T-rich Stretch Research Articles

DNA-Binding Specificities of Human Transcription Factors

Although the proteins that read the gene regulatory code, transcription factors (TFs), have been largely identified, it is not well known which sequences TFs can recognize. We have analyzed the sequence-specific binding of human TFs using high-throughput SELEX and ChIP sequencing. A total of 830 binding profiles were obtained, describing 239 distinctly different binding specificities. The models represent the majority of human TFs, approximately doubling the coverage compared to existing systematic studies. Our results reveal additional specificity determinants for a large number of factors for which a partial specificity was known, including a commonly observed A- or T-rich stretch that flanks the core motifs. Global analysis of the data revealed that homodimer orientation and spacing preferences, and base-stacking interactions, have a larger role in TF-DNA binding than previously appreciated. We further describe a binding model incorporating these features that is required to understand binding of TFs to DNA.

RNA Folding in Transcription Elongation Complex: IMPLICATION FOR TRANSCRIPTION TERMINATION

Intrinsic transcription termination signal in DNA consists of a short inverted repeat followed by a T-rich stretch. Transcription of this sequence by RNA polymerase (RNAP) results in formation of a "termination hairpin" (TH) in the nascent RNA and in rapid dissociation of the transcription elongation complex (EC) at termination points located 7-8 nt downstream of the base of TH stem. RNAP envelops 15 nt of the RNA following RNA growing 3'-end, suggesting that folding of the TH is impeded by a tight protein environment when RNAP reaches the termination points. To monitor TH folding under this constraint, we halted Escherichia coli ECs at various distances downstream from a TH and treated them with single-strand specific RNase T1. The EC interfered with TH formation when halted at 6, 7, and 8, but not 9, nt downstream from the base of the potential stem. Thus, immediately before termination, the downstream arm of the TH is protected from complementary interactions with the upstream arm. This protection makes TH folding extremely sensitive to the sequence context, because the upstream arm easily engages in competing interactions with the rest of the nascent RNA. We demonstrate that by de-synchronizing TH formation and transcription of the termination points, this subtle competition significantly affects the efficiency of transcription termination. This finding can explain previous puzzling observations that sequences far upstream of the TH or point mutations in the terminator that preserve TH stability affect termination. These results can help understand other time sensitive co-transcriptional processes in pro- and eukaryotes.

A motif within a complex promoter from the oomycete Phytophthora infestans determines transcription during an intermediate stage of sporulation

Sporulation in Phytophthora infestans is associated with a major remodeling of the transcriptome. To better understand promoter structure and how sporulation-specific expression is determined in this organism, the Pks1 gene was analyzed. Pks1 encodes a protein kinase that is induced at an intermediate stage of sporulation, prior to sporangium maturation. Major and minor transcription start sites mapped throughout the promoter, which contains many T-rich stretches and Inr-like elements. Within the T-rich region are several motifs which bound nuclear proteins in EMSA. Tests of modified promoters in transformants implicated a CCGTTG located 110-nt upstream of the transcription start point as a major regulator of sporulation-specific transcription. The motif also bound a sporulation-specific nuclear protein complex. A bioinformatics analysis indicated that the motif is highly over-represented within co-expressed promoters, in which it predominantly resides 100–300-nt upstream of transcription start sites. Other sequences, such as a CATTTGTT motif, also bound nuclear proteins but did not play an essential role in spore-specific expression.

