YY1 is an initiator sequence-binding protein that directs and activates transcription in vitro

Identification of two repressor elements in the mouse alpha 2(I) collagen promoter

We recently identified three areas of Sp1 binding located between -568 and -453 of the 5' flanking region of the murine alpha2(I) collagen promoter which are necessary for optimal activity. We now identify two additional regions of Sp1 binding located at -371 to -351 (region 4) and at -690 to -613 (region 5), which when mutated increased promoter activity in transfected rat hepatic stellate cells indicating they contain negative regulatory elements. AP-2 bound to region 4 while YY1 bound most strongly to region 5. AP-2 decreased Sp1 binding to region 4 and had a dual effect on Sp1 binding to region 5 decreasing and increasing Sp1 binding at low and high concentrations of AP-2, respectively. YY1 enhanced Sp1 binding to both regions. AP-2 inhibited or enhanced the stimulatory effect of a transfected Sp1 expression vector on the alpha2(I) collagen promoter in Drosophila cells at low or high AP-2 expression, respectively. YY1 enhanced or inhibited the activation of the promoter by low or high Sp1 expression, respectively. This study identifies two negative regulatory elements in the murine alpha2(I) collagen promoter and shows that AP-2 and YY1 interact with Sp1 at these sites and can inhibit the activating action of Sp1.

trans repression of the human metallothionein IIA gene promoter by PZ120, a novel 120-kilodalton zinc finger protein

Metallothioneins are small, highly conserved, cysteine-rich proteins that bind a variety of metal ions. They are found in virtually all eukaryotic organisms and are regulated primarily at the transcriptional level. In humans, the predominant metallothionein gene is hMTIIA, which accounts for 50% of all metallothioneins expressed in cultured human cells. The hMTIIA promoter is quite complex. In addition to cis-acting DNA sequences that serve as binding sites for trans-acting factors such as Sp1, AP1, AP2, AP4, and the glucocorticoid receptor, the hMTIIA promoter contains eight consensus metal response element sequences. We report here the cloning of a novel zinc finger protein with a molecular mass of 120 kDa (PZ120) that interacts specifically with the hMTIIA transcription initiation site. The PZ120 protein is ubiquitously expressed in most tissues and possesses a conserved poxvirus and zinc finger (POZ) motif previously found in several zinc finger transcription factors. Intriguingly, we found that a region of PZ120 outside of the zinc finger domain can bind specifically to the hMTIIA DNA. Using transient-transfection analysis, we found that PZ120 repressed transcription of the hMTIIA promoter. These results suggest that the hMTIIA gene is regulated by an additional negative regulator that has not been previously described.

Transcriptional up-regulation of the delayed early gene HRS/SRp40 during liver regeneration. Interactions among YY1, GA-binding proteins, and mitogenic signals

Arg-Ser-rich domain-containing proteins (SR proteins), a family of splicing factors, can regulate pre-mRNA alternative splicing in a concentration dependent manner. Thus, the relative expression of various SR proteins may play an important role in alternative splicing regulation. HRS/SRp40, an SR protein and delayed early gene in liver regeneration, can mediate alternative splicing of fibronectin mRNA. Here we determined that transcription of the HRS/SRp40 gene is induced about 5-fold during liver regeneration, similar to the level of steady-state mRNA. We found that both mouse and human HRS promoters lack TATA and CAAT boxes. The mouse promoter region from -130 to -18, which contains highly conserved GA-binding protein (GABP) and YY1 binding sites, conferred high transcriptional activity. While GABPalpha/GABPbeta heterodimer transactivated the HRS promoter, YY1 functioned as a repressor. During liver regeneration, the relative amount of GABPalpha/GABPbeta heterodimer increased 3-fold, and YY1 changed little, which could partially account for the increase in HRS gene transcription. Interleukin-6, a critical mitogenic component of liver regeneration, was able to relieve the repressive activity of the YY1 site within the HRS promoter. The combined effect of small changes in the level of existing transcription factors and mitogenic signals may explain the transcriptional activation of the HRS gene during cell growth.

Regulation of RNA polymerase II-dependent transcription by poly(ADP-ribosyl)ation of transcription factors

Poly(ADP-ribosyl) transferase (ADPRT) is a nuclear protein that modifies proteins by forming and attaching to them poly(ADP-ribose) chains. Poly(ADP-ribosyl)ation represents an event of major importance in perturbed cell nuclei and participates in the regulation of fundamental processes including DNA repair and transcription. Although ADPRT serves as a positive cofactor of transcription, initiation of its catalytic activity may cause repression of RNA polymerase II-dependent transcription. It is demonstrated here that ADPRT-dependent silencing of transcription involves ADP-ribosylation of the TATA-binding protein. This modification occurs only if poly(ADP-ribosyl)ation is initiated before TATA-binding protein has bound to DNA and thereby prevents formation of active transcription complexes. Specific DNA binding of other transcription factors including Yin Yang 1, p53, NFkappaB, Sp1, and CREB but not c-Jun or AP-2 is similarly affected. After assembly of transcription complexes initiation of poly(ADP-ribosyl)ation does not influence DNA binding of transcription factors. Accordingly, if bound to DNA, transcription factors are inaccessible to poly(ADP-ribosyl)ation. Thus, poly(ADP-ribosyl)ation prevents binding of transcription factors to DNA, whereas binding to DNA prevents their modification. Considering its ability to detect DNA strand breaks and stimulate DNA repair, it is proposed that ADPRT serves as a molecular switch between transcription and repair of DNA to avoid expression of damaged genes.

RNA splicing of bacterial genes in eukaryotes

The presence of intervening sequences or introns in eukaryotic genes has been known for more than 20 years, and the mechanisms underlying RNA splicing have been studied in depth both genetically and biochemically. In recent years, however, an increasing number of bacterial genes have been introduced into higher eukaryotes as important tools for genetic studies. Their gene products are frequently used as an indirect measure for cell type-specific promoter activity, as, for example, in the case of chloramphenicol acetyl transferase (CAT assay) or beta-galactosidase. Here we show that RNA splicing of two prokaryotic genes encoding site-specific DNA recombinases occurs in eukaryotic cells. In one case, splicing is only observed after treatment of cells with the cytokine alpha interferon. We further demonstrate that mutating an intragenic donor splice site in a bacterial gene apparently activates a second, alternative splicing pathway. In conjunction with previous reports, our findings should also be regarded as a warning that splicing of bacterial genes in higher eukaryotes is a more common phenomenon than presently recognized, which may be difficult to overcome and may cause problems in the interpretation of experimental results.

Cloning and characterization of the mouse histone deacetylase-2 gene

Histone deacetylase-2 (HDAC2) is a component of a complex that mediates transcriptional repression in mammalian cells. A mouse HDAC2 cDNA was used to identify several recombinant clones containing the entire mouse HDAC2 gene. The mouse HDAC2 gene spans over 36 kilobase pairs and is composed of 14 exons (ranging from 58 to 362 nucleotides in length) and 13 introns (ranging from 75 base pairs to 19 kilobase pairs in length). Primer extension analysis with total RNA from NIH3T3 cells revealed a major transcriptional start site at 221 base pairs 5' of the ATG translational start codon. Upstream of the transcriptional start site, no canonical TATA box was found, but binding sites for several known transcription factors were identified. Transient transfection studies with 5' deletion mutants localized the promoter to no more than 76 base pairs upstream from the major transcriptional start site. Fluorescence in situ hybridization mapped mouse HDAC2 to chromosomal location 10B1, which is in close proximity to the growth factor-inducible gene fisp-12. Information concerning the genomic organization and promoter of HDAC2 will be useful in studies of the regulation of histone deacetylase activities, which in turn are important in studies of the regulation of transcriptional repression in mammalian cells.

