Two TFIIIA activities regulate expression of the Xenopus 5S RNA gene families

Transcription of individual tRNAGly1 genes from within a multigene family is regulated by transcription factor TFIIIB

Members of a multigene family from the silkworm Bombyx mori have been classified based on their transcriptions in homologous nuclear extracts, into three groups of highly, moderately and poorly transcribed genes. Because all these gene copies have identical coding sequences and consequently identical promoter elements (the A and B boxes), the flanking sequences modulate their expression levels. Here we demonstrate the interaction of transcription factor TFIIIB with these genes and its role in regulating differential transcriptions. The binding of TFIIIB to the poorly transcribed gene -6,7 was less stable compared with binding of TFIIIB to the highly expressed copy, -1. The presence of a 5' upstream TATA sequence closer to the coding region in -6,7 suggested that the initial binding of TFIIIC to the A and B boxes sterically hindered anchoring of TFIIIB via direct interactions, leading to lower stability of TFIIIC-B-DNA complexes. Also, the multiple TATATAA sequences present in the flanking regions of this poorly transcribed gene successfully competed for TFIIIB reducing transcription. The transcription level could be enhanced to some extent by supplementation of TFIIIB but not by TATA box binding protein. The poor transcription of -6,7 was thus attributed both to the formation of a less stable transcription complex and the sequestration of TFIIIB. Availability of the transcription factor TFIIIB in excess could serve as a general mechanism to initiate transcription from all the individual members of the gene family as per the developmental needs within the tissue.

Heterogeneous nuclear ribonucleoprotein K is a transcription factor

The CT element is a positively acting homopyrimidine tract upstream of the c-myc gene to which the well-characterized transcription factor Spl and heterogeneous nuclear ribonucleoprotein (hnRNP) K, a less well-characterized protein associated with hnRNP complexes, have previously been shown to bind. The present work demonstrates that both of these molecules contribute to CT element-activated transcription in vitro. The pyrimidine-rich strand of the CT element both bound to hnRNP K and competitively inhibited transcription in vitro, suggesting a role for hnRNP K in activating transcription through this single-stranded sequence. Direct addition of recombinant hnRNP K to reaction mixtures programmed with templates bearing single-stranded CT elements increased specific RNA synthesis. If hnRNP K is a transcription factor, then interactions with the RNA polymerase II transcription apparatus are predicted. Affinity columns charged with recombinant hnRNP K specifically bind a component(s) necessary for transcription activation. The depleted factors were biochemically complemented by a crude TFIID phosphocellulose fraction, indicating that hnRNP K might interact with the TATA-binding protein (TBP)-TBP-associated factor complex. Coimmunoprecipitation of a complex formed in vivo between hnRNP K and epitope-tagged TBP as well as binding in vitro between recombinant proteins demonstrated a protein-protein interaction between TBP and hnRNP K. Furthermore, when the two proteins were overexpressed in vivo, transcription from a CT element-dependent reporter was synergistically activated. These data indicate that hnRNP K binds to a specific cis element, interacts with the RNA polymerase II transcription machinery, and stimulates transcription and thus has all of the properties of a transcription factor.

The role of transcription factors, chromatin structure and DNA replication in 5 S RNA gene regulation

Differential expression of the oocyte and somatic 5 S RNA genes during Xenopus development can be explained by changes in transcription factor and histone interactions with the two types of gene. Both factors and histones bind 5 S RNA genes with specificity. Protein-protein interactions determine the stability of potentially transcriptionally active or repressed nucleoprotein complexes. A decline in transcription factor abundance, differential binding of transcription factors to oocyte and somatic 5 S genes, and increased competition with the histones for association with DNA during early embryogenesis, can account for the developmental decision to selectively repress the oocyte genes, while retaining the somatic genes in the transcriptionally active state. The 5 S ribosomal genes of Xenopus are perhaps the simplest eukaryotic genes to show regulated expression during development. A large multigene family (oocyte 5 S DNA) is transcriptionally active in oocytes but is repressed in somatic cells, whereas a small multigene family (somatic 5 S DNA) is active in both cell types. A potential molecular mechanism to explain the developmental switch that turns off oocyte 5 S DNA transcription has been experimentally reconstructed in vitro and more recently tested in vivo. Central to this mechanism is the specific association of both transcription factors and histones with 5 S RNA genes. How the interplay of histones and transcription factors is thought to affect transcription, and how their respective contributions might change during development from an oocyte, to an embryo and eventually to a somatic cell is the focus of this review.

