Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: EC:3.5.4.4 (
adenosine deaminase
)
5,136
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Analysis of human
adenosine deaminase
(
ADA
) gene transcription in four different cell lines indicated that a high density of
RNA polymerase II
complexes is present at the 5' end of the gene and that the extent of transcription elongation beyond the promoter-proximal region governs gene expression. To determine the sequence requirements for a potential transcription arrest site in the promoter-proximal region, genomic clones containing the
ADA
promoter, exon 1, and various lengths of intron 1 were injected into Xenopus laevis oocyte germinal vesicles. Transcription analysis indicated that nascent
ADA
transcripts were highly represented at the promoter-proximal region of the injected templates, suggesting that transcription arrest occurred in the oocyte transcription system. Analysis of the transcription products indicated that
ADA
transcription initiated at the authentic start site and that the most prominent, short
ADA
transcripts were 105 nucleotides in length. The 3' end of these transcripts mapped within exon 1, 10 nucleotides downstream of the translation initiation codon. Deletion analysis demonstrated that sequences within exon 1 were sufficient to specify the synthesis of the 105-nucleotide transcripts. Taken together, these data suggest that a transcription arrest mechanism operates in the promoter-proximal region of the human
ADA
gene and that regulation of elongation beyond this point plays a major role in regulating
ADA
gene expression.
...
PMID:Identification and characterization of transcriptional arrest sites in exon 1 of the human adenosine deaminase gene. 169 31
An elongation block to
RNA polymerase II
transcription in exon 1 is a major regulatory step in expression of the murine
adenosine deaminase
(
ADA
) gene. Previous work in the laboratory identified abundant short transcripts with 3' termini in exon 1 in steady-state RNA from injected oocytes. Using a cell-free system to investigate the mechanism of premature 3' end formation, we found that polymerase II generates prominent
ADA
transcripts approximately 96 to 100 nucleotides in length which are similar to the major short transcripts found in steady-state RNA from oocytes injected with
ADA
templates. We have determined that these transcripts are the processed products of 108- to 112-nucleotide precursors. Precursor formation is (i) favored in reactions using circular templates, (ii) not the result of a posttranscriptional processing event, (iii) sensitive to low concentrations of Sarkosyl, and (iv) dependent on a factor(s) which is inactivated in crude extracts at 47 degrees C for 15 min. The cell-free system will allow further characterization of the template and factor requirements involved in the control of premature 3' end formation by
RNA polymerase II
.
...
PMID:A heat-labile factor promotes premature 3' end formation in exon 1 of the murine adenosine deaminase gene in a cell-free transcription system. 171 27
We have previously demonstrated that a transcriptional arrest site exists in exon 1 of the human
adenosine deaminase
(
ADA
) gene and that this site may play a role in
ADA
gene expression (Z. Chen, M. L. Harless, D. A. Wright, and R. E. Kellems, Mol. Cell. Biol. 10:4555-4564, 1990). Sequences involved in this process are not known precisely. To further define the template requirements for transcriptional arrest within exon 1 of the human
ADA
gene, various
ADA
templates were constructed and their abilities to confer transcriptional arrest were determined following injection into Xenopus oocytes. The exon 1 transcriptional arrest signal functioned downstream of several
RNA polymerase II
promoters and an RNA polymerase III promoter, implying that the transcriptional arrest site in exon 1 of the
ADA
gene is promoter independent. We identified a 43-bp DNA fragment which functions as a transcriptional arrest signal. Additional studies showed that the transcriptional arrest site functioned only in the naturally occurring orientation. Therefore, we have identified a 43-bp DNA fragment which functions as a transcriptional arrest signal in an orientation-dependent and promoter-independent manner. On the basis of our findings, we hypothesize that tissue-specific expression of the
ADA
gene is governed by factors that function as antiterminators to promote transcriptional readthrough of the exon 1 transcriptional arrest site.
...
PMID:Sequence requirements for transcriptional arrest in exon 1 of the human adenosine deaminase gene. 194 87
The relative rates of transcription of the human
adenosine deaminase
(
ADA
) gene were determined in isolated nuclei from T and B lymphoblasts and skin fibroblasts.
ADA
gene transcription occurs at higher rates in T cells than in B cells and fibroblasts. Relative steady state
ADA
mRNA levels were also determined for each cell line, and these values were found to correlate with relative rates of transcription of the gene. Therefore, the primary mechanism for control of expression of this ubiquitous enzyme is at the level of transcription. The ratios of
ADA
enzymatic activity to specific mRNA content were also compared between cell lines. The B lymphoblasts exhibited lower ratios than did the T lymphoblasts, suggesting that rates of protein degradation were several fold greater in B than in T lymphoblast cell lines. This finding is consistent with previous direct measurements of
ADA
protein turnover. Differential rates of protein turnover in B as compared to T cells provide a secondary mechanism for the regulation of
ADA
expression. In addition to transcription initiation being the major control mechanism of steady state
ADA
mRNA in all cell lines, first intron elongation pausing occurs in fibroblasts, and discrete regions of
RNA polymerase II
and RNA polymerase III antisense transcripts are observed in all cell lines studied.
...
PMID:Cell type-specific transcriptional regulation of the human adenosine deaminase gene. 278 3
Transcription arrest plays a role in regulating the expression of a number of genes, including the murine
adenosine deaminase
(
ADA
) gene. We have previously identified two prominent arrest sites at the 5' end of the
ADA
gene: one in the first exon and one in the first intron (J. W. Innis and R. E. Kellems, Mol. Cell. Biol. 11:5398-5409, 1991). Here we report the functional characterization of the intron 1 arrest site, located 137 to 145 nucleotides downstream of the cap site. We have determined, using gel filtration, that the intron 1 arrest site is a stable
RNA polymerase II
pause site and that the transcription elongation factor SII promotes read-through at this site. Additionally, the sequence determinants for the pause are located within a 37-bp fragment encompassing this site (+123 to +158) and can direct transcription arrest in an orientation-dependent manner in the context of the
ADA
and adenovirus major late promoters. Specific point mutations in this region increase or decrease the relative pausing efficiency. We also show that the sequence determinants for transcription arrest can function when placed an additional 104 bp downstream of their natural position.
