Susceptibility to chronic pain following nerve injury is genetically affected by CACNG2.
Nissenbaum J
et al.
Genome Res 2010 Sep;20(9)1180-1190
Nissenbaum J, Devor M, Seltzer Z, Gebauer M, Michaelis M, Tal M, Dorfman R, Abitbul-Yarkoni M, Lu Y, Elahipanah T, delCanho S, Minert A, Fried K, Persson AK, Shpigler H, Shabo E, Yakir B, Pisanté A, Darvasi A.
Genome Res 2010 Sep;20(9)1180-1190
Abstract: Chronic neuropathic pain is affected by specifics of the precipitating neural pathology, psychosocial factors, and by genetic predisposition. Little is known about the identity of predisposing genes. Using an integrative approach, we discovered that CACNG2 significantly affects susceptibility to chronic pain following nerve injury. CACNG2 encodes for stargazin, a protein intimately involved in the trafficking of glutamatergic AMPA receptors. The protein might also be a Ca(2+) channel subunit. CACNG2 has previously been implicated in epilepsy. Initially, using two fine-mapping strategies in a mouse model (recombinant progeny testing [RPT] and recombinant inbred segregation test [RIST]), we mapped a pain-related quantitative trait locus (QTL) (Pain1) into a 4.2-Mb interval on chromosome 15. This interval includes 155 genes. Subsequently, bioinformatics and whole-genome microarray expression analysis were used to narrow the list of candidates and ultimately to pinpoint Cacng2 as a likely candidate. Analysis of stargazer mice, a Cacng2 hypomorphic mutant, provided electrophysiological and behavioral evidence for the gene's functional role in pain processing. Finally, we showed that human CACNG2 polymorphisms are associated with chronic pain in a cohort of cancer patients who underwent breast surgery. Our findings provide novel information on the genetic basis of neuropathic pain and new insights into pain physiology that may ultimately enable better treatments.
Genetic localization of the Ca2+ channel gene CACNG2 near SCA10 on chromosome 22q13.
Burgess DL
et al.
Epilepsia 2000 Jan;41(1)24-27
Burgess DL, Matsuura T, Ashizawa T, Noebels JL.
Epilepsia 2000 Jan;41(1)24-27
Abstract: <h4>Purpose</h4>Voltage-dependent calcium channel mutations have been associated with spinocerebellar ataxia in humans (SCA6) and with ataxia, progressive cerebellar degeneration, and epilepsy in mice (tottering, lethargic, and stargazer). A novel autosomal dominant spinocerebellar ataxia syndrome with epilepsy (SCA10) was recently mapped to chromosome 22q13. The human ortholog of the mouse stargazer locus, the calcium channel gamma subunit gene CACNG2, also is located in this region. Because the phenotypes of stargazer mice and SCA10 patients were similar, consisting of both cerebellar ataxia and seizures, we hypothesized that CACNG2 was a likely candidate for the SCA10 locus.<h4>Methods</h4>Polymerase chain reaction (PCR) based assays were developed for two polymorphic microsatellite markers near CACNG2. The location of CACNG2 was determined by linkage and haplotype analysis of the genotypes of 22 individuals from a human pedigree segregating SCA10.<h4>Results</h4>SCA10 was previously localized distal to marker D22S1177 on chromosome 22q13. We determined that CACNG2 was linked to D22S283 and D22S1177 with the marker order: centromere-D22S283-bcmDLB1 (CACNG2)-D22S1177-D22S423-telomere. Thus CACNG2 is located proximal to the SCA10 recombinant interval.<h4>Conclusions</h4>Here we report the first genetic linkage of CACNG2 on chromosome 22q13 and exclude it as a candidate for SCA10. In addition, our data clarify the relation between the physical and genetic linkage maps of this region and will facilitate isolation of the SCA10 gene.
The mouse stargazer gene encodes a neuronal Ca2+-channel gamma subunit.
Letts VA
et al.
Nat Genet 1998 Aug;19(4)340-347
Letts VA, Felix R, Biddlecome GH, Arikkath J, Mahaffey CL, Valenzuela A, Bartlett FS, Mori Y, Campbell KP, Frankel WN.
Nat Genet 1998 Aug;19(4)340-347
Abstract: Stargazer mice have spike-wave seizures characteristic of absence epilepsy, with accompanying defects in the cerebellum and inner ear. We describe here a novel gene, Cacng2, whose expression is disrupted in two stargazer alleles. It encodes a 36-kD protein (stargazin) with structural similarity to the gamma subunit of skeletal muscle voltage-gated calcium (Ca2+) channels. Stargazin is brain-specific and, like other neuronal Ca2+-channel subunits, is enriched in synaptic plasma membranes. In vitro, stargazin increases steady-state inactivation of alpha1 class A Ca2+ channels. The anticipated effect in stargazer mutants, inappropriate Ca2+ entry, may contribute to their more pronounced seizure phenotype compared with other mouse absence models with Ca2+-channel defects. The discovery that the stargazer gene encodes a gamma subunit completes the identification of the major subunit types for neuronal Ca2+ channels, namely alpha1, alpha2delta, beta and gamma, providing a new opportunity to understand how these channels function in the mammalian brain and how they may be targeted in the treatment of neuroexcitability disorders.
