Effects of Calcium Binding and the Hypertrophic Cardiomyopathy
A8V Mutation on the Dynamic Equilibrium between Closed and Open Conformations
of the Regulatory N‑Domain of Isolated Cardiac Troponin C
posted on 2013-03-19, 00:00authored byNicole
M. Cordina, Chu K. Liew, David A. Gell, Piotr G. Fajer, Joel P. Mackay, Louise J. Brown
Troponin C (TnC) is the calcium-binding
subunit of the troponin
complex responsible for initiating striated muscle contraction in
response to calcium influx. In the skeletal TnC isoform, calcium binding
induces a structural change in the regulatory N-domain of TnC that
involves a transition from a closed to open structural state and accompanying
exposure of a large hydrophobic patch for troponin I (TnI) to subsequently
bind. However, little is understood about how calcium primes the N-domain
of the cardiac isoform (cTnC) for interaction with the TnI subunit
as the open conformation of the regulatory domain of cTnC has been
observed only in the presence of bound TnI. Here we use paramagnetic
relaxation enhancement (PRE) to characterize the closed to open transition
of isolated cTnC in solution, a process that cannot be observed by
traditional nuclear magnetic resonance methods. Our PRE data from
four spin-labeled monocysteine constructs of isolated cTnC reveal
that calcium binding triggers movement of the N-domain helices toward
an open state. Fitting of the PRE data to a closed to open transition
model reveals the presence of a small population of cTnC molecules
in the absence of calcium that possess an open conformation, the level
of which increases substantially upon Ca2+ binding. These
data support a model in which calcium binding creates a dynamic equilibrium
between the closed and open structural states to prime cTnC for interaction
with its target peptide. We also used PRE data to assess the structural
effects of a familial hypertrophic cardiomyopathy point mutation located
within the N-domain of cTnC (A8V). The PRE data show that the Ca2+ switch mechanism is perturbed by the A8V mutation, resulting
in a more open N-domain conformation in both the apo and holo states.