The importance of downstream delta-factor binding elements for the activity of the rpL32 promoter

WDR5 is a conserved regulator of protein synthesis gene expression

WDR5 is a highly-conserved nuclear protein that performs multiple scaffolding functions in the context of chromatin. WDR5 is also a promising target for pharmacological inhibition in cancer, with small molecule inhibitors of an arginine-binding pocket of WDR5 (the 'WIN' site) showing efficacy against a range of cancer cell lines in vitro. Efforts to understand WDR5, or establish the mechanism of action of WIN site inhibitors, however, are stymied by its many functions in the nucleus, and a lack of knowledge of the conserved gene networks-if any-that are under its control. Here, we have performed comparative genomic analyses to identify the conserved sites of WDR5 binding to chromatin, and the conserved genes regulated by WDR5, across a diverse panel of cancer cell lines. We show that a specific cohort of protein synthesis genes (PSGs) are invariantly bound by WDR5, demonstrate that the WIN site anchors WDR5 to chromatin at these sites, and establish that PSGs are bona fide, acute, and persistent targets of WIN site blockade. Together, these data reveal that WDR5 plays a predominant transcriptional role in biomass accumulation and provide further evidence that WIN site inhibitors act to repress gene networks linked to protein synthesis homeostasis.

A splice-site variant in the lncRNA gene RP1-140A9.1 cosegregates in the large Volkmann cataract family

Purpose

To identify the mutation for Volkmann cataract (CTRCT8) at 1p36.33.

Methods

The genes in the candidate region 1p36.33 were Sanger and parallel deep sequenced, and informative single nucleotide polymorphisms (SNPs) were identified for linkage analysis. Expression analysis with reverse transcription polymerase chain reaction (RT-PCR) of the candidate gene was performed using RNA from different human tissues. Quantitative transcription polymerase chain reaction (qRT-PCR) analysis of the GNB1 gene was performed in affected and healthy individuals. Bioinformatic analysis of the linkage regions including the candidate gene was performed.

Results

Linkage analysis of the 1p36.33 CCV locus applying new marker systems obtained with Sanger and deep sequencing reduced the candidate locus from 2.1 Mb to 0.389 Mb flanked by the markers STS-22AC and rs549772338 and resulted in an logarithm of the odds (LOD) score of Z = 21.67. The identified mutation, rs763295804, affects the donor splice site in the long non-coding RNA gene RP1-140A9.1 (ENSG00000231050). The gene including splice-site junctions is conserved in primates but not in other mammalian genomes, and two alternative transcripts were shown with RT-PCR. One of these transcripts represented a lens cell-specific transcript. Meta-analysis of the Cross-Linking-Immuno-Precipitation sequencing (CLIP-Seq) data suggested the RNA binding protein (RBP) eIF4AIII is an active counterpart for RP1-140A9.1, and several miRNA and transcription factors binding sites were predicted in the proximity of the mutation. ENCODE DNase I hypersensitivity and histone methylation and acetylation data suggest the genomic region may have regulatory functions.

Conclusions

The mutation in RP1-140A9.1 suggests the long non-coding RNA as the candidate cataract gene associated with the autosomal dominant inherited congenital cataract from CCV. The mutation has the potential to destroy exon/intron splicing of both transcripts of RP1-140A9.1. Sanger and massive deep resequencing of the linkage region failed to identify alternative candidates suggesting the mutation in RP1-140A9.1 is causative for the CCV phenotype.

[Analysis of transcriptional regulatory sites in introns of human and mouse ribosomal protein genes]

Previous studies from oligonucleotides in the ribosomal protein (RP) genes of the yeast and fruitfly indicated that the potential transcriptional regulatory sites are located in the introns of the genes. The transcriptional regulatory sites in introns are still poorly understood. To explore the functional significance of transcriptional regulation of introns, we extracted over-represented oligonucleotides (also known as motifs) in the first introns of the human and mouse ribosomal protein genes by statistical comparative analysis, and found that over 85% of these oligonucleotides were consistent with the known transcriptional factor binding sites, which might be potential transcriptional regulatory elements. By analyzing the base compositions of these elements, we found that a majority (>95%) of the detected motifs were rich in C and G and only a few of them were rich in A and T. Moreover, the oligonucleotides were close to the 5'-ends of the first introns (the distances between the motifs and the transcriptional start sites or upstream regions of genes are short). We speculated that the properties of over-represented motifs in the first introns might be associated with the transcriptional control.

