Saccharomyces cerevisiae RAD5-encoded DNA repair protein contains DNA helicase and zinc-binding sequence motifs and affects the stability of simple repetitive sequences in the genome.

rad5 (rev2) mutants of Saccharomyces cerevisiae are sensitive to UV light and other DNA-damaging agents, and RAD5 is in the RAD6 epistasis group of DNA repair genes. To unambiguously define the function of RAD5, we have cloned the RAD5 gene, determined the effects of the rad5 deletion mutation on DNA repair, DNA damage-induced mutagenesis, and other cellular processes, and analyzed the sequence of RAD5-encoded protein. Our genetic studies indicate that RAD5 functions primarily with RAD18 in error-free postreplication repair. We also show that RAD5 affects the rate of instability of poly(GT) repeat sequences. Genomic poly(GT) sequences normally change length at a rate of about 10(-4); this rate is approximately 10-fold lower in the rad5 deletion mutant than in the corresponding isogenic wild-type strain. RAD5 encodes a protein of 1,169 amino acids of M(r) 134,000, and it contains several interesting sequence motifs. All seven conserved domains found associated with DNA helicases are present in RAD5. RAD5 also contains a cysteine-rich sequence motif that resembles the corresponding sequences found in 11 other proteins, including those encoded by the DNA repair gene RAD18 and the RAG1 gene required for immunoglobin gene arrangement. A leucine zipper motif preceded by a basic region is also present in RAD5. The cysteine-rich region may coordinate the binding of zinc; this region and the basic segment might constitute distinct DNA-binding domains in RAD5. Possible roles of RAD5 putative ATPase/DNA helicase activity in DNA repair and in the maintenance of wild-type rates of instability of simple repetitive sequences are discussed.     

Analysis of the essential and excision repair functions of the RAD3 gene of Saccharomyces cerevisiae by mutagenesis.

The RAD3 gene of Saccharomyces cerevisiae, which is involved in excision repair of DNA and is essential for cell viability, was mutagenized by site-specific and random mutagenesis. Site-specific mutagenesis was targeted to two regions near the 5' and 3' ends of the coding region, selected on the basis of amino acid sequence homology with known nucleotide binding and with known specific DNA-binding proteins, respectively. Two mutations in the putative nucleotide-binding region and one in the putative DNA-binding region inactivate the excision repair function of the gene, but not the essential function. A gene encoding two tandem mutations in the putative DNA-binding region is defective in both excision repair and essential functions of RAD3. Seven plasmids were isolated following random mutagenesis with hydroxylamine. Mutations in six of these plasmids were identified by gap repair of mutant plasmids from the chromosome of strains with previously mapped rad3 mutations, followed by DNA sequencing. Three of these contain missense mutations which inactivate only the excision repair function. The other three carry nonsense mutations which inactivate both the excision repair and essential functions. Collectively our results indicate that the RAD3 excision repair function is more sensitive to inactivation than is the essential function. Overexpression of wild-type Rad3 protein and a number of rad3 mutant proteins did not affect the UV resistance of wild-type yeast cells. However, overexpression of Rad3-2 protein rendered wild-type cells partially UV sensitive, indicating that excess Rad3-2 protein is dominant to the wild-type form. These and other results suggest that Rad3-2 protein retains its affinity for damaged DNA or other substrates, but is not catalytically active in excision repair.     

Cloning and sequencing of an Escherichia coli gene, nlp, highly homologous to the ner genes of bacteriophages Mu and D108.

An nlp (Ner-like protein) gene was isolated from Escherichia coli. The nucleotide sequence of a 1,342-base-pair chromosomal DNA fragment containing the nlp gene was analyzed. It contained two open reading frames; one encoded 91 amino acid residues with an Mr of 10,361, and the other (ORFX) encoded 131 amino acid residues of the carboxyl-terminal region of a truncated polypeptide. The amino acid sequence deduced from the DNA sequence of nlp was highly homologous (62 to 63%) to the Ner proteins of bacteriophages Mu and D108. The amino-terminal region of Nlp deduced from the complete open reading frame contained a presumed DNA-binding region. The nlp gene was located at 69.3 min on the E. coli genetic map.     

