Parentage verification in field progeny testing program of Mehsana buffalo.

The present study was undertaken to construct a multiplex microsatellite panel for parentage testing in Mehsana buffalo (Bubalus bubalis). The study was based on a total of 212 Mehsana buffalos (100 dams, 100 daughters, and 12 sires). Genomic DNA was extracted from blood and semen samples. A panel of 10 microsatellite markers (CSSM61, ILSTS29, ILSTS17, ILSTS28, CSSM57, CSSM22, ILSTS61, CSSM8, ETH152, and ILSTS11) was amplified in a single multiplex reaction and analyzed by capillary electrophoresis on an automated DNA sequencer. The expected heterozygosity ranged from 0.642 to 0.833 (mean 0.762). The total exclusion probability using 10 microsatellite loci with 1 known parent was 0.993. Seven out of 10 microsatellite loci revealed relatively high polymorphic information content (>0.7). Eighty-one daughters out of 100 daughters qualified by compatibility according to Mendelism. The results suggest that multiplex microsatellite panel is a fast, robust, reliable, and economic tool to verify the parentage as well as to assign the putative sire to daughters under progeny testing with very high accuracy and hence can be used in routine parentage testing.

The phenotypic spectrum of GLI3 morphopathies includes autosomal dominant preaxial polydactyly type-IV and postaxial polydactyly type-A/B; No phenotype prediction from the position of GLI3 mutations.

Functional characterization of a gene often requires the discovery of the full spectrum of its associated phenotypes. Mutations in the human GLI3 gene have been identified in Greig cepalopolysyndactyly, Pallister-Hall syndrome (PHS), and postaxial polydactyly type-A (PAP-A). We studied the involvement of GLI3 in additional phenotypes of digital abnormalities in one family (UR003) with preaxial polydactyly type-IV (PPD-IV), three families (UR014, UR015, and UR016) with dominant PAP-A/B (with PPD-A and -B in the same family), and one family with PHS. Linkage analysis showed no recombination with GLI3-linked polymorphisms. Family UR003 had a 1-nt frameshift insertion, resulting in a truncated protein of 1,245 amino acids. A frameshift mutation due to a 1-nt deletion was found in family UR014, resulting in a truncated protein of 1,280 amino acids. Family UR015 had a nonsense mutation, R643X, and family UR016 had a missense mutation, G727R, in a highly conserved amino acid of domain 3. The patient with PHS had a nonsense mutation, E1147X. These results add two phenotypes to the phenotypic spectrum caused by GLI3 mutations: the combined PAP-A/B and PPD-IV. These mutations do not support the suggested association between the mutations in GLI3 and the resulting phenotypes. We propose that all phenotypes associated with GLI3 mutations be called "GLI3 morphopathies," since the phenotypic borders of the resulting syndromes are not well defined and there is no apparent genotype-phenotype correlation.

The gene for autosomal dominant hidrotic ectodermal dysplasia (Clouston syndrome) in a large Indian family maps to the 13q11-q12.1 pericentromeric region.

Hidrotic ectodermal dysplasia (HED), Clouston syndrome (MIM No. 129500), is an autosomal dominant disorder affecting the skin and its derivatives. It is characterized by alopecia, dysplastic nails in hands and feet, and hyperkeratosis of the palms and soles. We have studied a large Indian pedigree (UR005), from Gujarat region, consisting of a total 127 individuals including 41 affected (12 males and 29 females). The phenotype in this family ranged from atrichosis to hypotrichosis, sparsity or absence of eyebrows, and thickening of palms and soles. In order to map the disease locus by linkage analysis, DNA polymorphisms were used in DNAs from 23 affected and 8 normal individuals. While genotyping was in progress, Kibar et al. [1996] reported mapping of the locus of a similar disease in French-Canadian families to 13q around marker D13S141. We then utilized markers on 13q to genotype the members of the Indian family. Linkage with 13q11-12.1 markers was confirmed with a maximum lod score of 3.27 (theta=0.00) with locus D13S1316. Multipoint linkage analysis yielded a lod score of 5.04 at theta=0.00 with D13S1316; haplotype analysis indicated that the gene for the Clouston syndrome in this family is localized proximal to D13S292. These data suggest that the gene for the Clouston syndrome in this Indian pedigree is probably the same as that described in the French Canadian families. The combination of data from all available families linked to 13q11-12.1 will make it possible to narrow the critical region and facilitate the positional cloning of the elusive gene.

