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Description
Ica(TTx) is a sodium current component seen in a number of neural and cardiac preparations. In each case,
ICa(TTx) channels were found to express both different gating and different permeability properties from the
main body of sodium current in that cell type. For rat ventricular cells we have shown that ICa(TTX) channels
are encoded by a different gene from that encoding the classical cardiac sodium current. As expected from
the very existence of a clear current component, ICa(TTX) channels do affect the electrical behavior of
ventricular cells and can even generate action potentials. ICa(TTx) activates over a more negative range of
potentials than the classical cardiac sodium current. It should, then, act to amplify the depolarization
delivered to a ventricular cell and so provide the immediate trigger for the cardiac action potential. Owing to
this role, ICa(TTX) could be of considerable importance in cardiac arrhythmias and in their control. It has been
reported in both human atrial and ventricular cells. We have, then, a new channel encoded by a distinct gene
that contributes to cardiac cell electrical behavior. The potential importance of this channel for both normal
and pathological cardiac electrophysiology calls for its extensive study. We propose to: (i) Determine the
slow inactivation properties of ICa(TTx) and compare them to those of the classical sodium current. The slow
inactivation process is critical for determining the stationary state pool of available sodium channels. The
expected role of ICa(TTX) as the immediate trigger for the cardiac action potential suggests that its slow
inactivation properties (and defects in them) could have disproportionately strong effects on the generation
and conduction of the cardiac action potentials. (ii) Quantitatively determine the selectivity sequence of
ICa(TTX) channels to both mono- and divalent ions. The characteristics of a current component are determined
by it selectivity as well as its gating properties. This will be the first determination of the alkali ion selectivity
of a native sodium channel that expresses high calcium permeability and could be of importance for the
emerging picture of the structural basis for ion selectivity in typical sodium channels. (iii) Start the molecular
identification of ICa(TTX) channels by use of antisense oligonucleotides directed against the several sodium
channel isoforms known to be expressed in cardiac cell. (iv) Compare the properties of ICa(TTX) in normal and
failing human hearts to see it alterations in its properties correlate with pathological conditions.
Status | Finished |
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Effective start/end date | 9/1/03 → 8/31/09 |
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