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Query: UMLS:C0027627 (
metastases
)
103,950
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The
mta1
gene is a recently identified novel candidate metastasis-associated gene. The deduced amino acid sequence contains an src homology-3 domain binding motif, a zinc finger motif and possible phosphorylation sites, suggesting that this gene is involved in signal transduction or regulation of gene expression. The purpose of our study was to examine the mRNA expression levels of the MTA1, the human homologue of the rat
mta1
gene in colorectal and gastric carcinomas and thus to evaluate the relevance of the expression of this gene to human carcinoma progression. The expression of MTA1 mRNA in 36 colorectal and 34 gastric carcinoma samples was compared with that in corresponding normal mucosa tissues by semi-quantitative reverse-transcription polymerase chain reaction (RT-PCR) and the results were compared with clinico-pathologic data. A relative overexpression of MTA1 mRNA (tumor/normal ratio > or = 2) was observed in 14 of 36 (38.9%) colorectal carcinomas and 13 of 34 (38.2%) gastric carcinomas. Clinico-pathologic correlations demonstrated that in colorectal carcinomas, tumors overexpressing MTA1 mRNA exhibited a significantly deeper wall invasion and a higher rate of metastasis to lymph nodes, and tended to be at an advanced Dukes' stage with frequent lymphatic involvement. In gastric carcinomas, the tumors overexpressing MTA1 mRNA showed significantly higher rates of serosal invasion and lymph node metastasis and tended to have a higher rate of vascular involvement. Our data suggest that overexpression of the MTA1 gene correlates with tumor invasion and the presence of
metastases
and that a high expression of MTA1 mRNA may be a potential indicator for assessing the malignant potential of colorectal and gastric carcinomas.
...
PMID:Overexpression of the MTA1 gene in gastrointestinal carcinomas: correlation with invasion and metastasis. 929 40
Breast cancer patients usually do not die of their primary cancers; they die of
metastatic disease
. Thus understanding the progression of breast cancer to the metastatic state and the changes that take place in highly malignant breast cells are important goals that could eventually result in new therapeutic approaches to highly progressive breast disease. Changes in the expression of certain genes or alterations in gene structures and encoded products can result in benign tumour cells progressing to the metastatic state. Experimentally, this has been performed by transferring dominantly acting oncogenes into susceptible cells and then testing the malignant properties of these cells in suitable animal models, but such rapid qualitative changes occur in vivo only rarely, and the natural progression of mammary cells to the metastatic state is thought to occur through a slow stepwise process that can take several years. Some of the slow stepwise changes in mammary cancer progression can be reversible and need not involve dominantly acting oncogenes or tumour suppressor genes, consistent with clinical observations. An important element of the natural progression of mammary tumours to malignancy may be their ability to circumvent microenvironmental controls that regulate growth and cellular diversity, a process that appears to involve mainly quantitative changes in gene expression, resulting in loss of normal cellular regulation. One of the important mechanisms of cellular regulation in epithelial tissues, such as those found in the breast, is mediated by intercellular junctional communication. Alterations in gene expression can result in loss of gap-junctional communication, concomitant with cellular diversification and progression. It is thought that the highly malignant cancer cells that have slowly evolved in vivo with only a few qualitative changes in gene structure have undergone extensive cycles of diversification and the accumulation of several quantitative changes in the expression of various genes that encode products related to malignancy. We have identified some of the genes that are related to progression and metastasis in breast cancer. For example, one of these genes, a novel gene called
mta1
(in rodents) or MTA1 (in humans) appears to be involved in mammary cell motility and growth regulation. Thus highly malignant cellular phenotypes can arise rapidly due to specific qualitative changes in critical controlling genes, or more slowly via less critical qualitative genetic changes coupled with other cellular changes, such as loss of intercellular communication, and changes in gene expression, such as in the MTA1 gene, resulting in cellular diversification and ultimately tumour progression to the metastatic state.
...
PMID:Breast cancer metastasis-associated genes: role in tumour progression to the metastatic state. 951 27
The morbidity in most cancer patients is not due to their primary cancers; it is due to
metastatic disease
. Thus understanding the progression of tumors to the metastatic state and the changes that take place in highly malignant cells are important in the development of new therapeutic approaches to diagnose, prognostically assess and treat highly progressive malignancies. Changes in the expression of certain genes or alterations of gene structures and encoded products can result in benign tumor cells progressing to the invasive and metastatic states. This has been shown in the laboratory by transferring dominantly acting oncogenes into susceptible cells and then testing the malignant properties of these cells in vivo. Usually such rapid qualitative changes in malignant state occur only rarely; the natural progression of tumor cells to the invasive or metastatic state occurs through a slow stepwise process of change. Tumor progression, in some instances, can be reversible, involving changes in dominantly acting oncogenes or tumor suppressor genes. The natural progression of tumors to highly malignant states also involves their ability to circumvent host microenvironmental controls that regulate cellular growth and diversity. Quantitative changes in gene expression rather than qualitative changes in gene structure are important in microenvironmental effects on progression. One of the important mechanisms of cellular regulation in epithelial tissues, such as breast epithelium, appears to be mediated by intercellular junctional communication. Changes in gene expression can result in loss of junctional communication, followed by cellular diversification and progression. Highly malignant tumor cells that have slowly evolved in vivo with only a few qualitative changes in gene structure have probably undergone extensive cycles of diversification and have multiple quantitative differences in gene expression. Some of these genes are related to metastasis. For example, we have identified a novel gene called
mta1
(rat) or MTA1 (human) that appears to be involved in mammary cell motility and growth regulation. This may be an example of a gene that regulates highly malignant cellular phenotypes. When coupled with other cellular changes, such as loss of intercellular communication, specific changes in gene expression may result in cellular diversification and tumor progression.
