Localization of yeast RNA polymerase I core subunits by immunoelectron microscopy

Immunoelectron microscopy was used to determine the spatial organization of the yeast RNA polymerase I core subunits on a three-dimensional model of the enzyme. Images of antibody-labeled enzymes were compared with the native enzyme to determine the localization of the antibody binding site on the surface of the model. Monoclonal antibodies were used as probes to identify the two largest subunits homologous to the bacterial beta and beta' subunits. The epitopes for the two monoclonal antibodies were mapped using subunit-specific phage display libraries, thus allowing a direct correlation of the structural data with functional information on conserved sequence elements. An epitope close to conserved region C of the beta-like subunit is located at the base of the finger-like domain, whereas a sequence between conserved regions C and D of the beta'-like subunit is located in the apical region of the enzyme. Polyclonal antibodies outlined the alpha-like subunit AC40 and subunit AC19 which were found co-localized also in the apical region of the enzyme. The spatial location of the subunits is correlated with their biological activity and the inhibitory effect of the antibodies.

Interactions between yeast TFIIIB components

Yeast transcription factor TFIIIB is a multicomponent factor comprised of the TATA-binding protein TBP and of associated factors TFIIIB70 and B". Epitope-tagged or histidine-tagged TFIIIB70 could be quantitatively removed from TFIIIB by affinity chromatography. TBP and B" (apparent mass 160-200 kDa) could be easily separated by gel filtration or ion-exchange chromatography. While only weak interactions were detected between TBP and B", direct binding of [35S]-labeled TBP to membrane-bound TFIIIB70 could be demonstrated in absence of DNA. On tRNA genes, there was no basal level of transcription in the complete absence of TBP. The two characterized TFIIIB components (recombinant rTFIIIB70 and rTBP) and a fraction cochromatographing with B" activity were found to be required for TFIIIC-independent transcription of the TATA-containing U6 RNA gene in vitro. Therefore, beside the TFIIIC-dependent assembly process, each TFIIIB component must have an essential role in DNA binding or RNA polymerase recruitment.

Interactions between yeast TFIIIB components

Yeast transcription factor TFIIIB is a multicomponent factor comprised of the TATA-binding protein TBP and of associated factors TFIIIB70 and B". Epitope-tagged or histidine-tagged TFIIIB70 could be quantitatively removed from TFIIIB by affinity chromatography. TBP and B" (apparent mass 160-200 kDa) could be easily separated by gel filtration or ion-exchange chromatography. While only weak interactions were detected between TBP and B", direct binding of [35S]-labeled TBP to membrane-bound TFIIIB70 could be demonstrated in absence of DNA. On tRNA genes, there was no basal level of transcription in the complete absence of TBP. The two characterized TFIIIB components (recombinant rTFIIIB70 and rTBP) and a fraction cochromatographing with B" activity were found to be required for TFIIIC-independent transcription of the TATA-containing U6 RNA gene in vitro. Therefore, beside the TFIIIC-dependent assembly process, each TFIIIB component must have an essential role in DNA binding or RNA polymerase recruitment.

Competition between chromatin and transcription complex assembly regulates gene expression during early development

Xenopus early development is characterized by a generalized absence of transcription, which resumes at the midblastula transition (MBT). We analyzed this regulation using a plasmid containing the c-myc promoter that is under the same developmental control when injected into fertilized eggs. We find that the repression of transcription can be relieved simply by preincubating the reporter plasmid with TATA binding protein (TBP). However, the repression of gene activity normally occurring before the MBT soon becomes dominant over this activation independent of cell cycle phases. This inactivation correlates with chromatin assembly, and titration of chromatin components not only relieves repression of TBP-dependent transcription but also permits the establishment of stable transcription during early development. Our data suggest that the large excess of histones represses gene activity during early development through a dynamic competition between chromatin assembly and transcription complex assembly.

