The stretch-inactivated channel, a vanilloid receptor variant, is expressed in small-diameter sensory neurons in the rat.

Exposure to hypertonic conditions is known to produce pain and activate small-diameter sensory neurons. Recently, the vanilloid receptor variant and stretch-inactivated ion channel (SIC) was cloned and shown to mediate an inward current in response to cell shrinkage. Since other vanilloid receptors have been previously shown to mediate nociception, we investigated whether SIC is expressed in sensory neurons. Using reverse transcription-polymerase chain reaction and in situ hybridization techniques, we identified SIC in the neurons of dorsal root and trigeminal ganglia. Furthermore, SIC was found to be present almost exclusively in the small-diameter sensory neurons, which includes the nociceptive population. Since SIC is activated by cell shrinkage, it may participate in the mediation of pain produced by hypertonic stimuli.

Molecular cloning of an N-terminal splice variant of the capsaicin receptor. Loss of N-terminal domain suggests functional divergence among capsaicin receptor subtypes.

Recently a cDNA clone, vanilloid receptor subtype-1 (VR1), was isolated and found to encode an ion channel that is activated by both capsaicin, the pain producing compound in chili peppers, and by noxious thermal stimuli. Subsequently, two related cDNAs have been isolated, a stretch inactivating channel with mechanosensitive properties and a vanilloid receptor-like protein that is responsive to high temperatures (52-53 degrees C). Here, we report the isolation of a vanilloid receptor 5'-splice variant (VR.5'sv) which differs from VR1 by elimination of the majority of the intracellular N-terminal domain and ankyrin repeat elements. Both VR.5'sv and VR1 mRNA were shown to be expressed in tissues reportedly responsive to capsaicin including dorsal root ganglion, brain, and peripheral blood mononuclear cells. Functional expression of VR.5'sv in Xenopus oocytes and mammalian cells showed no sensitivity to capsaicin, the potent vanilloid resiniferatoxin, hydrogen ions (pH 6.2), or noxious thermal stimuli (50 degrees C). Since VR.5'sv is otherwise identical to VR1 throughout its transmembrane spanning domains and C-terminal region, these results support the hypothesis that the N-terminal intracellular domain is essential for the formation of functional receptors activated by vanilloid compounds and noxious thermal stimuli.

Functional screening of 2 Mb of human chromosome 21q22.2 in transgenic mice implicates minibrain in learning defects associated with Down syndrome.

Using Down syndrome as a model for complex trait analysis, we sought to identify loci from chromosome 21q22.2 which, when present in an extra dose, contribute to learning abnormalities. We generated low-copy-number transgenic mice, containing four different yeast artificial chromosomes (YACs) that together cover approximately 2 megabases (Mb) of contiguous DNA from 21q22.2. We subjected independent lines derived from each of these YAC transgenes to a series of behavioural and learning assays. Two of the four YACs caused defects in learning and memory in the transgenic animals, while the other two YACs had no effect. The most severe defects were caused by a 570-kb YAC; the interval responsible for these defects was narrowed to a 180-kb critical region as a consequence of YAC fragmentation. This region contains the human homologue of a Drosophila gene, minibrain, and strongly implicates it in learning defects associated with Down syndrome.