EC:2.7.7.6 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Target Concepts:

Query: EC:2.7.7.6 (RNA polymerase)
34,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

DNA containing the plasmid origin of bacteriophage P1 is replicated in vitro by a protein fraction prepared from uninfected Escherichia coli supplemented with purified P1 RepA protein. It has previously been shown that the reaction required the E. coli DnaA initiator protein, the DnaB helicase, DnaC protein, RNA polymerase, and DNA gyrase. I show here that three E. coli heat shock proteins, DnaJ, DnaK, and GrpE, are directly involved in P1 plasmid replication. Purified DnaJ, DnaK, and GrpE proteins were required to stimulate P1 plasmid ori DNA-dependent replication in in vitro complementation assays in which the host protein fractions were prepared from cells mutated in the corresponding gene. I have also found that the DnaJ and RepA proteins form a complex. This complex exists in crude cell extracts and can be isolated as a molecular species of about 160,000 Da containing one dimer of DnaJ protein and one dimer of RepA. The complex can also be reconstituted by mixing purified DnaJ and RepA proteins. These results imply that the DnaJ-RepA complex, DnaK, and GrpE are directly involved in P1 plasmid replication.
...
PMID:Three Escherichia coli heat shock proteins are required for P1 plasmid DNA replication: formation of an active complex between E. coli DnaJ protein and the P1 initiator protein. 218 45

The Escherichia coli DnaK heat shock protein has been identified previously as a negative regulator of E. coli heat shock gene expression. We report that two other heat shock proteins, DnaJ and GrpE, are also involved in the negative regulation of heat shock gene expression. Strains carrying defective dnaK, dnaJ, or grpE alleles have enhanced synthesis of heat shock proteins at low temperature and fail to shut off the heat shock response after shift to high temperature. These regulatory defects are due to the loss of normal control over the synthesis and stability of sigma 32, the alternate RNA polymerase sigma-factor required for heat shock gene expression. We conclude that DnaK, DnaJ, and GrpE regulate the concentration of sigma 32. We suggest that the synthesis of heat shock proteins is controlled by a homeostatic mechanism linking the function of heat shock proteins to the concentration of sigma 32.
...
PMID:DnaK, DnaJ, and GrpE heat shock proteins negatively regulate heat shock gene expression by controlling the synthesis and stability of sigma 32. 226 29

We have investigated heat-shock response in a marine bacterium Vibrio harveyi. We have found that 39 degrees C was the highest temperature at which V. harveyi was able to grow steadily. A shift from 30 degrees C to 39 degrees C caused increased synthesis of at least 10 proteins, as judged by SDS-PAGE, with molecular masses of 90, 70, 58, 41, 31, 27, 22, 15, 14.5 and 14kDa. The 70, 58, 41 and 14.5 kDa proteins were immunologically homologous to DnaK, GroEL, DnaJ and GroES heat-shock proteins of Escherichia coli, respectively. V. harveyi GroES protein had a lower molecular mass (14.5 kDa) than E. coli GroES, migrating in SDS-PAGE as 15kDa protein. We showed that a protein of approximately 43 kDa, immunologically reactive with antiserum against E. coli sigma 32 subunit (sigma 32) of RNA polymerase, was induced by heat-shock and co-purified with V. harveyi RNA polymerase. These results suggest that the 43 kDa protein is a heat-shock sigma protein of V. harveyi. Preparation containing the V. harveyi sigma 32 homologue, supplemented with core RNA polymerase of E. coli, was able to transcribe heat-shock promoters of E. coli in vitro.
...
PMID:Characterization of heat-shock response of the marine bacterium Vibrio harveyi. 747 74