...
PMID:Functional analysis of a stable transcription arrest site in the first intron of the murine adenosine deaminase gene. 847 37
Hepatitis delta virus (HDV) is a unique viroid-like human pathogen that is always associated with hepatitis B infection. Replication of HDV involves the transcription of genomic RNA, probably by the host
RNA polymerase II
, by a rolling circle mechanism followed by self-cleavage and self-ligation. Editing of antigenomic RNA, possibly involving the enzyme
adenosine deaminase
, generates two functionally distinct forms of delta antigen. The molecular basis for HDV pathogenicity remains uncertain.
...
PMID:Replication of hepatitis delta virus. 887 76
Although the PITSLRE protein kinases are members of the cyclin-dependent kinase superfamily, their cellular function is unclear. Previously we demonstrated that the general RNA splicing factor RNPS1 is a specific PITSLRE p110 kinase interactor in vivo. This suggests that the PITSLRE family of protein kinases is involved in some aspect of RNA processing or transcription. Here we identify multiple transcriptional elongation factors, including ELL2, TFIIF(1), TFIIS, and FACT, as PITSLRE kinase-associated proteins. We demonstrate that PITSLRE p110 protein kinases co-immunoprecipitate and/or co-purify with these elongation factors as well as with
RNA polymerase II
. Antibody-mediated inhibition of PITSLRE kinase specifically suppressed
RNA polymerase II
-dependent in vitro transcription initiated at a GC-rich (
adenosine deaminase
) or TATA box-dependent (Ad2ML) promoter, and this suppression was rescued by readdition of purified PITSLRE p110 kinase. Together, these data strongly suggest that PITSLRE protein kinases participate in a signaling pathway that potentially regulates or links transcription and RNA processing events.
...
PMID:PITSLRE p110 protein kinases associate with transcription complexes and affect their activity. 1170 59
The archetypal TATA-box deficient G+C-rich promoter of the murine
adenosine deaminase
gene (Ada) requires a 48-bp minimal self-sufficient promoter element (MSPE) for function. This MSPE was used to isolate a novel full-length cDNA clone that encodes a 66-kDa murine G+C-rich promoter binding protein (mGPBP). The mGPBP mRNAs are ubiquitously expressed as either 3.0- or 3.5-kb forms differing in 3' polyadenylation site usage. Purified recombinant mGPBP, in the absence of any other mammalian cofactors, binds specifically to both the murine Ada gene promoter's MSPE and the nonhomologous human Topo IIalpha gene's G+C-rich promoter. In situ binding assays, immunoprecipitation, and Western blot analyses demonstrated that mGPBP is a nuclear factor that can form complexes with TATA-binding protein, TFIIB, TFIIF,
RNA polymerase II
, and P300/CBP both in vitro and in intact cells. In cotransfection assays, increased mGPBP expression transactivated the murine Ada gene's promoter. Sequestering of GPBP present in HeLa cell nuclear extract by immunoabsorption completely and reversibly suppressed extract-dependent in vitro transcription from the murine Ada gene's G+C-rich promoter. However, transcription from the human Topo IIalpha gene's TATA box-containing G+C-rich promoter was only partially suppressed and the adenovirus major late gene's classical TATA box-dependent promoter is totally unaffected under identical assay conditions. These results implicate GPBP as a requisite G+C-rich promoter-specific transcription factor and provide a mechanistic basis for distinguishing transcription initiated at a TATA box-deficient G+C-rich promoter from that initiated at a TATA box-dependent promoter.
...
PMID:The murine G+C-rich promoter binding protein mGPBP is required for promoter-specific transcription. 1461 17
The carboxy-terminal domain (CTD) of the large subunit of
RNA polymerase II
(pol II) is essential for several co-transcriptional pre-messenger RNA processing events, including capping, 3'-end processing and splicing. We investigated the role of the CTD of RNA pol II in the coordination of A to I editing and splicing of the ADAR2 (ADAR: adenosine deaminases that act on RNA) pre-mRNA. The auto-editing of Adar2 intron 4 by the ADAR2
adenosine deaminase
is tightly coupled to splicing, as the modification of the dinucleotide AA to AI creates a new 3' splice site. Unlike other introns, the CTD is not required for efficient splicing of intron 4 at either the normal 3' splice site or the alternative site created by editing. However, the CTD is required for efficient co-transcriptional auto-editing of ADAR2 intron 4. Our results implicate the CTD in site-selective RNA editing by ADAR2 and in coordination of editing with alternative splicing.
...
PMID:RNA editing and alternative splicing: the importance of co-transcriptional coordination. 1660 95
microRNAs (miRNAs) are extensively involved in developmental programming. Some miRNAs are highly conserved, while others are lineage specific. All miRNAs maturate through a series of processing steps. Here we review recent progresses in the studies of early steps in miRNA biogenesis, focusing on animal systems. The miRNA maturation pathways are surprisingly diverse, involving transcription by
RNA polymerase II
or III, cleavage by the Drosha nuclease or the spliceosome, and sometimes modifications by the
adenosine deaminase
ADAR. The relationship between the diversity in miRNA biogenesis and the apparently rapid evolution of miRNA genes and functions is discussed.
...
PMID:MicroRNA biogenesis: there's more than one way to skin a cat. 1877 99
1
2
Next >>