Epigenetic Silencing of Gene Expression in Entamoeba histolytica

Transcriptional silencing of an amebapore (ap-a) gene occurred in Entamoeba histolytica following the transfection of plasmids containing a DNA segment (473 bp) homologous to the 5' upstream region of the gene. This segment contains the promoter region of the ap-a gene, a T-rich stretch, followed by a truncated SINE1 (short interspersed element) that is transcribed from the opposite strand. The downstream silencing of the ap-a gene did not occur with plasmids containing the entire SINE1 sequence or lacking the entire SINE1 sequences including the T-rich stretch. Such plasmids promoted the overexpression of the ap-a gene. The transcription of the SINE element required both the T-rich stretch as well as sequences from the 5' end of SINE. RNA extracts from gene-silenced cultures showed small amounts of short (approximately 140 nt), single-stranded molecules with homology to SINE1 transcripts but no siRNA. Chromatin immunoprecipitation (ChIP) analysis of silenced G3 trophozoites with an antibody against methylated K4 of histone H3 revealed a demethylation of K4 at the domain of the ap-a gene indicating transcriptional inactivation. These results suggest the involvement of the SINE1 element in triggering the gene silencing and the role of histone modification in its epigenetic maintenance. The avirulent phenotype of the silenced trophozoites was demonstrated in various assays and the results suggest they may have a potential use for vaccination.

Involvement of a Short Interspersed Element in Epigenetic Transcriptional Silencing of the Amoebapore Gene in Entamoeba histolytica

Transcriptional silencing of an amoebapore (ap-a) gene occurred in Entamoeba histolytica following the transfection of plasmids containing a DNA segment (473 bp) homologous to the 5' upstream region of the gene (R. Bracha, Y. Nuchamowitz, and D. Mirelman, Eukaryot. Cell 2:295-305, 2003). This segment contains the promoter region of the ap-a gene, a T-rich stretch, followed by a truncated SINE1 (short interspersed element 1) that is transcribed from the antisense strand. Transfection of plasmids containing truncated SINE1 sequences which lack their 3' regulatory elements upstream of the ap-a gene was essential for the downstream silencing of the ap-a gene while transfection with plasmids containing the entire SINE1 sequence or without the T-rich stretch promoted the overexpression of the ap-a gene. Both the T-rich stretch and sequences of the 5' SINE1 were essential for the transcription of SINE1. RNA extracts from gene-silenced cultures showed small amounts of short (approximately 140-nucleotide), single-stranded molecules with homology to SINE1 but no short interfering RNA. Chromatin immunoprecipitation analysis with an antibody against methylated K4 of histone H3 showed a demethylation of K4 at the domain of the ap-a gene, indicating transcriptional inactivation. These results suggest the involvement of SINE1 in triggering the gene silencing and the role of histone modification in its epigenetic maintenance.

An Entamoeba histolytica LINE/SINE pair inserts at common target sites cleaved by the restriction enzyme-like LINE-encoded endonuclease.

The non-long-terminal-repeat (non-LTR) retrotransposons (also called long interspersed repetitive elements [LINEs]) are among the oldest retroelements. Here we describe the properties of such an element from a primitive protozoan parasite, Entamoeba histolytica, that infects the human gut. This 4.8-kb element, called EhLINE1, is present in about 140 copies dispersed throughout the genome. The element belongs to the R4 clade of non-LTR elements. It has a centrally located reverse transcriptase domain and a restriction enzyme-like endonuclease (EN) domain at the carboxy terminus. We have cloned and expressed a 794-bp fragment containing the EN domain in Escherichia coli. The purified protein could nick supercoiled pBluescript DNA to yield open circular and linear DNAs. The conserved PDX(12-14)D motif was required for activity. Genomic sequences flanking the sites of insertion of EhLINE1 and the putative partner short interspersed repetitive element (SINE), EhSINE1, were analyzed. Both elements resulted in short target site duplications (TSD) upon insertion. A common feature was the presence of a short T-rich stretch just upstream of the TSD in most insertion sites. By sequence analysis an empty target site in the E. histolytica genome, known to be occupied by EhSINE1, was identified. When a 176-bp fragment containing the empty site was used as a substrate for EN, it was prominently nicked on the bottom strand at the precise point of insertion of EhSINE1, showing that this SINE could use the LINE-encoded endonuclease for its insertion. The nick on the bottom strand was toward the right of the TSD, which is uncommon. The lack of strict target site-specificity of the restriction enzyme-like EN encoded by EhLINE1 is also exceptional. A model for retrotransposition of EhLINE1/SINE1 is presented.

