X chromosome: Difference between revisions

Human X chromosome
	File:Human male karyotpe high resolution - X chromosome cropped.png Human X chromosome (after G-banding)
	File:Human male karyotpe high resolution - Chromosome X.png X chromosome in human male karyogram
Features
Length (bp)	156,040,895 bp; (GRCh38)
No. of genes	804 (CCDS)
Type	Allosome
Centromere position	Submetacentric; (61.0 Mbp)
Complete gene lists
CCDS	Gene list
HGNC	Gene list
UniProt	Gene list
NCBI	Gene list
External map viewers
Ensembl	Chromosome X
Entrez	Chromosome X
NCBI	Chromosome X
UCSC	Chromosome X
Full DNA sequences
RefSeq	NC_000023 (FASTA)
GenBank	CM000685 (FASTA)

VisualWikitext

Latest revision as of 09:05, 14 December 2018

The X chromosome is one of the two sex-determining chromosomes (allosomes) in many organisms, including mammals (the other is the Y chromosome), and is found in both males and females. It is a part of the XY sex-determination system and X0 sex-determination system. The X chromosome was named for its unique properties by early researchers, which resulted in the naming of its counterpart Y chromosome, for the next letter in the alphabet, following its subsequent discovery.^[5]

Discovery

It was first noted that the X chromosome was special in 1890 by Hermann Henking in Leipzig. Henking was studying the testicles of Pyrrhocoris and noticed that one chromosome did not take part in meiosis. Chromosomes are so named because of their ability to take up staining (chroma in Greek means color). Although the X chromosome could be stained just as well as the others, Henking was unsure whether it was a different class of object and consequently named it X element,^[6] which later became X chromosome after it was established that it was indeed a chromosome.^[7]

The idea that the X chromosome was named after its similarity to the letter "X" is mistaken. All chromosomes normally appear as an amorphous blob under the microscope and only take on a well defined shape during mitosis. This shape is vaguely X-shaped for all chromosomes. It is entirely coincidental that the Y chromosome, during mitosis, has two very short branches which can look merged under the microscope and appear as the descender of a Y-shape.^[8]

It was first suggested that the X chromosome was involved in sex determination by Clarence Erwin McClung in 1901. After comparing his work on locusts with Henking's and others, McClung noted that only half the sperm received an X chromosome. He called this chromosome an accessory chromosome, and insisted (correctly) that it was a proper chromosome, and theorized (incorrectly) that it was the male-determining chromosome.^[6]

Inheritance pattern

File:X chromosome ancestral line Fibonacci sequence.svg

The number of possible ancestors on the X chromosome inheritance line at a given ancestral generation follows the Fibonacci sequence. (After Hutchison, L. "Growing the Family Tree: The Power of DNA in Reconstructing Family Relationships".^[9])

Luke Hutchison noticed that a number of possible ancestors on the X chromosome inheritance line at a given ancestral generation follows the Fibonacci sequence.^[9] A male individual has an X chromosome, which he received from his mother, and a Y chromosome, which he received from his father. The male counts as the "origin" of his own X chromosome (<math>F_1=1</math>), and at his parents' generation, his X chromosome came from a single parent (<math>F_2=1</math>). The male's mother received one X chromosome from her mother (the son's maternal grandmother), and one from her father (the son's maternal grandfather), so two grandparents contributed to the male descendant's X chromosome (<math>F_3=2</math>). The maternal grandfather received his X chromosome from his mother, and the maternal grandmother received X chromosomes from both of her parents, so three great-grandparents contributed to the male descendant's X chromosome (<math>F_4=3</math>). Five great-great-grandparents contributed to the male descendant's X chromosome (<math>F_5=5</math>), etc. (Note that this assumes that all ancestors of a given descendant are independent, but if any genealogy is traced far enough back in time, ancestors begin to appear on multiple lines of the genealogy, until eventually, a population founder appears on all lines of the genealogy.)

Humans

Function

File:Sd4hi-unten-crop.jpg

Nucleus of a female amniotic fluid cell. Top: Both X-chromosome territories are detected by FISH. Shown is a single optical section made with a confocal microscope. Bottom: Same nucleus stained with DAPI and recorded with a CCD camera. The Barr body is indicated by the arrow, it identifies the inactive X (Xi).

