XIAP-mediated neuroprotection in retinal ischemia.

Retinal ischemia results in the loss of vision in a number of ocular diseases including acute glaucoma, diabetic retinopathy, hypertensive retinopathy and retinal vascular occlusion. Recent studies have shown that most of the neuronal death that leads to loss of vision results from apoptosis. XIAP-mediated gene therapy has been shown to protect a number of neuronal types from apoptosis but has never been assessed in retinal neurons following ischemic-induced cell death. We injected an adeno-associated viral vector expressing XIAP or GFP into rat eyes and 6 weeks later, rendered them ischemic by raising intraocular pressure. Functional analysis revealed that XIAP-treated eyes retained larger b-wave amplitudes than GFP-treated eyes up to 4 weeks post-ischemia. The number of cells in the inner nuclear layer (INL) and the thickness of the inner retina were significantly preserved in XIAP-treated eyes compared to GFP-treated eyes. Similarly, there was no significant reduction in optic nerve axon numbers in XIAP-treated eyes. There were also significantly fewer TUNEL (TdT-dUTP terminal nick end labeling) positive cells in the INL of XIAP-treated retinas at 24 h post-ischemia. Thus, XIAP-mediated gene therapy imparts both functional and structural protection to the retina after a transient ischemic episode.

Hox C6 expression during development and regeneration of forelimbs in larval Notophthalmus viridescens.

A central theme concerning the epimorphic regenerative potential of urodele amphibian appendages is that limb regeneration in the adult parallels larval limb development. Results of previous research have led to the suggestion that homeobox containing genes are "re-expressed" during the epimorphic regeneration of forelimbs of adult Notophthalmus viridescens in patterns which retrace larval limb development. However, to date no literature exists concerning expression patterns of any homeobox containing genes during larval development of this species. The lack of such information has been a hindrance in exploring the similarities as well as differences which exist between limb regeneration in adults and limb development in larvae. Here we report the first such results of the localization of Hox C6 (formerly, NvHBox-1) in developing and regenerating forelimbs of N. viridescens larvae as demonstrated by whole-mount in situ hybridization. Inasmuch as the pattern of Hox C6 expression is similar in developing forelimb buds of larvae and epimorphically regenerating forelimb blastemata of both adults and larvae, our results support the paradigm that epimorphic regeneration in adult newts parallels larval forelimb development. However, in contrast with observations which document the presence of Hox C6 in both intact, as well as regenerating hindlimbs and tails of adult newts, our results reveal no such Hox C6 expression during larval development of hindlimbs or the tail. As such, our findings indicate that critical differences in larval hindlimb and tail development versus adult expression patterns of this gene in these two appendages may be due primarily to differences in gene regulation as opposed to gene function. Thus, the apparent ability of urodeles to regulate genes in such a highly co-ordinated fashion so as to replace lost, differentiated, appendicular structures in adult animals may assist, at least in part, in better elucidating the phenomenon of epimorphic regeneration.

Molecular cloning of the Notophthalmus viridescens radical fringe cDNA and characterization of its expression during forelimb development and adult forelimb regeneration.

Larval and adult newts provide important experimental models to study limb development and regeneration. These animals have exceptional ability to regenerate their appendages, as well as other vital structures. Our research examines the role of the fringe gene (fng) in the developing and regenerating adult newt forelimb. Fringe codes for a secretory protein. It was first discovered in Drosophila, and later homologues were isolated in Xenopus laevis, chick and mouse. This gene has been highly conserved throughout evolution, indicating its crucial role in vertebrate and invertebrate development. We have isolated, cloned, and sequenced the full length of the Notophthalmus viridescens radical fringe cDNA (nrFng) by screening a newt forelimb blastema cDNA library with a 500-bp fragment of the Xenopus lunatic fringe cDNA. The newt fringe cDNA codes for a 396 amino acid protein with a predicted N-terminal signal sequence. Newt fringe shows high homology with radical fringe homologues of many species. Whole mount mRNA in situ hybridization on several stages of newt limb development reveals that nrFng is first expressed in the limb field, with intense expression as the limb bud develops. However, gene expression diminishes with more advanced digit development. A significant role in adult forelimb regeneration is also evident, as we isolated the cDNA from a regeneration-specific library and found it highly expressed during the regenerative phases of active cell division and then down regulated at sites undergoing differentiation and morphogenesis.

