Catherine Plant

Mutations in the RP2 Gene Cause Disease in 10% of Families with Familial X-Linked Retinitis Pigmentosa Assessed in This Study

We wish to thank Dr. Wolfgang Berger for kindly providing the primer sequences 2 wk prior to publication. The authors also wish to thank all the clinicians and participating families who have supported our research over the years; Dr. Kamal Dulai for invaluable computer support; and Ilaria Zito for running SSCP gels. This research was supported by The Wellcome Trust (grant 051733/Z/97 to A.J.H.), the Guide Dogs for the Blind Association (grant 95-52A to D.L.T.), and the British RP Society.

Genetic analysis of the guanylate cyclase activator 1B (GUCA1B) gene in patients with autosomal dominant retinal dystrophies

The guanylate cyclase activator proteins (GCAP1 and GCAP2) are calcium binding proteins which by activating Ret-GC1 play a key role in the recovery phase of phototransduction. Recently a mutation in theGUCA1A gene (coding for GCAP1) mapping to the 6p21.1 region was described as causing cone dystrophy in a British family. In addition mutations in Ret-GC1have been shown to cause Leber congenital amaurosis and cone-rod dystrophy. To determine whether GCAP2 is involved in dominant retinal degenerative diseases, the GCAP2 gene was screened in 400 unrelated subjects with autosomal dominant central and peripheral retinal dystrophies. A number of changes involving the intronic as well as the coding sequence were observed. In exon 1 a T to C nucleotide change was observed leaving the tyrosine residue 57 unchanged. In exon 3 a 1 bp intronic insertion, a single nucleotide substitution G to A in the intron 3′ of this exon, and a GAG to GAT change at codon 155 were observed. This latter change results in a conservative change of glutamic acid to aspartic acid. In exon 4 a 7 bp intronic insertion, a single nucleotide A to G substitution in the intron 5′ of this exon, and a single base pair change C to G in the intron 3′ of exon 4 were seen. None of these changes would be expected to affect correct splicing of this gene. All these changes were observed in controls. The results of this study do not show any evidence so far that GCAP2 is involved in the pathogenesis of autosomal dominant retinal degeneration in this group of patients. All the changes detected were found to be sequence variations or polymorphisms and not disease causing.

A linkage survey of 20 dominant retinitis pigmentosa families: frequencies of the nine known loci and evidence for further heterogeneity.

Autosomal dominant retinitis pigmentosa (ADRP) is caused by mutations in two known genes, rhodopsin and peripherin/Rds, and seven loci identified only by linkage analysis. Rhodopsin and peripherin/Rds have been estimated to account for 20-31% and less than 5% of ADRP, respectively. No estimate of frequency has previously been possible for the remaining loci, since these can only be implicated when families are large enough for linkage analysis. We have carried out such analyses on 20 unrelated pedigrees with 11 or more meioses. Frequency estimates based on such a small sample provide only broad approximations, while the above estimations are based on mutation detection in much larger clinic based patient series. However, when markers are informative, linkage analysis cannot fail to detect disease causation at a locus, whereas mutation detection techniques might miss some mutations. Also diagnosing dominant RP from a family history taken in a genetic clinic may not be reliable. It is therefore interesting that 10 (50%) of the families tested have rhodopsin-RP, suggesting that, in large clearly dominant RP pedigrees, rhodopsin may account for a higher proportion of disease than had previously been suspected. Four (20%) map to chromosome 19q, implying that this is the second most common ADRP locus. One maps to chromosome 7p, one to 17p, and one to 17q, while none maps to 1cen, peripherin/Rds, 8q, or 7q. Three give exclusion of all of these loci, showing that while the majority of dominant RP maps to the known loci, a small proportion derives from loci yet to be identified.

Novel frameshift mutations in the RP2 gene and polymorphic variants.

Mutations in the RP2 gene located on Xp11.23 are associated with X‐linked retinitis pigmentosa (XLRP), a severe form of progressive retinal degeneration which leads to complete loss of vision in affected males. To date, 14 different mutations in the RP2 gene have been reported to cause XLRP, the majority of which lead to a coding frameshift within the gene and predicted truncation of the protein product. We here report two novel frameshift mutations in RP2 identified in XLRP families by PCR‐SSCP and direct sequencing, namely 723delT and 796‐799del. Four single nucleotide polymorphisms (SNPs) within the coding region of RP2 are also described (105A>T, 597T>C, 844C>T, 1012G>T), the first polymorphisms to be reported within this gene of unknown function, two of which alter the amino acid sequence. The current study extends the XLRP mutation profile of RP2 and highlights non‐pathogenic coding sequence variations which may facilitate both functional studies of the gene and analysis of intragenic allelic contribution to the phenotype. Hum Mutat 15:580, 2000.