The X chromosome in humans spans more than 153 million base pairs (the building material of DNA). It represents about 800 protein-coding genes compared to the Y chromosome containing about 70 genes, out of 20,000–25,000 total genes in the human genome. Each person usually has one pair of sex chromosomes in each cell. Females have two X chromosomes, whereas males have one X and one Y chromosome. Both males and females retain one of their mother's X chromosomes, and females retain their second X chromosome from their father. Since the father retains his X chromosome from his mother, a human female has one X chromosome from her paternal grandmother (father's side), and one X chromosome from her mother. This inheritance pattern follows the Fibonacci numbers at a given ancestral depth.

Genetic disorders that are due to mutations in genes on the X chromosome are described as X linked.

The X chromosome carries hundreds of genes but few, if any, of these have anything to do directly with sex determination. Early in embryonic development in females, one of the two X chromosomes is randomly and permanently inactivated in nearly all somatic cells (cells other than egg and sperm cells). This phenomenon is called X-inactivation or Lyonization, and creates a Barr body. If X-inactivation in the somatic cell meant a complete de-functionalizing of one of the X-chromosomes, it would ensure that females, like males, had only one functional copy of the X chromosome in each somatic cell. This was previously assumed to be the case. However, recent research suggests that the Barr body may be more biologically active than was previously supposed.^[10]

Genes

Number of genes

The following are some of the gene count estimates of human X chromosome. Because researchers use different approaches to genome annotation their predictions of the number of genes on each chromosome varies (for technical details, see gene prediction). Among various projects, the collaborative consensus coding sequence project (CCDS) takes an extremely conservative strategy. So CCDS's gene number prediction represents a lower bound on the total number of human protein-coding genes.^[11]

Estimated by	Protein-coding genes	Non-coding RNA genes	Pseudogenes	Source	Release date
CCDS	804	—	—	^[2]	2016-09-08
HGNC	825	260	606	^[12]	2017-05-12
Ensembl	841	639	871	^[13]	2017-03-29
UniProt	839	—	—	^[14]	2018-02-28
NCBI	874	494	879	^[15]^[16]^[17]	2017-05-19

Gene list

The following is a partial list of genes on human chromosome X. For complete list, see the link in the infobox on the right.

