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Query: EC:6.5.1.2 (
DNA ligase
)
2,749
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The Escherichia coli rho 026 mutation that alters the transcription termination protein
Rho
prevents growth of wild-type bacteriophage T4. Among the consequences of this mutation are delayed and reduced T4 DNA replication. We show that these defects can be explained by defective synthesis of certain T4 replication-recombination proteins. Expression of T4 gene 41 (DNA helicase/primase) is drastically reduced, and expression of T4 genes 43 (DNA polymerase), 30 (
DNA ligase
), 46 (recombination nuclease), and probably 44 (DNA polymerase-associated ATPase) is reduced to a lesser extent. The compensating T4 mutation goF1 partially restores the synthesis of these proteins and, concomitantly, the synthesis of T4 DNA in the E. coli rho mutant. From analyzing DNA synthesis in wild-type and various multiply mutant T4 strains, we infer that defective or reduced synthesis of these proteins in rho 026-infected cells has several major effects on DNA replication. It impairs lagging-strand synthesis during the primary mode of DNA replication; it delays and depresses recombination-dependent (secondary mode) initiation; and it inhibits the use of tertiary origins. All three T4 genes whose expression is reduced in rho 026 cells and whose upstream sequences are known have a palindrome containing a CUUCGG sequence between the promoter(s) and ribosome-binding site. We speculate that these palindromes might be important for factor-dependent transcription termination-antitermination during normal T4 development. Our results are consistent with previous proposals that the altered
Rho
factor of rho 026 may cause excessive termination because the transcription complex does not interact normally with a T4 antiterminator encoded by the wild-type goF gene and that the T4 goF1 mutation restores this interaction.
...
PMID:Impaired expression of certain prereplicative bacteriophage T4 genes explains impaired T4 DNA synthesis in Escherichia coli rho (nusD) mutants. 254 60
Homologs of the eukaryotic DNA-end-binding protein Ku were identified in several bacterial and one archeal genome using iterative database searches with sequence profiles. Identification of prokaryotic Ku homologs allowed the dissection of the Ku protein sequences into three distinct domains, the Ku core that is conserved in eukaryotes and prokaryotes, a derived von Willebrand A domain that is fused to the amino terminus of the core in eukaryotic Ku proteins, and the newly recognized helix-extension-helix (HEH) domain that is fused to the carboxyl terminus of the core in eukaryotes and in one of the Ku homologs from the Actinomycete Streptomyces coelicolor. The version of the HEH domain present in eukaryotic Ku proteins represents the previously described DNA-binding domain called SAP. The Ku homolog from S. coelicolor contains a distinct version of the HEH domain that belongs to a previously unnoticed family of nucleic-acid-binding domains, which also includes HEH domains from the bacterial transcription termination factor
Rho
, bacterial and eukaryotic lysyl-tRNA synthetases, bacteriophage T4 endonuclease VII, and several uncharacterized proteins. The distribution of the Ku homologs in bacteria coincides with that of the archeal-eukaryotic-type DNA primase and genes for prokaryotic Ku homologs form predicted operons with genes coding for an ATP-dependent
DNA ligase
and/or archeal-eukaryotic-type DNA primase. Some of these operons additionally encode an uncharacterized protein that may function as nuclease or an Slx1p-like predicted nuclease containing a URI domain. A hypothesis is proposed that the Ku homolog, together with the associated gene products, comprise a previously unrecognized prokaryotic system for repair of double-strand breaks in DNA.
...
PMID:Prokaryotic homologs of the eukaryotic DNA-end-binding protein Ku, novel domains in the Ku protein and prediction of a prokaryotic double-strand break repair system. 1148 77
