Multiple functional motifs in the chicken U1 RNA gene enhancer

The ubiquitous transcriptional protein ZNF143 activates a diversity of genes while assisting to organize chromatin structure

Zinc Finger Protein 143 (ZNF143) is a pervasive C2H2 zinc-finger transcriptional activator protein regulating the efficiency of eukaryotic promoter regions. ZNF143 is able to activate transcription at both protein coding genes and small RNA genes transcribed by either RNA polymerase II or RNA polymerase III. Target genes regulated by ZNF143 are involved in an array of different cellular processes including both cancer and development. Although a key player in regulating eukaryotic genes, the molecular mechanism by with ZNF143 binds and activates genes transcribed by two different polymerases is still relatively unknown. In addition to its role as a transcriptional regulator, recent genomics experiments have implicated ZNF143 as a potential co-factor involved in chromatin looping and establishing higher order structure within the genome. This review focuses primarily on possible activation mechanisms of promoters by ZNF143, with less emphasis on the role of ZNF143 in cancer and development, and its function in establishing higher order chromatin contacts within the genome.

Identification of a SPH element in the distal region of a human U6 small nuclear RNA gene promoter and characterization of the SPH binding factor in HeLa cell extracts

Vertebrate small nuclear RNA (snRNA) gene promoters contain a distal, enhancer-like region that is composed of an octamer motif adjacent to at least one other element. Here we show that a human U6 snRNA distal region contains a SPH motif previously found in several chicken snRNA gene enhancers and the 5'-flanking region of vertebrate selenocysteine tRNA genes. SPH binding factor (SBF) was detected in either chicken or HeLa cell extracts that could bind SPH elements in a species-independent manner. Both human and chicken SBF required divalent cation to bind effectively to DNA. DNase I footprinting experiments indicated that human SBF specifically protected the human U6 SPH element. Furthermore, a SBF polypeptide of approximately 85 kDa was detected in both HeLa and chicken extracts following ultraviolet light-mediated cross-linking to human U6 or chicken U4 SPH elements. A part of the human U6 SPH element was quite sensitive to mutation, as demonstrated by both specific protein binding and transcription assays. From these data it is apparent that the distal regions of some RNA polymerase III- and RNA polymerase II-transcribed small RNA promoters are virtually identical in composition, and their mechanisms of transcriptional activation are possibly quite similar.

The transcriptional activator ZNF143 is essential for normal development in zebrafish

Background

ZNF143 is a sequence-specific DNA-binding protein that stimulates transcription of both small RNA genes by RNA polymerase II or III, or protein-coding genes by RNA polymerase II, using separable activating domains. We describe phenotypic effects following knockdown of this protein in developing Danio rerio (zebrafish) embryos by injection of morpholino antisense oligonucleotides that target znf143 mRNA.

Results

The loss of function phenotype is pleiotropic and includes a broad array of abnormalities including defects in heart, blood, ear and midbrain hindbrain boundary. Defects are rescued by coinjection of synthetic mRNA encoding full-length ZNF143 protein, but not by protein lacking the amino-terminal activation domains. Accordingly, expression of several marker genes is affected following knockdown, including GATA-binding protein 1 (gata1), cardiac myosin light chain 2 (cmlc2) and paired box gene 2a (pax2a). The zebrafish pax2a gene proximal promoter contains two binding sites for ZNF143, and reporter gene transcription driven by this promoter in transfected cells is activated by this protein.

Conclusions

Normal development of zebrafish embryos requires ZNF143. Furthermore, the pax2a gene is probably one example of many protein-coding gene targets of ZNF143 during zebrafish development.

The Small RNA gene activator protein, SphI postoctamer homology-binding factor/selenocysteine tRNA gene transcription activating factor, stimulates transcription of the human interferon regulatory factor-3 gene

Many small nuclear RNA gene promoters are activated by SphI postoctamer homology (SPH)-binding factor/selenocysteine tRNA gene transcription activating factor (SBF/Staf). Whereas this transcription factor was initially identified by its ability to bind to SPH elements in such promoters, it was more recently shown to have the capacity to activate transcription of a synthetic mRNA gene promoter through a distinct activation domain. Here, we show that the human interferon regulatory factor-3 (IRF-3) gene promoter contains a functional SPH element that is bound by SBF/Staf in vitro and in transfected cells.

