Jahan Dadgar

A Novel Nociceptor Signaling Pathway Revealed in Protein Kinase C ε Mutant Mice

Abstract There is great interest in discovering new targets for pain therapy since current methods of analgesia are often only partially successful. Although protein kinase C (PKC) enhances nociceptor function, it is not known which PKC isozymes contribute. Here, we show that epinephrine-induced mechanical and thermal hyperalgesia and acetic acid–associated hyperalgesia are markedly attenuated in PKCe mutant mice, but baseline nociceptive thresholds are normal. Moreover, epinephrine-, carrageenan-, and nerve growth factor– (NGF-) induced hyperalgesia in normal rats, and epinephrine-induced enhancement of tetrodotoxin-resistant Na + current (TTX-R I Na ) in cultured rat dorsal root ganglion (DRG) neurons, are inhibited by a PKCe-selective inhibitor peptide. Our findings indicate that PKCe regulates nociceptor function and suggest that PKCe inhibitors could prove useful in the treatment of pain.

Prkcz null mice show normal learning and memory

Protein kinase M-ζ (PKM-ζ) is a constitutively active form of atypical protein kinase C that is exclusively expressed in the brain and implicated in the maintenance of long-term memory. Most studies that support a role for PKM-ζ in memory maintenance have used pharmacological PKM-ζ inhibitors such as the myristoylated zeta inhibitory peptide (ZIP) or chelerythrine. Here we use a genetic approach and target exon 9 of the Prkcz gene to generate mice that lack both protein kinase C-ζ (PKC-ζ) and PKM-ζ (Prkcz−/− mice). Prkcz−/− mice showed normal behaviour in a cage environment and in baseline tests of motor function and sensory perception, but displayed reduced anxiety-like behaviour. Notably, Prkcz−/− mice did not show deficits in learning or memory in tests of cued fear conditioning, novel object recognition, object location recognition, conditioned place preference for cocaine, or motor learning, when compared with wild-type littermates. ZIP injection into the nucleus accumbens reduced expression of cocaine-conditioned place preference in Prkcz−/− mice. In vitro, ZIP and scrambled ZIP inhibited PKM-ζ, PKC-ι and PKC-ζ with similar inhibition constant (Ki) values. Chelerythrine was a weak inhibitor of PKM-ζ (Ki = 76 μM). Our findings show that absence of PKM-ζ does not impair learning and memory in mice, and that ZIP can erase reward memory even when PKM-ζ is not present.

Energy-driven uptake of N-methyl-4-phenylpyridine by brain mitochondria mediates the neurotoxicity of MPTP

The oxidation of NAD+-linked substrates by rat brain mitochondria is completely inhibited by pre-incubation with 0.5 mM N-methyl-4-phenylpyridine (MPP+). The effect is dependent on the integrity of the mitochondria because far higher concentrations of MPP+ are required to inhibit NADH oxidation in inverted mitochondria or isolated inner membrane preparations. The reason for this difference in behavior has been traced to a novel system for the uptake of MPP+ into mitochondria against a concentration gradient. The uptake system is energized by the transmembrane potential, as shown by the fact that valinomycin plus K+, which collapses this gradient, abolishes MPP+ uptake, while agents which collapse the proton gradient have no effect on the process. If an uncoupler is added to mitochondria preloaded with MPP+, efflux of the latter occurs with the concentration gradient. The uptake system has been studied in liver, whole brain, cortex, and midbrain preparations from rats. It may be readily distinguished from the synaptic dopamine reuptake system, since the former is blocked by uncouplers and respiratory inhibitors, but not by dopamine or mazindol, whereas the synaptic system is blocked by mazindol and competitively inhibited by dopamine but is not affected by respiratory inhibitors or uncouplers. Energy-driven uptake of MPP+ by brain mitochondria may be a crucial step in the complex sequence of events leading to the neurotoxic actions of its precursor, MPTP.

Cortical activation of accumbens hyperpolarization-active NMDARs mediates aversion-resistant alcohol intake

Compulsive drinking despite serious adverse medical, social and economic consequences is a characteristic of alcohol use disorders in humans. Although frontal cortical areas have been implicated in alcohol use disorders, little is known about the molecular mechanisms and pathways that sustain aversion-resistant intake. Here, we show that nucleus accumbens core (NAcore) NMDA-type glutamate receptors and medial prefrontal (mPFC) and insula glutamatergic inputs to the NAcore are necessary for aversion-resistant alcohol consumption in rats. Aversion-resistant intake was associated with a new type of NMDA receptor adaptation, in which hyperpolarization-active NMDA receptors were present at mPFC and insula but not amygdalar inputs in the NAcore. Accordingly, inhibition of Grin2c NMDA receptor subunits in the NAcore reduced aversion-resistant alcohol intake. None of these manipulations altered intake when alcohol was not paired with an aversive consequence. Our results identify a mechanism by which hyperpolarization-active NMDA receptors under mPFC- and insula-to-NAcore inputs sustain aversion-resistant alcohol intake.

