The pentapeptide QYNAD does not block voltage-gated sodium channels.

BACKGROUND: An endogenous pentapeptide (Gln-Tyr-Asn-Ala-Asp; QYNAD) that is present at elevated levels in human CSF from patients with demyelinating diseases has been reported to block voltage-gated sodium channels at low (10 micro M) concentrations. Objective : Because of the potential importance of sodium channel blocking activity in demyelinating disorders, this study attempted to determine the sensitivity to QYNAD of different sodium channel subtypes, including Na(v)1.6, the major sodium channel at nodes of Ranvier, and Na(v)1.2, which is expressed in axons with abnormal myelin. METHODS: Sodium channel function was assayed using patch-clamp recordings, both in heterologous expression systems and in intact neurons. RESULTS: QYNAD synthesized in 10 different batches by four different facilities failed to block sodium currents, even at concentrations as high as 500 micro M (50-fold higher than the blocking concentration originally reported). QYNAD had no effect on the currents produced by recombinant Na(v)1.2, Na(v)1.4, Na(v)1.6, and Na(v)1.7 sodium channels or on the sodium currents that are produced by native channels in adult hippocampal or dorsal root ganglion neurons. QYNAD did not interfere with conduction in the optic nerve, a myelinated fiber tract that is often affected in MS. CONCLUSIONS: These experiments do not show any sodium channel blocking effect of QYNAD. The conclusion that QYNAD contributes to the pathophysiology of inflammatory neurologic disorders by blocking voltage-gated sodium channels should therefore be viewed with caution.

Expression of Nav1.8 sodium channels perturbs the firing patterns of cerebellar Purkinje cells.

The sensory neuron specific sodium channel Na(v)1.8/SNS exhibits depolarized voltage-dependence of inactivation, slow inactivation and rapid repriming, which differentiate it from other voltage-gated sodium channels. Na(v)1.8 is normally selectively expressed at high levels in sensory ganglion neurons, but not within the CNS. However, expression of Na(v)1.8 mRNA and protein are upregulated within cerebellar Purkinje cells in animal models of multiple sclerosis (MS), and in human MS. To examine the effect of expression of Na(v)1.8 on the activity pattern of Purkinje cells, we biolistically introduced Na(v)1.8 cDNA into these cells in vitro. We report here that Na(v)1.8 can be functionally expressed at physiological levels (similar to the levels in DRG neurons where Na(v)1.8 is normally expressed) within Purkinje cells, and that its expression alters the activity of these neurons in three ways: first, by increasing the amplitude and duration of action potentials; second, by decreasing the proportion of action potentials that are conglomerate and the number of spikes per conglomerate action potential; and third, by contributing to the production of sustained, pacemaker-like impulse trains in response to depolarization. These results provide support for the hypothesis that the expression of Na(v)1.8 channels within Purkinje cells, which occurs in MS, may perturb their function.

Na(v)1.5 underlies the 'third TTX-R sodium current' in rat small DRG neurons.

In addition to slow-inactivating and persistent TTX-R Na(+) currents produced by Na(v)1.8 and Na(v)1.9 Na(+) channels, respectively, a third TTX-R Na(+) current with fast activation and inactivation can be recorded in 80% of small neurons of dorsal root ganglia (DRG) from E15 rats, but in only 3% of adult small DRG neurons. The half-time for activation, the time constant for inactivation, and the midpoints of activation and inactivation of the third TTX-R Na(+) currents are significantly different from those of Na(v)1.8 and Na(v)1.9 Na(+) currents. The estimated TTX K(i) (2.11+/-0.34 microM) of the third TTX-R Na(+) current is significantly lower than those of Na(v)1.8 and Na(v)1.9 Na(+) currents. The Cd(2+) sensitivity of third TTX-R Na(+) current is closer to cardiac Na(+) currents. A concentration of 1 mM Cd(2+) is required to completely block this current, which is significantly lower than the 5 mM required to block Na(v)1.8 and Na(v)1.9 currents. The third TTX-R Na(+) channel is not co-expressed with Na(v)1.8 and Na(v)1.9 Na(+) channels in DRG neurons of E18 rats, at a time when all three currents show comparable densities. The physiological and pharmacological profiles of the third TTX-R Na(+) current are similar to those of the cardiac Na(+) channel Na(v)1.5 and RT-PCR and restriction enzyme polymorphism analysis, show a parallel pattern of expression of Na(v)1.5 in DRG during development. Taken together, these results demonstrate that Na(v)1.5 is expressed in a developmentally regulated manner in DRG neurons and suggest that Na(v)1.5 Na(+) channel produces the third TTX-R current.

