Tsix

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TSIX
Identifiers
Aliases TSIX , LINC00013, NCRNA00013, XIST-AS, XIST-AS1, XISTAS, Tsix, TSIX transcript, XIST antisense RNA
External IDs OMIM: 300181 GeneCards: TSIX
Orthologs
SpeciesHumanMouse
Entrez
Ensembl
UniProt
RefSeq (mRNA)

n/a

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RefSeq (protein)

n/a

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Location (UCSC) Chr X: 73.79 – 73.83 Mb n/a
PubMed search [2] n/a
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Simplified flowchart of Tsix's role in Xist gene function Tsix flowchart.PNG
Simplified flowchart of Tsix's role in Xist gene function

Tsix is a non-coding RNA gene that is antisense to the Xist RNA. Tsix binds Xist during X chromosome inactivation. The name Tsix comes from the reverse of Xist, which stands for X-inactive specific transcript. [3]

Contents

Background

Female mammals have two X chromosomes and males have one X and one Y chromosome. The X chromosome has many active genes. This leads to dosage compensation problems: the two X chromosomes in the female will create twice as many gene products as the one X in the male. To mitigate this, one of the X chromosomes is inactivated in females, so that each sex only has one set of X chromosome genes. The inactive X chromosome in cells of females is visible as a Barr body under the microscope. Males do not have Barr bodies, as they only have one X chromosome. [3]

Xist is only expressed from the future inactive X chromosome in females and is able to "coat" the chromosome from which it was produced. Many copies of Xist RNA bind the future inactivated X chromosome. Tsix prevents the accumulation of Xist on the future active female X chromosome to maintain the active euchromatin state of the chosen chromosome. [3] [4]

Function in mammals

In the extra-embryonic lineage in mice and some other mammals, all female individuals have two X chromosomes. However, during embryonic development, an X chromosome is deactivated, while the other X chromosome is left untouched, in a process called imprinted X-inactivation. Xist inactivates an X chromosome at random in female mice by condensing the chromatin, via histone methylation among other mechanisms that are currently being studied. This inactivation happens at random in each individual cell, allowing for a different X chromosome to be inactivated in each cell. Female mammals are therefore called genetic mosaics, for having two different X chromosomes expressed throughout their body. Tsix binds complementary Xist RNA and renders it non-functional. After binding it, Xist is made inactive through dicer. [4] Thus, Xist does not condense chromatin on the other X chromosome, letting it remain active. This does not occur on the other chromosome, and Xist proceeds to inactivate that chromosome. [5] Tsix also functions to silence transcription of Xist through epigenetic regulation. [4]

Tsix and Xist regulate X chromosome protein production in female mice to prevent early embryonic mortality. [6] X inactivation allows for equal dosage of X-linked genes for both males and females by inactivating the extra X chromosome in the females. [7] Mutation of the maternal Tsix gene can cause over accumulation of Xist on both X chromosomes, silencing both X chromosomes in females and the single X chromosome in male. This can cause early mortality. However, if the paternal Tsix allele is active, it can rescue female embryos from the over-accumulation of Xist. [8]

Mutations

When one allele of Tsix in mice is null, the inactivation is skewed toward the mutant X chromosome. This is due to an accumulation of Xist that is not countered by Tsix, and causes the mutant chromosome to be inactivated. When both alleles of Tsix are null (homozygous mutant), the results are low fertility, lower proportion of female births and a reversion to random X inactivation rather than gene imprinting. [9]

Regulation in cell differentiation

In development, X chromosome inactivation is a part of cellular differentiation. This is accomplished by normal Xist function. To confer pluripotency in an embryonic stem cell, factors inhibit Xist transcription. These factors also upregulate transcription of Tsix, which serves to inhibit Xist further. This cell is then able to remain pluripotent as X inactivation is not accomplished. [10]

The marker Rex1, as well as other members of the pluripotency network, are recruited to the Tsix promoter and transcription elongation of Tsix occurs. [10] Along with Tsix and other proteins, factor PRDM14 has been shown to be necessary for the return to pluripotency. Assisted by Tsix, PRDM14 can associate with Xist and remove the inactivation of an X chromosome. [11]

