Characterization of factors and DNA sequences required for accurate transcription of the Saccharomyces cerevisiae 5 S RNA gene

Cysteine-rich zinc finger proteins and the nuclear factor kappa-B pathway

Inflammation-related disorders, such as autoimmune diseases and cancer, impose a significant global health burden. Zinc finger proteins (ZFs) are ubiquitous metalloproteins which regulate inflammation and many biological signaling pathways related to growth, development, and immune function. Numerous ZFs are involved in the nuclear factor kappa-light-chain-enhancer of activated B cells (NFκB) pathway, associating them with inflammation-related diseases that feature chronically elevated pro-inflammatory cytokines. This review highlights the predominance of ZFs in NFκB-related signaling and summarizes the breadth of functions that these proteins perform. The cysteine-specific post-translational modification (PTM) of persulfidation is also discussed in the context of these cysteine-rich ZFs, including what is known from the few available reports on the functional implications of ZF persulfidation. Persulfidation, mediated by endogenously produced hydrogen sulfide (H2S), has a recently established role in signaling inflammation. This work will summarize the known connections between ZFs and persulfidation and has the potential to inform on the development of related therapies.

Retrotransposon profiling of RNA polymerase III initiation sites

Although retroviruses are relatively promiscuous in choice of integration sites, retrotransposons can display marked integration specificity. In yeast and slime mold, some retrotransposons are associated with tRNA genes (tDNAs). In the Saccharomyces cerevisiae genome, the long terminal repeat retrotransposon Ty3 is found at RNA polymerase III (Pol III) transcription start sites of tDNAs. Ty1, 2, and 4 elements also cluster in the upstream regions of these genes. To determine the extent to which other Pol III-transcribed genes serve as genomic targets for Ty3, a set of 10,000 Ty3 genomic retrotranspositions were mapped using high-throughput DNA sequencing. Integrations occurred at all known tDNAs, two tDNA relics (iYGR033c and ZOD1), and six non-tDNA, Pol III-transcribed types of genes (RDN5, SNR6, SNR52, RPR1, RNA170, and SCR1). Previous work in vitro demonstrated that the Pol III transcription factor (TF) IIIB is important for Ty3 targeting. However, seven loci that bind the TFIIIB loader, TFIIIC, were not targeted, underscoring the unexplained absence of TFIIIB at those sites. Ty3 integrations also occurred in two open reading frames not previously associated with Pol III transcription, suggesting the existence of a small number of additional sites in the yeast genome that interact with Pol III transcription complexes.

The RNA polymerase III-recruiting factor TFIIIB induces a DNA bend between the TATA box and the transcriptional start site

TFIIIB, the RNA polymerase III-recruiting factor of Saccharomyces cerevisiae, may be assembled upstream of the transcriptional start site, either through the interaction of its constituent TATA-binding protein (TBP) with a strong TATA-box, or by means of the multisubunit assembly factor, TFIIIC. Missing nucleoside interference analysis of TFIIIC-dependent TFIIIB-DNA complex formation revealed enhanced complex formation at 0 degreesC when the DNA is missing nucleosides in two broad 7-10 bp regions centered around base-pairs -17 and -3 relative to the transcriptional start site; no effect of missing nucleosides was evident at 20 degreesC. The implication of these results for required DNA flexure in TFIIIC-mediated TFIIIB-DNA complex formation was pursued in a TFIIIC-independent context, using DNA with a suboptimal 6 bp TATA box (TATAAA). A unique missing nucleoside at the downstream end of the TATA box, corresponding to the position of one of two TBP-mediated DNA kinks, significantly enhances TBP-DNA complex formation. In contrast, TFIIIB displays a broad preference for missing nucleosides within an approximately 15 bp region immediately downstream of the TATA box. Consecutive mismatches (4-nt loops), either at the sites of TBP-mediated DNA kinking at both ends of the TATA box or within the identified region where missing nucleosides promote TFIIIB-DNA complex formation, also result in enhanced and specific TFIIIB assembly; 4-nt loops further downstream do not lead to preferential placement of TFIIIB. We conclude that TFIIIB induces an additional DNA deformation between the TATA box and the start site of transcription that is likely to be more extended than the sharp kinks generated by TBP.