Nitric oxide blocks fast, slow, and persistent Na+ channels in C-type DRG neurons by S-nitrosylation.

C-type dorsal root ganglion (DRG) neurons express three types of Na+ currents: fast TTX-sensitive, slow TTX-resistant, and persistent TTX-resistant Na+ currents. The nitric oxide (NO) donors papa-NONOate and S-nitroso-N-acetyl-DL-penicillamine inhibit all three types of Na+ currents. The NO scavenger hemoglobin abolished the effects of papa-NONOate on Na+ currents, indicating that NO or NO-related species inhibit these Na+ currents. NO donor inhibition of all three types of Na+ currents was reversed by washout. Incubation of neurons with 8-bromo cGMP, a membrane-permeable analogue of cGMP, and cG-PKI, an inhibitor of cGMP-dependent protein kinase, had no effect on papa-NONOate-mediated Na+ current block, demonstrating that Na+ current inhibition is independent of cGMP. Alkylation of free thiols with N-ethylmaleimide prevented the actions of papa-NONOate, suggesting that NO, or a related reactive nitrogen species, modifies sulfhydryl groups on Na+ channels or a closely associated protein. Papa-NONOate-mediated block of Na+ currents is not due to a hyperpolarizing shift in steady state voltage-dependent inactivation. The absence of NO-mediated enhancement of slow inactivation in fast and slow Na+ channels indicates that NO does not inhibit fast and slow Na+ channels by facilitating the transition to a slow inactivated state. These results demonstrate that inhibition of Na+ currents is not due to the modulation of fast and slow sodium channel inactivation. Taken together, these results show that NO or NO-related products modify the sulfhydryl groups on Na+ channels and inhibit Na+ currents by blocking the channel conductance.

Glycosylation alters steady-state inactivation of sodium channel Nav1.9/NaN in dorsal root ganglion neurons and is developmentally regulated.

Na channel NaN (Na(v)1.9) produces a persistent TTX-resistant (TTX-R) current in small-diameter neurons of dorsal root ganglia (DRG) and trigeminal ganglia. Na(v)1.9-specific antibodies react in immunoblot assays with a 210 kDa protein from the membrane fractions of adult DRG and trigeminal ganglia. The size of the immunoreactive protein is in close agreement with the predicted Na(v)1.9 theoretical molecular weight of 201 kDa, suggesting limited glycosylation of this channel in adult tissues. Neonatal rat DRG membrane fractions, however, contain an additional higher molecular weight immunoreactive protein. Reverse transcription-PCR analysis did not show additional longer transcripts that could encode the larger protein. Enzymatic deglycosylation of the membrane preparations converted both immunoreactive proteins into a single faster migrating band, consistent with two states of glycosylation of Na(v)1.9. The developmental change in the glycosylation state of Na(v)1.9 is paralleled by a developmental change in the gating of the persistent TTX-R Na(+) current attributable to Na(v)1.9 in native DRG neurons. Whole-cell patch-clamp analysis demonstrates that the midpoint of steady-state inactivation is shifted 7 mV in a hyperpolarized direction in neonatal (postnatal days 0-3) compared with adult DRG neurons, although there is no significant difference in activation. Pretreatment of neonatal DRG neurons with neuraminidase causes an 8 mV depolarizing shift in the midpoint of steady-state inactivation of Na(v)1.9, making it indistinguishable from that of adult DRG neurons. Our data show that extensive glycosylation of rat Na(v)1.9 is developmentally regulated and changes a critical property of this channel in native neurons.

Contribution of Na(v)1.8 sodium channels to action potential electrogenesis in DRG neurons.

