1. Chapter 3 HEREDITARY INFLUENCES ON DEVELOPMENT

2. PRINCIPLES OF HEREDITARY TRANSMISSION
Development begins at conception
Sperm cell penetrates ovum
Zygote is formed
46 chromosomes (23 from each parent)
Genes, stretches of DNA
Provides biological basis for development

3. PRINCIPLES OF HEREDITARY TRANSMISSION
Growth of Zygote, Production of Body Cells
Zygote replicates through mitosis
Each division duplicates chromosomes
Each new cell contains the 46 we inherited at conception

4. Figure 3.1 Mitosis: the way that cells replicate themselves.

5. PRINCIPLES OF HEREDITARY TRANSMISSION
The Germ Cells (produce sperm and ova)
Production of Gametes through Meiosis
Duplication of 46 chromosomes
Crossing-over: adjacent chromosomes break and exchange segments of genes
Pairs of duplicated chromosomes segregate into 2 new cells
Cells divide, 23 single chromosomes

6. Figure 3.2 Diagram of the meiosis of a male germ cell.

7. PRINCIPLES OF HEREDITARY TRANSMISSION
The Germ Cells
Hereditary Uniqueness
Independent assortment – each chromosome pair segregates independently, resulting in genetic uniqueness

8. PRINCIPLES OF HEREDITARY TRANSMISSION
Multiple Births
Monozygotic twins: single zygote divides, are genetically identical
Dizygotic (fraternal) twins: 2 ova released and fertilized by different sperm, are as genetically similar as any sibling pair

9. Figure 3.3 Identical, or monozygotic, twins (left) develop from a single zygote. Because they have inherited identical sets of genes, they look alike, are the same sex, and share all other inherited characteristics. Fraternal, or dizygotic, twins (right) have no more genes in common than siblings born at different times. Consequently, they may not look alike (as we see in this photo) and may not even be the same sex.

10. PRINCIPLES OF HEREDITARY TRANSMISSION
Male or Female
Karyotypes – chromosomal portraits
22 pairs (autosomes) are similar in males and females
23rd pair are the sex chromosomes
Males – X and Y, Females – 2 X’s
Ova contain X’s, sperm an X or a Y
Males determine sex of children

11. Figure 3.4 These karoytypes of a male (left) and a female (right) have been arranged so that the chromosomes could be displayed in pairs. Note that the twenty-third pair of chromosomes for the male consists of one elongated X chromosome and a Y chromosome that is noticeably smaller, whereas the twenty-third pair for the female consists of two X chromosomes.

12. PRINCIPLES OF HEREDITARY TRANSMISSION
What Do Genes Do?
Produce enzymes and proteins necessary for creation and functioning of cells
Guide cell differentiation
Regulate the pace/timing of development
Environmental factors (internal and external) influence how genes function

13. Table 3.1 Different Levels of Gene-Environment Interaction That Influence Genetic Expression

14. PRINCIPLES OF HEREDITARY TRANSMISSION
How are Genes Expressed?
Single-Gene Inheritance Patterns
Simple Dominant-Recessive Inheritance
1 pair of genes (alleles), 1 from each parent
Either dominant or recessive
Homozygous – same alleles
Heterozygous – different alleles

15. Figure 3.5 Possible genotypes (and phenotypes) resulting from a mating of two heterozygotes for normal vision.

17. PRINCIPLES OF HEREDITARY TRANSMISSION
How are Genes Expressed?
Codominance
Phenotype is a compromise between the dominant and recessive alleles
Sex-Linked Inheritance
Genes located on sex chromosomes
Most from recessive genes found only on X chromosomes (common in males)

18. Figure 3.6 Normal (round) and “sickled” (elongated) red blood cells from a person with sickle-cell anemia.

19. Figure 3. 7 Sex-linked inheritance of red/green color blindness
Figure 3.7 Sex-linked inheritance of red/green color blindness. In the example here, the mother can distinguish reds from greens but is a carrier because one of her X chromosomes contains a color-blind allele. Notice that her sons have a 50 percent chance of inheriting the color-blind allele and being color-blind, whereas none of her daughters would display the trait. A girl can be color-blind only if her father is color blind and her mother is at least a carrier of the color-blind gene.

20. PRINCIPLES OF HEREDITARY TRANSMISSION
How are Genes Expressed?
Polygenic Inheritance
Characteristics influenced by many pairs of alleles
Most complex human attributes are polygenic

21. Figure 3.8 Single-gene and multiple gene distributions for traits with additive gene effects. (a) A single gene with two alleles yields three genotypes and three phenotypes. (b) Two genes, each with two alleles, yield nine genotypes and 5 phenotypes. (c) Three genes, each with two alleles, yield twenty-seven genotypes and seven phenotypes. (d) Normal bell-shaped curve of continuous variation.

22. HEREDITARY DISORDERS
Congenital defects – present at birth (5%)
Chromosomal Abnormalities – too many or too few
Sex Chromosome Abnormalities
Abnormalities of the Autosome
Down syndrome most common – trisomy-21 (extra 21st chromosome)

23. Figure 3.9 Sources of Congenital Defects

24. Table 3.2 Four Common Sex Chromosome Abnormalities

25. Table 3.2 Four Common Sex Chromosome Abnormalities (continued)

26. HEREDITARY DISORDERS
Genetic Abnormalities
Many passed to children by parents who are carriers of recessive alleles
Some are caused by dominant alleles
Some result from mutations – changes in structure of one or more genes
Spontaneous
Environmental hazards

27. Table 3.3 Brief Description of Major Recessive Hereditary Diseases

28. HEREDITARY DISORDERS
Predicting Hereditary Disorders
Genetic counseling – both chromosomal and genetic abnormalities
Obtain a pedigree – family history
DNA from parents’ blood
Consider options based on risk

29. HEREDITARY DISORDERS
Detecting Hereditary Disorders
Amniocentesis – withdrawal of a sample of amniotic fluid, tests fetal cells within fluid
Risk of miscarriage higher than risk of birth defect in women younger than 35
Conducted 11th/14th week of pregnancy
Results 2 to 3 weeks later

30. Figure 3.11 In amniocentesis, a needle is inserted through the abdominal wall into the uterus. Fluid is withdrawn and fetal cells are cultured, a process that takes about 3 weeks.

