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Wikipedia

H19 (gene)

April 12, 2024

For other uses, see H19 (disambiguation).

H19 is a gene for a long noncoding RNA, found in humans and elsewhere. H19 has a role in the negative regulation (or limiting) of body weight and cell proliferation.[3] This gene also has a role in the formation of some cancers and in the regulation of gene expression.[4]

H19
Identifiers
AliasesH19, BWS, LINC00008, ASM1, NCRNA00008, imprinted maternally expressed transcript, D11S813E, MIR675HG, imprinted maternally expressed transcript (non-protein coding), H19 imprinted maternally expressed transcript, WT2, PRO2605, ASM
External IDsOMIM: 103280 GeneCards: H19
Orthologs
SpeciesHumanMouse
Entrez

283120

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Ensembl

ENSG00000130600
ENSG00000288237

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UniProt

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RefSeq (mRNA)

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RefSeq (protein)

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Location (UCSC)Chr 11: 2 – 2 Mbn/a
PubMed search[2]n/a
Wikidata
View/Edit Human

The H19 gene is expressed exclusively on one parental allele in a phenomenon known as imprinting.[5] H19 is only transcribed from the maternally inherited allele; the paternal H19 allele is not expressed.[6] H19 was first named ASM (for Adult Skeletal Muscle) because of its expression in adult skeletal muscle ("ASM") in rats.[7] H19 is also known as BWS because aberrant H19 expression can be involved in Beckwith-Wiedemann Syndrome ("BWS"), as well as Silver-Russell syndrome.[8] Epigenetics deregulations at H19 imprinted gene in sperm have been observed associated with male infertility.[9]

Gene characterization edit

The H19 gene contains 3 Sp1 binding sites, however these 3 sites are present in a part of the sequence that has shown no transcriptional activity in deletion assays.[10] As a result, these Sp1 binding sites are not expected to contribute much to the regulation of H19 gene transcription. The H19 gene sequence also contains binding sites for the C/EBP family of transcription factors.[10] One of these C/EBP transcription factor binding sites also contains a CpG site.[10] In vitro methylation of this CpG site on a DNA construct strongly inhibited transcription of the H19 gene.[10]

In cell lines derived from human choriocarcinomas, Kopf et al. found that transcription of H19 was under the simultaneous control of both a 5’ upstream and a 3’ downstream region.[11] Kopf et al. have suggested that this simultaneous and bidirectional regulation of H19 may involve a member of the AP2 transcription factor family.[11]

H19 gene transcription has also been shown to be activated by the presence of the E2F1 transcription factor.[12][13]

RNA product edit

The H19 gene codes for a 2.3 kb RNA product.[14] It is transcribed by RNA polymerase II, spliced and polyadenylated, but it does not appear to be translated.[15]

After many studies, researchers finally concluded that the end product of the H19 gene is a RNA strand for the following reasons:

  • The H19 RNA product is evolutionarily conserved at the nucleotide level in humans and rodents[16]
  • There is no known open reading frame; the H19 mRNA contains stop codons in all 3 reading frames [15]
  • The cDNA version of the human H19 does not contain the short introns that are characteristic of imprinted genes [16]
  • Although the RNA sequence was highly conserved evolutionarily, at the amino acid level, there was a complete absence of conservation [16]
  • Free energy (thermodynamics) analysis of the H19 RNA sequence revealed a multitude of possible secondary RNA structures, including 16 helices and various hairpin loops [16]
  • In situ hybridization of the H19 RNA revealed that it localizes in a cytoplasmic ribonucleoprotein particle, leading some to suggest that the H19 RNA functions as a riboregulator.[17]

Loss of function and overexpression experiments on H19 have revealed two things:

  1. Loss of H19 is not lethal in mice[18]
  2. Overexpression of H19 is a dominant and lethal mutation[14]

Mice with a loss of H19 function express an overgrowth phenotype similar to babies with BWS.[18] This has led researchers to suggest that perhaps the only function of H19 RNA expression is to regulate the expression of IGF2 (Insulin Growth Factor 2).[18] Overexpression of IGF2 can be responsible for overgrowth, and generally, IGF2 is expressed in the absence of H19. Mouse embryos overexpressing H19 tend to die between embryonic day 14 and birth.[14] Brunkow et al. have suggested two reasons for the lethality of H19 overexpression in embryonic mice:

  1. The overexpression of H19 in tissues where it is normally expressed (e.g., liver and gut) caused its lethal effects[14]
    • This implies that H19 gene dosage is under strict control in the fetus
  2. The expression of H19 in tissues where it is normally not expressed (e.g., brain) caused its lethal effects[14]

Expression timeline edit

In the early placentae (6–8 weeks gestation), both parental H19 alleles (maternal and paternal) are expressed.[19][20]

After 10 weeks gestation and in full term placentae, there is exclusive expression of H19 from the maternal chromosome.[19][20] In the embryo, maternal expression of H19 is present in endodermal and mesodermal tissues.[14] The regulated expression of H19, from biallelic to monoallelic, throughout embryonic development suggests that regulation is essential for the growth of embryonic and extraembryonic tissues.[19] Immediately after birth, H19 expression is downregulated in all tissues except for skeletal muscle.[14]

Studies by Tanos et al. suggest that the accumulation of H19 RNA in skeletal muscle cells is solely due to the stabilization of that RNA in the muscle cells during differentiation.[21]

In females, H19 is expressed postnatally during puberty and pregnancy in the mammary glands, and in the uterus during pregnancy.[22]

A study by Shoshani et al. suggests that H19 is continued to be expressed in high amounts in the liver after birth, specifically in diploid hepatocytes.[23]

Epigenetics edit

Genomic imprinting is surmised to have arisen due to the conflicting interests of maternal and paternal genes within a pregnancy.[24]

Within a pregnancy, the father wants the mother to devote as much of her resources as possible towards the growth (benefit) of his offspring.[24] However, within the same pregnancy, the mother wants to conserve as much of her resources as possible towards future births without compromising the health of the child(ren) she is currently carrying.[24]

H19 contains a differentially methylated region that is also an imprinting control region. This imprinting control region is differentially methylated at its CpGs according to parental inheritance. Usually, the paternal copy of H19 is methylated and silent while the maternal copy is hypomethylated or unmethylated and expressed in the offspring cell. Methylation of the H19 promoter is negatively correlated with H19 expression.[25]

As methylation of the promoter reaches 100%, H19 expression from that promoter approaches 0.[25] At the same time as H19 expression decreases, the expression of IGF2, a neighboring gene on chromosome 11, increases.[25]

Cells treated with Azad, a demethylating agent, grow much slower than cells cultured in the absence of Azad.[25] At the same time, H19 expression increases while IGF2 expression decreases in the presence of Azad.[25] The reduction of IGF2 expression could be a reason for the slower growth of cells treated with Azad. As well, in a mouse bladder carcinoma cell line, where transfection of a human H19 DNA construct results in high expression of H19, the methylation of the H19 promoter reduces H19 expression.[20] The paternal H19 allele, which is silent postnatally, shows increasing methylation of CpGs in its promoter with gestation time in the fetus.[20] It appears conclusive that the H19 gene is epigenetically controlled via methylation, where methylation on or near the vicinity of one allele prevents the expression of that allele. As well, based on the results from Banet et al., it appears that functional H19 imprinting occurs during early placenta development.[20]

In addition, methylation loss at H19 imprinted gene has been observed associated with MTHFR gene promoter hypermethylation in semen samples from infertile males.[9] Similarly, the CTCF-binding site 6 region of H19 can also be hypomethylated with MTHFR gene promoter hypermethylation.[9]

Replication edit

A common characteristic of imprinted genes is asynchronous replication during the DNA synthesis phase of the mitotic cycle.[16] The replication of two alleles of the same gene can differ according to which parent the allele originated from.[16] On the human chromosome 11p15, the methylated paternal H19 allele replicates early in the S phase while the hypomethylated maternal allele replicates later.[16] Studies by Bergstrom et al. have determined that the later-replicating maternal H19 allele is CTCF-bound, and that it is this CTCF binding that determines the time of H19 replication.[16]

As an oncogene edit

Evidence for the identification of H19 as an oncogene:

  • Overexpression of H19 appears to be important in the development of esophageal and colorectal cancer cells[26]
  • Cells expressing H19 are able to form bigger colonies in soft agar in anchorage-independent growth assays as compared to the control.[27]
  • Downregulation of H19 in breast and lung cancer cells decreases their clonogenicity and anchorage-dependent growth[28]
  • Subcutaneous injection of H19 into mice promoted tumor progression[27]
  • Tumors formed by injection of bladder carcinoma cells into mice express H19; prior to the injection, these bladder carcinoma cells did not express H19.[29]
  • Ectopic H19 expression in vivo enhances the tumorigenic potential of carcinoma cells[30]
  • c-Myc, an oncogene that functions as a regulator of gene transcription, induces H19 expression[28]
  • Knocking down H19 in hypoxic stress diminishes p57 induction[30]

Evidence against the identification of H19 as an oncogene:

  • The amount of H19 RNA transfected into breast cancer cells did not affect: cell proliferation, cell cycle timing or anchorage-dependent growth[27]
  • Tumorigenic mesenchymal stem cells express high levels of H19 compared with non-tumorigenic mesenchymal stem cells. Knock-down of H19 in the tumorigenic cells reduced their tumor forming capacity significantly[23]

As an oncofetal RNA gene edit

Definition of an oncofetal gene:

  • A gene expressed in tumors arising from tissues that express this gene in fetal life[31]

H19, while possessing oncogenic properties, is best defined as an oncofetal RNA gene because:

  • The final product of the H19 gene is RNA[31]
  • H19 is highly expressed prenatally and downregulated postnatally[19]
  • Postnatally, H19 is expressed at high levels in cancer cells[14]

Role in cancer edit

Increased H19 expression is found in the following cancers: adrenocortical neoplasms, choriocarcinomas, hepatocellular carcinomas, bladder cancers, ovarian serous epithelial cancers, head and neck carcinomas, endometrial cancer, breast cancer, acute T cell leukemia/lymphoma, Wilms' tumor, testicular germ cell cancer, esophageal cancer and lung cancer.[12][19][20][21][25][32][33][34][35]