Tsix in humans

X chromosome inactivation is random in human females, and imprinting does not occur. The deletion of a CpG island, a site involved in epigenetic regulation, in the human Tsix gene prevents Tsix from imprinting on the X chromosomes. Instead, the human Tsix chromosome is coexpressed with the human Xist gene on the inactivated X chromosome, indicating that it does not play an important role in random X chromosome inactivation. [12] An autosome may be a more likely candidate for regulating this process in humans. The presence of Tsix in humans may be an evolutionary vestige, a sequence that no longer has a function in humans. Alternately, it may be necessary to study cells closer to the X inactivation stage rather than older cells in order to accurately locate Tsix expression and function. [5]

See also

Related Research Articles

Genomic imprinting is an epigenetic phenomenon that causes genes to be expressed or not, depending on whether they are inherited from the mother or the father. Genes can also be partially imprinted. Partial imprinting occurs when alleles from both parents are differently expressed rather than complete expression and complete suppression of one parent's allele. Forms of genomic imprinting have been demonstrated in fungi, plants and animals. In 2014, there were about 150 imprinted genes known in mice and about half that in humans. As of 2019, 260 imprinted genes have been reported in mice and 228 in humans.

<span class="mw-page-title-main">Barr body</span> Form taken by the inactive X chromosome in a female somatic cell

A Barr body or X-chromatin is an inactive X chromosome. In species with XY sex-determination, females typically have two X chromosomes, and one is rendered inactive in a process called lyonization. Errors in chromosome separation can also result in male and female individuals with extra X chromosomes. The Lyon hypothesis states that in cells with multiple X chromosomes, all but one are inactivated early in embryonic development in mammals. The X chromosomes that become inactivated are chosen randomly, except in marsupials and in some extra-embryonic tissues of some placental mammals, in which the X chromosome from the sperm is always deactivated.

<span class="mw-page-title-main">Non-Mendelian inheritance</span> Type of pattern of inheritance

Non-Mendelian inheritance is any pattern in which traits do not segregate in accordance with Mendel's laws. These laws describe the inheritance of traits linked to single genes on chromosomes in the nucleus. In Mendelian inheritance, each parent contributes one of two possible alleles for a trait. If the genotypes of both parents in a genetic cross are known, Mendel's laws can be used to determine the distribution of phenotypes expected for the population of offspring. There are several situations in which the proportions of phenotypes observed in the progeny do not match the predicted values.

<span class="mw-page-title-main">Sex-chromosome dosage compensation</span>

Dosage compensation is the process by which organisms equalize the expression of genes between members of different biological sexes. Across species, different sexes are often characterized by different types and numbers of sex chromosomes. In order to neutralize the large difference in gene dosage produced by differing numbers of sex chromosomes among the sexes, various evolutionary branches have acquired various methods to equalize gene expression among the sexes. Because sex chromosomes contain different numbers of genes, different species of organisms have developed different mechanisms to cope with this inequality. Replicating the actual gene is impossible; thus organisms instead equalize the expression from each gene. For example, in humans, female (XX) cells randomly silence the transcription of one X chromosome, and transcribe all information from the other, expressed X chromosome. Thus, human females have the same number of expressed X-linked genes per cell as do human males (XY), both sexes having essentially one X chromosome per cell, from which to transcribe and express genes.

<span class="mw-page-title-main">X-inactivation</span> Inactivation of copies of X chromosome

X-inactivation is a process by which one of the copies of the X chromosome is inactivated in therian female mammals. The inactive X chromosome is silenced by being packaged into a transcriptionally inactive structure called heterochromatin. As nearly all female mammals have two X chromosomes, X-inactivation prevents them from having twice as many X chromosome gene products as males, who only possess a single copy of the X chromosome.

<span class="mw-page-title-main">Homeobox protein NANOG</span> Mammalian protein found in humans

Homeobox protein NANOG(hNanog) is a transcriptional factor that helps embryonic stem cells (ESCs) maintain pluripotency by suppressing cell determination factors. hNanog is encoded in humans by the NANOG gene. Several types of cancer are associated with NANOG.

