User:Dakotahodgson/sandbox

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Y linkage Wikipedia Article[edit]

I am planning to edit the y linkage stub article as part of my course in advanced genetics here at UWO.

Current Article[edit]

basic definition of y linkage
brief overview of inheritance of y linked genes
small reference to infertility in males because of y chromosome deletions
notes that the y chromosome is small and contains very few genes

Y-linked Inheritance[edit]

The pattern of Y linked inheritance is due to a large lack of recombination between the X and Y chromosomes during meiosis.^[1] On the Y chromosome there are two pseudoautosomal regions (regions that have sequences homologous with the X chromosome, where recombination between X and Y can occur) on the ends of both the short p and long q arms^[1]. These regions can line up and recombine with homologous sequences on the X chromosome during meiosis, whereas the rest of the Y chromosome, approximately 95% known as the male specific region MSY, will not participate in recombination. ^[2] A gene is Y-linked when it lies within the MSY, and because of the complete lack of recombination in this region, Y linked genes, traits and disorders can only be passed from father to son. Protein coding genes in the MSY have a wide variety of biological functions, and although a great deal of them are male development and reproduction specific, many have roles in a multitude of other systems. ^[3]

Testis-determining Factor[edit]

The Y chromosome, showing the location of the SRY gene

The sex determining region of the Y chromosome (SRY), found in the MSY, is commonly known as the testis-determining factor. ^[1] SRY is known as such because its job is to induce the differentiation of bipotential gonads to produce testes.^[4] It is important to note that the SRY genes do have homologous sequences on the X chromosome. In males, the X homologs are active, whereas in females, the homologous sequences are inactivated on both X chromosomes.^[1] The active presence of testis-determining factor genes in an individual will induce male development. In the absence of testis-determining factor genes, female development will occur by default. ^[5] In rare cases, XY individuals can be female. This can be because an individual has a loss of function mutation in a SRY gene; even though they have a Y chromosome, without the testis determining factor, development will default to female.^[2]

Y-linked Male Infertility[edit]

Genetic abnormalities account for 15% of the cases of infertility in human males.^[6] These abnormalities have been attributed to aneuploidies or mutations of mainly the sex chromosomes, but also the autosomes.^[7] The Y chromosome has a significant role in male reproduction and development, and any alterations can be detrimental to these systems.^[3]

Azoospermia[edit]

Male infertility is often in the form of azoospermia, a condition in which there is no sperm in the ejaculate.^[3] Azoospermia can be caused genetically by either sex chromosome abnormalities in the form of Turner Syndrome (where individuals have only one X chromosome), Klinefelter Syndrome (individuals with two X and one Y chromosomes) or Double Y Syndrome (individuals with one X and two Y chromosomes), or small Y chromosome deletions, known as microdeletions. The Y chromosome deletions that have been linked to infertility tend to occur in the azoospermia factor regions (AZF) of the Y chromosome classified into AZFa, b and c. Because the Y chromosome does not have a homologous chromosome to recombine with, these deletions often cannot be repaired. Deletions within any of these regions can result in a complete absence of sperm cells (AZFa), a block during meiosis (AZFb) or an arrest during spermatogenesis that produces a small number of incorrectly shaped sperm (AZFc – the most common). ^[3]

References[edit]

^ ^a ^b ^c ^d Lahn, B (2001). "the human Y chromosome, in the light of evolution". Nature Reviews. 2.
^ ^a ^b Jangravi, Z (2013). "A fresh look at the male-specific region of the human Y chromosome". Journal of proteome research. 12.
^ ^a ^b ^c ^d Heard, E; Turner, J (2011). "Function of the sex chromosomes in mammalian fertility". Cold Spring Harbor Perspectives in Biology. 3.
^ Barrionuevo, F (2012). "Genes promoting and disturbing testis development". Histology and Histopathology. 27.
^ Quinn, A (2012). "The molecular genetics of sex determination and sex reversal in mammals". Seminars in Reproductive Medicine. 30.
^ Ferlin, A (2006). "Genetic causes of male infertility". Reproduction Toxicology. 22.
^ Ali, S; Hasnain, S (2003). "Genomics of the human Y-chromosome 1. Association with male infertility". Gene. 321.

[The_human_Y_chromosome,_in_the_light_of_evolution-1] Lahn, B (2001). "the human Y chromosome, in the light of evolution". Nature Reviews. 2.

[A_fresh_look_at_the_male-specific_region_of_the_Y_chromosome_-_Z._Jangravi-2] Jangravi, Z (2013). "A fresh look at the male-specific region of the human Y chromosome". Journal of proteome research. 12.

[Function_of_the_sex_chromosomes_in_mammalian_fertility-3] Heard, E; Turner, J (2011). "Function of the sex chromosomes in mammalian fertility". Cold Spring Harbor Perspectives in Biology. 3.

[Genes_promoting_and_disturbing_testis_development-4] Barrionuevo, F (2012). "Genes promoting and disturbing testis development". Histology and Histopathology. 27.

[The_molecular_genetics_of_sex_determination_and_sex_reversal_in_mammals-5] Quinn, A (2012). "The molecular genetics of sex determination and sex reversal in mammals". Seminars in Reproductive Medicine. 30.

[Genetic_causes_of_male_infertility-6] Ferlin, A (2006). "Genetic causes of male infertility". Reproduction Toxicology. 22.

[Genomics_of_the_human_Y-chromosome_1._Association_with_male_infertility-7] Ali, S; Hasnain, S (2003). "Genomics of the human Y-chromosome 1. Association with male infertility". Gene. 321.

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