Evolution - PowerPoint PPT Presentation

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Evolution

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Evolution Changes in types of organisms over a period of time Fossils A fossil is some remnant of an organism that proves its existence Imprints of bacteria, leaves ... – PowerPoint PPT presentation

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Title: Evolution


1
Evolution
  • Changes in types of organisms over a period of
    time

2
Fossils
  • A fossil is some remnant of an organism that
    proves its existence
  • Imprints of bacteria, leaves or footprints
  • Insects, pollen, or flower parts in amber
  • Tools or pottery shards
  • Bones of organisms in sedimentary rock
  • Cave drawings

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Determining fossil age
  • Relative dating
  • Oldest fossils are in the deepest sedimentary
    rock layers
  • Younger layers hold newer, more complex fossils

6
  • Absolute dating
  • Can be used to determine a precise age in years
  • Use the decay rate of radio-isotopes like carbon
    14
  • The oldest known fossils are approximately 3
    billion years old

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Comparative studies
  • Researchers use comparative studies to establish
    evolutionary relationships between organisms

9
Comparative anatomy
  • Comparing specific body structures
  • Analogous structures have a similar function but
    the structure is different
  • Ex the wing of an insect and the wing of a bird

10
  • Homologous structures are similar in structure
    but may have different functions
  • Ex) human hand, cat paw, whale flipper, bat wing

11
  • Vestigial structures are reduced in size and have
    no known function
  • They resemble structures in other organisms
  • Ex) the human appendix or the pelvis bone in a
    whale

12
Comparative embryology
  • The comparison of embryonic development
  • Early development is similar in many species
  • The closer the relationship between species the
    more similar is development

13
Comparative cytology
  • Observing similarities in cell structures
  • All cells have some common organelles that
    perform identical functions
  • Plasma membrane, cytoplasm, and ribosomes

14
Comparative Biochemistry
  • Similarities involving proteins, enzymes and
    nucleic acids
  • All organisms share genetic codes
  • Transcription and translation
  • All organisms carry on cell respiration in the
    same way
  • All autotrophs carry on photosynthesis in the
    same way

15
Theories of Evolution
16
J.B. Lamarck
  • Use and disuse
  • Organisms can change their body structure over
    the course of a lifetime
  • ATROPHY structure decreases in mass with disuse
  • HYPERTROPHY structure increases in mass with
    use

17
  • Lamarck believed that ACQUIRED TRAITS could then
    be passed to the offspring
  • Example) the neck of the giraffe

18
August Weissman
  • Disproved Lamarcks theory of use and disuse
  • He cut off the tails of mice then mated them
  • All of the offspring had long tails
  • This experiment was repeated for 22 generations
  • All of the mice were born with long tails!

19
Charles Darwin
  • Theory of Natural Selection
  • Darwin served as a geologist, botanist,
    zoologist, and general man of science aboard the
    H.M.S. Beagle from 1831-1836

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  • Overproduction organisms produce more offspring
    than can possibly survive
  • Struggle for existence there are only limited
    resources available
  • Not all offspring will survive
  • Natural selection those organisms with
    advantages in a given environment are most likely
    to survive and reproduce
  • Those who survive and reproduce are the FITTEST

24
  • Variation offspring tend to be different from
    their parents and each other
  • Speciation after many generations are involved
    in natural selection
  • A population may be so different from the
    original population that it can be classified as
    a different species
  • SPECIES organisms who can mate and produce
    fertile offspring

25
Speciation
  • Involves isolation
  • Anything which prevents two groups within a
    species from interbreeding

26
Geographic isolation
  • A population is divided by a natural barrier
  • mountains
  • Deserts
  • Body of water
  • Landslide cause by an earthquake
  • Geographic isolation can instigate a speciation
    eventbut genetic changes are necessary to
    complete the process

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Reproductive isolation
  • Differing selection pressures on the new
    environments can complete the differentiation of
    the new species.

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  • the differences between the isolated groups
    become so great that they can no longer interbreed

31
Microevolution
  • Small, gradual changes which are detectable
    within a few generations

32
  • Industrial Melanism changes in the colors of a
    population as a result of human industrial
    activity

33
Macroevolution
  • Long term changes that make a new species

34
General patterns for evolution
  • Divergent evolution different groups evolve
    from one ancestor

35
  • Convergent evolution two or more different
    groups evolve so that they resemble one another
    strongly

36
  • Adaptive radiation organisms spread into new
    environments and become adapted through natural
    selection

37
Adaptations
  • an anatomical structure, physiological process or
    behavioral trait of an organism that has evolved
    over a period of time by the process of natural
    selection
  • it increases the expected long-term reproductive
    success of the organism

38
  • Organisms that are adapted to their environment
    are able to
  • obtain air, water, food and nutrients
  • cope with physical conditions such as
    temperature, light and heat
  • defend themselves from their natural enemies
  • reproduce
  • respond to changes around them

39
  • Camouflage and mimicry are adaptations some
    animals use as protection from predators.
  • An animal that uses camouflage looks like things
    in its environment. It might look like a leaf, a
    twig, or a rock.