In Escherichia coli individual sigma factors direct RNA polymerase (RNAP) to specific promoters. Upon heat shock induction there is a transient increase in the rate of transcription of approximately 20 heat shock genes, whose promoters are recognized by the RNAP-sigma 32 rather than the RNAP-sigma 70 holoenzyme. At least three heat shock proteins, DnaK, DnaJ and GrpE, are involved in negative modulation of the sigma 32-dependent heat shock response. Here we show, using purified enzymes, that upon heat treatment of RNAP holoenzyme the sigma 70 factor is preferentially inactivated, whereas the resulting heat-treated RNAP core is still able to initiate transcription once supplemented with sigma 32 (or fresh sigma 70). Heat-aggregated sigma 70 becomes a target for the joint action of DnaK, DnaJ and GrpE proteins, which reactivate it in an ATP-dependent reaction. The RNAP-sigma 32 holoenzyme is relatively stable at temperatures at which the RNAP-sigma 70 holoenzyme is inactivated. Furthermore, we show that formation of the RNAP-sigma 32 holoenzyme is favored over that of RNAP-sigma 70 at elevated temperatures. We propose a model of negative autoregulation of the heat shock response in which cooperative action of DnaK, DnaJ and GrpE heat shock proteins switches transcription back to constitutively expressed genes through the simultaneous reactivation of heat-aggregated sigma 70, as well as sequestration of sigma 32 away from RNAP.
...
PMID:Both ambient temperature and the DnaK chaperone machine modulate the heat shock response in Escherichia coli by regulating the switch between sigma 70 and sigma 32 factors assembled with RNA polymerase. 758 36

In Escherichia coli the heat shock response is under the positive control of the sigma 32 transcription factor. Three of the heat shock proteins, DnaK, DnaI, and GrpE, play a central role in the negative autoregulation of this response at the transcriptional level. Recently, we have shown that the DnaK and DnaJ proteins can compete with RNA polymerase for binding to the sigma 32 transcription factor in the presence of ATP, by forming a stable DnaJ-sigma 32-DnaK protein complex. Here, we report that DnaJ protein can catalytically activate DnaK's ATPase activity. In addition, DnaJ can activate DnaK to bind to sigma 32 in an ATP-dependent reaction, forming a stable sigma 32-DnaK complex. Results obtained with two DnaJ mutants, a missense and a truncated version, suggest that the N-terminal portion of DnaJ, which is conserved in all family members, is essential for this activation reaction. The activated form of DnaK binds preferentially to sigma 32 versus the bacteriophage lambda P protein substrate.
...
PMID:The DnaJ chaperone catalytically activates the DnaK chaperone to preferentially bind the sigma 32 heat shock transcriptional regulator. 760 76

We have shown previously that in amino acid-starved, relaxed (rel-) mutants of Escherichia coli replication of the lambda plasmid occurs via the lambda O-containing replication complex (RC) that was assembled prior to the onset of amino acid starvation and is inherited by one of the two daughter plasmid circles in each replication cycle. This replication is regulated neither by binding of the lambda O initiator to ori lambda, nor by the lambda Cro-mediated repression. Here we show that it is dependent on both RNA polymerase and DnaA functions, which is consistent with our recent finding that transcriptional activation of ori lambda is under the control of DnaA. In the system studied, DnaA-regulated transcriptional activation of ori lambda seems to be the only rate-limiting process. The lambda plasmid replication mediated by the inherited RC appeared to be independent of the functions of lambda P and DnaJ required in RC assembly In vitro experiments performed by others suggest that DnaJ first binds to the ori lambda-bound lambda O-lambda P-DnaB pre-primosome and subsequently lambda P complexed with DnaJ is preferentially recognized by DnaK-GrpE; chaperone-mediated rearrangement of this structure relieves DnaB helicase of lambda P inhibition. Recently we proposed that this process is directly coupled to the insertion of the pre-primosome between DNA strands transiently separated by transcription. This last-mentioned process may be required in lambda plasmid replication mediated by the inherited RC, which appeared in turn to be dependent on DnaK and GrpE functions.
...
PMID:Plasmid and host functions required for lambda plasmid replication carried out by the inherited replication complex. 777 59

The heat-shock 70 protein (Hsp70) chaperone family is very conserved and its prokaryotic homologue, the DnaK protein, is assumed to form one of the cellular systems for the prevention and restoration of heat-induced protein denaturation. By using anti-DnaK antibodies we purified the DnaK homologue heat-shock cognate protein (Hsc70) from calf thymus to apparent homogeneity. This protein was classified as an eukaryotic Hsc70, since (i) monoclonal antibodies against eukaryotic Hsc70 recognized it, (ii) its amino-terminal sequence showed strong homology to Hsp70s from eukaryotes and, (iii) it had an intrinsic weak ATPase activity that was stimulated by various peptide substrates. We show that this calf thymus Hsc70 protein protected calf thymus DNA polymerases alpha and epsilon as well as Escherichia coli DNA polymerase III and RNA polymerase from heat inactivation and could reactivate these heat-inactivated enzymes in an ATP-hydrolysis dependent manner, likely leading to the dissociation of aggregates formed during heat inactivation. In contrast to this, DnaK protein was exclusively able to protect and to reactivate the enzymes from E.coli but not from eukaryotic cells. Finally, the addition of calf thymus DnaJ co-chaperone homologue reduced the amount of Hsc70 required for reactivation at least 10-fold.
...
PMID:Calf thymus Hsc70 protein protects and reactivates prokaryotic and eukaryotic enzymes. 779 40