APOO: encoding protein Apolipoprotein O
ARMCX6: encoding protein Armadillo repeat containing X-linked 6
BEX1: encoding protein Brain-expressed X-linked protein 1
BEX2: encoding protein Brain-expressed X-linked protein 2
BEX4: encoding protein Brain expressed, X-linked 4
CCDC120: encoding protein Coiled coil domain containing protein 120
CCDC22: encoding protein Coiled-coil domain containing 22
CD99L2: CD99 antigen-like protein 2
CHRDL1: encoding protein Chordin-like 1
CMTX2 encoding protein Charcot-Marie-Tooth neuropathy, X-linked 2 (recessive)
CMTX3 encoding protein Charcot-Marie-Tooth neuropathy, X-linked 3 (dominant)
CT45A5: encoding protein Cancer/testis antigen family 45, member A5
CXorf36: encoding protein hypothetical protein LOC79742
CXorf40A: Chromosome X open reading frame 40
CXorf49: chromosome X open reading frame 49. encoding protein
CXorf66: encoding protein Chromosome X Open Reading Frame 66
CXorf67: encoding protein Uncharacterized protein CXorf67
DACH2: encoding protein Dachshund homolog 2
EFHC2: encoding protein EF-hand domain (C-terminal) containing 2
ERCC6L encoding protein ERCC excision repair 6 like, spindle assembly checkpoint helicase
F8A1: Factor VIII intron 22 protein
FAM120C: encoding protein Family with sequence similarity 120C
FAM122B: Family with sequence similarity 122 member B
FAM122C: encoding protein Family with sequence similarity 122C
FAM127A: CAAX box protein 1
FAM50A: Family with sequence similarity 50 member A
FATE1: Fetal and adult testis-expressed transcript protein
FMR1-AS1: encoding a long non-coding RNA FMR1 antisense RNA 1
FRMPD3: encoding protein FERM and PDZ domain containing 3
FUNDC1: encoding protein FUN14 domain containing 1
FUNDC2: FUN14 domain-containing protein 2
GATA1: encoding GATA1 transcription factor
GNL3L encoding protein G protein nucleolar 3 like
GPRASP2: G-protein coupled receptor-associated sorting protein 2
GRIPAP1: encoding protein GRIP1-associated protein 1
HDHD1A: encoding enzyme Haloacid dehalogenase-like hydrolase domain-containing protein 1A
LAS1L encoding protein LAS1-like protein
MAGEA2: encoding protein Melanoma-associated antigen 2
MAGEA5 encoding protein Melanoma antigen family A, 5
MAGEA8: encoding protein Melanoma antigen family A, 8
MAGED4B: encoding protein Melanoma-associated antigen D4
MAGT1: encoding protein Magnesium transporter protein 1
MBNL3: encoding protein Muscleblind-like protein 3
MIR222: encoding microRNA MicroRNA 222
MIR361: encoding microRNA MicroRNA 361
MIR660: encoding protein MicroRNA 660
MORF4L2: encoding protein Mortality factor 4-like protein 2
MOSPD1: encoding protein Motile sperm domain containing 1
MOSPD2: encoding protein Motile sperm domain containing 2
NKRF: encoding protein NF-kappa-B-repressing factor
NRK: encoding enzyme Nik-related protein kinase
OTUD5: encoding protein OTU deubiquitinase 5
PASD1: encoding protein PAS domain-containing protein 1
PBDC1: encoding a protein of unestablished function
PCYT1B: encoding enzyme Choline-phosphate cytidylyltransferase B
PIN4: encoding enzyme Peptidyl-prolyl cis-trans isomerase NIMA-interacting 4
PLAC1: encoding protein Placenta-specific protein 1
PLP2: encoding protein Proteolipid protein 2
RPA4: encoding protein Replication protein A 30 kDa subunit
RPS6KA6: encoding protein Ribosomal protein S6 kinase, 90kDa, polypeptide 6
RRAGB: encoding protein Ras-related GTP-binding protein B
SFRS17A: encoding protein Splicing factor, arginine/serine-rich 17A
SLITRK2: encoding protein SLIT and NTRK-like protein 2
SMARCA1: encoding protein Probable global transcription activator SNF2L1
SMS: encoding enzyme Spermine synthase
SSR4: encoding protein Translocon-associated protein subunit delta
TAF7l: encoding protein TATA-box binding protein associated factor 7-like
TCEAL1: encoding protein Transcription elongation factor A protein-like 1
TCEAL4: encoding protein Transcription elongation factor A protein-like 4
THOC2: encoding protein THO complex subunit 2
TMEM29: encoding protein Protein FAM156A
TMEM47: encoding protein Transmembrane protein 47
TMLHE: encoding enzyme Trimethyllysine dioxygenase, mitochondrial
TNMD encoding protein Tenomodulin (also referred to as tendin, myodulin, Tnmd and TeM)
TRAPPC2P1 encoding protein Trafficking protein particle complex subunit 2
TREX2: encoding enzyme Three prime repair exonuclease 2
TRO: encoding protein Trophinin
TSPYL2: encoding protein Testis-specific Y-encoded-like protein 2
USP51: encoding enzyme Ubiquitin carboxyl-terminal hydrolase 51
YIPF6: encoding protein Protein YIPF6
ZC3H12B: encoding protein ZC3H12B
ZFP92: encoding protein ZFP92 zinc finger protein
ZMYM3: encoding protein Zinc finger MYM-type protein 3
ZNF157: encoding protein Zinc finger protein 157
ZNF182 encoding protein Zinc finger protein 182
ZNF275: encoding protein Zinc finger protein 275
ZNF674: encoding protein Zinc finger protein 674

Structure

It is theorized by Ross et al. 2005 and Ohno 1967 that the X chromosome is at least partially derived from the autosomal (non-sex-related) genome of other mammals, evidenced from interspecies genomic sequence alignments.

