Sex Determination

Question 1

What are the biological advantages of sexual reproduction?

Answer 1

It speeds evolution and contributes to survival of species by increasing genetic variabilityIt also protects and preserves species

Question 2

What is X chromosomal inactivation, and what are the implications?

Answer 2

Cells from normal females inactivate one X chromosome.All diploid somatic cells in both males and females have a single active X chromosome regardless of the total number of X and Y chromosomes present.X inactivation is normally random so that females are mosaic for expression of their X chromosomes. On average, 50% of cells in any given tissue will express the paternally inherited X and 50% will express the maternally inherited X.

Question 3

What is the mechanism for X chromosome inactivation?

Answer 3

X inactivation results from DNA methylation and modifications of histone proteins that depend on expression of the XIST gene on the inactive X. The XIST gene encodes noncoding RNA, which is expressed in cell nuclei where it associates in cis (i.e. with the inactive X) as part of an XIST RNA/Barr body complex (See Figure 6-13 in Thompson and Thompson).

Question 4

What are the two cases when X inactivation is not random?

Answer 4

Nonrandom X inactivation occurs when an X chromosome is abnormal or there is an X; autosome translocation.Cytogenetic analysis looking for an X; autosomal translocation is indicated when a female presents with an X-linked recessive phenotype.In the absence of cytogenetic abnormalities, nonrandom X inactivation can be diagnosed by analyzing the methylation pattern of highly polymorphic X chromosomal loci (e.g. gene for the androgen receptor, AR, Xq11-12).Selection will favor normal X’s, and will preferentially deactivate abnormal X’s.

Question 5

How is sexual differentiation genetically regulated?

Answer 5

1. Genetic sex (XX, XY)2. Gonadal sex: Is SRY expressed?SRY is the principal determinant of testicular differentiation. In the absence of SRY expression, undifferentiated gonadal tissue develops into ovaries.

Question 6

What 2 stages do germ cells go through with regards to gonads?

Answer 6

Sexually independent pregonadal stage, during which they migrate from yolk sac to developing gonads.Gonadal dependent stage: when they mature.

Question 7

How is male/female genital sex regulated?

Answer 7

Specific hormones and growth factors from differentiated testes determine male gonads.In the absence of these factors or receptors, female genitalia develop (internal and external).

Question 8

What 2 non-germ cells are within normal testes?What do they produce?

Answer 8

Sertolli: Mullerian Inhibitory Factor (MIF)Leydig cells: Testosterone

Question 9

What does MIF do?

Answer 9

Prevents formation of mullerian (paramesonephric) duct derivatives (fallopian tubes, uterus, upper vagina).

Question 10

What does testosterone do?

Answer 10

Stimulates the development of Wolffian ducts (mesonephric) into the epididymal ducts and ductus deferens.Also stimulates descent of testes into the scrotum.

Question 11

What are the clinical characteristics of 45X?

Answer 11

45 X occurs most frequently (possibly as frequently as 50% of conceptions, but in about 1 in 2000 to 5000 liveborns) and produces Turner syndrome.In this condition early female gonadal and genital development are normal. However, gonadal dysgenesis (involution and degeneration of developing ovaries through apoptotic mechanisms) develops during late fetal life.Short stature, perceptual disorders and anatomic maldevelopment of the heart (coarctation of the aorta) and kidneys (fused) are also associated with this condition.

Question 12

What are the clinical characteristics of 47 XXY?

Answer 12

47 XXY individuals develop as anatomic males but also have gonadal dysgenesis. This results in infertility due to failed maturation of spermatogonia and low levels of testosterone production. Tall stature (eunichoid appearance), gynecomastea and increased impulsive behavior are also associated with this condition (Klinefelter syndrome). The frequency is about 1 in 1000.

Question 13

What are the clinical characteristics of 47XYY?

Answer 13

47 XYY individuals are normal males that are generally taller than expected in their families. The frequency is approximately 1 in 900-1000 in the general population but higher among men in penal institutions. The reason(s) for these differences in distribution are incompletely understood.

Question 14

Describe the clinical approach to disorders of sexual differentiation.

Answer 14

Determine the karyotype, guides both surgical and psychosocial management and genetic counselling.