Genome instability edit

Main article: Genome instability

Cellular DNA integrity is often compromised in cancer. Genome instability can refer to the accumulation of extra copies of DNA/chromosomes, chromosomal translocations, chromosomal inversion, chromosome deletions, single stranded breaks in DNA, double stranded breaks in DNA, the intercalation of foreign substances into the DNA double helix, or any abnormal changes in DNA tertiary structure that can cause either the loss of DNA, or the misexpression of genes. It appears that H19 expression is tightly linked to the ploidy of the cell. Diploid liver cells express high levels of H19, whereas the polyploid cell fraction do not express H19. Also, diploid mesenchymal stem cells express high levels of H19 compared to polyploid mesenchymal stem cells. Knock-down of H19 lead to increased polyploidization of mesenchymal stem cells, and induced polyploidy resulted in reduced expression of H19, providing a direct link between H19 expression and the amount of DNA within the cell.[23]

Adrenocortical neoplasms edit

In contrast to most other cancers, adrenocortical neoplasms appear to have decreased expression of H19. To determine a possible cause for the downregulation of H19, Gao et al. studied the methylation of 12 CpG sites in the H19 promoter in normal, hyperplasia, adenoma and carcinoma adrenals. They found that in carcinomas, there was more methylation of CpGs than in normal, hyperplasia and adenoma adrenals.[25] Consequently, normal H19 expression was detectable in normal and hyperplasia adrenals, but in carcinomas and surprisingly, adenomas, there was a lower H19 expression that was coupled with detectable (increased) IGF2 expression.[25]

The presence of IGF2 RNA expression when H19 RNA was downregulated provides further evidence that IGF2 expression is tightly coupled to and dependent on the absence of H19 expression. As well, the loss of H19 in adrenal cancers may be indicative of tumor suppressor activity by H19, leading Gao et al. to suggest that the loss of H19 and subsequent gain of IGF2 may be involved in adrenal cancer induction. Although Gao et al. found that there was not one CpG methylation site that was more important than the others in downregulating H19 expression, they did find that the increase in CpG methylation in adrenal carcinomas followed the pattern of methylation of the normal, hyperplasia and adenoma adrenals. The mean percent methylation of H19 CpGs peaked at sites 9 and 10 in normal, hyperplasia, adenoma and carcinoma adrenals and the lowest mean percent methylation of H19 CpGs dipped at site 7 in normal, hyperplasia, adenoma and carcinoma adrenals.

The mean percent methylation of H19 CpGs at sites 13 and 14, after the transcription start site, is insignificant between normal, hyperplasia, adenoma and carcinoma adrenals. This is because methylation of CpGs after the transcription start site is assumed to interfere with RNA polymerase II during transcription. Another point of interest is the significant difference in CpG methylation at site 11 between normal and hyperplasia adrenals. The mean percent CpG methylation at site 11 for hyperplasia and adenoma adrenals is significantly different from that of normal adrenals and carcinoma adrenals, leading Gao et al. to suggest that site 11 is the initial methylated CpG that eventually leads to widespread methylation of the H19 promoter.[25]

Choriocarcinomas edit

Choriocarcinomas, in contrast to adrenal carcinomas, have upregulated H19 and downregulated IGF2 expression.[19] The upregulated H19 expression, however, came from alleles that were fully methylated.[19] Surgically removed choriocarcinomas from human patients also exhibited a heavily methylated H19 promoter with enhanced H19 expression.[19] This led researchers Arima et al. to suggest that in cases of choriocarcinomas, the H19 promoter was mutated, allowing it to overcome the transcriptional repression of promoter CpG methylation.

Hepatocellular carcinoma edit

In hepatocellular carcinoma, the expression of H19 and IGF2 usually changes from monoallelic to biallelic.[30] In in vitro studies, culturing hepatocellular carcinoma cell lines in hypoxic condition upregulated H19 expression.[30] Whether or not the loss of imprinting for the H19 promoter is a characteristic of hepatocellular carcinoma is not known, as some cell lines exhibit loss of imprinting while others did not.

Bladder cancers edit

Bladder mucosa is one of the tissues that express high levels of H19 RNA prenatally.[35] In bladder cancers, H19 is also upregulated and present in most stages.[20] The presence of H19 RNA was strongest in bladder carcinomas (sampled in situ) that tend to progress rapidly to invasive cancer as well as invasive transitional cell carcinomas.[36]

In samples of bladder carcinoma, loss of imprinting at the H19 loci were observed.[29] Verhaugh et al. investigated various polymorphisms in the H19 gene and found that some heterozygous SNP polymorphisms, such as rs2839698 TC, were associated with a decreased risk of developing non-muscle invasive bladder cancer as well as bladder cancer overall; however, this association disappeared for homozygotes (CC).[37]

Endometrial/ovarian cancer edit

In normal endometrial tissue, there is no H19 expression; however, in endometrial cancer, H19 is expressed.[21] The expression level of H19 RNA in the epithelial cells of the endometrium increases as tissue differentiation is lost in endometrial cancer.[21]

In ovarian cancers, 75% of low malignancy tumors and 65% of invasive ovarian carcinomas are H19 RNA positive.[32]

Breast cancer edit

Normal breast tissue does not express H19 RNA, except during puberty and pregnancy in the mammary glands.[38]

However, in breast cancer, 72.5% of the breast adenocarcinomas studied by Adriaenssens et al. displayed increased H19 expression when compared to normal breast tissue. Of the tissues with upregulated H19, 92.2% are stromal cells and only 2.9% are epithelial cells.[38] Studies by Berteaux et al. have also found that the overexpression of H19 in breast cancer cells promotes proliferation.[13] The expression of H19 in these cells is also independent of the tumor suppressor protein p53 and the cell cycle marker Ki-67.[38] However, the presence of tumor suppressor protein pRb and transcription factor E2F6 is sufficient to repress H19 expression in breast cancer cells.[13]

In experiments conducted by Doyle et al., it was found that MCF-7, a breast adenomacarcinoma cell line,[39] did not express the H19 gene; however a subline of MCF-7 with a multidrug resistance phenotype, MCF-7/AdrVp, had upregulation of H19.[34] Curiously, mutant revertant MCF-7/AdrVp cells that lost their multidrug resistance and became drug-sensitive also lost H19 expression.[34] Drug-resistant MCF-AdrVp cells do not overexpress P-glycoprotein, a cell membrane efflux pump commonly found in multidrug resistant cells; instead, they overexpress a 95kD membrane glycoprotein p95.[34] p95, or NCA-90, is related to carcinoembryonic antigens, which have been found to reduce drug toxicity by Kawaharata et al.[40][41]

NCI-H1688, a human lung carcinoma cell line that displays multidrug resistance, also overexpress p95 (NCA-90) and H19.[34] No other cell lines with the multidrug resistance phenotype have been found to overexpress p95 (NCA-90) in conjunction with H19.[34]

Larynx cancer edit

H19 is overexpressed in laryngeal squamous cell carcinomas that relapse as compared to those that do not relapse. In a pilot study aimed at the development of a prognostic classifier for this cancer H19 was the strongest predictor of relapse. It was overexpressed in cancers that later developed local or distant recurrence. Its expression did not correlate with the expression of IGF2 and H19 overexpression is unlikely to be a simple consequence of loss of imprinting of the locus containing H19 and IGF2 [42]

Wilms' tumour edit

Wilms' tumour is a cancer of the kidney that most commonly occurs in childhood. An association with H19 has been reported.[43]

Participation in signaling pathways edit

The exact role of H19 RNA within the cell is currently not known. There are various known substances and conditions that are known to activate H19 transcription and there are various known effects of H19 RNA on cell cycle activity/status, although precisely how H19 RNA exerts these effects is still unknown.

Upstream effectors – hormonal regulation edit

A previous study conducted by Adriaenssens et al. on H19 correlated an overexpression of H19 with the presence of steroid receptors.[22]

Further studies found that 17-β-estradiol, the dominant form of estrogen, and corticosterone were able to individually stimulate H19 transcription in the uterus, while the presence of progesterone inhibited this effect.[22]Tamoxifen is a competitive binder of the estrogen receptor and is often used in chemotherapy treatment of breast cancer. While 17-β-estradiol alone stimulated H19 transcription in MCF-7 cells, the addition of tamoxifen inhibited H19 transcription, demonstrating that there is a putative role of hormones in H19 transcription.[22]

Downstream effects – angiogenesis, metabolism, tissue invasion and migration edit

When a cancer bladder cell line, T24P, which does not express H19 was transfected with a DNA construct expressing the H19 gene under the control of the cytomegalovirus promoter, many changes were seen in the resulting cells when compared to both the original T24P cell line and a H19-antisense DNA construct transfected T24P cell line. While there was no difference in proliferation in 10% FCS (normal condition) between the 3 cell lines, when grown in 0.1% FCS (starved serum), the H19-transfected cells maintained their rate of growth while both the control and the antisense H19 transfected cells decreased their rate of proliferation by approximately 50%.[44]

When p57 induction in 0.1% FCS media was measured in the 3 cell lines, both the control and antisense H19 transfected cells had significantly upregulated p57; however, the H19-transfected cells showed a significant downregulation of p57 in 0.1% FCS as compared to 10% FCS.[44] In addition, while the expression of PCNA, required for progression of the cell cycle beyond the S phase, was significantly downregulated in all 3 cell lines, the reduction was approximately 80%-90% in the control and antisense H19 transfected cells and only 30% in the H19 transfected cells.[44]

An examination of the differences in gene expressed between the H19 transfected cells and the antisense H19 transfected cells showed that the following genes were upregulated: uPar, c-src kinase, tyrosine kinase 2 mitogen-activated protein kinase kinase, tyrosine kinase 2, c-jun, JNK1, Janus kinase 1, TNF-a, interleukin-6, heparin-binding growth factor-like growth factor, intracellular adhesion molecule 1, NF-κB, ephrin A4 and ezrin.[44] It is also suggested that angiogenin and FGF18 may be potential transcriptional targets of the H19 RNA.[30] As a result of the functions and signaling pathways that H19 RNA-upregulated genes are involved in, it has been suggested that H19 RNA plays crucial roles in tissue invasion, migration and angiogenesis in tumorigenesis.[44]

Lottin et al. also found that the overexpression of H19 positively regulates post-transcriptionally thioredoxin.[45] Thioredoxin is a protein crucial to the reduction-oxidation reactions involved in metabolism within a cell, and is often found at high levels in cancerous tissues that also overexpress H19 RNA.[45]

IGF2 edit

H19 and IGF2 expression are closely linked, as they are expressed in the same tissues during fetal development, albeit from differing parental alleles.[18]