C-type dorsal root ganglion (DRG) neurons can generate tetrodotoxin-resistant (TTX-R) sodium-dependent action potentials. However, multiple sodium channels are expressed in these neurons, and the molecular identity of the TTX-R sodium channels that contribute to action potential production in these neurons has not been established. In this study, we used current-clamp recordings to compare action potential electrogenesis in Na(v)1.8 (+/+) and (-/-) small DRG neurons maintained for 2-8 h in vitro to examine the role of sodium channel Na(v)1.8 (alpha-SNS) in action potential electrogenesis. Although there was no significant difference in resting membrane potential, input resistance, current threshold, or voltage threshold in Na(v)1.8 (+/+) and (-/-) DRG neurons, there were significant differences in action potential electrogenesis. Most Na(v)1.8 (+/+) neurons generate all-or-none action potentials, whereas most of Na(v)1.8 (-/-) neurons produce smaller graded responses. The peak of the response was significantly reduced in Na(v)1.8 (-/-) neurons [31.5 +/- 2.2 (SE) mV] compared with Na(v)1.8 (+/+) neurons (55.0 +/- 4.3 mV). The maximum rise slope was 84.7 +/- 11.2 mV/ms in Na(v)1.8 (+/+) neurons, significantly faster than in Na(v)1.8 (-/-) neurons where it was 47.2 +/- 1.3 mV/ms. Calculations based on the action potential overshoot in Na(v)1.8 (+/+) and (-/-) neurons, following blockade of Ca(2+) currents, indicate that Na(v)1.8 contributes a substantial fraction (80-90%) of the inward membrane current that flows during the rising phase of the action potential. We found that fast TTX-sensitive Na(+) channels can produce all-or-none action potentials in some Na(v)1.8 (-/-) neurons but, presumably as a result of steady-state inactivation of these channels, electrogenesis in Na(v)1.8 (-/-) neurons is more sensitive to membrane depolarization than in Na(v)1.8 (+/+) neurons, and, in the absence of Na(v)1.8, is attenuated with even modest depolarization. These observations indicate that Na(v)1.8 contributes substantially to action potential electrogenesis in C-type DRG neurons.

Nav1.3 sodium channels: rapid repriming and slow closed-state inactivation display quantitative differences after expression in a mammalian cell line and in spinal sensory neurons.

Although rat brain Nav1.3 voltage-gated sodium channels have been expressed and studied in Xenopus oocytes, these channels have not been studied after their expression in mammalian cells. We characterized the properties of the rat brain Nav1.3 sodium channels expressed in human embryonic kidney (HEK) 293 cells. Nav1.3 channels generated fast-activating and fast-inactivating currents. Recovery from inactivation was relatively rapid at negative potentials (<-80 mV) but was slow at more positive potentials. Development of closed-state inactivation was slow, and, as predicted on this basis, Nav1.3 channels generated large ramp currents in response to slow depolarizations. Coexpression of beta3 subunits had small but significant effects on the kinetic and voltage-dependent properties of Nav1.3 currents in HEK 293 cells, but coexpression of beta1 and beta2 subunits had little or no effect on Nav1.3 properties. Nav1.3 channels, mutated to be tetrodotoxin-resistant (TTX-R), were expressed in SNS-null dorsal root ganglion (DRG) neurons via biolistics and were compared with the same construct expressed in HEK 293 cells. The voltage dependence of steady-state inactivation was approximately 7 mV more depolarized in SNS-null DRG neurons, demonstrating the importance of background cell type in determining physiological properties. Moreover, consistent with the idea that cellular factors can modulate the properties of Nav1.3, the repriming kinetics were twofold faster in the neurons than in the HEK 293 cells. The rapid repriming of Nav1.3 suggests that it contributes to the acceleration of repriming of TTX-sensitive (TTX-S) sodium currents that are seen after peripheral axotomy of DRG neurons. The relatively rapid recovery from inactivation and the slow closed-state inactivation kinetics of Nav1.3 channels suggest that neurons expressing Nav1.3 may exhibit a reduced threshold and/or a relatively high frequency of firing.

alpha-SNS produces the slow TTX-resistant sodium current in large cutaneous afferent DRG neurons.

