ISSN:
1432-2013
Keywords:
Na+ channel
;
Batrachotoxin
;
Tetrodotoxin
;
Benzocaine
;
NaIIA channel
Source:
Springer Online Journal Archives 1860-2000
Topics:
Medicine
Notes:
Abstract The effects of batrachotoxin (BTX) on cloned α-subunit Na+ channels were examined in CHO-K1 cells (a chinese hamster ovary cell line) transfected with rat brain NaIIA cDNA. Under whole-cell patch clamp conditions, BTX shifted the voltage dependence of the activation process by about 45 mV towards the hyperpolarizing direction and eliminated the inactivating phase of Na+ currents. Repetitive depolarizations greatly facilitated the binding of BTX with NaIIA channels while the membrane was held at −100 mV. In chloramine-T-pretreated cells, the association rate of BTX binding with the NaIIA channel was 6.5-fold faster than that in untreated cells. The estimated association rate constant for BTX binding with the open form of NaIIA channel was 1.11×106 mol−1·s−1 at room temperature. BTX-modified NaIIA channels were blocked by tetrodotoxin (TTX) in a complicated manner. First, the TTX binding to the closed state of BTX-modified NaIIA channels was not voltage dependent. The K D value of TTX was measured at 8.9 nM, which was similar to that of unmodified channels (K D=14.2 nM). Second, the block of the open state of BTX-modified NaIIA channels by TTX was voltage dependent; depolarization reduced the potency of TTX block between −20 mV to +50 mV. Below −30 mV, the TTX affinity began to level off, probably because of the increased presence of the closed state. Unexpectedly, steady-state inactivation of BTX-modified NaIIA channels was minimal as measured by the two-pulse protocol, a phenomenon distinctly different from that found in GH3 cells. Neutral local anesthetic benzocaine, however, drastically enhanced the steady-state inactivation of BTX-modified NaIIA channels, with its maximal effect around −60 mV. We conclude that BTX can bind and modify the NaIIA α-subunit. However, a specific subtype of α-subunits and/or an unidentified modulating process may be required for the optimal steady-state inactivation of BTX-modified Na+ channels.
Type of Medium:
Electronic Resource
URL:
http://dx.doi.org/10.1007/BF00374539
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