This coupled expression is only lost in cases of loss of imprinting (inherited CpG methylated) or promoter mutation.[46]

The hypermethylation of the H19 promoter on the paternal allele plays a vital role in allowing the expression of the paternal allele of IGF2.[25] In DNMT-null mice, the paternal allele of IGF2 is also silenced as the paternal H19 promoter is no longer methylated and repressed.[18] A reason for the close coupling of H19 and IGF2 expression may be that they share the same 3’ gene enhancer.[18] When this 3’ enhancer was deleted, researchers Leighton et al. found decreased H19 and IGF2 RNA expressions in the gut, liver and kidney; however, the methylation status of these genes were not affected by the deleted enhancer.[18] Suggestions for why H19 is preferentially activated by the 3’ enhancer instead of IGF2 are that H19 has a stronger promoter than IGF2 and that the H19 gene is physically closer to the 3’ enhancers than the IGF2 gene.[47]

It is of interest to note that mice inheriting a deleted maternal H19 and a deleted paternal IGF2 gene were indistinguishable from wildtype mice in birth weight and postnatal growth.[47] Mice inheriting only a deleted maternal H19 gene, however, displayed somatic overgrowth while mice inheriting only a deleted paternal IGF2 gene displayed somatic undergrowth when compared to wildtype mice.[47] This indicates that the loss of H19 is not lethal, H19 expression governs IGF2 repression, and the overexpression of IGF2 is responsible for the overgrowth phenotype observed in the maternal inheritance of a deleted H19 gene.[47]

Cancer therapy edit

While the functions of the H19 RNA in the cell are still unclear, its presence in the many types of carcinoma cells suggest that it can be used as a tumor marker for initial diagnosis, cancer recurrence and malignant potential.[21][36][48]

Gene therapy edit

The activation of the H19 promoter in cancerous cells (and its silence in normal tissues) has led to the suggestion of using the H19 promoter in gene therapy to drive the expression of cytotoxic genes in tumorigenic cells.[20] Gene therapy trials utilizing the H19 promoter to drive the expression of cytotoxic genes are currently being tested on mice.[20]

Drug discovery edit

A plasmid composed of the H19 gene regulatory sequences that drive the expression of the 'A' strand of Diphtheria Toxin (DT-A), is undergoing clinical testing as a treatment for superficial bladder cancer,[49] ovarian cancer[50] and pancreatic cancer.[51] The plasmid, designated BC-819 (or DTA-H19), embodies a targeted therapy approach, in that the plasmid enters all dividing cells, but the DT-A expression is triggered by the presence of H19 transcription factors found only in tumor cells, thus destroying the tumor without affecting normal cells.

In a double-center, dose escalation Phase I/IIa clinical trial of BC-819 as a treatment for superficial bladder cancer,[52] no severe adverse events related to the plasmid were detected, and tumor responses were observed in more than 70% of patients, including those with a still not-optimized therapeutic dose and regimen.

BC-819 was previously tested in human compassionate use for the treatment of superficial bladder cancer, ovarian cancer and metastatic liver cancer. The bladder cancer patient, who was a candidate for radical cystectomy when he was treated in 2004, reported no cancer recurrence and no side effects.[52] The ovarian cancer patient experienced a 50% decline in the amount of the ovarian cancer marker protein CA-125 in her blood as well as a significant decrease in the number of cancerous cells in her ascitic fluid. The patient suffering from metastatic liver cancer was treated with direct injection of BC-819 into the tumor, with considerable tumor necrosis observed.

Pharmacogenomics edit

While the expression profile of H19 in most cancer types is known, the role of H19 RNA in influencing cancer cell response to drug treatment is still unknown. However, recent studies have discovered the expression of thioredoxin and p95 (NCA-90) in cancer cells when H19 RNA is present in high quantities.[34][45] This knowledge can lead to a more personalized cancer treatment plan; for example, the expression of p95 in a H19-overexpressing cancer cell may indicate higher tolerance of drug toxicity, so cancer treatment for an individual with high levels of H19 (and p95) may focus more on radiotherapy or immunotherapy instead of chemotherapy.

Immunotherapy edit

It is not currently known if H19 expression can be used to induce an anti-cancer response in immune cells.