In this study, we used sensory neuron specific (SNS) sodium channel gene knockout (-/-) mice to ask whether SNS sodium channel produces the slow Na(+) current ("slow") in large (>40 microm diam) cutaneous afferent dorsal root ganglion (DRG) neurons. SNS wild-type (+/+) mice were used as controls. Retrograde Fluoro-Gold labeling permitted the definitive identification of cutaneous afferent neurons. Prepulse inactivation was used to separate the fast and slow Na(+) currents. Fifty-two percent of the large cutaneous afferent neurons isolated from SNS (+/+) mice expressed only fast-inactivating Na(+) currents ("fast"), and 48% expressed both fast and slow Na(+) currents. The fast and slow current densities were 0.90 +/- 0.12 and 0.39 +/- 0.16 nA/pF, respectively. Fast Na(+) currents were blocked completely by 300 nM tetrodotoxin (TTX), while slow Na(+) currents were resistant to 300 nM TTX, confirming that the slow Na(+) currents observed in large cutaneous DRG neurons are TTX-resistant (TTX-R). Slow Na(+) currents could not be detected in large cutaneous afferent neurons from SNS (-/-) mice; these cells expressed only fast Na(+) current, and it was blocked by 300 nM TTX. The fast Na(+) current density in SNS (-/-) neurons was 1.47 +/- 0. 14 nA/pF, approximately 60% higher than the current density observed in SNS (+/+) mice (P < 0.02). A low-voltage-activated TTX-R Na(+) current ("persistent") observed in small C-type neurons is not present in large cutaneous afferent neurons from either SNS (+/+) or SNS (-/-) mice. These results show that the slow TTX-R Na(+) current in large cutaneous afferent DRG is produced by the SNS sodium channel.

Nitric oxide is an autocrine regulator of Na(+) currents in axotomized C-type DRG neurons.

In this study, we examined whether nitric oxide synthase (NOS) is upregulated in small dorsal root ganglion (DRG) neurons after axotomy and, if so, whether the upregulation of NOS modulates Na(+) currents in these cells. We identified axotomized C-type DRG neurons using a fluorescent label, hydroxystilbamine methanesulfonate and found that sciatic nerve transection upregulates NOS activity in 60% of these neurons. Fast-inactivating tetrodotoxin-sensitive (TTX-S) Na(+) ("fast") current and slowly inactivating tetrodotoxin-resistant (TTX-R) Na(+) ("slow") current were present in control noninjured neurons with current densities of 1.08 +/- 0. 09 nA/pF and 1.03 +/- 0.10 nA/pF, respectively (means +/- SE). In some control neurons, a persistent TTX-R Na(+) current was observed with current amplitude as much as approximately 50% of the TTX-S Na(+) current amplitude and 100% of the TTX-R Na(+) current amplitude. Seven to 10 days after axotomy, current density of the fast and slow Na(+) currents was reduced to 0.58 +/- 0.05 nA/pF (P < 0.01) and 0.2 +/- 0.05 nA/pF (P < 0.001), respectively. Persistent TTX-R Na(+) current was not observed in axotomized neurons. Nitric oxide (NO) produced by the upregulation of NOS can block Na(+) currents. To examine the role of NOS upregulation on the reduction of the three types of Na(+) currents in axotomized neurons, axotomized DRG neurons were incubated with 1 mM N(G)-nitro-L-arginine methyl ester (L-NAME), a NOS inhibitor. The current density of fast and slow Na(+) channels in these neurons increased to 0.82 +/- 0.08 nA/pF (P < 0.01) and 0.34 +/- 0.04 nA/pF (P < 0.05), respectively. However, we did not observe any persistent TTX-R current in axotomized neurons incubated with L-NAME. These results demonstrate that endogenous NO/NO-related species block both fast and slow Na(+) current in DRG neurons and suggest that NO functions as an autocrine regulator of Na(+) currents in injured DRG neurons.

Calcium regulates L-type Ca2+ channel expression in rat skeletal muscle cells.