31. HEREDITARY DISORDERS
Detecting Hereditary Disorders
Chorionic villus sampling – collects cells from chorion,
Conducted 8th/9th week of pregnancy
Results in 24 hours
Risk of miscarriage 1 in 50
Ultrasound – sound waves provide outline of fetus – useful after 14th week, safe

32. Figure 3.12 Chorionic villus sampling can be performed much earlier in pregnancy, and results are available within 24 hours. Two approaches to obtaining a sample of chorionic villi are shown here: inserting a thin tube through the vagina into the uterus or a needle through the abdominal wall. In either of these methods, ultrasound is used for guidance. ADAPTED FROM MOORE & PERSAUD, 1993.

33. Figure 3.13 Photo of 3-D ultrasound of fetus.

34. HEREDITARY DISORDERS
Treating Hereditary Disorders
Special diets for metabolic disorders
Fetal surgery, hormone therapy
Gene replacement therapy – relieves symptoms, doesn’t cure disorder
Germline gene therapy – replace harmful genes early in embryonic stage to cure defect; not yet used in humans

35. HEREDITARY INFLUENCES ON BEHAVIOR
Behavioral genetics - study of how genes and environment influence behavior
Methods of studying hereditary influences
Selective breeding – animal studies
Family studies – examining kinship
Twin studies – identical vs. fraternal
Adoption studies – children similar to biological or adoptive parents?

36. HEREDITARY INFLUENCES ON BEHAVIOR
Contribution of Genes and Environment
Concordance rates - % of pairs of people who both display a trait if one member has it
Gene Influences
Heritability coefficient = (r identical – r fraternal) X 2

37. Figure 3.15 Concordance rates for identical and fraternal twins for several behavioral dimensions. FROM PLOMIN ET. AL, 1994.

38. Figure 3.16 Concordance rates for identical and fraternal twins for several behavioral dimensions. FROM PLOMIN ET AL., 1994.

39. Table 3.4 Average Correlation Coefficients for Intelligence-Test Scores from Family Studies Involving Persons at Four Levels of Kinship

40. HEREDITARY INFLUENCES ON BEHAVIOR
Contribution of Genes and Environment
Nonshared Environmental Influences
= 1-r(identical twins reared together)
Shared Environmental Influences
= 1 – (H + NSE)

41. HEREDITARY INFLUENCES ON BEHAVIOR
Myths about Heritability Estimates
Cannot tell us if we have inherited a trait
Differences among individuals due to differences in inherited genes
Only apply to populations under particular environmental circumstances
Clearly heritable traits CAN be modified by environmental influences

42. HEREDITARY INFLUENCES ON BEHAVIOR
Hereditary Influences on Intellectual Performance
As children age
Genes contribute more
Nonshared environment increases
Shared environment decreases

43. Figure 3.17 Changes in the correlation between the IQ scores of identical and fraternal twins over childhood. DATA FROM WILSON, 1983.

44. HEREDITARY INFLUENCES ON BEHAVIOR
Hereditary Contributions to Personality
Introversion/extraversion and empathetic concern are both genetically influenced
Moderate heritability (+.40)
Nonshared environmental influences are also important
Shared environmental influences are relevant for religious & social values

45. Table 3.5 Personality Resemblances among Family Members at Three Levels of Kinship

46. HEREDITARY INFLUENCES ON BEHAVIOR
Hereditary Contributions to Behavior Disorders and Mental Illness
Schizophrenia, alcoholism, criminality, depression, hyperactivity, bipolar disorder, neurotic disorders – all genetically influenced
Inherit a predisposition, not the disorder

47. THEORIES OF HEREDITARY AND ENVIRONMENTAL INTERACTIONS
The Canalization Principle
Multiple pathways individuals may develop
Nature and nurture combine to determine pathway
Either genes or environment may limit the extent the other can influence development

48. THEORIES OF HEREDITARY AND ENVIRONMENTAL INTERACTIONS
The Range-of-Reaction Principle
Genotype sets a range of possible outcomes
Environment largely influences where within the range an attribute will fall

49. Figure 3.18 Hypothetical reaction ranges for the intellectual performances of three children in restricted, average, and intellectually-enriching environments. ADAPTED FROM GOTTESMAN,

50. THEORIES OF HEREDITARY AND ENVIRONMENTAL INTERACTIONS
Genotype-Environment Correlations
Passive – home environment is influenced by parents genotypes
Evocative – genetically influenced attributes affects behavior of others toward the child
Active – environments children seek will be compatible with genetic predispositions

51. THEORIES OF HEREDITARY AND ENVIRONMENTAL INTERACTIONS
How Do Genotype-Environment Correlations Influence Development?
Passive – important when young
Evocative – remain important throughout development
Active – important as a child matures

52. Figure 3.19 Relative influence of passive, evocative, and active (niche-picking) genotype/environment correlations as a function of age.

53. CONTRIBUTIONS AND CRITICISMS OF THE BEHAVIORAL GENETICS APPROACH
Many attributes thought to be environmentally determined are influenced by genes
Genetics and environment intertwined
Criticisms
Describes rather than explains development