. • Autopolyploidy can be induced in plants using colchicine, a chemical extracted from the autumn crocus. • Autopolyploids with odd ploidys eg. triploid or • pentaploid have trouble reproducing sexually • That does not stop them from being good crops if they can be propagated asexually Outcrossing – two plants Selfing – self-fertilized Vegetative – asexual

  23. D 2.5 Explain how polyploidy can contribute to speciation. Allopolyploids (allo= different) come about when a sterile F1 hybrid For example, Triticale is the hybrid of wheat (Triticum turgidum) and rye (Secale cereale). It combines sought-after characteristics of the parents, but the initial hybrids were sterile until doubling of the number of chromosomes occurred For example, Triticale is the hybrid of wheat (Triticum turgidum) and rye (Secale cereale). It combines sought-after characteristics of the parents, but the initial hybrids were sterile until doubling of the number of chromosomes occurred = + Wheat Rye Triticale

  24. D 2.6 Compareallopatric and sympatric speciation. • Species are created by a series of evolutionary processes • populations become isolated • geographically isolated • reproductively isolated • isolated populations evolve independently • Isolation • Allopatric • geographic separation • Sympatric • still live in same area

  25. D 2.6 Compareallopatric and sympatric speciation. • Allopatric speciation – speciation that occurs when • Most • Population evolves as a result of natural selection and/or genetic drift

  26. D 2.6 Compareallopatric and sympatric speciation. • Often results from physical isolation due to the constant changing of the earth’s surface • Ex.: river shifting course, glaciers migrating, mountain ranges forming, land bridges forming, etc.

  27. D 2.6 Compareallopatric and sympatric speciation. • Also results from a type of genetic drift called founders effect: • Genetic drift is • Founders effect occurs when a

  28. Example of founders effect: The new population is genetically different than the parent population. Parent Population: red, yellow, black

  29. D 2.6 Compareallopatric and sympatric speciation. • Sympatric speciation - a new species develops • More common in • Usually results from: • Ecological isolation • Polyploidy

  30. D 2.7 Outline the process of adaptive radiation. Adaptive Radiation  When a species gives rise to many new species in a relatively short period of time  Typically occurs when populations of a

  31. D 2.7 Outline the process of adaptive radiation. Think Darwin’s finches (AGAIN!) They originated from a population of an ancestral species that flew or were blown to the Galapagos islands from mainland South America. They colonized the islands and (while geographically isolated) evolved via natural selection to have beaks that suited the types of food available on their islands. Their beaks are homologous structuresin that they have evolved from a common structure to have different functions. Warbler finch Cactus eater Tree finches Ground finches Insect eaters Seed eaters Bud eater

  32. D 2.7 Outline the process of adaptive radiation. Seedeaters Flowereaters Insecteaters Rapid speciation:new species filling new niches,because they inheritedsuccessful adaptations. Adaptive radiation

  33. D 2.7 Outline the process of adaptive radiation. Darwin’s finches • Differences in beaks • associated with eating different foods • survival & reproduction of beneficial adaptations to foods available on islands Warbler finch Cactus finch Woodpecker finch Sharp-beaked finch Small insectivorous tree finch Small ground finch Warbler finch Large insectivorous tree finch Cactus eater Mediumground finch Tree finches Ground finches Insect eaters Seed eaters Vegetarian tree finch Large ground finch Bud eater

  34. D 2.7 Outline the process of adaptive radiation. Darwin’s finches • Darwin’s conclusions • small populations of original South American finches landed on islands • variation in beaks enabled individuals to • over many generations, the populations of finches changed anatomically & behaviorally • accumulation of advantageous traits in population • emergence of

  35. D 2.8 Compare convergent and divergent evolution. Convergent evolution describes evolution towards . • Other (random!) examples include: • Penguins in the southern hemisphere and Auks in the northern hemisphere both use wings as flippers • Echolocation in bats, toothed whales and shrews to capture prey. • Flight/gliding in birds, pterosaurs, bats, insects and flying fish! Little Auk http://commons.wikimedia.org/wiki/File:AlleAlle_2.jpg Little Penguin http://commons.wikimedia.org/wiki/File:Little_penguin_Eudyptula_minor.jpg

  36. D 2.8 Compare convergent and divergent evolution. Features that come about by convergent evolution are known as

  37. D 2.8 Compare convergent and divergent evolution. Divergent evolution describes evolution towards . Divergent Evolution is another way of saying (D.2.7). As natural selection acts on two or more species that have arisen from a common ancestor, they become phenotypically different.

