Hsp104 as a key modulator of prion-mediated oxidative stress in Saccharomyces cerevisiae.

Maintenance of cellular redox homoeostasis forms an important part of the cellular defence mechanism and continued cell viability. Despite extensive studies, the role of the chaperone Hsp104 (heat-shock protein of 102 kDa) in propagation of misfolded protein aggregates in the cell and generation of oxidative stress remains poorly understood. Expression of RNQ1-RFP in Saccharomyces cerevisiae cells led to the generation of the prion form of the protein and increased oxidative stress. In the present study, we show that disruption of Hsp104 in an isogenic yeast strain led to solubilization of RNQ1-RFP. This reduced the oxidative stress generated in the cell. The higher level of oxidative stress in the Hsp104-containing (parental) strain correlated with lower activity of almost all of the intracellular antioxidant enzymes assayed. Surprisingly, this did not correspond with the gene expression analysis data. To compensate for the decrease in protein translation induced by a high level of reactive oxygen species, transcriptional up-regulation takes place. This explains the discrepancy observed between the transcription level and functional enzymatic product. Our results show that in a ΔHsp104 strain, due to lower oxidative stress, no such mismatch is observed, corresponding with higher cell viability. Thus Hsp104 is indirectly responsible for enhancing the oxidative stress in a prion-rich environment.

Disease-associated mutations within the yeast DNAJB6 homolog Sis1 slow conformer-specific substrate processing and can be corrected by the modulation of nucleotide exchange factors.

Molecular chaperones, or heat shock proteins (HSPs), protect against the toxic misfolding and aggregation of proteins. As such, mutations or deficiencies within the chaperone network can lead to disease. Dominant mutations within DNAJB6 (Hsp40)-an Hsp70 co-chaperone-lead to a protein aggregation-linked myopathy termed Limb-Girdle Muscular Dystrophy Type D1 (LGMDD1). Here, we used the yeast prion model client in conjunction with in vitro chaperone activity assays to gain mechanistic insights into the molecular basis of LGMDD1. Here, we show how mutations analogous to those found in LGMDD1 affect Sis1 (a functional homolog of human DNAJB6) function by altering the structure of client protein aggregates, interfering with the Hsp70 ATPase cycle, dimerization and substrate processing; poisoning the function of wild-type protein. These results uncover the mechanisms through which LGMDD1-associated mutations alter chaperone activity, and provide insights relevant to potential therapeutic interventions.

Inhibition of DNAJ-HSP70 interaction improves strength in muscular dystrophy.

Dominant mutations in the HSP70 cochaperone DNAJB6 cause a late-onset muscle disease termed limb-girdle muscular dystrophy type D1 (LGMDD1), which is characterized by protein aggregation and vacuolar myopathology. Disease mutations reside within the G/F domain of DNAJB6, but the molecular mechanisms underlying dysfunction are not well understood. Using yeast, cell culture, and mouse models of LGMDD1, we found that the toxicity associated with disease-associated DNAJB6 required its interaction with HSP70 and that abrogating this interaction genetically or with small molecules was protective. In skeletal muscle, DNAJB6 localizes to the Z-disc with HSP70. Whereas HSP70 normally diffused rapidly between the Z-disc and sarcoplasm, the rate of diffusion of HSP70 in LGMDD1 mouse muscle was diminished, probably because it had an unusual affinity for the Z-disc and mutant DNAJB6. Treating LGMDD1 mice with a small-molecule inhibitor of the DNAJ-HSP70 complex remobilized HSP70, improved strength, and corrected myopathology. These data support a model in which LGMDD1 mutations in DNAJB6 are a gain-of-function disease that is, counterintuitively, mediated via HSP70 binding. Thus, therapeutic approaches targeting HSP70-DNAJB6 may be effective in treating this inherited muscular dystrophy.

Specific detection of tetanus toxoid using an aptamer-based matrix.

Batch-to-batch variation of therapeutic proteins produced by biological means requires rigorous monitoring at all stages of the production process. A large number of animals are employed for risk assessment of biologicals, which has low ethical and economic acceptability. Research is now focussed on the validation of in vitro and ex vivo tests to replace live challenges. Among in vitro methods, enzyme-linked immunosorbent assay (ELISA) is considered to be the gold standard for estimation of integrity of tetanus toxoid. ELISA utilizes antibodies for detection, which, because of their biological origin and limited modifiability, may have low stability and result in irreproducibility. We have developed a method using highly specific and selective RNA aptamers for detection of tetanus toxoid. Using displacement assay, we first identified aptamers which bind to different aptatopes on the surface of the toxoid. Pairs of these aptamers were employed as capture-detection ligands in a sandwich-ALISA (aptamer-linked immobilized sorbent assay) format. The binding efficiency was confirmed by the fluorescence intensity in each microtire plate well. Using aptamers alone, detection of tetanus toxoid was possible with the same level of sensitivity as antibody. Aptamers were also used in the capture ALISA format. Adjuvanted tetanus toxoid was subjected to accelerated stress testing, including thermal, mechanical and freeze-thawing stress conditions. The loss in antigenicity of the preparation determined by ALISA in each case was found to be similar to that determined by conventional ELISA. Thus, it is possible to replace antibodies with aptamers to develop a more robust detection tool for tetanus toxoid.