Sorghum bicolor SbHSP110 has an elongated shape and is able of protecting against aggregation and replacing human HSPH1/HSP110 in refolding and disaggregation assays.

Perturbations in the native structure, often caused by stressing cellular conditions, not only impair protein function but also lead to the formation of aggregates, which can accumulate in the cell leading to harmful effects. Some organisms, such as plants, express the molecular chaperone HSP100 (homologous to HSP104 from yeast), which has the remarkable capacity to disaggregate and reactivate proteins. Recently, studies with animal cells, which lack a canonical HSP100, have identified the involvement of a distinct system composed of HSP70/HSP40 that needs the assistance of HSP110 to efficiently perform protein breakdown. As sessile plants experience stressful conditions more severe than those experienced by animals, we asked whether a plant HSP110 could also play a role in collaborating with HSP70/HSP40 in a system that increases the efficiency of disaggregation. Thus, the gene for a putative HSP110 from the cereal Sorghum bicolor was cloned and the protein, named SbHSP110, purified. For comparison purposes, human HsHSP110 (HSPH1/HSP105) was also purified and investigated in parallel. First, a combination of spectroscopic and hydrodynamic techniques was used for the characterization of the conformation and stability of recombinant SbHSP110, which was produced folded. Second, small-angle X-ray scattering and combined predictors of protein structure indicated that SbHSP110 and HsHSP110 have similar conformations. Then, the chaperone activities, which included protection against aggregation, refolding, and reactivation, were investigated, showing that SbHSP110 and HsHSP110 have similar functional activities. Altogether, the results add to the structure/function relationship study of HSP110s and support the hypothesis that plants have multiple strategies to act upon the reactivation of protein aggregates.

The chaperone HSPB1 prepares protein aggregates for resolubilization by HSP70.

In human cells under stress conditions, misfolded polypeptides can form potentially cytotoxic insoluble aggregates. To eliminate aggregates, the HSP70 chaperone machinery extracts and resolubilizes polypeptides for triage to refolding or degradation. Yeast and bacterial chaperones of the small heat-shock protein (sHSP) family can bind substrates at early stages of misfolding, during the aggregation process. The co-aggregated sHSPs then facilitate downstream disaggregation by HSP70. Because it is unknown whether a human sHSP has this activity, we investigated the disaggregation role of human HSPB1. HSPB1 co-aggregated with unfolded protein substrates, firefly luciferase and mammalian lactate dehydrogenase. The co-aggregates formed with HSPB1 were smaller and more regularly shaped than those formed in its absence. Importantly, co-aggregation promoted the efficient disaggregation and refolding of the substrates, led by HSP70. HSPB1 itself was also extracted during disaggregation, and its homo-oligomerization ability was not required. Therefore, we propose that a human sHSP is an integral part of the chaperone network for protein disaggregation.

Tryparedoxin peroxidases and superoxide dismutases expression as well as ROS release are related to Trypanosoma cruzi epimastigotes growth phases.

Trypanosoma cruzi's antioxidant system is unique and relevant to the parasite. In this study, quantitative assays were performed to determine cytosolic and mitochondrial tryparedoxin peroxidases and superoxide dismutases expression (TcCPx, TcMPx, SODB and SODA) in correlation to H(2)O(2) release and O(2)(-) production. Differences were observed regarding H(2)O(2) release and O(2)(-) production between strains and along the growth curve. All of the enzymes studied exhibited varied expression as a function of time in culture. Although at lower levels, the Y strain exhibited the same pattern of Tulahuen 2 enzyme expression for all of the proteins studied, except SODA. In the stationary phase, the degree of expression of all of the enzymes in the Y strain returned to similar levels as those detected in the log phase with the exception of TcCPx and SODA. In Tulahuen 2, a higher expression of TcMPx, SODA and SODB was detected in the early stationary phase, and a slight decrease was observed in the late stationary phase for each enzyme, excluding TcMPx, which exhibited a marked decrease, and TcCPx, which increased its level. Because of the significance of ROS in redox signaling, these differences in enzyme expression underscore the importance of these parameters for epimastigote proliferation.