The X chromosome is notably larger and has a more active euchromatin region than its Y chromosome counterpart. Further comparison of the X and Y reveal regions of homology between the two. However, the corresponding region in the Y appears far shorter and lacks regions that are conserved in the X throughout primate species, implying a genetic degeneration for Y in that region. Because males have only one X chromosome, they are more likely to have an X chromosome-related disease.

It is estimated that about 10% of the genes encoded by the X chromosome are associated with a family of "CT" genes, so named because they encode for markers found in both tumor cells (in cancer patients) as well as in the human testis (in healthy patients).^[18]

Role in diseases

Numerical abnormalities

Klinefelter syndrome:

Klinefelter syndrome is caused by the presence of one or more extra copies of the X chromosome in a male's cells. Extra genetic material from the X chromosome interferes with male sexual development, preventing the testicles from functioning normally and reducing the levels of testosterone.
Males with Klinefelter syndrome typically have one extra copy of the X chromosome in each cell, for a total of two X chromosomes and one Y chromosome (47,XXY). It is less common for affected males to have two or three extra X chromosomes (48,XXXY or 49,XXXXY) or extra copies of both the X and Y chromosomes (48,XXYY) in each cell. The extra genetic material may lead to tall stature, learning and reading disabilities, and other medical problems. Each extra X chromosome lowers the child's IQ by about 15 points,^[19]^[20] which means that the average IQ in Klinefelter syndrome is in general in the normal range, although below average. When additional X and/or Y chromosomes are present in 48,XXXY, 48,XXYY, or 49,XXXXY, developmental delays and cognitive difficulties can be more severe and mild intellectual disability may be present.
Klinefelter syndrome can also result from an extra X chromosome in only some of the body's cells. These cases are called mosaic 46,XY/47,XXY.

Triple X syndrome (also called 47,XXX or trisomy X):

This syndrome results from an extra copy of the X chromosome in each of a female's cells. Females with trisomy X have three X chromosomes, for a total of 47 chromosomes per cell. The average IQ of females with this syndrome is 90, while the average IQ of unaffected siblings is 100.^[21] Their stature on average is taller than normal females. They are fertile and their children do not inherit the condition.^[22]
Females with more than one extra copy of the X chromosome (48, XXXX syndrome or 49, XXXXX syndrome) have been identified, but these conditions are rare.

Turner syndrome:

This results when each of a female's cells has one normal X chromosome and the other sex chromosome is missing or altered. The missing genetic material affects development and causes the features of the condition, including short stature and infertility.
About half of individuals with Turner syndrome have monosomy X (45,X), which means each cell in a woman's body has only one copy of the X chromosome instead of the usual two copies. Turner syndrome can also occur if one of the sex chromosomes is partially missing or rearranged rather than completely missing. Some women with Turner syndrome have a chromosomal change in only some of their cells. These cases are called Turner syndrome mosaics (45,X/46,XX).

X-linked recessive disorders

Sex linkage was first discovered in insects, e.g., T. H. Morgan's 1910 discovery of the pattern of inheritance of the white eyes mutation in Drosophila melanogaster.^[23] Such discoveries helped to explain x-linked disorders in humans, e.g., haemophilia A and B, adrenoleukodystrophy, and red-green color blindness.

Other disorders

XX male syndrome is a rare disorder, where the SRY region of the Y chromosome has recombined to be located on one of the X chromosomes. As a result, the XX combination after fertilization has the same effect as a XY combination, resulting in a male. However, the other genes of the X chromosome cause feminization as well.

X-linked endothelial corneal dystrophy is an extremely rare disease of cornea associated with Xq25 region. Lisch epithelial corneal dystrophy is associated with Xp22.3.

Megalocornea 1 is associated with Xq21.3-q22^{[medical citation needed]}

Adrenoleukodystrophy, a rare and fatal disorder that is carried by the mother on the x-cell. It affects only boys between the ages of 5 and 10 and destroys the protective cell surrounding the nerves, myelin, in the brain. The female carrier hardly shows any symptoms because females have a copy of the x-cell. This disorder causes a once healthy boy to lose all abilities to walk, talk, see, hear, and even swallow. Within 2 years after diagnosis, most boys with Adrenoleukodystrophy die.