A novel family of T-box genes in urodele amphibian limb development and regeneration: candidate genes involved in vertebrate forelimb/hindlimb patterning.

In certain urodeles, a lost appendage, including hand and foot, can be completely replaced through epimorphic regeneration. The regeneration process involves cellular activities similar to those described for embryogenesis. Working on the assumption that the morphological pattern specific for a forelimb or a hindlimb is controlled by different gene activities in the two limbs, we employed a mRNA differential display screen for the detection of candidate limb identity genes. Using this approach, we have isolated a newt gene which in regenerating and developing limbs reveals properties expected of a gene having a role in controlling limb morphology: (1) it is exclusively expressed in the forelimbs, but not hindlimbs, (2) during embryonic development its expression is co-incident with forelimb bud formation, (3) it has an elevated message level throughout the undifferentiated limb bud and the blastema, respectively, and (4) it is expressed only in mesenchymal, but not in epidermal tissues. This novel newt gene shares a conserved DNA-binding domain, the T-box, with putative transcription factors including the Brachyury (T) gene product. In a following PCR-based screen, we used the evolutionarily conserved T-box motif and amplified a family of related genes in the newt; their different expression patterns in normal and regenerating forelimbs, hindlimbs and tail suggest, in general, an important role of T-domain proteins in vertebrate pattern formation.

Isolation of a novel G protein-coupled receptor (GPR4) localized to chromosome 19q13.3.

We present the cloning and sequencing of the human gene for a novel G-protein coupled receptor (GPR4), from the critical myotonic dystrophy (DM) region on chromosome 19q13.3. The homologous porcine gene was isolated and sequenced as well. The genes of both species are intronless and contain an open reading frame encoding a protein of 362 amino acids. In human, two isoforms of GPR4 are expressed, differing in their 3' untranslated region due to the use of alternate polyadenylation signals and measuring approximately 2.8 and 1.8 kb, respectively. Northern blot analysis showed that GPR4 is widely expressed, with higher levels in kidney, heart, and especially lung, where it is at least fivefold greater than in other tissues. Sequence analysis suggests that GPR4 is a peptide receptor and shares strongest homologies with purinergic receptors and receptors for angiotensin II, platelet activating factor, thrombin, and bradykinin.

Convergent myotonic dystrophy (DM) haplotypes: potential inconsistencies in human disease gene localization.

Myotonic dystrophy (DM) is an autosomal dominant neuromuscular disease which has been shown to be caused by an unstable trinucleotide repeat located on chromosome 19q. We have conducted extensive haplotype analysis on 105 DM chromosomes using twelve 19q13.2 loci identifying 18 RFLPs, spanning a physical distance of 1.3 Mb containing the DM gene. Three major haplotypes (H1, H2 and H3) comprising 46.7% of the DM chromosomes in our population, were observed. With the exception of H1 and H2 derivatives (H4, H5 and H6), the remainder of the DM chromosomes analyzed were found to have unique haplotypes. Haplotypes H2 and H3 observed exclusively on DM chromosomes of French-Canadian origin contain identical 500-kb core regions. The low frequency of this core haplotype in normal chromosomes (0.8%) is consistent with a mapping of the DM gene within this region. However, the DM mutation is found 160 kb distal to the point of divergence between the two haplotypes. In contrast, the 450-kb region shared by haplotypes H1 and H2 contains the DM mutation. Further analysis of the DM region using a polymorphic microsatellite (GJ-VSSM2; D19S207) located 15 kb distal to the DM mutation revealed strong allelic association of one of the (CA)n repeat alleles to DM; allele 5 was observed on 88.2% of DM chromosomes and 6% of normal chromosomes. The fact that the (CA)n allele 5 was found on all 56 DM chromosomes containing the three major haplotypes indicates that DM chromosomes in our population, including the two French-Canadian haplotypes which have a common region outside the DM gene, are probably derived from the same mutational event.(ABSTRACT TRUNCATED AT 250 WORDS)

Intergenerational stability of the myotonic dystrophy protomutation.

