Rosemary E. Kelsell

TRPV3 is a temperature-sensitive vanilloid receptor-like protein

Vanilloid receptor-1 (VR1, also known as TRPV1) is a thermosensitive, nonselective cation channel that is expressed by capsaicin-sensitive sensory afferents and is activated by noxious heat, acidic pH and the alkaloid irritant capsaicin. Although VR1 gene disruption results in a loss of capsaicin responses, it has minimal effects on thermal nociception. This and other experiments—such as those showing the existence of capsaicin-insensitive heat sensors in sensory neurons—suggest the existence of thermosensitive receptors distinct from VR1. Here we identify a member of the vanilloid receptor/TRP gene family, vanilloid receptor-like protein 3 (VRL3, also known as TRPV3), which is heat-sensitive but capsaicin-insensitive. VRL3 is coded for by a 2,370-base-pair open reading frame, transcribed from a gene adjacent to VR1, and is structurally homologous to VR1. VRL3 responds to noxious heat with a threshold of about 39 °C and is co-expressed in dorsal root ganglion neurons with VR1. Furthermore, when heterologously expressed, VRL3 is able to associate with VR1 and may modulate its responses. Hence, not only is VRL3 a thermosensitive ion channel but it may represent an additional vanilloid receptor subunit involved in the formation of heteromeric vanilloid receptor channels.

Tissue Distribution Profiles of the Human TRPM Cation Channel Family

Eight members of the TRP-melastatin (TRPM) subfamily have been identified, whose physiological functions and distribution are poorly characterized. Although tissue expression and distribution patterns have been reported for individual TRPM channels, comparisons between individual studies are not possible because of variations in analysis techniques and tissue selection. We report here a comparative analysis of the expression patterns of all of the human TRPM channels in selected peripheral tissues and the central nervous system (CNS) using two distinct but complimentary approaches: TaqMan and SYBR Green real-time quantitative reverse transcription polymerase chain reaction (RT-PCR). These techniques generated comparative distribution profiles and demonstrated tissue-specific co-expression of TRPM mRNA species, indicating significant potential for the formation of heteromeric channels. TRPM channels 2, 4, 5, 6, and 7 in contrast to 1, 3, and 8 are widely distributed in the CNS and periphery. The tissues demonstrating highest expression for individual family members were brain (TRPM1), brain and bone marrow (TRPM2), brain and pituitary (TRPM3), intestine and prostate (TRPM4), intestine, pancreas, and prostate (TRPM5), intestine and brain (TRPM6), heart, pituitary, bone, and adipose tissue (TRPM7), and prostate and liver (TRPM8). The data reported here will guide the elucidation of TRPM channel physiological functions.

Cloning and Functional Expression of Human Short TRP7, a Candidate Protein for Store-operated Ca2+ Influx

The regulation and control of plasma membrane Ca2+ fluxes is critical for the initiation and maintenance of a variety of signal transduction cascades. Recently, the study of transient receptor potential channels (TRPs) has suggested that these proteins have an important role to play in mediating capacitative calcium entry. In this study, we have isolated a cDNA from human brain that encodes a novel transient receptor potential channel termed human TRP7 (hTRP7). hTRP7 is a member of the short TRP channel family and is 98% homologous to mouse TRP7 (mTRP7). At the mRNA level hTRP7 was widely expressed in tissues of the central nervous system, as well as some peripheral tissues such as pituitary gland and kidney. However, in contrast to mTRP7, which is highly expressed in heart and lung, hTRP7 was undetectable in these tissues. For functional analysis, we heterologously expressed hTRP7 cDNA in an human embryonic kidney cell line. In comparison with untransfected cells depletion of intracellular calcium stores in hTRP7-expressing cells, using either carbachol or thapsigargin, produced a marked increase in the subsequent level of Ca2+ influx. This increased Ca2+ entry was blocked by inhibitors of capacitative calcium entry such as La3+ and Gd3+. Furthermore, transient transfection of an hTRP7 antisense expression construct into cells expressing hTRP7 eliminated the augmented store-operated Ca2+ entry. Our findings suggest that hTRP7 is a store-operated calcium channel, a finding in stark contrast to the mouse orthologue, mTRP7, which is reported to enhance Ca2+ influx independently of store depletion, and suggests that human and mouse TRP7 channels may fulfil different physiological roles.