Role in mental abilities and intelligence

The X-chromosome has played a crucial role in the development of sexually selected characteristics for over 300 million years. During that time it has accumulated a disproportionate number of genes concerned with mental functions. For reasons that are not yet understood, there is an excess proportion of genes on the X-chromosome that are associated with the development of intelligence, with no obvious links to other significant biological functions.^[24]^[25] . In other words, a significant proportion of genes associated with intelligence is passed on to the male offspring from the maternal side and to the female offspring from either/both maternal and paternal side.There has also been interest in the possibility that haploinsufficiency for one or more X-linked genes has a specific impact on development of the Amygdala and its connections with cortical centres involved in social–cognition processing or the ‘social brain'.^[24]^[26]^{[clarification needed]}

Cytogenetic band

G-banding ideograms of human X chromosome

File:Human chromosome X ideogram vertical.svg

G-banding ideogram of human X chromosome in resolution 850 bphs. Band length in this diagram is proportional to base-pair length. This type of ideogram is generally used in genome browsers (e.g. Ensembl, UCSC Genome Browser).

File:Human chromosome X - 400 550 850 bphs.png

G-banding patterns of human X chromosome in three different resolutions (400,^[27] 550^[28] and 850^[4]). Band length in this diagram is based on the ideograms from ISCN (2013).^[29] This type of ideogram represents actual relative band length observed under a microscope at the different moments during the mitotic process.^[30]