Transcription factor IIIA (TFIIIA): an update

Xenopus transcription factor, termed TFIIIA, is the first eukaryotic transcription factor purified to homogeneity and one of the most extensively characterized polymerase III gene factors at the levels both of the protein and its gene. It is an abundant protein in oocytes and is specifically required for the 5S RNA gene transcription. It promotes the formation of a stable transcription complex by first binding to the internal control region of the 5S RNA gene through its zinc finger motifs. It contains two structural domains and associates with 5S RNA to form 7S ribonucleoprotein particles in oocytes. Its expression is developmentally controlled at the level of transcription and translation. It participates in the assembly of active chromatin templates and, at least in part, is responsible for the differential expression of two kinds of 5S RNA genes in Xenopus.

Kinetic control of 5 S RNA gene transcription

We have determined that the differential transcription of somatic and oocyte-type 5 S RNA genes in a Xenopus laevis oocyte extract is a consequence of vastly different rates of stable complex assembly. Somatic-type 5 S RNA genes sequester a limiting transcription factor much more rapidly than oocyte-type 5 S RNA genes. Once formed, however, transcription complexes on both types of genes are stable, and are transcribed at nearly equivalent rates. The relative rates of stable transcription complex assembly are strongly dependent on the concentration of Mg2+. Kinetic differences in transcription complex assembly provides a key distinguishing feature between these two genes which may be used in the selective repression of oocyte-type 5 S RNA genes during the early development of Xenopus, and may also be utilized in other systems of regulated gene expression.

Mutant conformation of p53. Precise epitope mapping using a filamentous phage epitope library

Many naturally occurring point mutations in the p53 gene lead to a proportion of the encoded protein molecules adopting a distinct, "mutant" conformation characterized by exposure of a normally cryptic epitope recognized by the monoclonal antibody PAb240. Here the PAb240 epitope is defined using a filamentous phage epitope library. The hexapeptides displayed by the PAb240-binding phage isolated from the library were all highly related and allowed both direct localization of the epitope and prediction of a specific interaction between PAb240 and Xenopus TFIIIA. This study demonstrates for the first time the power of phage epitope libraries in the precise definition of previously unmapped epitopes. Identification of the PAb240 epitope precisely defines a region of the p53 molecule structurally altered by the mutation-induced conformational shift.

Differential expression of oocyte-type class III genes with fraction TFIIIC from immature or mature oocytes

The Xenopus OAX genes can be expressed in oocytes but are virtually inactive in somatic tissues. The tRNA(Met1) (tMET) genes also appear to be developmentally regulated. We have examined the reason for the differential expression of these class III genes. Analysis of the transcriptional activities of extracts derived from immature and mature oocytes revealed that the developmental regulation of these genes can be reproduced in vitro. We have partially purified the required transcription factors B and C from these extracts to ascertain the components responsible for this differential activity. The immature oocyte C fraction activates the tMET and OAX genes when reconstituted with either the immature or mature oocyte-derived B fraction. In contrast, the mature oocyte C fraction fails to activate these genes regardless of which B fraction is used. Both C fractions activated the somatic 5S gene. Purification of the oocyte C fractions by phosphocellulose or B box DNA affinity chromatography failed to separate additional activities responsible for the differential expression of OAX or tMET. By using template exclusion assays, the inability of the mature oocyte C fraction to activate transcription was correlated with an inability to form stable transcription complexes with the tMET or OAX gene.

Differential expression of oocyte-type class III genes with fraction TFIIIC from immature or mature oocytes

The Xenopus OAX genes can be expressed in oocytes but are virtually inactive in somatic tissues. The tRNA(Met1) (tMET) genes also appear to be developmentally regulated. We have examined the reason for the differential expression of these class III genes. Analysis of the transcriptional activities of extracts derived from immature and mature oocytes revealed that the developmental regulation of these genes can be reproduced in vitro. We have partially purified the required transcription factors B and C from these extracts to ascertain the components responsible for this differential activity. The immature oocyte C fraction activates the tMET and OAX genes when reconstituted with either the immature or mature oocyte-derived B fraction. In contrast, the mature oocyte C fraction fails to activate these genes regardless of which B fraction is used. Both C fractions activated the somatic 5S gene. Purification of the oocyte C fractions by phosphocellulose or B box DNA affinity chromatography failed to separate additional activities responsible for the differential expression of OAX or tMET. By using template exclusion assays, the inability of the mature oocyte C fraction to activate transcription was correlated with an inability to form stable transcription complexes with the tMET or OAX gene.

