Analysis of the mouse dhfr promoter region: existence of a divergently transcribed gene

Analysis of Promoters of Arabidopsis thaliana Divergent Gene Pair SERAT3;2 and IDH-III Shows SERAT3;2 Promoter is Nested Within the IDH-III Promoter

Intergenic regions of divergent gene pairs show bidirectional promoter activity but whether regulatory sequences for gene expression in opposite directions are shared is not established. In this study, promoters of divergently arranged gene pair At4g35640-At4g35650 (SERAT3;2-IDH-III) of Arabidopsis thaliana were analyzed to identify overlapping regulatory regions. Both genes showed the highest expression in flower buds and flowers. 5' RACE experiments extended the intergenic region from 161 bp shown in TAIR annotation to 512 bp. GUS analysis of transgenic A. thaliana plants carrying the 691 bp fragment (512 bp intergenic region plus 5' UTR of both the genes) linked to uidA gene revealed that SERAT3;2 promoter drives gene expression in the tapetum, whereas IDH-III promoter functions specifically in microspores/pollen. Serial 5' deletion of the 691 bp fragment showed SERAT3;2 promoter extends up to -355 position, whereas IDH-III promoter encompasses the 512 bp intergenic region. In transgenics, uidA transcript levels were lower than native SERAT3;2 and IDH-III transcripts indicating presence of additional cis regulatory elements beyond the 691 bp fragment. The present study demonstrated for the first time occurrence of a nested promoter in plants and identified a novel bidirectional promoter capable of driving gene expression in tapetum and microspores/pollen.

An intergenic region shared by At4g35985 and At4g35987 in Arabidopsis thaliana is a tissue specific and stress inducible bidirectional promoter analyzed in transgenic arabidopsis and tobacco plants

On chromosome 4 in the Arabidopsis genome, two neighboring genes (calmodulin methyl transferase At4g35987 and senescence associated gene At4g35985) are located in a head-to-head divergent orientation sharing a putative bidirectional promoter. This 1258 bp intergenic region contains a number of environmental stress responsive and tissue specific cis-regulatory elements. Transcript analysis of At4g35985 and At4g35987 genes by quantitative real time PCR showed tissue specific and stress inducible expression profiles. We tested the bidirectional promoter-function of the intergenic region shared by the divergent genes At4g35985 and At4g35987 using two reporter genes (GFP and GUS) in both orientations in transient tobacco protoplast and Agro-infiltration assays, as well as in stably transformed transgenic Arabidopsis and tobacco plants. In transient assays with GFP and GUS reporter genes the At4g35985 promoter (P85) showed stronger expression (about 3.5 fold) compared to the At4g35987 promoter (P87). The tissue specific as well as stress responsive functional nature of the bidirectional promoter was evaluated in independent transgenic Arabidopsis and tobacco lines. Expression of P85 activity was detected in the midrib of leaves, leaf trichomes, apical meristemic regions, throughout the root, lateral roots and flowers. The expression of P87 was observed in leaf-tip, hydathodes, apical meristem, root tips, emerging lateral root tips, root stele region and in floral tissues. The bidirectional promoter in both orientations shows differential up-regulation (2.5 to 3 fold) under salt stress. Use of such regulatory elements of bidirectional promoters showing spatial and stress inducible promoter-functions in heterologous system might be an important tool for plant biotechnology and gene stacking applications.

MSH3 polymorphisms and protein levels affect CAG repeat instability in Huntington's disease mice

Expansions of trinucleotide CAG/CTG repeats in somatic tissues are thought to contribute to ongoing disease progression through an affected individual's life with Huntington's disease or myotonic dystrophy. Broad ranges of repeat instability arise between individuals with expanded repeats, suggesting the existence of modifiers of repeat instability. Mice with expanded CAG/CTG repeats show variable levels of instability depending upon mouse strain. However, to date the genetic modifiers underlying these differences have not been identified. We show that in liver and striatum the R6/1 Huntington's disease (HD) (CAG)∼100 transgene, when present in a congenic C57BL/6J (B6) background, incurred expansion-biased repeat mutations, whereas the repeat was stable in a congenic BALB/cByJ (CBy) background. Reciprocal congenic mice revealed the Msh3 gene as the determinant for the differences in repeat instability. Expansion bias was observed in congenic mice homozygous for the B6 Msh3 gene on a CBy background, while the CAG tract was stabilized in congenics homozygous for the CBy Msh3 gene on a B6 background. The CAG stabilization was as dramatic as genetic deficiency of Msh2. The B6 and CBy Msh3 genes had identical promoters but differed in coding regions and showed strikingly different protein levels. B6 MSH3 variant protein is highly expressed and associated with CAG expansions, while the CBy MSH3 variant protein is expressed at barely detectable levels, associating with CAG stability. The DHFR protein, which is divergently transcribed from a promoter shared by the Msh3 gene, did not show varied levels between mouse strains. Thus, naturally occurring MSH3 protein polymorphisms are modifiers of CAG repeat instability, likely through variable MSH3 protein stability. Since evidence supports that somatic CAG instability is a modifier and predictor of disease, our data are consistent with the hypothesis that variable levels of CAG instability associated with polymorphisms of DNA repair genes may have prognostic implications for various repeat-associated diseases.

The genetic instability of repetitive DNA sequences in particular genes can lead to numerous neurodegenerative, neurological, and neuromuscular diseases. These diseases show progressively increasing severity of symptoms through the life of the affected individual, a phenomenon that is linked with increasing instability of the repeated sequences as the person ages. There is variability in the levels of this instability between individuals—the source of this variability is unknown. We have shown in a mouse model of repeat instability that small differences in a certain DNA repair gene, MSH3, whose protein is known to fix broken DNA, can lead to variable levels of repeat instability. These DNA repair variants lead to different repair protein levels, where lower levels lead to reduced repeat instability. Our findings reveal that such naturally occurring variations in DNA repair genes in affected humans may serve as a predictor of disease progression. Moreover, our findings support the concept that pharmacological reduction of MSH3 protein should reduce repeat instability and disease progression.

Control of Transcriptional Elongation by RNA Polymerase II: A Retrospective

The origins of our current understanding of control of transcription elongation lie in pioneering experiments that mapped RNA polymerase II on viral and cellular genes. These studies first uncovered the surprising excess of polymerase molecules that we now know to be situated at the at the 5' ends of most genes in multicellular organisms. The pileup of pol II near transcription start sites reflects a ubiquitous bottle-neck that limits elongation right at the start of the transcription elongation. Subsequent seminal work identified conserved protein factors that positively and negatively control the flux of polymerase through this bottle-neck, and make a major contribution to control of gene expression.

A comparative analysis of divergently-paired genes (DPGs) among Drosophila and vertebrate genomes

Background

Divergently-paired genes (DPGs) are defined as two adjacent genes that are transcribed toward the opposite direction (or from different DNA strands) and shared their transcription start sites (TSSs) less than 1,000 base pairs apart. DPGs are products of a common organizational feature among eukaryotic genes yet to be surveyed across divergent genomes over well-defined evolutionary distances since mutations in the sequence between a pair of DPGs may result in alternations in shared promoters and thus affect the function of both genes. By sharing promoters, the gene pairs take the advantage of co-regulation albeit bearing doubled mutational burdens in maintaining their normal functions.

Results

Drosophila melanogaster has a significant fraction (31.6% of all genes) of DPGs which are remarkably conserved relative to its gene density as compared to other eukaryotes. Our survey and comparative analysis revealed different evolutionary patterns among DPGs between insect and vertebrate lineages. The conservation of DPGs in D. melanogaster is of significance as they are mostly housekeeping genes characterized by the absence of TATA box in their promoter sequences. The combination of Initiator and Downstream Promoter Element may play an important role in regulating DPGs in D. melanogaster, providing an excellent niche for studying the molecular details for transcription regulations.

Conclusion

DPGs appear to have arisen independently among different evolutionary lineages, such as the insect and vertebrate lineages, and exhibit variable degrees of conservation. Such architectural organizations, including convergently-paired genes (CPGs) may associate with transcriptional regulation and have significant functional relevance.

