1 / 28

SYSTEMATICS/ TAXONOMY

SYSTEMATICS/ TAXONOMY. CHAPTER 13 BIOL 1120. SPECIES. MACROEVOLUTION—large, complex changes in life Changes accumulate in populations slowly over time TIME!!!!! Evolution—produced diversity of life Organisms grouped into species—distinct types of organisms

jaunie
Télécharger la présentation

SYSTEMATICS/ TAXONOMY

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. SYSTEMATICS/TAXONOMY CHAPTER 13 BIOL 1120

  2. SPECIES • MACROEVOLUTION—large, complex changes in life • Changes accumulate in populations slowly over time • TIME!!!!! • Evolution—produced diversity of life • Organisms grouped into species—distinct types of organisms • The meaning of the term “species” has evolved over time

  3. Linnaeus (1707-1778) • Species—all examples of creatures that were alike in minute detail of body structure • Two-word naming—binomial nomenclature • First name—genus • Second name—species • Hierarchical system for classification: grouped similar genera into orders, classes, kingdoms • His system did not consider evolutionary relationships (each species was created separately and could not change)---meaning species could not appear/disappear, not related to one another

  4. Darwin (1809-1882) • Connected species diversity to evolution • As natural selection became accepted, scientists no longer viewed classification as a way to just organize life • Classification became thought of as hypotheses about the evolutionary history of life

  5. Ernest Mayr (1940s) • Amended Linneaus’s and Darwin’s work by considering reproduction and genetics. • Biological species—a population, or group of populations, whose members can interbreed and produce fertile offspring • Speciation (formation new species) occurs when members of a population can no longer successful interbreed

  6. Speciation

  7. Mayr • Species—does not rely on physical appearance (less subjective than Linnaeus’s observations) • Linneaus-2 similar looking butterflies cannot belong to different species • Mayr—if two groups can produce fertile offspring, share a gene pool, same species

  8. Species--Conflicts • Mayr’s concept of species—cannot relate to asexual reproducers • Cannot apply to extinct organisms (fossil) • Some organisms can interbreed in captivity, but do not in nature • Reproductive isolation is not absolute—closely related plants can produce fertile offspring together • Species concept cannot always be used to decide if organisms are the same/different species • DNA analysis is helpful (if >97% identical, same species) • DNA drawback—cannot determine if organisms currently share a gene pool • ISOLATION is mot common criterion used to define species

  9. Reproductive Barriers/Speciation • Interruption in courtship, fertilization, embryo formation, or offspring development. • 2 broad groups: prezygotic and prostzygotic • Prezygotic occur before formation of zygote • Postzygotic: reduce the fitness of a hybrid offspring (offspring from two different species)

  10. Prezygotic BarriersAffect the ability of two species to combine gametes and form a zygote • Barriers include: • Ecological (habitat) isolation: difference in habitat preference in same geographic area • Temporal isolation: Mating will not occur if two species are active at different times of day or reach reproductive maturity at different times of year • Behavioral isolation: behavioral differences (distinct calls of different species of tree frogs to attract mates • Mechanical isolation: any change in the shape of gamete delivering or receiving structures can prevent interbreeding • Gametic isolation: sperm cannot fertilize egg; aquatic organisms release sperm, gametes have distinct surface molecules to recognize gametes

  11. Postzygotic Barriers (hybrid incompatibility) • Barriers include: • Hybrid inviability: hybrid embryo dies before reaching reproductive maturity; genes of parents incompatible • Hybrid infertility (sterility): mule; infertile because horse egg has 1> chromosome than donkey, meiosis does not occur because chromosomes are not homologous • Hybrid breakdown: a hybrid that can reproduce, but their offspring may have abnormalities that reduce their fitness Successful hybridization rare in animals; occurs frequently in plants

  12. Allopatric Speciation Speciation/Spatial Patterns • allo-other; patric-fatherland • Geographic barrier • River, desert, glacier, changes in sea level, formation or destruction of mountains, bodies of water • No interaction=no gene flow • Microevol. act independently in each group • Most common mechanism; abundant evidence

  13. Sympatric Speciation Speciation/Spatial Patterns • Sym-together • Populations diverge genetically while living in the same area • Habitats-consist of microenvironments; species specialize in different zones • Plants: polyploidy, increases the # of sets of chromosomes • Occurs when gametes of 2 diff species fuse; also when meiosis fails • ½ flowering plants are polyploids; 95% ferns • Rare in animals (extra chromosomes are often fatal)

  14. ParapatricSpeciation Speciation/Spatial Patterns • Para-alongside • Part of a population enters a new habitat bordering range of parent species • Gene flow can occur among individuals that venture into shared border zone • Can be a result of disruptive selection: ind. w/ intermediate forms have lower fitness than at either extreme; selection would counteract gene flow by eliminating ind. not well suited for either habitat

  15. Darwin One species gradually transforms into another through a series of intermediate stages TIME!!! Speciation-Gradualism

  16. Gould and Eldredge Brief bursts of rapid evolution interrupting long period of little change (transitional forms don’t exist—explains lack in fossil record) Fits w/allopatric speciation – geographic isolation Speciation—Punctuated equilibrium

  17. Speciation and Adaptive Radiation • Occurs in rapid bursts • Gives rise to multiple specialized forms in a short time • Heterogeneous environment (multiple food sources)

  18. Extinction • Death of an entire species • Factors: • Failure to adapt to environmental change • Lack of alleles in gene pool to produce fertile offspring • Habitat loss • Predators • Disease • Smaller populations likely to endure a major change • Low genetic diversity • Inbreeding (lethal recessive alleles, reduce reproduction/survivabilty) • HUMANS!!!!

  19. Extinction • Background extinction rate • Gradual loss of species as populations shrink when facing new challenges • Mass extinction • A great number of species disappear over short period of time (impact theory)

  20. Taxonomic Hierarchy • Taxonomists—classify based on similarities • 3 Domains (Archaea, Bacteria, Eukarya) • Kingdom King • Phylum Phillip • Class Called • Order On • Family Five • Genus Great • Species Soldiers • Taxa: a group at any rank • The more features two organisms share, the more taxonomic levels they share

  21. Phylogenetics • Evolutionary tree (also called phylogeny) • Illustrate specie’s relationships based on decent from common ancestors • Evidence used to construct: • Anatomical features of fossils and existing organisms • Behaviors • Physiological adaptations • Molecular sequences • May be misleading • Cladistics solves this problem

  22. Cladistics • Phylogenetic system • Groups by distinguishing between ancestral and derived characters • Ancestral character: inherited traits that resemble ancestors • Derived character: features that are different that the ancestor

  23. Cladistics • Builds on concept of homology (homologous structures-common ancestor) • Shared, derived characters are used to define groups • A clade (monophyletic group) group of organisms consisting of a common ancestor and all its descendants

  24. Cladogram • Treelike diagram depicting shared, derived characteristics (based on historical relationships/ not similarities) • Tips of branches = taxa (existing species) • node = indicates where two groups arose from a common ancestor • Branching pattern = populations that diverge genetically, split off, form new species Common ancestor Common ancestor

More Related