Sequence context for transcription and translation of the Arabidopsis RPL23aA and RPL23aB paralogs

The 80S cytoplasmic ribosome is responsible for translating the transcriptome into the proteome. Demand for ribosome production depends on growth rate, and both the ribosomal RNA (rRNA) and ribosomal protein (RP) components must respond coordinately and rapidly to positive and negative growth stimuli to prevent deleterious effects of excess or insufficient subunits. The 81 RPs of the Arabidopsis 80S ribosome are encoded by multigene families that often exhibit overlapping patterns of transcript accumulation; however, only one isoform of each RP family (with the exception of a small number of acidic RPs) assembles into a single ribosome. Here we dissected the regulatory regions (RRs) of both members of the RPL23a family (RPL23aA and RPL23aB) to identify salient cis-acting elements involved in transcriptional, posttranscriptional, and translational regulation of expression. Full length and truncated RRs of RPL23a paralogs were cloned upstream of a GUS reporter gene and expressed in Arabidopsis transgenic plants. High level expression in mitotically active tissues, driven by RPL23aA and RPL23aB RRs, required TATA-box, telo-box, and site II motif elements. First and second introns were found to play a minor role in posttranscriptional regulation of paralogs, and conserved transcript features (e.g., UTR base composition) may be involved in enhancing translational efficiency. Overall, our results indicate that RPL23a expression is governed by a complex network of multiple regulatory layers.

Genome-wide analysis of YY2 versus YY1 target genes

Yin Yang 1 (YY1) is a critical transcription factor controlling cell proliferation, development and DNA damage responses. Retrotranspositions have independently generated additional YY family members in multiple species. Although Drosophila YY1 [pleiohomeotic (Pho)] and its homolog [pleiohomeotic-like (Phol)] redundantly control homeotic gene expression, the regulatory contributions of YY1-homologs have not yet been examined in other species. Indeed, targets for the mammalian YY1 homolog YY2 are completely unknown. Using gene set enrichment analysis, we found that lentiviral constructs containing short hairpin loop inhibitory RNAs for human YY1 (shYY1) and its homolog YY2 (shYY2) caused significant changes in both shared and distinguishable gene sets in human cells. Ribosomal protein genes were the most significant gene set upregulated by both shYY1 and shYY2, although combined shYY1/2 knock downs were not additive. In contrast, shYY2 reversed the anti-proliferative effects of shYY1, and shYY2 particularly altered UV damage response, platelet-specific and mitochondrial function genes. We found that decreases in YY1 or YY2 caused inverse changes in UV sensitivity, and that their combined loss reversed their respective individual effects. Our studies show that human YY2 is not redundant to YY1, and YY2 is a significant regulator of genes previously identified as uniquely responding to YY1.

Bone marrow cells from patients with Shwachman-Diamond syndrome abnormally express genes involved in ribosome biogenesis and RNA processing

Shwachman-Diamond Syndrome (SDS) is a multi-system genetic disorder with bone marrow failure. SBDS, the gene associated with SDS, has been postulated to play a role in ribosome biogenesis and RNA processing, but its functions are still unknown. To study whether these pathways are interrupted when Sbds protein is lost, we studied the expression of related genes in patient SBDS-/- cells by an oligonucleotide microarray. We first analysed ribosomal protein (RP) genes, which are normally co-regulated. In SDS, 27 of the 85 RP genes were downregulated. Among the downregulated RP genes, seven are known to be associated with the inhibition of apoptosis. RPS27L, which mediates p53-dependent induction of apoptosis, was the only upregulated RP gene. Interestingly, several genes involved in RP mRNA transcription were downregulated without affecting the expression of genes involved in mRNA degradation, suggesting that the downregulation of the RP gene expression might be at the transcriptional level. Importantly we also found dysregulation of multiple genes involved in rRNA transcription and pre-rRNA processing. We conclude that SDS marrow cells exhibit major dysregulation of RP, RNA processing and RNA transcription genes.