References edit

  1. ^ a b c ENSG00000288237 GRCh38: Ensembl release 89: ENSG00000130600, ENSG00000288237 - Ensembl, May 2017
  2. ^ "Human PubMed Reference:". National Center for Biotechnology Information, U.S. National Library of Medicine.
  3. ^ Gabory, et al. (2009). "H19 acts as a trans regulator of the imprinted gene network controlling growth in mice" (PDF). Development. 136 (20): 3413–3421. doi:10.1242/dev.036061. PMID 19762426.
  4. ^ "H19: imprinted maternally expressed transcript (non-protein coding) (Homo sapiens)". Entrez Gene. National Center for Biotechnology Information. Retrieved 2008-06-06.
  5. ^ Zhang Y, Tycko B (April 1992). "Monoallelic expression of the human H19 gene". Nat. Genet. 1 (1): 40–44. doi:10.1038/ng0492-40. PMID 1363808. S2CID 35338859.
  6. ^ Rachmilewitz J, Goshen R, Ariel I, Schneider T, de Groot N, Hochberg A (August 1992). "Parental imprinting of the human H19 gene". FEBS Lett. 309 (1): 25–28. doi:10.1016/0014-5793(92)80731-U. PMID 1380925. S2CID 22194553.
  7. ^ Leibovitch MP, Nguyen VC, Gross MS, Solhonne B, Leibovitch SA, Bernheim A (November 1991). "The human ASM (adult skeletal muscle) gene: expression and chromosomal assignment to 11p15". Biochem. Biophys. Res. Commun. 180 (3): 1241–1250. doi:10.1016/S0006-291X(05)81329-4. PMID 1953776.
  8. ^ Online Mendelian Inheritance in Man (OMIM): H19 Gene - 103280
  9. ^ a b c Rotondo JC, Selvatici R, Di Domenico M, Marci R, Vesce F, Tognon M, Martini F (September 2013). "Methylation loss at H19 imprinted gene correlates with methylenetetrahydrofolate reductase gene promoter hypermethylation in semen samples from infertile males". Epigenetics. 8 (9): 990–997. doi:10.4161/epi.25798. PMC 3883776. PMID 23975186.
  10. ^ a b c d Jinno Y, Ikeda Y, Yun K, Maw M, Masuzaki H, Fukuda H, Inuzuka K, Fujishita A, Ohtani Y, Okimoto T, Ishimaru T, Niikawa N (July 1995). "Establishment of functional imprinting of the H19 gene in human developing placentae". Nat. Genet. 10 (3): 318–324. doi:10.1038/ng0795-318. PMID 7670470. S2CID 34185893.
  11. ^ a b Kopf E, Bibi O, Ayesh S, et al. (August 1998). "The effect of retinoic acid on the activation of the human H19 promoter by a 3' downstream region". FEBS Lett. 432 (3): 123–127. doi:10.1016/S0014-5793(98)00841-2. PMID 9720909. S2CID 30015086.
  12. ^ a b Takeuchi S, Hofmann WK, Tsukasaki K, et al. (May 2007). "Loss of H19 imprinting in adult T-cell leukaemia/lymphoma". Br. J. Haematol. 137 (4): 380–381. doi:10.1111/j.1365-2141.2007.06581.x. PMID 17408396. S2CID 46427539.
  13. ^ a b c Berteaux N, Lottin S, Monté D, Pinte S, Quatannens B, Coll J, Hondermarck H, Curgy JJ, Dugimont T, Adriaenssens E (August 2005). "H19 mRNA-like noncoding RNA promotes breast cancer cell proliferation through positive control by E2F1". J. Biol. Chem. 280 (33): 29625–29636. doi:10.1074/jbc.M504033200. PMID 15985428.
  14. ^ a b c d e f g h Brunkow ME, Tilghman SM (June 1991). "Ectopic expression of the H19 gene in mice causes prenatal lethality". Genes Dev. 5 (6): 1092–1101. doi:10.1101/gad.5.6.1092. PMID 2044956.
  15. ^ a b Brannan CI, Dees EC, Ingram RS, Tilghman SM (January 1990). "The product of the H19 gene may function as an RNA". Mol. Cell. Biol. 10 (1): 28–36. doi:10.1128/MCB.10.1.28. PMC 360709. PMID 1688465.
  16. ^ a b c d e f g h Bergström R, Whitehead J, Kurukuti S, Ohlsson R (February 2007). "CTCF regulates asynchronous replication of the imprinted H19/Igf2 domain". Cell Cycle. 6 (4): 450–454. doi:10.4161/cc.6.4.3854. PMID 17329968.
  17. ^ Szymanski M, Erdmann VA, Barciszewski J. . Bioscience Chapter Database. Landes Bioscience. Archived from the original on 2007-07-06. Retrieved 2008-06-06.
  18. ^ a b c d e f g Leighton PA, Saam JR, Ingram RS, Stewart CL, Tilghman SM (September 1995). "An enhancer deletion affects both H19 and Igf2 expression". Genes Dev. 9 (17): 2079–2089. doi:10.1101/gad.9.17.2079. PMID 7544754.
  19. ^ a b c d e f g h Arima T, Matsuda T, Takagi N, Wake N (January 1997). "Association of IGF2 and H19 imprinting with choriocarcinoma development". Cancer Genet. Cytogenet. 93 (1): 39–47. doi:10.1016/S0165-4608(96)00221-X. PMID 9062579.
  20. ^ a b c d e f g h i Banet G, Bibi O, Matouk I, et al. (September 2000). "Characterization of human and mouse H19 regulatory sequences". Mol. Biol. Rep. 27 (3): 157–165. doi:10.1023/A:1007139713781. PMID 11254105. S2CID 8842695.
  21. ^ a b c d e Tanos V, Ariel I, Prus D, De-Groot N, Hochberg A (2004). "H19 and IGF2 gene expression in human normal, hyperplastic, and malignant endometrium". Int. J. Gynecol. Cancer. 14 (3): 521–525. doi:10.1111/j.1048-891x.2004.014314.x. PMID 15228427. S2CID 43533877.
  22. ^ a b c d Adriaenssens E, Lottin S, Dugimont T, Fauquette W, Coll J, Dupouy JP, Boilly B, Curgy JJ (August 1999). "Steroid hormones modulate H19 gene expression in both mammary gland and uterus". Oncogene. 18 (31): 4460–4473. doi:10.1038/sj.onc.1202819. PMID 10442637.
  23. ^ a b c Shoshani O, Massalha H, Shani N, Kagan S, Ravid O, Madar S, Trakhtenbrot L, Leshkowitz D, Rechavi G, Zipori D (December 2012). "Polyploidization of murine mesenchymal cells is associated with suppression of the long noncoding RNA H19 and reduced tumorigenicity" (PDF). Cancer Research. 72 (24): 6403–6413. doi:10.1158/0008-5472.CAN-12-1155. PMID 23047867.
  24. ^ a b c Moore T, Haig D (February 1991). "Genomic imprinting in mammalian development: a parental tug-of-war". Trends Genet. 7 (2): 45–49. doi:10.1016/0168-9525(91)90230-N. PMID 2035190.
  25. ^ a b c d e f g h i j Gao ZH, Suppola S, Liu J, Heikkilä P, Jänne J, Voutilainen R (March 2002). "Association of H19 promoter methylation with the expression of H19 and IGF-II genes in adrenocortical tumors". J. Clin. Endocrinol. Metab. 87 (3): 1170–1176. doi:10.1210/jcem.87.3.8331. PMID 11889182.
  26. ^ Hibi K, Nakamura H, Hirai A, Fujikake Y, Kasai Y, Akiyama S, Ito K, Takagi H (February 1996). "Loss of H19 imprinting in esophageal cancer". Cancer Res. 56 (3): 480–482. PMID 8564957.
  27. ^ a b c Lottin S, Adriaenssens E, Dupressoir T, Berteaux N, Montpellier C, Coll J, Dugimont T, Curgy JJ (November 2002). "Overexpression of an ectopic H19 gene enhances the tumorigenic properties of breast cancer cells". Carcinogenesis. 23 (11): 1885–1895. doi:10.1093/carcin/23.11.1885. PMID 12419837.
  28. ^ a b Barsyte-Lovejoy D, Lau SK, Boutros PC, Khosravi F, Jurisica I, Andrulis IL, Tsao MS, Penn LZ (May 2006). "The c-Myc oncogene directly induces the H19 noncoding RNA by allele-specific binding to potentiate tumorigenesis" (PDF). Cancer Res. 66 (10): 5330–5337. doi:10.1158/0008-5472.CAN-06-0037. PMID 16707459.
  29. ^ a b Elkin M, Shevelev A, Schulze E, Tykocinsky M, Cooper M, Ariel I, Pode D, Kopf E, de Groot N, Hochberg A (October 1995). "The expression of the imprinted H19 and IGF-2 genes in human bladder carcinoma". FEBS Lett. 374 (1): 57–61. doi:10.1016/0014-5793(95)01074-O. PMID 7589512. S2CID 21179965.
  30. ^ a b c d e Matouk IJ, DeGroot N, Mezan S, Ayesh S, Abu-lail R, Hochberg A, Galun E (2007). Wölfl S (ed.). "The H19 non-coding RNA is essential for human tumor growth". PLOS ONE. 2 (9): e845. Bibcode:2007PLoSO...2..845M. doi:10.1371/journal.pone.0000845. PMC 1959184. PMID 17786216.  
  31. ^ a b Ariel I, Ayesh S, Perlman EJ, Pizov G, Tanos V, Schneider T, Erdmann VA, Podeh D, Komitowski D, Quasem AS, de Groot N, Hochberg A (February 1997). "The product of the imprinted H19 gene is an oncofetal RNA". Mol. Pathol. 50 (1): 34–44. doi:10.1136/mp.50.1.34. PMC 379577. PMID 9208812.
  32. ^ a b Tanos V, Prus D, Ayesh S, Weinstein D, Tykocinski ML, De-Groot N, Hochberg A, Ariel I (July 1999). "Expression of the imprinted H19 oncofetal RNA in epithelial ovarian cancer". Eur. J. Obstet. Gynecol. Reprod. Biol. 85 (1): 7–11. doi:10.1016/S0301-2115(98)00275-9. PMID 10428315.
  33. ^ el-Naggar AK, Lai S, Tucker SA, Clayman GL, Goepfert H, Hong WK, Huff V (November 1999). "Frequent loss of imprinting at the IGF2 and H19 genes in head and neck squamous carcinoma". Oncogene. 18 (50): 7063–7069. doi:10.1038/sj.onc.1203192. PMID 10597307. S2CID 8775403.
  34. ^ a b c d e f g Doyle LA, Yang W, Rishi AK, Gao Y, Ross DD (July 1996). "H19 gene overexpression in atypical multidrug-resistant cells associated with expression of a 95-kilodalton membrane glycoprotein". Cancer Res. 56 (13): 2904–2907. PMID 8674037.
  35. ^ a b Ariel I, de Groot N, Hochberg A (March 2000). "Imprinted H19 gene expression in embryogenesis and human cancer: the oncofetal connection". Am. J. Med. Genet. 91 (1): 46–50. doi:10.1002/(SICI)1096-8628(20000306)91:1<46::AID-AJMG8>3.0.CO;2-I. PMID 10751088.
  36. ^ a b Ariel I, Lustig O, Schneider T, Pizov G, Sappir M, De-Groot N, Hochberg A (February 1995). "The imprinted H19 gene as a tumor marker in bladder carcinoma". Urology. 45 (2): 335–338. doi:10.1016/0090-4295(95)80030-1. PMID 7855987.
  37. ^ Verhaegh GW, Verkleij L, Vermeulen SH, den Heijer M, Witjes JA, Kiemeney LA (February 2008). "Polymorphisms in the H19 Gene and the Risk of Bladder Cancer". Eur. Urol. 54 (5): 1118–1126. doi:10.1016/j.eururo.2008.01.060. PMID 18262338.
  38. ^ a b c Adriaenssens E, Dumont L, Lottin S, Bolle D, Leprêtre A, Delobelle A, Bouali F, Dugimont T, Coll J, Curgy JJ (November 1998). "H19 overexpression in breast adenocarcinoma stromal cells is associated with tumor values and steroid receptor status but independent of p53 and Ki-67 expression". Am. J. Pathol. 153 (5): 1597–1607. doi:10.1016/S0002-9440(10)65748-3. PMC 1853398. PMID 9811352. Archived from the original on 2003-09-12.
  39. ^ "Breast Cell Line MCF-7". Cancer Biology - Breast Cancer Cell Line Database. University of Texas M. D. Anderson Cancer Center. Retrieved 2008-06-06.
  40. ^ Ross DD, Gao Y, Yang W, Leszyk J, Shively J, Doyle LA (December 1997). "The 95-kilodalton membrane glycoprotein overexpressed in novel multidrug-resistant breast cancer cells is NCA, the nonspecific cross-reacting antigen of carcinoembryonic antigen". Cancer Res. 57 (24): 5460–5464. PMID 9407950.
  41. ^ Kawaharata H, Hinoda Y, Itoh F, Endo T, Oikawa S, Nakazato H, Imai K (July 1997). "Decreased sensitivity of carcinoembryonic antigen cDNA-transfected cells to adriamycin". Int. J. Cancer. 72 (2): 377–382. doi:10.1002/(SICI)1097-0215(19970717)72:2<377::AID-IJC29>3.0.CO;2-B. PMID 9219849.
  42. ^ Mirisola V, Mora R, Esposito AI, Guastini L, Tabacchiera F, Paleari L, Amaro A, Angelini G, Dellepiane M, Pfeffer U, Salami A (August 2011). "A prognostic multigene classifier for squamous cell carcinomas of the larynx". Cancer Letters. 307 (1): 37–46. doi:10.1016/j.canlet.2011.03.013. PMID 21481529.
  43. ^ Coorens THH, Treger TD, Al-Saadi R, Moore L, Tran MGB, Mitchell TJ, Tugnait S, Thevanesan C, Young MD, Oliver TRW, Oostveen M, Collord G, Tarpey PS, Cagan A, Hooks Y, Brougham M, Reynolds BC, Barone G, Anderson J, Jorgensen M, Burke GAA, Visser J, Nicholson JC, Smeulders N, Mushtaq I, Stewart GD, Campbell PJ, Wedge DC, Martincorena I, Rampling D, Hook L, Warren AY, Coleman N, Chowdhury T, Sebire N, Drost J, Saeb-Parsy K, Stratton MR, Straathof K, Pritchard-Jones K, Behjati S (2019) Embryonal precursors of Wilms tumor. Science 366(6470):1247-1251
  44. ^ a b c d e Ayesh S, Matouk I, Schneider T, Ohana P, Laster M, Al-Sharef W, De-Groot N, Hochberg A (October 2002). "Possible physiological role of H19 RNA". Mol. Carcinog. 35 (2): 63–74. doi:10.1002/mc.10075. PMID 12325036. S2CID 38724288.
  45. ^ a b c Lottin S, Vercoutter-Edouart AS, Adriaenssens E, Czeszak X, Lemoine J, Roudbaraki M, Coll J, Hondermarck H, Dugimont T, Curgy JJ (February 2002). "Thioredoxin post-transcriptional regulation by H19 provides a new function to mRNA-like non-coding RNA". Oncogene. 21 (10): 1625–1631. doi:10.1038/sj.onc.1205233. PMID 11896592. S2CID 29493356.
  46. ^ Kim KS, Lee YI (November 1997). "Biallelic expression of the H19 and IGF2 genes in hepatocellular carcinoma". Cancer Lett. 119 (2): 143–148. doi:10.1016/S0304-3835(97)00264-4. PMID 9570364.
  47. ^ a b c d Leighton PA, Ingram RS, Eggenschwiler J, Efstratiadis A, Tilghman SM (May 1995). "Disruption of imprinting caused by deletion of the H19 gene region in mice". Nature. 375 (6526): 34–39. Bibcode:1995Natur.375...34L. doi:10.1038/375034a0. PMID 7536897. S2CID 2998931.
  48. ^ Ariel I, Sughayer M, Fellig Y, Pizov G, Ayesh S, Podeh D, Libdeh BA, Levy C, Birman T, Tykocinski ML, de Groot N, Hochberg A (December 2000). "The imprinted H19 gene is a marker of early recurrence in human bladder carcinoma". Mol. Pathol. 53 (6): 320–323. doi:10.1136/mp.53.6.320. PMC 1186987. PMID 11193051.
  49. ^ "Phase 2b, Trial of Intravesical DTA-H19/PEI in Patients With Intermediate-Risk Superficial Bladder Cancer". ClinicalTrials.gov. U.S. National Institutes of Health. 2009-08-31. Retrieved 2010-01-14.
  50. ^ "Phase 1/2a Study of DTA-H19 in Advanced Stage Ovarian Cancer With Symptomatic Ascites". ClinicalTrials.gov. U.S. National Institutes of Health. 2009-12-03. Retrieved 2010-01-14.
  51. ^ "Phase 1/2a DTA-H19 in Patients With Unresentable Pancreatic Cancer". ClinicalTrials.gov. U.S. National Institutes of Health. 2009-11-09. Retrieved 2010-01-14.
  52. ^ a b Sidi AA, Ohana P, Benjamin S, Shalev M, Ransom JH, Lamm D, Hochberg A, Leibovitch I (December 2008). "Phase I/II Marker Lesion Study of Intravesical BC-819 DNA Plasmid in H19 Over Expressing Superficial Bladder Cancer Refractory to Bacillus Calmette-Guerin". The Journal of Urology. 180 (6): 2379–2383. doi:10.1016/j.juro.2008.08.006. ISSN 0022-5347. PMID 18950807.