Point mutations 5' to the tRNA selenocysteine TATA box alter RNA polymerase III transcription by affecting the binding of TBP

The selenocysteine tRNA(Sec) gene possesses two external promoter elements, one of which is constituted by a strong TATA box. Point mutant analysis performed in this study led to the conclusion that the functional TATA promoter actually encompasses the sequence -34 GGGTATAAAAGG-23. Individual changes at T-31 do not affect transcription much. Position T-29 is less permissive to mutation since transversion to a G, for example, is less well tolerated than at T-31. Interestingly, a double point mutation, converting GG(-33/-32) to TT, causes abrogation of transcription in vivo and severe reduction of transcription in vitro with human TBP. Therefore, data obtained underscore the fact that, in the Xenopus tRNA(Sec), these two Gs are an integral part of the TATA promoter. Gel retardation experiments indicate that the GG to TT substitution, which led human TBP to lose its ability to support efficient transcription in vitro, correlates with the appearance of an altered pattern of retarded complexes. Altogether, the data presented in this report support a model in which TBP interacts directly with the TATA element of the tRNA(Sec) gene, in contrast to the type of interaction proposed for classical TATA-less tRNA genes.

TFIIIC relieves repression of U6 snRNA transcription by chromatin

The U6 small nuclear (sn)RNA gene (SNR6) from the yeast Saccharomyces cerevisiae is transcribed by RNA polymerase III in vivo. This gene is unusual in having a TATA box at position -30, and an essential B-block element located downstream of the T-rich termination signal. The B block is one of the two intragenic promoter elements of transfer RNA genes that are recognized by transcription factor (TF)IIIC (ref. 4). But accurate in vitro transcription of yeast U6 snRNA gene by PolIII in a purified system requires only TFIIIB components, including the TATA-box binding protein TBP. Here we report that, after nucleosome reconstitution or chromatin assembly, U6 snRNA synthesis becomes dependent on TFIIIC and on the integrity of the B-block element. This observation resolves an apparent paradox between in vitro and in vivo results concerning the necessity of the downstream B-block element and sheds light on a new role of TFIIIC in gene activation.

The TATA-binding protein participates in TFIIIB assembly on tRNA genes

The TATA-binding protein TBP has been recently recognized as a general class III transcription factor. Using the gel shift assay to monitor initiation complex assembly on a yeast tRNA gene, we show that TBP is required for the TFIIIC-dependent assembly of TFIIIB. TFIIIB depleted of TBP by a simple chromatographic step does not bind stably to the TFIIIC-tDNA complex. Addition of yeast or human recombinant TBP allows the formation of a TFIIIB-TBP-TFIIIC-tDNA complex. The presence of TBP in the complex was inferred from the effect of anti-TBP antibodies and from the different migration properties of TFIIIB-TBP-tDNA complexes formed with yeast or human TBP.

Influence of pretreatment clinical characteristics on the response rate to mitomycin/vindesine/cisplatin (MVP) in unresectable non-small cell lung cancer. ATTIT (Association pour le Traitement des Tumeurs Intra-Thoraciques)

The authors report their experience with the MVP (mitomycin/vindesine/cisplatin) regimen of the Memorial Sloan-Kettering Cancer Center (MSKCC) which showed the highest response rate in non-small cell lung cancer (NSCLC). The aim was to respect the original reported schedule to appreciate its activity, because the same drug combination with dose and schedule variations used by other investigators has failed to reproduce the original report results. 82 consecutive previously untreated patients with unresectable and/or metastatic NSCLC received mitomycin (8 mg/m2 days 1, 29, 71), vindesine (3 mg/m2, days 1, 8, 15, 22, 29, 43, 57, 71) and cisplatin (120 mg/m2, days 1, 29, 71), with evaluation on day 71. 24 objective responses were noted (29%) (2 complete response/22 partial response) (95% CI 19%-39%), without differences according to histology. Differences in median survival were noted according to the performance status and type of response. Overall survival rates in responding patients were similar to those noted with the original schedules. Analysis of selection criteria showed that there were more patients with bone (P less than 0.01) or liver metastases (P less than 0.05), less women (P less than 0.001) and less adenocarcinoma (P less than 0.001) than the MSKCC trial. A dose intensity analysis showed only a minimal difference in the average weekly doses of vindesine (10% lower than MSKCC trial: 1.8 mg/m2 vs. 2.25 mg/m2). Disease improvement, a subjective response criterion used in the MSKCC trial, was probably underestimated in the current study. We conclude that the potential benefit of chemotherapy with a three-drug combination in NSCLC is greatest in patients with stage IIIa and IIIb disease or stage IV disease with a good performance status and a low metastatic volume.

