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Chromosome 15

From Wikipedia, the free encyclopedia
Chromosome 15
Human chromosome 15 pair after G-banding.
One is from mother, one is from father.
Chromosome 15 pair
in human male karyogram.
Features
Length (bp)99,753,195 bp
(CHM13)
No. of genes561 (CCDS)[1]
TypeAutosome
Centromere positionAcrocentric[2]
(19.0 Mbp[3])
Complete gene lists
CCDSGene list
HGNCGene list
UniProtGene list
NCBIGene list
External map viewers
EnsemblChromosome 15
EntrezChromosome 15
NCBIChromosome 15
UCSCChromosome 15
Full DNA sequences
RefSeqNC_000015 (FASTA)
GenBankCM000677 (FASTA)

Chromosome 15 is one of the 23 pairs of chromosomes in humans. People normally have two copies of this chromosome. Chromosome 15 spans about 99.7 million base pairs (the building material of DNA) and represents between 3% and 3.5% of the total DNA in cells. Chromosome 15 is an acrocentric chromosome, with a very small short arm (the "p" arm, for "petite"), which contains few protein coding genes among its 19 million base pairs. It has a larger long arm (the "q" arm) that is gene rich, spanning about 83 million base pairs.

The human leukocyte antigen gene for β2-microglobulin is found on chromosome 15, as well as the FBN1 gene, coding for both fibrillin-1 (a protein critical to the proper functioning of connective tissue), and asprosin (a small protein produced from part of the transcribed FBN1 gene mRNA), which is involved in fat metabolism.

Genes

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Number of genes

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The following are some of the gene count estimates of human chromosome 15. 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.[4]

Estimated by Protein-coding genes Non-coding RNA genes Pseudogenes Source Release date
CCDS 561 [1] 2016-09-08
HGNC 559 328 433 [5] 2017-05-12
Ensembl 605 992 508 [6] 2017-03-29
UniProt 601 [7] 2018-02-28
NCBI 629 716 594 [8][9][10] 2017-05-19

Gene list

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The following is a partial list of genes on human chromosome 15. For complete list, see the link in the infobox on the right.

