UNIPROT:P06889 - FACTA Search

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5' Sequences of the human cardiac alpha-actin gene are involved in the tissue-specific and developmental regulation of the gene. Deletion analyses combined with transient expression experiments in muscle cells have demonstrated three primary regions of functional importance (A. Minty and L. Kedes, Mol. Cell. Biol. 6:2125-2136, 1986; T. Miwa and L. Kedes, Mol. Cell. Biol. 7:2803-2813, 1987), and we have previously demonstrated binding of a protein indistinguishable from serum response factor (SRF) to the most proximal region (T.A. Gustafson, T. Miwa, L.M. Boxer, and L. Kedes, Mol. Cell. Biol. 8:4110-4119, 1988). In this report, we examine protein interaction with the remainder of the promoter. Gel shift and footprinting assays revealed that at least seven distinct nuclear proteins interacted with known and putative regulatory regions of the promoter. The transcription factor Sp1 bound to eight sites, as demonstrated by footprinting assays and gel shift analysis with purified Sp1. Purified CCAAT box-binding transcription factor CTF/NF-I and Sp1 were shown to interact with the far-upstream regulatory element at -410, and footprint analysis showed extensive overlap of these two sites. Two unidentified proteins with similar but distinct footprints interacted with the second region of functional importance at -140, which contains the second CArG motif [CC(A + T rich)6GG], and these proteins were shown to be distinct from SRF. SRF was found to bind to the remaining three CArG boxes, two of which were closely interdigitated with Sp1 sites. In addition, CArG box 4 was found to interact with SRF and another distinct protein whose footprint was contained within the SRF-binding site. Sequences surrounding the TATA box were also shown to bind proteins. Sp1 was shown to bind to a site immediately downstream from the TATA box and to a site within the first exon. Thus, each of the three functional upstream regions, as defined by transfection assays, was shown to interact with five factors: Sp1 and CTF/NF-I at the upstream site, two unidentified proteins at the central site, and SRF at the most proximal site. These results suggest that expression of the cardiac actin gene in muscle cells is controlled by complex interactions among multiple upstream and intragenic elements.
Mol Cell Biol 1989 Aug
PMID:Identification of multiple proteins that interact with functional regions of the human cardiac alpha-actin promoter. 279 88

To investigate the transcriptional control of nuclear-encoded respiratory genes in mammals, we have performed a deletional analysis of cis-acting regulatory sequences in the rat somatic cytochrome c gene. Three major regions are required for maximal expression of the transfected gene in kidney cell lines CV-1 and COS-1. One of these, region III (+71 to +115 from the transcription initiation site), is an unusual intragenic controlling element found in the 5' end of the first intron, while the other two, region I (-191 to -165) and region II (-139 to -84), define the upstream promoter. Region II contains two consensus CCAAT boxes and mediates a constitutive level of expression in both cell lines. In contrast, regions I and III are both required for the increased promoter activity observed in COS-1 cells compared with promoter activity observed in CV-1 cells, and the regions function individually as competitors with the full promoter for trans-acting factors or complexes. Region III contains a perfect octanucleotide homology with region I in addition to a consensus Sp1-transcription-factor-binding site. Promoter stimulation in COS-1 cells can be duplicated in CV-1 cells by cotransfecting with a T-antigen-producing vector, but purified T antigen does not bind anywhere in the cytochrome c promoter. A control promoter from the mouse metallothionein I gene is similarly activated in T-antigen-producing cells only in the presence of zinc, which activates its upstream regulatory sites. We conclude that T antigen stimulates these cellular promoters through the activation or induction of cellular factors or complexes that mediate their effects through promoter-specific regulatory elements. Cytochrome c promoter regions activated in this system may play a physiological role in controlling gene expression.
Mol Cell Biol 1988 Jan
PMID:Both upstream and intron sequence elements are required for elevated expression of the rat somatic cytochrome c gene in COS-1 cells. 282 5