DNA-Binding proteins possibly involved in regulation of the post-logarithmic-phase expression of lipoprotein P35 in Borrelia burgdorferi.

Previously, we have shown that the transcription of p35, a lipoprotein gene of Borrelia burgdorferi, is upregulated or initiated during the post-logarithmic bacterial growth phase in vitro. To identify potential regulatory factors, we examined the formation of DNA-protein complexes by electromobility shift assay, using a 157-bp DNA fragment that spans the p35 promoter region and cell-free extracts of spirochetes harvested from both logarithmic and stationary growth phases. The binding properties of the extracts with the promoter region of the flaB gene, a constitutively expressed, growth-phase-independent gene, were also compared. The results from these experiments demonstrate that B. burgdorferi stationary-phase cell-free extracts have a growth-phase-dependent DNA binding protein that interacts specifically with the p35 promoter region. We show, in addition, that a segment from the 157-bp p35 promoter region which contains both a T-rich stretch and an inverted repeat is able to compete off the stationary-phase-specific complex when the segment is present in molar excess.

Molecular analysis of the gene family of the signal recognition particle (SRP) RNA of tomato.

The sequence variants of the signal recognition particle (SRP) RNA gene family from four tomato cultivars have been isolated and characterized which indicated the existence of SRP RNA pseudogenes. Sequence analysis revealed two conserved sequence motifs in the upstream region, a TATA-like box and an upstream sequence element (USE), 'TCCCACATCG', both located at a conserved distance to the transcription start point. These elements are identical to the DNA-dependent RNA polymerase III (pol III)-specific promoters of U-rich small nuclear RNA (UsnRNA) genes of plants. Moreover, T-rich stretches are found at the 3' end of the coding regions of the SRP RNA genes which could act as typical pol III termination signals. These findings and recent results from site-directed mutation analysis of the SRP RNA genes from Arabidopsis thaliana indicate that, in contrast to mammalian systems, plant pol III SRP RNA genes are most probably regulated by external promoter elements. According to the identical promoter organization between plant U3-, U6snRNA, MRP-like RNA and SRP RNA genes, one can group these genes into the 'pol III(EXT)USE' subclass of externally regulated USE-dependent pol III genes.

The rRNA Enhancer Regulates rRNA Transcription in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, the rRNA genes are organized as a tandem array of head-to-tail repeats. An enhancer of rRNA transcription is present just at the end of each transcription unit, 2 kb away from the next one. This enhancer is unusual for S. cerevisiae in that it acts both upstream and downstream of, and even across, genes. The role of the enhancer in the nutritional regulation of rRNA transcription was studied by introducing a centromere plasmid carrying two rRNA minigenes in tandem, flanking a single enhancer, into cells. Analysis of the transcripts from the two minigenes showed that the enhancer was absolutely required for the stimulation of transcription of rRNA that occurs when cells are shifted from a poor carbon source to a good carbon source. While full enhancer function is provided by a 45-bp region at the 3' end of the 190-bp enhancer, some activity was also conferred by other elements, including both a T-rich stretch and a region containing the binding sites for the proteins Reb1p and Abf1p. We conclude that the enhancer is composed of redundant elements and that it is a major element in the regulation of rRNA transcription.

The rRNA enhancer regulates rRNA transcription in Saccharomyces cerevisiae.

In Saccharomyces cerevisiae, the rRNA genes are organized as a tandem array of head-to-tail repeats. An enhancer of rRNA transcription is present just at the end of each transcription unit, 2 kb away from the next one. This enhancer is unusual for S. cerevisiae in that it acts both upstream and downstream of, and even across, genes. The role of the enhancer in the nutritional regulation of rRNA transcription was studied by introducing a centromere plasmid carrying two rRNA minigenes in tandem, flanking a single enhancer, into cells. Analysis of the transcripts from the two minigenes showed that the enhancer was absolutely required for the stimulation of transcription of rRNA that occurs when cells are shifted from a poor carbon source to a good carbon source. While full enhancer function is provided by a 45-bp region at the 3' end of the 190-bp enhancer, some activity was also conferred by other elements, including both a T-rich stretch and a region containing the binding sites for the proteins Reb1p and Abf1p. We conclude that the enhancer is composed of redundant elements and that it is a major element in the regulation of rRNA transcription.