External links edit

Online Mendelian Inheritance in Man (OMIM): H19 Gene - 103280

April 12, 2024
gene, other, uses, disambiguation, gene, long, noncoding, found, humans, elsewhere, role, negative, regulation, limiting, body, weight, cell, proliferation, this, gene, also, role, formation, some, cancers, regulation, gene, expression, h19identifiersaliasesh1. For other uses see H19 disambiguation H19 is a gene for a long noncoding RNA found in humans and elsewhere H19 has a role in the negative regulation or limiting of body weight and cell proliferation 3 This gene also has a role in the formation of some cancers and in the regulation of gene expression 4 H19IdentifiersAliasesH19 BWS LINC00008 ASM1 NCRNA00008 imprinted maternally expressed transcript D11S813E MIR675HG imprinted maternally expressed transcript non protein coding H19 imprinted maternally expressed transcript WT2 PRO2605 ASMExternal IDsOMIM 103280 GeneCards H19Gene location Human Chr Chromosome 11 human 1 Band11p15 5Start1 995 171 bp 1 End2 001 470 bp 1 RNA expression patternBgeeHumanMouse ortholog Top expressed inplacentagastrocnemius muscleskeletal muscle tissueleft uterine tubeleft ventriclecanal of the cervixright lobe of liverright uterine tubegastric mucosasubcutaneous adipose tissuen aMore reference expression dataBioGPSMore reference expression dataOrthologsSpeciesHumanMouseEntrez283120n aEnsemblENSG00000130600ENSG00000288237n aUniProtnan aRefSeq mRNA n an aRefSeq protein n an aLocation UCSC Chr 11 2 2 Mbn aPubMed search 2 n aWikidataView Edit HumanThe H19 gene is expressed exclusively on one parental allele in a phenomenon known as imprinting 5 H19 is only transcribed from the maternally inherited allele the paternal H19 allele is not expressed 6 H19 was first named ASM for Adult Skeletal Muscle because of its expression in adult skeletal muscle ASM in rats 7 H19 is also known as BWS because aberrant H19 expression can be involved in Beckwith Wiedemann Syndrome BWS as well as Silver Russell syndrome 8 Epigenetics deregulations at H19 imprinted gene in sperm have been observed associated with male infertility 9 Contents 1 Gene characterization 2 RNA product 3 Expression timeline 4 Epigenetics 5 Replication 6 As an oncogene 6 1 As an oncofetal RNA gene 7 Role in cancer 7 1 Genome instability 7 2 Adrenocortical neoplasms 7 3 Choriocarcinomas 7 4 Hepatocellular carcinoma 7 5 Bladder cancers 7 6 Endometrial ovarian cancer 7 7 Breast cancer 7 8 Larynx cancer 7 9 Wilms tumour 8 Participation in signaling pathways 8 1 Upstream effectors hormonal regulation 8 2 Downstream effects angiogenesis metabolism tissue invasion and migration 9 IGF2 10 Cancer therapy 10 1 Gene therapy 10 2 Drug discovery 10 3 Pharmacogenomics 10 4 Immunotherapy 11 References 12 External linksGene characterization editThe H19 gene contains 3 Sp1 binding sites however these 3 sites are present in a part of the sequence that has shown no transcriptional activity in deletion assays 10 As a result these Sp1 binding sites are not expected to contribute much to the regulation of H19 gene transcription The H19 gene sequence also contains binding sites for the C EBP family of transcription factors 10 One of these C EBP transcription factor binding sites also contains a CpG site 10 In vitro methylation of this CpG site on a DNA construct strongly inhibited transcription of the H19 gene 10 In cell lines derived from human choriocarcinomas Kopf et al found that transcription of H19 was under the simultaneous control of both a 5 upstream and a 3 downstream region 11 Kopf et al have suggested that this simultaneous and bidirectional regulation of H19 may involve a member of the AP2 transcription factor family 11 H19 gene transcription has also been shown to be activated by the presence of the E2F1 transcription factor 12 13 RNA product editThe H19 gene codes for a 2 3 kb RNA product 14 It is transcribed by RNA polymerase II spliced and polyadenylated but it does not appear to be translated 15 After many studies researchers finally concluded that the end product of the H19 gene is a RNA strand for the following reasons The H19 RNA product is evolutionarily conserved at the nucleotide level in humans and rodents 16 There is no known open reading frame the H19 mRNA contains stop codons in all 3 reading frames 15 The cDNA version of the human H19 does not contain the short introns that are characteristic of imprinted genes 16 Although the RNA sequence was highly conserved evolutionarily at the amino acid level there was a complete absence of conservation 16 Free energy thermodynamics analysis of the H19 RNA sequence revealed a multitude of possible secondary RNA structures including 16 helices and various hairpin loops 16 In situ hybridization of the H19 RNA revealed that it localizes in a cytoplasmic ribonucleoprotein particle leading some to suggest that the H19 RNA functions as a riboregulator 17 Loss of function and overexpression experiments on H19 have revealed two things Loss of H19 is not lethal in mice 18 Overexpression of H19 is a dominant and lethal mutation 14 Mice with a loss of H19 function express an overgrowth phenotype similar to babies with BWS 18 This has led researchers to suggest that perhaps the only function of H19 RNA expression is to regulate the expression of IGF2 Insulin Growth Factor 2 18 Overexpression of IGF2 can be responsible for overgrowth and generally IGF2 is expressed in the absence of H19 Mouse embryos overexpressing H19 tend to die between embryonic day 14 and birth 14 Brunkow et al have suggested two reasons for the lethality of H19 overexpression in embryonic mice The overexpression of H19 in tissues where it is normally expressed e g liver and gut caused its lethal effects 14 This implies that H19 gene dosage is under strict control in the fetus The expression of H19 in tissues where it is normally not expressed e g brain caused its lethal effects 14 Expression timeline editIn the early placentae 6 8 weeks gestation both parental H19 alleles maternal and paternal are expressed 19 20 After 10 weeks gestation and in full term placentae there is exclusive expression of H19 from the maternal chromosome 19 20 In the embryo maternal expression of H19 is present in endodermal and mesodermal tissues 14 The regulated expression of H19 from biallelic to monoallelic throughout embryonic development suggests that regulation is essential for the growth of embryonic and extraembryonic tissues 19 Immediately after birth H19 expression is downregulated in all tissues except for skeletal muscle 14 Studies by Tanos et al suggest that the accumulation of H19 RNA in skeletal muscle cells is solely due to the stabilization of that RNA in the muscle cells during differentiation 21 In females H19 is expressed postnatally during puberty and pregnancy in the mammary glands and in the uterus during pregnancy 22 A study by Shoshani et al suggests that H19 is continued to be expressed in high amounts in the liver after birth specifically in diploid hepatocytes 23 Epigenetics editGenomic imprinting is surmised to have arisen due to the conflicting interests of maternal and paternal genes within a pregnancy 24 Within a pregnancy the father wants the mother to devote as much of her resources as possible towards the growth benefit of his offspring 24 However within the same pregnancy the mother wants to conserve as much of her resources as possible towards future births without compromising the health of the child ren she is currently carrying 24 H19 contains a differentially methylated region that is also an imprinting control region This imprinting control region is differentially methylated at its CpGs according to parental inheritance Usually the paternal copy of H19 is methylated and silent while the maternal copy is hypomethylated or unmethylated and expressed in the offspring cell Methylation of the H19 promoter is negatively correlated with H19 expression 25 As methylation of the promoter reaches 100 H19 expression from that promoter approaches 0 25 At the same time as H19 expression decreases the expression of IGF2 a neighboring gene on chromosome 11 increases 25 Cells treated with Azad a demethylating agent grow much slower than cells cultured in the absence of Azad 25 At the same time H19 expression increases while IGF2 expression decreases in the presence of Azad 25 The reduction of IGF2 expression could be a reason for the slower growth of cells treated with Azad As well in a mouse bladder carcinoma cell line where transfection of a human H19 DNA construct results in high expression of H19 the methylation of the H19 promoter reduces H19 expression 20 The paternal H19 allele which is silent postnatally shows increasing methylation of CpGs in its promoter with gestation time in the fetus 20 It appears conclusive that the H19 gene is epigenetically controlled via methylation where methylation on or near the vicinity of one allele prevents the expression of that allele As well based on the results from Banet et al it appears that functional H19 imprinting occurs during early placenta development 20 In addition methylation loss at H19 imprinted gene has been observed associated with MTHFR gene promoter hypermethylation in semen samples from infertile males 9 Similarly the CTCF binding site 6 region of H19 can also be hypomethylated with MTHFR gene promoter hypermethylation 9 Replication editA common characteristic of imprinted genes is asynchronous replication during the DNA synthesis phase of the mitotic cycle 16 The replication of two alleles of the same gene can differ according to which parent the allele originated from 16 On the human chromosome 11p15 the methylated paternal H19 allele replicates early in the S phase while the hypomethylated maternal allele replicates later 16 Studies by Bergstrom et al have determined that the later replicating maternal H19 allele is CTCF bound and that it is this CTCF binding that determines the time of H19 replication 16 As an oncogene editEvidence for the identification of H19 as an oncogene Overexpression of H19 appears to be important in the