Primary skeletal muscle cells were cultured in a normal- (1.8 mM) or high- (4.8 mM) Ca2+ culture medium to determine whether Ca2+ modulates the number of L-type Ca2+ channels. Skeletal myoballs cultured in a normal medium showed, when exposed to a high extracellular [Ca2+], ([Ca2+]e) a transient increase in intracellular [Ca2+] ([Ca2+]i) from a resting concentration of 60 to 160 nM. By day 3, however, when the experiments were made, [Ca2+]i no longer differed from control (pre-exposure to high Ca2+). The maximum charge movements in myoballs incubated in 1.8 and 4.8 mM were 16.4+/-1.05 (n=56) and 24.1+/-1.18 nC/microF (n=58; P<0.01), respectively, and peak Ca2+ currents at 20 mV were -10.8+/-1.09 (n=46) and -12.8+/-0.75 nA/microF (n=82), respectively (P>0.05). The tail current amplitudes in 1.8 and 4.8 mM Ca2+-treated cells were -9.3+/-1.23 and -14.2+/-1.37 nA/microF (P<0.05), respectively, at 10 mV and -15.3+/-1.76 and -23.6+/-2.02 nA/microF (P<0.05), respectively at 60 mV. The maximum binding of [3H]PN200-110 (a radioligand specific for L-type Ca2+ channel alpha1 subunits) in myoballs cultured in 1.8 and 4.8 mM [Ca2+]e was 1.34+/-0.23 and 3.2+/-0.63 pmol/mg protein (n=8; P<0.02), respectively. The increase in [Ca2+]i associated with the increases in charge movements, tail currents and the number of L-type Ca2+ channel alpha1 subunits in skeletal muscle cells cultured in high [Ca2+]e support the concept that extracellular Ca2+ influx modulates the expression of L-type Ca2+ channels in skeletal muscle cells.

Insulin-like growth factor-1 enhances rat skeletal muscle charge movement and L-type Ca2+ channel gene expression.

1. We investigated whether insulin-like growth factor-1 (IGF-1), an endogenous potent activator of skeletal muscle proliferation and differentiation, enhances L-type Ca2+ channel gene expression resulting in increased functional voltage sensors in single skeletal muscle cells. 2. Charge movement and inward Ca2+ current were recorded in primary cultured rat myoballs using the whole-cell configuration of the patch-clamp technique. Ca2+ current and maximum charge movement (Qmax) were potentiated in cells treated with IGF-1 without significant changes in their voltage dependence. Peak Ca2+ current in control and IGF-1-treated cells was -7.8 +/- 0.44 and -10. 5 +/- 0.37 pA pF-1, respectively (P < 0.01), whilst Qmax was 12.9 +/- 0.4 and 22.0 +/- 0.3 nC microF-1, respectively (P < 0.01). 3. The number of L-type Ca2+ channels was found to increase in the same preparation. The maximum binding capacity (Bmax) of the high-affinity radioligand [3H]PN200-110 in control and IGF-1-treated cells was 1.21 +/- 0.25 and 3.15 +/- 0.5 pmol (mg protein)-1, respectively (P < 0.01). No significant change in the dissociation constant for [3H]PN200-110 was found. 4. Antisense RNA amplification showed a significant increase in the level of mRNA encoding the L-type Ca2+ channel alpha1-subunit in IGF-1-treated cells. 5. This study demonstrates that IGF-1 regulates charge movement and the level of L-type Ca2+ channel alpha1-subunits through activation of gene expression in skeletal muscle cells.

Effectiveness of caloric restriction in preventing age-related changes in rat skeletal muscle.

The dihydropyridine receptor (DHPR) and ryanodine receptor (RYR1) are needed for excitation-contraction coupling in skeletal muscle. Previous studies from this laboratory have shown DHPR-RYR1 uncoupling in 33-month-old Fischer 344 x Brown Norway F1 (F344BNF1) rats fed ad libitum. The purpose of the present study is to determine whether caloric restriction prevents age-related impairments in skeletal muscle function and expression of DHPR and RyR1. Bundles of soleus and extensor digitorum longus (EDL) were studied from rats fed ad libitum and on 60 percent caloric restriction. Significant differences were found in peak twitch or tetanic tension between the ad libitum and calorie-restricted groups in soleus and EDL muscles. A significant increase in the expression of DHPR and RyR1 was observed in caloric restricted rats. These results show that calorie restriction preserves the mechanical properties of aging hind-limb skeletal muscle and maintains the level of DHPR and RyR1 in aged F344BNF1 rats fed ad libitum.