Identification of a novel DNA-binding protein to osmotin promoter

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Structural and functional organization of a porcine gene coding for nuclear factor I

This paper describes the structure of a 70-kb porcine gene for nuclear factor I, including its promoter region, comprising a total of 11 exons. Different mRNAs that we have isolated as cDNAs from both porcine liver and human HeLa cells presumably are generated from this gene by differential splicing events. One cDNA species from porcine liver that lacks exon 9 carries coding information for a protein of 439 amino acids. The in vitro translated protein displays all the properties of an NFI-like protein with high affinity toward the sequence element TGG(N)6GCCAA, as shown by gel shift analysis, and no or little affinity toward CCAAT box containing sequences. Cotranslation experiments with full-length and truncated variants of the protein demonstrate that it binds as a dimer to its cognate DNA recognition sequence. Its DNA-binding domain which is retained in all cDNA clones was mapped by deletion analysis to the 250 N-terminal amino acids of the protein. No structural homologies are observed between this protein and other known DNA-binding proteins; instead, the protein contains a novel alpha-helical sequence motif consisting of several lysine residues spaced at intervals of seven amino acids which we have termed the "lysine helix". The C-terminal portion of the protein derived from full-length cDNAs encodes a short amino acid sequence which is identical with the heptapeptide repeat CT7 observed in the C-terminal domain of the largest subunits of yeast and mouse RNA polymerase II. This region is removed by differential splicing in some of the NFI/CTF cDNAs and thus may be of functional significance.     

High Resolution Structural Studies of Cro Repressor Protein and Implications for DNA Recognition

Abstract

Cro repressor is a small dimeric protein that binds to specific sites on the DNA of bacteriophage λ. The structure of Cro has been determined and suggests that the protein binds to its sequence-specific sites with a pair of two-fold related α-helices of the protein located within successive major grooves of the DNA.

From the known three-dimensional structure of the repressor, model building and energy refinement have been used to develop a detailed model for the presumed complex between Cro and DNA. Recognition of specific DNA binding sites appears to occur via multiple hydrogen bonds between amino acid side chains of the protein and base pair atoms exposed within the major groove of DNA. The Cro:DNA model is consistent with the calculated electrostatic potential energy surface of the protein.

From a series of amino acid sequence and gene sequence comparisons, it appears that a number of other DNA-binding proteins have an α-helical DNA-binding region similar to that seen in Cro. The apparent sequence homology includes not only DNA-binding proteins from different bacteriophages, but also gene-regulatory proteins from bacteria and yeast. It has also been found that the conformations of part of the presumed DNA-binding regions of Cro repressor, λ repressor and CAP gene activator proteins are strikingly similar. Taken together, these results strongly suggest that a two-helical structural unit occurs in the DNA-binding region of many proteins that regulate gene expression. However, the results to date do not suggest that there is a simple one-to-one recognition code between amino acids and bases.

Crystals have been obtained of complexes of Cro with six-base-pair and nine-basepair DNA oligomers, and X-ray analysis of these co-crystals is in progress.     

Evolution and mutagenesis of the mammalian excision repair gene ERCC-1.

The human DNA excision repair protein ERCC-1 exhibits homology to the yeast RAD10 repair protein and its longer C-terminus displays similarity to parts of the E. coli repair proteins uvrA and uvrC. To study the evolution of this 'mosaic' ERCC-1 gene we have isolated the mouse homologue. Mouse ERCC-1 harbors the same pattern of homology with RAD10 and has a comparable C-terminal extension as its human equivalent. Mutation studies show that the strongly conserved C-terminus is essential in contrast to the less conserved N-terminus which is even dispensible. The mouse ERCC-1 amino acid sequence is compatible with a previously postulated nuclear location signal and DNA-binding domain. The ERCC-1 promoter harbors a region which is highly conserved in mouse and man. Since the ERCC-1 promoter is devoid of all classical promoter elements this region may be responsible for the low constitutive level of expression in all mouse tissues and stages of embryogenesis examined.     