Control of genes by mammalian retroposons

Available data on possible genetic impacts of mammalian retroposons are reviewed. Most important is the growing number of established examples showing the involvement of retroposons in modulation of expression of protein-coding genes transcribed by RNA polymerase II (Pol II). Retroposons contain conserved blocks of nucleotide sequence for binding of some important Pol II transcription factors as well as sequences involved in regulation of stability of mRNA. Moreover, these mobile genes provide short regions of sequence homology for illegitimate recombinations, leading to diverse genome rearrangements during evolution. Therefore, mammalian retroposons representing a significant fraction of noncoding DNA cannot be considered at present as junk DNA but as important genetic symbionts driving the evolution of regulatory networks controlling gene expression.

Cloning and characterization of the 5'-flanking region for the human topoisomerase III gene

The human DNA topoisomerase III (hTOP3) gene encodes a topoisomerase homologous to the Escherichia coli DNA topoisomerase I subfamily. To understand the mechanisms responsible for regulating hTOP3 expression, we have cloned the 5'-flanking region of the gene coding for the hTOP3 and analyzed its promoter activity. The presence of a single transcription initiation site was suggested by primer extension analysis. The hTOP3 gene promoter is moderately high in GC content and lacks a canonical TATA box, suggesting that hTOP3 promoter has overall similarity to promoters of a number of housekeeping genes. Examination of the promoter sequence indicated the presence of four Sp-1 consensus binding sequences and a putative initiator element surrounding the transcription initiation site. Transient expression of a luciferase reporter gene under the control of serially deleted 5'-flanking sequences revealed that the 52-base pair region from -326 to -275 upstream of the transcription initiation site includes a positive cis-acting element(s) for the efficient expression of hTOP3 gene. On the basis of gel mobility shift and supershift assays, we demonstrated that both YY1 and USF1 transcription factors can bind to the 52-base pair region. When HeLa cells were transiently transfected with a mutant construct which had disabled both YY1- and USF1-binding sites, the luciferase activity was greatly reduced, suggesting that these binding elements play a functional role in the basal activation of the hTOP3 promoter. Transfection studies with mutations that selectively impaired YY1 or USF1 binding suggested that both YY1 and USF1 function as activators in the hTOP3 promoter.

Transcription of the juvenile hormone esterase gene under the control of both an initiator and AT-rich motif

The binding of transcription factors to the core promoter of the juvenile hormone esterase gene was functionally characterized using both a cell-free in vitro transcription functional assay and a cell transfection assay. A core JHE promoter (-61 to +28 bp relative to transcription start site) supported faithful transcription from the in vivo transcription start site. The nuclear extracts from the Sf9 insect cell line that provided transcription from that template also bound to that template as a probe in gel-mobility shift assays. Deletion or transversion of the initiator-binding motif (-1 to +4 bp) abolished detectable transcription either in vitro or in transfected cells. An AT-rich motif (ATATAT; -28 to -23 bp) serves another transcription factor-binding site. Mutation of the AT-rich motif to a canonical TATA-box preserved transcription, while either its deletion or complete transversion abolished or significantly reduced detectable transcriptional activity. These results indicate that, under these conditions, the functional operation of this core promoter approaches that of a composite promoter in which both the TATA- and initiator-binding protein complexes are necessary, even for basal transcription. On the other hand, these debilitating mutations to either the TATA box or initiator motif did not prevent the ability of the corresponding gel-shift competitive probes to compete with the wild-type promoter for binding by the transcription factors. Even a double transversion of both the AT-rich motif and the initiator-binding motif was able to competitively displace the protein complex that bound to the labelled wild-type probe. These data strongly indicate the presence of (an) additional core-promoter-associated transcription factor(s) (that is not the 'downstream element') that contact(s) the AT-binding complex and/or initiator-binding factor with sufficient avidity to remove them from binding to the competing wild-type promoter sequence.

Characterization of the initiator and downstream promoter elements of herpes simplex virus 1 late genes

Previously identified cis-acting regulatory elements of herpes simplex virus (HSV) 1 late promoters include a TATA element upstream from the start of transcription, an initiator-like element at the start of transcription, and sequences downstream from the start of transcription. To determine whether these elements are functionally equivalent to similar elements from other eukaryotic genes, model late promoters were constructed using well-characterized regulatory elements from non-HSV genes. These modular promoters were then inserted into the viral genome upstream from a lacZ marker gene. Results showed that a eukaryotic initiator element, along with a TATA element, can function as a late HSV promoter. Several initiator sequences from both viral and nonviral genes were functionally similar to the initiator-like element in HSV-1 late promoters; however, a random sequence of the same size and a similarly located sequence from the HSV-1 early thymidine kinase promoter could not substitute for the initiator element. These results indicate that eukaryotic initiator elements are functionally equivalent to HSV-1 late promoter initiator elements. In addition, the downstream element of the late glycoprotein C promoter was further analyzed by construction of a series of small deletions and insertions. The presence of the downstream glycoprotein C region in a promoter consisting of a strong TATA and initiator element increased mRNA expression by a modest amount; this effect appeared to be sequence specific and dependent on its exact alignment with the upstream elements of the promoter.

Human CART1, a paired-class homeodomain protein, activates transcription through palindromic binding sites

Homeodomain proteins play important roles in animal development by controlling the expression of genes involved in determining cell fates. The recently cloned human Cart1 gene encodes a paired-class homeodomain (hCART1), whose rodent homolog is mainly expressed in early chondrocytes and in prechondrocytic mesenchymal cells. To better understand its role as a transcription factor, the author has selected specific hCART1 binding sites from a random pool of oligonucleotides. It is reported here that all sites obtained contain a palindrome consisting of two TAAT sequences separated by three or four base pairs. In electromobility shift assays, recombinant hCART1 proteins bind to a palindromic probe as a multimer, possibly a homodimer. In transient transfection assays, hCART1 activates transcription from reporter plasmids containing hCART1 binding sites in HeLa cells, demonstrating both site-dependence and dosage-dependence. It is also shown here that hCART1 localizes to nucleus. These data indicate that hCART1 is a sequence-specific transcription activator in HeLa cells. In combination with data from previous studies in which hCART1 represses transcription in different cell types and promoters, they suggest that hCART1 may be a transcription modulator with both repression and activation activities.

Growth regulation of the expression of mouse cDNA and gene encoding a serine/threonine kinase related to Saccharomyces cerevisiae CDC7 essential for G1/S transition. Structure, chromosomal localization, and expression of mouse gene for s. cerevisiae Cdc7-related kinase

Saccharomyces cerevisiae CDC7 encodes a serine/threonine kinase required for G1/S transition of the yeast cells. We previously reported human and Xenopus cDNAs encoding CDC7-related kinases and suggested the possibility that chromosomal replication of higher eukaryotes may be regulated through conserved mechanisms involving Cdc7-related kinases. Here we report a murine cDNA and gene (muCdc7) encoding a serine/threonine kinase related to CDC7. The predicted coding frame for the longest cDNA for muCdc7 consists of 564 amino acids, which shares 46, 77, and 93% identity, respectively, with those of budding yeast, Xenopus, and human in kinase conserved domains. The chromosomal gene for muCdc7, located at the band 5E5 on the mouse chromosome 5, consists of 12 exons, and its exon/intron organization shares some similarity with that of other protein kinases including Cdk and cAMP-dependent kinase. Transcription of muCdc7, initiated at multiple sites over the 370-base pair promoter region, is repressed in the resting state and is induced at the G1/S boundary after growth factor stimulation in a growth factor-dependent cell line. Transient transfection assays indicated that a 231-base pair segment of the muCdc7 promoter containing three putative E2F binding sites and one Sp1 site but lacking TATA sequence is sufficient for response to growth stimulation.