  • AAGAB: alpha- and gamma-adaptin binding protein
  • ACSBG1: encoding enzyme Acyl-CoA Synthetase, Bubblegum Family, member 1
  • ADH1: alcohol dehydrogenase
  • ARHGAP11B: a human-specific gene encoding the Rho GTPase activating protein 11B, that amplifies basal progenitors, controls neural progenitor proliferation, and contributes to neocortex folding.
  • ARPIN: encoding protein Actin related protein 2/3 complex inhibitor
  • ARPP-19: encoding protein cAMP-regulated phosphoprotein 19
  • B2MR: encoding protein Beta-2-microglobulin regulator
  • C15orf15: encoding protein Probable ribosome biogenesis protein RLP24
  • C15orf32: encoding protein Uncharacterized protein C15orf32
  • C15orf54: encoding protein Chromosome 15 Open Reading Frame 54
  • CAPN3: Calpain 3 (limb-girdle muscular dystrophy type 2A)
  • CELF6: encoding protein Cugbp elav-like family member 6
  • CHP: Calcium binding protein P22\
  • CHSY1: Chondroitin sulfate synthase 1
  • CLK3: CDC like kinase 3
  • ClpX: encoding enzyme ATP-dependent Clp protease ATP-binding subunit clpX-like, mitochondrial
  • COMMD4: encoding protein COMM domain-containing protein 4
  • CPEB1: Cytoplasmic polyladenylation element binding protein 1
  • CRAT37: encoding protein Cervical cancer-associated transcript 37
  • CYP19A1: encoding protein Cytochrome p450 family 19 subfamily a member 1
  • DTWD1:
  • ELL3: encoding protein Elongation factor RNA polymerase II-like 3
  • FAH: fumarylacetoacetate hydrolase (fumarylacetoacetase)
  • FAM214A: encoding protein Protein FAM214A
  • FBN1: fibrillin 1 (Marfan syndrome)
  • FOXB1: encoding protein Forkhead box B1
  • GATM: Glycine aminotransferase, mitochondrial
  • GCHFR: GTP cyclohydrolase 1 feedback regulatory protein
  • GLC1I: encoding protein Glaucoma 1, open angle, i
  • GLCE: D-glucuronyl C5-epimerase
  • GOLGA8H: encoding protein Golgin subfamily A member 8H
  • HDGFRP3:
  • HEXA: hexosaminidase A (alpha polypeptide)(Tay–Sachs disease)
  • HMG20A: encoding protein High mobility group protein 20A
  • IDDM3 encoding protein Insulin dependent diabetes mellitus 3
  • IMP3: encoding protein U3 small nucleolar ribonucleoprotein protein IMP3
  • ITPKA: encoding enzyme Inositol-trisphosphate 3-kinase A
  • IVD: isovaleryl Coenzyme A dehydrogenase
  • KATNBL1: encoding protein KATNBL1
  • KIAA1024: encoding protein Kiaa1024
  • LARP6 encoding protein La-related protein 6 also known as acheron or La ribonucleoprotein domain family member 6 (LARP6),
  • LCMT2: encoding enzyme Leucine carboxyl methyltransferase 2
  • LINC00926 encoding protein Long intergenic non-protein coding RNA 926
  • MESDC2: encoding protein LDLR chaperone MESD
  • MESP1: encoding protein Mesoderm posterior 1 homolog (mouse)
  • MFAP1: encoding protein Microfibrillar-associated protein 1
  • MCPH4: microcephaly, primary autosomal recessive 4
  • MCTP2: encoding protein Multiple c2 domains, transmembrane 2
  • MIR7-2: encoding protein MicroRNA 7-2
  • MIR1282: encoding protein MicroRNA 1282
  • MIR627: encoding protein MicroRNA 627
  • MIR9-3HG: encoding protein MIR9-3 host gene
  • NIPA2: encoding protein Non-imprinted in Prader-Willi/Angelman syndrome region protein 2
  • NUSAP1: encoding protein Nucleolar and spindle associated protein 1
  • OCA2: oculocutaneous albinism II (pink-eye dilution homolog, mouse)
  • PDCD7: encoding protein Programmed cell death protein 7
  • PIF1: encoding protein PIF1 5'-to-3' DNA helicase
  • PIGBOS1: encoding protein Pigb opposite strand 1
  • PLA2G4D: encoding protein Phospholipase A2 group IVD
  • PLA2G4E: encoding protein Phospholipase A2 group IVE
  • PML: promyelocytic leukemia protein (involved in t(15,17) with RARalpha, predominant cause of acute promyelocytic leukemia.
  • POTEB: encoding protein POTE ankyrin domain family, member B
  • PTPLAD1: encoding enzyme Protein tyrosine phosphatase-like protein PTPLAD1
  • PYGO1: encoding protein Pygopus homolog 1 (Drosophila)
  • RAD51: RAD51 homolog (RecA homolog, E. coli) (S. cerevisiae)
  • RMDN3: encoding protein Regulator of microtubule dynamics protein 3
  • RNR3: encoding RNA, ribosomal 45S cluster 3
  • RTF1: encoding protein Rtf1, Paf1/RNA polymerase II complex component, homolog (S. cerevisiae)
  • RTFDC1: encoding protein Replication termination factor 2
  • SCAMP2: encoding protein Secretory carrier-associated membrane protein 2
  • SCAMP5: encoding protein Secretory carrier-associated membrane protein 5
  • SCZD10: encoding protein Schizophrenia disorder 10 (periodic catatonia)
  • SCAPER: S-phase CyclinA Associated Protein residing in the Endoplasmic Reticulum
  • SENP8: encoding enzyme Sentrin-specific protease 8
  • SERF2: encoding protein Small EDRK-rich factor 2
  • SLC24A5: the gene responsible for at least 1/3 of the skin color differences between races, expressed in the brain and the nervous system
  • SNAPC5: encoding protein snRNA-activating protein complex subunit 5
  • SPN1: encoding protein Snurportin1
  • STRC: stereocilin
  • SUHW4: encoding protein Zinc finger protein 280D
  • SYNM: encoding protein Synemin
  • TEX9: encoding protein Testis-expressed protein 9
  • TGFBR2: location 3p24.2-p25 due to a inactivation mutation
  • TMC3: encoding protein Transmembrane channel like 3
  • TM6SF1: encoding protein Transmembrane 6 superfamily member 1
  • TMCO5A: encoding protein Transmembrane and coiled-coil domains 5A
  • TMED3: encoding protein Transmembrane p24 trafficking protein 3
  • UBE2Q2: encoding protein Ubiquitin conjugating enzyme e2 q2
  • UBE3A: ubiquitin protein ligase E3A (human papilloma virus E6-associated protein, Angelman syndrome)
  • Ube3a-ATS:
  • UNC13C: encoding protein Unc-13 homolog C
  • VPS39: encoding protein hVam6p/Vps39-like protein
  • WDR76: encoding protein Wd repeat domain 76
  • ZNF592: encoding protein Zinc finger protein 592