Assembly of the mitochondrial membrane system. Sequence of the oxi 2 gene of yeast mitochondrial DNA

The region of mitochondrial DNA (mtDNA) containing the oxi 2 locus has been sequenced in a rho- clone (DS40) derived from the respiratory competent strain D273-10B/A48 of Saccharomyces cerevisiae. The DS40 clone was established to have retained only genetic markers in the oxi 2 locus and to have a segment of mtDNA extending from 18.6 to 24.3 units of the wild type map. The mitochondrial genome of DS40 includes a sequence that has been tentatively identified as the structural gene of Subunit 3 of cytochrome oxidase. The coding sequence is 810 nucleotides long and generates a protein with a molecular weight of 30,340. The amino acid composition of the oxi 2 gene product deduced from the nucleotide sequence is in agreement with the composition of the purified Subunit 3 of yeast cytochrome oxidase. The orientation of the DS40 mtDNA segment relative to wild type mtDNA indicates that the oxi 2 gene is transcribed from the same DNA strand as the oxi 1 and several other mitochondrial genes.     

Evaluation and mapping of the DNA binding and oligomerization domains of the IE2 regulatory protein of human cytomegalovirus using yeast one and two hybrid interaction assays

The 86-kDa IE2 nuclear phosphoprotein encoded by the human cytomegalovirus (HCMV) major immediate-early (MIE) gene behaves as both a non-specific transactivator of viral and cellular gene expression and as a specific DNA-binding protein targeted to the cis-repression sequence (CRS) at the cap site of its own promoter/enhancer region. Although the IE2 protein produced in bacteria has been shown to bind to the 14-bp palindromic CRS motif and IE2 synthesized in vitro forms stable dimers in solution through the conserved C-terminus of the protein, there is no direct evidence as yet that the intracellular mammalian forms of IE2 do so. Here, we show that the intact HCMV IE2 protein both binds to CRS DNA and dimerizes in yeast cells. In a one-hybrid assay system, a GAL4/IE2 fusion protein expressed in yeast cells activated target HIS3 expression only when CRS sites were located upstream of the GAL1 minimal promoter, but failed to do so on mutant CRS sites, demonstrating a requirement for sequence-specific DNA-binding by IE2. Examination of a series of deletion and triple amino acid point mutations in the C-terminal half of IE2 mapped the domains required for DNA-binding in yeast to the entire region between codons 313 and 579, whereas in the previous in vitro study with truncated bacterial GST fusion proteins, it was mapped to between codons 346 and 579. Transient co-transfection assays with deleted IE2 effector genes in Vero cells showed that the extra segment of IE2 between codons 313 and 346 is also required for both autoregulation and transactivation activity in mammalian cells. In a two-hybrid assay to study IE2 self-interations, we generated both GAL4 DNA-binding (DB) and activation domain (A)/IE2 fusion proteins and showed that IE2 could also dimerize or oligomerize through the C-terminus of the protein in yeast cells. Domains required for this interaction were all mapped to within the region between codons 388 and 542, which is coincident with the domain mapped previously for dimerization by co-translation and immunoprecipitation in vitro. Comparison of the domains of the IE2 protein required for CRS binding and dimerization in yeast suggests that these activities correlate precisely with requirements for the negative autoregulation function of the IE2 protein in mammalian cells.     

Plant homologue of human excision repair gene ERCC1 points to conservation of DNA repair mechanisms

Nucleotide excision repair (NER), a highly versatile DNA repair mechanism, is capable of removing various types of DNA damage including those induced by UV radiation and chemical mutagens. NER has been well characterized in yeast and mammalian systems but its presence in plants has not been reported. Here it is reported that a plant gene isolated from male germline cells of lily (Lilium longiflorum) shows a striking amino acid sequence similarity to the DNA excision repair proteins human ERCC1 and yeast RAD10. Homologous genes are also shown to be present in a number of taxonomically diverse plant genera tested, suggesting that this gene may have a conserved function in plants. The protein encoded by this gene is able to correct significantly the sensitivity to the cross-linking agent mitomycin C in ERCC1-deficient Chinese hamster ovary (CHO) cells. These findings suggest that the NER mechanism is conserved in yeast, animals and higher plants.     