Protein Kinase Cδ Mediates Ethanol-induced Up-regulation of L-type Calcium Channels

Brief ethanol exposure inhibits L-type, voltage-gated calcium channels in neural cells, whereas chronic exposure increases the number of functional channels. In PC12 cells, this adaptive response is mediated by protein kinase C (PKC), but the PKC isozyme responsible is unknown. Since chronic ethanol exposure increases expression of PKCδ and PKCε, we investigated the role these isozymes play in up-regulation of L-type channels by ethanol. Incubation with the PKC inhibitor GF 109203X or expression of a PKCδ fragment that inhibits phorbol ester-induced PKCδ translocation largely prevented ethanol-induced increases in dihydropyridine binding and K+-stimulated 45Ca2+uptake. A corresponding PKCε fragment had no effect on this response. These findings indicate that PKCδ mediates up-regulation of L-type channels by ethanol. Remaining responses to ethanol in cells expressing the PKCδ fragment were not inhibited by GF 109203X, indicating that PKCδ-independent mechanisms also contribute. PKCδ overexpression increased binding sites for dihydropyridine and L-channel antagonists, but did not increase K+-stimulated45Ca2+ uptake, possibly because of homeostatic responses that maintain base-line levels of channel function. Since L-type channels modulate drinking behavior and contribute to neuronal hyperexcitability during alcohol withdrawal, these findings suggest an important role for PKCδ in alcohol consumption and dependence.

Ethanol Regulates Calcium Channel Subunits by Protein Kinase C δ-dependent and -independent Mechanisms

Chronic exposure to ethanol increases the number of functional L-type voltage-gated calcium channels in neural cells. In PC12 cells, this adaptive response is mediated by protein kinase C δ (PKCδ), but the mechanisms by which this occurs are not known. Since expression of several different calcium channel subunits can increase the abundance of functional L-type channels, we sought to identify which subunits are regulated by ethanol. Incubation of PC12 cells with 120–150 mm ethanol for 6 days increased levels of α1C, α2, and β1b subunit immunoreactivity in cell membranes and selectively increased the abundance of mRNA encoding the α1C-1 splice variant of α1C. In cells expressing a fragment of PKCδ (δV1) that selectively inhibits PKCδ, there was no increase in membrane-associated α1C, α2, and β1b immunoreactivity following chronic ethanol exposure. However, ethanol still increased levels of α1C-1 mRNA in these cells. These results indicate that ethanol increases the abundance of L-type channels by at least two mechanisms; one involves increases in mRNA encoding a splice variant of α1Cand the other is post-transcriptional, rate-limiting, and requires PKCδ.

A Transgenic Rat for Investigating the Anatomy and Function of Corticotrophin Releasing Factor Circuits

Corticotrophin-releasing factor (CRF) is a 41 amino acid neuropeptide that coordinates adaptive responses to stress. CRF projections from neurons in the central nucleus of the amygdala (CeA) to the brainstem are of particular interest for their role in motivated behavior. To directly examine the anatomy and function of CRF neurons, we generated a BAC transgenic Crh-Cre rat in which bacterial Cre recombinase is expressed from the Crh promoter. Using Cre-dependent reporters, we found that Cre expressing neurons in these rats are immunoreactive for CRF and are clustered in the lateral CeA (CeL) and the oval nucleus of the BNST. We detected major projections from CeA CRF neurons to parabrachial nuclei and the locus coeruleus, dorsal and ventral BNST, and more minor projections to lateral portions of the substantia nigra, ventral tegmental area, and lateral hypothalamus. Optogenetic stimulation of CeA CRF neurons evoked GABA-ergic responses in 11% of non-CRF neurons in the medial CeA (CeM) and 44% of non-CRF neurons in the CeL. Chemogenetic stimulation of CeA CRF neurons induced Fos in a similar proportion of non-CRF CeM neurons but a smaller proportion of non-CRF CeL neurons. The CRF1 receptor antagonist R121919 reduced this Fos induction by two-thirds in these regions. These results indicate that CeL CRF neurons provide both local inhibitory GABA and excitatory CRF signals to other CeA neurons, and demonstrate the value of the Crh-Cre rat as a tool for studying circuit function and physiology of CRF neurons.

PKCε phosphorylation of the sodium channel NaV1.8 increases channel function and produces mechanical hyperalgesia in mice

Mechanical hyperalgesia is a common and potentially disabling complication of many inflammatory and neuropathic conditions. Activation of the enzyme PKCε in primary afferent nociceptors is a major mechanism that underlies mechanical hyperalgesia, but the PKCε substrates involved downstream are not known. Here, we report that in a proteomic screen we identified the NaV1.8 sodium channel, which is selectively expressed in nociceptors, as a PKCε substrate. PKCε-mediated phosphorylation increased NaV1.8 currents, lowered the threshold voltage for activation, and produced a depolarizing shift in inactivation in wild-type - but not in PKCε-null - sensory neurons. PKCε phosphorylated NaV1.8 at S1452, and alanine substitution at this site blocked PKCε modulation of channel properties. Moreover, a specific PKCε activator peptide, ψεRACK, produced mechanical hyperalgesia in wild-type mice but not in Scn10a-/- mice, which lack NaV1.8 channels. These studies demonstrate that NaV1.8 is an important, direct substrate of PKCε that mediates PKCε-dependent mechanical hyperalgesia.

Chronic ethanol exposure induces an N-type calcium channel splice variant with altered channel kinetics

Chronic ethanol exposure increases the density of N‐type calcium channels in brain. We report that ethanol increases levels of mRNA for a splice variant of the N channel specific subunit α12.2 that lacks exon 31a. Whole cell recordings demonstrated an increase in N‐type current with a faster activation rate and a shift in activation to more negative potentials after chronic alcohol exposure, consistent with increased abundance of channels containing this variant. These results identify a novel mechanism whereby chronic ethanol exposure can increase neuronal excitability by altering levels of channel splice variants.

PKCε phosphorylates α4β2 nicotinic ACh receptors and promotes recovery from desensitization

Nicotinic (ACh) receptor recovery from desensitization is modulated by PKC, but the PKC isozymes and the phosphorylation sites involved have not been identified. We investigated whether PKCε phosphorylation of α4β2 nAChRs regulates receptor recovery from desensitization.