Chromosomal conditions

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The following conditions are caused by mutations in chromosome 15. Two of the conditions (Angelman syndrome and Prader–Willi syndrome) involve a loss of gene activity in the same part of chromosome 15, the 15q11.2-q13.1 region. This discovery provided the first evidence in humans that something beyond genes could determine how the genes are expressed.[11]

Angelman syndrome

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The main characteristics of Angelman syndrome are severe intellectual disability, ataxia, lack of speech, and excessively happy demeanor. Angelman syndrome results from a loss of gene activity in a specific part of chromosome 15, the 15q11-q13 region. This region contains a gene called UBE3A that, when mutated or absent, likely causes the characteristic features of this condition. People normally have two copies of the UBE3A gene, one from each parent. Both copies of this gene are active in many of the body's tissues. In the brain, however, only the copy inherited from a person's mother (the maternal copy) is active. If the maternal copy is lost because of a chromosomal change or a gene mutation, a person will have no working copies of the UBE3A gene in the brain.

In most cases (about 70%)[citation needed], people with Angelman syndrome have a deletion in the maternal copy of chromosome 15. This chromosomal change deletes the region of chromosome 15 that includes the UBE3A gene. Because the copy of the UBE3A gene inherited from a person's father (the paternal copy) is normally inactive in the brain, a deletion in the maternal chromosome 15 results in no active copies of the UBE3A gene in the brain.

In 3% to 7% of cases,[citation needed] Angelman syndrome occurs when a person has two copies of the paternal chromosome 15 instead of one copy from each parent. This phenomenon is called paternal uniparental disomy (UPD). People with paternal UPD for chromosome 15 have two copies of the UBE3A gene, but they are both inherited from the father and are therefore inactive in the brain.

About 10% of Angelman syndrome cases are caused by a mutation in the UBE3A gene, and another 3% result from a defect in the DNA region that controls the activation of the UBE3A gene and other genes on the maternal copy of chromosome 15. In a small percentage of cases, Angelman syndrome may be caused by a chromosomal rearrangement called a translocation or by a mutation in a gene other than UBE3A. These genetic changes can abnormally inactivate the UBE3A gene.

Angelman syndrome can be hereditary, as evidenced by one case where a patient became pregnant with a daughter who also had the condition.[12]

Prader–Willi syndrome

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The main characteristics of this condition include polyphagia (extreme, insatiable appetite), mild to moderate developmental delay, hypogonadism resulting in delayed to no puberty, and hypotonia. Prader-Willi syndrome is caused by the loss of active genes in a specific part of chromosome 15, the 15q11-q13 region. People normally have two copies of this chromosome in each cell, one copy from each parent. Prader–Willi syndrome occurs when the paternal copy is partly or entirely missing.

In about 70% of cases,[citation needed] Prader–Willi syndrome occurs when the 15q11-q13 region of the paternal chromosome 15 is deleted. The genes in this region are normally active on the paternal copy of the chromosome and are inactive on the maternal copy. Therefore, a person with a deletion in the paternal chromosome 15 will have no active genes in this region.

In about 25% of cases, a person with Prader–Willi syndrome has two maternal copies of chromosome 15 in each cell instead of one copy from each parent. This phenomenon is called maternal uniparental disomy. Because some genes are normally active only on the paternal copy of this chromosome, a person with two maternal copies of chromosome 15 will have no active copies of these genes.