Structural organization of the entire mouse mitochondrial aspartate aminotransferase (EC 2.6.1.1) gene was determined by analyzing the overlapping genomic clones obtained from a Charon 4A DNA library. The gene is 25 X 10(3) base-pairs long and contains ten exons interrupted by nine introns of various sizes. The 5' and 3'-flanking regions, the exact sizes and boundaries of the exon blocks including the transcription-initiation sites were determined. The 5' end of the gene lacks the prototypical 5' transcriptional regulatory sequence elements, such as TATA and CAAT boxes, but contains G + C-rich sequences, two putative binding sites for a cellular transcription factor, Sp1, and multiple transcription-initiation sites. Moreover, the sequences around the transcription-initiation sites are compatible with the formation of a number of potentially stable stem-loop structures. The leader sequence, which is essential for the transport of the protein into the mitochondria, is coded by the first exon and is separated from the mature protein by the first intron. The pyridoxal 5'-phosphate-binding domain, consisting of seven alternating beta-sheets and alpha-helical polypeptide strands, is separated by four introns present at the ends of alpha-helices. These genomic DNA structures suggest that the introns were not inserted into a previously uninterrupted coding sequence, but rather are products of evolution of the ancestral gene. However, a further correlation between the positions of introns relative to the well-defined structural domains of the mature protein was not obvious.
J Mol Biol 1987 Nov 05
PMID:Structural organization of the mouse mitochondrial aspartate aminotransferase gene. 282 32

We have used recombinant simian virus 40 (SV40) minichromosomes to retrieve sequence-specific DNA-binding proteins derived from the cell nucleus of COS-7 cells. We showed that the transcription factors AP-1 and Sp1 are stably bound to the SV40 DNA late in viral infection. Under similar conditions, minichromosomes carrying the rat insulin (rINS1) enhancer, which is under negative regulation in COS-7 cells, bound two proteins which mapped to distinct regions of the rINS1 enhancer. The SV40 P element competed for one of these proteins which bound to the region from -198 to -230. This factor may be related to AP-1. The other factor selectively bound a regulatory element in the region from -92 to -124 of the insulin enhancer. These proteins may play a role in regulating the rINS1 enhancer function.
Mol Cell Biol 1988 Feb
PMID:Capturing nuclear sequence-specific DNA-binding proteins by using simian virus 40-derived minichromosomes. 283 46

Polymerase II transcription of a human gene for the small nuclear RNA U2 is dependent on two different promoter elements: a TATA-equivalent proximal sequence element and a distal enhancer element, which has been shown to contain Sp1- and octamer-binding sites. We have investigated the functional interplay between these transcription factor-binding sites of the enhancer, following transfection of U2 maxigene constructions into HeLa cells. There is a functional non-additive co-operation between the octamer-binding factor and Sp1, which is not dependent on the evolutionally conserved steric arrangement of these binding sites. We demonstrate that the conserved Sp1-binding site of the U2 enhancer can be fully substituted by a nuclear factor I (NFI) binding site, and that the octamer-binding factor functions in stimulating transcription in conjunction with either Sp1 or NFI. Since the octamer-binding factor is most probably the same protein as nuclear factor III (NFIII), the results imply that the NFI/NFIII complex, involved in adenovirus DNA replication, also can function as an efficient activator of transcription.
J Mol Biol 1989 Jan 20
PMID:Nuclear factor I can functionally replace transcription factor Sp1 in a U2 small nuclear RNA gene enhancer. 292 13

Expression of the chicken delta-crystallin gene 1 injected into the nuclei of mouse cells is lens specific. Coinjection of GC box-containing DNA fragments from delta-crystallin, simian virus 40 early, and herpes simplex virus type 1 tk promoters effectively suppressed delta-crystallin expression in the lens, but coinjection with DNA fragments not containing the GC box did not. This suppression was likely due to the competition of an Sp1-like transcription factor(s) and indicates involvement of the apparently ubiquitous factor(s) in the tissue-specific expression of the delta-crystallin gene.
Mol Cell Biol 1986 Nov
PMID:In vivo competition of delta-crystallin gene expression by DNA fragments containing a GC box. 302 36

The location in the mouse genome of the 149-base pair MES-1 element, previously isolated by its ability to restore expression to an enhancerless selectable gene, was analyzed. The active moiety of the single-copy MES-1 element is located between the 5' ends of two divergent transcription units, SURF-1 and SURF-2, both of which specify more than one mRNA species by differential splicing. The heterogeneous 5' ends of the SURF transcripts are separated by only 50 to 75 base pairs, and this sequence possesses a high G + C content (65%) and contains neither the TATA and CAAT box motifs normally associated with many highly expressed genes nor the GC box motif (Sp1-binding site) associated with a number of housekeeping genes. Although MES-1 appears to have enhancerlike properties when linked to heterologous genes, its normal genomic location suggests that it functions as a bidirectional promoter. Thus, MES-1 may represent a new class of enhancer-promoter element.
Mol Cell Biol 1986 Dec
PMID:The MES-1 murine enhancer element is closely associated with the heterogeneous 5' ends of two divergent transcription units. 302 60