The complete nucleotide sequence of chicken ribosomal protein L7a gene and the multiple factor binding sites in its 5′-flanking region

The nucleotide sequence of the gene encoding chicken ribosomal protein L7a was determined. The gene contains eight exons and seven introns, which spread over 3613 nucleotides. The transcription initiation sites were located on four consecutive nucleotides GCCC, which are at the 5′ terminus of a short polypyrimidine tract of eight base-pairs flanked by G + C-rich regions. Neither a canonical TATA nor a CAAT box was found in the 5′-flanking region. Instead, a short A + T-rich stretch was found at the position where the TATA box is expected to be. There is an intensive nuclear protein binding motif repeated four times in the region −134 to −50. This motif is common to many ribosomal protein genes and may play an important role in the control of ribosomal protein gene expression.

Elements involved in anin vitroblock to transcription elongation at the end of the L1 mRNA family of adenovirus 2

Using the 3' end of the L1 mRNA family of adenovirus 2 (Ad2) as a model system, we investigated transcription elongation following a poly(A) signal in a cell-free system. The results show that RNA polymerase II can halt transcription elongation at a T-rich stretch in the non-coding DNA strand 20 nucleotides downstream of the poly(A) signal. The block to transcription elongation is enhanced when Sarkosyl is included in the elongation reaction. Deletion studies narrowed the region which directs the elongation block at the T-rich stretch, to an upstream fragment of 53 nucleotides that is very dA-rich and also contains a functional poly(A) signal. The deletion studies and analysis by site-directed mutagenesis indicate that in the present system, RNA secondary structure, the stretch of T's and the poly(A) signal are not the dominant elements responsible for the elongation block. The block to transcription elongation at the T-rich stretch was also shown to be 5 times more effective in an uninfected extract than in an Ad2 infected extract, which is reminiscent of the in vivo situation and is consistent with the suggestion that a trans-acting factor is involved in modulating the elongation block at the T-rich stretch.

Homeodomain binding sites in the 5′ flanking region of the Bombyx mori silk fibroin light-chain gene

Multiple A + T-rich stretches in the 5' flanking region of the Bombyx mori fibroin light-chain gene have been shown to bind two Drosophila homeodomain proteins, EVE (even-skipped) and ZEN (zerknüllt), with high affinities. Some of these sites fall into a class that has the established consensus sequence of the binding sites (TCAATTAAAT) for a diverse group of Drosophila homeodomain proteins, while others are quite heterogenous except that they all possess a core TAAT motif. Since clusters of homeodomain binding sites can also be found in the promoters of other silk protein genes, the fibroin gene and the sericin-1 gene, these observations suggest a possible involvement of some homeobox genes in the regulation of a group of silk protein genes.

Sequence similarities among monkey ori-enriched ( ors) fragments

Nucleotide sequences have been determined for eight ors ( ori-enriched sequence) fragments isolated from monkey DNA by a method that was designed to enrich for origins of DNA replication [Kaufmann et al., Mol. Cell. Biol. 5 (1985) 721–727]. Evidence has been presented that some or possibly all of these sequences can serve, albeit inefficiently, as oris in vivo [Frappier and Zannis-Hadjopoulos, Proc. Natl. Acad. Sci. USA 84 (1987) 6668–6672]. Two of the fragments were found to contain the long terminal repeat-like elements of the ‘O-family’ of moderately repetitive sequences that are present in human DNA as a transposon-like element [Paulson et al., Nature 315 (1985) 359–361]. Extensive pair-wise comparisons of the sequences failed to detect any statistically significant common sequences, except for long asymmetrically distributed A + T-rich stretches. Nonetheless, when the ors fragments were examined for the presence of published consensus sequences, seven of eight were found to contain the control sequence described by Dierks et al. [Cell 32 (1983) 695–706], and the same seven of eight were found to contain both the scaffold attachment region T consensus [Gasser and Laemmli, Cell 46 (1986) 521–530] and the minimal Saccharomyces cerevisiae autonomously replicating sequence consensus [e.g., Palzkill and Newlon, Cell 53 (1988) 441–450].