Question 15

HOMEWORK: Sex in turtles is determined by the incubation temperature of their eggs. How does this happen?

Answer 15

Above a pivotal temperature, the turtle becomes a female. Below, it becomes a male. This is due to synergy between particular hormones and temperature.

Question 16

HOMEWORK: Haploinsufficiency for the SOX9 gene results in what skeletal dysplasia in which 75% of affected individuals with an XY karyotype develop ovaries?

Answer 16

Campomelic dysplasia: newborns have congenital bowing and angulation of long bones.

Question 17

HOMEWORK: Describe a condition in which SRY is absent and 46, XX individuals develop testicular tissue and male external genitalia. How does this occur?

Answer 17

SRY has been translocated to an X chromosome?

Question 18

What proteins does human genomic DNA combine with?What do they do?How are they arranged?

Answer 18

Histones, nonhistone proteinsHistones: involved in proper packaging in chromatin fiberNonhistone proteins: less understood. Solenoids are attached to them.Double helix wraps around histone octamers to form nucleosome fiber, which is arranged in a secondary helical chromatin structure (solenoid).

Question 19

What genomes do human cells contain?

Answer 19

Nuclear and mitochondrial

Question 20

What are the features of the mitochondrial genome?

Answer 20

Inheritance is exclusively maternal.16kB genome, few dozen genesUses slightly different triplet code.Can lead to genetic disease if mutated.Vast majority of proteins that function in mitochondria are encoded by nuclear genes.

Question 21

What are the fundamental principles regarding the evolution and organization of the human genome?

Answer 21

The human genome is a record of evolutionary history. As such, it reflects results of different selection pressures, and contains genes and genomic features that have been retained.

Question 22

What can genome variation cause?

Answer 22

Evolutionary changes and genetic disease

Question 23

Is the human genome static or dynamic?Why?

Answer 23

Dynamic.30 new mutations occur in each individual, recombination shuffles regions

Question 24

How frequently might one find an identical SNP between two individuals?

Answer 24

1/1000 base pairs between two randomly chosen human genomes.

Question 25

What are the types of variations that occur between genomes?

Answer 25

Insertion/deletion polymorphisms: Minisatellites (10-100 bps), microsatellites (2-4 nucleotide repeats)Single Nucleotide PolymorphismsCopy number variations (segments of genome 200bp-2Mb)

Question 26

What are examples of gene-rich and gene-poor chromosomes?What does it mean for DNA to be stable or unstable, GC rich, AT rich, euchromatic, or heterochromatic?

Answer 26

Gene rich: Chromosome 19Gene poor: 13,18,21Unstable: dynamic regionsStable: conserved regionsGC rich: 38% of the genomeAT rich: 54%Euchromatic: more relaxedHeterochromatic: more condensed

Question 27

Is the genome totally sequenced?

Answer 27

No, many gaps remain in euchromatic regions. Plus, repeat regions are hard to sequence.

Question 28

What categories can DNA sequences be assigned to?What are the frequencies of each class?

Answer 28

Protein coding (1.5%)Genes (20-25%)Single copy sequences (50%)Repetitive DNA (40-50%)

Question 29

What are the classes of repetitive DNA?

Answer 29

Tandem repeats (satellite): used for cytogenetic bandingDispersed repetitive elements: Alu (SINE = Short Interspersed repetitive Elements) and L1 (LINE = Long Interspersed repetitive Elements) families. Retrotransposition may cause insertional inactivation of genes.SINE: 300bp related members, 500k copiesLINE: 6kb related members, 100k copies

Question 30

How many genes are there?What are the different types of genes?

Answer 30

25,000 to 30,000Protein coding, RNA encoding, pseudogenes (intron containing or intronless)

Question 31

What is a gene family and how do they arise?

Answer 31

Gene family: composed of genes with sequence similarity but distinct functions.They arise through gene duplication, then mutation.

Question 32

What is the advantage of gene duplication?

Answer 32

When a gene duplicates, it frees up a copy to mutate while the other copy maintains a critical function.

Question 33

What is the missing heritability problem?

Answer 33

Genetic associations have not been found for a large part of expected genomic contribution. Bummer.