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PDBsum entry 2mzp
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Contractile protein
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PDB id
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2mzp
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References listed in PDB file
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Key reference
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Title
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Structure and dynamics of the acidosis-Resistant a162h mutant of the switch region of troponin i bound to the regulatory domain of troponin c.
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Authors
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S.E.Pineda-Sanabria,
I.M.Robertson,
B.D.Sykes.
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Ref.
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Biochemistry, 2015,
54,
3583-3593.
[DOI no: ]
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PubMed id
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Abstract
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Intracellular acidosis lowers the Ca(2+) sensitivity of cardiac muscle, which
results in decreased force generation, decreased cardiac output, and,
eventually, heart failure. The A162H mutant of cardiac troponin I in the thin
filament turns the heart acidosis-resistant. Physiological and structural
studies have provided insights into the mechanism of protection by the A162H
substitution; however, the effect of other native residues of cardiac troponin I
is not fully understood. In this study, we determined the structure of the A162H
mutant of the switch region of cardiac troponin I bound to the regulatory domain
of troponin C at pH 6.1, and the dynamics as a function of pH, by NMR
spectroscopy to evaluate the changes induced by protonation of A162H. The
results indicate that A162H induces a transitory curved conformation on troponin
I that promotes contraction, but it is countered by residue E164 to ensure
proper relaxation. Our model explains the absence of diastolic impairment in the
gain-of-function phenotype induced by the A162H substitution as well as the
effects of a variety of mutants studied previously. The description of this
mechanism underlines the fine quality of regulation on cardiac muscle
contraction and anticipates pharmacological agents that induce modest changes in
the contraction-relaxation equilibrium to produce marked effects in cardiac
performance.
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