Desmin Modifications Associate with Amyloid-like Oligomers Deposition in Heart Failure

Overview

Journal Cardiovasc Res

Specialty Cardiology & Vascular Diseases

Date 2014 Jan 14

PMID 24413773

Citations 45

Authors

Giulio Agnetti

Victoria L Halperin

Jonathan A Kirk

Khalid Chakir

Yurong Guo

Linda Lund

Francesco Nicolini

Tiziano Gherli

Carlo Guarnieri

Claudio M Caldarera

Gordon F Tomaselli

David A Kass

Jennifer E Van Eyk

Affiliations

Soon will be listed here.

Abstract

Aims: The ultimate cause of heart failure (HF) is not known to date. The cytoskeletal protein desmin is differentially modified and forms amyloid-like oligomers in HF. We postulated that desmin post-translational modifications (PTMs) could drive aberrant desmin aggregation in HF. Therefore, we identified these PTMs and investigated their impact on desmin amyloidogenicity in human and experimental HF.

Methods And Results: We detected increased levels of selectively phosphorylated and cleaved desmin in a canine pacing model of dyssynchronous HF (DHF) compared with either controls or animals treated with cardiac resynchronization therapy (CRT). This unique animal model combines clinically relevant features with the possibility of a partly rescued phenotype. We confirmed analogous changes in desmin modifications in human HF and identified two phosphorylation sites within a glycogen synthase kinase 3 (GSK3) consensus sequence. Desmin-positive oligomers were also increased in DHF hearts compared with controls. Their amyloid properties were decreased by treatment with CRT or an anti-amyloid small molecule. Finally, we confirmed GSK3's involvement with desmin phosphorylation using an in vitro model.

Conclusions: Based on these findings, we postulate a new mechanism of cardiac toxicity based on the PTM-driven accumulation of desmin amyloid-like oligomers. Phosphorylation and cleavage as well as oligomers formation are reduced by treatment (CRT) indicating a relationship between the three. Finally, the decrease of desmin amyloid-like oligomers with CRT or small molecules points both to a general mechanism of HF based on desmin toxicity that is independent of protein mutations and to novel potential therapies.

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