Li-Qiong Chen

Myosin VI is an actin-based motor that moves backwards.

Myosins and kinesins are molecular motors that hydrolyse ATP to track along actin filaments and microtubules, respectively. Although the kinesin family includes motors that move towards either the plus or minus ends of microtubules, all characterized myosin motors move towards the barbed (+) end of actin filaments. Crystal structures of myosin II (refs 3,4,5,6) have shown that small movements within the myosin motor core are transmitted through the ‘converter domain’ to a ‘lever arm’ consisting of a light-chain-binding helix and associated light chains. The lever arm further amplifies the motions of the converter domain into large directed movements. Here we report that myosin VI, an unconventional myosin, moves towards the pointed (-) end of actin. We visualized the myosin VI construct bound to actin using cryo-electron microscopy and image analysis, and found that an ADP-mediated conformational change in the domain distal to the motor, a structure likely to be the effective lever arm, is in the opposite direction to that observed for other myosins. Thus, it appears that myosin VI achieves reverse-direction movement by rotating its lever arm in the opposite direction to conventional myosin lever arm movement.

On the Molecular Nature of the Lidocaine Receptor of Cardiac Na+ Channels Modification of Block by Alterations in the α-Subunit III-IV Interdomain

The mechanism of inhibition of Na+ channels by lidocaine has been suggested to involve low-affinity binding to rested states and high-affinity binding to the inactivated state of the channel, implying either multiple receptor sites or allosteric modulation of receptor affinity. Alternatively, the lidocaine receptor may be guarded by the channel gates. To test these distinct hypotheses, inhibition of Na+ channels by lidocaine was studied by voltage-clamp methods in both native and heterologous expression systems. Native Na+ channels were studied in guinea pig ventricular myocytes, and recombinant human heart Na+ channels were expressed in Xenopus laevis oocytes. Fast inactivation was eliminated by mutating three amino acids (isoleucine, phenylalanine, and methionine) in the III-IV interdomain to glutamines or by enzymatic digestion with alpha-chymotrypsin. In channels with intact fast inactivation, lidocaine block developed with a time constant of 589 +/- 42 ms (n = 7) at membrane potentials between -50 and +20 mV, as measured by use of twin pulse protocols. The IC50 was 36 +/- 1.8 mumol/L. Control channels inactivated within 20 ms, and slow inactivation developed much later (time constant of slow inactivation, 6.2 +/- 0.36 s). The major component of block developed long after activated and open channels were no longer available for drug binding. Control channels recovered fully from inactivation in < 50 ms at -120 mV (time constant, 11 +/- 0.5 ms; n = 50).(ABSTRACT TRUNCATED AT 250 WORDS)

Modulation of Human Muscle Sodium Channels by Intracellular Fatty Acids Is Dependent on the Channel Isoform

Free fatty acids (FFAs), including arachidonic acid (AA), are implicated in the direct and indirect modulation of a spectrum of voltage-gated ion channels. Skeletal muscle sodium channels can be either activated or inhibited by FFA exposure; the response is dependent on both FFA structure and site of exposure. Recombinant human skeletal muscle sodium channels (hSkM1) were transfected into heterologous human renal epithelium HEK293t cells. Cytoplasmic delivery of 5 μM AA augmented the voltage-activated sodium current of hSkM1 channels by 190% (±54 S.E., n = 7) over a 20-min period. Similar results were seen with 5 μM oleic acid. Sodium currents in HEK293t cells transfected with human cardiac muscle sodium channels (hH1) were insensitive to AA treatment, and exposure to oleic acid inhibited the hH1 currents over a 20-min period by 29% (±13 S.E., n = 5). The increase in hSkM1 current was not accompanied by shifts in voltage dependence of activation, steady-state inactivation, or markedly altered kinetics of inactivation of the macroscopic current. The FFA-induced increase in sodium currents was not dependent on protein kinase C activity. In contrast, both isoforms were reversibly inhibited by external application of unsaturated FFA. Thus, the differential effects of FFA on skeletal muscle sodium channels first noted in cultured muscle cells can be reproduced by expressing recombinant sodium channels in epithelial cells. Although the responses to applied FFAs could be direct or indirect, we suggest that: 1) SkM1 has two classes of response to FFA, one which produces augmentation of macroscopic currents with intracellular FFA, and a second which produces inhibition with extracellular FFA; 2) H1 has only one class of response, which produces inhibition with extracellular FFA. A testable hypothesis is that the presence or absence of each response is due to a specific structure in SkM1 or H1. These specific structures may directly interact with FFA or may interact with intermediate components.

