Molecular basis for regulation of the heat shock transcription factor sigma32 by the DnaK and DnaJ chaperones.

Central to the transcriptional control of the Escherichia coli heat shock regulon is the stress-dependent inhibition of the sigma(32) subunit of RNA polymerase by reversible association with the DnaK chaperone, mediated by the DnaJ cochaperone. Here we identified two distinct sites in sigma(32) as binding sites for DnaK and DnaJ. DnaJ binding destabilizes a distant region of sigma(32) in close spatial vicinity of the DnaK-binding site, and DnaK destabilizes a region in the N-terminal domain, the primary target for the FtsH protease, which degrades sigma(32) in vivo.

Synthetic peptide and protein domain arrays prepared by the SPOT technology.

The SPOT(trade mark) technology for highly parallel synthesis of peptides on flat surfaces in array type format has evolved into a versatile toolbox for a variety of applications in proteomics such as mapping protein-protein interactions and profiling the substrate specificity of enzymes such as kinases and proteases. Originally developed for the synthesis of short overlapping peptide sequences for mapping antibody epitopes this technology has recently been extended to the synthesis of functional protein domains. This opens up a variety of future applications such as target identification and protein expression profiling.

Structure of an anti-cholera toxin antibody Fab in complex with an epitope-derived D-peptide: a case of polyspecific recognition.

The structure of a complex of the anti-cholera toxin antibody TE33 Fab (fragment antibody) with the D-peptide vpGsqhyds was solved to 1.78 A resolution. The D-peptide was derived from the linear L-peptide epitope VPGSQHIDS by a stepwise transformation.