Evidence for a conformational change in the DNA gyrase-DNA complex from hydroxyl radical footprinting.

We have used the technique of hydroxyl radical footprinting to probe the complex between DNA gyrase and a 198 bp DNA fragment containing the preferred gyrase cleavage site from plasmid pBR322. We find that gyrase protects 128 bp from the hydroxyl radical with the central 13 bp (adjacent to the gyrase cleavage site) being most strongly protected. Flanking the central region are arms showing periodic protection from the reagent suggesting a helical repeat of 10.6 bp, consistent with the DNA being wrapped upon the enzyme surface. The presence of 5'-adenylyl-beta,gamma-imidodiphosphate or a quinolone drug causes alteration of the protection pattern consistent with a conformational change in the complex involving one arm of the wrapped DNA. The significance of these results for the mechanism of DNA supercoiling by gyrase is discussed.     

Dissociation of intact Escherichia coli ribosomes in a mass spectrometer. Evidence for conformational change in a ribosome elongation factor G complex

We used mass spectrometry to identify proteins that are released in the gas phase from Escherichia coli ribosomes in response to a range of different solution conditions and cofactor binding. From solution at neutral pH the spectra are dominated by just 4 of the 54 ribosomal proteins (L7/L12, L11, and L10). Lowering the pH of the solution leads to the gas phase dissociation of four additional proteins as well as the 5 S RNA. Replacement of Mg(2+) by Li(+) ions in solutions of ribosomes induced the dissociation of 17 ribosomal proteins. Correlation of these results with available structural information for ribosomes revealed that a relatively high interaction surface area of the protein with RNA was the major force in preventing dissociation. By using the proteins that dissociate to probe their interactions with RNA, we examined different complexes of the ribosome formed with the elongation factor G and inhibited by fusidic acid or thiostrepton. Mass spectra recorded for the fusidic acid-inhibited complex reveal subtle changes in peak intensity of the proteins that dissociate. By contrast gas phase dissociation from the thiostrepton-inhibited complex is markedly different and demonstrates the presence of L5 and L18, two proteins that interact exclusively with the 5 S RNA. These results allow us to propose that the ribosome elongation factor-G complex inhibited by thiostrepton, but not fusidic acid, involves destabilization of 5 S RNA-protein interactions.     

A novel tetratricopeptide repeat-containing J-protein localized in a plasma membrane-bound protein complex of the phytopathogenic oomycete Phytophthora megasperma

Phytoalexins originating from plant tissues may cause within cells of fungi or oomycetes a change in the localization of actin, tubulin and chaperones. To test the hypothesis in a filamentously growing oomycete, we compared the distribution of cellular markers in the presence and absence of hydroxystilbene phytoalexins. Using cDNA from the phytopathogenic organism Phytophthora megasperma, the causal agent of root rot on soybean and many other plants, and including probes for Hsp70 and Hsp40, we cloned a DnaJ-protein (Jcp) with the capacity of interacting with both a particular Hsp70 isoform via its J-domain and with other proteins via its tetratricopeptide repeat (TPR) domain. Antisera raised against the bacterially expressed protein Jcp allowed the analysis of its intracellular localization during hyphal growth. Following the subfractionation of cell homogenates, we detected virtually all immunoreactive Jcp in the plasma membrane-enriched fraction and as constituent of a membrane-associated protein complex. In agreement with the biochemical findings, immunocytochemical stains of hyphae showed Jcp as part of cortical patches positioned along the plasma membrane similar to the distribution of actin patches. Confocal microscopy, however, revealed that the Jcp-containing patches did not generally co-localize with the patches visualized by the actin stain. The 59-kDa Jcp, characterized by a large 8-fold TPR domain at the N-terminal region and a J-domain close to the C-terminus, is a good candidate for bridging the gap between Hsp70 and Hsp90 by protein-protein interactions. By administration of plant-derived phytoalexins it was shown that the presence of resveratrol or piceatannol significantly reduces the amount of the Jcp-containing patches, but does not lead to a relocalization of intracellular Jcp.     

Inhibition of factor Xa by a peptidyl-alpha-ketothiazole involves two steps. Evidence for a stabilizing conformational change.

Recently, peptidylketothiazoles have been shown to be potent inhibitors of proteases, but the details of the interaction have not yet been studied. In the work presented here, the interaction of factor Xa, a coagulation protease, with the transition state inhibitor BnSO(2)-D-Arg-Gly-Arg-ketothiazole (C921-78) is characterized. C921-78 is a tight and selective inhibitor of the coagulation protease factor Xa (K(d) = 14 pM). The hydrolytic activity of factor Xa was inhibited by C921-78 in a time-dependent manner. The rate-limiting step of the bimolecular combination of inhibitor and enzyme was competitive with the substrate. Conversely, the inhibitor could be displaced from the active site of the enzyme after exposure of the preformed complex to an excess of substrate or to the active site inhibitor dansyl-Glu-Gly-Arg-chloromethyl ketone (DEGR-CMK) in a slow reaction. The formation of the C921-78-factor Xa complex resulted in a 60% increase in the magnitude of the fluorescence emission spectrum. Rapid mixing of the enzyme and inhibitor produces a monophasic fluorescence increase, compatible with spectral transition in a single step. The rate constant for this reaction increased hyperbolically with the concentration of C921-78, but the amplitude remained constant. These results are consistent with the initial formation of an enzyme-inhibitor complex (EI), followed by a unimolecular conversion of EI to EI linked to a spectral transition. The rate constants of the isomerization provide an estimate of 300000-fold stabilization. Thus, the inhibition of factor Xa by C921-78 follows a mechanism similar to that described classically for slow tight binding inhibitors. However, the two steps of the reaction cannot be kinetically separated by the rapid equilibrium assumption, and therefore, the formation of EI is partially rate-limiting, too. The driving energy for the unusually fast isomerization step may result from the highly favorable interactions of the inhibitor in the primary binding site.     

Evidence for fast conformational change upon ligand dissociation in the HemAT class of bacterial oxygen sensors

Here we report the results of transient absorption and photoacoustic calorimetry studies of CO photodissociation from the heme domain of the bacterial oxygen sensor HemAT-Bs. The results indicate that CO photolysis is accompanied by an overall DeltaH of -19 kcal mol(-1) and DeltaV of +4 ml mol(-1) as well as a red-shifted kinetic difference spectrum all occurring in <50 ns. Analysis of the DeltaH/DeltaV reveals that a conformational change takes place with a DeltaH(conf) of -40 kcal mol(-1) and DeltaV(conf) of -22 ml mol(-1). These thermodynamic changes are consistent with an increase in the solvent accessible surface area of the protein upon ligand dissociation, as observed in the X-ray structure of the ferric CN-bound and CN free forms of HemAT-Bs.