Searching for bidirectional promoters in Arabidopsis thaliana

Background

A "bidirectional gene pair" is defined as two adjacent genes which are located on opposite strands of DNA with transcription start sites (TSSs) not more than 1000 base pairs apart and the intergenic region between two TSSs is commonly designated as a putative "bidirectional promoter". Individual examples of bidirectional gene pairs have been reported for years, as well as a few genome-wide analyses have been studied in mammalian and human genomes. However, no genome-wide analysis of bidirectional genes for plants has been done. Furthermore, the exact mechanism of this gene organization is still less understood.

Results

We conducted comprehensive analysis of bidirectional gene pairs through the whole Arabidopsis thaliana genome and identified 2471 bidirectional gene pairs. The analysis shows that bidirectional genes are often coexpressed and tend to be involved in the same biological function. Furthermore, bidirectional gene pairs associated with similar functions seem to have stronger expression correlation. We pay more attention to the regulatory analysis on the intergenic regions between bidirectional genes. Using a hierarchical stochastic language model (HSL) (which is developed by ourselves), we can identify intergenic regions enriched of regulatory elements which are essential for the initiation of transcription. Finally, we picked 27 functionally associated bidirectional gene pairs with their intergenic regions enriched of regulatory elements and hypothesized them to be regulated by bidirectional promoters, some of which have the same orthologs in ancient organisms. More than half of these bidirectional gene pairs are further supported by sharing similar functional categories as these of handful experimental verified bidirectional genes.

Conclusion

Bidirectional gene pairs are concluded also prevalent in plant genome. Promoter analyses of the intergenic regions between bidirectional genes could be a new way to study the bidirectional gene structure, which may provide a important clue for further analysis. Such a method could be applied to other genomes.

Systematic analysis of head-to-head gene organization: evolutionary conservation and potential biological relevance

Several “head-to-head” (or “bidirectional”) gene pairs have been studied in individual experiments, but genome-wide analysis of this gene organization, especially in terms of transcriptional correlation and functional association, is still insufficient. We conducted a systematic investigation of head-to-head gene organization focusing on structural features, evolutionary conservation, expression correlation and functional association. Of the present 1,262, 1,071, and 491 head-to-head pairs identified in human, mouse, and rat genomes, respectively, pairs with 1– to 400–base pair distance between transcription start sites form the majority (62.36%, 64.15%, and 55.19% for human, mouse, and rat, respectively) of each dataset, and the largest group is always the one with a transcription start site distance of 101 to 200 base pairs. The phylogenetic analysis among Fugu, chicken, and human indicates a negative selection on the separation of head-to-head genes across vertebrate evolution, and thus the ancestral existence of this gene organization. The expression analysis shows that most of the human head-to-head genes are significantly correlated, and the correlation could be positive, negative, or alternative depending on the experimental conditions. Finally, head-to-head genes statistically tend to perform similar functions, and gene pairs associated with the significant cofunctions seem to have stronger expression correlations. The findings indicate that the head-to-head gene organization is ancient and conserved, which subjects functionally related genes to correlated transcriptional regulation and thus provides an exquisite mechanism of transcriptional regulation based on gene organization. These results have significantly expanded the knowledge about head-to-head gene organization. Supplementary materials for this study are available at http://www.scbit.org/h2h.

It was commonly assumed that higher eukaryotic genomes are loosely organized and genes are interspersed in the whole genome sequences. However, experiments have continuously identified eukaryotic head-to-head gene pairs with genes located closely next to each other, possibly sharing a same promoter; and preliminary genomic surveys have even proved head-to-head gene pair to be a common feature of human genome. The authors report a systematic investigation of head-to-head gene pairs in terms of the genomic structure, evolutionary conservation, expressional correlation, and functional association. The authors first identified some common structural and distributional patterns in three representative mammalian genomes: human, mouse, and rat. Then, through comparative analyses between human, chicken, and Fugu, they observed a conservation tendency of head-to-head gene pairs in vertebrates. Finally, interactive analyses of expressional and functional association yielded some interesting results, including the significant expression correlation of head-to-head genes, especially for the pairs with significant functional association. The main conclusion of this paper is that the head-to-head gene organization is ancient and conserved, subjecting functionally related genes to coregulated transcription. Lists of head-to-head gene pairs in human, mouse, rat, chicken, and Fugu are provided, while some individual pairs in need of further in-depth investigations are highlighted.

The matrix attachment region in the Chinese hamster dihydrofolate reductase origin of replication may be required for local chromatid separation

Centered in the Chinese hamster dihydrofolate reductase origin of replication is a prominent nuclear matrix attachment region (MAR). Indirect lines of evidence suggested that this MAR might be required for origin activation in early S phase. To test this possibility, we have deleted the MAR from a Chinese hamster ovary variant harboring a single copy of the dihydrofolate reductase locus. However, 2D gel replicon mapping shows that removal of the MAR has no significant effect either on the frequency or timing of initiation in this locus. Rather, fluorescence in situ hybridization studies on cells swollen under either neutral or alkaline conditions show that deletion of the MAR interferes with local separation of daughter chromatids. This surprising result provides direct genetic evidence that at least a subset of MARs performs an important biological function, possibly related to chromatid cohesion and separation.

Protein-DNA interactions at the major and minor promoters of the divergently transcribed dhfr and rep3 genes during the Chinese hamster ovary cell cycle

In mammals, two TATA-less bidirectional promoters regulate expression of the divergently transcribed dihydrofolate reductase (dhfr) and rep3 genes. In CHOC 400 cells, dhfr mRNA levels increase about fourfold during the G1-to-S phase transition of the cell cycle, whereas the levels of rep3 transcripts vary less than twofold during this time. To assess the role of DNA-binding proteins in transcriptional regulation of the dhfr and rep3 genes, the major and minor dhfr-rep3 promoter regions were analyzed by high-resolution genomic footprinting during the cell cycle. At the major dhfr promoter, prominent DNase I footprints over four upstream Sp1 binding sites did not vary throughout G1 and entry into the S phase. Genomic footprinting revealed that a protein is constitutively bound to the overlapping E2F sites throughout the G1-to-S phase transition, an interaction that is most evident on the transcribed template strand. On the nontranscribed strand, multiple changes in the DNase I cleavage pattern are observed during transit through G1 and entry into the S phase. By using gel mobility shift assays and a series of sequence-specific probes, two different species of E2F were shown to interact with the dhfr promoter during the cell cycle. The DNA binding activity of one E2F species, which preferentially recognizes the sequence TTTGGCGC, did not vary significantly during the cell cycle. The DNA binding activity of the second E2F species, which preferentially recognizes the sequence TTTCGCGC, increased during the G1-to-S phase transition. Together, these results indicate that Sp1 and the species of E2F that binds TTTGGCGC participate in the formation of a basal transcription complex, while the species of E2F that binds TTTCGCGC regulates dhfr gene expression during the G1-to-S phase transition. At the minor promoter, DNase I footprints at a consensus c-Myc binding site and three Sp1 binding sites showed little variation during the G1-to-S phase transition. In addition to protein binding at sequences known to be involved in the regulation of transcription, genomic footprinting of the entire promoter region also showed that a protein factor is constitutively bound to the first intron of the rep3 gene.

Identification of two initiator elements in the bidirectional promoter of the human dihydrofolate reductase and mismatch repair protein 1 genes

The human dihydrofolate reductase (DHFR) gene and mismatch repair protein 1 (MRP1) genes are organized in a head-to-head configuration separated by an 90 base pair sequence. We have previously shown that as small as a 114 bp promoter sequences is sufficient for accurate and efficient initiation of divergent transcription. In this study, the mechanism of accurate transcription initiation in vivo from this short bidirectional promoter was analyzed by a newly developed highly sensitive primer extension assay. The GC boxes in the middle of this sequence were essential for bidirectional promoter activity, but not sufficient for accurate initiation. The sequences overlapping the transcription initiation sites of the DHFR and MRP1 genes were shown to function as the initiator, which directs transcription from an internal site. These initiators were strictly position dependent and were active only when located from 40 to 50 base pairs downstream from the GC box. Although there is no apparent sequence homology between two initiators, a common nuclear factor bound to these elements. Existence of two initiators located on both sides of the middle GC box seems to be the molecular basis of bidirectional activity of this short DNA sequence.