Overexpression of IGF-1 exclusively in skeletal muscle prevents age-related decline in the number of dihydropyridine receptors.

Excitation-contraction uncoupling has been identified as a mechanism underlying skeletal muscle weakness in aging mammals (sarcopenia). The basic mechanism for excitation-contraction uncoupling is a larger number of ryanodine receptors (RyR1) uncoupled to dihydropyridine receptors (DHPRs) (Delbono, O., O'Rourke, K. S., and Ettinger, W. H. (1995) J. Membr. Biol. 148, 211-222). In the present study, we used transgenic mice overexpressing human insulin-like growth factor-1 exclusively in skeletal muscle to test the hypothesis that a high concentration of IGF-1 prevents age-related decreases in DHPR number and in muscle force. Transgenic mice express 10-20-fold higher IGF-1 concentrations than nontransgenic mice at all ages (1-24 months). The number of DHPRs is 50-100% higher, and the DHPR/RyR1 ratio is 40% higher in transgenic soleus (predominantly type I fiber muscles), extensor digitorum longus (predominantly type II fiber muscles), and the pool of type I and type II fiber muscles than in nontransgenic young (6 months), adult (12 months), and old (24 months) mice. Furthermore, no age-related changes in DHPRs and the DHPR/RyR1 ratio were observed in transgenic muscles. The specific single twitch and tetanic muscle force in old transgenic soleus and extensor digitorum longus muscles are 50% higher than in old nontransgenic muscles. Taken together, these results support the concept that IGF-1- dependent prevention of age-related decline in DHPR expression is associated with stronger muscle contraction in older transgenic mice.

Caloric restriction prevents age-related decline in skeletal muscle dihydropyridine receptor and ryanodine receptor expression.

The dihydropyridine receptor (DHPR), a voltage-gated L-type Ca2+ channel, and the Ca2+ release channel/ryanodine receptor isoform-1 (RyR1) are key molecules involved in skeletal muscle excitation-contraction coupling. We have reported age-related decreases in the level of DHPR expression in fast- and slow-twitch muscles from Fisher 344 cross Brown Norway (F344BNX) rats (Renganathan, Messi and Delbono, J. Membr. Biol. 157 (1997) 247-253). Based on these studies we postulate that excitation-contraction uncoupling is a basic mechanism for the decline in muscle force with aging (Delbono, Renganathan and Messi, Muscle Nerve Suppl. 5 (1997) S88-92). In the present study, we extended our studies to older ages and we intended to prevent or retard excitation-contraction uncoupling by restricting the caloric intake of the F344BNX rats from 16 weeks of age. Three age groups, 8-, 18-, and 33-month old caloric restricted rats, were compared with ad libitum fed animals. The number of DHPR and RyR1 and DHPR/RyR1 ratio (an index of the level of receptors uncoupling) in skeletal muscles of 8-month and 18-month rats was not significantly different in either ad libitum fed or caloric restricted rats. However, the age-related decrease in the number of DHPR, RyR1 and DHPR/RyR1 ratio observed in 33-month old ad libitum fed rats was absent in 33-month old caloric restricted rats. These results suggest that caloric restriction prevents age-related decreases in the number of DHPR, RyR1 and DHPR/RyR1 ratio observed in fast- and slow-twitch rat skeletal muscles.

Up-regulation of human alpha7 nicotinic receptors by chronic treatment with activator and antagonist ligands.