In a small percentage of cases, Prader–Willi syndrome is not caused by a chromosomal rearrangement called a translocation. Rarely, the condition is caused by an abnormality in the DNA region that controls the activity of genes on the paternal chromosome 15. Because patients almost always have difficulty reproducing, Prader–Willi syndrome is generally not hereditary.

Isodicentric chromosome 15

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A specific chromosomal change called an isodicentric chromosome 15 (IDIC15) (also known by a number of other names) can affect growth and development. The patient possesses an "extra" or "marker" chromosome. This small extra chromosome is made up of genetic material from chromosome 15 that has been abnormally duplicated (copied) and attached end-to-end. In some cases, the extra chromosome is very small and has no effect on a person's health. A larger isodicentric chromosome 15 can result in weak muscle tone (hypotonia), intellectual disability, seizures, and behavioral problems.[13] Signs and symptoms of autism (a developmental disorder that affects communication and social interaction) have also been associated with the presence of an isodicentric chromosome 15.

Other chromosomal conditions

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Other changes in the number or structure of chromosome 15 can cause developmental delays, delayed growth and development, hypotonia, and characteristic facial features.[citation needed] These changes include an extra copy of part of chromosome 15 in each cell (partial trisomy 15) or a missing segment of the chromosome in each cell (partial monosomy 15). In some cases, several of the chromosome's DNA building blocks (nucleotides) are deleted or duplicated.

The following diseases are some of those related to genes on chromosome 15:[citation needed]

Cytogenetic band

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G-banding ideograms of human chromosome 15
G-banding ideogram of human chromosome 15 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).
G-banding patterns of human chromosome 15 in three different resolutions (400,[15] 550[16] and 850[3]). Band length in this diagram is based on the ideograms from ISCN (2013).[17] This type of ideogram represents actual relative band length observed under a microscope at the different moments during the mitotic process.[18]
G-bands of human chromosome 15 in resolution 850 bphs[3]
Chr. Arm[19] Band[20] ISCN
start[21]
ISCN
stop[21]
Basepair
start
Basepair
stop
Stain[22] Density
15 p 13 0 270 1 4,200,000 gvar
15 p 12 270 631 4,200,001 9,700,000 stalk
15 p 11.2 631 1142 9,700,001 17,500,000 gvar
15 p 11.1 1142 1382 17,500,001 19,000,000 acen
15 q 11.1 1382 1487 19,000,001 20,500,000 acen
15 q 11.2 1487 1773 20,500,001 25,500,000 gneg
15 q 12 1773 1968 25,500,001 27,800,000 gpos 50
15 q 13.1 1968 2164 27,800,001 30,000,000 gneg
15 q 13.2 2164 2284 30,000,001 30,900,000 gpos 50
15 q 13.3 2284 2524 30,900,001 33,400,000 gneg
15 q 14 2524 2765 33,400,001 39,800,000 gpos 75
15 q 15.1 2765 2975 39,800,001 42,500,000 gneg
15 q 15.2 2975 3065 42,500,001 43,300,000 gpos 25
15 q 15.3 3065 3245 43,300,001 44,500,000 gneg
15 q 21.1 3245 3471 44,500,001 49,200,000 gpos 75
15 q 21.2 3471 3621 49,200,001 52,600,000 gneg
15 q 21.3 3621 3846 52,600,001 58,800,000 gpos 75
15 q 22.1 3846 3982 58,800,001 59,000,000 gneg
15 q 22.2 3982 4087 59,000,001 63,400,000 gpos 25
15 q 22.31 4087 4252 63,400,001 66,900,000 gneg
15 q 22.32 4252 4357 66,900,001 67,000,000 gpos 25
15 q 22.33 4357 4507 67,000,001 67,200,000 gneg
15 q 23 4507 4613 67,200,001 72,400,000 gpos 25
15 q 24.1 4613 4748 72,400,001 74,900,000 gneg
15 q 24.2 4748 4808 74,900,001 76,300,000 gpos 25
15 q 24.3 4808 4928 76,300,001 78,000,000 gneg
15 q 25.1 4928 5048 78,000,001 81,400,000 gpos 50
15 q 25.2 5048 5169 81,400,001 84,700,000 gneg
15 q 25.3 5169 5379 84,700,001 88,500,000 gpos 50
15 q 26.1 5379 5649 88,500,001 93,800,000 gneg
15 q 26.2 5649 5860 93,800,001 98,000,000 gpos 50
15 q 26.3 5860 6070 98,000,001 101,991,189 gneg