The minimal self-sufficient element in a murine G+C-rich promoter is a large element with imperfect dyad symmetry

The murine adenosine deaminase gene has a structurally archetypal TATAA-box-deficient G+C-rich promoter. The three Sp1 binding sites of the promoter are neither necessary nor sufficient for promoter function. Minimal basal promoter activity resides within a 48-bp element downstream of the Sp1 binding sites. This element shows an imperfect dyad symmetry around the promoter's major transcriptional initiation site and contains at least two nuclear protein binding sites. The distinctive sequence characteristics and nuclear protein binding locations of this element led us to propose a model for how such promoters may function.

Activation and suppression of a cryptic promoter in the intron of the human melanoma-associated ME491 antigen gene

A deletion mutant of the human melanoma-associated ME491 antigen gene starting at the first intron (lambda R31) differentially mediates the antigen expression depending on the cell type. Cryptic promoter activity residing in a 270-base-pair (bp) fragment of the first intron was examined by primer extension analysis and recombinant chloramphenicol acetyltransferase (CAT) assay. The cryptic promoter, further localized within a 153-bp fragment (fr153BN), exerted its effect in Ltk- and H-ras-transformed NIH3T3 (3T3-Hras) but not in parental NIH3T3 cells. The results suggested that the cryptic promoter was associated with a novel ras-responsive positive regulatory element, since fr153BN did not contain an AP-1-binding sequence motif, known as the ras-responsive enhancer element. The cryptic promoter activity of fr153BN was suppressed by an upstream 121-bp fragment (fr121SB) which contained a consensus sequence motif for binding of a repressor protein, GC factor, and regions showing sequence similarity with putative cis-acting repressor elements found in the vimentin gene. The degree of the suppression was greater in 3T3-Hras than in Ltk- cells. These positive and negative regulatory elements may be differentially involved in the regulation of ME491 antigen expression depending on the cell type.

Functional characterization of the human hypoxanthine phosphoribosyltransferase gene promoter: evidence for a negative regulatory element

The enzyme hypoxanthine phosphoribosyltransferase (HPRT) catalyzes the metabolic salvage of the purine bases hypoxanthine and guanine. We previously characterized the genomic structure of the human HPRT gene and described its promoter sequence. In this report, we identify cis-acting transcriptional control regions of the human HPRT gene by linking various 5'-flanking sequences to the bacterial chloramphenicol acetyltransferase gene. The sequence from positions -219 to -122 relative to the translation initiation site is required for maximal expression of this gene, and it functions equally in both normal and reverse orientations. In addition, a cis-acting negative element is present in the region spanning from positions -570 to -388. This negative element can also repress promoters of heterologous genes, such as those of adenosine deaminase and dihydrofolate reductase, which are structurally and functionally similar to the human HPRT promoter. Furthermore, this repressor element functions independently of its orientation but appears to be distance dependent. In vivo competition assays demonstrated that the trans-acting factor(s) that binds to this negative element specifically inhibits human HPRT promoter activity. Taken together, these data localize cis-acting sequences important in the regulation of human HPRT gene expression and should allow the study of protein-DNA interactions which modulate the transcription of this gene.

Functional characterization of the human hypoxanthine phosphoribosyltransferase gene promoter: evidence for a negative regulatory element

The enzyme hypoxanthine phosphoribosyltransferase (HPRT) catalyzes the metabolic salvage of the purine bases hypoxanthine and guanine. We previously characterized the genomic structure of the human HPRT gene and described its promoter sequence. In this report, we identify cis-acting transcriptional control regions of the human HPRT gene by linking various 5'-flanking sequences to the bacterial chloramphenicol acetyltransferase gene. The sequence from positions -219 to -122 relative to the translation initiation site is required for maximal expression of this gene, and it functions equally in both normal and reverse orientations. In addition, a cis-acting negative element is present in the region spanning from positions -570 to -388. This negative element can also repress promoters of heterologous genes, such as those of adenosine deaminase and dihydrofolate reductase, which are structurally and functionally similar to the human HPRT promoter. Furthermore, this repressor element functions independently of its orientation but appears to be distance dependent. In vivo competition assays demonstrated that the trans-acting factor(s) that binds to this negative element specifically inhibits human HPRT promoter activity. Taken together, these data localize cis-acting sequences important in the regulation of human HPRT gene expression and should allow the study of protein-DNA interactions which modulate the transcription of this gene.

DNA repair in the c-myc proto-oncogene locus: possible involvement in susceptibility or resistance to plasmacytoma induction in BALB/c mice

This report describes an unexpected difference in the efficiency of removal of UV-induced DNA damage in the c-myc locus in splenic B lymphoblasts from two inbred strains of mice. In cells from plasmacytoma-resistant DBA/2N mice, 35% of UV-induced damage in the regulatory and 5' flank of c-myc is removed by 12 h. However, in cells from plasmacytoma-susceptible BALB/cAn mice, damage is not removed from this region. In the protein-encoding region and 3' flank of c-myc as well as in two dihydrofolate reductase gene fragments, UV damage is repaired with similar efficiency in B lymphoblasts from both strains of mice. Furthermore, in the protein-encoding portion and 3' flank of c-myc, damage is selectively removed from only the transcribed strand. No repair is detected in the nontranscribed strand. In contrast, DNA repair in the 5' flank of c-myc is not strand specific; in DNA from DBA/2N cells, UV damage is rapidly removed from both the transcribed and nontranscribed strands. In BALB/cAn cells no repair was detected in either strand in the 5'flank, consistent with the results with double-stranded, nick-translated probes to this region of c-myc. In addition to the repair studies, we have detected post-UV-damage formation: in most of the genes studied, we find that additional T4 endonuclease-sensitive sites are formed in the DNA 2 h after irradiation. Our findings provide new insights into the details of gene-specific and strand-specific DNA repair and suggest that there may be close links between DNA repair and B-cell neoplastic development.

Testis-specific expression of the human MYCL2 gene

We have characterized the expression of MYCL2, an intronless X-linked gene related to MYCL1. RNase protection analysis of a panel of human normal and tumor tissues has revealed that MYCL2 is expressed almost exclusively in human adult normal testis; much lower levels of transcript were detected in one human lung adenocarcinoma. No MYCL2 transcript was found in human testis RNA obtained from second trimester fetuses. This observation suggests a germ cell rather than somatic cell origin of the transcript and possible developmental regulation of MYCL2. Northern blot analysis of poly(A)+ RNA from adult human normal testis with an antisense riboprobe revealed a transcript of approximately 4.8-kb, which is in agreement with the size predicted from the MYCL2 nucleotide sequence. Antisense transcripts were found spanning regions of MYCL2 corresponding to all three exons of MYCL1. No sizable open reading frame was seen for the MYCL2 antisense transcripts suggesting that they may represent either regulatory sequences or an intron of a gene encoded by the complementary strand. RNase protection assays and the 5' RACE protocol (Rapid Amplification of cDNA Ends) were used to address the localization of the transcription start site of the MYCL2 sense transcript and different putative promoters and transcription regulatory elements have been identified.

DNA repair in the c-myc proto-oncogene locus: possible involvement in susceptibility or resistance to plasmacytoma induction in BALB/c mice

This report describes an unexpected difference in the efficiency of removal of UV-induced DNA damage in the c-myc locus in splenic B lymphoblasts from two inbred strains of mice. In cells from plasmacytoma-resistant DBA/2N mice, 35% of UV-induced damage in the regulatory and 5' flank of c-myc is removed by 12 h. However, in cells from plasmacytoma-susceptible BALB/cAn mice, damage is not removed from this region. In the protein-encoding region and 3' flank of c-myc as well as in two dihydrofolate reductase gene fragments, UV damage is repaired with similar efficiency in B lymphoblasts from both strains of mice. Furthermore, in the protein-encoding portion and 3' flank of c-myc, damage is selectively removed from only the transcribed strand. No repair is detected in the nontranscribed strand. In contrast, DNA repair in the 5' flank of c-myc is not strand specific; in DNA from DBA/2N cells, UV damage is rapidly removed from both the transcribed and nontranscribed strands. In BALB/cAn cells no repair was detected in either strand in the 5'flank, consistent with the results with double-stranded, nick-translated probes to this region of c-myc. In addition to the repair studies, we have detected post-UV-damage formation: in most of the genes studied, we find that additional T4 endonuclease-sensitive sites are formed in the DNA 2 h after irradiation. Our findings provide new insights into the details of gene-specific and strand-specific DNA repair and suggest that there may be close links between DNA repair and B-cell neoplastic development.

