Abstract 352: Manf, a Structurally Unique Redox-sensitive Chaperone, Restores Er-protein Folding in the Ischemic Heart

Abstract

Rationale: In cardiomyocytes, secreted and membrane proteins critical for heart function are synthesized and folded in the sarcoplasmic/endoplasmic reticulum (SR/ER). We previously showed that myocardial ischemia decreases oxygen required for disulfide bond formation in nascent proteins, causing ER stress, i.e. the toxic accumulation of unfolded proteins, which contributes to cardiomyocyte death. In response to ER stress, the transcription factor ATF6 induces various ER-resident proteins that restore SR/ER protein folding, including ER chaperones. We found that ATF6 induces mesencephalic astrocyte-derived neurotrophic factor (MANF), a recently identified protein of unknown function. MANF is structurally unique, so its function could not be inferred by analogy to other proteins. Since we found that MANF is an ATF6-inducible ER-resident protein we hypothesized that it functions as a chaperone, and since MANF has 8 cysteine residues that are conserved in a wide range of species, that its chaperone function is redox-regulated and protective in the ischemic heart. Methods: The ability of recombinant MANF (rMANF) to suppress misfolded protein aggregation was examined in an in vitro chaperone assay. The effect of MANF knockdown on cell viability during simulated ischemia (sI) was determined in neonatal rat ventricular myocytes (NRVM). The effect of MANF loss-of-function in the ischemic heart, in vivo , was determined in a novel mouse model in which MANF is knocked down in cardiomyocytes. Results: rMANF formed disulfide-dependent complexes with and suppressed aggregation of model misfolded proteins in vitro , and these effects were lost when the cysteines in rMANF were mutated to alanine. In NRVM, MANF knockdown decreased viability during simulated ischemia; this viability deficit was restored upon ectopic expression of wild type, but not mutant MANF. MANF knockdown in the heart, in vivo , increased ischemia/reperfusion damage, and this damage was mitigated using an AAV9-based gene therapy approach to restore MANF expression. Conclusions: MANF is a novel redox-sensitive SR/ER-resident chaperone that is a critical contributor to SR/ER protein folding during the adaptive ER stress response and mitigates ischemia/reperfusion damage in the heart.