A hydrophobic segment within the 81-amino-acid domain of TFIIIA from Saccharomyces cerevisiae is essential for its transcription factor activity

Transcription factor IIIA (TFIIIA) binds to the internal control region of the 5S RNA gene as the first step in the in vitro assembly of a TFIIIB-TFIIIC-TFIIIA-DNA transcription complex. An 81-amino-acid domain that is present between zinc fingers 8 and 9 of TFIIIA from Saccharomyces cerevisiae is essential for the transcription factor activity of this protein (C. A. Milne and J. Segall, J. Biol. Chem. 268:11364-11371, 1993). We have monitored the effect of mutations within this domain on the ability of TFIIIA to support transcription of the 5S RNA gene in vitro and to maintain cell viability. TFIIIA with internal deletions that removed residues 282 to 315, 316 to 334, 328 to 341, or 342 to 351 of the 81-amino-acid domain retained activity, whereas TFIIIA with a deletion of the short leucine-rich segment 352NGLNLLLN359 at the carboxyl-terminal end of this domain was devoid of activity. Analysis of the effects of double and quadruple mutations in the region extending from residue 336 to 364 confirmed that hydrophobic residues in this portion of the 81-amino-acid domain, particularly L343, L347, L354, L356, L357, and L358, and to a lesser extent F336 and L337, contributed to the ability of TFIIIA to promote transcription. We propose that these hydrophobic residues play a role in mediating an interaction between TFIIIA and another component of the transcriptional machinery. We also found that TFIIIA remained active if either zinc finger 8 or zinc finger 9 was disrupted by mutation but that TFIIIA containing a disruption of both zinc finger 8 and zinc finger 9 was inactive.

The Saccharomyces cerevisiae MFS superfamily SGE1 gene confers resistance to cationic dyes

A gene from Saccharomyces cerevisiae whose overexpression confers resistance to 10-N-nonyl acridine orange (NAO) has been isolated. This cationic dye binds acidic phospholipids and more specifically cardiolipin (Petit, J. M., Maftah, A., Ratinaud, M. H. and Julien, R. Eur. J. Biochem. 209, 267-273, 1992). The isolated gene was found to be identical to SGE1, a partial multicopy suppressor of the gal11 mutation (Amakasu, H., Suzuki, Y., Nishizawa, M. and Fukasawa, T. Genetics 134, 675-683, 1993), that also confers crystal violet resistance to a supersensitive strain (Ehrenhofer-Murray, A. E., Wurgler, F. E. and Sengstag, C. Mol. Gen. Genet. 244, 287-294, 1994). The data presented in this paper show that the SGE1 gene product, a member of the major facilitator superfamily, confers a pleiotropic drug-resistance phenotype when present in high copy number. The results also demonstrate that Sge1p acts as an extrusion permease whose specificity seems restricted to dye molecules possessing a large unsaturated domain that stabilizes a permanent positive charge such as NAO, crystal violet, ethidium bromide or malachite green.

Interaction of wild-type and truncated forms of transcription factor IIIA from Saccharomyces cerevisiae with the 5 S RNA gene