Long-term in vivo expression of retrovirus-mediated gene transfer in mouse fibroblast implants

Toward the goal of gene therapy, we have been attempting to establish model somatic cell systems with the potential of sustained expression of the foreign gene. We report here that long-term expression of foreign genes in mouse embryo fibroblast implants can be achieved if a housekeeping gene promoter is used to drive transcription. Specifically, we have shown that in implants containing a beta-galactosidase gene linked to either an immediate early promoter of cytomegalovirus or a dihydrofolate reductase (DHFR) gene promoter, only the DHFR promoter allows long-term expression. We propose that choice of the promoter manifests significant influence on the long-term expression of genes introduced in fibroblast implants by retroviral vectors.

Analysis of the mouse Dhfr/Rep-3 major promoter region by using linker-scanning and internal deletion mutations and DNase I footprinting

The mouse dihydrofolate reductase (Dhfr) promoter region is buried within a CpG island (a region rich in unmethylated CpG dinucleotides), has a high G+C content, and lacks CAAT and TATA elements. The region contains four 48-bp repeats, each of which contains an Sp1-binding site. Another gene, Rep-3 (formerly designated Rep-1), shares the same general promoter region with Dhfr, being transcribed in the direction opposite that of Dhfr. Both genes appear to be housekeeping genes and are expressed at relatively low levels in all tissues. The 5' termini of the major Dhfr transcripts are separated from the 5' termini of the Rep-3 transcripts by approximately 140 bp. This curious structural arrangement suggested that the two genes might share common regulatory elements. To investigate the promoter sequences driving bidirectional transcription, a series of promoter mutations was constructed. These mutations were assayed by a replicating minigene system and by promoter fusions to the chloramphenicol acetyltransferase gene. Linker-scanning mutations that spanned the four repeats produced a variety of mRNA transcript phenotypes. The effects were primarily quantitative, generally reducing the abundance of transcripts for one or both genes. Some mutations affected Dhfr in a qualitative manner, such as by changing the startpoint of one of the major Dhfr transcripts or changing the relative abundance of the two major Dhfr transcripts. Additionally, protein transcription factors that bind to sequences in the mouse Dhfr/Rep-3 major promoter region, potentially affecting expression of either or both genes, were investigated by DNase I footprinting. The results indicate that multiple protein-DNA interactions occur in this region, reflecting potentially complex transcriptional control mechanisms that might modulate expression of either or both genes under different physiological conditions.

Analysis of the mouse Dhfr/Rep-3 major promoter region by using linker-scanning and internal deletion mutations and DNase I footprinting

The mouse dihydrofolate reductase (Dhfr) promoter region is buried within a CpG island (a region rich in unmethylated CpG dinucleotides), has a high G+C content, and lacks CAAT and TATA elements. The region contains four 48-bp repeats, each of which contains an Sp1-binding site. Another gene, Rep-3 (formerly designated Rep-1), shares the same general promoter region with Dhfr, being transcribed in the direction opposite that of Dhfr. Both genes appear to be housekeeping genes and are expressed at relatively low levels in all tissues. The 5' termini of the major Dhfr transcripts are separated from the 5' termini of the Rep-3 transcripts by approximately 140 bp. This curious structural arrangement suggested that the two genes might share common regulatory elements. To investigate the promoter sequences driving bidirectional transcription, a series of promoter mutations was constructed. These mutations were assayed by a replicating minigene system and by promoter fusions to the chloramphenicol acetyltransferase gene. Linker-scanning mutations that spanned the four repeats produced a variety of mRNA transcript phenotypes. The effects were primarily quantitative, generally reducing the abundance of transcripts for one or both genes. Some mutations affected Dhfr in a qualitative manner, such as by changing the startpoint of one of the major Dhfr transcripts or changing the relative abundance of the two major Dhfr transcripts. Additionally, protein transcription factors that bind to sequences in the mouse Dhfr/Rep-3 major promoter region, potentially affecting expression of either or both genes, were investigated by DNase I footprinting. The results indicate that multiple protein-DNA interactions occur in this region, reflecting potentially complex transcriptional control mechanisms that might modulate expression of either or both genes under different physiological conditions.

Sequences downstream of the transcription initiation site modulate the activity of the murine dihydrofolate reductase promoter

The murine dihydrofolate reductase gene is regulated by a bidirectional promoter that lacks a TATA box. To identify the DNA sequences required for dihydrofolate reductase transcription, the activities of various templates were determined by in vitro transcription analysis. Our data indicate that sequences both upstream and downstream of the transcription initiation site modulate the activity of the dihydrofolate reductase promoter. We have focused on two regions downstream of the transcription initiation site that are important in determining the overall efficiency of the promoter. Region 1, which included exon 1 and part of intron 1, could stimulate transcription when placed in either orientation in the normal downstream position and when inserted upstream of the transcription start site. This region could also stimulate transcription in trans when the enhancer was physically separate from the promoter. Deletion of region 2, spanning 46 nucleotides of the 5' untranslated region, reduced transcriptional activity by fivefold. DNase I footprinting reactions identified protein-binding sites in both downstream stimulatory regions. Protein bound to two sites in region 1, both of which contain an inverted CCAAT box. The protein-binding site in the 5' untranslated region has extensive homology to binding sites in promoters that both lack (simian virus 40 late) and contain (adenovirus type 2 major late promoter and c-myc) TATA boxes.

Identification of a new promoter upstream of the murine dihydrofolate reductase gene

In vitro reactions identified a transcription initiation site located 740 nucleotides upstream of the dihydrofolate reductase translational start. Transcription from this site proceeded in the direction opposite to that of dihydrofolate reductase mRNA. Deletion mapping indicated that this new promoter can be separated from the dihydrofolate reductase promoter and that separation increased transcription at -740. Transcripts that initiate at -740 were also detected in cellular RNA, indicating that this is a bona fide transcription initiation site in vivo.

c-Ha-ras gene bidirectional promoter expressed in vitro: location and regulation

Increased transcriptional activity of the c-Ha-ras gene product is correlated with induction of several important human tumor types. For this reason, we have investigated the nature of the c-Ha-ras promoter and the factors that regulate its expression. Using S1 and primer extension analysis of c-Ha-ras RNA from EJ cells, we have identified 18 initiation sites within an upstream exon (exon -1) whose 3' end (the donor splice site [D]) is located 1,105 base pairs (bp) upstream of the ATG codon. The furthest-upstream initiation site is located -191 bp relative to D, and the furthest downstream is located -16 bp relative to D. Transient expression assays, in which a series of mutants spanning this region were ligated to a promoterless chloramphenicol acetyltransferase vector, functionally confirmed the position and extent of this promoter. Mutational analysis further located a 47-bp element located between -243 and -196 relative to D that up-regulated transcriptional activity of the promoter region by 20- to 40-fold. This region contained both a GC box known to bind SP1 and a CCAAT box. Insertion of a simian virus 40 enhancer 5' to the promoter up-regulated transcription from each initiation site by approximately 10- to 20-fold. We have also localized, both by chloramphenicol acetyltransferase assay and by S1 analysis, a strong promoter operating in the direction opposite that of the gene and originating immediately 5' to the 47-bp regulatory region. The reverse promoter was found to have nine initiation sites between -248 and -278 relative to D.