Identification and characterization of the human adipocyte apM-1 promoter

The human adipocyte-specific apM-1 gene encodes a secretory protein of the adipose tissue and seems to play a role in the pathogenesis of obesity. A 1.3 kb amount of the proximal promoter region has been cloned and analyzed for the presence of putative transcription factor binding sites. Several binding sites known to be involved in adipogenesis and regulation of adipocyte-specific genes (C/EBP, SREBP) are present. No TATA box, but a classical CCAAT box could be identified. To confirm functionality and cell specificity of the 1.3 kb promoter, a series of 5'-deleted fragments were ligated in front of the luciferase gene and the constructs were transfected into 3T3-L1 adipocytes. The reporter gene was effectively transcribed, as demonstrated by the expression of enzyme activity. The 5'-end of the human cDNA was completed by 5'-RACE-PCR. Several alternative transcription start sites were detected by RNase protection assay and primer extension analysis. In addition, an exon/intron boundary was mapped at the extreme 5'-end of the cDNA sequence. Genomic Southern blotting suggests that the human apM-1 gene is a single copy gene.

Role of the transcription start site core region and transcription factor YY1 in Rous sarcoma virus long terminal repeat promoter activity

The Rous sarcoma virus (RSV) long terminal repeat (LTR) contains a transcriptionally potent enhancer and promoter that functions in a variety of cell types. Previous studies have identified the viral sequences required for enhancer activity, and characterization of these elements has provided insight into the mechanism of RSV transcriptional activity. The objective of this study was to better define the RSV LTR promoter by examining the transcription start site core (TSSC) region. Deletion of the TSSC resulted in complete loss of transcriptional activity despite the presence of a functional TATA box, suggesting that the TSSC is required for viral expression. Homologies within the TSSC to the DNA binding motif of YY1 suggested that it might regulate promoter activity. YY1 has been shown to regulate transcription in some cellular genes and viral promoters by binding to sites overlapping the transcription start site. Gel shift assays using YY1 antibody identified YY1 as one of three complexes that bound to the TSSC. Mutation of the YY1 binding site reduced RSV transcriptional activity by more than 50%, suggesting that YY1, in addition to other TSSC-binding factors, regulates RSV transcription. Furthermore, in vitro transcription assays performed with Drosophila embryo extract (devoid of YY1 activity) showed decreased levels of RSV transcription, while transient transfection experiments overexpressing YY1 demonstrated that YY1 could transactivate the RSV LTR approximately 6- to 7-fold. We propose that the TSSC plays a vital role in RSV transcription and that this function is partially carried out by the transcription factor YY1.

Recruitment of human TBP selectively activates RNA polymerase II TATA-dependent promoters

An increasing body of evidence suggests that eukaryotic activators stimulate polymerase II transcription by facilitating the assembly of the functional basal machinery at the promoter. Here we describe experiments that provide added support for the idea that recruitment of TATA-binding protein (TBP) is a rate-limiting step for transcription activation in mammalian cells. We found that, in human cell lines, recruitment of TBP to a promoter, as a GAL4-TBP fusion protein, can provide a substantial activation of transcription. Activation mediated by the hTBP, tethered to promoter DNA, is strictly dependent upon the presence of a functional TATA element, and it directs faithful transcription initiation. Interestingly, GAL4-hTBP activation was not observed from initiator (Inr) -dependent TATA-less promoters. These results suggest that TBP binding to DNA is not a rate-limiting step for the initial stages of TFIID recruitment to initiator-dependent TATA-less promoters. Finally, we provide evidence that synergy between GAL4-hTBP and defined transcription domains is restricted to activators, such as VP16 and Tat, which are likely to function at steps subsequent to the TFIID recruitment. These findings strengthen the idea that recruitment of TBP represents an important mechanism of activation of TATA-dependent promoters, and on the other hand, they suggest that TBP-DNA interactions are largely dispensable for specific transcription of initiator dependent TATA-less promoters.

Multiple domains for initiator binding proteins TFII-I and YY-1 are present in the initiator and upstream regions of the rat XDH/XO TATA-less promoter

We previously reported that the TATA-less rat xanthine dehydrogenase/oxidase (XDH/XO) promoter is organized with multiple initiator elements (Inr 1, 2, 3 and 4). Additionally, we identified six factor binding footprints in the upstream region of this promoter (FP 1-FP 6), two of which (FP 2 and FP 4) we showed to be C/EBP binding sites. In this report we continue our characterization of the XDH/XO promoter, detailing other cis elements which comprise the Inr and upstream binding factors. Interestingly, multiple binding domains for known initiator binding proteins, YY-1 and USF-related factor/TFII-I, have been identified which potentially play an important role in transcription initiation.

Rescue and autonomous replication of adeno-associated virus type 2 genomes containing Rep-binding site mutations in the viral p5 promoter

The Rep proteins encoded by the adeno-associated virus type 2 (AAV) play a crucial role in the rescue, replication, and integration of the viral genome. In the absence of a helper virus, little expression of the AAV Rep proteins occurs, and the AAV genome fails to undergo DNA replication. Since previous studies have established that expression of the Rep78 and Rep68 proteins from the viral p5 promoter is controlled by the Rep-binding site (RBS) and the YY1 factor-binding site (YBS), we constructed a number of recombinant AAV plasmids containing mutations and/or deletions of the RBS and the YBS in the p5 promoter. These plasmids were transfected in HeLa or 293 cells and analyzed for the potential to undergo AAV DNA rescue and replication. Our studies revealed that (i) a low-level rescue and autonomous replication of the wild-type AAV genome occurred in 293 but not in HeLa cells; (ii) mutations in the RBS resulted in augmented expression from the p5 promoter, leading to more efficient rescue and/or replication of the AAV genome in 293 but not in HeLa cells; (iii) little rescue and/or replication occurred from plasmids containing mutations in the YBS alone in the absence of coinfection with adenovirus; (iv) expression of the adenovirus E1A gene products was insufficient to mediate rescue and/or replication of the AAV genome in HeLa cells; (v) autonomously replicated AAV genomes in 293 cells were successfully encapsidated in mature progeny virions that were biologically active in secondary infection of HeLa cells in the presence of adenovirus; and (vi) stable transfection of recombinant AAV plasmids containing a gene for resistance to neomycin significantly affected stable integration only in 293 cells, presumably because rescue and autonomous replication of the AAV genome from these plasmids occurred in 293 cells but not in HeLa or KB cells. These data suggest that in the absence of adenovirus, the AAV Rep protein-RBS interaction plays a dominant role in down-regulating viral gene expression from the p5 promoter and that perturbation in this interaction is sufficient to confer autonomous replication competence to AAV in 293 cells.

The Drosophila Polycomb group gene pleiohomeotic encodes a DNA binding protein with homology to the transcription factor YY1

Genes of the Polycomb group (PcG) of Drosophila encode proteins necessary for the maintenance of transcriptional repression of homeotic genes. PcG proteins are thought to act by binding as multiprotein complexes to DNA through Polycomb group response elements (PREs); however, specific DNA binding has not been demonstrated for any of the PcG proteins. We have identified a sequence-specific DNA binding protein that interacts with a PRE from the Drosophila engrailed gene. This protein (PHO) is a homolog of the ubiquitous mammalian transcription factor Yin Yang-1 and is encoded by pleiohomeotic, a known member of the PcG. We propose that PHO acts to anchor PcG protein complexes to DNA.

