Muscle and motor-skill dysfunction in a K+ channel-deficient mouse are not due to altered muscle excitability or fiber type but depend on the genetic background

The voltage-gated K+ channel Kv3.1 is expressed in skeletal muscle and in GABAergic interneurons in the central nervous system. Hence, the absence of Kv3.1 K+ channels may lead to a phenotype of myogenic or neurogenic origin, or both. Kv3.1-deficient (Kv3.1-/-) 129/Sv mice display altered contractile properties of their skeletal muscles and show poor performance on a rotating rod. In contrast, Kv3.1-/- mice on the (129/Sv x C57BL/6)F1 background display normal muscle properties and perform like wild-type mice. The correlation of poor performance on the rotating rod with altered muscle properties supports the notion that the skeletal muscle dysfunction in Kv3.1-/- 129/Sv mice may be responsible for the impaired motor skills on the rotating rod. Surprisingly, we did not find major differences between wild-type and Kv3.1-/- 129/Sv skeletal muscles in either the resting or action potential, the delayed-rectifier potassium conductance (gK) or the distribution of fast and slow muscle fibers. These findings suggest that the Kv3.1 K+ channel may not play a major role in the intrinsic excitability of skeletal muscle fibers although its absence leads to slower contraction and relaxation and to smaller forces in muscles of 129/Sv Kv3.1-/- mice.

Increased gamma- and decreased delta-oscillations in a mouse deficient for a potassium channel expressed in fast-spiking interneurons

Kv3.1 is a voltage-gated, fast activating/deactivating potassium (K(+)) channel with a high-threshold of activation and a large unit conductance. Kv3.1 K(+) channels are expressed in fast-spiking, parvalbumin-containing interneurons in cortex, hippocampus, striatum, the thalamic reticular nucleus (TRN), and in several nuclei of the brain stem. A high density of Kv3.1 channels contributes to short-duration action potentials, fast afterhyperpolarizations, and brief refractory periods enhancing the capability in these neurons for high-frequency firing. Kv3.1 K(+) channel expression in the TRN and cortex also suggests a role in thalamocortical and cortical function. Here we show that fast gamma and slow delta oscillations recorded from the somatomotor cortex are altered in the freely behaving Kv3.1 mutant mouse. Electroencephalographic (EEG) recordings from homozygous Kv3.1(-/-) mice show a three- to fourfold increase in both absolute and relative spectral power in the gamma frequency range (20-60 Hz). In contrast, Kv3.1-deficient mice have a 20-50% reduction of power in the slow delta range (2-3 Hz). The increase in gamma power is most prominent during waking in the 40- to 55-Hz range, whereas the decrease in delta power occurs equally across all states of arousal. Our findings suggest that Kv3. 1-expressing neurons are involved in the generation and maintenance of cortical fast gamma and slow delta oscillations. Hence the Kv3. 1-mutant mouse could serve as a model to study the generation and maintenance of fast gamma and slow delta rhythms and their involvement in behavior and cognition.

Narcolepsy in orexin knockout mice: molecular genetics of sleep regulation

Neurons containing the neuropeptide orexin (hypocretin) are located exclusively in the lateral hypothalamus and send axons to numerous regions throughout the central nervous system, including the major nuclei implicated in sleep regulation. Here, we report that, by behavioral and electroencephalographic criteria, orexin knockout mice exhibit a phenotype strikingly similar to human narcolepsy patients, as well as canarc-1 mutant dogs, the only known monogenic model of narcolepsy. Moreover, modafinil, an anti-narcoleptic drug with ill-defined mechanisms of action, activates orexin-containing neurons. We propose that orexin regulates sleep/wakefulness states, and that orexin knockout mice are a model of human narcolepsy, a disorder characterized primarily by rapid eye movement (REM) sleep dysregulation.

Altered outward K(+) currents in Drosophila larval neurons of memory mutants rutabaga and amnesiac

K(+) currents in cultured Drosophila larval neurons have been classified into four categories according to their inactivation time constants, relative amplitude, and response to K(+) channel blockers 4-AP and tetraethylammonium. The percentage (65%) of neurons displaying K(+) currents which were reduced to 30% in amplitude by 5 mM cyclic adenosine monophosphate (cAMP) analog 8-bromo-cAMP in both Drosophila memory mutants rutabaga (rut) and amnesiac (amn) was significantly larger than that (50%) in wild type. This initial characterization provides evidence for altered K(+) currents in both rut and amn mutants. Arachidonic acid, a specifical inhibitor of Kv4 family (shal) K(+) channels, was found to inhibit K(+) currents in cultured Drosophila neurons, suggesting the presence of shal channels in these neurons.