Identification of the genes coding for the second-largest subunits of RNA polymerases I and III of Drosophila melanogaster

We have isolated cDNA and genomic clones of Drosophila melanogaster by cross-hybridization with a 658 bp fragment of the yeast gene coding for the second-largest subunit of RNA polymerase III (RET1). Determination of the sequence by comparison of genomic and cDNA regions reveals an ORF of 3405 nucleotides which is interrupted in the genomic sequence by an intron of 48 bp. The deduced polypeptide consists of 1135 amino acids with a calculated molecular weight of 128 kDa. The protein sequence shows the same conserved regions of homology as those observed for all the second-largest subunits of RNA polymerases cloned so far. The gene (DmRP128) obviously codes for a second-largest subunit of an RNA polymerase which is different from DmRP140 and DmRP135. We have purified three distinct RNA polymerase activities from D. melanogaster. By using specific RNA polymerase inhibitors in enzyme assays and by comparing their subunit composition we were able to distinguish between RNA polymerase I, II, and III. RNA polymerase preparations of D. melanogaster were blotted and the second-largest subunits were identified with antibodies raised against polypeptides expressed from DmRP128 and DmRP135. Anti-DmRP135 antibodies react strongly with the second-largest subunit of RNA polymerase I but do not react with the respective subunits of RNA polymerase II and III. The second-largest subunit of RNA polymerase III is only recognized by anti-DmRP128. Previously, we have claimed that DmRP135 codes for the second-largest subunit of RNA polymerase III.(ABSTRACT TRUNCATED AT 250 WORDS)

Participation of the TATA factor in transcription of the yeast U6 gene by RNA polymerase C

Fractionation of transcription extracts has led to the identification of multiple transcription factors specific for each form of nuclear RNA polymerase. Accurate transcription in vitro of the yeast U6 RNA gene by RNA polymerase C requires at least two factors. One of them was physically and functionally indistinguishable from transcription factor IID (TFIID or BTF1), a pivotal component of polymerase B transcription complexes, which binds to the TATA element. Purified yeast TFIID (yIID) or bacterial extracts that contained recombinant yIID were equally competent to direct specific transcription of the U6 gene by RNA polymerase C. The results suggest the formation of a hybrid transcription machinery, which may imply an evolutionary relation between class B and class C transcription factors.

Contacts between the factor TUF and RPG sequences

The yeast TUF factor binds specifically to RPG-like sequences involved in multiple functions at enhancers, silencers, and telomeres. We have characterized the interaction of TUF with its optimal binding sequence, rpg-1 (1-ACACCCATACATTT-14), using a gel DNA-binding assay in combination with methylation protection and mutagenesis experiments. As many as 10 base pairs appear to be engaged in factor binding. Analysis of a collection of 30 different RPG mutants demonstrated the importance of 8 base pairs at position 2, 3, 4, 5, 6, 7, 10, and 12 and the critical role of the central GC pair at position 5. Methylation protection data on four different natural sites confirmed a close contact at positions 4, 5, 6, and 10 and suggested additional contacts at base pairs 8, 12, and 13. The derived consensus sequence was RCAAYCCRYNCAYY. A quantitative band shift analysis was used to determine the equilibrium dissociation constant for the complex of TUF and its optimal binding site rpg-1. The specific dissociation constant (K8) was found to be 1.3 x 10(-11) M. The comparison of the K8 value with the dissociation constant obtained for nonspecific DNA sites (Kn8 = 8.7 x 10(-6) M) shows the high binding selectivity of TUF for its specific RPG target.