A yeast DNA repair gene partially complements defective excision repair in mammalian cells.

The RAD10 gene of Saccharomyces cerevisiae is required for nucleotide excision repair of DNA. Expression of RAD10 mRNA and Rad10 protein was demonstrated in Chinese hamster ovary (CHO) cells containing amplified copies of the gene, and RAD10 mRNA was also detected in stable transfectants without gene amplification. Following transfection with the RAD10 gene, three independently isolated excision repair-defective CHO cell lines from the same genetic complementation group (complementation group 2) showed partial complementation of sensitivity to killing by UV radiation and to the DNA cross-linking agent mitomycin C. These results were not observed when RAD10 was introduced into excision repair-defective CHO cell lines from other genetic complementation groups, nor when the yeast RAD3 gene was expressed in cells from genetic complementation group 2. Enhanced UV resistance in cells carrying the RAD10 gene was accompanied by partial reactivation of the plasmid-borne chloramphenicol acetyltransferase (cat) gene following its inactivation by UV radiation. The phenotype of CHO cells from genetic complementation group 2 is also specifically complemented by the human ERCC1 gene, and the ERCC1 and RAD10 genes have similar amino acid sequences. The present experiments therefore indicate that the structural homology between the yeast Rad10 and human Ercc1 polypeptides is reflected at a functional level, and suggest that nucleotide excision repair proteins are conserved in eukaryotes.     

Nucleotide sequence of the Salmonella typhimurium mutL gene required for mismatch repair: homology of MutL to HexB of Streptococcus pneumoniae and to PMS1 of the yeast Saccharomyces cerevisiae.

The mutL gene of Salmonella typhimurium LT2 is required for dam-dependent methyl-directed DNA mismatch repair. We have cloned and sequenced the mutL gene of S. typhimurium LT2 and compared its sequence with those of the hexB gene product of the gram-positive bacterium Streptococcus pneumoniae and the PMS1 gene product of the yeast Saccharomyces cerevisiae. MutL was found to be quite similar to the HexB mismatch repair protein of S. pneumoniae and to the mismatch repair protein PMS1 of the yeast S. cerevisiae. The significant similarities among these proteins were confined to their amino-terminal regions and suggest common evolution of the mismatch repair machinery in those organisms. The DNA sequence for mutL predicted a gene encoding a protein of 618 amino acid residues with a molecular weight of 67,761. The assignment of reading frame was confirmed by the construction of a chimeric protein consisting of the first 30 amino acids of LacZ fused to residues 53 through 618 of MutL. Interestingly, the presence of excess amounts of this fusion protein in wild-type mutL+ cells resulted in a trans-dominant effect causing the cell to exhibit a high spontaneous mutation frequency.     

Capture of extranuclear DNA at fission yeast double-strand breaks

Proper repair of DNA double-strand breaks (DSBs) is necessary for the maintenance of genomic integrity. Here, a new simple assay was used to study extrachromosomal DSB repair in Schizosaccharomyces pombe. Strikingly, DSB repair was associated with the capture of fission yeast mitochondrial DNA (mtDNA) at high frequency. Capture of mtDNA fragments required the Lig4p/Pku70p nonhomologous end-joining (NHEJ) machinery and its frequency was highly increased in fission yeast cells grown to stationary phase. The fission yeast Mre11 complex Rad32p/Rad50p/Nbs1p was also required for efficient capture of mtDNA at DSBs, supporting a role for the complex in promoting intermolecular ligation. Competition assays further revealed that microsatellite DNA from higher eukaryotes was preferentially captured at yeast DSBs. Finally, cotransformation experiments indicated that, in NHEJ-deficient cells, capture of extranuclear DNA at DSBs was observed if homologies--as short as 8 bp--were present between DNA substrate and DSB ends. Hence, whether driven by NHEJ, microhomology-mediated end-joining, or homologous recombination, DNA capture associated with DSB repair is a mutagenic process threatening genomic stability.