Transcriptional mapping of the amplified region encoding the dihydrofolate reductase-thymidylate synthase of Leishmania major reveals a high density of transcripts, including overlapping and antisense RNAs

We have examined the transcriptional organization of the R region of the protozoan parasite Leishmania major. This region encodes the bifunctional enzyme dihydrofolate reductase-thymidylate synthase (DHFR-TS) and is frequently amplified as a 30-kilobase (kb) extrachromosomal circular DNA in methotrexate-resistant lines. Northern (RNA) blot analysis shows that the R region encodes at least 10 stable cytoplasmic polysomal poly(A)+ RNAs, ranging in size from 1.7 to 13 kb and including the 3.2-kb DHFR-TS mRNA. Transcriptional mapping reveals that these RNAs are closely spaced and collectively cover more than 95% of the 30-kb amplified R region. The organization is complex, including several overlapping RNAs 3' of DHFR-TS and two examples of antisense RNAs 5' of DHFR-TS. The R region RNAs can be grouped into two empirical domains, with eight contiguous RNAs transcribed in the same direction as that of DHFR-TS and two contiguous RNAs transcribed in the orientation opposite to that of DHFR-TS. The two 5'-most RNAs of the DHFR-TS-containing domain overlap the RNAs transcribed from the opposite strand. These data are relevant to models of transcription, including recent studies suggesting polycistronic transcription in trypanosomatids. The abundance of R region RNAs increases uniformly 10- to 15-fold in the amplified R1000-3 line relative to the wild type, and no new RNAs were observed. This suggests that all elements required in cis for DHFR-TS expression are contained within the 30-kb circular DNA. Quantitative analysis reveals that the steady-state DHFR-TS mRNA and protein levels are not growth phase regulated, unlike the monofunctional mouse DHFR. DHFR-TS is developmentally regulated, however, declining about fivefold in lesion amastigotes relative to promastigotes.

Dual bidirectional promoters at the mouse dhfr locus: cloning and characterization of two mRNA classes of the divergently transcribed Rep-1 gene

The mouse dihydrofolate reductase gene (dhfr) is a housekeeping gene expressed under the control of a promoter region embedded in a CpG island--a region rich in unmethylated CpG dinucleotides. A divergent transcription unit exists immediately upstream of the dhfr gene which is coamplified with dhfr in some but not all methotrexate-resistant cell lines. We show that the promoter region for this gene pair consists of two bidirectional promoters, a major and minor promoter, which are situated within a 660-base-pair region upstream of the dhfr ATG translation initiation codon. The major promoter controls over 90% of dhfr transcription, while the minor promoter directs the transcription of the remaining dhfr mRNAs. The major promoter functions bidirectionally, transcribing a divergent 4.0-kilobase poly(A) mRNA (class A) in the direction opposite that of dhfr transcription. The predicted protein product of this mRNA is 105 kilodaltons. The minor promoter also functions bidirectionally, directing the transcription of at least two divergent RNAs (class B). These RNAs, present in quantities approximately 1/10 to 1/50 that of the class A mRNAs, are 4.4- and 1.6-kilobase poly(A) mRNAs. cDNAs representing both class A and class B mRNAs have been cloned from a mouse fibroblast cell line which has amplified the dhfr locus (3T3R500). DNA sequence analysis of these cDNAs reveals that the class A and class B mRNAs share, for the most part, the same exons. On the basis of S1 nuclease protection analysis of RNA preparations from several mouse tissues, both dhfr and divergent genes showed similar levels of expression but did show some specificity in start site utilization. Computer homology searches have revealed sequence similarity of the divergent transcripts with bacterial genes involved in DNA mismatch repair, and we therefore have named the divergently transcribed gene Rep-1.

Identification of a new promoter upstream of the murine dihydrofolate reductase gene

In vitro reactions identified a transcription initiation site located 740 nucleotides upstream of the dihydrofolate reductase translational start. Transcription from this site proceeded in the direction opposite to that of dihydrofolate reductase mRNA. Deletion mapping indicated that this new promoter can be separated from the dihydrofolate reductase promoter and that separation increased transcription at -740. Transcripts that initiate at -740 were also detected in cellular RNA, indicating that this is a bona fide transcription initiation site in vivo.

c-Ha-ras gene bidirectional promoter expressed in vitro: location and regulation

Increased transcriptional activity of the c-Ha-ras gene product is correlated with induction of several important human tumor types. For this reason, we have investigated the nature of the c-Ha-ras promoter and the factors that regulate its expression. Using S1 and primer extension analysis of c-Ha-ras RNA from EJ cells, we have identified 18 initiation sites within an upstream exon (exon -1) whose 3' end (the donor splice site [D]) is located 1,105 base pairs (bp) upstream of the ATG codon. The furthest-upstream initiation site is located -191 bp relative to D, and the furthest downstream is located -16 bp relative to D. Transient expression assays, in which a series of mutants spanning this region were ligated to a promoterless chloramphenicol acetyltransferase vector, functionally confirmed the position and extent of this promoter. Mutational analysis further located a 47-bp element located between -243 and -196 relative to D that up-regulated transcriptional activity of the promoter region by 20- to 40-fold. This region contained both a GC box known to bind SP1 and a CCAAT box. Insertion of a simian virus 40 enhancer 5' to the promoter up-regulated transcription from each initiation site by approximately 10- to 20-fold. We have also localized, both by chloramphenicol acetyltransferase assay and by S1 analysis, a strong promoter operating in the direction opposite that of the gene and originating immediately 5' to the 47-bp regulatory region. The reverse promoter was found to have nine initiation sites between -248 and -278 relative to D.

Transcriptional mapping of the amplified region encoding the dihydrofolate reductase-thymidylate synthase of Leishmania major reveals a high density of transcripts, including overlapping and antisense RNAs

We have examined the transcriptional organization of the R region of the protozoan parasite Leishmania major. This region encodes the bifunctional enzyme dihydrofolate reductase-thymidylate synthase (DHFR-TS) and is frequently amplified as a 30-kilobase (kb) extrachromosomal circular DNA in methotrexate-resistant lines. Northern (RNA) blot analysis shows that the R region encodes at least 10 stable cytoplasmic polysomal poly(A)+ RNAs, ranging in size from 1.7 to 13 kb and including the 3.2-kb DHFR-TS mRNA. Transcriptional mapping reveals that these RNAs are closely spaced and collectively cover more than 95% of the 30-kb amplified R region. The organization is complex, including several overlapping RNAs 3' of DHFR-TS and two examples of antisense RNAs 5' of DHFR-TS. The R region RNAs can be grouped into two empirical domains, with eight contiguous RNAs transcribed in the same direction as that of DHFR-TS and two contiguous RNAs transcribed in the orientation opposite to that of DHFR-TS. The two 5'-most RNAs of the DHFR-TS-containing domain overlap the RNAs transcribed from the opposite strand. These data are relevant to models of transcription, including recent studies suggesting polycistronic transcription in trypanosomatids. The abundance of R region RNAs increases uniformly 10- to 15-fold in the amplified R1000-3 line relative to the wild type, and no new RNAs were observed. This suggests that all elements required in cis for DHFR-TS expression are contained within the 30-kb circular DNA. Quantitative analysis reveals that the steady-state DHFR-TS mRNA and protein levels are not growth phase regulated, unlike the monofunctional mouse DHFR. DHFR-TS is developmentally regulated, however, declining about fivefold in lesion amastigotes relative to promastigotes.

Demethylation enhances removal of pyrimidine dimers from the overall genome and from specific DNA sequences in Chinese hamster ovary cells

We have examined the effects of changes in cytosine methylation on DNA repair in UV-irradiated Chinese hamster ovary (CHO) cells. A hypomethylated derivative of the CHO K1B11 line, B11aza, was established by passaging B11 cells over several months in increasing concentrations of 5-azacytidine; greater than 60% demethylation was consistently demonstrated in these conditioned cells. Following a UV dose of 10 J/m2, the amount of repair replication performed within 24 h was approximately twofold higher in B11aza cells than in control B11 cells. Removal of T4 endonuclease V-sensitive sites (ESS) from specific restriction fragments within and around the dihydrofolate reductase (DHFR) gene was then examined in B11aza cells and compared with that in B11 cells. Although demethylation had little or no effect on repair in the 5' half of the DHFR gene, within a nontranscribed sequence immediately downstream from the gene, or within an extragenic region further downstream from the DHFR gene, significant increases in repair were observed at the 3' end of the DHFR gene and within an extragenic region upstream of the DHFR gene. However, the increases in DNA repair were not accompanied by any changes in overall cellular resistance to UV when colony-forming ability was assayed. We suggest that the level of DNA methylation may play an indirect role in the regulation of DNA repair, perhaps through an effect on chromatin structure or transcriptional activity.

