Human Genetics

Human Genetics Concepts and Applications Eighth Edition Powerpoint Lecture Outline Ricki Lewis Prepared by Dubear Kroening University of Wisconsin-Fox Valley

Chapter 6 Matters of Sex

Sexual Development • In early embryos unspecialized gonads and two sets of reproductive ducts exist until week 6 • An embryo develops as a male or female using information from the Y chromosome Figure 6.1

Male or Female? • Gender is ultimately a genetic phenomenon • It also has psychological and sociological components • Males have 22 pairs of autosomes and X and Y chromosomes • Females have 22 pairs of autosomes and two X chromosomes

Sex Chromosomes Determine Gender • Human males are the heterogametic sex with different sex chromosomes, (XY) • Human females are the homogametic sex (XX) • In other species sex can be determined in many ways For example, in birds and snakes • males are homogametic ZZ • females are heterogametic ZW

X and Y Chromosomes • X chromosome • contains more than 1,500 genes • larger than the Y chromosome • acts as a homolog to Y chromosome in males • Y chromosome • contains 231 genes • many DNA segments are palindromes and may destabilize DNA Figure 6.2

Genes on the Y Chromosome Genes shared with X chromosome define the pseudoautosomal regions (PAR1 and PAR2) • Male specific (MSY) including SRY gene • SRY gene is important in determining sex Figure 6.3

SRY Gene • Encodes a transcription factor protein • Controls the expression of other genes • Stimulates male development • Developing testes secrete anti-Mullerian hormone and destroy female structures • Testosterone and DHT are secreted and stimulate male structures

Mutations that Disrupt Normal Sexual Development Figure 6.4

Table 6.1

Sex ratios • Mendel’s laws predict an equal number of males and females • Calculated by # of males / # of females x 1,000 • Primary sex ratio – conceptions • Secondary – births • Bias in China and India • Changes with age

Figure 6.6

Y-linked Traits • Genes on the Y chromosome • Very rare • Transmitted male to male • No affected females • Currently, identified Y-linked traits involve infertility and are not transmitted

Possible genotypes X+Y  Hemizygouswild type male XmY Hemizygous mutant male X+X+ Homozyogus wild female X+Xm Heterozygous female carrier XmXm Homozygous mutant female X-linked Traits

X-linked Recessive Traits • Always expressed in hemizygous males • Female homozygotes show the trait but female heterozygotes do not • Affected males: Inherited from affected or heterozygous mother • Affected females: affected fathers and affected or heterozygous mothers

X-linked Recessive InheritanceIchthyosis Figure 6.7

Figure 6.8- Queen Victoria’s Family- Hemophilia

X-linked Dominant Inheritance • Expressed with one copy • Males are often more severely affected • Typically associated with miscarriage or lethality in males • Passed from father to all his daughters but none of his sons

X-linked Dominant Inheritance: Congenital Generalized Hypertrichosis Figure 6.10

Genetics Problems • Look at inheritance pattern • Draw pedigree • List genotypes and phenotypes and their probabilities • Assign genotypes and phenotypes • Determine alleles into gametes • Punnett square – ratios • Repeat for next generation

Homosexuality • Same genotype and phenotype • Physical attraction to same sex. • Homosexuality-all cultures,thousands of years • Found in > 500 animal species. • Evidence may suggest a genetic component • Twin/sibling studies- more likely in identical twins. • Brain areas different in homosexual men. • Hamer 1993- Identifying possible markers • studied 40 pairs of homosexual brothers • 5 identical genetic markers on the X chromosome found in 33 of the pairs. • Markers not found in heterosexual brothers. • Research in this area is controversial- • No gene identified. • Altered gene expression in male Drosophila • Mutant white gene expressed in all cells caused decreased serotonin levels and homosexual behavior

6-3 X Inactivation • The XIST gene encodes an RNAthat binds to andinactivates the X chromosome • Inactivated X chromosome forms a Barr body • Manifesting heterozygotes

6.3 - X Inactivation • Females have two alleles for X chromosome genes but males have only one • In mammals, X inactivation balances this inequality. • Early in embryonic development one X chromosome is randomly inactivated in each cell. • Which X chromosome is inactivated is random. • Some cells express the father’s X chromosome genes, some cells express the mother’s X chromosome genes. • Results in mosiac expression.

Figure 6.12

Specific region on X chromosome • X inactivation center. • XIST gene- controls inactivation process. • XIST gene encodes an RNA that binds to a specific site on the same chromosome inactivating the X chromosome. • All daughter cells will have inactivated X chromosomes. • Adult females- patches of tissue- phenotypically different in X-linked gene expression. • Genotype not altered. • Inactivation is reversed in germline cells that become oocytes. • Inactivated X chromosome- visualized in interphase as a dark staining Barr body. ( absorbs stain faster due to methyl groups on DNA) • No Barr bodies found in males.

Heterozygotes and X Inactivation • Homozygous X-linked genotypes-X inactivation-no effect. • Heterozygous- X inactivation-has an effect. • Expression of 1 allele or the other. • Not usually a health problem- enough cells produce gene product. • Examples • incontinentia pigmenti-swirls of skin color- melanin • Anhidrotic ectodermal dysplasia- patches lacking sweat glands and hair. • Manifesting heterozygote- X linked carrier who expresses the phenotype. • Rarely observed in humans.

Cats Heterozygous for the Coat Color Gene- females Tortoiseshell Calico Brownish/black & yellow patches against a white (epistasis) background

6.4- Gender Effects on Phenotype Sex-limited Traits: • Traits that affect a structure or function in only one sex. • May be autosomal or X linked • Affects one sex; genes transmitted by both Examples: • Beard growth-hormones • Breast size • Milk production and horn development –cattle • Preeclampsia- elevated blood pressure. • Sperm production levels

Sex-influenced Traits: • Traits in which the phenotype expressed by a heterozygote is influenced by gender. • Allele appears dominant in one gender and recessive in the other Example: • Pattern baldness is a sex-influenced trait: • dominant in men- BB or Bb • Recessive in females bb menwomen m/m bald bald m/+ bald unaffected +/+ unaffected unaffected

Male pattern baldness- Adams family

Genomic Imprinting • 1% of our genes exhibit • “parent of origin” effect –silencing expression from one parent • Function unknown, may play a role in development • Genes silenced by an epigenetic event, DNA methylation • Imprints maintained in mitotic divisions but lost in meiosis

Genomic Imprinting Figure 6.16

Importance of Genomic Imprinting • Experiments suggest that it takes two opposite sex parents to produce a healthy embryo • Genes from female parent direct embryo development, • Genes from the male parent-placental development. • May explain incomplete penetrance- • polydactyl- silencing of mutant allele.

Imprinting and Human Disease Deletion on chromosome 15 reveals imprinting Figure 6.17 • Inherited paternally • Prader-Willi syndrome • Inherited maternally • Angelmansyndrome

Callipyge (“beautiful buttock”) Sheep Is Caused by Genomic Imprinting • Over-muscled hindquarters • Autosomal dominant • Trait only passed if it came from the father and the female may not carry the trait • Seven other genes are overexpessed on chromosome 18

Figure 6.18

Human Genetics

Human Genetics

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Human Genetics

Human Genetics

HUMAN GENETICS

Human Genetics

Human Genetics

Human Genetics

Human Genetics

Human Genetics

HUMAN GENETICS

HUMAN GENETICS

Human Genetics

Human Genetics

Human Genetics

Human Genetics

Human Genetics

Human Genetics

Human Genetics

HUMAN GENETICS

Human Genetics

Human Genetics

Human Genetics

Human Genetics