Structural Organization of the Microsomal Glutathione S-Transferase Gene (MGST1) on Chromosome 12p13.1â13.2
The structure and regulation of the microsomal glutathione S -transferase gene ( MGST1 ) are considerably more complex than originally perceived to be. The MGST1 gene has two alternative first exons and is located in the 12p13.1â13.2 region. Two other potential first exons were determined to be no...
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| Veröffentlicht in: | The Journal of biological chemistry 2000-04, Vol.275 (17), p.13000 |
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| container_title | The Journal of biological chemistry |
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| creator | Michael J. Kelner Richard D. Bagnell Mark A. Montoya Leita A. Estes Lena Forsberg Ralf Morgenstern |
| description | The structure and regulation of the microsomal glutathione S -transferase gene ( MGST1 ) are considerably more complex than originally perceived to be. The MGST1 gene has two alternative first exons and is located in the 12p13.1â13.2 region. Two other potential first exons were determined
to be nonfunctional. The region between the functional first exons cannot direct transcription. Thus, one common promoter
element directing transcription exists, and RNA splicing occurs such that only one of the first exons (containing only untranslated
mRNA) is incorporated into each mRNA species with common downstream exons. MGST1 expression and regulation are therefore similar to those of other hepatic xenobiotic handling enzymes, which also produce
mRNA species differing only in the 5â²-untranslated regions to yield identical proteins. MGST1 was previously considered a âhousekeepingâ gene, as non-oxidant inducers had little effect on activity. However, the promoter
region immediately upstream of the dominant first exon transcriptionally responds to oxidative stress. In this respect, MGST1 is similar to glutathione peroxidases that also transcriptionally respond to oxidative stress. The discovery that MGST1 utilizes alternative first exon splicing eliminates a problem with the first description of MGST1 cDNA in that it appeared that MGST1 expression was in violation of the ribosomal scanning model. The identification that the first exon originally noted is in
fact a minor alternative first exon far downstream of the primary first exon eliminates this conundrum. |
| doi_str_mv | 10.1074/jbc.275.17.13000 |
| format | Article |
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to be nonfunctional. The region between the functional first exons cannot direct transcription. Thus, one common promoter
element directing transcription exists, and RNA splicing occurs such that only one of the first exons (containing only untranslated
mRNA) is incorporated into each mRNA species with common downstream exons. MGST1 expression and regulation are therefore similar to those of other hepatic xenobiotic handling enzymes, which also produce
mRNA species differing only in the 5â²-untranslated regions to yield identical proteins. MGST1 was previously considered a âhousekeepingâ gene, as non-oxidant inducers had little effect on activity. However, the promoter
region immediately upstream of the dominant first exon transcriptionally responds to oxidative stress. In this respect, MGST1 is similar to glutathione peroxidases that also transcriptionally respond to oxidative stress. The discovery that MGST1 utilizes alternative first exon splicing eliminates a problem with the first description of MGST1 cDNA in that it appeared that MGST1 expression was in violation of the ribosomal scanning model. The identification that the first exon originally noted is in
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to be nonfunctional. The region between the functional first exons cannot direct transcription. Thus, one common promoter
element directing transcription exists, and RNA splicing occurs such that only one of the first exons (containing only untranslated
mRNA) is incorporated into each mRNA species with common downstream exons. MGST1 expression and regulation are therefore similar to those of other hepatic xenobiotic handling enzymes, which also produce
mRNA species differing only in the 5â²-untranslated regions to yield identical proteins. MGST1 was previously considered a âhousekeepingâ gene, as non-oxidant inducers had little effect on activity. However, the promoter
region immediately upstream of the dominant first exon transcriptionally responds to oxidative stress. In this respect, MGST1 is similar to glutathione peroxidases that also transcriptionally respond to oxidative stress. The discovery that MGST1 utilizes alternative first exon splicing eliminates a problem with the first description of MGST1 cDNA in that it appeared that MGST1 expression was in violation of the ribosomal scanning model. The identification that the first exon originally noted is in
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to be nonfunctional. The region between the functional first exons cannot direct transcription. Thus, one common promoter
element directing transcription exists, and RNA splicing occurs such that only one of the first exons (containing only untranslated
mRNA) is incorporated into each mRNA species with common downstream exons. MGST1 expression and regulation are therefore similar to those of other hepatic xenobiotic handling enzymes, which also produce
mRNA species differing only in the 5â²-untranslated regions to yield identical proteins. MGST1 was previously considered a âhousekeepingâ gene, as non-oxidant inducers had little effect on activity. However, the promoter
region immediately upstream of the dominant first exon transcriptionally responds to oxidative stress. In this respect, MGST1 is similar to glutathione peroxidases that also transcriptionally respond to oxidative stress. The discovery that MGST1 utilizes alternative first exon splicing eliminates a problem with the first description of MGST1 cDNA in that it appeared that MGST1 expression was in violation of the ribosomal scanning model. The identification that the first exon originally noted is in
fact a minor alternative first exon far downstream of the primary first exon eliminates this conundrum.</abstract><pub>American Society for Biochemistry and Molecular Biology</pub><pmid>10777602</pmid><doi>10.1074/jbc.275.17.13000</doi></addata></record> |
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| ispartof | The Journal of biological chemistry, 2000-04, Vol.275 (17), p.13000 |
| issn | 0021-9258 1083-351X |
| language | eng |
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| source | Elektronische Zeitschriftenbibliothek - Frei zugängliche E-Journals; Alma/SFX Local Collection |
| title | Structural Organization of the Microsomal Glutathione S-Transferase Gene (MGST1) on Chromosome 12p13.1â13.2 |
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