The sequences of four histone H3 genes coding for the replication variant proteins H3.1 and H3.2 have been determined. Three of these genes, two coding for H3.1 proteins and one for an H3.2 protein, are located on chromosome 13 and expressed at low levels. The fourth gene, encoding an H3.2 protein, is located on chromosome 3 and expressed at a high level. The coding regions of the three genes on chromosome 13 are more similar to each other than to the H3 gene on chromosome 3, and equally divergent from it, suggesting that either gene duplication or gene conversion has occurred since the genes were dispersed onto two chromosomes. A 14-base sequence including the CCAAT sequence and located 5' to the genes on chromosome 13 has been conserved. The histone H3 gene on chromosome 3 has multiple potential binding sites for the Sp1 transcription factor. The coding regions show greater than 95% conservation among the four genes. This is due to the strict pattern of codon usage and the presence of two long (greater than 60 base) regions of completely conserved nucleic acid sequence. These conserved regions in the coding sequence may have an important functional role at the mRNA or DNA level.
J Mol Evol 1986
PMID:Sequences of four mouse histone H3 genes: implications for evolution of mouse histone genes. 302 55

To study the factors which influence the coordinately and developmentally regulated expression of the three adjacent fibrinogen genes, we have defined the functional regions of the gamma-fibrinogen promoter and the proteins which bind to them. Using a series of 5' and internal deletion mutations, we found that sequences between 88 and 43 base pairs (bp) upstream of the gamma-fibrinogen transcription initiation site functioned in cis to direct properly initiated mRNA accumulation in transfected hepatocytes. The efficient function of these sequences was highly distance dependent, since transcriptional activity decreased by 92% when they were moved 32 bp upstream of the TATA box. We demonstrated that two known and one putative transcriptional factors interacted with this 47-bp sequence. The transcription factor Sp1 interacted with sequences between -51 and -46 as demonstrated by protection from DNase I digestion with the purified protein. Directly adjacent to the Sp1 site, between nucleotides -66 and -53, there was a sequence which bound a CAAT-binding factor. Finally, sequences just 5' to the CAAT factor-binding site interacted with the adenovirus major late transcriptional factor as previously demonstrated. Internal deletion mutations which disrupt these interactions diminished the activity of the promoter in vivo. One consequence of the interaction of these proteins is that a bend is placed in the DNA at or near their sites of interaction.
Mol Cell Biol 1988 Jun
PMID:Sp1, a CAAT-binding factor, and the adenovirus major late promoter transcription factor interact with functional regions of the gamma-fibrinogen promoter. 304 86

We cloned and characterized a mouse cytosolic malate dehydrogenase (cMDHase) (EC 1.1.1.37) gene, which is about 14 x 10(3) base-pairs long and is interrupted by eight introns. The 5' and 3' flanking regions and the exact sizes and boundaries of the exon blocks, including the transcription-initiation sites, were determined. The 5' end of the gene lacks the TATA and CAAT boxes characteristic of eukaryotic promoters, but contains G + C-rich sequences, one putative binding site for a cellular transcription factor, Sp1, and at least two major transcription-initiation sites. The sequences around the transcription-initiation sites are compatible with the formation of a number of potentially stable stem-loop structures. We compared structural organization of the mouse cMDHase gene with that of the previously characterized mouse mitochondrial MDHase (mMDHase) gene, and found that the conservation of intron positions spreads across much of the two genes. This result suggests that a common ancestral gene for the cytosolic MDHase and the mitochondrial MDHase was broken up by introns, before the divergence. We also compared the nucleotide sequence of the promoter region of the mouse cytosolic MDHase gene with that of the other three mouse genes coding for isoenzymes participating in the malate-aspartate shuttle, i.e. mitochondrial MDHase, cytosolic and mitochondrial aspartate aminotransferases (cAspATase and mAspATase). We found that highly conserved regions are present in the promoter region of the cAspATase gene.
J Mol Biol 1988 Aug 05
PMID:Structural organization of the mouse cytosolic malate dehydrogenase gene: comparison with that of the mouse mitochondrial malate dehydrogenase gene. 317 22

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