Dual bidirectional promoters at the mouse dhfr locus: cloning and characterization of two mRNA classes of the divergently transcribed Rep-1 gene

The mouse dihydrofolate reductase gene (dhfr) is a housekeeping gene expressed under the control of a promoter region embedded in a CpG island--a region rich in unmethylated CpG dinucleotides. A divergent transcription unit exists immediately upstream of the dhfr gene which is coamplified with dhfr in some but not all methotrexate-resistant cell lines. We show that the promoter region for this gene pair consists of two bidirectional promoters, a major and minor promoter, which are situated within a 660-base-pair region upstream of the dhfr ATG translation initiation codon. The major promoter controls over 90% of dhfr transcription, while the minor promoter directs the transcription of the remaining dhfr mRNAs. The major promoter functions bidirectionally, transcribing a divergent 4.0-kilobase poly(A) mRNA (class A) in the direction opposite that of dhfr transcription. The predicted protein product of this mRNA is 105 kilodaltons. The minor promoter also functions bidirectionally, directing the transcription of at least two divergent RNAs (class B). These RNAs, present in quantities approximately 1/10 to 1/50 that of the class A mRNAs, are 4.4- and 1.6-kilobase poly(A) mRNAs. cDNAs representing both class A and class B mRNAs have been cloned from a mouse fibroblast cell line which has amplified the dhfr locus (3T3R500). DNA sequence analysis of these cDNAs reveals that the class A and class B mRNAs share, for the most part, the same exons. On the basis of S1 nuclease protection analysis of RNA preparations from several mouse tissues, both dhfr and divergent genes showed similar levels of expression but did show some specificity in start site utilization. Computer homology searches have revealed sequence similarity of the divergent transcripts with bacterial genes involved in DNA mismatch repair, and we therefore have named the divergently transcribed gene Rep-1.

An ubiquitously expressed gene 3.5 kilobases upstream of the glycerol-3-phosphate dehydrogenase gene in mice

While studying the organization of the mouse glycerol-phosphate dehydrogenase gene (Gdc-1 on chromosome 15), we identified a novel transcriptional unit located only 3.4 kilobases (kb) upstream of the 5' end of the Gdc-1 gene. This gene has been provisionally named D15Kz1. The unusual proximity of these two genes led us to investigate the pattern of expression and sequence characteristics of the new gene for comparison with those of Gdc-1. D15Kz1 was found to have transcripts of 3.2 and 3.4 kb in length. The 3.4-kb transcript was expressed at low levels in all tissues examined, whereas the 3.2-kb transcript was detected only in the cerebral cortex and the brown fat. D15Kz1 and Gdc-1 are not coordinately regulated, as evidenced by the characteristics of their expression in several tissues and in differentiating 3T3-F442A adipocyte cultures. A cDNA sequence of 3,105 bases isolated from an embryonal carcinoma lambda gt10 cDNA library had a large open reading frame of 461 amino acids at one end followed by 1.6 kb of sequence with multiple stop codons. Algorithms used to search the protein and nucleic acid data bases detected no significant sequence similarity to any other protein or gene. Southern blot analysis of genomic DNA using the D15Kz1 cDNA as a probe indicated that D15Kz1 is a single-copy gene in the mouse genome and that it is conserved in humans, rats, and chickens. This conservation of gene sequences suggests that D15Kz1 encodes a protein with an important cellular function.

Chimeric 3-hydroxy-3-methylglutaryl coenzyme A reductase-dihydrofolate reductase genes display bidirectional expression and unidirectional regulation in stably transfected cells

We have constructed hybrid dihydrofolate reductase (DHFR) genes which are controlled by the sterol-responsive hamster 3-hydroxy-3-methylglutaryl coenzyme A (HMG CoA) reductase promoter. Stable transfection frequencies of these chimeric templates into a DHFR-deficient Chinese hamster cell line indicate that the HMG CoA reductase promoter fragment confers DHFR transformation irrespective of its orientation relative to a downstream murine DHFR cDNA. Sterol-regulated levels of DHFR RNA and protein are detected from hybrid genes which carry a properly oriented promoter fragment. Constructions which invert this HMG CoA reductase promoter, however, generate DHFR RNA levels which do not respond to sterols. In the context of these transfected fusion genes, we present evidence of divergent opposite-strand transcription initiating from the HMG CoA reductase 5' fragment. In contrast, the endogenous HMG CoA reductase promoter region shows no apparent evidence of such bidirectional activity.

A negative regulatory element with properties similar to those of enhancers is contained within an Alu sequence

A negative regulatory element has been found within a member of the African green monkey Alu family of interspersed repeated sequences. This "reducer" element decreased transcription in both directions from a cellular simian virus 40-like bidirectional promoter independently of both orientation and position. The reducer was not promoter specific since it also decreased expression from the simian virus 40 early and human beta-globin promoters. In addition, the reducer decreased transcription from a polymerase III promoter. The reducer was contained in 38 base pairs of an Alu family member and interacted specifically with a monkey cell nuclear protein.

Demethylation enhances removal of pyrimidine dimers from the overall genome and from specific DNA sequences in Chinese hamster ovary cells

We have examined the effects of changes in cytosine methylation on DNA repair in UV-irradiated Chinese hamster ovary (CHO) cells. A hypomethylated derivative of the CHO K1B11 line, B11aza, was established by passaging B11 cells over several months in increasing concentrations of 5-azacytidine; greater than 60% demethylation was consistently demonstrated in these conditioned cells. Following a UV dose of 10 J/m2, the amount of repair replication performed within 24 h was approximately twofold higher in B11aza cells than in control B11 cells. Removal of T4 endonuclease V-sensitive sites (ESS) from specific restriction fragments within and around the dihydrofolate reductase (DHFR) gene was then examined in B11aza cells and compared with that in B11 cells. Although demethylation had little or no effect on repair in the 5' half of the DHFR gene, within a nontranscribed sequence immediately downstream from the gene, or within an extragenic region further downstream from the DHFR gene, significant increases in repair were observed at the 3' end of the DHFR gene and within an extragenic region upstream of the DHFR gene. However, the increases in DNA repair were not accompanied by any changes in overall cellular resistance to UV when colony-forming ability was assayed. We suggest that the level of DNA methylation may play an indirect role in the regulation of DNA repair, perhaps through an effect on chromatin structure or transcriptional activity.

Regulatory elements involved in the bidirectional activity of an immunoglobulin promoter

We show that the promoter from the mouse VH441 heavy-chain immunoglobulin gene, when present on plasmids transiently introduced into myeloma cells, promotes transcription bidirectionally, due to the presence on both strands of TATA-like sequences bracketing the highly conserved decanucleotide element. The two divergent promoters compete for the transcriptional machinery, their relative strength ultimately reflecting the likeness of the two TATA boxes to the consensus sequence. Moreover, their relative activity is also strongly influenced by certain point mutations within the distally located heavy-chain enhancer. The bearing of these results on current concepts of promoter function is discussed.

An ubiquitously expressed gene 3.5 kilobases upstream of the glycerol-3-phosphate dehydrogenase gene in mice

While studying the organization of the mouse glycerol-phosphate dehydrogenase gene (Gdc-1 on chromosome 15), we identified a novel transcriptional unit located only 3.4 kilobases (kb) upstream of the 5' end of the Gdc-1 gene. This gene has been provisionally named D15Kz1. The unusual proximity of these two genes led us to investigate the pattern of expression and sequence characteristics of the new gene for comparison with those of Gdc-1. D15Kz1 was found to have transcripts of 3.2 and 3.4 kb in length. The 3.4-kb transcript was expressed at low levels in all tissues examined, whereas the 3.2-kb transcript was detected only in the cerebral cortex and the brown fat. D15Kz1 and Gdc-1 are not coordinately regulated, as evidenced by the characteristics of their expression in several tissues and in differentiating 3T3-F442A adipocyte cultures. A cDNA sequence of 3,105 bases isolated from an embryonal carcinoma lambda gt10 cDNA library had a large open reading frame of 461 amino acids at one end followed by 1.6 kb of sequence with multiple stop codons. Algorithms used to search the protein and nucleic acid data bases detected no significant sequence similarity to any other protein or gene. Southern blot analysis of genomic DNA using the D15Kz1 cDNA as a probe indicated that D15Kz1 is a single-copy gene in the mouse genome and that it is conserved in humans, rats, and chickens. This conservation of gene sequences suggests that D15Kz1 encodes a protein with an important cellular function.