The distal elements, OCT and SPH, stimulate the formation of preinitiation complexes on a human U6 snRNA gene promoter in vitro

The distal control region of a human U6 small nuclear RNA (snRNA) gene promoter contains two separable elements, octamer (OCT) and SPH, found in many vertebrate snRNA genes. Complete distal regions generally account for a 4- to 100-fold stimulation of snRNA gene promoters. We examined the mechanism of transcriptional stimulation by each element when linked to the proximal U6 promoter. Multimers of either OCT or SPH did not increase transcriptional levels above that with a single copy, either in transfected human cells or after in vitro transcription in a HeLa S100 extract. The orientation of a single SPH element differentially stimulated transcription in transfected cells, whereas the orientation of an octamer element was not important. Using Sarkosyl to limit transcription to a single-round, we concluded that promoters containing either OCT or SPH elements supported an increased number of preinitiation complexes in vitro. Furthermore, the rate of formation of U6 promoter preinitiation complexes resistant to low (0.015%) concentrations of Sarkosyl was accelerated on templates containing either OCT or SPH. However, neither element had a significant effect on the number of rounds of reinitiation in the S100 extract.

Analysis of the structure and expression of the chicken gene encoding a homolog of the human RREB-1 transcription factor

Ras proteins are involved in a number of signal transduction pathways including the mitogen-activated kinase cascade. Activated MAPKs translocate to the nucleus and phosphorylate transcription factors such as c-myc, TCF and AP-1. Recently, a Ras-responsive element binding transcription factor, RREB-1, was cloned from a human medullary thyroid carcinoma cell line. RREB-1 is a zinc finger protein that binds to a Ras-responsive element in the promoter of the human calcitonin gene. We report the cloning of the chicken homologue to human RREB-1. Amino-acid alignment demonstrates that chicken and human RREB-1 are 53% identical and 69% similar. Genomic southern analysis indicates that chicken rreb-1 is a single-copy gene in the chicken genome. We demonstrate that chicken and human rreb-1 display the same tissue distribution, being expressed in all tissues examined except the brain. Interestingly, chicken RREB-1 has an extended N-terminus and contains 16 zinc fingers of the TFIIIA subclass, in comparison to human RREB-1 which was reported to contain only four zinc fingers. The size discrepancy between the two predicted gene products is further discussed. An unusual structural feature of RREB-1 is the widely spaced arrangement of the zinc fingers.

Identification of proximal sequence element nucleotides contributing to the differential expression of variant U4 small nuclear RNA genes

The two U4 genes in the chicken genome code for distinct sequence variants of U4 small nuclear RNA that are differentially expressed during development. Whereas U4B RNA is constitutively expressed, U4X RNA is specifically down-regulated relative to U4B in a tissue-specific manner during development. To investigate mechanisms controlling the differential expression of the U4B and U4X genes, chimeric U4 genes were constructed and their transcriptional activities assayed by injection into Xenopus oocytes or by transfection of CV-1 cells. The proximal regulatory region of the U4B gene and the enhancers of both the U4B and U4X genes functioned efficiently in each expression system. However, the proximal region of the U4X gene was inactive. To localize and identify the responsible nucleotides, reciprocal point mutations were introduced into the U4X and U4B proximal regulatory regions. The results indicate that the U4X gene contains a suboptimal proximal sequence element, and that this results primarily from the identities of the nucleotides at positions -61 and -57 relative to the transcription start site.

Structure of the differentially expressed mouse U3A gene

Two markedly different forms of U3 RNA are present in mouse, the relative abundance of which largely depends upon the tissues. In all cases studied so far, the more abundant form is U3B, encoded by four previously characterized genes. We report here the isolation and analysis of the unique gene encoding the U3A variant, which completes the characterization of the mouse U3 multigene family. Comparisons with rat U3 genes indicate that the diversification of the A and B forms has predated the mouse/rat separation. The two forms of U3 RNA are submitted to similar, but not identical, primary and secondary structure constraints. As for the sequences flanking the RNA coding region, similar observations emerge for both types of genes: for each type, the 5' flanks are strongly conserved between mouse and rat, over at least the proximal 500 bp, whereas only about 30 bp of proximal 3' flanks are preserved, which include a signal for the formation of vertebrate U small nRNA 3' end. By contrast the 5' flanks of the two types of genes diverge extensively from each other, either in mouse or in rat, and could be involved in the differential expression of the two forms. Even over the few conserved motifs thought to be involved in the basic transcriptional control of vertebrate U small nRNA genes, the A and B forms of U3 genes exhibit specific differences maintained in the two rodent species.