G-bands of human X chromosome in resolution 850 bphs^[4]
Chr.	Arm^[31]	Band^[32]	ISCN start^[33]	ISCN stop^[33]	Basepair start	Basepair stop	Stain^[34]	Density
X	p	22.33	0	323	7000100000000000000♠1	7006440000000000000♠4,400,000	gneg
X	p	22.32	323	504	7006440000100000000♠4,400,001	7006610000000000000♠6,100,000	gpos	50
X	p	22.31	504	866	7006610000100000000♠6,100,001	7006960000000000000♠9,600,000	gneg
X	p	22.2	866	1034	7006960000100000000♠9,600,001	7007174000000000000♠17,400,000	gpos	50
X	p	22.13	1034	1345	7007174000010000000♠17,400,001	7007192000000000000♠19,200,000	gneg
X	p	22.12	1345	1448	7007192000010000000♠19,200,001	7007219000000000000♠21,900,000	gpos	50
X	p	22.11	1448	1577	7007219000010000000♠21,900,001	7007249000000000000♠24,900,000	gneg
X	p	21.3	1577	1784	7007249000010000000♠24,900,001	7007293000000000000♠29,300,000	gpos	100
X	p	21.2	1784	1862	7007293000010000000♠29,300,001	7007315000000000000♠31,500,000	gneg
X	p	21.1	1862	2120	7007315000010000000♠31,500,001	7007378000000000000♠37,800,000	gpos	100
X	p	11.4	2120	2430	7007378000010000000♠37,800,001	7007425000000000000♠42,500,000	gneg
X	p	11.3	2430	2624	7007425000010000000♠42,500,001	7007476000000000000♠47,600,000	gpos	75
X	p	11.23	2624	2948	7007476000010000000♠47,600,001	7007501000000000000♠50,100,000	gneg
X	p	11.22	2948	3129	7007501000010000000♠50,100,001	7007548000000000000♠54,800,000	gpos	25
X	p	11.21	3129	3206	7007548000010000000♠54,800,001	7007581000000000000♠58,100,000	gneg
X	p	11.1	3206	3297	7007581000010000000♠58,100,001	7007610000000000000♠61,000,000	acen
X	q	11.1	3297	3491	7007610000010000000♠61,000,001	7007638000000000000♠63,800,000	acen
X	q	11.2	3491	3620	7007638000010000000♠63,800,001	7007654000000000000♠65,400,000	gneg
X	q	12	3620	3827	7007654000010000000♠65,400,001	7007685000000000000♠68,500,000	gpos	50
X	q	13.1	3827	4137	7007685000010000000♠68,500,001	7007730000000000000♠73,000,000	gneg
X	q	13.2	4137	4292	7007730000010000000♠73,000,001	7007747000000000000♠74,700,000	gpos	50
X	q	13.3	4292	4447	7007747000010000000♠74,700,001	7007768000000000000♠76,800,000	gneg
X	q	21.1	4447	4732	7007768000010000000♠76,800,001	7007854000000000000♠85,400,000	gpos	100
X	q	21.2	4732	4809	7007854000010000000♠85,400,001	7007870000000000000♠87,000,000	gneg
X	q	21.31	4809	5107	7007870000010000000♠87,000,001	7007927000000000000♠92,700,000	gpos	100
X	q	21.32	5107	5184	7007927000010000000♠92,700,001	7007943000000000000♠94,300,000	gneg
X	q	21.33	5184	5430	7007943000010000000♠94,300,001	7007991000000000000♠99,100,000	gpos	75
X	q	22.1	5430	5701	7007991000010000000♠99,100,001	7008103300000000000♠103,300,000	gneg
X	q	22.2	5701	5843	7008103300001000000♠103,300,001	7008104500000000000♠104,500,000	gpos	50
X	q	22.3	5843	6050	7008104500001000000♠104,500,001	7008109400000000000♠109,400,000	gneg
X	q	23	6050	6322	7008109400001000000♠109,400,001	7008117400000000000♠117,400,000	gpos	75
X	q	24	6322	6619	7008117400001000000♠117,400,001	7008121800000000000♠121,800,000	gneg
X	q	25	6619	7059	7008121800001000000♠121,800,001	7008129500000000000♠129,500,000	gpos	100
X	q	26.1	7059	7253	7008129500001000000♠129,500,001	7008131300000000000♠131,300,000	gneg
X	q	26.2	7253	7395	7008131300001000000♠131,300,001	7008134500000000000♠134,500,000	gpos	25
X	q	26.3	7395	7602	7008134500001000000♠134,500,001	7008138900000000000♠138,900,000	gneg
X	q	27.1	7602	7808	7008138900001000000♠138,900,001	7008141200000000000♠141,200,000	gpos	75
X	q	27.2	7808	7886	7008141200001000000♠141,200,001	7008143000000000000♠143,000,000	gneg
X	q	27.3	7886	8145	7008143000001000000♠143,000,001	7008148000000000000♠148,000,000	gpos	100
X	q	28	8145	8610	7008148000001000000♠148,000,001	7008156040895000000♠156,040,895	gneg

References

Earlier versions of this article contain material from the National Library of Medicine (https://web.archive.org/web/20081122151614/http://www.nlm.nih.gov/copyright.html), a part of the National Institutes of Health (USA,) which, as a US government publication, is in the public domain.

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↑ Genome Decoration Page, NCBI. Ideogram data for Homo sapience (400 bphs, Assembly GRCh38.p3). Last update 2014-03-04. Retrieved 2017-04-26.
↑ Genome Decoration Page, NCBI. Ideogram data for Homo sapience (550 bphs, Assembly GRCh38.p3). Last update 2015-08-11. Retrieved 2017-04-26.
↑ International Standing Committee on Human Cytogenetic Nomenclature (2013). ISCN 2013: An International System for Human Cytogenetic Nomenclature (2013). Karger Medical and Scientific Publishers. ISBN 978-3-318-02253-7.
↑ Sethakulvichai, W.; Manitpornsut, S.; Wiboonrat, M.; Lilakiatsakun, W.; Assawamakin, A.; Tongsima, S. (2012). Estimation of band level resolutions of human chromosome images. In Computer Science and Software Engineering (JCSSE), 2012 International Joint Conference on. pp. 276–282. doi:10.1109/JCSSE.2012.6261965. ISBN 978-1-4673-1921-8.
↑ "p": Short arm; "q": Long arm.
↑ For cytogenetic banding nomenclature, see article locus.
↑ ^33.0 ^33.1 These values (ISCN start/stop) are based on the length of bands/ideograms from the ISCN book, An International System for Human Cytogenetic Nomenclature (2013). Arbitrary unit.
↑ gpos: Region which is positively stained by G banding, generally AT-rich and gene poor; gneg: Region which is negatively stained by G banding, generally CG-rich and gene rich; acen Centromere. var: Variable region; stalk: Stalk.