The chicken skeletal alpha-actin gene promoter region exhibits partial dyad symmetry and a capacity to drive bidirectional transcription

The chicken skeletal alpha-actin gene promoter region (-202 to -12) provides myogenic transcriptional specificity. This promoter contains partial dyad symmetry about an axis at nucleotide -108 and in transfection experiments is capable of directing transcription in a bidirectional manner. At least three different transcription initiation start sites, oriented toward upstream sequences, were mapped 25 to 30 base pairs from TATA-like regions. The opposing transcriptional activity was potentiated upon the deletion of sequences proximal to the alpha-actin transcription start site. Thus, sequences which serve to position RNA polymerase for alpha-actin transcription may allow, in their absence, the selection of alternative and reverse-oriented start sites. Nuclear runoff transcription assays of embryonic muscle indicated that divergent transcription may occur in vivo but with rapid turnover of nuclear transcripts. Divergent transcriptional activity enabled us to define the 3' regulatory boundary of the skeletal alpha-actin promoter which retains a high level of myogenic transcriptional activity. The 3' regulatory border was detected when serial 3' deletions bisected the element (-91 CCAAA TATGG -82) which reduced transcriptional activity by 80%. Previously we showed that disruption of its upstream counterpart (-127 CCAAAGAAGG -136) resulted in about a 90% decrease in activity. These element pairs, which we describe as CCAAT box-associated repeats, are conserved in all sequenced vertebrate sarcomeric actin genes and may act in a cooperative manner to facilitate transcription in myogenic cells.

Chimeric 3-hydroxy-3-methylglutaryl coenzyme A reductase-dihydrofolate reductase genes display bidirectional expression and unidirectional regulation in stably transfected cells

We have constructed hybrid dihydrofolate reductase (DHFR) genes which are controlled by the sterol-responsive hamster 3-hydroxy-3-methylglutaryl coenzyme A (HMG CoA) reductase promoter. Stable transfection frequencies of these chimeric templates into a DHFR-deficient Chinese hamster cell line indicate that the HMG CoA reductase promoter fragment confers DHFR transformation irrespective of its orientation relative to a downstream murine DHFR cDNA. Sterol-regulated levels of DHFR RNA and protein are detected from hybrid genes which carry a properly oriented promoter fragment. Constructions which invert this HMG CoA reductase promoter, however, generate DHFR RNA levels which do not respond to sterols. In the context of these transfected fusion genes, we present evidence of divergent opposite-strand transcription initiating from the HMG CoA reductase 5' fragment. In contrast, the endogenous HMG CoA reductase promoter region shows no apparent evidence of such bidirectional activity.

A negative regulatory element with properties similar to those of enhancers is contained within an Alu sequence

A negative regulatory element has been found within a member of the African green monkey Alu family of interspersed repeated sequences. This "reducer" element decreased transcription in both directions from a cellular simian virus 40-like bidirectional promoter independently of both orientation and position. The reducer was not promoter specific since it also decreased expression from the simian virus 40 early and human beta-globin promoters. In addition, the reducer decreased transcription from a polymerase III promoter. The reducer was contained in 38 base pairs of an Alu family member and interacted specifically with a monkey cell nuclear protein.

The chicken skeletal alpha-actin gene promoter region exhibits partial dyad symmetry and a capacity to drive bidirectional transcription

The chicken skeletal alpha-actin gene promoter region (-202 to -12) provides myogenic transcriptional specificity. This promoter contains partial dyad symmetry about an axis at nucleotide -108 and in transfection experiments is capable of directing transcription in a bidirectional manner. At least three different transcription initiation start sites, oriented toward upstream sequences, were mapped 25 to 30 base pairs from TATA-like regions. The opposing transcriptional activity was potentiated upon the deletion of sequences proximal to the alpha-actin transcription start site. Thus, sequences which serve to position RNA polymerase for alpha-actin transcription may allow, in their absence, the selection of alternative and reverse-oriented start sites. Nuclear runoff transcription assays of embryonic muscle indicated that divergent transcription may occur in vivo but with rapid turnover of nuclear transcripts. Divergent transcriptional activity enabled us to define the 3' regulatory boundary of the skeletal alpha-actin promoter which retains a high level of myogenic transcriptional activity. The 3' regulatory border was detected when serial 3' deletions bisected the element (-91 CCAAA TATGG -82) which reduced transcriptional activity by 80%. Previously we showed that disruption of its upstream counterpart (-127 CCAAAGAAGG -136) resulted in about a 90% decrease in activity. These element pairs, which we describe as CCAAT box-associated repeats, are conserved in all sequenced vertebrate sarcomeric actin genes and may act in a cooperative manner to facilitate transcription in myogenic cells.

Analysis of signals controlling expression of the Chinese hamster ovary aprt gene

The 5' end of the Chinese hamster ovary aprt gene was sequenced and transcription start sites were determined by both S1 nuclease protection and primer extension assays. Deletion mutants covering the same area were constructed, and adenine phosphoribosyltransferase (APRT) or chloramphenicol acetyltransferase (CAT) activity was measured by transient-expression assays. The aprt gene uses a single cluster of transcription start sites and lacks consensus sequences such as TATA and CCAAT, which are general components of eucaryotic promoters. The 5' deletion mutations of the promoter sequences demonstrated that (i) there is no decrease in either APRT activity or transcription extending to position -89 (relative to the main transcription start site); (ii) an additional 29-base-pair (bp) deletion decreases APRT activity and transcription twofold; and (iii) a deletion past the transcription start sites (P5' delta +27) abolishes both APRT activity and transcription, indicating that a 60-bp fragment immediately upstream of the main transcription start site is involved in basic transcription and a 29-bp fragment just upstream of the 60 bp-fragment stimulates transcription twofold. The 3' deletion mutations showed that a deletion of a 61-bp fragment in the 5' leader and coding sequence abolishes the efficient translation of an aprt-CAT gene transcript. In addition, there are two polyadenylation signals at the genomic 3' end, with the proximal one being sufficient for functional polyadenylation.

Identification of DNA sequences required for mouse APRT gene expression

The mouse aprt promoter contains four GC boxes, which bind transcription factor Spl in vitro, and lacks both TATA and CCAAT boxes. Removal of the two most distal GC boxes of this promoter had little effect on APRT enzyme levels produced in a transient expression assay. Deletion of the distal three GC boxes resulted in a 50% reduction, and deletion of all GC boxes resulted in essentially complete loss of APRT activity. There are two predominant transcription start sites which are located within the region containing the GC boxes. The promoter behaved as a relatively strong promoter when compared to the RSV LTR promoter in a transient CAT assay, and operated in one orientation only. No upstream anti-sense transcripts were detected in either mouse CAK or liver cells, confirming that the mouse aprt promoter, unlike some other GC-rich promoters appears not to support bidirectional transcription.

Analysis of gene expression using episomal mouse dihydrofolate reductase minigenes

We have constructed a plasmid encoding a mouse dihydrofolate reductase (dhfr) minigene which produces dhfr transcripts with all of the 5' and 3' ends observed from the chromosomal mouse dhfr gene. The minigene contains 5' flanking regions, all dhfr coding sequences, one intervening sequence, 11.5 kb of 3' flanking regions beyond the termination codon, an E. coli plasmid origin of replication and antibiotic resistance, and an SV40 minimal origin of replication; the total size is 17.2 kb. When transfected into cells constitutively producing a temperature sensitive SV40 T antigen, the plasmid minigene replicates at the permissive temperature, but fails to replicate at the nonpermissive temperature. Therefore, transcription can be observed in the presence or absence of minigene replication. In addition, a stable divergently transcribed RNA is produced from the dhfr minigene promoter region, with the same 5' ends that are seen in the chromosomal divergently transcribed gene. We show that deletion of the sole remaining intron of the dhfr minigene significantly lowers the amount of dhfr transcript produced but does not affect the amount of divergent transcript. The promoter region for these transcripts contains four 48 bp repeats; reducing the number of these repeats lowers the amount of both dhfr and divergent transcripts produced from the minigene.