Transcriptional control and the role of silencers in transcriptional regulation in eukaryotes

Mechanisms controlling transcription and its regulation are fundamental to our understanding of molecular biology and, ultimately, cellular biology. Our knowledge of transcription initiation and integral factors such as RNA polymerase is considerable, and more recently our understanding of the involvement of enhancers and complexes such as holoenzyme and mediator has increased dramatically. However, an understanding of transcriptional repression is also essential for a complete understanding of promoter structure and the regulation of gene expression. Transcriptional repression in eukaryotes is achieved through 'silencers', of which there are two types, namely 'silencer elements' and 'negative regulatory elements' (NREs). Silencer elements are classical, position-independent elements that direct an active repression mechanism, and NREs are position-dependent elements that direct a passive repression mechanism. In addition, 'repressors' are DNA-binding trasncription factors that interact directly with silencers. A review of the recent literature reveals that it is the silencer itself and its context within a given promoter, rather than the interacting repressor, that determines the mechanism of repression. Silencers form an intrinsic part of many eukaryotic promoters and, consequently, knowledge of their interactive role with enchancers and other transcriptional elements is essential for our understanding of gene regulation in eukaryotes.

Rex-1, a gene encoding a transcription factor expressed in the early embryo, is regulated via Oct-3/4 and Oct-6 binding to an octamer site and a novel protein, Rox-1, binding to an adjacent site

The Rex-1 (Zfp-42) gene, which encodes an acidic zinc finger protein, is expressed at high levels in embryonic stem (ES) and F9 teratocarcinoma cells. Prior analysis identified an octamer motif in the Rex-1 promoter which is required for promoter activity in undifferentiated F9 cells and is involved in retinoic acid (RA)-associated reduction in expression. We show here that the Oct-3/4 transcription factor, but not Oct-1, can either activate or repress the Rex-1 promoter, depending on the cellular environment. Rex-1 repression is enhanced by E1A. The protein domain required for Oct-3/4 activation was mapped to amino acids 1 to 35, whereas the domain required for Oct-3/4 repression was mapped to amino acids 61 to 126, suggesting that the molecular mechanisms underlying transcriptional activation and repression differ. Like Oct-3/4, Oct-6 can also lower the expression of the Rex-1 promoter via the octamer site, and the amino-terminal portion of Oct-6 mediates this repression. In addition to the octamer motif, a novel positive regulatory element, located immediately 5' of the octamer motif, was identified in the Rex-1 promoter. Mutations in this element greatly reduce Rex-1 promoter activity in F9 cells. High levels of a binding protein(s), designated Rox-1, recognize this novel DNA element in F9 cells, and this binding activity is reduced following RA treatment. Taken together, these results indicate that the Rex-1 promoter is regulated by specific octamer family members in early embryonic cells and that a novel element also contributes to Rex-1 expression.

Correct usage of multiple transcription initiation sites and C/EBP-dependent transcription activation of the rat XDH/XO TATA-less promoter requires downstream elements located in the coding region of the gene

In the present study, we have shown that a downstream element located in the coding region of the TATA-less rat xanthine dehydrogenase/oxidase (XDH/XO) gene (-7 to +42) plays an important role in transcription initiation and C/EBP transcriptional activation. Previous work from our laboratory has shown that the promoter is organized with multiple initiator elements (Inr 1, 2, 3 and 4) which are important for transcription initiation. Additionally, we had identified two C/EBP binding sites upstream of this promoter. Deletional and mutational studies revealed that C/EBP binding was not essential for the basal level of transcriptional initation. However when XO-luciferase constructs include downstream sequence extending to +42 there is development of C/EBP sensitivity as well as a shift in the initiator usage. In the absence of the downstream element, primer extension analyses reveals Inr 3 and 4 to be the major start sites but in the presence of this additional sequence the usage is shifted to Inr 1 and 2. This shift in Inr usage more closely resembles that seen in intact macrophages or liver cells. Gel mobility shift assays indicate the presence of several binding factors located in this downstream region, one of which has been identified as YY-1. We postulate that YY-1 allows DNA bending which permits the upstream C/EBP elements to exhibit a transcriptional activation which is not seen when the downstream element is absent. This study presents a potential model for regulation of the XDH/XO promoter.

Isolation and functional characterization of the mouse p75 TNF receptor promoter

Tumor necrosis factor (TNF) is a pleiotropic cytokine that plays an important role in immunological and inflammatory responses. It exerts its biological effects via two distinct membrane receptors of apparent molecular weight of 55 (p55TNFR) and 75 kDa (p75TNFR), respectively. Most cell lines and primary tissues express both receptor types. While the p55TNFR gene is constitutively expressed at rather low levels, the transcription of p75TNFR is strongly modulated by a number of stimulatory agents. To characterize the mouse p75TNFR gene expression on a molecular level, we screened a mouse genomic library using the 5' end of the p75TNFR cDNA as a probe. A 6.3kb genomic clone containing about 6 kb of 5' flanking region and 300 bp of 3' sequence including the translational start site and the first exon was isolated and subcloned. Primer extension analysis revealed three transcriptional start sites located at -35, -39, and -564 bp upstream of the ATG-containing first exon. To determine whether the 5' flanking region exerts functional promoter activity, we generated deletion mutants fused to the luciferase reporter gene. Transfection of mouse fibroblasts (NIH3T3) with these constructs showed functional promoter activity of the isolated 5' region. By further sequence analysis of the 5' flanking region a number of putative DNA-binding sites for transcription factors, e.g., Sp1, CREB, Yi, YY1, and IFN gamma-responsive element, were identified.

CIF150, a human cofactor for transcription factor IID-dependent initiator function

The transcription factor IID (TFIID) complex is highly conserved between the Drosophila and mammalian systems. A mammalian homolog has been described for all the Drosophila TATA box-binding protein-associated factors (TAFs), with the exception of dTAF(II)150. We previously reported the identification of CIF, an essential cofactor for TFIID-dependent transcription from promoters containing initiator (Inr) elements. Here we describe the molecular cloning of CIF150, the human homolog of dTAF(II)150, and present biochemical evidence that this factor is involved in Inr activity. CIF150 is capable of mediating TFIID-dependent Inr activity in a complementation assay, and a protein fraction lacking Inr activity lacks detectable amounts of CIF150. Despite the striking similarity to dTAF(II)150, CIF150 does not appear to be associated with human TFIID. However, in vitro binding assays revealed a specific and direct interaction between CIF150 and hTAF(II)135. This interaction might be structurally important for the functional interaction between CIF150 and human TFIID, since CIF150 stabilizes TFIID binding to a core promoter.

Characterization of the TATA-less core promoter of the cell cycle-regulated cdc25C gene

The TATA- and Inr-less promoter of the human cdc25C gene is regulated during the cell cycle through binding of a repressor to two contiguous promoter-proximal elements, the CDE and CHR. In this study we have characterized in detail the region of the cdc25C promoter immediately downstream of these elements. Several lines of evidence suggest that this region of approximately 60 bp acts as the core promoter. This sequence: (i) harbors most of the transcription initiation sites; (ii) possesses basal promoter activity in vivo ; (iii) shows no stable protein binding in vivo as indicated by genomic dimethyl sulfate and phenanthroline copper footprinting; (iv) contains single-stranded regions in vivo as shown by potassium permanganate footprinting; (v) is hypersensitive to DNase I cleavage in permeabilized cells. Mutational analysis of the core promoter revealed the presence of three sites which play a role in transcription. Two of these sites were found to represent low affinity binding sites for transcription factors of the Sp1 family. Mutation of these sites led to decreased levels of transcription, while their alteration to canonical Sp1 sites impaired cell cycle regulation. Thus the transient interaction of Sp1 with the core promoter appears to be necessary for maximal transcription without perturbing cell cycle regulation.