Regulation of Junonia coenia densovirus P9 promoter expression

Transcriptional activity of the Junonia coenia densovirus (JcDNV) P9 promoter depends on a 557-bp sequence located within the overlapping 3' sequences for viral capsid and nonstructural genes. Utilizing a somatic transformation assay to assess JcDNV promoter activity in Drosophila melanogaster and Plodia interpunctella, viral sequences were subjected to deletional analysis. Removal of a 685-bp fragment reduced P9-driven expression to background levels. Inclusion of a second expression cassette demonstrated vector persistence and confirmed somatic transformation. P9 promoter-driven expression was restored by insertion of a 557-bp JcDNV fragment or by inclusion of a heterologous baculovirus hr5 enhancer. Consensus polycomb transcriptional factor binding sites were identified within the 557-bp fragment, which suggests a potential role in regulating densoviral transcription.

Ribosomal protein gene regulation: what about plants?

The ribosome is an intricate ribonucleoprotein complex with a multitude of protein constituents present in equimolar amounts. Coordination of the synthesis of these ribosomal proteins (r-proteins) presents a major challenge to the cell. Although most r-proteins are highly conserved, the mechanisms by which r-protein gene expression is regulated often differ widely among species. While the primary regulatory mechanisms coordinating r-protein synthesis in bacteria, yeast, and animals have been identified, the mechanisms governing the coordination of plant r-protein expression remain largely unexplored. In addition, plants are unique among eukaryotes in carrying multiple (often more than two) functional genes encoding each r-protein, which substantially complicates coordinate expression. A survey of the current knowledge regarding coordinated systems of r-protein gene expression in different model organisms suggests that vertebrate r-protein gene regulation provides a valuable comparison for plants.

Characteristics and clustering of human ribosomal protein genes

Background

The ribosome is a central player in the translation system, which in mammals consists of four RNA species and 79 ribosomal proteins (RPs). The control mechanisms of gene expression and the functions of RPs are believed to be identical. Most RP genes have common promoters and were therefore assumed to have a unified gene expression control mechanism.

Results

We systematically analyzed the homogeneity and heterogeneity of RP genes on the basis of their expression profiles, promoter structures, encoded amino acid compositions, and codon compositions. The results revealed that (1) most RP genes are coordinately expressed at the mRNA level, with higher signals in the spleen, lymph node dissection (LND), and fetal brain. However, 17 genes, including the P protein genes (RPLP0, RPLP1, RPLP2), are expressed in a tissue-specific manner. (2) Most promoters have GC boxes and possible binding sites for nuclear respiratory factor 2, Yin and Yang 1, and/or activator protein 1. However, they do not have canonical TATA boxes. (3) Analysis of the amino acid composition of the encoded proteins indicated a high lysine and arginine content. (4) The major RP genes exhibit a characteristic synonymous codon composition with high rates of G or C in the third-codon position and a high content of AAG, CAG, ATC, GAG, CAC, and CTG.

Conclusion

Eleven of the RP genes are still identified as being unique and did not exhibit at least some of the above characteristics, indicating that they may have unknown functions not present in other RP genes. Furthermore, we found sequences conserved between human and mouse genes around the transcription start sites and in the intronic regions. This study suggests certain overall trends and characteristic features of human RP genes.

Identification of highly specific localized sequence motifs in human ribosomal protein gene promoters

For ribosomal protein (RP) genes the start of transcription is rigidly controlled to maintain the 5'-TOP signal on the messenger RNA. The responsible regulatory mechanism is not yet fully understood. Careful comparative analysis of their proximal promoter sequences reveals common characteristics and thus provides clues to the underlying mechanism. We have extracted the proximal promoters of the 80 human cytosolic ribosomal protein genes together with the orthologous mouse sequences. After annotating the set with transcription factor binding sites based on the available literature, we searched for over-represented sequence motifs. We uncovered a novel motif that is localized at a fixed distance downstream to the transcription start. 31 out of the 80 promoters contain the motif in the same orientation around position +62 (standard deviation 6). A second evolutionary conserved and palindromic motif is found 13 times in the RP promoter set, 9 instances of which are located upstream around position -40. In addition, we see a characteristic profile of the GC-content and of the CpG dinucleotide frequencies. Our results support a model for the transcription of ribosomal protein genes in which the maintenance of the accurate start of transcription is provided by specific transcription factors. Such a factor binds the target DNA at a fixed location relative to the TSS, and possibly interacts directly with the basal transcription machinery.