Transcription factor (TF) IIIA, which contains nine zinc finger motifs, binds to the internal control region of the 5S RNA gene as the first step in the assembly of a multifactor complex that promotes accurate initiation of transcription by RNA polymerase III. We have monitored the interaction of wild-type and truncated forms of yeast TFIIIA with the 5 S RNA gene. The DNase I footprints obtained with full-length TFIIIA and a polypeptide containing the amino-terminal five zinc fingers (TF5) were indistinguishable, extending from nucleotides +64 to +99 of the 5 S RNA gene. This suggests that fingers 6 through 9 of yeast TFIIIA are not in tight association with DNA. The DNase I footprint obtained with a polypeptide containing the amino-terminal four zinc fingers (TF4) was 14 base pairs shorter than that of TF5, extending from nucleotides +78 to +99 on the nontranscribed strand and from nucleotides +79 to +98 on the transcribed strand of the 5 S RNA gene. Protection provided by a polypeptide containing the first three zinc fingers (TF3) was similar to that provided by TF4, with the exception that protection on the nontranscribed strand ended at nucleotide +80, rather than nucleotide +78. Methylation protection analysis indicated that finger 5 makes major groove contacts with guanines +73 and +74. The amino-terminal four zinc fingers make contacts that span the internal control region, which extends from nucleotides +81 to +94 of the 5 S RNA gene, with finger 4 appearing to contact guanine +82. Measurements of the apparent Kd values of the TFIIIA.DNA complexes indicated that the amino-terminal three zinc fingers of TFIIIA have a binding energy that is similar to that of the full-length protein.

Topography of transcription factor complexes on the Saccharomyces cerevisiae 5 S RNA gene

Locations of component proteins of yeast RNA polymerase III transcription factors (TFIII) A, C and B on a 5 S rRNA gene have been determined by site-specific DNA-protein photo-crosslinking. Comparison with a previously analyzed tRNA gene shows that similar nucleoprotein structures assemble on these two genes despite their differently located internal promoter elements. A principal signature of this homology is the placement of the 95 kDA subunit of TFIIIC, which associates with the box A promoter element of the tRNA gene. On the 5 S rRNA gene, the 95 kDa subunit occupies the same space in the absence of a box A sequence, and despite the presence of a box A-like sequence 30 base-pairs further downstream. A 90 kDa component that was not previously recognized as an integral part of TFIIIC has been specifically located at the 3' end of the 5 S rRNA gene.

Sequence and organization of 5S RNA genes from the eukaryotic protist Acanthamoeba castellanii

A 5S RNA genomic clone has been isolated from Acanthamoeba castellanii and the sequence of the coding region plus flanking DNA was determined. This clone encodes an RNA whose sequence matches that of 5S RNA from this organism. There is sequence similarity in the 5'-flanking region to other eukaryotic 5S RNA genes which require or are greatly affected by upstream regions for transcriptional activity. The immediate 3'-flanking region has a termination sequence similar to that found in all genes that are transcribed by RNA polymerase III. The 5S RNA genes of A. castellanii are dispersed, which is highly unusual, since the majority of eukaryotic organisms contain 5S genes clustered in tandem repeats. There may be up to 480 genes encoding 5S RNA in each A. castellanii cell.

S. cerevisiae TFIIIB is the transcription initiation factor proper of RNA polymerase III, while TFIIIA and TFIIIC are assembly factors

The S. cerevisiae RNA polymerase III (pol III) transcription factor TFIIIB binds to DNA upstream of the transcription start site of the SUP4 tRNA(Tyr) gene in a TFIIIC-dependent reaction and to the major 5S rRNA gene in a reaction requiring TFIIIC and TFIIIA. It is shown here that TFIIIB alone correctly positions pol III for repeated cycles of transcription on both genes, with the same efficiency as fully assembled transcription complexes. Thus, TFIIIB is the sole transcription initiation factor of S. cerevisiae pol III; TFIIIC and TFIIIA are assembly factors for TFIIIB. The TFIIIB-dependent binding of pol III to the SUP4 tRNA and 5S rRNA genes has been analyzed in binary (protein and DNA only) and precisely arrested ternary (protein, DNA, and RNA) transcription complexes. Pol III unwinds at least 14 bp of DNA at the SUP4 transcription start in a temperature-dependent process. The unwound DNA segment moves downstream with nascent RNA as a transcription bubble of approximately the same size.

Aspergillus nidulans 5S rRNA genes and pseudogenes

The sequence of four Aspergillus nidulans 5S rRNA genes and of two pseudogenes has been determined. A conserved sequence about 100 bp upstream of the 5S rRNA coding sequences has been found in three genes and one pseudogene. The two pseudogenes correspond to the 5' half of the 5S rRNA coding sequence and their 3' flanking sequences which are not homologous to 5S rRNA are strongly conserved.