External links

National Institutes of Health. "X chromosome". Genetics Home Reference. Retrieved 2017-05-06.
"X chromosome". Human Genome Project Information Archive 1990–2003. Retrieved 2017-05-06.

[National_Center_for_Biotechnology_Information_2017-1] "Human Genome Assembly GRCh38 - Genome Reference Consortium". National Center for Biotechnology Information. 2013-12-24. Retrieved 2017-03-04.

[CCDS-2] 2.0 ^2.1 "Search results - X[CHR] AND "Homo sapiens"[Organism] AND ("has ccds"[Properties] AND alive[prop]) - Gene". NCBI. CCDS Release 20 for Homo sapiens. 2016-09-08. Retrieved 2017-05-28.

[StrachanRead2010-3] Tom Strachan; Andrew Read (2 April 2010). Human Molecular Genetics. Garland Science. p. 45. ISBN 978-1-136-84407-2.

[850bphs-4] 4.0 ^4.1 ^4.2 Genome Decoration Page, NCBI. Ideogram data for Homo sapience (850 bphs, Assembly GRCh38.p3). Last update 2014-06-03. Retrieved 2017-04-26.

[nyt-angier-5] Angier, Natalie (2007-05-01). "For Motherly X Chromosome, Gender Is Only the Beginning". New York Times. Retrieved 2007-05-01.

[Schwartz-6] 6.0 ^6.1 James Schwartz, In Pursuit of the Gene: From Darwin to DNA, pages 155-158, Harvard University Press, 2009 ISBN 0674034910

[7] David Bainbridge, 'The X in Sex: How the X Chromosome Controls Our Lives, pages 3-5, Harvard University Press, 2003 ISBN 0674016211.

[8] Bainbridge, pages 65-66

[xcs-9] 9.0 ^9.1 Hutchison, Luke (September 2004). "Growing the Family Tree: The Power of DNA in Reconstructing Family Relationships" (PDF). Proceedings of the First Symposium on Bioinformatics and Biotechnology (BIOT-04). Retrieved 2016-09-03.

[Carrel-10] Carrel L, Willard H (2005). "X-inactivation profile reveals extensive variability in X-linked gene expression in females". Nature. 434 (7031): 400–4. doi:10.1038/nature03479. PMID 15772666.

[pmid20441615-11] Pertea M, Salzberg SL (2010). "Between a chicken and a grape: estimating the number of human genes". Genome Biol. 11 (5): 206. doi:10.1186/gb-2010-11-5-206. PMC 2898077. PMID 20441615.

[HGNC20170512-12] "Statistics & Downloads for chromosome X". HUGO Gene Nomenclature Committee. 2017-05-12. Retrieved 2017-05-19.

[Ensembl_Release_88-13] "Chromosome X: Chromosome summary - Homo sapiens". Ensembl Release 88. 2017-03-29. Retrieved 2017-05-19.

[UniProt-14] "Human chromosome X: entries, gene names and cross-references to MIM". UniProt. 2018-02-28. Retrieved 2018-03-16.

[NCBI_coding-15] "Search results - X[CHR] AND "Homo sapiens"[Organism] AND ("genetype protein coding"[Properties] AND alive[prop]) - Gene". NCBI. 2017-05-19. Retrieved 2017-05-20.

[NCBI_noncoding-16] "Search results - X[CHR] AND "Homo sapiens"[Organism] AND ( ("genetype miscrna"[Properties] OR "genetype ncrna"[Properties] OR "genetype rrna"[Properties] OR "genetype trna"[Properties] OR "genetype scrna"[Properties] OR "genetype snrna"[Properties] OR "genetype snorna"[Properties]) NOT "genetype protein coding"[Properties] AND alive[prop]) - Gene". NCBI. 2017-05-19. Retrieved 2017-05-20.

