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Modification of cloned brain Na+ channels by batrachotoxin (1994)

Wang, G. K. ; Wang, S. -Y.

Springer

Pflügers Archiv 427 (1994), S. 309-316

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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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A common local anesthetic receptor for benzocaine and etidocaine in voltage-gated μ1 Na+ channels (1997)

Wang, G. K. ; Quan, C. ; Wang, S.-Y.

Springer

Pflügers Archiv 435 (1997), S. 293-302

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ISSN: 1432-2013

Keywords: Key words Local anesthetics ; Benzocaine ; Single receptor hypothesis ; Mutant muscle Na+ channels

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract According to Hille’s modulated receptor hypothesis, benzocaine shares a common receptor with all other local anesthetics (LAs) in the voltage-gated Na+ channel. We tested this single receptor hypothesis using mutant muscle Na+ channels of μ1-I1575A, F1579A, and N1584A transiently expressed in Hek-293t cells. Both benzocaine and etidocaine are more effective at blocking μ1-N1584A current than the wild-type current, while they are less potent at blocking μ1-F1579A current. Such concurrent changes of both benzocaine and etidocaine potency towards F1579A and N1584A mutants suggest that they share a common LA receptor. Consistent with results found in studies of native Na+ channels, permanently charged QX-314 at 1 mM is not effective at blocking wild-type, F1579A, and N1584A current via external application. In contrast, QX-314 is relatively potent at blocking I1575A current when applied externally. This increased potency of external QX-314 against the μ1-I1575A mutant has been reported previously in a study of the brain counterpart. Mutant I1575A also appears to be highly sensitive to the external divalent cation Cd2+, probably because of the presence of cysteine residues near the μ1-I1575 position in the IV-S6 segment. To our surprise, neutral benzocaine becomes more effective at blocking μ1-I1575A current than the wild-type current, whereas the opposite is found for etidocaine. We hypothesize that an increase in accessibility of external QX-314 to the μ1-I1575A mutant is accompanied by a reduction of binding towards the charged amine component.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s004240050515

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Slow inactivation of muscle μ1 Na+ channels in permanently transfected mammalian cells (1996)

Wang, S.-Y. ; Wang, G. K.

Springer

Pflügers Archiv 432 (1996), S. 692-699

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ISSN: 1432-2013

Keywords: Key words Na+ channel ; Slow inactivation ; μ1 channel ; Chloramine-T ; Batrachotoxin

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract The slow inactivation of cloned muscle α-subunit Na+ channels was investigated using a Chinese hamster ovary cell line permanently transfected with rat muscle μ1 cDNA. Expression of μ1 Na+ channels was found in cells maintained for more than 6 months after transfection; 〉 70% of cells expressed ≥ 3 nA of Na+ current at +30 mV under whole-cell patch-clamp conditions. As expected, Na+ currents in these cells were blocked by tetrodotoxin as well as by μ-conotoxin. After prolonged depolarization (10 s at +30 mV) to inactivate voltage-gated Na+ channels, Na+ currents slowly reappeared over a time course of several minutes, during which time the cell was repolarized to the holding potential of −100 mV. This recovery from slow inactivation was best fitted by a double exponential function with τ1 = 2.5 s (amplitude = 53%) and τ2 = 83.4 s (amplitude = 38%). In contrast, the development of slow inactivation at +30 mV was best fitted by a single exponential function, with τ = 3.0 s. Steady-state slow inactivation (s ∞) had a midpoint potential (s 0.5) of −52 mV and a slope factor (k) of 7.8 mV. Elimination of fast inactivation by treatment with chloramine-T accelerated the development of slow inactivation significantly (by ≈four fold) but had little effect on recovery or on steady-state slow inactivation. Finally, as in cloned brain NaIIA Na+ channels, batrachotoxin abolished both fast and slow inactivation of μ1 Na+ channels. These results together suggest that slow inactivation takes place in the α-subunit of μ1 muscle Na+ channels and is governed by a μl protein region different from that governing fast inactivation.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s004240050187

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