Identification of two factors which bind to the upstream sequences of a number of nuclear genes coding for mitochondrial proteins and to genetic elements important for cell division in yeast.

Two abundant factors, GFI and GFII which interact with the 5' flanking regions of nuclear genes coding for proteins of the mitochondrial respiratory chain have been identified. In one case (subunit VIII of QH2: cytochrome c oxidoreductase) the binding sites for both factors overlap completely and their binding is mutually exclusive. For the other 5' regions tested the GFI and GFII binding sites do not coincide. Interestingly, binding sites for GFI and GFII are also present in or at the 3' ends of the coding regions of two genes of the PHO gene family and in DNA elements important for optimal ARS and CEN function respectively. The sites recognized by GFI conform to the consensus RTCRNNNNNNACGNR, while those recognized by GFII contain the element RTCACGTG. We speculate that GFI and GFII may play a role in different cellular processes, dependent on the context of their binding sites and that one of these processes may be the coordination of the expression of genes involved in mitochondrial biogenesis with the progress of the cell cycle.     

Yeast general transcription factor GFI: sequence requirements for binding to DNA and evolutionary conservation

GFI is an abundant DNA binding protein in the yeast S. cerevisiae. The protein binds to specific sequences in both ARS elements and the upstream regions of a large number of genes and is likely to play an important role in yeast cell growth. To get insight into the relative strength of the various GFI-DNA binding sites within the yeast genome, we have determined dissociation rates for several GFI-DNA complexes and found them to vary over a 70-fold range. Strong binding sites for GFI are present in the upstream activating sequences of the gene encoding the 40 kDa subunit II of the QH2:cytochrome c reductase, the gene encoding ribosomal protein S33 and in the intron of the actin gene. The binding site in the ARS1-TRP1 region is of intermediate strength. All strong binding sites conform to the sequence 5' RTCRYYYNNNACG-3'. Modification interference experiments and studies with mutant binding sites indicate that critical bases for GFI recognition are within the two elements of the consensus DNA recognition sequence. Proteins with the DNA binding specificities of GFI and GFII can also be detected in the yeast K. lactis, suggesting evolutionary conservation of at least the respective DNA-binding domains in both yeasts.     

Two novel Drosophila TAF(II)s have homology with human TAF(II)30 and are differentially regulated during development

TFIID is a multiprotein complex composed of the TATA binding protein (TBP) and TBP-associated factors (TAF(II)s). The binding of TFIID to the promoter is the first step of RNA polymerase II preinitiation complex assembly on protein-coding genes. Yeast (y) and human (h) TFIID complexes contain 10 to 13 TAF(II)s. Biochemical studies suggested that the Drosophila (d) TFIID complexes contain only eight TAF(II)s, leaving a number of yeast and human TAF(II)s (e.g., hTAF(II)55, hTAF(II)30, and hTAF(II)18) without known Drosophila homologues. We demonstrate that Drosophila has not one but two hTAF(II)30 homologues, dTAF(II)16 and dTAF(II)24, which are encoded by two adjacent genes. These two genes are localized in a head-to-head orientation, and their 5' extremities overlap. We show that these novel dTAF(II)s are expressed and that they are both associated with TBP and other bona fide dTAF(II)s in dTFIID complexes. dTAF(II)24, but not dTAF(II)16, was also found to be associated with the histone acetyltransferase (HAT) dGCN5. Thus, dTAF(II)16 and dTAF(II)24 are functional homologues of hTAF(II)30, and this is the first demonstration that a TAF(II)-GCN5-HAT complex exists in Drosophila. The two dTAF(II)s are differentially expressed during embryogenesis and can be detected in both nuclei and cytoplasm of the cells. These results together indicate that dTAF(II)16 and dTAF(II)24 may have similar but not identical functions.     

Interchangeability and distinct properties of bacterial Fe-S cluster assembly systems: functional replacement of the isc and suf operons in Escherichia coli with the nifSU-like operon from Helicobacter pylori

The assembly of iron-sulfur (Fe-S) clusters, a key step in the post-translational maturation of Fe-S proteins, is mediated by a complex apparatus. In E. coli, this process involves two independent systems called ISC and SUF encoded by the iscSUA-hscBA-fdx gene cluster and sufABCDSE operon, respectively. Another system, termed NIF (nifSU), is required for the maturation of nitrogenase in nitrogen-fixing bacteria. We have developed a novel genetic system to gain further insight into these multi-component systems, and to determine how ISC, SUF and NIF might differ in their roles in Fe-S assembly. We have constructed an E. coli mutant lacking both the isc and suf operons, and this strain can only survive in the presence of a complementing plasmid. Using the plasmid replacement technique, we examined the isc and suf operons, and identified the genes essential for the function. Additionally, we have found that nifSU-like genes cloned from Helicobacter pylori are functionally exchangeable with the isc and suf operons. Thus, the NIF-like system participates in the maturation of a wide variety of Fe-S proteins. An increased ability of NIF to complement isc and suf loss was seen under anaerobic conditions. This may explain why the NIF system is only found in a limited number of bacterial species, and most other organisms prefer the ISC and/or SUF systems. While the differences between ISC and SUF were small with respect to the complementing activity, the SUF system appears to be more advantageous for bacterial growth in the presence of hydrogen peroxide.