development of esophageal and colorectal cancer cells 26 Cells expressing H19 are able to form bigger colonies in soft agar in anchorage independent growth assays as compared to the control 27 Downregulation of H19 in breast and lung cancer cells decreases their clonogenicity and anchorage dependent growth 28 Subcutaneous injection of H19 into mice promoted tumor progression 27 Tumors formed by injection of bladder carcinoma cells into mice express H19 prior to the injection these bladder carcinoma cells did not express H19 29 Ectopic H19 expression in vivo enhances the tumorigenic potential of carcinoma cells 30 c Myc an oncogene that functions as a regulator of gene transcription induces H19 expression 28 Knocking down H19 in hypoxic stress diminishes p57 induction 30 Evidence against the identification of H19 as an oncogene The amount of H19 RNA transfected into breast cancer cells did not affect cell proliferation cell cycle timing or anchorage dependent growth 27 Tumorigenic mesenchymal stem cells express high levels of H19 compared with non tumorigenic mesenchymal stem cells Knock down of H19 in the tumorigenic cells reduced their tumor forming capacity significantly 23 As an oncofetal RNA gene edit Definition of an oncofetal gene A gene expressed in tumors arising from tissues that express this gene in fetal life 31 H19 while possessing oncogenic properties is best defined as an oncofetal RNA gene because The final product of the H19 gene is RNA 31 H19 is highly expressed prenatally and downregulated postnatally 19 Postnatally H19 is expressed at high levels in cancer cells 14 Role in cancer editIncreased H19 expression is found in the following cancers adrenocortical neoplasms choriocarcinomas hepatocellular carcinomas bladder cancers ovarian serous epithelial cancers head and neck carcinomas endometrial cancer breast cancer acute T cell leukemia lymphoma Wilms tumor testicular germ cell cancer esophageal cancer and lung cancer 12 19 20 21 25 32 33 34 35 Genome instability edit Main article Genome instability Cellular DNA integrity is often compromised in cancer Genome instability can refer to the accumulation of extra copies of DNA chromosomes chromosomal translocations chromosomal inversion chromosome deletions single stranded breaks in DNA double stranded breaks in DNA the intercalation of foreign substances into the DNA double helix or any abnormal changes in DNA tertiary structure that can cause either the loss of DNA or the misexpression of genes It appears that H19 expression is tightly linked to the ploidy of the cell Diploid liver cells express high levels of H19 whereas the polyploid cell fraction do not express H19 Also diploid mesenchymal stem cells express high levels of H19 compared to polyploid mesenchymal stem cells Knock down of H19 lead to increased polyploidization of mesenchymal stem cells and induced polyploidy resulted in reduced expression of H19 providing a direct link between H19 expression and the amount of DNA within the cell 23 Adrenocortical neoplasms edit In contrast to most other cancers adrenocortical neoplasms appear to have decreased expression of H19 To determine a possible cause for the downregulation of H19 Gao et al studied the methylation of 12 CpG sites in the H19 promoter in normal hyperplasia adenoma and carcinoma adrenals They found that in carcinomas there was more methylation of CpGs than in normal hyperplasia and adenoma adrenals 25 Consequently normal H19 expression was detectable in normal and hyperplasia adrenals but in carcinomas and surprisingly adenomas there was a lower H19 expression that was coupled with detectable increased IGF2 expression 25 The presence of IGF2 RNA expression when H19 RNA was downregulated provides further evidence that IGF2 expression is tightly coupled to and dependent on the absence of H19 expression As well the loss of H19 in adrenal cancers may be indicative of tumor suppressor activity by H19 leading Gao et al to suggest that the loss of H19 and subsequent gain of IGF2 may be involved in adrenal cancer induction Although Gao et al found that there was not one CpG methylation site that was more important than the others in downregulating H19 expression they did find that the increase in CpG methylation in adrenal carcinomas followed the pattern of methylation of the normal hyperplasia and adenoma adrenals The mean percent methylation of H19 CpGs peaked at sites 9 and 10 in normal hyperplasia adenoma and carcinoma adrenals and the lowest mean percent methylation of H19 CpGs dipped at site 7 in normal hyperplasia adenoma and carcinoma adrenals The mean percent methylation of H19 CpGs at sites 13 and 14 after the transcription start site is insignificant between normal hyperplasia adenoma and carcinoma adrenals This is because methylation of CpGs after the transcription start site is assumed to interfere with RNA polymerase II during transcription Another point of interest is the significant difference in CpG methylation at site 11 between normal and hyperplasia adrenals The mean percent CpG methylation at site 11 for hyperplasia and adenoma adrenals is significantly different from that of normal adrenals and carcinoma adrenals leading Gao et al to suggest that site 11 is the initial methylated CpG that eventually leads to widespread methylation of the H19 promoter 25 Choriocarcinomas edit Choriocarcinomas in contrast to adrenal carcinomas have upregulated H19 and downregulated IGF2 expression 19 The upregulated H19 expression however came from alleles that were fully methylated 19 Surgically removed choriocarcinomas from human patients also exhibited a heavily methylated H19 promoter with enhanced H19 expression 19 This led researchers Arima et al to suggest that in cases of choriocarcinomas the H19 promoter was mutated allowing it to overcome the transcriptional repression of promoter CpG methylation Hepatocellular carcinoma edit In hepatocellular carcinoma the expression of H19 and IGF2 usually changes from monoallelic to biallelic 30 In in vitro studies culturing hepatocellular carcinoma cell lines in hypoxic condition upregulated H19 expression 30 Whether or not the loss of imprinting for the H19 promoter is a characteristic of hepatocellular carcinoma is not known as some cell lines exhibit loss of imprinting while others did not Bladder cancers edit Bladder mucosa is one of the tissues that express high levels of H19 RNA prenatally 35 In bladder cancers H19 is also upregulated and present in most stages 20 The presence of H19 RNA was strongest in bladder carcinomas sampled in situ that tend to progress rapidly to invasive cancer as well as invasive transitional cell carcinomas 36 In samples of bladder carcinoma loss of imprinting at the H19 loci were observed 29 Verhaugh et al investigated various polymorphisms in the H19 gene and found that some heterozygous SNP polymorphisms such as rs2839698 TC were associated with a decreased risk of developing non muscle invasive bladder cancer as well as bladder cancer overall however this association disappeared for homozygotes CC 37 Endometrial ovarian cancer edit In normal endometrial tissue there is no H19 expression however in endometrial cancer H19 is expressed 21 The expression level of H19 RNA in the epithelial cells of the endometrium increases as tissue differentiation is lost in endometrial cancer 21 In ovarian cancers 75 of low malignancy tumors and 65 of invasive ovarian carcinomas are H19 RNA positive 32 Breast cancer edit Normal breast tissue does not express H19 RNA except during puberty and pregnancy in the mammary glands 38 However in breast cancer 72 5 of the breast adenocarcinomas studied by Adriaenssens et al displayed increased H19 expression when compared to normal breast tissue Of the tissues with upregulated H19 92 2 are stromal cells and only 2 9 are epithelial cells 38 Studies by Berteaux et al have also found that the overexpression of H19 in breast cancer cells promotes proliferation 13 The expression of H19 in these cells is also independent of the tumor suppressor protein p53 and the cell cycle marker Ki 67 38 However the presence of tumor suppressor protein pRb and transcription factor E2F6 is sufficient to repress H19 expression in breast cancer cells 13 In experiments conducted by Doyle et al it was found that MCF 7 a breast adenomacarcinoma cell line 39 did not express the H19 gene however a subline of MCF 7 with a multidrug resistance phenotype MCF 7 AdrVp had upregulation of H19 34 Curiously mutant revertant MCF 7 AdrVp cells that lost their multidrug resistance and became drug sensitive also lost H19 expression 34 Drug resistant MCF AdrVp cells do not overexpress P glycoprotein a cell membrane efflux pump commonly found in multidrug resistant cells instead they overexpress a 95kD membrane glycoprotein p95 34 p95 or NCA 90 is related to carcinoembryonic antigens which have been found to reduce drug toxicity by Kawaharata et al 40 41 NCI H1688 a human lung carcinoma cell line that displays multidrug resistance also overexpress p95 NCA 90 and H19 34 No other cell lines with the multidrug resistance phenotype have been found to overexpress p95 NCA 90 in conjunction with H19 34 Larynx cancer edit H19 is overexpressed in laryngeal squamous cell carcinomas that relapse as compared to those that do not relapse In a pilot study aimed at the development of a prognostic classifier for this cancer H19 was the strongest predictor of relapse It was overexpressed in cancers that later developed local or distant recurrence Its expression did not correlate with the expression of IGF2 and H19 overexpression is unlikely to be a simple consequence of loss of imprinting of the locus containing H19 and IGF2 42 Wilms tumour edit Wilms tumour is a cancer of the kidney that most commonly occurs in childhood An association with H19 has been reported 43 Participation in signaling pathways editThe exact role of H19 RNA within the cell is currently not known There are various known substances and conditions that are known to activate H19 transcription and there are various known effects of H19 