Effects of Tityus Serrulatus Scorpion Toxin gamma on Voltage-Gated Na sup + Channels

The effects of Brazilian scorpion Tityus serrulatus toxin gamma (TiTx gamma) were studied on voltage-gated Na+ channels from human heart (hHl) and rat skeletal muscle (rSkM1). The Na+ channels were expressed in Xenopus laevis oocytes, and Na+ currents were recorded using two-microelectrode voltage-clamp techniques. In control experiments, the threshold of activation of hH1 is more negative than that of rSkM1 by approximately 20 mV. The toxin induces a shift of the voltage dependence of activation toward more negative potential values and reduces the amplitude of the current when administered to rSkM1. In contrast, TiTx gamma has little discernible effect on the current-voltage curve for hH1 at 100 nmol/L. Chimeric channels formed from these two isoforms were constructed to localize the binding site of TiTx gamma on rSkM1. TiTx gamma shifts the activation of a chimera (SSHH) in which domains 1 (D1) and 2 (D2) derive from rSkM1 and domain 3(D3) and 4 (D4) derive from hH1. This finding suggests that the toxin acts on the activation of rSkM1 by binding either to D1 and/or D2. TiTx gamma shifted the activation of another chimera with D2-D3-D4 from rSkM1 (HSSS) toward more hyperpolarizing potentials and had no effect on the activation of other chimeras with only D1-D3-D4 from rSkM1 (SHSS) or only D3 from rSkM1 (HHSH). Finally, a chimera in which D2 is from rSkM1 and all others domains are from hH1 (HSHH) provides further compelling support for our hypothesis. TiTx gamma shifts the activation of this chimera toward more negative potential values. Thus, TiTx gamma action on chimeras segregates with the source of D2: when D2 is from rSkM1, the toxin affects activation. We infer that D2 plays an important role in the activation process of voltage-gated Na+ channels.

Chimeric study of sodium channels from rat skeletal and cardiac muscle

Two isoforms of voltage‐dependent Na channels, cloned from rat skeletal muscle, were expressed in Xenopus oocytes. The currents of rSkM1 and rSkM2 differ functionally in 4 properties: (i) tetrodotoxin (TTX) sensitivity, (ii) μ‐conotoxin (μ‐CTX) sensitivity, (iii) amplitude of single channel currents, and (iv) rate of inactivation. rSkM1 is sensitive to both TTX and μ‐CTX. rSkM2 is resistant to both toxins. Currents of rSkM1 have a higher single channel conductance and a slower rate of inactivation than those of rSkM2. We constructed (i) chimeras by interchanging domain 1 (D1) between the two isoforms, (ii) block mutations of 22 amino acids in length that interchanged parts of the loop between transmembrane segments S5 and S6 in both D1 and D4, and (iii) point mutations in the SS2 region of this loop in D1. The TTX sensitivity could be switched between the two isoforms by the exchange of a single amino acid, tyrosine‐401 in rSkM1 and cysteine‐374 in rSkM2 in SS2 of D1. By contrast most chimeras and point mutants had an intermediate sensitivity to μ‐CTX when compared with the wild‐type channels. The point mutant rSkM1 (Y401C) had an intermediate single‐channel conductance between those of the wild‐type isoforms, whereas rSkM2 (C374Y) had a slightly lower conductance than rSkM2. The rate of inactivation was found to be determined by multiple regions of the protein, since chimeras in which D1 was swapped had intermediate rates of inactivation compared with the wild‐type isoforms.

Extrapore Residues of the S5-S6 Loop of Domain 2 of the Voltage-Gated Skeletal Muscle Sodium Channel (rSkM1) Contribute to the μ-Conotoxin GIIIA Binding Site

The tetradomain voltage-gated sodium channels from rat skeletal muscle (rSkM1) and from human heart (hH1) possess different sensitivities to the 22-amino-acid peptide toxin, mu-conotoxin GIIIA (mu-CTX). rSkM1 is sensitive (IC50 = 51.4 nM) whereas hH1 is relatively resistant (IC50 = 5700 nM) to the action of the toxin, a difference in sensitivity of >100-fold. The affinity of the mu-CTX for a chimera formed from domain 1 (D1), D2, and D3 from rSkM1and D4 from hH1 (SSSH; S indicates origin of domain is skeletal muscle and H indicates origin of domain is heart) was paradoxically increased approximately fourfold relative to that of rSkM1. The source of D3 is unimportant regarding the difference in the relative affinity of rSkM1 and hH1 for mu-CTX. Binding of mu-CTX to HSSS was substantially decreased (IC50 = 1145 nM). Another chimera with a major portion of D2 deriving form hH1 showed no detectable binding of mu-CTX (IC50 > 10 microM). These data indicate that D1 and, especially, D2 play crucial roles in forming the mu-CTX receptor. Charge-neutralizing mutations in D1 and D2 (Asp384, Asp762, and Glu765) had no effect on toxin binding. However, mutations at a neutral and an anionic site (residues 728 and 730) in S5-S6/D2 of rSkM1, which are not in the putative pore region, were found to decrease significantly the mu-CTX affinity with little effect on tetrodotoxin binding (</=1.3-fold increase in affinity). Furthermore, substitution at Asp730 with cysteine and exposure to Cd2+ or methanethiosulfonate reagents had no significant effect on sodium currents, consistent with this residue not contributing to the pore.