Sympathetic axons surround neuropeptide-negative axotomized sensory neurons

Nerve injury can lead to sympathetically dependent neuropathic pain. A possible site of sympathetic-sensory interaction is the dorsal root ganglion (DRG), where sympathetic axons form pericellular 'baskets' around a subpopulation of DRG neurons. Since these structures possibly represent functional units of sympathetic pain, we attempted to characterize the neuropeptidergic phenotype of basketed DRG neurons. We performed double-labeling immunohistochemistry for tyrosine hydroxylase and neuropeptides on DRG sections, 2 weeks following L5 spinal nerve ligation (a well-characterized animal model of sympathetic pain). We found that basketed DRG neurons typically do not contain substance P, calcitonin gene-related peptide, galanin, neuropeptide tyrosine, or vasoactive intestinal polypeptide, and we conclude that if sympathetic baskets contribute to neuropathic pain, the involvement of these neuropeptides is unimportant.

A new pharyngitis model using capsaicin in rats

1. Application of capsaicin solution onto the rat pharyngeal mucosa caused a well-reproducible increase in vascular permeability in the pharynx. 2. Capsaicin-induced pharyngeal inflammation was unaffected by a histamine H1 blocker and non-steroidal anti-inflammatory agents, whereas dexamethasone was effective in its inhibition. 3. FK224, a dual antagonist of tachykinin NK1 and NK2 receptors, and FK888, a selective antagonist of NK1 receptor, significantly inhibited capsaicin-induced plasma exudation in the pharynx. 4. In capsaicinized animals, the application of capsaicin solution in the pharyngeal mucosa did not induce pharyngitis. 5. These results suggest that the mechanism of the capsaicin-induced pharyngitis primarily involves tachykinins.

Dystrobrevin deficiency at the sarcolemma of patients with muscular dystrophy

Mutations in the genes encoding dystrophin or dystrophin-associated proteins are responsible for Duchenne muscular dystrophy or various forms of limb-girdle muscular dystrophies respectively. We have recently cloned the gene for the murine 87 kDa postsynaptic protein dystrobrevin, a dystrophin-associated protein. Anti-dystrobrevin antibodies stain the sarcolemma in normal skeletal muscle indicating that dystrobrevin co-localises with dystrophin and the dystrophin-associated protein complex. By contrast, dystrobrevin membrane staining is severely reduced in muscles of Duchenne muscular dystrophy patients, consistent with dystrobrevin being a dystrophin-associated protein. Interestingly, dystrobrevin staining at the sarcolemma is dramatically reduced in patients with limb-girdle muscular dystrophy arising from the loss of one or all of the sarcoglycan components. Normal dystrobrevin staining is observed in patients with other forms of limb-girdle muscular dystrophy where dystrophin and the rest of the dystrophin-associated protein complex are normally expressed and in other neuromuscular disorders. Our results show that dystrobrevin-deficiency is a generic feature of dystrophies linked to dystrophin and the dystrophin-associated proteins. This is the first indication that a cytoplasmic component of the dystrophin-associated protein complex may be involved in the pathogenesis of limb-girdle muscular dystrophy.

Pleiotropic effects of a disrupted K+ channel gene: reduced body weight, impaired motor skill and muscle contraction, but no seizures

To investigate the roles of K+ channels in the regulation and fine-tuning of cellular excitability, we generated a mutant mouse carrying a disrupted gene for the fast activating, voltage-gated K+ channel Kv3.1. Kv3.1-/- mice are viable and fertile but have significantly reduced body weights compared with their Kv3.1+/- littermates. Wild-type, heterozygous, and homozygous Kv3.1 channel-deficient mice exhibit similar spontaneous locomotor and exploratory activity. In a test for coordinated motor skill, however, homozygous Kv3.1-/- mice perform significantly worse than their heterozygous Kv3.1+/- or wild-type littermates. Both fast and slow skeletal muscles of Kv3.1-/- mice are slower to reach peak force and to relax after contraction, consequently leading to tetanic responses at lower stimulation frequencies. Both mutant muscles generate significantly smaller contractile forces during a single twitch and during tetanic conditions. Although Kv3.1-/- mutants exhibit a normal auditory frequency range, they show significant differences in their acoustic startle responses. Contrary to expectation, homozygous Kv3.1-/- mice do not have increased spontaneous seizure activity.

Capsaicin-induced inhibition of mitogen and interleukin-2-stimulated T cell proliferation: its reversal by in vivo substance P administration

The direct and indirect interaction between the nervous and the immune systems was evaluated in the rat using the neurotoxin capsaicin. Capsaicin treatment of neonatal rats (50 mg/kg at 2 days of age), results in a marked inhibition of mitogen and hrIL-2-induced cell proliferation both in the spleen and peripheral blood. Inhibition is already evident on day 15 after treatment and persists until day 90 in the spleen; at this time a return to control levels is observed in peripheral blood. The inhibition of proliferative response strongly correlates with a decreased number of CD5+ and CD4+ T cells as evaluated by immunofluorescence and FACS analysis. Moreover, continuous in vivo SP administration stimulates mitogen and hrIL-2-induced proliferative response and completely reverts the capsaicin-induced inhibition of lymphocyte proliferation in the spleen.