Mapping one form of autosomal dominant postaxial polydactyly type A to chromosome 7p15-q11.23 by linkage analysis.

Postaxial polydactyly type-A (PAP-A) in humans is an autosomal dominant trait characterized by an extra digit in the ulnar and/or fibular side of the upper and/or lower extremities. The extra digit is well formed and articulates with the fifth, or extra, metacarpal/metatarsal, and thus it is usually functional. In order to map the gene responsible for PAP-A, we studied a five-generation Indian family of 37 individuals (15 of whom were affected). A genomewide search with highly informative polymorphic markers on part of the pedigree showed linkage between the PAP-A phenotype and markers on chromosome 7p15-q11.23 (no crossovers were found with D7S526, D7S795, D7S528, D7S521, D7S691, D7S667, D7S478, D7S1830, D7S803, D7S801, or ELN). The highest LOD score was obtained with marker D7S801 (zeta max = 4.21; theta = 0). Haplotype analysis enabled the mapping of the PAP-A phenotype in this family between markers D7S2848 and D7S669. Analysis of additional families with PAP-A will narrow down the critical genomic region, facilitate positional cloning of the PAP-A gene, and/or uncover potential genetic heterogeneity.

An autosomal dominant triphalangeal thumb: polysyndactyly syndrome with variable expression in a large Indian family maps to 7q36.

Hereditary developmental abnormalities of the upper or lower limbs in humans are easily recognizable phenotypes that can be used in the mapping and cloning of genes involved in normal human development. We studied a large Indian pedigree (UR002) with an autosomal dominant triphalangeal thumb (TPT) and polysyndactyly (PSD). The abnormalities were present only in the upper limbs, and the phenotype was fully penetrant. The expression of the phenotype was variable and ranged from unilateral TPT to bilateral TPT, preaxial du-, tri-, or quadruplication of the thumb, or syndactyly of multiple thumbs. There were 112 affected individuals in the pedigree. Previous linkage analyses on apparently similar phenotypes have identified a locus at 7q36 [Heutink et al., 1994, Nature Genet 6:287-291; Tsukurov et al., 1994]. To map the gene responsible for the TPT-PSD in family UR002, we performed linkage analysis in DNA from 47 affected and 7 normal individuals. Marker D7S550, located at 7q36, yielded a maximum LOD score of 11.31 at theta = 0.00. Additional markers in the region also showed no recombination. These data indicate that the gene responsible for the hand abnormality in pedigree UR002 maps to the same region as that in previous pedigrees with similar phenotype. Further analyses of recombinants among all the linked families by using new polymorphic markers will narrow the critical genomic region and facilitate positional cloning of the elusive gene.

Polydactyly: a study of a five generation Indian family.

Preaxial polydactyly was observed in up to five generations of an Indian family living in a village in the Rajkot district (Gujarat). Among the 71 affected members, 45 were males and 26 were females. All these affected members showed preaxial polydactyly manifesting as a well formed, articulated extra digit of the hand or foot. Twenty other cases were also identified with polydactyly involving triphalangeal digits replacing the thumbs or duplication of the big toe(s). To the best of our knowledge, the present family is the largest in which several members have preaxial polydactyly of different types. No other abnormalities were apparent. The present study strongly suggests that preaxial polydactyly with a well formed extra digit, triphalangeal thumbs, and duplication of the big toe can be manifestations of the same autosomal dominant gene. It is likely that other factors are modifying the expression of this gene.