Steady-state- and stress-induced expression of Escherichia coli heat-shock genes is regulated at the transcriptional level through controls of concentration and activity of the positive regulator, the heat-shock promoter-specific subunit of RNA polymerase, sigma 32. Central to these controls are functions of the DnaK, DnaJ, GrpE heat-shock proteins as negative modulators that mediate degradation as well as repression of activity and, in some conditions, of synthesis of sigma 32. DnaJ has a key role in modulation since it binds sigma 32 and, jointly with DnaK and GrpE, represses its activity. Furthermore, DnaJ is capable of binding heat-damaged proteins, targeting DnaK and GrpE to these substrates, and thereby mediating DnaK-, DnaJ-, GrpE-dependent repair. It is proposed that one important signal transduction pathway that converts stress to a heat-shock response relies on the sequestering of DnaJ through binding to damaged proteins which derepresses and stabilizes sigma 32. Damage repair ameliorates the inducing signal and frees DnaJ, DnaK, GrpE to shut off the heat-shock response.
...
PMID:Regulation of the Escherichia coli heat-shock response. 790 31

In this work we show that the GroEL (Hsp60 equivalent) chaperone protein can protected purified Escherichia coli RNA polymerase (RNAP) holoenzyme from heat inactivation better than the DnaK (Hsp70 equivalent) chaperone can. In this protection reaction, the GroES protein is not essential, but its presence reduces the amount of GroEL required. GroEL and GroES can also reactivate heat-inactivated RNAP in the presence of ATP. The mutant GroEL673 protein, with or without GroES, is incapable of reactivating heat-inactivated RNAP. GroEL673 can only protect RNAP, and this protecting ability is not stimulated by GroES. The mechanism by which the DnaJ and GrpE heat shock proteins contribute to DnaK's ability to reactivate heat-inactivated RNAP GroEL673 has also been investigated. We found that the DnaJ protein substantially reduces the levels of DnaK protein needed in this reactivation assay. However, the observed lag in reactivation is diminished only in the additional presence of the GrpE protein. Hence, DnaJ and GrpE are involved in both steps of this reactivation reaction (recognition of substrate and release of chaperone from the substrate-chaperone complex) while, in the case of the GroEL-dependent reaction, GroES is involved only during the release of chaperone from the substrate-chaperone complex.
...
PMID:Both the Escherichia coli chaperone systems, GroEL/GroES and DnaK/DnaJ/GrpE, can reactivate heat-treated RNA polymerase. Different mechanisms for the same activity. 790 51

Phage P4 DNA is replicated in cell-free extracts of Escherichia coli in the presence of partially purified P4 alpha protein [Krevolin and Calendar (1985), J. Mol. Biol. 182, 507-517]. Using a modified in vitro replication assay, we have further characterized this process. Analysis by agarose gel electrophoresis and autoradiography of in vitro replicated molecules demonstrates that the system yields supercoiled monomeric DNA as the main product. Electron microscopic analysis of in vitro generated intermediates indicates that DNA synthesis initiates in vitro mainly at ori, the origin of replication used in vivo. Replication proceeds from this origin bidirectionally, resulting in theta-type molecules. In contrast to the in vivo situation, no extensive single-stranded regions were found in these intermediates. The initiation proteins of the host, DnaB and DnaG, and the chaperones DnaJ and DnaK are not required for P4 replication, because polyclonal antibodies against those polypeptides do not inhibit the process. The reaction is inhibited by antibodies against the SSB protein, and by ara-CTP, a specific inhibitor of DNA polymerase III holoenzyme. Consistent with previous reports, P4 in vitro replication is independent of transcription by host RNA polymerase. Novobiocin, a DNA gyrase inhibitor, strongly inhibits P4 DNA synthesis, indicating that form I DNA is the required substrate.
...
PMID:Phage P4 DNA replication in vitro. 802 13

1 2 3 4 Next >>