Regulatory elements in the minimal promoter region of the mouse Xist gene

The Xist gene plays a central role in regulating X chromosome inactivation and Xist transcription has recently been shown to be necessary for X inactivation in mouse. We are currently analysing regulation of the Xist gene in order to determine the mechanisms underlying initiation of Xist expression and X inactivation. Sequence comparisons indicate that a region of approximately 0.4 kb upstream of the the major transcriptional start site comprises the Xist minimal promoter. Analysis of reporter constructs demonstrates that the minimal promoter region is active both in embryonic stem (ES) cells and in differentiated derivatives, indicating that sequences either further upstream or downstream are required for appropriate developmental control of Xist transcription. We have examined the minimal promoter region in detail, and in addition to common promoter elements have identified two previously uncharacterised transcription-factor binding sites. Mutation of these sites in reporter constructs indicates that they are functionally important.

Cloning of an inr- and E-box-binding protein, TFII-I, that interacts physically and functionally with USF1

The transcription factor TFII-I has been shown to bind independently to two distinct promoter elements, a pyrimidine-rich initiator (Inr) and a recognition site (E-box) for upstream stimulatory factor 1 (USF1), and to stimulate USF1 binding to both of these sites. Here we describe the isolation of a cDNA encoding TFII-I and demonstrate that the corresponding 120 kDa polypeptide, when expressed ectopically, is capable of binding to both Inr and E-box elements. The primary structure of TFII-I reveals novel features that include six directly repeated 90 residue motifs that each possess a potential helix-loop/span-helix homology. These unique structural features suggest that TFII-I may have the capacity for multiple protein-protein and, potentially, multiple protein-DNA interactions. Consistent with this hypothesis and with previous in vitro studies, we further demonstrate that ectopic TFII-I and USF1 can act synergistically, and in some cases independently, to activate transcription in vivo through both Inr and the E-box elements of the adenovirus major late promoter. We also describe domains of USF1 that are necessary for its independent and synergistic activation functions.

Murine Macrophage Mannose Receptor Promoter Is Regulated by the Transcription Factors PU.1 and SP1

The mannose receptor (MR) is a transmembrane protein that functions primarily as a phagocytic receptor for a wide range of microorganisms. Its expression appears to be restricted to tissue macrophages and Langerhans cells. To gain an understanding of the regulation of the gene, we have isolated the 5′ flanking sequence of the murine MR gene and have analyzed a 536-bp sequence upstream of the ATG start site for transcriptional activity. This sequence lacks a TATA box but contains an initiator (Inr) consensus element overlapping the single transcriptional start site. Transcription factor binding sites contained within this sequence include PU.1, Sp1, ETS, GATA, and MYB motifs. Serial 100-bp deletions of this promoter fragment fused to a luciferase reporter gene showed various patterns of activity when transfected into different cell types. In myeloid cells, sequence elements upstream of bp −300 appeared to have a silencing effect on promoter activity. Of the four potential PU.1 binding sites contained within the fragment, one site (at −164) bound the PU.1 factor most strongly, whereas the adjacent PU.1 site (at −177 bp) bound PU.1 to a lesser degree. Mutations of these sites decreased transcriptional activity but did not abolish it. However, promoter activity was abrogated when both the −164 bp PU.1 site and the adjacent −177 bp PU.1 site were mutated. In addition, mutation of the Sp1 site also significantly reduced promoter activity. Cotransfection studies in Drosophila Schneider cells indicated that PU.1 and Sp1 may function synergistically in transactivating the murine MR. This study indicates that MR gene expression is regulated in part by the interaction between the ubiquitously expressed factor Sp1 and the lymphoid/myeloid factor PU.1 and provides a basis for studying the regulation of this gene.

GA-binding protein-dependent transcription initiator elements. Effect of helical spacing between polyomavirus enhancer a factor 3(PEA3)/Ets-binding sites on initiator activity

Many eukaryotic RNA polymerase II promoters contain initiator elements which direct accurate transcription in a TATA-independent manner. The PEA3/Ets-binding site (PEA3/EBS) is a common enhancer element in eukaryotic genes and is also found near the transcriptional start sites of many TATA-less promoters. We demonstrate that two PEA3/EBSs driving expression of the luciferase reporter gene, function as a minimal transcriptional initiator element. Maximal levels of transcription was achieved when two PEA3/EBSs, in either orientation, were located on the same face of the DNA helix, and the sites could be separated by up to three helical turns. In vitro transcription start sites directed by PEA3/EBS elements were clustered on either side of the upstream PEA3/EBS and were abolished by immunodepletion of GA-binding protein (GABP) from FM3A cell nuclear extracts. In vivo, co-transfection of GABPalpha and GABPbeta expression vectors enhanced reporter gene expression driven from PEA3/EBS initiator elements. Like other initiator elements, the PEA3/EBS elements were activated synergistically by upstream Sp1-binding sites. Thus, our results establish GABP as both a transcriptional activator factor and as an initiator factor.

Interaction of the transcription factor YY1 with human poly(ADP-ribosyl) transferase

Poly(ADP-ribosyl) transferase (ADPRT) is a nuclear enzyme that catalyzes the synthesis of ADP-ribose polymers from NAD+ as well as the transfer of these polymers onto acceptor proteins. The function of ADPRT is thought to be related to a number of nuclear processes including DNA repair and transcription. The transcription factor Yin Yang 1 (YY1) is a potent regulator of RNA polymerase II (Pol II)-dependent transcription. In this study Alu-retroposon-associated binding sites for YY1 located in the distal region of the promoter of the human ADPRT gene have been identified suggesting a possible involvement of this protein in the regulation of ADPRT-gene expression. In the presence of the recombinant automodification domain of the ADPRT the formation of specific YY1 complexes, detected in gel-shift experiments, was strongly inhibited, indicating that this domain of the enzyme may interact directly with YY1. In accordance with this result YY1 was specifically precipitated from nuclear extracts by ADPRT immobilized on sepharose. These results suggest a direct ADPRT-YY1 interaction which may be of importance in the regulation of Pol II-dependent transcription. They also indicate that in some human promoters this regulation may be mediated by retroposons of the Alu family.

A novel transcriptional regulatory region within the core promoter of the hepatocyte growth factor gene is responsible for its inducibility by cytokines via the C/EBP family of transcription factors

Hepatocyte growth factor (HGF) is an inducible cytokine that is essential for the normal growth and development of various tissues, such as the liver. To decipher the molecular mechanisms that regulate HGF gene induction at the transcriptional level, we carried out in vitro and in vivo studies on the mouse HGF gene promoter. We have identified a novel regulatory element, located between -6 and +7 bp (from the transcription start site) in the HGF basal promoter region, which binds to inducible transcription factors and dictates responsiveness to extracellular stimuli that activate this gene. The core binding sequence for the inducible cis-acting factors was determined to be TTTGCAA (-4 to +3 bp) within the HGF promoter. Competition and gel mobility supershift assays showed that these binding complexes are composed of C/EBPbeta (CCAAT/enhancer-binding protein beta) and C/EBPdelta. DNA binding analysis also revealed that the binding site for the C/EBP family of transcription factors in the HGF promoter region overlaps that of another binding protein (complex C1), which binds specifically to a novel sequence with a core binding site of ACCGGT located adjacent to the C/EBP site (-9 to -4 bp). C1 binds to this region of the promoter and represses the inducible upregulation by C/EBP through direct competition for their individual binding sites. Partial hepatectomy, which is known to activate HGF gene expression in the liver, increased C/EBP (especially C/EBPbeta) binding activity to this region of the HGF promoter. Thus, our present results provide a mechanistic explanation for the transcriptional induction of the HGF gene by extracellular signals (i.e., cytokines) that induce tissue growth and regeneration.

