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Target Concepts:
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Query: UNIPROT:Q9UIJ5 (
Rec
)
58,342
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The bacteriophage T4 dda protein is a 5'-3'
DNA helicase
that stimulates DNA replication and recombination reactions in vitro and seems to play a role in the initiation of T4 DNA replication in vivo. Oligonucleotide probes based on NH2-terminal amino acid sequence were used to precisely map the location of the dda gene on the T4 chromosome. Using polymerase chain reaction techniques, the dda gene was then cloned into an expression vector, and the overproduced protein was purified in two chromatography steps. Both the genomic and cloned dda genes were sequenced and found to be identical, encoding a protein of 439 amino acids. The dda protein contains amino acid sequences resembling those of other known helicases, and is most homologous to the Escherichia coli recD protein. Protein affinity chromatography was used to show a direct interaction between the dda protein and the T4 uvsX protein (a
rec
A-type DNA recombinase).
...
PMID:Overexpression, purification, sequence analysis, and characterization of the T4 bacteriophage dda DNA helicase. 132 8
The protein-mediated exchange of strands between a DNA double helix and a homologous DNA single strand involves both synapsis and branch migration, which are two important aspects of any general recombination reaction. Purified DNA-dependent ATPases from Escherichia coli (recA protein), Ustilago (
rec
1 protein) and phage T4 (uvsX protein) have been shown to drive both synapsis and branch migration in vitro. The T4 gene 32 protein is a helix-destabilizing protein that greatly stimulates uvsX-protein-catalysed synapsis, and the E. coli SSB (single-strand binding) protein stimulates the analogous recA-protein-mediated reaction to a lesser degree. One suspects that several other proteins also play a role in the strand exchange process. For example, a
DNA helicase
could in principle accelerate branch migration rates by helping to melt the helix at the branch point. The T4 dda protein is a
DNA helicase
that is required to move the T4 replication fork past DNA template-bound proteins in vitro. Previously, we have shown that the dda protein binds to a column that contains immobilized T4 uvsX protein. We show here that this helicase specifically stimulates the branch migration reaction that the uvsX protein catalyses as a central part of the genetic recombination process in a T4 bacteriophage-infected cell.
...
PMID:Stimulation of protein-directed strand exchange by a DNA helicase. 295 Mar 27
A 713-base-pair Hae III fragment from bacteriophage T4 encompassing the denV gene with its preceding promoter has been cloned in a pBR322-derived positive-selection vector and introduced into a variety of DNA repair-deficient uvr and
rec
and uvr,
rec
Escherichia coli strains. The denV gene was found to be expressed, probably from its own promoter, causing pyrimidine dimer incision-deficient uvrA, uvrB, uvrC strains to be rescued by the denV gene. A uvrD (
DNA helicase
II) strain was also complemented, but to a lesser extent. A wild-type strain did not seem to be affected at the UV doses tested. Surprisingly, all recA, recB, and recC strains tested also showed an increased UV resistance, perhaps by reinforcement of the intact uvr system in these strains. Complementation of denV- T4 strains and host-cell reactivation of lambda phage was also observed in denV+ E. coli strains. Equilibrium sedimentation showed that DNA repair synthesis occurred in a UV-irradiated uvrA E. coli strain carrying the cloned denV gene. Southern blotting confirmed our earlier results [Valerie, K., Henderson, E. E. & de Riel, J. K. (1984) Nucleic Acids Res. 12, 8085-8096] that the denV gene is located at 64 kilobases on the T4 map. Phage T2 (denV-) did not hybridize to a denV-specific probe.
...
PMID:Expression of a cloned denV gene of bacteriophage T4 in Escherichia coli. 299 91
We are investigating the mechanisms for deletion formation through the use of mutants which alter deletion frequency together with well characterized systems for deletion detection. We report here on three mutations which were isolated for their ability to stimulate deletions in plasmid pMC874 (dli mutations). The mutation
rec
-2251 (formerly known as dli1) is a new allele of recBCD, a group of genes coding for the polypeptide components of the major recombination enzyme complex in E. coli; the second one, dli2 may be a new allele of uvrD, which codes for
DNA helicase
II; and the third one, dli3, has the phenotype of a mismatch repair mutation. Here we compare the effects of mutations in SOS-repair genes to those of the dli mutations on three different deletion events: (a) the deletion of short (60-100-bp) palindromic and non-palindromic inserts in derivatives of plasmid pBR325; (b) larger (600-800-bp) deletions in plasmid pMC874; and (c) the excision of the Tn10 transposon from chromosomal sites. Our results indicate that some form of SOS processing stimulates the loss of palindromes but not non-palindromes in plasmid pBR325 derivatives, and that RecA is necessary for UV-induced excision of Tn10 but this event is inhibited by UmuCD or its homolog MucAB. Each of the dli mutations showed unique effects on different classes of deletions. Mutation
rec
-2251 stimulated specifically deletions in pMC874 but had no effect on the deletion of non-palindromes in pBR325, and reduced the incidence of the other deletion events tested including loss of palindromic inserts in pBR325 as well as Tn10 excision. Mutation dli2, on the other hand, stimulated all deletions tested to varying extents, while dli3 did not affect markedly deletion formation in pBR325 plasmids but had a large stimulatory effect on both deletions in plasmid pMC874 and Tn10 excision. These results reveal that (a) some SOS-repair functions participate in deletion formation, (b) mutations selected for altering the incidence of one class of deletions may have totally different effects on other deletion events, and (c) the differences in mutant behavior may result in part from the ability of some pathways to discriminate among different deletion intermediates such as hairpins or cruciforms formed by palindromic sequences vs. transient secondary structures stabilized by direct repeats flanking non-palindromic sequences.