<span class="mw-page-title-main">ATR-X syndrome</span> Medical condition

Alpha-thalassemia mental retardation syndrome (ATRX), also called alpha-thalassemia X-linked intellectual disability syndrome, nondeletion type or ATR-X syndrome, is an X-linked recessive condition associated with a mutation in the ATRX gene. Males with this condition tend to be moderately intellectually disabled and have physical characteristics including coarse facial features, microcephaly, hypertelorism, a depressed nasal bridge, a tented upper lip and an everted lower lip. Mild or moderate anemia, associated with alpha-thalassemia, is part of the condition. Females with this mutated gene have no specific signs or features, but if they do, they may demonstrate skewed X chromosome inactivation.

Polycomb-group proteins are a family of protein complexes first discovered in fruit flies that can remodel chromatin such that epigenetic silencing of genes takes place. Polycomb-group proteins are well known for silencing Hox genes through modulation of chromatin structure during embryonic development in fruit flies. They derive their name from the fact that the first sign of a decrease in PcG function is often a homeotic transformation of posterior legs towards anterior legs, which have a characteristic comb-like set of bristles.

<span class="mw-page-title-main">H19 (gene)</span> Negative regulation (or limiting) of body weight and cell proliferation

H19 is a gene for a long noncoding RNA, found in humans and elsewhere. H19 has a role in the negative regulation of body weight and cell proliferation. This gene also has a role in the formation of some cancers and in the regulation of gene expression. .

<span class="mw-page-title-main">XIST</span> Non-coding RNA

Xist is a non-coding RNA on the X chromosome of the placental mammals that acts as a major effector of the X-inactivation process. It is a component of the Xic – X-chromosome inactivation centre – along with two other RNA genes and two protein genes.

<span class="mw-page-title-main">CHD8</span> Protein-coding gene in the species Homo sapiens

Chromodomain-helicase-DNA-binding protein 8 is an enzyme that in humans is encoded by the CHD8 gene.

<span class="mw-page-title-main">Long non-coding RNA</span> Non-protein coding transcripts longer than 200 nucleotides

Long non-coding RNAs are a type of RNA, generally defined as transcripts more than 200 nucleotides that are not translated into protein. This arbitrary limit distinguishes long ncRNAs from small non-coding RNAs, such as microRNAs (miRNAs), small interfering RNAs (siRNAs), Piwi-interacting RNAs (piRNAs), small nucleolar RNAs (snoRNAs), and other short RNAs. Long intervening/intergenic noncoding RNAs (lincRNAs) are sequences of lncRNA which do not overlap protein-coding genes.

Skewed X-chromosome inactivation occurs when the X-inactivation of one X chromosome is favored over the other, leading to an uneven number of cells with each chromosome inactivated. It is usually defined as one allele being found on the active X chromosome in over 75% of cells, and extreme skewing is when over 90% of cells have inactivated the same X chromosome. It can be caused by primary nonrandom inactivation, either by chance due to a small cell pool or directed by genes, or by secondary nonrandom inactivation, which occurs by selection.

A knockout mouse, or knock-out mouse, is a genetically modified mouse in which researchers have inactivated, or "knocked out", an existing gene by replacing it or disrupting it with an artificial piece of DNA. They are important animal models for studying the role of genes which have been sequenced but whose functions have not been determined. By causing a specific gene to be inactive in the mouse, and observing any differences from normal behaviour or physiology, researchers can infer its probable function.

Epigenetics of human development is the study of how epigenetics effects human development.

<span class="mw-page-title-main">Polycomb recruitment in X chromosome inactivation</span>

X chromosome inactivation (XCI) is the phenomenon that has been selected during the evolution to balance X-linked gene dosage between XX females and XY males.

Jeannie T. Lee is a Professor of Genetics at Harvard Medical School and the Massachusetts General Hospital, and a Howard Hughes Medical Institute Investigator. She is known for her work on X-chromosome inactivation and for discovering the functions of a new class of epigenetic regulators known as long noncoding RNAs (lncRNAs), including Xist and Tsix.

<span class="mw-page-title-main">Pr/set domain 15</span> Protein-coding gene in humans

PR/SET domain 15 is a protein that in humans is encoded by the PRDM15 gene.