Identification of a functional CT-element in the Phytophthora infestans piypt1 gene promoter

CT-rich sequences of incompletely characterized function have been found in the gene promoter regions of many organisms, fungi and members of the genus Phytophthora prominently among them. We describe here an in vitro analysis of CT-element function in regulating transcription of the Phytophthora infestans piypt1 gene, a gene that encodes a monomeric G-protein believed to be involved in regulation of vesicle transport (Chen and Roxby (1996) Gene 181, 89-94). The results of the promoter analysis indicate that a 17-bp CT-element lying close to the transcription start point of this gene is important in determining the frequency of transcription initiation. Competition experiments suggest that transcription factors bind to the CT element. A subregion lying at the 5'-end of the CT-element resembles an Inr element, a type of CT-rich transcription regulator first discovered in some mammalian genes. This Inr-like subregion appears to be more important in the interactions leading to transcription initiation than more downstream regions within this CT-element. Two proteins, of 37 and 45 kDa, respectively, that bind to the CT-element and are presumed to be transcription factors were detected in P. infestans nuclear extracts by southwestern blotting.

The 5'-upstream region of the rat phospholipase C-beta 3 gene contains two critical Sp1 sites and an HIV Inr-like element

The 5'-upstream region of the rat phospholipase C-beta 3 gene (PLC-beta 3) has been cloned and characterized. Sequence analysis of the 5'-upstream region showed that it contains a GC-rich region (-166 to +1: 79%) and multiple binding sites for the transcription factors Sp1, AP-1 and AP-2, but does not contain a canonical TATA box. Primer extension analysis of total RNA isolated from rat glial cell C6Bul revealed that single transcription start point (tsp) is located at an initiator (Inr) element similar to that found in the HIV promoter. Gel mobility shift and competitive mobility shift assays indicated that this Inr element forms a DNA-protein complex with the HIV Inr-binding protein, LBP-1/CP2 or a homologue. In order to localize functional elements of the 5'-upstream region of the rat PLC-beta 3 gene, 5'-deletion fragments were cloned into a chloramphenicol acetyltransferase (CAT) reporter vector. Transient transfection analyses of the 5'-deletion mutants identified a crucial promoter element located at -128 to -14. Supershift mobility assays, site-directed mutagenesis and DNase I footprints indicated that Sp1 binds to three GC boxes within the sequence between -128 and -14 of the PLC-beta 3 promoter. Transient transfection analyses of promoter constructs containing site-specific mutation(s) of these three GC boxes demonstrated that two GC boxes, located proximal to the tsp, are important elements for normal promoter activity.

Multiple mechanisms of transcriptional repression by YY1

The four C-terminal GLI-Krüppel type zinc fingers of YY1 have been identified as a transcriptional repression domain. Previous reports have proposed DNA-bending and activator-quenching mechanisms for this zinc finger-mediated repression. In addition, previous work indicated that p300 and CBP might be involved in YY1-mediated repression. We have analyzed these possible models for the zinc finger-mediated repression. The role of each zinc finger in the repression and DNA-binding functions was determined by using a structure-and-function approach. We show that zinc finger 2 of YY1 plays a central role in both DNA binding and transcriptional repression. However, a survey of a panel of YY1 mutants indicates that these two functions can be separated, which argues against the DNA-bending model for repression. We show that the physical interaction between YY1 and p300, a coactivator for CREB, is not sufficient for repression of CREB-mediated transcription. Our studies indicate that YY1 functions as an activator-specific repressor. Repression of CTF-1-directed transcription may be accomplished through direct physical interaction between YY1 and this activator. In contrast, physical interaction is not necessary for YY1 to repress Sp1- and CREB-mediated transcription. Rather, the repression likely reflects an ability of YY1 to interfere with communication between these activators and their targets within the general transcription machinery. Taken together, our results suggest that YY1 employs multiple mechanisms to achieve activator-specific repression.

Methods for studying the biochemical properties of an Inr element binding protein: TFII-I

Transcription initiation in eukaryotic mRNA coding genes is brought about by a host of general transcription factors, which assemble into a functional preinitiation complex (PIC) at the core promoter region, and gene-specific factors, which exert their effects on the rate and/or stability of the PIC. The core promoter region consists of a well-characterized TATA box and/or a less well-characterized pyrimidine-rich initiator element (Inr). While the biochemical mechanisms of TATA-mediated transcription initiation are extensively studied and known to be directed by the TATA binding protein, the mechanisms via the Inr element are poorly understood, as several factors have been shown to bind to an Inr. Here, we describe the biochemical properties of an Inr binding protein, TFII-I, employing the naturally occurring TATA-less but Inr-containing promoter derived from the T-cell receptor beta chain gene (V beta).

Identification and characterization of the human XIST gene promoter: implications for models of X chromosome inactivation

The XIST gene in both humans and mice is expressed exclusively from the inactive X chromosome and is required for X chromosome inactivation to occur early in development. In order to understand transcriptional regulation of the XIST gene, we have identified and characterized the human XIST promoter and two repeated DNA elements that modulate promoter activity. As determined by reporter gene constructs, the XIST minimal promoter is constitutively active at high levels in human male and female cell lines and in transgenic mice. We demonstrate that this promoter activity is dependent in vitro upon binding of the common transcription factors SP1, YY1 and TBP. We further identify two cis -acting repeated DNA sequences that influence reporter gene activity. First, DNA fragments containing a set of highly conserved repeats located within the 5'-end of XIST stimulate reporter activity 3-fold in transiently transfected cell lines. Second, a 450 bp alternating purine-pyrimidine repeat located 25 kb upstream of the XIST promoter partially suppresses promoter activity by approximately 70% in transient transfection assays. These results indicate that the XIST promoter is constitutively active and that critical steps in the X inactivation process must involve silencing of XIST on the active X chromosome by factors that interact with and/or recognize sequences located outside the minimal promoter.

Glial development in the Drosophila CNS requires concomitant activation of glial and repression of neuronal differentiation genes

Two classes of glial cells are found in the embryonic Drosophila CNS, midline glial cells and lateral glial cells. Midline glial development is triggered by EGF-receptor signalling, whereas lateral glial development is controlled by the gcm gene. Subsequent glial cell differentiation depends partly on the pointed gene. Here we describe a novel component required for all CNS glia development. The tramtrack gene encodes two zinc-finger proteins, one of which, ttkp69, is expressed in all non-neuronal CNS cells. We show that ttkp69 is downstream of gcm and can repress neuronal differentiation. Double mutant analysis and coexpression experiments indicate that glial cell differentiation may depend on a dual process, requiring the activation of glial differentiation by pointed and the concomitant repression of neuronal development by tramtrack.