RNA on cell cycle activity status although precisely how H19 RNA exerts these effects is still unknown Upstream effectors hormonal regulation edit A previous study conducted by Adriaenssens et al on H19 correlated an overexpression of H19 with the presence of steroid receptors 22 Further studies found that 17 b estradiol the dominant form of estrogen and corticosterone were able to individually stimulate H19 transcription in the uterus while the presence of progesterone inhibited this effect 22 Tamoxifen is a competitive binder of the estrogen receptor and is often used in chemotherapy treatment of breast cancer While 17 b estradiol alone stimulated H19 transcription in MCF 7 cells the addition of tamoxifen inhibited H19 transcription demonstrating that there is a putative role of hormones in H19 transcription 22 Downstream effects angiogenesis metabolism tissue invasion and migration edit When a cancer bladder cell line T24P which does not express H19 was transfected with a DNA construct expressing the H19 gene under the control of the cytomegalovirus promoter many changes were seen in the resulting cells when compared to both the original T24P cell line and a H19 antisense DNA construct transfected T24P cell line While there was no difference in proliferation in 10 FCS normal condition between the 3 cell lines when grown in 0 1 FCS starved serum the H19 transfected cells maintained their rate of growth while both the control and the antisense H19 transfected cells decreased their rate of proliferation by approximately 50 44 When p57 induction in 0 1 FCS media was measured in the 3 cell lines both the control and antisense H19 transfected cells had significantly upregulated p57 however the H19 transfected cells showed a significant downregulation of p57 in 0 1 FCS as compared to 10 FCS 44 In addition while the expression of PCNA required for progression of the cell cycle beyond the S phase was significantly downregulated in all 3 cell lines the reduction was approximately 80 90 in the control and antisense H19 transfected cells and only 30 in the H19 transfected cells 44 An examination of the differences in gene expressed between the H19 transfected cells and the antisense H19 transfected cells showed that the following genes were upregulated uPar c src kinase tyrosine kinase 2 mitogen activated protein kinase kinase tyrosine kinase 2 c jun JNK1 Janus kinase 1 TNF a interleukin 6 heparin binding growth factor like growth factor intracellular adhesion molecule 1 NF kB ephrin A4 and ezrin 44 It is also suggested that angiogenin and FGF18 may be potential transcriptional targets of the H19 RNA 30 As a result of the functions and signaling pathways that H19 RNA upregulated genes are involved in it has been suggested that H19 RNA plays crucial roles in tissue invasion migration and angiogenesis in tumorigenesis 44 Lottin et al also found that the overexpression of H19 positively regulates post transcriptionally thioredoxin 45 Thioredoxin is a protein crucial to the reduction oxidation reactions involved in metabolism within a cell and is often found at high levels in cancerous tissues that also overexpress H19 RNA 45 IGF2 editH19 and IGF2 expression are closely linked as they are expressed in the same tissues during fetal development albeit from differing parental alleles 18 This coupled expression is only lost in cases of loss of imprinting inherited CpG methylated or promoter mutation 46 The hypermethylation of the H19 promoter on the paternal allele plays a vital role in allowing the expression of the paternal allele of IGF2 25 In DNMT null mice the paternal allele of IGF2 is also silenced as the paternal H19 promoter is no longer methylated and repressed 18 A reason for the close coupling of H19 and IGF2 expression may be that they share the same 3 gene enhancer 18 When this 3 enhancer was deleted researchers Leighton et al found decreased H19 and IGF2 RNA expressions in the gut liver and kidney however the methylation status of these genes were not affected by the deleted enhancer 18 Suggestions for why H19 is preferentially activated by the 3 enhancer instead of IGF2 are that H19 has a stronger promoter than IGF2 and that the H19 gene is physically closer to the 3 enhancers than the IGF2 gene 47 It is of interest to note that mice inheriting a deleted maternal H19 and a deleted paternal IGF2 gene were indistinguishable from wildtype mice in birth weight and postnatal growth 47 Mice inheriting only a deleted maternal H19 gene however displayed somatic overgrowth while mice inheriting only a deleted paternal IGF2 gene displayed somatic undergrowth when compared to wildtype mice 47 This indicates that the loss of H19 is not lethal H19 expression governs IGF2 repression and the overexpression of IGF2 is responsible for the overgrowth phenotype observed in the maternal inheritance of a deleted H19 gene 47 Cancer therapy editWhile the functions of the H19 RNA in the cell are still unclear its presence in the many types of carcinoma cells suggest that it can be used as a tumor marker for initial diagnosis cancer recurrence and malignant potential 21 36 48 Gene therapy edit The activation of the H19 promoter in cancerous cells and its silence in normal tissues has led to the suggestion of using the H19 promoter in gene therapy to drive the expression of cytotoxic genes in tumorigenic cells 20 Gene therapy trials utilizing the H19 promoter to drive the expression of cytotoxic genes are currently being tested on mice 20 Drug discovery edit A plasmid composed of the H19 gene regulatory sequences that drive the expression of the A strand of Diphtheria Toxin DT A is undergoing clinical testing as a treatment for superficial bladder cancer 49 ovarian cancer 50 and pancreatic cancer 51 The plasmid designated BC 819 or DTA H19 embodies a targeted therapy approach in that the plasmid enters all dividing cells but the DT A expression is triggered by the presence of H19 transcription factors found only in tumor cells thus destroying the tumor without affecting normal cells In a double center dose escalation Phase I IIa clinical trial of BC 819 as a treatment for superficial bladder cancer 52 no severe adverse events related to the plasmid were detected and tumor responses were observed in more than 70 of patients including those with a still not optimized therapeutic dose and regimen BC 819 was previously tested in human compassionate use for the treatment of superficial bladder cancer ovarian cancer and metastatic liver cancer The bladder cancer patient who was a candidate for radical cystectomy when he was treated in 2004 reported no cancer recurrence and no side effects 52 The ovarian cancer patient experienced a 50 decline in the amount of the ovarian cancer marker protein CA 125 in her blood as well as a significant decrease in the number of cancerous cells in her ascitic fluid The patient suffering from metastatic liver cancer was treated with direct injection of BC 819 into the tumor with considerable tumor necrosis observed Pharmacogenomics edit While the expression profile of H19 in most cancer types is known the role of H19 RNA in influencing cancer cell response to drug treatment is still unknown However recent studies have discovered the expression of thioredoxin and p95 NCA 90 in cancer cells when H19 RNA is present in high quantities 34 45 This knowledge can lead to a more personalized cancer treatment plan for example the expression of p95 in a H19 overexpressing cancer cell may indicate higher tolerance of drug toxicity so cancer treatment for an individual with high levels of H19 and p95 may focus more on radiotherapy or immunotherapy instead of chemotherapy Immunotherapy edit It is not currently known if H19 expression can be used to induce an anti cancer response in immune cells References edit a b c ENSG00000288237 GRCh38 Ensembl release 89 ENSG00000130600 ENSG00000288237 Ensembl May 2017 Human PubMed Reference National Center for Biotechnology Information U S National Library of Medicine Gabory et al 2009 H19 acts as a trans regulator of the imprinted gene network controlling growth in mice PDF Development 136 20 3413 3421 doi 10 1242 dev 036061 PMID 19762426 H19 imprinted maternally expressed transcript non protein coding Homo sapiens Entrez Gene National Center for Biotechnology Information Retrieved 2008 06 06 Zhang Y Tycko B April 1992 Monoallelic expression of the human H19 gene Nat Genet 1 1 40 44 doi 10 1038 ng0492 40 PMID 1363808 S2CID 35338859 Rachmilewitz J Goshen R Ariel I Schneider T de Groot N Hochberg A August 1992 Parental imprinting of the human H19 gene FEBS Lett 309 1 25 28 doi 10 1016 0014 5793 92 80731 U PMID 1380925 S2CID 22194553 Leibovitch MP Nguyen VC Gross MS Solhonne B Leibovitch SA Bernheim A November 1991 The human ASM adult skeletal muscle gene expression and chromosomal assignment to 11p15 Biochem Biophys Res Commun 180 3 1241 1250 doi 10 1016 S0006 291X 05 81329 4 PMID 1953776 Online Mendelian Inheritance in Man OMIM H19 Gene 103280 a b c Rotondo JC Selvatici R Di Domenico M Marci R Vesce F Tognon M Martini F September 2013 Methylation loss at H19 imprinted gene correlates with methylenetetrahydrofolate reductase gene promoter hypermethylation in semen samples from infertile males Epigenetics 8 9 990 997 doi 10 4161 epi 25798 PMC 3883776 PMID 23975186 a b c d Jinno Y Ikeda Y Yun K Maw M Masuzaki H Fukuda H Inuzuka K Fujishita A Ohtani Y Okimoto T Ishimaru T Niikawa N July 1995 Establishment of functional imprinting of the H19 gene in human developing placentae Nat Genet 10 3 318 324 doi 10 1038 ng0795 318 PMID 7670470 S2CID 34185893 a b Kopf E Bibi O Ayesh S et al August 1998 The effect of retinoic acid on the activation of the human H19 promoter by a 3 downstream region FEBS Lett 432 3 123 127 doi 10 1016 S0014 5793 98 00841 2 PMID 9720909 S2CID 30015086 a b Takeuchi S Hofmann WK Tsukasaki K et al May 2007 Loss of H19 imprinting in adult T cell leukaemia lymphoma Br J Haematol 137 4 380 381 doi 10 1111 j 1365 2141 2007 06581 x PMID 17408396 S2CID 46427539 a b c Berteaux N Lottin S Monte D Pinte