  38. D 2.8 Compare convergent and divergent evolution. It gives rise to , features that now look different or have a different purpose for each species that has evolved

  39. D 2.9 Discuss ideas on the pace of evolution, including gradualism and punctuated equilibrium. Gradualism • Gradual divergence over long spans of time • assume that big changes occur as the accumulation of many small ones

  40. D 2.9 Discuss ideas on the pace of evolution, including gradualism and punctuated equilibrium. Punctuated Equilibrium • Rate of speciation is not constant • . • long periods of little or no change • species undergo rapid change when they 1st bud from parent population Time

  41. D 2.9 Discuss ideas on the pace of evolution, including gradualism and punctuated equilibrium. Revisiting the tree for punctuated equilibrium it should be noted that the “sudden” speciation events are only sudden in terms of geological time. They would still take many generations and possibly thousands of years. The periods of stasis may be explained by stabilizing selection. The punctuation could be explained by directional selection or disruptive selection.

  42. D 2.9 Discuss ideas on the pace of evolution, including gradualism and punctuated equilibrium. The downward facing arrows indicate selection pressure against individuals with that morphology Before After All images CC Andrew Colvin

  43. Coevolution • Occurs when • Examples include predators and prey and organisms that live in symbiotic relationships (mutualism, commensalism, parasitism) • As one evolves a new feature or modifies an old one, the other typically evolves new adaptations in response Stinging ant & the acacia plant Ant stings insects that try to eat the plant, plant provides food in the form of nectar & shelter in the form of thorns

  44. D 2.10 Describe one example of transient polymorphism. • Polymorphism is the (Poly = “many”; morphism = “shapes”) • Transient Polymorphism is • ex: peppered moth melanism Prior to 1840 peppered moths in Britain were light grey with dark spots to blend in with the grey lichen that grew on the trees in their habitat

  45. D 2.10 Describe one example of transient polymorphism. The first dark variant was reported in 1848 and by 1895 most of them were black. The term industrial melanism was coined. Soot and acid rain from the burning of coal changed the color of the trees that the moths rested on. Directional selection did the rest. • Draw a graph of what that might look like. http://www.flickr.com/photos/naturalhistoryman/817332984/

  46. D 2.10 Describe one example of transient polymorphism. Before long the majority were dark. This situation reversed after 1956 when Britain instituted the clean air act. Less coal was burnt and most trees returned to their original colour. Now in polluted areas most moths are dark and in rural areas most moths are light. They are not distinct species because they still interbreed. The theory that natural selection due to predation was the cause of these changes has been confirmed experimentally by Dr HBD Kettlewell

  47. D 2.11 Describe sickle cell anemia as an example of balanced polymorphism. Balanced Polymorphism •Two alleles are maintained in stable equilibrium •Heterozygote has Sickle cell anaemia occurs when a single-base mutation in the gene that codes for haemoglobin causes the amino acid valine to be produced in a particular spot rather than glutamic acid.

  48. D 2.11 Describe sickle cell anemia as an example of balanced polymorphism. Valine is non-polar, unlike glutamic acid, and this causes the mutant variety of haemoglobin (haemoglobin S) to crystallise at low concentrations of oxygen. This in turn pulls the red blood cell into a sickle shape. It is less able to carry oxygen and can get stuck in small capillaries, causing blockages, pain and damage. Homozygous individuals (HbS HbS) are subject to a debilitating condition and have a shortened life expectancy

  49. D 2.11 Describe sickle cell anemia as an example of balanced polymorphism. On the brighter side, while individuals who are heterozygous (HbA HbS) will have some mutant haemoglobin. They can lead normal lives. As a benefit, they are resistant to malaria as the plasmodium parasite that causes it is not able to use sickle cells to reproduce. Individuals that are homozygous normal (HbA HbA) have no sickle cells and no resistance to malaria. http://www.pbs.org/wgbh/evolution/library/01/2/l_012_02.html Historical distribution of malaria Distribution of the sickle cell trait

  50. HbA HbA Haemoglobin: Normal RBCs: Normal O2 Capacity: Normal Malaria resistance: None Heterozygous: Sickle cell trait Heterozygous: Sickle cell trait HbA HbS Haemoglobin: 50% normal, 50% mutant RBCs: Usually normal, sickle when [O2] low O2 Capacity: Mild anaemia Malaria resistance: Moderate A S A S A A S A A S S S HbS HbS Haemoglobin: mutant RBCs: Sickle O2 Capacity: Severe anaemia Malaria Resistance: High Homozygous: ‘Normal’ 25% chance Heterozygous: Sickle cell trait 50% chance Homozygous: Sickle Anaemia 25% chance http://en.wikipedia.org/wiki/File:Autorecessive.svg

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