The architecture of mammalian ribosomal protein promoters

BACKGROUND

Mammalian ribosomes contain 79 different proteins encoded by widely scattered single copy genes. Coordinate expression of these genes at transcriptional and post-transcriptional levels is required to ensure a roughly equimolar accumulation of ribosomal proteins. To date, detailed studies of only a very few ribosomal protein (rp) promoters have been made. To elucidate the general features of rp promoter architecture, I made a detailed sequence comparison of the promoter regions of the entire set of orthologous human and mouse rp genes.

RESULTS

A striking evolutionarily conserved feature of most rp genes is the separation by an intron of the sequences involved in transcriptional and translational regulation from the sequences with protein encoding function. Another conserved feature is the polypyrimidine initiator, which conforms to the consensus (Y)2C+1TY(T)2(Y)3. At least 60 % of the rp promoters contain a largely conserved TATA box or A/T-rich motif, which should theoretically have TBP-binding capability. A remarkably high proportion of the promoters contain conserved binding sites for transcription factors that were previously implicated in rp gene expression, namely upstream GABP and Sp1 sites and downstream YY1 sites. Over 80 % of human and mouse rp genes contain a transposable element residue within 900 bp of 5' flanking sequence; very little sequence identity between human and mouse orthologues was evident more than 200 bp upstream of the transcriptional start point.

CONCLUSIONS

This analysis has provided some valuable insights into the general architecture of mammalian rp promoters and has identified parameters that might coordinately regulate the transcriptional activity of certain subsets of rp genes.

Characterization of an intronic enhancer that regulates myelin proteolipid protein (Plp) gene expression in oligodendrocytes

The myelin proteolipid protein (Plp) gene is expressed in oligodendrocytes and encodes the most abundant protein (approximately 50%) present in mature myelin from the central nervous system (CNS). Plp gene activity is low to nonexistent early in development but sharply increases, concurrently with the active myelination period of CNS development. Work from our laboratory suggests that the temporal regulation of Plp gene expression in mice is mediated by a positive regulatory element located within Plp intron 1 DNA. We have termed this regulatory element/region ASE (for antisilencer/enhancer). The ASE is situated approximately 1 kb downstream of exon 1 DNA and encompasses nearly 100 bp. To understand the mechanisms by which the ASE augments Plp gene expression in oligodendrocytes, Plp-lacZ constructs were generated and transfected into a mouse oligodendroglial cell line (N20.1). Results presented here demonstrate that upstream regulatory elements in the Plp promoter/5'-flanking DNA are not required for ASE activity; the ASE worked perfectly well when the thymidine kinase (TK) promoter was substituted for the Plp promoter. However, the relative location of the ASE appears to be important. When placed upstream of 2.4 kb of Plp 5'-flanking DNA, or downstream of the lacZ expression cassette, the ASE was no longer effective. Thus, the ASE might have to be in the context of the intron in order to function. To begin to identify the crucial nucleotides within the ASE, orthologous sequences from rat, human, cow, and pig Plp genes were swapped for the mouse sequence. Results presented here demonstrate that the orthologous sequence from rat can substitute for the mouse ASE, unlike those from human, cow, or pig.

Ribosomal protein S19 expression during erythroid differentiation

The gene encoding ribosomal protein S19 (RPS19) has been shown to be mutated in 25% of the patients affected by Diamond-Blackfan anemia (DBA), a congenital erythroblastopenia. As the role of RPS19 in erythropoiesis is still to be defined, we performed studies on RPS19 expression during terminal erythroid differentiation. Comparative analysis of the genomic sequences of human and mouse RPS19 genes enabled the identification of 4 conserved sequence elements in the 5' region. Characterization of transcriptional elements allowed the identification of the promoter in the human RPS19 gene and the localization of a strong regulatory element in the third conserved sequence element. By Northern blot and Western blot analyses of murine splenic erythroblasts infected with the anemia-inducing strain Friend virus (FAV cells), RPS19 mRNA and protein expression were shown to decrease during terminal erythroid differentiation. We anticipate that these findings will contribute to further development of our understanding of the contribution of RPS19 to erythropoiesis.