Chromosomal organization of Xenopus laevis oocyte and somatic 5S rRNA genes in vivo

We describe the chromosomal organization of the major oocyte and somatic 5S RNA genes of Xenopus laevis in chromatin isolated from erythrocyte nuclei. Both major oocyte and somatic 5S DNA repeats are associated with nucleosomes; however, differences exist in the organization of chromatin over the oocyte and somatic 5S RNA genes. The repressed oocyte 5S RNA gene is protected from nuclease digestion by incorporation into a nucleosome, and the entire oocyte 5S DNA repeat is assembled into a loosely positioned array of nucleosomes. In contrast, the potentially active somatic 5S RNA gene is accessible to nuclease digestion, and the majority of somatic 5S RNA genes appear not to be incorporated into positioned nucleosomes. Evidence is presented supporting the stable association of transcription factors with the somatic 5S RNA genes. Histone H1 is shown to have a role both in determining the organization of nucleosomes over the oocyte 5S DNA repeat and in repressing transcription of the oocyte 5S RNA genes.

Chromosomal organization of Xenopus laevis oocyte and somatic 5S rRNA genes in vivo

We describe the chromosomal organization of the major oocyte and somatic 5S RNA genes of Xenopus laevis in chromatin isolated from erythrocyte nuclei. Both major oocyte and somatic 5S DNA repeats are associated with nucleosomes; however, differences exist in the organization of chromatin over the oocyte and somatic 5S RNA genes. The repressed oocyte 5S RNA gene is protected from nuclease digestion by incorporation into a nucleosome, and the entire oocyte 5S DNA repeat is assembled into a loosely positioned array of nucleosomes. In contrast, the potentially active somatic 5S RNA gene is accessible to nuclease digestion, and the majority of somatic 5S RNA genes appear not to be incorporated into positioned nucleosomes. Evidence is presented supporting the stable association of transcription factors with the somatic 5S RNA genes. Histone H1 is shown to have a role both in determining the organization of nucleosomes over the oocyte 5S DNA repeat and in repressing transcription of the oocyte 5S RNA genes.

Is there a Xenopus transcription factor that can substitute for TFIIIA? Re: Two TFIIIA activities regulate expression of the Xenopus 5S RNA gene families

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Transcription complex disruption caused by a transition in chromatin structure

Chromatin structure is known to influence class III gene expression in vitro. We describe the active transcription of Xenopus class III genes following replication and assembly into chromatin by using Xenopus egg extracts. Changes in the structure of this active chromatin dependent on the presence of exogeneous Mg2+ ATP or on the addition of a mixture of histones H2A and H2B are shown to lead to the selective repression of Xenopus 5S RNA genes. Preexisting transcription complexes on 5S DNA are disrupted following the reorganization of a "disordered" histone-DNA complex into a structure consisting of physiologically spaced nucleosomes. Thus, we demonstrate that chromatin structural transitions can have dominant and specific effects on transcription.

Yeast TFIIIA + TFIIIC/tau-factor, but not yeast TFIIIA alone, interacts with the Xenopus 5S rRNA gene

The successful use of mixed heterologous in vitro transcription systems has suggested that the species specificity of RNA polymerase III transcription is low. To see if this extends to lower eukaryotic class III transcription factors, we compared the interactions of the two yeast assembly factors, TFIIIA and TFIIIC/tau factor, with a homologous yeast 5S rRNA gene and a heterologous Xenopus laevis somatic 5S rRNA gene. Transcription assays showed that the Xenopus gene was transcriptionally inactive in a crude cell-free yeast extract that actively transcribes the homologous gene. However, the Xenopus gene was still able to compete for limiting transcription factors. Electrophoretic DNA binding assays revealed that while TFIIIA bound avidly to the yeast gene (generating the 'A-complex'), it had no affinity for the Xenopus 5S rRNA gene. Nevertheless, a complex of both TFIIIA and TFIIIC/tau factor (the 'AC-complex') was formed on the two genes with similar affinity, although only the complex assembled on the homologous gene was able to activate transcription. Thus enough sequence information is present on the heterologous gene to direct transcription factor assembly, but not to activate transcription. Like its counterpart in Xenopus, the yeast TFIIIA appears to be a zinc binding protein that is inactivated by EDTA and 1,10-phenanthroline, and reactivated in the presence of zinc ions. Bound to the 5S rRNA gene, TFIIIA is however significantly more resistant to inactivation by chelators than in its free state. The AC-complex differs from the A-complex by being less affected by chelators, and by being more sensitive to the dissociating effect of single-stranded DNA.