This study examined the binding and functional properties of human alpha7 neuronal nicotinic acetylcholine receptors stably expressed in human embryonic kidney (HEK) 293 cells following chronic treatment with nicotinic receptor ligands. Treatment of cells with (-)-nicotine (100 microM) for 120 h increased the Bmax values of [125I]alpha-bungarotoxin binding 2.5-fold over untreated cells. This effect was concentration-dependent (EC50) = 970 microM) and a 6-fold upregulation was observed with the maximal concentration of (-)-nicotine tested. Also, treatment of cells with ligands of varying intrinsic activities including (+/-)-epibatidine, (2,4)-dimethoxybenzylidene anabaseine (GTS-21) and 1,1-dimethyl-4-phenyl piperazinium iodide (DMPP) also upregulated [125I]alpha-bungarotoxin binding. A concentration-dependent upregulation of binding sites was also observed following treatment with the alpha7 nicotinic receptor antagonist, methyllycaconitine (EC50 = 92 microM) with a maximal upregulation of about 7-fold. Functionally, the peak amplitude of the whole-cell currents recorded by fast application of (-)-nicotine after chronic treatment of cells with concentrations of (-)-nicotine (1000 microM) or methyllycaconitine (10 microM) that elicited similar increases in binding levels (3.5-fold) resulted in increases of 2-fold (505 +/- 21 pA) and 6-fold (1820 +/- 137 pA) respectively in whole cell current amplitude compared to untreated cells (267 +/- 24 pA). These studies clearly demonstrate that long-term exposure to both activator and antagonist ligands can increase the density of alpha7 nicotinic receptors and can differentially enhance nicotinic receptor function.

Overexpression of hIGF-1 exclusively in skeletal muscle increases the number of dihydropyridine receptors in adult transgenic mice.

The number of dihydropyridine receptors (DHPR) and sarcoplasmic reticulum (SR) Ca2+ release channels (RyR1) and their interaction determine the efficacy of the sarcolemmal excitation-SR Ca2+ release-contraction coupling (ECC). Both receptors play a central role in ECC as demonstrated in various animal species and muscle subtypes. In the present work we studied the effect of transgenic overexpression of human insulin-like growth factor 1 (hIGF-1) on the levels of these two Ca2+ channels in extensor digitorum longus (EDL) (fast-twitch), soleus (slow-twitch) and pool of fast- and slow-twitch muscles from adult C57BL/6 mice. Muscles from hIGF-1 transgenic mice showed a significant increase in IGF-1 concentration (20-30-fold) and in the number of DHPR (52% increase) whereas no significant change in RyR1 binding sites was detected. The differential effect on DHPR and RyR1 resulted in a 30% increase in DHPR/RyR1 ratio. Fast- and slow-twitch muscles showed 50 and 70% increase in the number of DHPR and 30 and 80% increase in DHPR/RyR1, respectively. These results support the concept that the increased autocrine/paracrine secretion of hIGF-1 exerts potent stimulatory effects on DHPR alpha1 subunit expression in adult skeletal muscle.

Regulation of mouse skeletal muscle L-type Ca2+ channel by activation of the insulin-like growth factor-1 receptor.

We investigated the modulation of the skeletal muscle L-type Ca2+ channel/dihydropyridine receptor in response to insulin-like growth factor-1 receptor (IGF-1R) activation in single extensor digitorum longus muscle fibers from adult C57BL/6 mice. The L-type Ca2+ channel activity in its dual role as a voltage sensor and a selective Ca2+-conducting pore was recorded in voltage-clamp conditions. Peak Ca2+ current amplitude consistently increased after exposure to 20 ng/ml IGF-1 (EC50 = 5.6 +/- 1.8 nM). Peak IGF-1 effect on current amplitude at -20 mV was 210 +/- 18% of the control. Ca2+ current potentiation resulted from a shift in 13 mV of the Ca2+ current-voltage relationship toward more negative potentials. The IGF-1-induced facilitation of the Ca2+ current was not associated with an effect on charge movement amplitude and/or voltage distribution. These phenomena suggest that the L-type Ca2+ channel structures involved in voltage sensing are not involved in the response to the growth factor. The modulatory effect of IGF-1 on L-type Ca2+ channel was blocked by tyrosine kinase and PKC inhibitors, but not by a cAMP-dependent protein kinase inhibitor. IGF-1-dependent phosphorylation of the L-type Ca2+ channel alpha1 subunit was demonstrated by incorporation of [gamma-32P]ATP to monolayers of adult fast-twitch skeletal muscles. IGF-1 induced phosphorylation of a protein at the 165 kDa band, corresponding to the L-type Ca2+ channel alpha1 subunit. These results show that the activation of the IGF-1R facilitates skeletal muscle L-type Ca2+ channel activity via a PKC-dependent phosphorylation mechanism.