A new family linked to the RP13 locus for autosomal dominant retinitis pigmentosa on distal 17p.

A form of autosomal dominant retinitis pigmentosa (ADRP) mapping to chromosome 17p has been reported in a single large South African family. We now report a new family with severe early onset ADRP which maps to 17p. Linkage and haplotype analysis in this family places the ADRP locus in the 5 cM interval between markers AFMc024za5 and D17S1845, confirming the data obtained in the South African family. The discovery of a second 17p linked family may imply that this is one of the more common loci for dominant RP. In addition, the confirmation of an RP diagnosis at this locus is of interest since loci for a dominant cone dystrophy and Lebers congenital amaurosis (LCA1) have recently been linked to the same markers. While the cone dystrophy locus may be allelic with RP, our data and that of Goliath et al show that distinct genes are responsible for dominant RP and Lebers congenital amaurosis on chromosome 17p.

Refined genetic and physical positioning of the gene for Doyne honeycomb retinal dystrophy (DHRD).

Doyne honeycomb retinal dystrophy (DHRD) is a late-onset autosomal dominant disorder that causes degeneration of the retina and can lead to blindness. We have previously assigned DHRD to a 5-cM region of chromosome 2p16 between marker loci D2S2739 and D2S378. Using sequence-tagged sites (STSs), expressed sequence tags (ESTs) and polymorphic markers within the DHRD region, we have identified 18 yeast artificial chromosomes (YACs) encompassing the DHRD locus, spanning approximately 3 Mb. The YAC contig was constructed by STS content mapping of these YACs and incorporates 13 STSs, including four genes and six polymorphic marker loci. We also report the genetic mapping of two families with a dominant drusen phenotype to the DHRD locus, and genetic refinement of the disease locus to a critical interval flanked by microsatellite marker loci D2S2352 and D2S2251, a distance of approximately 700 kb. These studies exclude a number of candidate genes and provide a resource for construction of a transcriptional map of the region, as a prerequisite to identification of the DHRD disease-causing gene and genes for other diseases mapping in the region, such as Malattia leventinese and Carney complex.

Novel Mutations of the RPGR Gene in RP3 Families

X‐linked retinitis pigmentosa is a severe retinal degeneration characterized by night blindness and visual field constriction, leading to complete blindness within the third decade of life. Mutations in the RPGR gene (retinitis pigmentosa GTPase regulator), located on Xp21.1 in the RP3 region, have been associated with an RP phenotype. Further to our previous mutation screening of RPGR in families segregating with the RP3 locus, we have expanded this study to include other 8 RP3 pedigrees. Here we report the results of this expanded study and the identification of five mutations in RPGR, four of which are novel (IVS6+5 G>A, 950‐951delAA, 963 T>C, EX8del) and one of which occurs in the donor splice site of intron 1 (IVS1+1 G>A). These findings bring the proportion of “RP3 genotypes” with a mutation in this gene to 27% (10/37). Hum Mutat 15:386, 2000.

Further refinement of the Usher 2A locus at 1q41.

Usher syndrome (USH) is characterised by congenital sensorineural hearing loss and progressive pigmentary retinopathy. All three subtypes (USH1, USH2, and USH3) are inherited as recessive traits. People with Usher type 2 (USH2) have normal vestibular responses and moderate to severe hearing loss. These syndromes have been found to be genetically heterogeneous, with a single locus for USH2 at 1q41 (USH2A), six loci for USH1, and one for USH3. Some USH2 families have been excluded from the 1q41 locus suggesting that a second, as yet unidentified, locus (USH2B) must exist. Linkage studies suggest that around 90% of USH2 families are USH2A. Four USH2 families were analysed for linkage to markers flanking the USH2A locus. In one of these families a recombination event was observed in an affected subject which excludes the USH2A gene from proximal to the marker AFM143XF10 and defines this as the new centromeric flanking marker for the USH2A locus. A further recombination event in another patient from this family confirmed AFM144XF2 as the telomeric flanking marker. The interval between these polymorphic markers is estimated to be 400 kb. This region is completely contained in each of three YACs from the CEPH library: 867g9, 919h3, and 848b9. This refinement more than halves the critical genetic interval and will greatly facilitate positional cloning of the USH2A gene.