Transcription complex disruption caused by a transition in chromatin structure

Chromatin structure is known to influence class III gene expression in vitro. We describe the active transcription of Xenopus class III genes following replication and assembly into chromatin by using Xenopus egg extracts. Changes in the structure of this active chromatin dependent on the presence of exogeneous Mg2+ ATP or on the addition of a mixture of histones H2A and H2B are shown to lead to the selective repression of Xenopus 5S RNA genes. Preexisting transcription complexes on 5S DNA are disrupted following the reorganization of a "disordered" histone-DNA complex into a structure consisting of physiologically spaced nucleosomes. Thus, we demonstrate that chromatin structural transitions can have dominant and specific effects on transcription.

Xenopus transcription factor IIIA (XTFIIIA): after a decade of research

Xenopus transcription factor IIIA (XTFIIIA) is the first eukaryotic transcription factor purified to homogeneity and is specifically required for the 5S RNA gene transcription. It contains two structural domains and nine zinc finger motifs through which it recognizes the promoter region of the 5S RNA gene. It also binds to 5S RNA and serves to store 5S RNA in the form of 7S ribonucleoprotein particles in oocytes. Additionally, it forms a metastable complex with 5S DNA and promotes the formation of stable and competent transcription complexes. Its expression is developmentally controlled at the level of transcription and translation. Moreover, it participates in the assembly of active chromatin templates and at least, in part, is responsible for the developmental regulation of two kinds of 5S RNA genes in Xenopus.

Physical and immunological characterization of human transcription factor IIIA

Human transcription factor IIIA (htFIIIA), specifically required for transcription of the gene for 5S ribosomal RNA has been characterized with respect to some of its physical, immunological and functional properties. TFIIIA from HeLa cells, which selectively binds 5S RNA, is a monomer of approximately 35 kDa with a Stokes' radius of approximately 2.65 nm and a sedimentation coefficient of approximately 2.8 S. These values indicate that the human protein is of rather globular shape and hence diverges not only in molecular mass but also in most of the molecular properties from its highly asymmetric counterpart in Xenopus laevis oocytes. By raising specific polyclonal antibodies against hTFIIIA it was shown in Western immunoblots that there was no cross-reaction between anti-hTFIIIA antibodies and the amphibian protein. Conversely, monoclonal antibodies against three domains of X. laevis TFIIIA antibodies and the amphibian protein. Conversely, monoclonal antibodies against three domains of X. laevis TFIIIA did not cross-react with the human transcription factor. The polyclonal antisera raised against hTFIIIA specifically neutralized binding of the human transcription factor to 5S DNA and abolished in vitro transcription of 5S RNA but these antibodies were unable to inhibit 5S RNA synthesis in cellular extracts from Xenopus, Drosophila or yeast cells. Finally, the species variation of TFIIIA could be substantiated by electrophoretic mobility shift assays revealing preferential binding of hTFIIIA to the homologous 5S RNA gene.

Chromosomal footprinting of transcriptionally active and inactive oocyte-type 5S RNA genes of Xenopus laevis

The chromatin structure of the Xenopus oocyte-specific 5S rRNA genes was examined at high resolution in immature oocyte and somatic cell chromosomes by DNase I footprinting. On oocyte chromatin, where the genes are active, the cleavage preferences over the entire gene region showed a periodic pattern of sensitivity and were dramatically different from the patterns obtained with deproteinized DNA or somatic cell chromatin. Further, the normal binding site for TFIIIA over the internal promoter region was preferentially sensitive to cleavage, indicating that TFIIIA was not bound in the manner predicted by in vitro experiments. In somatic cell chromatin, the oocyte-type 5S genes displayed a cleavage pattern largely similar to deproteinized DNA suggesting the absence of positioned nucleosomes on these inactive genes, although the presence of uncharacterized repressor complexes could not be ruled out. These data are discussed in terms of potential forms of the chromatin structure and alternative mechanisms of oocyte-type gene activation.

