Crowding Modulates the Conformation, Affinity, and Activity of the Components of the Bacterial Disaggregase Machinery.

Chaperone-mediated protein aggregate reactivation is a complex reaction that depends on the sequential association of molecular chaperones on their interaction with protein aggregates and on substrate refolding. This process could be modulated by the highly crowded intracellular environment, which is known to affect protein conformational change, enzymatic activity, and protein-protein interactions. Here, we report that molecular crowding shapes the chaperone activity of bacterial disaggregase composed of the DnaK system (DnaK, DnaJ, and GrpE) and the molecular motor ClpB. A combination of biophysical and biochemical methods shows that the excluded volume conditions modify the conformation of DnaK and DnaJ without affecting that of GrpE. These crowding-induced conformational rearrangements activate DnaK, enhance the affinity of DnaK for DnaJ, but not for GrpE, and increase the sensitivity of the chaperone activity to cochaperone concentration, explaining the tight control of their relative intracellular amounts. Furthermore, crowding-mediated disordering of the G/F domain of DnaJ facilitates the reversible formation of intermolecular DnaJ conglomerates. These assemblies could drive the formation of Hsp70 clusters at the aggregate surface with the consequent enhancement of the disaggregation efficiency through their coordinated action via entropic pulling. Finally, crowding helps ClpB to outcompete GrpE for DnaK binding, a key aspect of DnaK/ClpB cooperation given the low affinity of the disaggregase for DnaK. Excluded volume conditions promote the formation of the bichaperone complex that disentangles aggregates, enhancing the efficiency of the disaggregation reaction.

Sedimentation Equilibrium Analysis of ClpB Self-Association in Diluted and Crowded Solutions.

ClpB belongs to the Hsp100 family of ring-forming heat-shock proteins involved in degradation of unfolded/misfolded proteins and in reactivation of protein aggregates. ClpB monomers reversibly associate to form the hexameric molecular chaperone that, together with the DnaK system, has the ability to disaggregate stress-denatured proteins. Here, we summarize the use of sedimentation equilibrium approaches, complemented with sedimentation velocity and composition-gradient static light scattering measurements, to study the self-association properties of ClpB in dilute and crowded solutions. As the functional unit of ClpB is the hexamer, we study the effect of environmental factors, i.e., ionic strength and natural ligands, in the association equilibrium of ClpB as well as the role of the flexible N-terminal and M domains of the protein in the self-association process. The application of the nonideal sedimentation equilibrium technique to measure the effects of volume exclusion, reproducing in part the natural crowded conditions inside a cell, on the self-association and on the stability of the oligomeric species of the disaggregase will be described. Finally, the biochemical and physiological implications of these studies and future experimental challenges to eventually reconstitute minimal disaggregating machineries will be discussed.

Crowding activates ClpB and enhances its association with DnaK for efficient protein aggregate reactivation.

Reactivation of intracellular protein aggregates after a severe stress is mandatory for cell survival. In bacteria, this activity depends on the collaboration between the DnaK system and ClpB, which in vivo occurs in a highly crowded environment. The reactivation reaction includes two steps: extraction of unfolded monomers from the aggregate and their subsequent refolding into the native conformation. Both steps might be compromised by excluded volume conditions that would favor aggregation of unstable protein folding intermediates. Here, we have investigated whether ClpB and the DnaK system are able to compensate this unproductive effect and efficiently reactivate aggregates of three different substrate proteins under crowding conditions. To this aim, we have compared the association equilibrium, biochemical properties, stability, and chaperone activity of the disaggregase ClpB in the absence and presence of an inert macromolecular crowding agent. Our data show that crowding i), increases three to four orders of magnitude the association constant of the functional hexamer; ii), shifts the conformational equilibrium of the protein monomer toward a compact state; iii), stimulates its ATPase activity; and iv), favors association of the chaperone with substrate proteins and with aggregate-bound DnaK. These effects strongly enhance protein aggregate reactivation by the DnaK-ClpB network, highlighting the importance of volume exclusion in complex processes in which several proteins have to work in a sequential manner.

Screening and evaluation of small organic molecules as ClpB inhibitors and potential antimicrobials.

Inhibition of ClpB, the bacterial representative of the heat-shock protein 100 family that is associated with virulence of several pathogens, could be an effective strategy to develop new antimicrobial agents. Using a high-throughput screening method, we have identified several compounds that bind to different conformations of ClpB and analyzed their effect on the ATPase and chaperone activities of the protein. Two of them inhibit these functional properties as well as the growth of Gram negative bacteria (E. coli), displaying antimicrobial activity under thermal or oxidative stress conditions. This activity is abolished upon deletion of ClpB, indicating that the action of these compounds is related to the stress cellular response in which ClpB is involved. Moreover, their moderate toxicity in human cell lines suggests that they might provide promising leads against bacterial growth.

DnaK-mediated association of ClpB to protein aggregates. A bichaperone network at the aggregate surface.

Intracellular protein aggregates formed under severe thermal stress can be reactivated by the concerted action of the Hsp70 system and Hsp100 chaperones. We analyzed here the interaction of DnaJ/DnaK and ClpB with protein aggregates. We show that aggregate properties modulate chaperone binding, which in turn determines aggregate reactivation efficiency. ClpB binding strictly depends on previous DnaK association with the aggregate. The affinity of ClpB for the aggregate-DnaK complex is low (K(d)=5-10 microM), indicating a weak interaction. Therefore, formation of the DnaK-ClpB bichaperone network is a three step process. After initial DnaJ binding, the cochaperone drives association of DnaK to aggregates, and in the third step, as shown here, DnaK mediates ClpB interaction with the aggregate surface.