S Quatannens B Coll J Hondermarck H Curgy JJ Dugimont T Adriaenssens E August 2005 H19 mRNA like noncoding RNA promotes breast cancer cell proliferation through positive control by E2F1 J Biol Chem 280 33 29625 29636 doi 10 1074 jbc M504033200 PMID 15985428 a b c d e f g h Brunkow ME Tilghman SM June 1991 Ectopic expression of the H19 gene in mice causes prenatal lethality Genes Dev 5 6 1092 1101 doi 10 1101 gad 5 6 1092 PMID 2044956 a b Brannan CI Dees EC Ingram RS Tilghman SM January 1990 The product of the H19 gene may function as an RNA Mol Cell Biol 10 1 28 36 doi 10 1128 MCB 10 1 28 PMC 360709 PMID 1688465 a b c d e f g h Bergstrom R Whitehead J Kurukuti S Ohlsson R February 2007 CTCF regulates asynchronous replication of the imprinted H19 Igf2 domain Cell Cycle 6 4 450 454 doi 10 4161 cc 6 4 3854 PMID 17329968 Szymanski M Erdmann VA Barciszewski J Eurekah Riboregulators An Overview Bioscience Chapter Database Landes Bioscience Archived from the original on 2007 07 06 Retrieved 2008 06 06 a b c d e f g Leighton PA Saam JR Ingram RS Stewart CL Tilghman SM September 1995 An enhancer deletion affects both H19 and Igf2 expression Genes Dev 9 17 2079 2089 doi 10 1101 gad 9 17 2079 PMID 7544754 a b c d e f g h Arima T Matsuda T Takagi N Wake N January 1997 Association of IGF2 and H19 imprinting with choriocarcinoma development Cancer Genet Cytogenet 93 1 39 47 doi 10 1016 S0165 4608 96 00221 X PMID 9062579 a b c d e f g h i Banet G Bibi O Matouk I et al September 2000 Characterization of human and mouse H19 regulatory sequences Mol Biol Rep 27 3 157 165 doi 10 1023 A 1007139713781 PMID 11254105 S2CID 8842695 a b c d e Tanos V Ariel I Prus D De Groot N Hochberg A 2004 H19 and IGF2 gene expression in human normal hyperplastic and malignant endometrium Int J Gynecol Cancer 14 3 521 525 doi 10 1111 j 1048 891x 2004 014314 x PMID 15228427 S2CID 43533877 a b c d Adriaenssens E Lottin S Dugimont T Fauquette W Coll J Dupouy JP Boilly B Curgy JJ August 1999 Steroid hormones modulate H19 gene expression in both mammary gland and uterus Oncogene 18 31 4460 4473 doi 10 1038 sj onc 1202819 PMID 10442637 a b c Shoshani O Massalha H Shani N Kagan S Ravid O Madar S Trakhtenbrot L Leshkowitz D Rechavi G Zipori D December 2012 Polyploidization of murine mesenchymal cells is associated with suppression of the long noncoding RNA H19 and reduced tumorigenicity PDF Cancer Research 72 24 6403 6413 doi 10 1158 0008 5472 CAN 12 1155 PMID 23047867 a b c Moore T Haig D February 1991 Genomic imprinting in mammalian development a parental tug of war Trends Genet 7 2 45 49 doi 10 1016 0168 9525 91 90230 N PMID 2035190 a b c d e f g h i j Gao ZH Suppola S Liu J Heikkila P Janne J Voutilainen R March 2002 Association of H19 promoter methylation with the expression of H19 and IGF II genes in adrenocortical tumors J Clin Endocrinol Metab 87 3 1170 1176 doi 10 1210 jcem 87 3 8331 PMID 11889182 Hibi K Nakamura H Hirai A Fujikake Y Kasai Y Akiyama S Ito K Takagi H February 1996 Loss of H19 imprinting in esophageal cancer Cancer Res 56 3 480 482 PMID 8564957 a b c Lottin S Adriaenssens E Dupressoir T Berteaux N Montpellier C Coll J Dugimont T Curgy JJ November 2002 Overexpression of an ectopic H19 gene enhances the tumorigenic properties of breast cancer cells Carcinogenesis 23 11 1885 1895 doi 10 1093 carcin 23 11 1885 PMID 12419837 a b Barsyte Lovejoy D Lau SK Boutros PC Khosravi F Jurisica I Andrulis IL Tsao MS Penn LZ May 2006 The c Myc oncogene directly induces the H19 noncoding RNA by allele specific binding to potentiate tumorigenesis PDF Cancer Res 66 10 5330 5337 doi 10 1158 0008 5472 CAN 06 0037 PMID 16707459 a b Elkin M Shevelev A Schulze E Tykocinsky M Cooper M Ariel I Pode D Kopf E de Groot N Hochberg A October 1995 The expression of the imprinted H19 and IGF 2 genes in human bladder carcinoma FEBS Lett 374 1 57 61 doi 10 1016 0014 5793 95 01074 O PMID 7589512 S2CID 21179965 a b c d e Matouk IJ DeGroot N Mezan S Ayesh S Abu lail R Hochberg A Galun E 2007 Wolfl S ed The H19 non coding RNA is essential for human tumor growth PLOS ONE 2 9 e845 Bibcode 2007PLoSO 2 845M doi 10 1371 journal pone 0000845 PMC 1959184 PMID 17786216 nbsp a b Ariel I Ayesh S Perlman EJ Pizov G Tanos V Schneider T Erdmann VA Podeh D Komitowski D Quasem AS de Groot N Hochberg A February 1997 The product of the imprinted H19 gene is an oncofetal RNA Mol Pathol 50 1 34 44 doi 10 1136 mp 50 1 34 PMC 379577 PMID 9208812 a b Tanos V Prus D Ayesh S Weinstein D Tykocinski ML De Groot N Hochberg A Ariel I July 1999 Expression of the imprinted H19 oncofetal RNA in epithelial ovarian cancer Eur J Obstet Gynecol Reprod Biol 85 1 7 11 doi 10 1016 S0301 2115 98 00275 9 PMID 10428315 el Naggar AK Lai S Tucker SA Clayman GL Goepfert H Hong WK Huff V November 1999 Frequent loss of imprinting at the IGF2 and H19 genes in head and neck squamous carcinoma Oncogene 18 50 7063 7069 doi 10 1038 sj onc 1203192 PMID 10597307 S2CID 8775403 a b c d e f g Doyle LA Yang W Rishi AK Gao Y Ross DD July 1996 H19 gene overexpression in atypical multidrug resistant cells associated with expression of a 95 kilodalton membrane glycoprotein Cancer Res 56 13 2904 2907 PMID 8674037 a b Ariel I de Groot N Hochberg A March 2000 Imprinted H19 gene expression in embryogenesis and human cancer the oncofetal connection Am J Med Genet 91 1 46 50 doi 10 1002 SICI 1096 8628 20000306 91 1 lt 46 AID AJMG8 gt 3 0 CO 2 I PMID 10751088 a b Ariel I Lustig O Schneider T Pizov G Sappir M De Groot N Hochberg A February 1995 The imprinted H19 gene as a tumor marker in bladder carcinoma Urology 45 2 335 338 doi 10 1016 0090 4295 95 80030 1 PMID 7855987 Verhaegh GW Verkleij L Vermeulen SH den Heijer M Witjes JA Kiemeney LA February 2008 Polymorphisms in the H19 Gene and the Risk of Bladder Cancer Eur Urol 54 5 1118 1126 doi 10 1016 j eururo 2008 01 060 PMID 18262338 a b c Adriaenssens E Dumont L Lottin S Bolle D Lepretre A Delobelle A Bouali F Dugimont T Coll J Curgy JJ November 1998 H19 overexpression in breast adenocarcinoma stromal cells is associated with tumor values and steroid receptor status but independent of p53 and Ki 67 expression Am J Pathol 153 5 1597 1607 doi 10 1016 S0002 9440 10 65748 3 PMC 1853398 PMID 9811352 Archived from the original on 2003 09 12 Breast Cell Line MCF 7 Cancer Biology Breast Cancer Cell Line Database University of Texas M D Anderson Cancer Center Retrieved 2008 06 06 Ross DD Gao Y Yang W Leszyk J Shively J Doyle LA December 1997 The 95 kilodalton membrane glycoprotein overexpressed in novel multidrug resistant breast cancer cells is NCA the nonspecific cross reacting antigen of carcinoembryonic antigen Cancer Res 57 24 5460 5464 PMID 9407950 Kawaharata H Hinoda Y Itoh F Endo T Oikawa S Nakazato H Imai K July 1997 Decreased sensitivity of carcinoembryonic antigen cDNA transfected cells to adriamycin Int J Cancer 72 2 377 382 doi 10 1002 SICI 1097 0215 19970717 72 2 lt 377 AID IJC29 gt 3 0 CO 2 B PMID 9219849 Mirisola V Mora R Esposito AI Guastini L Tabacchiera F Paleari L Amaro A Angelini G Dellepiane M Pfeffer U Salami A August 2011 A prognostic multigene classifier for squamous cell carcinomas of the larynx Cancer Letters 307 1 37 46 doi 10 1016 j canlet 2011 03 013 PMID 21481529 Coorens THH Treger TD Al Saadi R Moore L Tran MGB Mitchell TJ Tugnait S Thevanesan C Young MD Oliver TRW Oostveen M Collord G Tarpey PS Cagan A Hooks Y Brougham M Reynolds BC Barone G Anderson J Jorgensen M Burke GAA Visser J Nicholson JC Smeulders N Mushtaq I Stewart GD Campbell PJ Wedge DC Martincorena I Rampling D Hook L Warren AY Coleman N Chowdhury T Sebire N Drost J Saeb Parsy K Stratton MR Straathof K Pritchard Jones K Behjati S 2019 Embryonal precursors of Wilms tumor Science 366 6470 1247 1251 a b c d e Ayesh S Matouk I Schneider T Ohana P Laster M Al Sharef W De Groot N Hochberg A October 2002 Possible physiological role of H19 RNA Mol Carcinog 35 2 63 74 doi 10 1002 mc 10075 PMID 12325036 S2CID 38724288 a b c Lottin S Vercoutter Edouart AS Adriaenssens E Czeszak X Lemoine J Roudbaraki M Coll J Hondermarck H Dugimont T Curgy JJ February 2002 Thioredoxin post transcriptional regulation by H19 provides a new function to mRNA like non coding RNA Oncogene 21 10 1625 1631 doi 10 1038 sj onc 1205233 PMID 11896592 S2CID 29493356 Kim KS Lee YI November 1997 Biallelic expression of the H19 and IGF2 genes in hepatocellular carcinoma Cancer Lett 119 2 143 148 doi 10 1016 S0304 3835 97 00264 4 PMID 9570364 a b c d Leighton PA Ingram RS Eggenschwiler J Efstratiadis A Tilghman SM May 1995 Disruption of imprinting caused by deletion of the H19 gene region in mice Nature 375 6526 34 39 Bibcode 1995Natur 375 34L doi 10 1038 375034a0 PMID 7536897 S2CID 2998931 Ariel I Sughayer M Fellig Y Pizov G Ayesh S Podeh D Libdeh BA Levy C Birman T Tykocinski ML de Groot N Hochberg A December 2000 The imprinted H19 gene is a marker of early recurrence in human bladder carcinoma Mol Pathol 53 6 320 323 doi 10 1136 mp 53 6 320 PMC 1186987 PMID 11193051 Phase 2b Trial of Intravesical DTA H19 PEI in Patients With Intermediate Risk Superficial Bladder Cancer ClinicalTrials gov U S National Institutes of Health 2009 08 31 Retrieved 2010 01 14 Phase 1 2a Study of DTA H19 in Advanced Stage Ovarian Cancer With Symptomatic Ascites ClinicalTrials gov U S National Institutes of Health 2009 12 03 Retrieved 2010 01 14 Phase 1 2a DTA H19 in Patients With Unresentable Pancreatic Cancer ClinicalTrials gov U S National Institutes of Health 2009 11 09 Retrieved 2010 01 14 a b Sidi AA Ohana P Benjamin S Shalev M Ransom JH Lamm D Hochberg A Leibovitch I December 2008 Phase I II Marker Lesion Study of Intravesical BC 819 DNA Plasmid in H19 Over Expressing Superficial Bladder Cancer Refractory to Bacillus Calmette Guerin The Journal of Urology 180 6 2379 2383 doi 10 1016 j juro 2008 08 006 ISSN 0022 5347 PMID 18950807 External links editOnline Mendelian Inheritance in Man OMIM H19 Gene 103280 Retrieved from https en wikipedia org w index php title H19 gene amp oldid 1217629147, wikipedia, wiki, book, books, library,

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