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http//oncampus.richmond.edu/academics/education/p
rojects/webunits/adaptations/mimicry.html
  • Animals that use mimicry use colors and markings
    to look like another animal.
  • Example) the Monarch Butterfly and the Viceroy

43
Symbiosis
  • Two species live in close association with each
    other
  • In symbiosis, at least one member of the pair
    benefits from the relationship. The other member
    may be
  • injured parasitism
  • relatively unaffected commensalism
  • may also benefit mutualism

44
  • Mutualism () ()
  • Both organisms benefit

45
  • Moray eel and cleaner fish
  • The eel gets clean
  • The fish gets food
  • Both organisms benefit

46
  • Parasitism () (-)
  • the parasite benefits while the host is harmed

47
  • (1) The hookworm latches on the walls of the
    colon with its sharp teeth where it feeds on
    blood.
  • (2) The tapeworm is the longest parasite. A
    mature adult can lay a million eggs a day.
  • (3) Tapeworm eggs embedded in the colon.
  • (4) The roundworm can grow to be 20 inches (50
    cm) long and lay 200,000 eggs per day.
  • (5) Pinworms migrate outside the colon during the
    night to lay their eggs around the anus. This
    causes the nightly itching of many unsuspecting
    victims.

48
  • Commensalism () (0)
  • One organism benefits while the other is neither
    helped or harmed

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Heterotroph Hypothesis
  • 1920-30s
  • Formulated by a small group of scientists
  • Suggests a probable sequence in which organisms
    appeared

51
  • Life on Earth began about 3.5 billion years ago.
  • The atmosphere was very different from what it is
    today.
  • The early Earth atmosphere contained mostly
    hydrogen, water, ammonia, and methane.
  • There was very little oxygen

52
  • There were abundant energy sources for chemical
    reactions to occur
  • Heat
  • UV radiation
  • Electrical activity

53
Primordial soup
54
  • Gases in the atmosphere reacted with each other
    to form simple organic molecules
  • Example ) Amino acids, nucleotides

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Atoms combined to form molecules
57
Amino acids were formed
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Stanley Miller
  • Miller built an apparatus to test these ideas in
    1953
  • A mixture of gases thought to resemble the
    Earths primitive atmosphere was passed through
    an electric spark

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  • After one week the contents were analyzed
  • Miller found that it contained organic molecules
  • Urea
  • Amino acids
  • Lactic acid
  • Acetic acid

61
  • The Heterotroph Hypothesis SUGGESTS
  • The first organisms were anaerobic
  • No O2 was available in Earths primitive
    atmosphere

62
  • The first organisms used the organic molecules in
    the water for food
  • They released CO2 as a waste product
  • These organisms were ANAEROBIC HETEROTROPHS

63
  • Organisms that were able to use the CO2 evolved
    next
  • These organisms were ANAEROBIC AUTOTROPHS
  • They used the CO2 for photosynthesis
  • O2 was released as a waste product

64
  • Organisms that were able to use O2 evolved next
  • These were AEROBIC AUTOTROPHS and AEROBIC
    HETEROTROPHS

65
Rate of Evolution
  • Gradualism evolution occurs slowly and
    continuously over time

66
  • Punctuated equilibrium evolution can occur
    quickly
  • It can be followed by long periods of little or
    no change at all

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Population Genetics
  • The study of the genes in an entire population at
    one time
  • Population all of the members of one species in
    a specific area
  • Gene pool all of the alleles within a
    population
  • Gene frequency the of all alleles for one
    trait that are dominant or recessive

69
  • The Hardy-Weinberg Law based on genetic
    equilibrium
  • The condition where gene frequencies do not
    change from one generation to the next

70
  • The Hardy Weinberg Equation
  • p q 1
  • Where p dominant allele
  • q recessive allele
  • p2 2pq q2 1
  • Where p2 homozygous dominant
  • 2pq heterozygous
  • q2 homozygous recessive

71
  • Example
  • 30 of a population of banana-nose hoseringers
    show the recessive phenotype of yellow
    banana-nose as opposed to the dominant phenotype
    of green banana-nose

72
  • p q 1
  • Where p dominant allele
  • q recessive allele
  • 30 show the recessive phenotype

p .3 1 p .7
73
  • What of the banana-nose hoseringers are
    heterozygous for nose color?
  • p2 2pq q2 1

74
  • (.7)2 2 (.7)(.3) (.3)2 1
  • .49 .42 .09 1
  • 42 are heterozygous

75
  • For the Hardy-Weinberg law to be true five
    conditions must be met

76
  • 1) Large Populations
  • In small populations alleles of low frequency
    might be lost by the death of a few individuals

77
  • 2) No Migration
  • Individuals may not migrate into or out of the
    population

78
  • 3) No Mutations
  • These will change the frequency of the alleles in
    the population

79
  • 4) No Natural Selection
  • Each member of the population must survive long
    enough to have offspring

80
  • 5) Random Mating
  • Each member of the population must have an equal
    chance to reproduce

81
  • The Hardy-Weinberg law does NOT apply to
    situations in the real world!

82
  • Mutations occur spontaneously
  • Reproduction is NOT random
  • Natural selection DOES occur

83
  • The failure of Hardy-Weinberg Law is a sign that
    evolution is occurring!
  • There are changes in allele frequencies
  • External factors cause the changes in frequency
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