The role of c-myc in cellular growth control

Cell division is coupled to cell growth. Since some c-myc target genes are regulators of cell growth while others function in cell division pathways, c-myc is apparently poised at the interface of these processes. Cell culture systems have shown specific myc-associated growth phenotypes. Increased cell growth precedes DNA synthesis after myc activation in cells expressing myc-estrogen receptor fuson constructs and cells lacking c-myc exhibit a marked loss of protein synthesis. A number of candidate c-myc target genes regulate processes required for cell growth including rRNA transcription and processing, ribosomal protein transcription and translation, and translation initiation. These interactions all have the potential to account for the growth phenotypes in c-myc mutant cells. The ability of translation initiation factors, including eIF4E, to transform cells makes them particularly interesting targets of c-myc. Further evaluation of these target genes will provide important insights into growth control and c-myc's functions in cellular proliferation.

Isolation, characterization and expression of the Xenopus laevis ribosomal protein S6 gene

We report the isolation and characterization of genomic DNA clones encoding Xenopus ribosomal protein (rp) S6. A human rpS6 cDNA was used to screen a genomic DNA library, and this led to the isolation of a genomic clone encompassing the complete rpS6 gene locus. DNA sequencing and primer extension analysis indicate that Xenopus rpS6 is structurally analogous to the mammalian rpS6 genes, and its transcription starts at two sites within the same polypyrimidine tract of 10 bases. A series of deletions of the 5' region of the Xenopus rpS6 gene were fused to the chloramphenicol acetyltransferasereporter gene and transfected into COS-1 cells. The results suggest that the regulatory regions of the Xenopus rpS6 gene are clearly distinct from those earlier reported for the human rpS6 gene. Northern blot analysis of stage-specific embryonic RNA demonstrated an uniform rpS6 transcription during embryogenesis. Southern blot and PCR analyses indicate that the Xenopus rpS6 gene is pseudotetraploid in the Xenopus genome.

Functional characterization of transcriptional regulatory elements in the upstream region and intron 1 of the human S6 ribosomal protein gene

Expression of housekeeping genes involves regulation at comparable levels in a wide spectrum of cells. To define the cis-regulatory elements in the human S6 ribosomal protein (rpS6) gene, we made a series of deletions of the upstream non-transcribed region, including or excluding exon 1 or intron 1 sequences. The mutated rpS6 gene regulatory regions were fused to the chloramphenicol acetyltransferase reporter gene and transfected into HeLa and COS-1 cells. The results have identified three parts of the rpS6 gene that are required for efficient and specific transcription. The core promoter includes only a 40 bp region upstream of the transcription start site and initiation region. Both upstream and intronic elements enhance transcription from the core promoter. Furthermore, mutation of the splice donor site of intron 1 almost completely abolished the enhancing activity of the intronic transcriptional modulator. We used gel retardation assays to identify sequence-specific binding sites in the upstream region and in the proximal half of intron 1. Both common and different nuclear factors that bind the rpS6 gene promoter were identified in extracts from HeLa and COS-1 cells, suggesting that different transcription factors may bind specifically to the same binding region and might be interchangeable in their function to ensure high-level expression of housekeeping genes independently of the cell type.

A functional YY1 binding site is necessary and sufficient to activate Surf-1 promoter activity in response to serum growth factors

The human Surf-1 and Surf-2 housekeeping genes are divergently transcribed and share a bi-directional, TATA-less promoter. Housekeeping promoters typically contain complex arrays of transcription factor binding sites and several studies have suggested that many of these sites might be functionally redundant. The Surf-1/Surf-2 promoter region contains four factor binding sites; members of the ETS family of transcription factors bind to two of these sites whilst YY1 binds to a third site immediately downstream of the major Surf-1 transcription start point. Here we show that Sp1 binds to the fourth transcription factor binding site. Although YY1 and Sp1 have previously been shown to interact both in vitro and in vivo, these proteins function independently at the Surf-1/Surf-2 promoter. The binding of Sp1 alone is sufficient to bring about full promoter activity in the Surf-2 direction. In contrast, both Sp1 and ETS proteins are required to bring about full promoter activity in the Surf-1 direction. The YY1 binding site is not required for basal transcription in either direction. The YY1 binding site is, however, both necessary and sufficient to confer growth factor inducibility on transcription in the Surf-1 direction. Our data suggest that functionally redundant transcription factor binding sites might not be a general feature of housekeeping promoters.