The amplification of the CTG trinucleotide repeat in myotonic dystrophy (DM) correlates with increasingly severe phenotypes. We designate its minimal amplification the 'protomutation' since it is the mutation itself at an early stage of intergenerational evolution and is associated with very mild clinical signs. From the study of 536 DM mutation carriers (from 158 affected families), a total of 60 DM-parent/DM-offspring pairings were identified in which the parent had the protomutation. We found a strong correlation between the protomutation length and the amplification observed in the next generation. We also observed the stable transmission of the protomutation through successive generations. This stability may explain the maintenance in the population of this autosomal dominant disease despite the low reproductive fitness of severe DM phenotypes.

Reduction in size of the myotonic dystrophy trinucleotide repeat mutation during transmission.

Myotonic dystrophy (DM) is an autosomal-dominant disorder that affects 1 in 8000 individuals. Amplification of an unstable trinucleotide CTG repeat, located within the 3' untranslated region of a gene, correlates with a more severe DM phenotype. In three cases, the number of CTG repeats was reduced during the transmission of the DM allele; in one of these cases, the number was reduced to within the normal range and correlated at least with a delay in the onset of clinical signs of DM. Haplotype data of six polymorphic markers in the DM gene region indicate that, in this latter case, two stretches of the affected chromosome had been exchanged with that region of the wild-type chromosome.

Decrease in the size of the myotonic dystrophy CTG repeat during transmission from parent to child: implications for genetic counselling and genetic anticipation.

Recently an unstable trinucleotide CTG repeat, located within the 3' untranslated region of a gene on 19q13.3 was discovered in kindreds with myotonic dystrophy (DM). The age-of-onset/severity of DM shows a good correlation with CTG repeat size, and pedigrees and data reported to date have shown a striking trend toward amplification of the size of the CTG repeat during transmission from parent to child. The amplification has been accepted as the biological explanation for anticipation in the clinical severity observed in many families with DM. In this paper we report on 3 families where CTG amplification decreased during transmission from parent to child. In one case there was a gene conversion event, while in the remaining 2 there was a simpler reduction in the size of the repeat length. The changes appear to have been accompanied by a reduction in clinical severity in the child when compared to the parent. These observations are discussed in terms of their clinical implications and the biases that may exist in much of the reported data.

The correlation of age of onset with CTG trinucleotide repeat amplification in myotonic dystrophy.

The gene for myotonic dystrophy (DM) has recently been isolated and amplification of an unstable CTG trinucleotide repeat, located within the DM gene, has been identified in virtually all patients studied to date. A high proportion of DM families who are studied show a progressively earlier age of onset with succeeding generations and, in the few pedigrees reported so far, an increasing degree of amplification of the CTG repeat has been noted to parallel this trend. It has been implicit in several of the original reports on the nature of the changes in the DM gene that knowledge of CTG amplification status at the DM locus of a person will provide useful information concerning prognosis. However, no studies of genotype-phenotype correlation have been reported and there are no specific data on which to base such counsel. In this paper we report the correlation between the degree of CTG amplification and age of onset in 109 DM gene carriers from 17 families. Included are parent-child and sib-sib comparisons which provide a framework in which to incorporate DNA diagnostic studies when counselling subjects and families at risk for DM.

Physical and genetic characterization of the distal segment of the myotonic dystrophy area on 19q.

The mutation involved in myotonic dystrophy (DM) has been mapped to the region between the ERCC1 DNA repair gene and the anonymous D19S51 locus on 19q13.3. Starting at locus D19S112 (probe pX75b), which served as a novel entry site for this chromosome region, we have established a cosmid contig of approximately 200 kb. In the contig, a gene expressed in the brain and a highly informative, 12-allele (TG)n variable simple sequence motif (VSSM) were identified. With this marker, designated X75b-VSSM, a highly characteristic size distribution of alleles linked with DM, which differed significantly from that on normal chromosomes, was observed. Combining our physical mapping and genetic data, we show that the X75b-VSSM marker is the closest distal to DM, thus excluding the DM mutation from the entire telomeric portion of the ERCC1-D19S51 region.

Physical mapping and cloning of the proximal segment of the myotonic dystrophy gene region.