Differential protein-DNA interactions at the promoter and enhancer regions of developmentally regulated U4 snRNA genes

In the chicken genome there are two closely-linked genes, U4B and U4X, that code for different sequence variants of U4 small nuclear RNA (snRNA). Both genes are expressed with nearly equal efficiency in the early embryo, but U4X gene expression is specifically down-regulated relative to U4B as development proceeds. At the present time, little is known about the mechanisms that regulate differential expression of snRNA genes. We have now identified a novel chicken factor, PPBF, that binds sequence-specifically in vitro to the proximal regulatory region of the U4X gene, but not to the proximal region of the U4B gene. PPBF is itself regulated during development and may therefore be a key factor involved in differentially regulating U4X gene transcription relative to U4B. The U4X and U4B enhancers contain distinct sequence variants of two essential motifs (octamer and SPH). The Oct-1 transcription factor binds with similar affinities to both the U4X and U4B octamer motifs. However, a second essential snRNA enhancer-binding protein, SBF, has a 20- to 30-fold lower affinity for the SPH motif in the U4X enhancer than for the homologous SPH motif in the U4B enhancer. A potential role therefore exists for SBF, as well as PPBF, in the preferential down-regulation of the U4X RNA gene during chicken development.

Regulation of immunoglobulin gene transcription

Analysis of the immunoglobulin gene suggests that their expression is controlled through the combinatorial action of tissue- and stage-specific factors (OTF-2, TF-microB, NF-kappa B), as well as more widely expressed E motif-binding factors such as E47/E12. Two basic issues cloud understanding of how these factors are involved in immunoglobulin gene regulation. First, cloning of these factors shows them to be members of families of proteins, all with similar DNA-binding specificities. OTF-2 is a member of the POU domain family, NF-kappa B is a related protein, and the microE5/kappa E2-binding factors are members of the bHLH family. Second, these binding sites and associated factors are involved in the regulation of many genes, not only the immunoglobulin genes, and in fact not only lymphoid-specific genes. These facts complicate understanding which member of a family is in fact responsible for interaction with, and activation of, a particular binding element in an enhancer/promoter. Recently, more detailed analysis of the interactions between such proteins and their related binding sites suggest that a certain level of specificity may in fact be encoded by the DNA element such that one family member of a protein is preferentially bound, or alternatively that the protein-DNA interactions that occur give subtle alterations in protein conformation that unmask an activation or protein-protein interactive domain. An additional level of regulation is imparted by combinatorial mechanisms such as adjacent DNA-binding elements and factors that may alter activity, as well as "cofactors" that, by forming a complex with the bound factor, affect its activation of a gene in a particular cell type. A third level of specificity may be obtained by factors such as NF-kappa B and the bHLH family due to their ability to create heterogeneous complexes, creating unique complexes in a tissue- or stage-specific manner. The multiple functions transcription factors such as NF-kappa B and OTF-2 play in the transcriptional regulation of multiple genes seems complex in contrast to a one factor, one gene regulation model. However, this type of organization may limit the number of factors lymphocytes would require if each lymphoid-specific gene were activated by a unique factor. Thus what appears to be complexity at the molecular level may reflect an economical organization at the cellular level. Investigation of the key factors controlling these genes suggests an ordered cascade of transcription factors becomes available in the cell during B cell differentiation.(ABSTRACT TRUNCATED AT 400 WORDS)

Induction of an altered DNA conformation by an inversion rearrangement in the 5'-flanking DNA of a U1 RNA gene

The anomalous electrophoretic behavior of a 686 base pair restriction fragment containing an in vitro-generated inversion mutation within the enhancer region of a chicken U1 RNA gene was investigated. This DNA fragment migrated with an abnormally slow mobility in polyacrylamide gels but migrated normally in agarose gels relative to the wild type fragment of identical size and base composition. In polyacrylamide gels, the degree of retardation was enhanced at low temperature, a phenomenon associated with bent DNA. A putative site of bending was localized at or near one end of the inverted region. These data suggest that the altered DNA conformation results from the juxtaposition of two normally remote DNA sequences.