Electron microscopic study of yeast RNA polymerase A: analysis of single molecular images

The structural features of the yeast DNA-dependent RNA polymerase A (I) were examined by Scanning Transmission Electron Microscopy. The enzyme was absorbed in its monomeric form and negatively stained prior to digital image acquisition at low dose. The signal to noise ratio of single particle images was improved through averaging of a large number of previously aligned and partitioned images. Six classes of images were obtained reproducibly which corresponded to different projections of the enzyme. The enzyme structure was characterized by its presence of two curved arms which defined a longitudinal cleft. By analogy with the Escherichia coli enzyme, these arms could correspond to the two large subunits A135 and A190.

A yeast activity can substitute for the HeLa cell TATA box factor

Most class B (II) promoter regions from higher eukaryotes contain the TATA box and upstream and enhancer elements. Both the upstream and enhancer elements and their cognate factors have regulatory functions, whereas the TATA sequence interacts with the TATA box factor BTF1 to position RNA polymerase B and its ancillary initiation factors (STF, BTF2 and BTF3) to direct the initiation of transcription approximately 30 base pairs downstream. In many respects, class B promoter regions from the unicellular eukaryote Saccharomyces cerevisiae are similarly organized, containing upstream activating sequences that bear many similarities to enhancers. Although they are essential for initiation, the yeast TATA sequences are located at variable distances and further from the start sites (40-120 base pairs), whose locations are primarily determined by an initiator element. The basic molecular mechanisms that control initiation of transcription are known to be conserved from yeast to man: the yeast transcriptional transactivator GAL4 can activate a minimal TATA box-containing promoter in human HeLa cells, and a human inducible enhancer factor, the oestrogen receptor, can activate a similar minimal promoter in yeast. This striking evolutionary conservation prompted us to look for the presence in yeast of an activity that could possibly substitute for the human TATA box factor. We report here the existence of such an activity in yeast extracts.

TUF, the yeast DNA-binding factor specific for UASrpg upstream activating sequences: identification of the protein and its DNA-binding domain

The factor TUF interacts specifically with RPG or HOMOL1 sequences, which are present upstream of many genes coding for the yeast translational apparatus. Here we present evidence that the RPG and HOMOL1 motifs are variants of a consensus UASrpg (upstream activating sequence) recognized by the same factor. Factor TUF was identified by using two highly selective methods. The DNA-protein complex was isolated by pore-limit electrophoresis in polyacrylamide gradient gels and found to contain a single polypeptide of 150 kDa. In a two-step protein-blotting/nuclease-protection ("footprinting") procedure, the same 150-kDa polypeptide blotted on nitrocellulose exhibited the same specific DNA-binding properties as TUF factor. A 50-kDa DNA-binding domain of TUF was isolated by selective proteolysis. This suggests a bipolarization of the TUF protein, with distinct functional domains.

Catalytic activity of a copper(II)-oxidized glutathione complex on aqueous superoxide ion dismutation

The study of the catalytic activity of a Cu(II)-oxidized glutathione system upon the disproportionation of superoxide radicals shows that the mononuclear complex MA catalyzes dismutation in the pH range 7-9. The corresponding first-order rate constant of value kcat congruent to 6 X 10(6) M-1 sec-1 is pH independent, whereas the second-order rate constant ks for the reference solutions is pH dependent. The kcat constant is about 10-, 100-, and 300-fold higher than the ks constant at pH 7, 8, and 9, respectively. The measured effect is explained in terms of free axial sites in the square-planar arrangement around the copper ion.