...
PMID:Multiple pathways of deletion formation in Escherichia coli. 768 87
The acidic carboxy-terminal 89-amino acid fragment of bacteriophage T4 gene 32 protein was expressed in Escherichia coli to high levels from an inducible plasmid construct. Infection of induced cells by wild-type T4 phage results in impaired phage DNA synthesis. The time at which DNA synthesis begins and the diminution in DNA synthesis rates correlate with the amount of carboxy-terminal peptide that accumulates intracellularly prior to infection. Correspondingly, when induced cells are infected with viable phage containing a small deletion near the carboxy-terminus of 32 protein (delta PR201), the inhibition of phage DNA synthesis was much more severe. The mutant 32 protein competes less well against overproduced wild-type acid peptide than does wild-type 32 protein. The purified acid peptide, when used as the attached ligand for affinity chromatography, binds several T4 proteins from phage-infected cells, including 43 protein (T4 DNA polymerase), Dda protein (a
DNA helicase
), and UvsX protein (a
Rec
-like recombination protein). Furthermore, at 50- to 100-fold molar excess of acid peptide over intact 32 protein, phage DNA synthesis was specifically inhibited at the initiation step in an in vitro 5-protein DNA replication experiment. We propose that one or more phage replication proteins are titrated as non-productive protein-protein complexes at a site away from the DNA template. This implies that the carboxy-terminal domain of 32 protein is involved in an obligate step of replication machine assembly when the protein is properly attached to ssDNA in the vicinity of a primer-template junction. The assembly defect we observe is strikingly similar to the repression, or "squelching", of the activity of certain eukaryotic transcriptional activators.
...
PMID:Assembly of the bacteriophage T4 replication machine requires the acidic carboxy terminus of gene 32 protein. 842 54
The Saccharomyces cerevisae RAD3 gene is the homolog of human XPD, an essential gene encoding a
DNA helicase
of the TFIIH complex involved in both nucleotide excision repair (NER) and transcription. Some mutant alleles of RAD3 (rad3-101 and rad3-102) have partial defects in DNA repair and a strong hyper-recombination (hyper-Rec) phenotype. Previous studies showed that the hyper-
Rec
phenotype associated with rad3-101 and rad3-102 can be explained as a consequence of persistent single-stranded DNA gaps that are converted to recombinogenic double-strand breaks (DSBs) by replication. The systems previously used to characterize the hyper-
Rec
phenotype of rad3 strains do not detect the reciprocal products of mitotic recombination. We have further characterized these events using a system in which the reciprocal products of mitotic recombination are recovered. Both rad3-101 and rad3-102 elevate the frequency of reciprocal crossovers about 100-fold. Mapping of these events shows that three-quarters of these crossovers reflect DSBs formed at the same positions in both sister chromatids (double sister-chromatid breaks, DSCBs). The remainder reflects DSBs formed in single chromatids (single chromatid breaks, SCBs). The ratio of DSCBs to SCBs is similar to that observed for spontaneous recombination events in wild-type cells. We mapped 216 unselected genomic alterations throughout the genome including crossovers, gene conversions, deletions, and duplications. We found a significant association between the location of these recombination events and regions with elevated gamma-H2AX. In addition, there was a hotspot for deletions and duplications at the IMA2 and HXT11 genes near the left end of chromosome XV. A comparison of these data with our previous analysis of spontaneous mitotic recombination events suggests that a sub-set of spontaneous events in wild-type cells may be initiated by incomplete NER reactions, and that DSCBs, which cannot be repaired by sister-chromatid recombination, are a major source of mitotic recombination between homologous chromosomes.
...
PMID:High-Resolution Mapping of Homologous Recombination Events in rad3 Hyper-Recombination Mutants in Yeast. 2696 37
