May 30, 2012 in
Cardiology Cardiovascular researchers at
the University of Cincinnati (UC) have identified a genetic variant in a
cardiac protein that can be linked to heart rhythm dysfunction. Troponin-I ELISA Kits - Mouse, rat, rabbit,
dog, monkey Widely referenced in the literature - www.lifediagnostics.com This is the first genetic variant in a
calcium-binding protein (histidine-rich calcium binding protein) found to be
associated with ventricular arrhythmias and sudden cardiac death in dilated
cardiomyopathy patients, opening up new possibilities for treatment. Dilated
cardiomyopathy is a condition in which the heart becomes weakened and enlarged
and cannot pump blood efficiently. These findings are being presented for the
first time at the International Society of Heart Research's Pathology and
Treatment of Heart Failure meeting in Banff ,
Alberta , held May 27 through May
31, 2012. The team led by Vivek Singh, PhD, a research
scientist under the direction of Litsa Kranias, PhD, in the department of
pharmacology and cell biophysics at UC, says that sudden cardiac death is a
risk for patients with heart failure who are carriers of this variant in the
histidine-rich calcium-binding protein because the calcium inside their heart
cells is not properly controlled, possibly leading to the development of
arrhythmias. "The histidine-rich calcium-binding
protein (HRC) is a regulator of calcium uptake and release in the sarcoplasmic
reticulum, a network of tubes and sacs in heart muscle fibers that plays an
important role in heart contraction and relaxation by releasing and storing
calcium ions," Singh says. "Recently, our group at UC and Athens , Greece ,
identified a genetic variant in HRC, named Ser96Ala, which showed a significant
association with worsening ventricular arrhythmias and sudden cardiac death in
a group of patients with idiopathic dilated cardiomyopathy. In this study, our
team characterized the mechanisms and pathways that link the HRC variant with
arrhythmias causing sudden death." Researchers first generated animal models with
cardiac-specific expression of the human normal (S96S) or altered (A96A ) HRC. "Unexpectedly,
we found that contractility of heart cells significantly decreased with
disturbed calcium regulation in A96A
hearts when compared with S96S hearts," Singh says. "In addition, A96A heart cells showed more arrhythmic
behavior under stress conditions." Singh says this data could eventually provide
new insights into pathways that control calcium regulation, leading to the
development of new clinical interventions. "Our
results showed that the human HRC mutant model displayed altered intracellular
calcium (Ca2+) handling, associated with slowed Ca2+ uptake and increased Ca2+
leak, which may promote arrhythmias under stress," Singh says. "These
new findings are important because we can use this information to help develop
new methods of screening human patients and preventing arrhythmia development
in the carriers."
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