Neuropeptide deficits in schizophrenia vs. Alzheimer's disease cerebral cortex

Neuropeptide concentrations were determined in the postmortem cerebral cortex from 19 cognitive-impaired schizophrenics, 4 normal elderly subjects, 4 multi-infarct dementia (MID) cases, and 13 Alzheimer's disease (AD) patients. Only AD patients met criteria for AD. The normal elderly and MID cases were combined into one control group. Somatostatin concentrations were reduced in both schizophrenia and AD. Neuropeptide Y concentrations were reduced only in schizophrenia, and corticotropin-releasing hormone concentrations were primarily reduced in AD. Concentrations of vasoactive intestinal polypeptide and cholecystokinin also were reduced in schizophrenia, although not as profoundly as somatostatin or neuropeptide Y. In AD, cholecystokinin and vasoactive intestinal peptide were unchanged. Neuropeptide deficits in schizophrenics were more pronounced in the temporal and frontal lobes than in the occipital lobe. The mechanisms underlying these deficits in schizophrenia and AD are likely distinct. In schizophrenia, a common neural element, perhaps the cerebral cortical gaba-aminobutyric acid (GABA)-containing neuron, may underlie these deficits.

Disappearance of actin-binding protein, drebrin, from hippocampal synapses in Alzheimer's disease

The actin-binding protein drebrin is localized in postsynaptic terminals in adult brain and is considered to be related to synaptic plasticity. Immunocytochemical study demonstrated that widespread drebrin immunoreactivity was observed in hippocampal formations of control human brains, while Alzheimer's disease (AD) brains showed remarkable reductions in this immunoreactivity. Western blot analysis demonstrated that drebrin E (116kD) as well as drebrin A (125 kD) presented in adult human brains, and that these isoforms were decreased in parallel in AD brains. On the other hand, synaptic vesicle-specific 38-kD protein (SVP-38), a presynaptic marker was not so changed in AD brains in comparison with control brains by both techniques. These findings suggest that drebrin E and A in the adult human brain may be co-localized in postsynaptic terminals, and that drebrin may be more sensitive as a marker of synaptic damage than SVP-38, and that the disappearance of drebrin may contribute to the pathogenesis of memory disturbance in AD.

A novel neuropeptide, pituitary adenylate cyclase-activating polypeptide (PACAP), in human intestine: evidence for reduced content in Hirschsprung's disease

A novel neuropeptide, pituitary adenylate cyclase-activating polypeptide (PACAP), exhibits sequence homology with vasoactive intestinal polypeptide (VIP) and occurs in the mammalian brain, lung and gut. The distribution of PACAP in ganglionic and aganglionic portions of the large intestine of patients with Hirschsprung's disease was examined by immunohistochemistry and radioimmunoassay. PACAP-immunoreactive nerve fibers were distributed in all layers of the ganglionic and aganglionic segments of the intestine, although they were less numerous in the latter, and PACAP-immunoreactive nerve cell bodies were seen in the ganglionic portion of the intestine. The concentration of immunoreactive PACAP was lower in the aganglionic than in the ganglionic segment of the intestinal wall. PACAP and VIP were found to coexist in both ganglionic and aganglionic segments of the intestine. Apparently, PACAP participates in the regulation of gut motility. The scarcer PACAP innervation of the aganglionic segment may contribute to the defect in intestinal relaxation seen in patients with Hirschsprung's disease.

Neuronal cells are deficient in loading peptides onto MHC class I molecules

Virally infected neurons avoid destruction by cytotoxic T lymphocytes (CTLs) by failing to express major histocompatibility complex (MHC) class I molecules. Like neurons in vivo and in primary culture, the OBL21 neuronal cell line expressed barely detectable levels of MHC class I molecules. This correlated with very low levels of mRNAs for the MHC class I heavy chains (alpha C). OBL21 cells also fail to provide MHC class I molecules with the peptides necessary for their efficient assembly and transport to the cell surface. This function can be restored by treatment with interferon-gamma (IFN-gamma). The mRNA for peptide transporters HAM1 and HAM2 was not detectable in OBL21 neuronal cells, but was induced by IFN-gamma treatment. Hence, the ability of neurons to evade CTL-mediated killing results from expression at low levels of the MHC class I alpha C, the peptide transporters HAM1 and HAM2, and possibly other genes of the peptide-loading machinery.

Sensory nerve depletion potentiates inhibitory non-adrenergic, non-cholinergic nerves in guinea-pig airways

The effect of sensory neuropeptide depletion by systemic capsaicin pretreatment was studied both on inhibitory non-adrenergic, non-cholinergic responses elicited to electrical field stimulation and on bronchodilator responses to vasoactive intestinal peptide (the putative transmitter of these nerves), in guinea-pig trachea. Capsaicin pretreatment enhanced the relaxation responses induced by both electrical field stimulation and vasoactive intestinal peptide, whereas these responses were not significantly increased in vehicle-pretreated or in untreated animals. The bronchodilator response to isoprenaline was unaffected by capsaicin pretreatment. Sensory neuropeptide depletion therefore augments both inhibitory non-adrenergic, non-cholinergic responses and responses to exogenous vasoactive intestinal peptide, suggesting an effect on vasoactive intestinal peptide receptors.