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Persistence length of human cardiac ?-tropomyosin measured by single molecule direct probe microscopy.


ABSTRACT: ?-Tropomyosin (?Tm) is the predominant tropomyosin isoform in adult human heart and constitutes a major component in Ca²+-regulated systolic contraction of cardiac muscle. We present here the first direct probe images of WT human cardiac ?Tm by atomic force microscopy, and quantify its mechanical flexibility with three independent analysis methods. Single molecules of bacterially-expressed human cardiac ?Tm were imaged on poly-lysine coated mica and their contours were analyzed. Analysis of tangent-angle (?(s)) correlation along molecular contours, second moment of tangent angles (), and end-to-end length (L(e-e)) distributions respectively yielded values of persistence length (L(p)) of 41-46 nm, 40-45 nm, and 42-52 nm, corresponding to 1-1.3 molecular contour lengths (L(c)). We also demonstrate that a sufficiently large population, with at least 100 molecules, is required for a reliable L(p) measurement of ?Tm in single molecule studies. Our estimate that L(p) for ?Tm is only slightly longer than L(c) is consistent with a previous study showing there is little spread of cooperative activation into near-neighbor regulatory units of cardiac thin filaments. The L(p) determined here for human cardiac ?Tm perhaps represents an evolutionarily tuned optimum between Ca²+ sensitivity and cooperativity in cardiac thin filaments and likely constitutes an essential parameter for normal function in the human heart.

SUBMITTER: Loong CK 

PROVIDER: S-EPMC3380901 | biostudies-literature | 2012

REPOSITORIES: biostudies-literature

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Persistence length of human cardiac α-tropomyosin measured by single molecule direct probe microscopy.

Loong Campion K P CK   Zhou Huan-Xiang HX   Chase P Bryant PB  

PloS one 20120621 6


α-Tropomyosin (αTm) is the predominant tropomyosin isoform in adult human heart and constitutes a major component in Ca²+-regulated systolic contraction of cardiac muscle. We present here the first direct probe images of WT human cardiac αTm by atomic force microscopy, and quantify its mechanical flexibility with three independent analysis methods. Single molecules of bacterially-expressed human cardiac αTm were imaged on poly-lysine coated mica and their contours were analyzed. Analysis of tang  ...[more]

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