Zinc binding to Muscle LIM Protein regulates its structure and interaction with binding partners

Abstract

Muscle LIM protein (MLP) is a member of the cysteine‐rich protein family, localising predominantly to the Z‐disk of the myofilaments in cardiac myocytes. MLP is a mechanosensor and functions through its translocation to the nucleus from the myofilaments and through protein‐protein interactions in the cytoplasm. Mechanosensing enables the heart to adapt appropriately to alterations in hemodynamic load, whilst mutations in the MLP gene lead to cardiomyopathy and heart failure. MLP contains two LIM domains each consisting of a double zinc‐finger motif. Rather than interacting with DNA, LIM domains mediate protein‐protein interactions associated with cellular signalling.The aim of this investigation is to determine how zinc binding regulates the structure of MLP and determine the impact on its interaction with binding partners. The analysis was performed using a combination of circular dichroism (CD), bioinformatics tools and online servers. CD is the difference in absorption between left‐handed and right‐handed circularly polarised light, occurring when a molecule contains light‐absorbing groups. It can be used to study the secondary, tertiary and quaternary structure of proteins, as well as studying its conformational stability under different conditions.In this study, we used CD to determine structural changes to MLP in the presence and absence of zinc. MLP is predominantly helical (~36%) with a small percentage of beta‐strands of ~8%, 34% of unordered and 21% of turns. In the presence of excess zinc, the helical content was reduced to ~19% with a gain of beta‐strand component to 30%. The presence of EDTA caused MLP to lose some helical conformation to 22% with an increased in the beta‐strand content to 16%. These data suggest that zinc increases the structural folding and organization of MLP.The full length wildtype MLP sequence was submitted to a variety of servers along with the C58G mutation known to reduce zinc binding in the first LIM domain. This mutation in humans leads to heart failure. Heart failure is defined as a progressive condition in which the heart is unable to pump enough blood to meet the body's needs for oxygen and nutrients. Bioinformatic protein‐protein analysis indicated that the C58G mutation inhibits interaction with NRAP, TCAP, alpha‐actinin and cofilin 2 which would interfere with MLP binding to the z‐disk and the myofilaments within cardiac myocytes. This would have a significant negative impact on mechanosensing in the heart and explains why the C58G mutation in MLP leads to heart failure.Support or Funding InformationUniversity of Reading and Diamond Light SourceThis abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.