Accurate positioning of RNA polymerase II on a natural TATA-less promoter is independent of TATA-binding-protein-associated factors and initiator-binding proteins

Two promoter elements, the TATA element and initiator (Inr), are capable of directing specific transcription initiation of protein-encoding genes by RNA polymerase II (RNAPII). Although binding to the TATA element by the TATA-binding protein (TBP) has been shown to be the initial recognition step in transcription complex formation in vitro, the mechanism through which the basal machinery assembles into a functional complex on TATA-less promoters is controversial. Evidence supporting numerous models of Inr-mediated transcription complex formation exists, including the nucleation of a complex by Inr-binding proteins, a component of the TFIID complex, or a specific upstream activator common to many TATA-less promoters, Sp1. Using various techniques, we have undertaken a systematic analysis of the natural TATA-less human DNA polymerase beta (beta-pol) gene promoter. Although the beta-pol promoter contains upstream Sp1 elements and a functional Inr that binds YY1, neither of these factors is essential for Inr-mediated transcription complex formation. A complex containing TBP, TFIIB, TFIIF, and RNAPII (DBPolF complex) is capable of forming on the promoter in an Inr-dependent manner. A single point mutation within the Inr that affects DBPolF complex formation diminishes beta-pol transcriptional activity.

BRCA1 is a component of the RNA polymerase II holoenzyme

The familial breast-ovarian tumor suppressor gene product BRCA1 was found to be a component of the RNA polymerase II holoenzyme by several criteria. BRCA1 was found to copurify with the holoenzyme over multiple chromatographic steps. Other tested transcription activators that could potentially contact the holoenzyme were not stably associated with the holoenzyme as determined by copurification. Antibody specific for the holoenzyme component hSRB7 specifically purifies BRCA1. Immunopurification of BRCA1 complexes also specifically purifies transcriptionally active RNA polymerase II and transcription factors TFIIF, TFIIE, and TFIIH. Moreover, a BRCA1 domain, which is deleted in about 90% of clinically relevant mutations, participates in binding to the holoenzyme complex in cells. These data are consistent with recent data identifying transcription activation domains in the BRCA1 protein and link the BRCA1 tumor suppressor protein with the transcription process as a holoenzyme-bound protein.

Differential regulation of major surface promoter in hepatitis B virus

The major surface promoter of human hepatitis B virus can produce three distinct groups of S transcripts. The initiation sites of these transcripts are in close proximity. Encompassing the ATG for the middle surface protein, the largest S transcript (+1) encodes the middle surface protein whereas the other two (+20 and +31) can only code for small surface protein. Sequence analysis does not reveal any TATA element. In this study, we employ deletion, linker scanning, and linker insertion analyses to study systematically the sequence requirements for the initiations of all three transcripts and their upstream regulatory sequences. Our study reveals that the sequence downstream of -16 is sufficient for precise initiation of all three groups of S transcripts. The 3' boundary of minimal promoter element is +15 for the +1 transcript, whereas it is +39 for both +20 and +31 transcripts. Furthermore, there are distinct sequence requirements for the initiations of three groups of S transcripts. The sequences from -17 to -10 and from -1 to +7 are required for the initiation of +1 transcript, the sequence from +16 to +39 is essential for the +20 transcript, and the sequences from -17 to -10 and from +24 to +39 are required for the + 31 transcript. Our results also suggest that the transcription initiations of major surface promoter may be mediated in part by initiators. The initiations of these three groups of S transcripts are under differential regulation. The region from -39 to -16 containing both negative and positive regulatory elements selectively regulates the transcription levels of the two major S transcripts. Most notably, mutation of the sequence from -17 to -10, which contains a Sp1 site, leads to an increase in the imprecise initiation at +1 site and depresses the initiation of +20 and, to a greater extent, +31 transcript. The relevance of differential regulation of major surface promoter to the varied production of different surface protein isoforms in viral life cycle is discussed.

Expression and regulation of the human and mouse aspartylglucosaminidase gene

Aspartylglucosaminidase (AGA) is a lysosomal enzyme that catalyzes one of the final steps in the degradation of N-linked glycoproteins. Here we have analyzed the tissue-specific expression and regulation of the human and mouse AGA genes. We isolated and characterized human and mouse AGA 5'-flanking sequences including the promoter regions. Primer extension assay revealed multiple transcription start sites in both genes, characteristic of a housekeeping gene. The cross-species comparison studies pinpointed an approximately 450-base pair (bp) homologous region in the distal promoter. In the functional analysis of human AGA 5' sequence, the critical promoter region was defined, and an additional upstream region of 181 bp exhibiting an inhibitory effect on transcription was identified. Footprinting and gel shift assays indicated protein binding to the core promoter region consisting of two Sp1 binding sites, which were sufficient to produce basal promoter activity in the functional studies. The results also suggested the binding of a previously uncharacterized transcription factor to a 23-bp stretch in the inhibitory region.

The cellular YY1 transcription factor binds a cis-acting, negatively regulating element in the Epstein-Barr virus BRLF1 promoter

Disruption of Epstein-Barr virus latency is induced by expression of either the BZLF1 (in B cells and epithelial cells) or BRLF1 (in epithelial cells only) immediate-early protein. Regulation of BZLF1 and BRLF1 transcription may therefore modulate the stringency of viral latency. The cellular transcription factor YY1 negatively regulates BZLF1 transcription. Here we show that the BRLF1 promoter (Rp) sequences from -206 to -227 (relative to the mRNA start site) and from -7 to +6 are directly bound by YY1. Mutation of the upstream YY1 binding site increases constitutive Rp activity in epithelial cells and B cells, while mutation of the downstream YY1 binding site does not significantly affect Rp activity. Negative regulation of BZLF1 and BRLF1 transcription by YY1 may act to maintain viral latency.

Separate domains of MBP-1 involved in c-myc promoter binding and growth suppressive activity

We previously demonstrated that exogenous expression of MBP-1 induces rapid cell death in murine fibroblasts, and alters loss of anchorage-independent growth and tumorigenicity in human breast carcinoma cells. Here, we investigated the functional role of two different domains of MBP-1. A DNA-protein interaction study suggested that the amino-terminal half (amino acids 1-178) of MBP-1 possesses the c-myc P2 promoter binding activity. The same domain of MBP-1 also showed transcriptional repressor activity on c-myc promoter by in vitro transient expression assay. On the other hand, the carboxy terminal half (amino acids 190-335) of MBP-1 induced cell death in murine fibroblasts similar to full length MBP-1. Furthermore, exogenous protein expression from the carboxy terminal half of MBP-1 in human breast carcinoma (MCF-7) cells showed suppression of colony formation and loss of anchorage-independent growth. Results from this study suggest that MBP-1 exerts its biological effect through different functional domains.

Transcription of the Acanthamoeba TATA-binding protein gene. A single transcription factor acts both as an activator and a repressor

Transcription of the Acanthamoeba TATA-binding protein (TBP) gene is regulated by TBP promoter-binding factor (TPBF), a previously described transactivator that binds as a tetramer to the TBP Promoter Element (TPE) and stimulates transcription up to 10-fold in vitro. Here we report that TPBF also functions as a transcription repressor by binding to a negative cis-element, located between the TATA box and the transcription initiation site. The negative element, referred to as the nTPE, is structurally similar to the TPE, and its disruption increases the transcription potency of the TBP promoter. TPBF binds to the nTPE, as demonstrated by mobility shift assays. However, the binding affinity of TPBF for the nTPE is about 10-fold lower than for the TPE. When placed upstream of the TATA box, the nTPE has very little effect on transcription. However, it inhibits transcription when placed at several positions downstream of the TATA box. Mechanistic studies with the TBP promoter suggest that binding of TPBF to the nTPE not only prevents TBP from binding to the TATA box but also displaces bound TBP, thereby inhibiting further assembly of the preinitiation complex. These results suggest a mechanism in which the cellular TPBF concentration controls the level of TBP gene transcription and show that a single factor can be stimulatory, inhibitory, or neutral depending on the sequence and the context of its binding site.

