2. 5
C H A P T E R
EVOLUTION AND GENETICS
5-2

3. EVOLUTION AND GENETICS
Biochemical, or Molecular, Genetics
Population Genetics and Mechanisms of Genetic Evolution
The Modern Synthesis 3

4. EVOLUTION AND GENETICS
What is evolution, and how does it occur?
How does heredity work, and how is it studied?
What forces contribute to genetic evolution?

5. EVOLUTION
Humans have uniquely varied ways—cultural and biological—of adapting to environmental stresses
Many scholars became interested in biological diversity and our position within the classification of plants and animals during the 18th century

6. EVOLUTION
Creationism: biological similarities and differences originated at the Creation
Linnaeus (1707–1778) developed the first comprehensive and still influential classification, or taxonomy, of plants and animals
Fossil discoveries during the 18th and 19th centuries raised doubts about creationism

7. EVOLUTION
Catastrophism: modified version of creationism that accounts for the fossil record by positing divinely authored worldwide disasters that wiped out creatures represented in the fossil record

8. THEORY AND FACT
Evolution: transformation of species; descent with modification
Alternative to creationism and catastrophism
Darwin best known of evolutionists

9. THEORY AND FACT Darwin influenced by:
Grandfather, Erasmus Darwin, who proclaimed a common ancestry of all animal species
Lyell’s principle of uniformitarianism: the present is the key to the past
Theory of evolution

10. THEORY AND FACT
Natural selection: the process by which nature selects the forms most suited to survive and reproduce in a given environment
Competition for strategic resources
Variety within that population
Natural selection continues today

11. GENETICS Genetic science helps explain causes of biological variation
Mendelian genetics: ways in which chromosomes transmit genes across generations
Biochemical genetics: examines structure, function, and changes in DNA
Population genetics: investigates natural selection and the causes of genetic variation, stability, and change

12. MENDEL’S EXPERIMENTS
Austrian monk Gregor Mendel began series of experiments that revealed basic principle of genetics in 1856
Studied inheritance of seven contrasting traits in pea plants
Heredity is determined by discrete particles or units

13. MENDEL’S EXPERIMENTS
Concluded that a dominant form could mask another form in hybrid individuals, without destroying the recessive trait
Basic genetic units Mendel described were factors (now called genes or alleles) located on chromosomes

14. MENDEL’S EXPERIMENTS
Chromosome: a paired length of DNA, composed of multiple genes
Gene: a place (locus) on a chromosome that determines a particular trait
Allele: a variant to a particular gene

15. MENDEL’S EXPERIMENTS
Heterozygous: dissimilar alleles of a gene in an offspring
Homozygous: two identical alleles of a gene in an offspring
Genotype: organism’s hereditary makeup
Phenotype: evident biological traits
Dominance produces a distinction between genotype and phenotype

16. INDEPENDENT ASSORTMENT AND RECOMBINATION
Independent assortment: chromosomes are inherited independently of one another
Recombination: new types in an offspring on which natural selection can operate

17. Figure 5.1: Mendel’s Second Set of Experiments with Pea Plants17

18. Figure 5.2: Simplified Representation of a Normal Chromosome Pair18

19. Figure 5.3: Punnett Squares of a Homozygous Cross and a Heterozygous Cross19

20. Figure 5.4: Determinants of Phenotypes (Blood Groups) in the ABO System20

21. BIOCHEMICAL OR MOLECULAR GENETICS
Mutation: changes in the DNA molecules of which genes and chromosomes are built
Gametes: sex cells that make new generations
BIOCHEMICAL OR MOLECULAR GENETICS

22. BIOCHEMICAL, OR MOLECULAR, GENETICS
DNA molecule is a double helix
RNA carries DNA’s message to cytoplasm (outer area)
Structure of RNA, with paired bases, matches DNA
DNA, with RNA’s assistance, initiates and guides the construction of proteins necessary for bodily growth, maintenance, and repair

23. Figure 5.5: DNA Replication23

24. CELL DIVISION
Mitosis: ordinary cell division; one cell splits to form two identical cells
Meiosis: process that produces sex cells
Four cells produced from one
Each cell carries half genetic material of original cell
Products of meiosis from one parent combine with those from the other parent
Chromosomes sort independently

25. CROSSING OVER
Crossing over: the process wherein homologous chromosomes exchange segments by breakage and recombination
Can occur with any chromosome pair
An important source of variety

26. Figure 5.6: Crossing Over 26

27. MUTATION
Base substitution mutation: substitution of one base in a triplet by another
If mutation occurs in sex cell, new organism will carry mutation in every cell
Chromosomal rearrangement: pieces of a chromosome break off and reattach someplace else on that chromosome

28. MUTATION Approximately three mutations will occur in every sex cell
Most mutations are neutral
Evolution depends on mutations
Mutations are major source of genetically transmitted variety

29. POPULATION GENETICS AND MECHANISMS OF GENETIC EVOLUTION
Population genetics studies stable and changing populations
Gene pool: alleles and genotypes within breeding population
Genetic evolution: change in allele frequency in a breeding population

30. NATURAL SELECTION Genotype: the genetic makeup of an organism
Phenotype: organism’s biological traits
Natural selection acts only on phenotypes
Human biology has considerable plasticity
The environment works on a genotype to build a phenotype

31. DIRECTIONAL SELECTION
After several generations of selection, gene frequencies change
Adaptive: favored by natural selection
Directional selection continues as long as environmental sources stay the same
Selection operates only on traits that are present in a population
Humans adapt rapidly by modifying biological responses and learned behavior

32. SEXUAL SELECTION Selection also operates through competition for mates
Sexual selection: based on differential success in mating; a selection of traits that enhances mating success

33. STABILIZING SELECTION
Balanced polymorphism: frequencies of two or more alleles of a gene remain constant from generation to generation

34. Figure 5.7:Distribution of Sickle-Cell Allele and Falciparum Malaria in the Old World34

35. APPRECIATING ANTHROPOLOGY
Scientists linked the first European explorers of the New World to the origin of sexually transmitted syphilis
Researchers examined 26 geographically disparate strains in the family of Treponema bacteria
Infections in the New World have been traced back at least 7,000 years by studying scars on bones

36. RANDOM GENETIC DRIFT
Random genetic drift: change in allele frequency that results from chance
Lost alleles can reappear in gene pool only through mutation
Fixation—the replacement, for example, of blue eyes by brown eyes—is more rapid in small populations

37. GENE FLOW
Gene flow: exchange of genetic material between populations of the same species
Alleles spread through gene flow even when selection not operating on the allele
Species: group of related organisms whose members can interbreed to produce offspring that live and reproduce
Gene flow tends to prevent speciation: the formation of new species

38. Figure 5.8: Gene Flow between Local Populations38

39. THE MODERN SYNTHESIS Currently accepted view of evolution:
Microevolution: small-scale changes in allele frequencies over just a few generations
Macroevolution: large-scale changes in allele frequencies in a population over a longer time period

40. PUNCTUATED EQUILIBRIUM
Punctuated equilibrium: long periods of stasis may be interrupted by evolutionary leaps
Sudden environmental change offers possibility for the pace of evolutions to speed up
Species can survive radical environmental shifts, but extinction is more common