Molecular cloning, sequence analysis, and functional expression of a novel growth regulator, oncostatin M.

Oncostatin M is a polypeptide of Mr approximately 28,000 that acts as a growth regulator for many cultured mammalian cells. We report the cDNA and genomic cloning, sequence analysis, and functional expression in heterologous cells of oncostatin M. cDNA clones were isolated from mRNA of U937 cells that had been induced to differentiate into macrophagelike cells by treatment with phorbol 12-myristate 13-acetate, and a genomic clone was also isolated from human brain DNA. Sequence analysis of these clones established the 1,814-base-pair cDNA sequence as well as exon boundaries. This sequence predicted that oncostatin M is synthesized as a 252-amino-acid polypeptide, with a 25-residue hydrophobic sequence resembling a signal peptide at the N terminus. The predicted oncostatin M amino acid sequence shared no homology with other known proteins, but the sequence of the 3' noncoding region of the cDNA contained an A + T-rich stretch with sequence motifs found in the 3' untranslated regions of many cytokine and lymphokine cDNAs. Oncostatin M mRNA of approximately 2 kilobase pairs was detected in phorbol 12-myristate 13-acetate-treated U937 cells and in activated human T cells. Transfection of cDNA encoding the oncostatin M precursor into COS cells resulted in the secretion of proteins with the structural and functional properties of oncostatin M. The unique amino acid sequence, expression by lymphoid cells, and growth-regulatory activities of oncostatin M suggest that it is a novel cytokine.

Molecular cloning, sequence analysis, and functional expression of a novel growth regulator, oncostatin M.

Oncostatin M is a polypeptide of Mr approximately 28,000 that acts as a growth regulator for many cultured mammalian cells. We report the cDNA and genomic cloning, sequence analysis, and functional expression in heterologous cells of oncostatin M. cDNA clones were isolated from mRNA of U937 cells that had been induced to differentiate into macrophagelike cells by treatment with phorbol 12-myristate 13-acetate, and a genomic clone was also isolated from human brain DNA. Sequence analysis of these clones established the 1,814-base-pair cDNA sequence as well as exon boundaries. This sequence predicted that oncostatin M is synthesized as a 252-amino-acid polypeptide, with a 25-residue hydrophobic sequence resembling a signal peptide at the N terminus. The predicted oncostatin M amino acid sequence shared no homology with other known proteins, but the sequence of the 3' noncoding region of the cDNA contained an A + T-rich stretch with sequence motifs found in the 3' untranslated regions of many cytokine and lymphokine cDNAs. Oncostatin M mRNA of approximately 2 kilobase pairs was detected in phorbol 12-myristate 13-acetate-treated U937 cells and in activated human T cells. Transfection of cDNA encoding the oncostatin M precursor into COS cells resulted in the secretion of proteins with the structural and functional properties of oncostatin M. The unique amino acid sequence, expression by lymphoid cells, and growth-regulatory activities of oncostatin M suggest that it is a novel cytokine.

Structural organization of upstream exons and distribution of transcription start sites in the chicken c-myb gene.

We mapped and sequenced three upstream exons of the chicken c-myb gene and the regions flanking the first coding exon. We found multiple potential binding sites for transcription factors in the 5'-noncoding region, a T-rich stretch of 78 base pairs (bp) (68% T) in the first intron, and four fairly long open reading frames in the antisense direction of the first coding exon and its flanking regions. Three major transcription start sites, contained within a single 11-bp region, were identified by S1 nuclease analysis and primer extension. A sequence comparison of the avian and murine c-myb genes revealed a highly conserved sequence of 124 bp in the 5'-noncoding region. Its location between the putative transcription factor binding sites and the major transcription start sites suggests that it may play an important regulatory role in c-myb expression.

