Streptozocin-induced neuropathy is associated with altered expression of voltage-gated calcium channel subunit mRNAs in rat dorsal root ganglion neurones.

Voltage-gated calcium channels (VGCCs) within sensory neurones are believed to perform an important role in neuropathic pain. In the present study we examine the changes in VGCC mRNA which occur following streptozocin- (STZ) induced diabetic neuropathy using in situ hybridization. STZ caused a significant increase in alpha(2)delta(1), alpha(2)delta(2), and alpha(2)delta(3) mRNA levels in all neuronal cell types. Similarly, mRNA levels of alpha(1F), alpha(1I), and alpha(1S) were increased in all cell types studied whilst alpha(1A) and alpha(1G) mRNAs were specifically upregulated in medium and large diameter neurones. In conclusion, we demonstrate that the induction of diabetic neuropathy is associated with dramatic changes in the expression of VGCCs.

Expression of voltage-gated calcium channel subunits in rat dorsal root ganglion neurons.

In the present study, we have used in situ hybridisation to examine the distribution of calcium channel subunits in rat dorsal root ganglion (DRG) neurons. Within DRG neurons, the calcium channel alpha subunit mRNAs alpha(1A), alpha(1B), alpha(1C), alpha(1D), alpha(1E), alpha(1I) and alpha(1S) were readily detected in small (<25 microm), medium (25-45 microm) and large (>45 microm) diameter neurons. alpha(1F) was present at very low levels in these neurons whilst alpha(1G) was virtually undetectable. The calcium channel auxiliary subunits alpha(2)delta(1) and alpha(2)delta(2) showed a complementary pattern of distribution to that of alpha(2)delta(3) in DRG neurons. alpha(2)delta(1) and alpha(2)delta(2) transcripts were expressed predominantly in small c-type sensory neurons and were present at lower levels in large Abeta-type sensory neurons. In contrast, alpha(2)delta(3) mRNA was present in high quantities in the large-diameter cells but was expressed at lower levels in small-diameter neurons of the DRG. The present study provides an insight into the molecular profile of calcium channel alpha(1) and alpha(2)delta subunits in the neurons responsible for transmitting sensory information.

Effect of cysteine substitutions on the topology of the S4 segment of the Shaker potassium channel: implications for molecular models of gating.

1. The gating properties of voltage-gated potassium channels are largely determined by the amino acid sequence of their S4 segments. To investigate the nature of S4 movement during gating, we introduced single cysteines into the S4 segment of the Shaker potassium channel and expressed the mutants in Xenopus oocytes. We then measured the conductance-voltage (g-V) relationships and the rate and the voltage dependence of movement of the engineered cysteines, using p-chloromercuribenzene sulphonate (pCMBS) as a probe. 2. Mutation of charged residues at positions 362, 365 and 368, but not the uncharged residues (positions 360, 361, 363, 364 and 366), to cysteines shifted the g-V relationships to more positive potentials. Mutant channels in which cysteines replaced the charged residues at positions 362 and 365 (R362C and R365C) reacted faster with pCMBS than those in which cysteines were introduced in place of uncharged residues at positions 360 and 361 (I360C and L361C). Furthermore, the R365C mutant channel reacted with pCMBS even at hyperpolarised (-120 mV) potentials. Currents expressed by the doubly mutated R365S/V367C and R368S/V367C channels, but not the singly mutated V367C channel, were inhibited by pCMBS. Moreover, the R368C mutant channel was also affected by pCMBS. 3. Voltage dependence of block by pCMBS (2 min exposure) was steeper for L366C than for L361C and V363C mutant channels (effective charge 2.19, 1. 41 and 1.45, respectively). The voltage dependence of the pCMBS effect was also shifted to more depolarising potentials the deeper in the membrane the position of the residue mutated to cysteine (voltages for half-maximal effect -107, -94 and -73 mV for positions 361, 363 and 366, respectively). 4. Our data show firstly that charge-neutralising mutations in S4 alter the topology of this region such that the membrane-spanning portion of S4 is reduced. Secondly, our data for the other mutant channels suggest that S4 might move in at least two sequential steps, and can move up to its maximal limit even at the resting potential of the cell.

Measurement of the movement of the S4 segment during the activation of a voltage-gated potassium channel.

Voltage-gated ion channels contain a positively charged transmembrane segment termed S4. Recent evidence suggests that depolarisation of the membrane potential causes this segment to undergo conformational changes that, in turn, lead to the opening of the channel pore. In order to define these conformational changes in structural terms, we have introduced single cysteine substitutions into the S4 segment of the prototypical Shaker K+ channel at various positions and expressed the mutants in Xenopus oocytes. The cells were depolarised to induce K+ currents and the effect of application of 100 microM parachloromercuribenzenesulphonate (PCMBS) on these currents was examined by the two-electrode voltage-clamp technique. PCMBS inhibited K+ currents elicited by mutants L358C, L361C, V363C and L366C, but not those by V367C and S376C. Since PCMBS is a membrane-impermeable cysteine-modifying reagent, the data suggest that depolarisation must have caused the S4 segment to move out of the lipid bilayer into the extracellular phase rendering the residues at positions 358, 361, 363 and 366 susceptible to PCMBS attack. The lack of effect of PCMBS on V367C suggests that the exposure of S4 terminates at L366. Detailed analysis of L361C mutant revealed that the S4 movement can occur even below the resting potential of the cell, at which potential voltage-gated K+ channels are normally in a non-conducting closed state.