Structural characterization of the mouse ribosomal protein S6-encoding gene

The gene encoding mouse ribosomal protein (r-protein) S6 is 2.7 kb in length, and is composed of five exons. The intron positions of the mouse S6 (Rps6) coincide exactly to those of the homologous human S6 (RPS6), but the last intron present in the human is absent in the mouse gene. The latter displays higher G + C content than the RPS6, both in the overall sequenced region and at the 3rd codon position. The promoter area is highly conserved between mouse and human, and contains several putative cis-acting elements. Comparison of the intronic sequences of both genes revealed surprisingly a high degree of identity (63%) within 350 bp of the first intron. Besides the single-copy Rsp6 there are up to 15 S6 family members, most likely processed pseudogenes. Characterization of the Rps6 provides a basis to study the functions of the mammalian S6 by gene targeting.

YY1 and c-Myc associate in vivo in a manner that depends on c-Myc levels

The c-Myc oncoprotein has previously been shown to associate with transcription regulator YY1 and to inhibit its activity. We show herein that endogenous c-Myc and YY1 associate in vivo and that changes in c-Myc levels, which accompany mitogenic stimulation or differentiation of cultured cells, affect the ratio of free to c-Myc-associated YY1. We have also investigated the mechanism by which association with c-Myc inhibits YY1's ability to regulate transcription. c-Myc does not block binding of YY1 to DNA. However, protein association studies suggest that c-Myc interferes with the ability of YY1 to contact basal transcription proteins TATA-binding protein and TFIIB.

Regulatory elements in the promoter region of the rat gene encoding the acyl-CoA-binding protein

Acyl-CoA-binding protein (ACBP) is an ubiquitously expressed 10-kDa protein which is present in high amounts in cells involved in solute transport or secretion. Rat ACBP is encoded by a gene containing the typical hallmarks of a housekeeping gene. Analysis of the promoter region of the rat ACBP gene by electrophoretic mobility shift assay (EMSA) revealed specific binding of proteins from rat liver nuclear extracts to potential recognition sequences of NF-1/CTF, Sp1, AP-1, C/EBP and HNF-3. In addition, specific binding to a DR-1 type element was observed. By using in vitro translated peroxisome proliferator activated receptors (PPAR) and a retinoid X receptor alpha (RXRalpha), we demonstrated that this DR-1 element was capable of binding PPARalpha/RXRalpha, PPARdelta/RXRalpha and PPARgamma2/RXRalpha heterodimers. The PPARgamma2/RXRalpha heterodimer appeared to have the highest affinity for the ACBP DR-1 element. Addition of peroxisome proliferators (PP) to H4IIEC3 rat hepatoma cells led to an increase in the ACBP mRNA level, indicating that the DR-1 element could be a functional peroxisome proliferator responsive element (PPRE). Analysis of the ACBP promoter by transient transfection showed that deletion of the region containing the DR-1 element reduced transcriptional activity, and further indicated that three AP-2 sites and one NF-1/CTF site in the proximal promoter are of importance for basal promoter activity.

A characterization of transcriptional regulatory elements in chicken ribosomal protein L37a gene

Transcriptional control elements of chicken ribosomal protein L37a gene were characterized in terms of their activities to promote transcription and their protein binding activities. The region -120 to +168 was necessary for the maximal expression of the promoter-less CAT gene in a transfected chicken cell line. Using the DNase I protection assay, we identified nine protein binding regions distributed in a wide range of -122 to +195. The sequences of most of the elements are conserved among many vertebrate ribosomal protein genes at similar positions of the promoters. These common control elements and their binding proteins may coordinate the expression of ribosomal protein genes.

Characterization of two novel YY1 binding sites in the polyomavirus late promoter

NF-D is a ubiquitous nuclear factor that has been shown to bind specifically to a DNA element in the polyomavirus regulatory region. In this report, we demonstrate that NF-D is either identical or very similar to a transcription factor that has been variously named YY1, delta, NF-E1, UCRBP, or CF1. Moreover, we show the presence in the polyomavirus genome of a second DNA motif, located 40 bp from the first, which binds YY1/NF-D with high affinity. Both sites lie downstream of the major late transcription initiation sites. By site-directed mutagenesis, we demonstrate that both elements contribute positively to the activity of the late promoter, probably by a cooperative mechanism. We also demonstrate that the requirement of the YY1/NF-D function for late promoter activity varies with the cell line.

