Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
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Drug
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Target Concepts:
Gene/Protein
Disease
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Query: UNIPROT:Q9UIJ5 (
Rec
)
58,342
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
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
Few diseases exemplify the integration of research from bench to bedside as well as neonatal lupus, often described as a model of passively acquired autoimmunity. The signature histologic lesion of autoimmune congenital heart block (CHB) is fibrosis of the conducting tissue and, in some cases, the surrounding myocardium. Although anti-SSA/Ro-
SSB
/La antibodies are detected in > 85% of mothers whose fetuses are identified with conduction abnormalities in a structurally normal heart, the risk for a woman with the candidate antibodies to have a child with CHB is 2%. The mechanism by which maternal anti-SSA/Ro-
SSB
/La antibodies initiate and finally eventuate in atrioventricular nodal scarring is not yet defined, but it is clear that the antibodies alone are insufficient to cause disease and fetal factors are likely contributory. Previous in vitro and in vivo studies suggest that the pathologic cascade is initiated via apoptosis, resulting in translocation of SSA/Ro-
SSB
/La antigens to the cell surface where they are bound by maternal autoantibodies. Subsequently, the Fc portion of the bound immunoglobulin engages Fcgamma receptors on tissue macrophages, resulting in release of TGF-beta at a threshold favoring a profibrotic milieu and irreversible scarring. This cascade also involves tissue-specific activation of TGF-beta, which promotes the modulation of fibroblasts into myofibroblasts, a scarring phenotype. Recent findings point to genetic polymorphisms that promote high production of TGF-beta as possible fetal risk factors for CHB. Further elucidation of maternal and fetal contributory factors should provide insight into the pathogenesis of CHB and the rarity of irreversible injury.
Anat
Rec
A Discov Mol Cell Evol Biol 2004 Oct
PMID:Autoimmune-associated congenital heart block: dissecting the cascade from immunologic insult to relentless fibrosis. 1536 47
The RecA protein is a major enzyme of homologous recombination in bacterial cell. Forming a right-handed helical filament on ssDNA, it provides a homology search between two DNA molecules and homologous strand exchange. The RecA protein not only defends the cell from exposure to ionizing radiation and UV-irradiation, but also ensures the recombination process in the course of normal cell growth. A number of wild-type or mutant RecA proteins demonstrate increased recombinogenic properties in vitro and in vivo as compared with the wild-type RecA protein from Escherichia coli, which leads to hyper-recombination. The hyper-
rec
activity of RecA proteins during the recombination process in many depends on the filamentation dynamics on ssDNA and DNA-transferase properties. Changes in filamentation and DNA-transferase abilities of RecA protein may be the result of not only specific amino-acid substitutions, but also the functioning of the cell enzymatic apparatus, including such proteins as RecO, RecR, RecF, RecX, DinI,
SSB
, PsiB. To date, the function of each of these proteins is identified at the molecular level. However, the role of some of them in the cell metabolism remains to be seen. Increase in recombination in vivo is not always useful for a cell and faces various limitations. Moreover, in the bacterial cell some mechanisms are activated, that cause genomic reorganization, directed to suppress the expression of hyper-active RecA protein. The ways of hyper-active RecA protein regulation are very interesting, and they are studied in different model systems.
...
PMID:[Enzymatic control of homologous recombination in Escherichia coli cells and hyper-recombination]. 2380 53
The ability to restart broken DNA replication forks is essential across all domains of life. In
Escherichia coli
, the
priA
,
priB
,
priC
, and
dnaT
genes encode the replication restart proteins (RRPs) to accomplish this task. PriA plays a critical role in replication restart such that its absence reveals a dramatic phenotype: poor growth, high basal levels of SOS expression, poorly partitioned nucleoids (Par
-
), UV sensitivity, and recombination deficiency (
Rec
-
). PriA has 733 amino acids, and its structure is composed of six domains that enable it to bind to DNA replication fork-like structures, remodel the strands of DNA, interact with
SSB
(single-stranded DNA binding protein), PriB, and DnaT, and display ATPase, helicase, and translocase activities. We have characterized a new
priA
mutation called
priA316
::
cat
It is a composite mutation involving an insertion that truncates the protein within the winged-helix domain (at the 154th codon) and an ACG (Thr)-to-ATG (Met) mutation that allows reinitiation of translation at the 157th codon such that PriA is expressed in two pieces.
priA316
::
cat
phenotypes are like those of the wild type for growth, recombination, and UV resistance, revealing only a slightly increased level of SOS expression and defects in nucleoid partitioning in the mutant. Both parts of PriA are required for activity, and the N-terminal fragment can be optimized to yield wild-type activity. A deletion of the
lon
protease suppresses
priA316
::
cat
phenotypes. We hypothesize the two parts of PriA form a complex that supplies most of the PriA activity needed in the cell.
IMPORTANCE
PriA is a highly conserved multifunctional protein that plays a crucial role in the essential process of replication restart. Here we characterize an insertion mutation of
priA
with an intragenic suppressor such that it is now made in two parts. These two pieces split the winged-helix domain to separate the N-terminal 3' DNA-binding domain from the C-terminal domain of PriA. It is hypothesized that the two pieces form a complex that is capable of almost wild type
priA
function. The composite mutation leads to a moderate level of SOS expression and defects in partitioning of the chromosomes. Full function is restored by deletion of
lon
, suggesting that stability of this complex may be a reason for the partial phenotypes seen.
...
PMID:A
priA
Mutant Expressed in Two Pieces Has Almost Full Activity in Escherichia coli K-12. 2860 60
