GroEL to DnaK chaperone network behind the stability modulation of σ(32) at physiological temperature in Escherichia coli.

The stability of heat-shock transcription factor σ(32) in Escherichia coli has long been known to be modulated only by its own transcribed chaperone DnaK. Very few reports suggest a role for another heat-shock chaperone, GroEL, for maintenance of cellular σ(32) level. The present study demonstrates in vivo physical association between GroEL and σ(32) in E. coli at physiological temperature. This study further reveals that neither DnaK nor GroEL singly can modulate σ(32) stability in vivo; there is an ordered network between them, where GroEL acts upstream of DnaK.

In vitro holdase activity of E. coli small heat-shock proteins IbpA, IbpB and IbpAB: a biophysical study with some unconventional techniques.

E. coli small heat shock proteins IbpA and IbpB (inclusion body binding proteins A and B) are known to act as holding chaperones on denaturing, aggregate-prone proteins. But, there is no clear understanding about which of the IbpA and IbpB has more holdase activity and how the holdase activity of one was influenced by the presence of the other. This study was conducted to resolve the questions, using some uncommon physical techniques like dynamic light scattering, micro-viscometry and atomic force microscopy in addition to the common techniques of spectrophotometry and spectrofluorimetry. The holdase activity was investigated on the heat-denatured L-lactate dehydrogenase (LDH) of rabbit muscle. LDH was found to be deactivated completely without any aggregation at 52°C and with transient aggregation at 60°C; molecular dynamics simulation also revealed that at 52°C, denaturation occurred only at the active site of LDH. When LDH was allowed to be deactivated in the presence of IbpA, IbpB or (IbpA + IbpB), partial inhibition of i) denaturation at 52°C and ii) aggregation at 60°C were observed. The results further demonstrated that the holdase activity of IbpB was higher than that of IbpA and their combined effect was higher than their individual one.

Calcium chloride made E. coli competent for uptake of extraneous DNA through overproduction of OmpC protein.

In the standard method of transformation of Escherichia coli with extraneous DNA, cells are made competent for DNA uptake by incubating in ice-cold 100 mM CaCl(2). Analysis of the whole protein profile of CaCl(2)-treated E. coli cells by the techniques of one- and two-dimensional gel electrophoresis, MALDI-MS and immunoprecipitation revealed overproduction of outer membrane proteins OmpC, OmpA and heat-shock protein GroEL. In parity, transformation efficiency of E. coli ompC mutant by plasmid pUC19 DNA was found to be about 40 % lower than that of the wild type strain. Moreover, in E. coli cells containing groEL-bearing plasmid, induction of GroEL caused simultaneous overproduction of OmpC. On the other hand, less OmpC was synthesized in E. coli groEL mutant compared to its wild type counterpart, by CaCl(2)-shock. From these results it can be suggested that in the process of CaCl(2)-mediated generation of competence, the heat-shock chaperone GroEL has specific role in DNA entry into the cell, possibly through the overproduced OmpC and OmpA porins.

Evolutionary analysis of prokaryotic heat-shock transcription regulatory protein σ³².

Heat-stress to any living cell is known to trigger a universal defense response, called heat-shock response, with rapid induction of tens of different heat-shock proteins. Bacterial heat-shock genes are transcribed by the σ(32)-bound RNA polymerase instead of the normal σ(70)-bound RNA polymerase. In this study, the diversity in sequence, variation in secondary structure and function amongst the different functional regions of the proteobacterial σ(32) family of proteins, and their phylogenetic relationships have been analyzed. Bacterial σ(32) proteins can be subdivided into different functional regions which are referred to as regions 2, 3, and 4. There is a great deal of sequence conservation among the functional regions of proteobacterial σ(32) family of proteins though some mutations are also present in these regions. Region 2 is the most conserved one, while region 4 has comparatively more variable sequences. In the present work, we tried to explore the effects of mutations in these regions. Our study suggests that the sequence diversities due to natural mutations in the different regions of proteobacterial σ(32) family lead to different functions. So far, this study is the first bioinformatic approach towards the understanding of the mechanistic details of σ(32) family of proteins using the protein sequence information only. This study therefore may help in elucidating the hitherto unknown molecular mechanism of the functionalities of σ(32)family of proteins.

A structural insight into the prokaryotic heat shock transcription regulatory protein σ(32): an implication of σ(32)-DnaK interaction.

The heat shock response mechanism is a very vital biochemical process and is mainly controlled by σ(32) protein. The function of σ(32) is temperature dependent and at lower temperatures σ(32) is inactivated by its interactions with DnaK. This interaction is completely abolished above 42°C till date no molecular details of the interactions are available. In the present scenario, an attempt has been made to analyze first the predicted structure of σ(32) obtained by comparative modeling techniques and then to study the interactions between σ(32) and DnaK. From this molecular modeling study we could specifically identify the binding sites of the interactions of σ(32) with DnaK which will enlighten the mechanism of regulation of its activity and stability by DnaK. Our study provides the idea for future mutational experiments in order to find out the possible roles of the amino acids of region2 and region3 of σ(32) in stability as well as in binding with DnaK.