Nuclear factor YY1 activates the mammalian F0F1 ATP synthase alpha-subunit gene

Analysis of the promoters of the bovine and human nuclear-encoded mitochondrial F0F1 ATP synthase alpha-subunit genes (ATPA) has identified several positive cis-acting regulatory regions that are important for basal promoter activity in human HeLa cells. We have previously determined that the binding of a protein factor, termed ATPF1, to an E-box sequence (CANNTG) located within one of these cis-acting regions is critical for transcriptional activation of the ATPA gene. In this article, we describe a second positive cis-acting regulatory element of the ATPA gene that is important for expression of the ATPA gene. We show that this cis-acting element also contains a binding site for a protein present in HeLa cells. On the basis of electrophoretic mobility shift patterns, oligonucleotide competition assays, and immunological cross-reactivity, we conclude that this protein factor is Yin-Yang 1 (YY1). Experiments carried out to examine the functional role of YY1 within the context of the ATPA promoter demonstrated that YY1 acts as a positive regulator of the ATPA gene. For example, when the YY1 binding site of the ATPA promoter was placed upstream of a reporter gene it was found to activate transcription in transient transfection assays. In addition, disruption of the YY1 binding site in the ATPA gene resulted in a loss of transcriptional activity. Furthermore, in cotransfection experiments overexpression of YY1 in trans was found to activate transcription of ATPA promoter-CAT constructs. Thus, at least two positive trans-acting regulatory factors, ATPF1 and YY1, are important for expression of the bovine and human F0F1 ATP synthase alpha-subunit genes.

Characterization of functional domains within the multifunctional transcription factor, YY1

YY1 is a multifunctional transcription factor capable of either activation or repression of transcription. Using a series of mutant proteins, we have characterized domains responsible for activation or repression. We found that the YY1 transcriptional activation domain lies near the amino terminus and requires amino acids 16-29 and 80-100 for maximal activity. The region between residues 16 and 29 has the potential to form an acidic amphipathic helix, whereas residues between 80 and 100 are rich in proline and glutamine. The YY1 repression domain lies near the carboxyl terminus and is embedded within the YY1 zinc finger region necessary for binding to DNA. Deletion of YY1 amino acids, which include zinc fingers 3 and 4, abolishes repression. However, site-directed mutagenesis, progressive deletion, and internal deletion mutant analyses indicate that the normal structures of zinc fingers 3 and 4 are not required for repression.

DNA binding sites for the transcriptional activator/repressor YY1

YY1 is ubiquitously expressed zinc finger DNA binding protein. It can act as a transcriptional repressor or activator and, when binding at the initiator element, as a component of the basal transcription complex. Binding sites for YY1 have been reported in a wide variety of promoters and they exhibit substantial diversity in their sequence. To better understand how YY1 interacts with DNA and to be able to predict the presence of YY1 sites in a more comprehensive fashion, we have selected YY1 binding sites from a random pool of oligonucleotides. The sites display considerable heterogeneity, but contain a conserved 5'-CAT-3' core flanked by variable regions, generating the consensus 5'-(C/g/a)(G/t)(C/t/a)CATN(T/a)(T/g/c)-3', where the upper case letters represent the preferred base. This high degree of flexibility in DNA recognition can be predicted by modeling the interaction of the four YY1 zinc fingers with DNA and a detailed model for this interaction is presented and discussed.

Intron-dependent transient expression of the maize GapA1 gene

Transient expression experiments show that the maize GapA1 promoter exhibits a requirement for sequences contained within intron 1 and surrounding exon border regions for expression in maize Black Mexican Sweet cells. Maize GapA1-promoter constructs lacking intron 1 are inactive. Intron 1 and its exon border sequences, when reintroduced into constructs lacking introns, restore gene activity whereas intron 2 and its exon borders to not. The minimal promoter so defined encompasses roughly 250 bp upstream of the in vivo transcription start and appears also to include intron 1. An octameric sequence was identified in intron 1 of maize GapA1 which is similar to sequence motifs found in other maize introns known to increase transient expression. Partial restoration of gene expression in GapA1 constructs lacking intron 1 was achieved through insertion of the identified octameric sequence.