References

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Specific references:

  1. ^ a b "Search results – 15[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.
  2. ^ Tom Strachan; Andrew Read (2 April 2010). Human Molecular Genetics. Garland Science. p. 45. ISBN 978-1-136-84407-2.
  3. ^ a b c Genome Decoration Page, NCBI. Ideogram data for Homo sapience (850 bphs, Assembly GRCh38.p3). Last update 2014-06-03. Retrieved 2017-04-26.
  4. ^ 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.
  5. ^ "Statistics & Downloads for chromosome 15". HUGO Gene Nomenclature Committee. 2017-05-12. Archived from the original on 2017-06-29. Retrieved 2017-05-19.
  6. ^ "Chromosome 15: Chromosome summary – Homo sapiens". Ensembl Release 88. 2017-03-29. Retrieved 2017-05-19.
  7. ^ "Human chromosome 15: entries, gene names and cross-references to MIM". UniProt. 2018-02-28. Retrieved 2018-03-16.
  8. ^ "Search results – 15[CHR] AND "Homo sapiens"[Organism] AND ("genetype protein coding"[Properties] AND alive[prop]) – Gene". NCBI. 2017-05-19. Retrieved 2017-05-20.
  9. ^ "Search results – 15[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.
  10. ^ "Search results – 15[CHR] AND "Homo sapiens"[Organism] AND ("genetype pseudo"[Properties] AND alive[prop]) – Gene". NCBI. 2017-05-19. Retrieved 2017-05-20.
  11. ^ "Teacher's Guide". Ghost in Your Genes (season 35). Nova (TV series). October 16, 2007. Retrieved 2009-09-26. The program...recounts how one scientist determined how the deletion of a key sequence of DNA on human chromosome 15 could lead to two different syndromes depending on whether the deletion originated from the mother or the father [and] explains that this was the first human evidence that something other than genes themselves could determine how genes are expressed.
  12. ^ Lossie A, Driscoll D (1999). "Transmission of Angelman syndrome by an affected mother". Genet Med. 1 (6): 262–6. doi:10.1097/00125817-199909000-00004. PMID 11258627.
  13. ^ "What is Dup15q Syndrome? – Dup15q". www.dup15q.org. Archived from the original on 2017-09-06. Retrieved 2017-09-05.
  14. ^ "Photic Sneeze Reflex | AncestryDNA® Traits Learning Hub". www.ancestry.com. Retrieved 2022-02-22.
  15. ^ Genome Decoration Page, NCBI. Ideogram data for Homo sapience (400 bphs, Assembly GRCh38.p3). Last update 2014-03-04. Retrieved 2017-04-26.
  16. ^ Genome Decoration Page, NCBI. Ideogram data for Homo sapience (550 bphs, Assembly GRCh38.p3). Last update 2015-08-11. Retrieved 2017-04-26.
  17. ^ 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.
  18. ^ Sethakulvichai, W.; Manitpornsut, S.; Wiboonrat, M.; Lilakiatsakun, W.; Assawamakin, A.; Tongsima, S. (2012). "Estimation of band level resolutions of human chromosome images". 2012 Ninth International Conference on Computer Science and Software Engineering (JCSSE). pp. 276–282. doi:10.1109/JCSSE.2012.6261965. ISBN 978-1-4673-1921-8. S2CID 16666470.
  19. ^ "p": Short arm; "q": Long arm.
  20. ^ For cytogenetic banding nomenclature, see article locus.
  21. ^ a b 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.
  22. ^ 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.

General references:

[edit]
  • National Institutes of Health. "Chromosome 15". Genetics Home Reference. Archived from the original on August 3, 2004. Retrieved 2017-05-06.
  • "Chromosome 15". Human Genome Project Information Archive 1990–2003. Retrieved 2017-05-06.