Additional intragenic promoter elements of the Xenopus 5S RNA genes upstream from the TFIIIA-binding site

The major promoter element of the Xenopus laevis 5S RNA gene is located within the transcribed region of the gene and forms the binding site for the transcription initiation factor TFIIIA. We report an analysis of deletion and substitution mutations within the coding region of the major oocyte-type 5S gene of X. laevis. Our results differ from those of previous mutagenesis studies conducted on the somatic-type genes of Xenopus borealis and X. laevis. Transcription assays in whole oocyte S-150 extracts, with both oocyte- and somatic-type mutants, revealed additional promoter elements between the start site for transcription and the binding site for TFIIIA. These sequences regulate the efficiency of binding TFIIIC, a transcription factor required by the genes transcribed by RNA polymerase III containing intragenic promoters. Under TFIIIC-limiting conditions, the somatic-type gene had a 10-fold-higher affinity for TFIIIC than did the major oocyte-type 5S gene. One mutation in the oocyte-type gene (nucleotides +33 to +39) reduced TFIIIC affinity and transcriptional activity four- to fivefold. Differences in TFIIIC affinity between oocyte- and somatic-type genes may contribute to the differential transcription of these genes observed during Xenopus embryogenesis.

Additional intragenic promoter elements of the Xenopus 5S RNA genes upstream from the TFIIIA-binding site

The major promoter element of the Xenopus laevis 5S RNA gene is located within the transcribed region of the gene and forms the binding site for the transcription initiation factor TFIIIA. We report an analysis of deletion and substitution mutations within the coding region of the major oocyte-type 5S gene of X. laevis. Our results differ from those of previous mutagenesis studies conducted on the somatic-type genes of Xenopus borealis and X. laevis. Transcription assays in whole oocyte S-150 extracts, with both oocyte- and somatic-type mutants, revealed additional promoter elements between the start site for transcription and the binding site for TFIIIA. These sequences regulate the efficiency of binding TFIIIC, a transcription factor required by the genes transcribed by RNA polymerase III containing intragenic promoters. Under TFIIIC-limiting conditions, the somatic-type gene had a 10-fold-higher affinity for TFIIIC than did the major oocyte-type 5S gene. One mutation in the oocyte-type gene (nucleotides +33 to +39) reduced TFIIIC affinity and transcriptional activity four- to fivefold. Differences in TFIIIC affinity between oocyte- and somatic-type genes may contribute to the differential transcription of these genes observed during Xenopus embryogenesis.

The characterization of the TFIIIA synthesized in somatic cells of Xenopus laevis

In somatic cells of Xenopus, transcription of the TFIIIA gene initiates greater than 200 bp upstream from the start site used in oocytes. The resultant mRNA encodes a protein, S-TFIIIA, that is 22 amino acids longer at its amino terminus than the abundant form of TFIIIA in oocytes (O-TFIIIA). S-TFIIIA binds the 5S RNA gene and 5S RNA, and both O- and S-TFIIIA promote the formation of stable transcription complexes on oocyte-type 5S RNA genes in an oocyte nuclear extract. We have not found any functional difference between the two forms of TFIIIA. Different transcription start sites suggest differential promoter usage--one in oocytes that permits high levels of gene activity and another that is used in somatic cells for low-level TFIIIA mRNA synthesis.

Unraveling the complexities of transcription by RNA polymerase III

The biosynthesis of proteins and nucleic acids in eukaryotes requires the participation of numerous small RNAs, many of which are products of RNA polymerase III transcription. How cells are able to coordinate the synthesis of these RNAs during growth and replication has been the subject of recent exciting and thought-provoking studies. We review the progress in this area, and focus upon shared properties between transcription systems having different functions.

Functions of maternal mRNA in early development

In this review, the types of mRNAs found in oocytes and eggs of several animal species, particularly Drosophila, marine invertebrates, frogs, and mice, are described. The roles that proteins derived from these mRNAs play in early development are discussed, and connections between maternally inherited information and embryonic pattern are sought. Comparisons between genetically identified maternally expressed genes in Drosophila and maternal mRNAs biochemically characterized in other species are made when possible. Regulation of the meiotic and early embryonic cell cycles is reviewed, and translational control of maternal mRNA following maturation and/or fertilization is discussed with regard to specific mRNAs.