Calcium Functionally Uncouples the Heads of Myosin VI

This study examines the steady state activity and in vitro motility of single-headed (S1) and double-headed (HMM) myosin VI constructs within the context of two putative modes of regulation. Phosphorylation of threonine 406 does not alter either the rate of actin filament sliding or the maximal actin-activated ATPase rate of S1 or HMM constructs. Thus, we do not observe any regulation of myosin VI by phosphorylation within the motor domain. Interestingly, in the absence of calcium, the myosin VI HMM construct moves in an in vitro motility assay at a velocity that is twice that of S1 constructs, which may be indicative of movement that is not based on a “lever arm” mechanism. Increasing calcium above 10 μm slows both the rate of ADP release from S1 and HMM actomyosin VI and the rates of in vitro motility. Furthermore, high calcium concentrations appear to uncouple the two heads of myosin VI. Thus, phosphorylation and calcium are not on/off switches for myosin VI enzymatic activity, although calcium may alter the degree of processive movement for myosin VI-mediated cargo transport. Lastly, calmodulin mutants reveal that the calcium effect is dependent on calcium binding to the N-terminal lobe of calmodulin.

Lidocaine block of human heart sodium channels expressed in Xenopus oocytes

The tertiary amine lidocaine is used clinically for preventing cardiac arrhythmias, and has been widely studied on mammalian tissue. Xenopus oocytes were used as an expression system to study the effect of lidocaine on a sodium (Na) channel, derived from a full-length human heart (hH1) cDNA clone. The concentration dependence of the lidocaine block of hH1 Na current was consistent with a binding stoichiometry of 1:1. At low frequency stimulation, and at holding potentials < or = 100 mV, the IC50 was 226 microM, comparable to values found in mammalian cardiac cells. Lidocaine also shifted the steady-state inactivation of hH1 Na current to hyperpolarized potentials in a dose-dependent manner. Our experiments suggest that lidocaine block is state dependent, with high affinity for an inactivated state (KI = 11 microM) and low affinity for the resting state (KR = 3.9 mM). The quaternary amine derivative of lidocaine, QX-314, had no effect on Na current at an extracellular concentration of 1 mM.

DIFFERENCES IN THE BINDING SITES OF TWO SITE-3 SODIUM CHANNEL TOXINS

Abstract Site-3 toxins from scorpion and sea anemone bind to Na channels and selectively inhibit current decay. Anthopleurins A and B (ApA and ApB, respectively), toxins found in the venom of the sea anemone Anthopleura xanthogrammica, bind to closed states of mammalian skeletal and cardiac Na channels with differing affinities which arise from differences in first-order toxin/channel dissociation rate constants, koff. Using chimera comprising domain interchanges between channel isoforms, we examined the structural basis of this differential affinity. Toxin/channel association rates, kon, were similar for both toxins and both parental channels. Domain 4 determined koff for ApA, while ApB dissociated from all tested chimera in a cardiac-like manner. To probe this surprising difference between two such closely related toxins, we examined the interaction of chimeric channels with a form of ApB in which the two nonconserved basic residues, Arg-12 and Lys-49, were converted to the corresponding neutral amino acids from ApA. In the chimera comprising domain 1 from the cardiac muscle isoform and domains 2–4 from the skeletal muscle isoform, toxin dissociated at a rate intermediate between those of the parental channels. We conclude that the differential component of ApA binding is controlled by domain 4 and that some component of ApB binding is not shared by ApA. This additional component probably binds to an interface between channel domains and is partly mediated by toxin residues Arg-12 and Lys-49.

Regulation of Asymmetric Smooth Muscle Myosin II Molecules

The emerging view of smooth/nonmuscle myosin regulation suggests that the attainment of the completely inhibited state requires numerous weak interactions between components of the two heads and the myosin rod. To further examine the nature of the structural requirements for regulation, we engineered smooth muscle heavy meromyosin molecules that contained one complete head and truncations of the second head. These truncations eliminated the motor domain but retained two, one, or no light chains. All constructs contained 37 heptads of rod sequence. None of the truncated constructs displayed complete regulation of both ATPase and motility, reinforcing the idea that interactions between motor domains are necessary for complete regulation. Surprisingly, the rate of ADP release was slowed by regulatory light chain dephosphorylation of the truncated construct that contained all four light chains and one motor domain. These data suggest that there is a second step (ADP release) in the smooth muscle myosin-actin-activated ATPase cycle that is modulated by regulatory light chain phosphorylation. This may be part of the mechanism underlying “latch” in smooth muscle.