Activation of alpha7 nicotinic acetylcholine receptor promotes survival of spinal cord motoneurons.

Spinal cord motoneurons (MNs) undergo a process of cell death during embryonic development and are the target of lethal acquired or inherited disorders, such as the amyotrophic lateral sclerosis. Therefore, the identification of mechanisms leading to MN survival is of crucial importance. Elevations in intracellular Ca2+ promote chicken MN survival during the embryonic period of naturally occurring cell death. We have recently demonstrated that the alpha7 nicotinic acetylcholine receptor (nAChR) mediates significant increases in free Ca2+ concentration at membrane potentials at which other pathways for Ca2+ influx are inactive. Although it is possible that Ca2+ influx through alpha7 nAChR promotes cell survival, the relation between alpha7 nAChR activation, cytosolic free Ca2+ and mammalian spinal cord MN survival has not been established. In the present study we have now demonstrated that Ca2+ influx through the alpha7-subunit is sufficient to rescue a significant number of cultured spinal cord MNs from programmed cell death induced by trophic factor deprivation. This is the first demonstration that neuronal nAChRs are involved in the regulation of MN survival.

L-type Ca2+ channel-insulin-like growth factor-1 receptor signaling impairment in aging rat skeletal muscle.

The present study investigates the modulation of skeletal muscle L-type Ca2+ channel receptor in response to insulin-like growth factor-1 receptor (IGF-1R) activation. Single extensor digitorum longus and multifiber preparations were isolated from 7- (young), 14- (middle-age) and 28-(old) month- Fisher 344 X Brown Norway rats. Calcium current was potentiated in fibers from young and middle-age rats due to a -13 mV shift in half-activation potential. Fibers from old animals failed to show current potentiation in response to IGF-1R activation. IGF-1 induced a ten-fold increase in the phosphorylation of the L-type Ca2+ channel alpha1 subunit in young and middle-age fibers but failed to induce phosphorylation in old fibers. Addition of 0.5 mM Ca2+ increased the IGF-1 induced phosphorylation in young and middle-age fibers three fold but not in old fibers. The tyrosine kinase inhibitor, genistein, and the PKC inhibitor peptide, 19-36, decreased IGF-1 induced phosphorylation of alpha1 subunit to 15% in young and middle-age fibers but failed to inhibit phosphorylation in old fibers. These results demonstrate that the IGF-1-L-type Ca2+ channel alpha1 subunit signaling is impaired in skeletal muscle fibers from old animals due to alterations in the trk-PKC pathway.

Dihydropyridine receptor-ryanodine receptor uncoupling in aged skeletal muscle.

The mechanisms underlying skeletal muscle functional impairment and structural changes with advanced age are only partially understood. In the present study, we support and expand our theory about alterations in sarcolemmal excitation-sarcoplasmic reticulum Ca2+ release-contraction uncoupling as a primary skeletal muscle alteration and major determinant of weakness and fatigue in mammalian species including humans. To test the hypothesis that the number of RYR1 (ryanodine receptor) uncoupled to DHPR (dihydropyridine receptor) increases with age, we performed high-affinity ligand binding studies in soleus, extensor digitorum longus (EDL) and in a pool of several skeletal muscles consisting of a mixture of fast- and slow-twitch muscle fibers in middle-aged (14-month) and old (28-months) Fisher 344 Brown Norway F1 hybrids rats. The number of DHPR, RYR1, the coupling between both receptors expressed as the DHPR/RYR1 maximum binding capacity, and their dissociation constant for high-affinity ligands were measured. The DHPR/RYR1 ratio was significantly reduced in the three groups of muscles (pool: 1.03 +/- 0.15 and 0.80 +/- 0.11, soleus: 0.44 +/- 0. 12 and 0.26 +/- 0.10, and EDL: 0.95 +/- 0.14 and 0.68 +/- 0.10, for middle-aged and old muscles, respectively). These data support the concept that DHPR-RYR1 uncoupling results in alterations in the voltage-gated sarcoplasmic reticulum Ca2+ release mechanism, decreases in myoplasmic Ca2+ elevation in response to sarcolemmal depolarization, reduced Ca2+ supply to contractile proteins and reduced contraction force with aging.