Autosomal dominant cone-rod retinal dystrophy (CORD6) from heterozygous mutation of GUCY2D, which encodes retinal guanylate cyclase

OBJECTIVE To describe the clinical features of autosomal dominant cone-rod retinal dystrophy (CRD) in a British family mapping to chromosome 17p12-p13 (CORD6), with a heterozygous mutation (Glu837Asp/ Arg838Ser) of GUCY2D. DESIGN A prospective, clinical family survey. PATIENTS Ten affected members of a family with autosomal dominant CRD. METHODS Full clinical examinations were undertaken. Selected affected family members underwent electrophysiologic evaluation, scotopic static perimetry, dark adaptometry, and color vision assessment. MAIN OUTCOME MEASURES Clinical appearance and electroretinographic responses. RESULTS Typical clinical and electroretinographic features of childhood-onset CRD were recorded. In addition, moderate myopia and pendular nystagmus were seen in affected individuals. Color vision assessment in the youngest affected individual showed no color discrimination on a tritan axis, but retention of significant red-green discrimination. Electronegative electroretinogram responses were seen on electrophysiology in the only young family member examined. CONCLUSIONS The phenotype associated with GUCY2D CRD is clinically distinct from that associated with other dominant CRD loci. Unusual electroretinographic responses may indicate that this mutation of GUCY2D is associated with early defects in photoreceptor synaptic transmission to second-order neurons.

Localization of a gene (CORD7) for a dominant cone-rod dystrophy to chromosome 6q

We thank the family members for their cooperation in this study. This work was supported by the Wellcome Trust (grant 041905), the Frost Charitable Trust, and the Foundation Fighting Blindness.

Characterisation of recombinant rat TRPM2 and a TRPM2-like conductance in cultured rat striatal neurones

TRPM2, a member of the TRP ion channel family, is expressed both in the brain and immune cells of the monocyte lineage. Functionally, it is unique in its activation by intracellular ADP-ribose and both oxidative and nitrosative stress. To date studies of this channel have concentrated on human recombinant channels and rodent native preparations. This provides the potential for cross-species complications in the interpretation of native tissue observations based on recombinant channel phenotype. Consequently, we have cloned and heterologously expressed rat TRPM2 (rTRPM2) in HEK293 cells. We find that, like hTRPM2, it responds to intracellular ADP-ribose in a manner dependent on extracellular Ca(2+). At the single channel level rTRPM2 is a slow gating, large conductance (84pS) channel that rapidly runs down in isolated membrane patches. Pharmacologically, rTRPM2 is rapidly and irreversibly blocked by clotrimazole (10muM), thus resembling hTRPM2 but not the TRPM2-like current of the rat-derived insulinoma CRI-G1, which exhibits reversible inhibition by this agent. We show that cultured rat striatal neurones exhibit an ADP-ribose-activated conductance at both the whole cell and single channel level. Pharmacologically this neuronal current can be irreversibly inhibited by clotrimazole. It is also sensitive to removal of extracellular Ca(2+), suggesting that it is mediated by TRPM2-containing channels. These data provide a functional characterisation of heterologously expressed rTRPM2 and demonstrate that, in addition to the previous descriptions in immune cells, microglia and insulinomas, a TRPM2-like conductance can be found in neurones derived from the rodent CNS.

The neuroprotective agent sipatrigine (BW619C89) potently inhibits the human tandem pore-domain K+ channels TREK-1 and TRAAK

We have cloned and functionally expressed the human orthologue of the mouse TRAAK gene. When cDNA for hTRAAK is expressed in either Xenopus oocytes or HEK293 cells it forms a K(+)-selective conductance and hyperpolarises the resting membrane potential. Quantitative mRNA expression analysis using Taqman revealed that hTRAAK mRNA is predominantly present in the central nervous system where it exhibits a regionally diverse pattern of expression. Like the related channel TREK-1, the activity of TRAAK was potentiated by arachidonic acid. The neuroprotective agent sipatrigine (10 microM) inhibited both hTREK-1 (73.3+/-4.4%) and hTRAAK (45.1+/-11.2%) in a reversible, voltage-independent manner. Inhibition of both channels was dose-dependent and for TREK-1 occurred with an IC(50) of 4 microM. The related compound lamotrigine, which is a better anticonvulsant but weaker neuroprotective agent than sipatrigine, was a far less effective antagonist of both channels, producing <10% inhibition at a concentration of 10 microM.