...
PMID:Metastasis-Associated genes and metastatic tumor progression. 989 Dec 20
Once cancer cells have spread and formed secondary masses, breast cancers are largely incurable even with state-of-the-art medicine. To improve diagnosis and therapy, better markers are needed to distinguish cells which have a high probability for causing clinically relevant, macroscopic
metastases
. In this review, we summarize the several genes that regulate breast cancer metastasis. Two categories of genes are presented--metastasis activator (ras, MEK1,
mta1
, proteinases, adhesion molecules, chemoattractants/receptors, autotaxin, PKC, S100A4, RhoC, osteopontin) and metastasis suppressor (Nm23, E-cadherin, TIMPs, KiSS1, Kai1, Maspin, MKK4, BRMS1). While the mechanisms of action for most of these genes are not fully elucidated, some clues are emerging and are presented.
...
PMID:Genetic basis of human breast cancer metastasis. 1201 33
Using differential cDNA library screening techniques based on metastatic and nonmetastatic rat mammary adenocarcinoma cell lines, we previously cloned and sequenced the metastasis-associated gene
mta1
. Using homology to the rat
mta1
gene, we cloned the human MTA1 gene and found it to be over-expressed in a variety of human cell lines (breast, ovarian, lung, gastric and colorectal cancer but not melanoma or sarcoma) and cancerous tissues (breast, esophageal, colorectal, gastric and pancreatic cancer). We found a close similarity between the human MTA1 and rat
mta1
genes (88% and 96% identities of the nucleotide and predicted amino acid sequences, respectively). Both genes encode novel proteins that contain a proline rich region (SH3-binding motif), a putative zinc finger motif, a leucine zipper motif and 5 copies of the SPXX motif found in gene regulatory proteins. Using Southern blot analysis the MTA1 gene was highly conserved, and using Northern blot analysis MTA1 transcripts were found in virtually all human cell lines (melanoma, breast, cervix and ovarian carcinoma cells and normal breast epithelial cells). However, the expression level of the MTA1 gene in normal breast epithelial cells was approximately 50% of that found in rapidly growing adenocarcinoma and atypical epithelial cell lines. Experimental inhibition of MTA1 protein expression using antisense phosphorothioate oligonucleotides resulted in inhibition of growth and invasion of human MDA-MB-231 breast cancer cells with relatively high MTA1 expression. Furthermore, the MTA1 protein was localized in the nuclei of cells transfected with a mammalian expression vector containing a full-length MTA1 gene. Although some MTA1 protein was found in the cytoplasm, the vast majority of MTA1 protein was localized in the nucleus. Examination of recombinate MTA1 and related MTA2 proteins suggests that MTA1 protein is a histone deacetylase. It also appears to behave like a GATA-element transcription factor, since transfection of a GATA-element reporter into MTA1-expressing cells resulted in 10-20-fold increase in reporter expression over poorly MTA1-expressing cells. Since it was reported that nucleosome remodeling histone deacetylase complex (NuRD complex) involved in chromatin remodeling contains MTA1 protein and a MTA1-related protein (MTA2), we examined NuRD complexes for the presence of MTA1 protein and found an association of this protein with histone deacetylase. The results suggest that the MTA1 protein may serve multiple functions in cellular signaling, chromosome remodeling and transcription processes that are important in the progression, invasion and growth of metastatic epithelial cells.
Clin Exp
Metastasis
2003
PMID:Tumor metastasis-associated human MTA1 gene and its MTA1 protein product: role in epithelial cancer cell invasion, proliferation and nuclear regulation. 1265 Jun 3
Metastasis
is a complex series of sequential events involving several gene products and the regulated expression of several tumor cell genes. Using rat mammary adenocarcinoma cell lines of differing metastatic potentials and a differential complementary DNA (cDNA) hybridization method, our laboratory embarked in 1992 on a project to identify candidate metastasis-associated genes. Among the genes that were found to be abundantly overexpressed in highly metastatic rat cell lines compared to poorly metastatic cell lines, we identified a completely novel gene without any homologous or related genes in the database in 1994. The full-length cDNA of this gene was cloned, sequenced, and named
mta1
(metastasis-associated gene 1), and eventually, its human cDNA counterpart, MTA1, was also cloned and sequenced by our group. MTA1 has now been identified as one of the members of a gene family (MTA gene family). The products of the MTA genes, the MTA proteins, are transcriptional co-regulators that function in histone deacetylation and nucleosome remodeling. In this review, we will briefly discuss the researches for the identification and characterization of the
mta1
gene, its human counterpart MTA1, and their protein products.
Cancer
Metastasis
Rev 2014 Dec
PMID:Identification and characterization of metastasis-associated gene/protein 1 (MTA1). 2531 16