Monoallelic gene expression (MAE) is the phenomenon of the gene expression, when only one of the two gene copies (alleles) is actively expressed (transcribed), while the other is silent. Diploid organisms bear two homologous copies of each chromosome (one from each parent), a gene can be expressed from both chromosomes (biallelic expression) or from only one (monoallelic expression). MAE can be Random monoallelic expression (RME) or Constitutive monoallelic expression (constitutive). Constitutive monoallelic expression occurs from the same specific allele throughout the whole organism or tissue, as a result of genomic imprinting. RME is a broader class of monoallelic expression, which is defined by random allelic choice in somatic cells, so that different cells of the multi-cellular organism express different alleles.

X chromosome reactivation (XCR) is the process by which the inactive X chromosome (the Xi) is re-activated in the cells of eutherian female mammals. Therian female mammalian cells have two X chromosomes, while males have only one, requiring X-chromosome inactivation (XCI) for sex-chromosome dosage compensation. In eutherians, XCI is the random inactivation of one of the X chromosomes, silencing its expression. Much of the scientific knowledge currently known about XCR comes from research limited to mouse models or stem cells.

References

  1. 1 2 3 GRCh38: Ensembl release 89: ENSG00000270641 - Ensembl, May 2017
  2. "Human PubMed Reference:". National Center for Biotechnology Information, U.S. National Library of Medicine.
  3. 1 2 3 Lee JT, Davidow LS, Warshawsky D (1999). "Tsix, a gene antisense to Xist at the X-inactivation centre". Nat. Genet. 21 (4): 400–4. doi:10.1038/7734. PMID   10192391. S2CID   30636065.
  4. 1 2 3 Online Mendelian Inheritance in Man (OMIM): 300181
  5. 1 2 Cobb K (August 17, 2002). "Not a turn-on". Science News. 162 (7): 100–101. doi:10.2307/4013787. JSTOR   4013787.
  6. "Tsix MGI Mouse Gene Detail - MGI:1336196 - X (inactive)-specific transcript, opposite strand". Mouse Genome Informatics. The Jackson Laboratory. 20 March 2013.
  7. Stavropoulos N, Lu N, Lee JT (2001). "A functional role for Tsix transcription in blocking Xist RNA accumulation but not in X-chromosome choice". Proc. Natl. Acad. Sci. U.S.A. 98 (18): 10232–7. Bibcode:2001PNAS...9810232S. doi: 10.1073/pnas.171243598 . PMC   56944 . PMID   11481444.
  8. Sado T, Wang Z, Sasaki H, Li E (2001). "Regulation of imprinted X-chromosome inactivation in mice by Tsix". Development. 128 (8): 1275–86. doi:10.1242/dev.128.8.1275. PMID   11262229.
  9. Lee JT (2002). "Homozygous Tsix mutant mice reveal a sex-ratio distortion and revert to random X-inactivation". Nat. Genet. 32 (1): 195–200. doi:10.1038/ng939. PMID   12145659. S2CID   22497302.
  10. 1 2 Navarro P, Oldfield A, Legoupi J, Festuccia N, Dubois A, Attia M, Schoorlemmer J, Rougeulle C, Chambers I, Avner P (2010). "Molecular coupling of Tsix regulation and pluripotency". Nature. 468 (7322): 457–60. Bibcode:2010Natur.468..457N. doi:10.1038/nature09496. PMID   21085182. S2CID   205222742.
  11. Payer B, Rosenberg M, Yamaji M, Yabuta Y, Koyanagi-Aoi M, Hayashi K, Yamanaka S, Saitou M, Lee JT (2013). "Tsix RNA and the germline factor, PRDM14, link X reactivation and stem cell reprogramming". Mol. Cell. 52 (6): 805–18. doi:10.1016/j.molcel.2013.10.023. PMC   3950835 . PMID   24268575.
  12. Migeon BR (2003). "Is Tsix repression of Xist specific to mouse?". Nat. Genet. 33 (3): 337, author reply 337–8. doi: 10.1038/ng0303-337a . PMID   12610550. S2CID   9658810.