[NCBI_pseudo-17] "Search results - X[CHR] AND "Homo sapiens"[Organism] AND ("genetype pseudo"[Properties] AND alive[prop]) - Gene". NCBI. 2017-05-19. Retrieved 2017-05-20.

[ross-18] Ross M, et al. (2005). "The DNA sequence of the human X chromosome". Nature. 434 (7031): 325–37. doi:10.1038/nature03440. PMC 2665286. PMID 15772651.

[19] Harold Chen; Ian Krantz; Mary L Windle; Margaret M McGovern; Paul D Petry; Bruce Buehler (2013-02-22). "Klinefelter Syndrome Pathophysiology". Medscape. Retrieved 2014-07-18.

[20] Visootsak J, Graham JM (2006). "Klinefelter syndrome and other sex chromosomal aneuploidies". Orphanet J Rare Dis. 1: 42. doi:10.1186/1750-1172-1-42. PMC 1634840. PMID 17062147.

[21] Bender B, Puck M, Salbenblatt J, Robinson A (1986). Smith S, ed. Cognitive development of children with sex chromosome abnormalities. San Diego: College Hill Press. pp. 175–201.

[22] "Triple X syndrome". Genetics Home Reference. 2014-07-14. Retrieved 2014-07-18.

[23] Morgan, T. H. (1910). "Sex-limited inheritance in Drosophila". Science. 32: 120–122.

[:0-24] 24.0 ^24.1 Skuse, David H. (2005-04-15). "X-linked genes and mental functioning". Human Molecular Genetics. 14 Spec No 1: R27–32. doi:10.1093/hmg/ddi112. ISSN 0964-6906. PMID 15809269.

[25] Zhao, Min; Kong, Lei; Qu, Hong (2014-02-25). "A systems biology approach to identify intelligence quotient score-related genomic regions, and pathways relevant to potential therapeutic treatments". Scientific Reports. 4: 4176. doi:10.1038/srep04176. ISSN 2045-2322. PMC 3933868. PMID 24566931.

[26] Startin, Carla M.; Fiorentini, Chiara; de Haan, Michelle; Skuse, David H. (2015-01-01). "Variation in the X-linked EFHC2 gene is associated with social cognitive abilities in males". PLOS ONE. 10 (6): e0131604. doi:10.1371/journal.pone.0131604. ISSN 1932-6203. PMC 4481314. PMID 26107779.

[400bphs-27] Genome Decoration Page, NCBI. Ideogram data for Homo sapience (400 bphs, Assembly GRCh38.p3). Last update 2014-03-04. Retrieved 2017-04-26.

[550bphs-28] Genome Decoration Page, NCBI. Ideogram data for Homo sapience (550 bphs, Assembly GRCh38.p3). Last update 2015-08-11. Retrieved 2017-04-26.

[Nomenclature2013-29] International Standing Committee on Human Cytogenetic Nomenclature (2013). ISCN 2013: An International System for Human Cytogenetic Nomenclature (2013). Karger Medical and Scientific Publishers. ISBN 978-3-318-02253-7.

[SethakulvichaiManitpornsut2012-30] Sethakulvichai, W.; Manitpornsut, S.; Wiboonrat, M.; Lilakiatsakun, W.; Assawamakin, A.; Tongsima, S. (2012). Estimation of band level resolutions of human chromosome images. In Computer Science and Software Engineering (JCSSE), 2012 International Joint Conference on. pp. 276–282. doi:10.1109/JCSSE.2012.6261965. ISBN 978-1-4673-1921-8.

[31] "p": Short arm; "q": Long arm.

[32] For cytogenetic banding nomenclature, see article locus.

[ISCN-33] 33.0 ^33.1 These values (ISCN start/stop) are based on the length of bands/ideograms from the ISCN book, An International System for Human Cytogenetic Nomenclature (2013). Arbitrary unit.

[34] gpos: Region which is positively stained by G banding, generally AT-rich and gene poor; gneg: Region which is negatively stained by G banding, generally CG-rich and gene rich; acen Centromere. var: Variable region; stalk: Stalk.

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