The myotonic dystrophy (DM) region has been recently shown to be bracketed by two key recombinant events. One recombinant occurs in a Dutch DM family, which maps the DM locus distal to the ERCC1 gene and D19S115 (pE0.8). The other recombinant event is in a French Canadian DM family, which maps DM proximal to D19S51 (p134c). To further resolve this region, we initiated a chromosome walk in a telomeric direction from pE0.8, a proximal marker tightly linked to DM, toward the genetic locus. An Alu-PCR approach to chromosome walking in a cosmid library from flow-sorted chromosome 19 was used to isolate DM region cosmids. This effort has resulted in the cloning of a 350-kb genomic contig of human chromosome 19q13.3. New genetic and physical mapping information has been generated using the newly cloned markers from this study. As a result of this new mapping information, the minimal area that is to contain the DM gene has been redefined. Approximately 200 kb of sequence between pE0.8 and the closest proximal marker to DM, pKEX0.8, that would have otherwise been screened for DM candidate genes, has been eliminated as containing the DM gene.

Correlation between CTG trinucleotide repeat length and frequency of severe congenital myotonic dystrophy.

The myotonic dystrophy (DM) mutation has recently been identified as an unstable trinucleotide CTG repeat which is present 5-30 times in the normal population but which is amplified up to 2,000 times in DM. We have determined the status of the CTG repeat in 272 DM individuals. Infants with severe congenital DM, as well as their mothers, are shown to have on average a greater amplification of the CTG repeat than is seen in the noncongenital DM population. This fact, when viewed in conjunction with the tendency to increased CTG repeat length in our DM kindreds, provides evidence for the existence of genetic anticipation in the transmission of DM.

Myotonic dystrophy mutation: an unstable CTG repeat in the 3' untranslated region of the gene.

Myotonic dystrophy (DM) is the most common inherited neuromuscular disease in adults, with a global incidence of 1 in 8000 individuals. DM is an autosomal dominant, multisystemic disorder characterized primarily by myotonia and progressive muscle weakness. Genomic and complementary DNA probes that map to a 10-kilobase Eco RI genomic fragment from human chromosome 19q13.3 have been used to detect a variable length polymorphism in individuals with DM. Increases in the size of the allele in patients with DM are now shown to be due to an increased number of trinucleotide CTG repeats in the 3' untranslated region of a DM candidate gene. An increase in the severity of the disease in successive generations (genetic anticipation) is accompanied by an increase in the number of trinucleotide repeats. Nearly all cases of DM (98 percent or 253 of 258 individuals) displayed expansion of the CTG repeat region. These results suggest that DM is primarily caused by mutations that generate an amplification of a specific CTG repeat.

Cloning of the essential myotonic dystrophy region and mapping of the putative defect.

Myotonic dystrophy is a common dominant disorder (global incidence of 1:8,000) with variable onset and a protean nature of symptoms mainly involving progressive muscle wasting, myotonia and cataracts. To define the molecular defect, we have cloned the essential region of chromosome 19q13.3, including proximal and distal markers in a 700-kilobase contig formed by overlapping cosmids and yeast artificial chromosomes (YACs). The central part of the contig bridges an area of about 350 kilobases between two new flanking crossover borders. This segment has been extensively characterized through the isolation of five YAC clones and the subsequent subcloning in cosmids from which a detailed EcoRI, HindIII, MluI and NotI restriction map has been derived. Two genomic probes and two homologous complementary DNA probes were isolated using the cosmids. These probes are all situated within approximately 10 kilobases of genomic DNA and detect an unstable genomic segment in myotonic dystrophy patients. The length variation in this segment shows similarities to the instability seen at the fragile X locus. The physical map location and the genetic characteristics of the length polymorphism is compatible with a direct role in the pathogenesis of myotonic dystrophy.

D19S51 is closely linked with and maps distal to the myotonic dystrophy locus on 19q.

Recent genetic linkage studies have mapped the myotonic dystrophy (DM) locus to 19q13.3. All closely linked DM markers identified to date have been located on the centromeric side of the disease locus, with a relatively large genetic interval (9 cM) observed between the nearest distal marker and DM. We show here that the recently described marker p134C is tightly linked to DM (peak lod score 35.8 at peak recombination fraction .006) and confirm the previous suggestion that the p134C locus, D19S51 maps distal to the disease locus. D19S51 and the closest proximal flanking loci, ERCC1 and D19S115 (pE0.8), define a small genetic interval of less than 2 cM that contains the DM locus.