Transcriptional regulation of the mouse alpha A-crystallin gene: binding of USF to the -7/+5 region

Lens preferred-expression of the mouse alpha A-crystallin gene (alpha A-cry) is regulated at the transcriptional level by multiple elements located in the 5' flanking region of the gene. Here we present the first analysis of the functional role of the mouse alpha A-cry +1 region and the protein(s) which bind to it. The -7/+5 region of this promoter exhibits sequence similarity with the consensus upstream stimulating factor (USF) transcription factor binding site. A wild type oligodeoxyribonucleotide (oligo) spanning the mouse alpha A-cry -15/+15 region specifically inhibited the activity of a mouse alpha A-cry promoter-cat gene fusion (p alpha A 111aCAT) in competitive co-transfection studies in the mouse alpha TN4-1 lens cell line, as did an oligo containing the adenovirus 2 major late promoter strong USF binding site. In contrast, an alpha A-cry oligo mutated (-3/+3) within the USF-like binding site did not inhibit p alpha A111aCAT activity. Western blot analysis indicated that alpha TN4-1 cells express USF1. Co-transfection of p alpha A111aCAT and a USF1 cDNA expression vector into alpha TN4-1 cells resulted in a repression of mouse alpha A-cry promoter activity. Electrophoretic mobility shift analyses (EMSA) demonstrated that proteins in an alpha TN4-1 nuclear extract form a single major complex on synthetic oligos spanning the mouse alpha A-cry -15/+15 region. The formation of this complex was inhibited by the presence of unlabeled -15/+15 oligos or an anti-USF1 antibody. In addition, purified USF1 bound to this region, producing a complex similar in size to that observed with alpha TN4-1 nuclear extracts. Taken together, our findings show that USF can bind to the mouse alpha A-cry +1 site, and support the possibility that USF plays a role in promoter activity of this gene. Sequence similarities surrounding the +1 region of the alpha A-cry gene of the mouse, mole rat, hamster, and human, as well as the previously observed utilization of USF by different cry promoters suggest that USF contributes to the high expression of many crys in the ocular lens of diverse species.

URE, an initiator (Inr)-like site, suppresses the promoter of the rat dynorphin gene

We previously identified a DNA binding element termed the upstream regulatory element (URE) that contains the consensus initiator sequence (Inr) in the upstream promoter of the rat prodynorphin gene. The URE displays specific binding to the upstream regulatory element binding protein (UREB1), a novel transcription regulator. Here, we report that the URE functions as a suppressor element. A series of chloramphenicol acetyltransferase reporters (pCAT) were constructed by subcloning either wild-type or mutated URE sequences into a pCAT reporter plasmid 5' of bases -135 to +58 of the prodynorphin gene. The basal -135 to +58 dynorphin promoter (pCAT 0.2) has robust transcriptional activity in Chinese hamster ovary (CHO) cells but not in rat pheochromocytoma PC12 cells. This robust transcriptional activity was completely inhibited in the presence of wildtype URE, whereas the mutations of the URE had no effect. Gel mobility shift assays showed that the complex formed by the URE and nuclear protein extracts can be competed by addition of wild-type URE oligonucleotide but not by specific mutations of the URE, defining particular bases required for protein interaction with the URE. The identical URE sequence is also found upstream in the promoter of human macrophage inflammatory protein 1 beta (hMIP 1 beta). The suppressive activity of the rat dynorphin URE can be replaced by the hMIP 1 beta URE. These data suggest that the URE may serve as a suppressor element in the regulation of dynorphin and hMIP 1 beta gene transcription.

The adeno-associated virus (AAV) Rep protein acts as both a repressor and an activator to regulate AAV transcription during a productive infection

Adeno-associated virus (AAV) uses three promoters, p5, p19, and p40, to regulate viral gene expression. The p5 and p19 promoters direct the synthesis of the viral regulatory proteins, Rep78 and -68 and Rep52 and -40, respectively. The p5 Rep proteins bind a linear 22-bp sequence, the Rep binding element (RBE), that is within both the terminal repeat (TR) and the p5 promoter. In the absence of helper virus, all four Rep proteins have been shown to reduce transcription from the viral p5 and p19 promoters. In this report, we focus on the roles of these proteins and the RBEs in controlling transcription during a productive infection, that is, in the presence of adenovirus. We find that in the presence of adenovirus, the p5 RBE represses p5 transcription while the RBE in the TR activates p5. However, both the TR RBE and the p5 RBE transactivate the p19 and p40 promoters. The fact that the p5 RBE-Rep complex can transactivate p19 and p40 while repressing p5 suggests that Rep78/68 is both a repressor and a transactivator. Rep repression of p5 is specific for the p5 RBE, as other p5 promoter elements do not support this activity. We also demonstrate that in the presence of adenovirus, the p19 Rep proteins, which do not bind to the RBE, can eliminate repression of the p5 promoter by Rep78 and Rep68. This may occur by the association of Rep52 with Rep78 or Rep68 to produce a Rep78/68-Rep52 protein complex which can be detected in vivo by immunoprecipitation. Finally, two Rep mutants that were deficient in RBE binding and transactivation but positive for p5 repression were identified. These mutants may define interaction domains involved in making contacts with other proteins that facilitate repression. These observations suggest a mechanism for controlling the p5 and p19 mRNA levels during a productive AAV infection.

The initiator element of the adenovirus major late promoter has an important role in transcription initiation in vivo

Previous results showed that the structure and function of the adenovirus major late promoter (MLP) can be analyzed genetically in its correct location, despite its essential role in the viral life cycle. This genetic approach was extended to investigate the in vivo role of the initiator (INR), a transcriptional element that surrounds the start site of transcription. The analysis was designed to investigate if the INR is an alternative basal element to the canonical TATA box of the MLP, its relative importance in the functioning of the promoter, and if its function was affected by upstream activating elements. Accordingly, two different mutations in the INR were created and tested in the genome, either by themselves or together with mutations in the TATA box or one of the two upstream activating elements, the upstream promoter element (UPE) and the inverted CAAT box. The mutant viruses were examined first in one-step growth experiments, and then levels of late mRNA accumulation were measured by primer extension, transcription initiation was assayed in isolated nuclei, and viral DNA accumulation was determined by Southern hybridization. Neither mutation in the INR alone had any discernible phenotypic effects but when coupled to a phenotypically silent mutation in the TATA box gave rise to viruses with growth defects that were attributable to a significantly lowered rate of transcription initiation from the MLP. These results suggest that the INR plays a role in vivo and can act as an alternative basal element in the absence of a functioning TATA box. A virus with mutations in both the INR and the UPE, although viable, likewise had a severe deficiency in transcription, suggesting that the function of the INR is affected by that of the UPE. This contrasts with the previous report that a TATA box-UPE double mutation is not recoverable in virus. In addition, the virus with mutations in both the INR and the inverted CAAT box was phenotypically wild type, unlike the previously described TATA box-CAAT box double mutant, which had a severe transcription deficiency. Taken together, the present and previous genetic results can be interpreted as evidence that in the MLP, the TATA box and the UPE are the more important of the two basal and activating elements, respectively, but that the INR and CAAT can function in transcription initiation. We consider the role of the INR in the formation of the preinitiation complex and speculate on possible protein-protein interactions.