The relative contributions of various transcription factors to the overall promoter strength of the mouse ribosomal protein L30 gene

The promoter of the mouse gene encoding ribosomal protein L30 contains binding sites for four transcription factors; alpha (RFX-1), beta (GABP), gamma and delta (YY-1/NF-E1/UCRBP). The relative contributions of these factors to the strength of the rpL30 promoter in vivo and the degree of synergism among the factors was evaluated by transfection experiments using a series of mutant promoters in which one or more of the binding sites was drastically altered to prevent recognition by its cognate factor. Our results indicated that GABP and RFX-1 are the major determinants of the rpL30 promoter strength, acting synergistically to boost activity more than eightfold over that which occurs in their absence. The contributions of gamma and delta became evident only when the promoter was weakened by eliminating the participation of the other factors. Indeed, as the promoter strength was progressively reduced, the contribution of each individual factor increased, implying that the capacity of the general transcription machinery to be stimulated by these factors is saturable. The activity of the rpL30 promoter was significantly diminished when three pyrimidine residues spanning the start site were converted to purines, indicating that the integrity of the oligopyrimidine tract is also a determinant of the transcriptional efficiency. These studies reveal the hierarchy of importance of four transcription factors that govern the expression of the rpL30 gene. Moreover, they define the graduated levels of promoter activity that would result from deficiencies of these factors in any particular cell type. This information may provide a useful paradigm for understanding the transcriptional regulation of other ubiquitously expressed genes.

Lymphocyte p56L32 is a RNA/DNA-binding protein which interacts with conserved elements of the murine L32 ribosomal protein mRNA

In previous studies of the ribosomal protein L32 mRNA, we demonstrated that a conserved polypyrimidine tract found in the 5'-untranslated region (5'-UTR) was required for translational regulation in vivo and that a 56-kDa protein (p56L32) from T-lymphocytes specifically interacts with this sequence [Kaspar, R. L., Kakegawa, T., Cranston, H., Morris, D. R. & White, M. W. (1992) J. Biol. Chem. 267, 508-514]. Here we show that p56L32 binding to the L32 5'-UTR is complex and requires other 5'-UTR RNA sequences in conjunction with the polypyrimidine tract. Deletion and site-directed mutagenesis studies revealed that binding of p56L32 to the L32 5'-UTR requires a second RNA element, GGUGGCUGCC, 15 nucleotides downstream from the polypyrimidine tract. In contrast, L32 RNA transcripts altered in this downstream element were good substrates for binding of the polypyrimidine binding proteins from HeLa nuclear extracts, indicating that these proteins have RNA-binding specificities distinct from p56L32. Competition analysis demonstrated that p56L32 will bind to DNA as well as RNA with identical sequence specificity and similar affinity. Single or double-stranded DNAs composed of the L32 5'-UTR sequences were found to specifically compete with L32 RNA transcripts for p56L32 binding. The L32 5'-UTR downstream element, GGUGGCUGCC, which is required for p56L32 binding, has previously been implicated as a transcriptional element of the L32 gene. The ability of p56L32 to bind this sequence as DNA or RNA suggests p56L32 may have a dual role in the regulation of ribosomal protein mRNA accumulation and translation.

Functional three-domain single-chain T-cell receptors

T-cell receptors (TCRs) are membrane anchored heterodimers structurally related to antibody molecules. Single-chain antibodies can be engineered by linking the two variable domains, which fold properly by themselves. However, proper assembly of the variable domains of a human TCR (V alpha and V beta) that recognize the HLA-DR2b/myelin basic protein-(85-99) peptide complex was critically dependent on the addition of a third domain, the constant region of the TCR beta chain (C beta), to the single-chain construct. Single-chain molecules with the three-domain design, but not those with the two-domain design, expressed in a eukaryotic cell as chimeric molecules linked either to glycosyl phosphatidylinositol or to the transmembrane/cytoplasmic domains of the CD3 zeta chain were recognized by a conformation-sensitive monoclonal antibody. The chimeric three-domain single-chain TCR linked to CD3 zeta chain signaled in response to both the specific HLA-DR/peptide and the HLA-DR/superantigen staphylococcal enterotoxin B complexes. Thus, by using this three-domain design, functional single-chain TCR molecules were expressed with high efficiency. The lipid-linked single-chain TCR was solubilized by enzymatic cleavage and purified by affinity chromatography. The apparent requirement of the constant domain for cooperative folding of the two TCR variable domains may reflect significant structural differences between TCR and antibody molecules.