Phenotype of a British North Carolina macular dystrophy family linked to chromosome 6q

AIMS To document the phenotype of an autosomal dominant macular dystrophy diagnosed as having North Carolina macular dystrophy (NCMD) in this British family, and to verify that the disease locus corresponds with that of MCDR1 on chromosome 6q. METHODS 37 family members were examined and the phenotype characterised. DNA samples from the affected members, 19 unaffected and five spouses, were used to perform linkage analysis with six microsatellite marker loci situated within the MCDR1 region of chromosome 6q. RESULTS Every affected family member had lesions characteristic of NCMD, which developed early in life and usually remain stable thereafter. Although fundus changes are evident in the periphery, all tests revealed that functional loss is restricted to the macula. Some patients with large macular lesions had good visual acuity with fixation at the edge of the lesion at 5° eccentricity. Significant linkage to the MCDR1 locus on chromosome 6q was obtained with three marker loci, with a maximum lod score of 5.9 (q = 0.00) obtained with D6S249. CONCLUSION This family has the typical phenotype NCMD, and the causative gene was linked to the disease locus (MCDR1) on chromosome 6q. Early onset and localisation of the disease to the central macula allow specialisation of eccentric retina in some eyes with resultant good visual acuity.

Assessment of the interphotoreceptor matrix proteoglycan-1 (IMPG1) gene localised to 6q13-q15 in autosomal dominant Stargardt-like disease (ADSTGD), progressive bifocal chorioretinal atrophy (PBCRA), and North Carolina macular dystrophy (MCDR1).

We have recently characterised the genomic organisation of a novel interphotoreceptor matrix proteoglycan, IMPG1, and have mapped the gene locus to chromosome 6q13-q15 by fluorescence in situ hybridisation. As the interphotoreceptor matrix (IPM) is thought to play a critical role in retinal adhesion and the maintenance of photoreceptor cells, it is conceivable that a defect in one of the IPM components may cause degenerative lesions in retinal structures and thus may be associated with human retinopathies. By genetic linkage analysis, several retinal dystrophies including one form of autosomal dominant Stargardt-like macular dystrophy (STGD3), progressive bifocal chorioretinal atrophy (PBCRA), and North Carolina macular dystrophy (MCDR1) have previously been localised to a region on proximal 6q that overlaps the IMPG1 locus. We have therefore assessed the entire coding region of IMPG1 by exon amplification and subsequent single stranded conformational analysis in patients from 6q linked multigeneration families diagnosed with PBCRA and MCDR1, as well as a single patient from an autosomal dominant STGD pedigree unlinked to either of the two known STGD2 and STGD3 loci on chromosomes 13q and 6q, respectively. No disease associated mutations were identified. In addition, using an intragenic polymorphism, IMPG1 was excluded by genetic recombination from both the PBCRA and the MCDR1 loci. However, as the autosomal dominant Stargardt-like macular dystrophies are genetically heterogeneous, other forms of this disorder, in particular STGD3 previously linked to 6q, may be caused by mutations in IMPG1.

Genetic linkage analysis of a novel syndrome comprising North Carolina-like macular dystrophy and progressive sensorineural hearing loss

Aim: To characterise the phenotype and identify the underlying genetic defect in a family with deafness segregating with a North Carolina-like macular dystrophy (NCMD). Methods: Details of the family were obtained from the Moorfields Eye Hospital genetic clinic database and comprised eight affected, four unaffected members, and two spouses. Pedigree data were collated and leucocyte DNA extracted from venous blood. Positional candidate gene and genetic linkage strategies utilising polymerase chain reaction (PCR) based microsatellite marker genotyping were performed to identify the disease locus. Results: The non-progressive ocular phenotype shared similarities with North Carolina macular dystrophy. Electro-oculography and full field electroretinography were normal. Progressive sensorineural deafness was also present in all affected individuals over the age of 20 years. Hearing was normal in all unaffected relatives. Haplotype analysis indicated that this family is unrelated to previously reported families with NCMD. Genotyping excluded linkage to the MCDR1 locus and suggested a potential novel disease locus on chromosome 14q (Z=2.92 at 𝛉=0 for marker D14S261). Conclusion: The combination of anomalies segregating in this family represents a novel phenotype. This molecular analysis indicates the disease is genetically distinct from NCMD.