Isolation of structural genes for yeast RNA polymerases by immunological screening

A lambda gt11 yeast genomic library was screened with antibodies directed against yeast RNA polymerases A, B, and C. Thirty-five individual recombinant phages that expressed proteins in Escherichia coli that were antigenically related to RNA polymerases A, B, or C were isolated by using 22 distinct antisera. Thus, all 22 genes for the RNA polymerase subunits were potentially cloned. In three cases (lambda A-43, lambda A-40, and lambda A-34.5), an antigenic protein was expressed in E. coli with the same molecular weight as the corresponding subunit. When lambda A-40 DNA was used to hybrid-select yeast mRNA, the protein translated in vitro was the expected size for the A-40 subunit, further supporting our isolation of the A-40 gene. However, mRNA hybrid selected by lambda A-27 DNA did not code for a protein of the correct size. The lengths of the mRNA that hybridized to phage lambda A-190 or lambda C-160 DNA on RNA blots were in agreement with the predicted sizes of the coding regions of the corresponding genes. As predicted by our previous immunological results, yeast DNA inserts of the lambda A-190 and lambda C-160 clones cross-hybridized to the B-220 subunit gene. The cloned genes for the RNA polymerase subunits will prove to be valuable tools for the study of the function, regulation, and genetics of the yeast RNA polymerases.

A general upstream binding factor for genes of the yeast translational apparatus

Fractionation of yeast extracts on heparin-agarose revealed the presence of a DNA footprinting activity that interacted specifically with the 5'-upstream region of TEF1 and TEF2 genes coding for the protein synthesis elongation factor EF-1 alpha, and of the ribosomal protein gene RP51A. The protected regions encompassed the conserved sequences 'HOMOL1' (AACATC TA CG T A G CA) or RPG-box (ACCCATACATT TA) previously detected 200-400 bp upstream of most of the yeast ribosomal protein genes examined. Two types of protein-DNA complexes were separated by a gel electrophoresis retardation assay. Complex 1, formed on TEF1, TEF2 and RP51A 5'-flanking region, was correlated with the protection of a 25-bp sequence. Complex 2, formed on TEF2 or RP51A probes at higher protein concentrations, corresponded to an extended footprint of 35-40 bp. The migration characteristics of the protein-DNA complexes and competition experiments indicated that the same component(s) interacted with the three different promoters. It is suggested that this DNA factor(s) is required for activation and coordinated regulation of the whole family of genes coding for the translational apparatus.

Yeast RNA polymerase C and its subunits. Specific antibodies as structural and functional probes

Yeast RNA polymerase C purified by a simple large scale method was resolved into multiple components by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Specific antibodies directed against each polypeptide chain were prepared in rabbits and used as structural and functional probes. With minor exceptions, each antibody recognized specifically the corresponding polypeptide by blot-immunodetection. Cross-reactions with purified RNA polymerases A and B confirmed our previous description of the subunits shared by the three nuclear RNA polymerases. Immunoadsorption of RNA polymerase C at different stages of purification using antibodies to subunits C160 and C128 yielded the same collection of polypeptides as found in the purified enzyme: C160, C128, C82, C53, C40, C37, C34, C31, C27, C25, C23, C19, C14.5, C12.5, and C10. Subunit-specific antibodies were used to probe the activity of RNA polymerase C in a specific, reconstituted transcription system as well as on a nonspecific template. Transcription of the tRNAGlu3 gene in vitro was inhibited when RNA polymerase C was preincubated with antibodies directed to C128, C82, C53, C34, C23, or C19. Antibodies to C82, C53, and C34 were much less inhibitory in the nonspecific assay. Inhibition by anti-C128 or anti-C23 was relieved by preincubation of enzyme C with plasmid DNA prior to antibody addition. These results are discussed in terms of the participation of these polypeptides to the active enzyme molecule, and of their possible role in DNA binding or transcription factor recognition.