Analysis of signals controlling expression of the Chinese hamster ovary aprt gene

The 5' end of the Chinese hamster ovary aprt gene was sequenced and transcription start sites were determined by both S1 nuclease protection and primer extension assays. Deletion mutants covering the same area were constructed, and adenine phosphoribosyltransferase (APRT) or chloramphenicol acetyltransferase (CAT) activity was measured by transient-expression assays. The aprt gene uses a single cluster of transcription start sites and lacks consensus sequences such as TATA and CCAAT, which are general components of eucaryotic promoters. The 5' deletion mutations of the promoter sequences demonstrated that (i) there is no decrease in either APRT activity or transcription extending to position -89 (relative to the main transcription start site); (ii) an additional 29-base-pair (bp) deletion decreases APRT activity and transcription twofold; and (iii) a deletion past the transcription start sites (P5' delta +27) abolishes both APRT activity and transcription, indicating that a 60-bp fragment immediately upstream of the main transcription start site is involved in basic transcription and a 29-bp fragment just upstream of the 60 bp-fragment stimulates transcription twofold. The 3' deletion mutations showed that a deletion of a 61-bp fragment in the 5' leader and coding sequence abolishes the efficient translation of an aprt-CAT gene transcript. In addition, there are two polyadenylation signals at the genomic 3' end, with the proximal one being sufficient for functional polyadenylation.

Independent 5' and 3'-end determination of multiple dihydrofolate reductase transcripts

Multiple dihydrofolate reductase (dhfr) mRNAs, differing substantially in abundance, are produced as a result of the utilization of multiple transcription initiation sites and multiple polyadenylation sites. We have shown that dhfr mRNAs initiating from an upstream promoter region utilize the same collection of six polyadenylation sites and generate multiple dhfr mRNAs at the same relative abundance as do the mRNAs initiating from the major transcription promoter region. These results indicate that the 5' and 3' ends of dhfr mRNAs are independently determined. We show that the relative abundance of steady-state dhfr mRNAs was the same in nuclear and cytoplasmic RNA fractions. This finding makes it unlikely that differences in mRNA stability account for differences in the relative abundance of the multiple dhfr mRNAs in the cytoplasm. Our analysis of the dhfr promoter region revealed the existence of stable cytoplasmic polyadenylated transcripts complementary to the first 300 nucleotides of the dhfr transcripts initiating from the upstream promoter region. Therefore, the dhfr locus hosts two divergent and partially overlapping genes which share the same promoter region.

Independent 5' and 3'-end determination of multiple dihydrofolate reductase transcripts

Multiple dihydrofolate reductase (dhfr) mRNAs, differing substantially in abundance, are produced as a result of the utilization of multiple transcription initiation sites and multiple polyadenylation sites. We have shown that dhfr mRNAs initiating from an upstream promoter region utilize the same collection of six polyadenylation sites and generate multiple dhfr mRNAs at the same relative abundance as do the mRNAs initiating from the major transcription promoter region. These results indicate that the 5' and 3' ends of dhfr mRNAs are independently determined. We show that the relative abundance of steady-state dhfr mRNAs was the same in nuclear and cytoplasmic RNA fractions. This finding makes it unlikely that differences in mRNA stability account for differences in the relative abundance of the multiple dhfr mRNAs in the cytoplasm. Our analysis of the dhfr promoter region revealed the existence of stable cytoplasmic polyadenylated transcripts complementary to the first 300 nucleotides of the dhfr transcripts initiating from the upstream promoter region. Therefore, the dhfr locus hosts two divergent and partially overlapping genes which share the same promoter region.

Coincident start sites for divergent transcripts at a randomly selected CpG-rich island of mouse

We determined the nucleotide sequence of two HTF islands that were selected at random from mouse chromosomal DNA. Both were non-methylated, G + C rich, and contained CpG at close to the expected frequency. When used as probes, the two islands detected multiple transcripts in RNA from several mouse tissues. Cloned cDNAs for the major transcripts of one island (HTF9) were isolated and used to construct a transcriptional map. We found that HTF9 contains the origin of a pair of divergent transcripts that are probably messenger RNAs. The bidirectional promoter is different from those previously observed as the major transcription start sites for each orientation are coincident on opposite strands of the DNA. The results support the view that HTF islands often mark genes, and they suggest that bidirectional transcription may be a common feature of island promoters.

The MES-1 murine enhancer element is closely associated with the heterogeneous 5' ends of two divergent transcription units

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.

Novel promoter upstream of the human c-myc gene and regulation of c-myc expression in B-cell lymphomas

A new promoter of the human c-myc gene called P0, with multiple RNA start sites, was mapped over 500 bases upstream of the two previously identified promoters, P1 and P2. Sequencing full-length cDNA clones of P0 RNAs revealed two open reading frames upstream of that for the P64c-myc protein. P0 RNA is located on polyribosomes and released by puromycin, indicating that it functions as an mRNA. In vitro translation of RNA synthesized from the cloned cDNAs predicts that P0 transcripts are translated into a novel 12.5-kilodalton protein corresponding to the first open reading frame. The regulation of P0 RNA was studied in the B-cell lymphoma cell line Manca, in which only the translocated c-myc allele lacking exon 1 was thought to be active. However, we found that P0 transcription and the DNase I-hypersensitive site associated with this promoter persist on the untranslocated allele, even though P1/P2 transcription as measured by a nuclear runoff assay was repressed. These results suggest that allelic exclusion of c-myc expression in this B-cell lymphoma is caused by a repression of transcription which is specific to the P1/P2 promoters. We previously reported a block to elongation of transcription near the 3' end of exon 1 in the wild-type c-myc gene, which results in an excess of exon 1 over exon 2 transcription (5a). In contrast, we found that in the Daudi B-cell lymphoma, which retains exon 1 in the active allele, equimolar transcription of exons 1 and 2 occurs. This result suggests a model for the activation of c-myc in B-cell lymphomas.

Multiple transcription start sites, DNase I-hypersensitive sites, and an opposite-strand exon in the 5' region of the CHO dhfr gene

Transcription of the 26-kilobase (kb) dihydrofolate reductase (dhfr) gene in CHO cells is initiated at two sites: a major site (approximately 85% of the dhfr mRNA) at -63 relative to the translation start and a minor site (approximately 15%) at -107. Transcription also occurs from the opposite DNA strand in the dhfr 5' region, with a probable initiation site at approximately -195 relative to the dhfr translation start. A 4-kb polyadenylated RNA that is derived from the opposite-strand transcription increases threefold in abundance after serum starvation of CHO cells for 24 h. dhfr mRNA levels do not change during this time. The first dhfr exon lies within a 1-kb genomic region marked by exceptionally high G + C content and lack of DNA methylation. This region also includes a 214-base-pair (bp) exon for the opposite-strand transcript and five of the six DNase I-hypersensitive sites identified at the dhfr locus. Analysis of the DNA sequences of hamster, human (M. Chen, T. Shimada, A. D. Moulton, A. Cline, R. K. Humphries, J. Maizel, and A. W. Nienhuis, J. Biol. Chem. 259:3933-3943, 1984), and mouse (M. McGrogan, C. C. Simonsen, D. T. Smouse, P. J. Farnham, and R. T. Schimke, J. Biol. Chem. 260:2307-2314, 1985) dhfr genes reveals the presence of a 29-bp unit that is conserved 45 to 49 bp upstream of major and minor dhfr transcription start sites. This unit follows the consensus: GRGGCGGTGGCCTNNNNTGTCRCAARTRGGTR. The 5' part of the 29-bp unit contains a GC box that agrees with the GGGCGG consensus-binding site for the RNA polymerase II transcription factor Sp1 (D. Gidoni, W. A. Dynan, and R. Tjian, Nature (London) 312:409-413, 1984). Each of the three mammalian dhfr genes has several G-rich GC boxes proximal to the major dhfr transcription start site and several GC boxes of the opposite orientation (C rich) in a distal region about 500 bp upstream.