Relation of chromosome structure and gene expression

We have been able to map specific DNA fragments at the bases of chromatin loops with the help of a novel extraction procedure by using lithium-3',5'-diiodosalicylate. One such scaffold-attached region (SAR) is found in the non-transcribed spacer in each repeat of the histone gene cluster, on a 657 base pair (b.p.) restriction fragment. Exonuclease III digestion has localized two protein-binding domains on the SAR of the histone cluster. Each covers approximately 200 b.p. and they are separated by a nuclease-accessible region of about 100 b.p. These domains are rich in sequences closely related to the topoisomerase II cleavage consensus. We have studied the scaffold association of three developmentally regulated genes of Drosophila melanogaster: alcohol dehydrogenase (Adh), the homoeotic gene fushi tarazu (ftz) and Sgs-4, a gene encoding one of the glue proteins secreted by third-instar larvae. We find regions attached to the nuclear scaffold (SARS) both 5' and 3' of all three genes, defining small domains ranging from 4.5 to 13 kilobases. In the case of Adh, a gene with two promoters, we find two upstream and two downstream SARS. Those 5' of the gene co-map with regulatory regions for the adult and the larval transcripts, respectively. For Sgs-4, the 5' SAR covers 866 b.p. immediately upstream of the transcript, and encompasses the 200 b.p. regulatory region defined by two deletion mutants that produce little or no Sgs-4 protein. In ftz the 5' SAR is found 4.8 kilobases upstream of the start of transcription within a 2.5 kilobase element required for a high level of ftz expression in the early embryo. Sequence analysis of five upstream SARS reveals clusters of sequences closely related to the cleavage consensus of topoisomerase II. In addition, they contain multiple copies of two sequence motifs: a specific 10 b.p. A-rich sequence, and another 10 b.p. T-rich stretch. In conclusion, the intimate association of the SAR with the upstream/enhancer elements, the presence of clustered sequences highly homologous to the topoisomerase II cleavage consensus, and the localization of topoisomerase II in the scaffold, suggest a structure-function relation between chromosome organization and gene expression.

Cohabitation of scaffold binding regions with upstream/enhancer elements of three developmentally regulated genes of D. melanogaster

We find DNA fragments attached to the nuclear scaffold (SARs) both 5′ and 3′ of three Drosophila genes, defining looped domains ranging from 4.5 to 13 kb. For the two-promoter-containing gene Adh ( alcohol dehydrogenase), we find two upstream and two downstream SARs. For Sgs-4, the 5′ SAR covers 866 bp immediately upstream of the transcript, and in the case of fushi tarazu, the 5′ SAR is found on a small fragment 4.8 kb upstream of the start of transcription. These four upstream scaffold-attached fragments comap with enhancer-like regulatory sequences. Sequence analysis of five upstream SARs reveals clusters of sequences closely related to the cleavage consensus of topoisomerase II, several copies of a specific 10 bp A-rich sequence (AATAAA T CAAA), and another 10 bp T-rich stretch.

Removal of a 67-base-pair sequence in the noncoding region of protooncogene fos converts it to a transforming gene.

Transformation of fibroblasts by protooncogene fos (c-fos) requires the linkage of viral long terminal repeat (LTR) sequences and interruption of 3'-noncoding sequences. We have identified an A + T-rich stretch of 67 nucleotides, located 627-693 base pairs downstream from the coding domain and 123-189 base pairs upstream from the putative poly(A) addition site, removal of which confers transforming activity to the c-fos gene. A novel regulation of the expression of the c-fos gene is proposed, which may be functional in vivo to prevent the gene from becoming an oncogene.