Utility and performance of bacterial artificial chromosomes-on-beads assays in chromosome analysis of clinical prenatal samples, products of conception and blood samples.

AIM: Chromosome analysis of prenatal samples and products of conception (POC) has conventionally been done by karyotyping (KT). Shortcomings of KT like high turnaround time and culture failure led to technology innovations, such as the bacterial artificial chromosomes (BAC)s-on-Beads (BoBs)-based tests, Prenatal BoBs (prenatal samples) and KaryoLite BoBs (POC samples). In the present study, we validated and evaluated the utility of each test on prenatal, POC and blood samples. METHODS: Study A (n = 305; 259 prenatal + 46 blood/POC) and Study B (n = 176; 146 POC/chorionic vill + 30 blood/amniotic fluid) samples were analyzed using Prenatal and KaryoLite BoBs kits, respectively. KT, array-based Comparative Genomic Hybridization (arrayCGH) and fluorescence in situ hybridization (FISH) were used for comparison of results. Ability of KaryoLite BoBs to identify ring chromosomes was tested. RESULTS: Prenatal BoBs had zero test failure rate and results of all samples were concordant with KT results. Totally four microdeletions were identified by Prenatal BoBs but not by KT. In Study B, all but two POC samples (one triploid and one tetraploid) were concordant with KT and arrayCGH. Partial chromosomal imbalance detection rate was ~64% and KaryoLite BoBs indicated the presence of a ring chromosome in all four cases. The failure rate of KaryoLite BoBs was 3%. CONCLUSION: We conclude that Prenatal BoBs (common aneuploidies and nine microdeletions) together with KT constitutes more comprehensive prenatal testing compared to FISH and KT. KaryoLite BoBs for aneuploidies of all chromosomes is highly successful in POC analysis and the ability to indicate presence of ring chromosomes improves its clinical sensitivity. Both tests are robust and could also be used for different specimens.

The promise of discovering population-specific disease-associated genes in South Asia.

The more than 1.5 billion people who live in South Asia are correctly viewed not as a single large population but as many small endogamous groups. We assembled genome-wide data from over 2,800 individuals from over 260 distinct South Asian groups. We identified 81 unique groups, 14 of which had estimated census sizes of more than 1 million, that descend from founder events more extreme than those in Ashkenazi Jews and Finns, both of which have high rates of recessive disease due to founder events. We identified multiple examples of recessive diseases in South Asia that are the result of such founder events. This study highlights an underappreciated opportunity for decreasing disease burden among South Asians through discovery of and testing for recessive disease-associated genes.

Mutations in ARSB in MPS VI patients in India.

Mucopolysaccharidosis VI (MPS VI) is an autosomal recessive inborn error of metabolism caused by mutations in the arylsulfatase B gene (ARSB) and consequent deficient activity of ARSB, a lysosomal enzyme. We present here the results of a study undertaken to identify the mutations in ARSB in MPS VI patients in India. Around 160 ARSB mutations, of which just 4 are from India, have been reported in the literature. Our study covered nine MPS VI patients from eight families. Both familial mutations were found in seven families, and only one mutation was found in one family. Seven mutations were found - four novel (p.G38_G40del3, p.C91R, p.L98R and p.R315P), two previously reported from India (p.D53N and p.W450C), and one reported from outside India (p.R160Q). One mutation, p.W450C, was present in two families, and the other six mutations were present in one family each. Analysis of the molecular structure of the enzyme revealed that most of these mutations either cause loss of an active site residue or destabilize the structure of the enzyme. The only previous study on mutations in ARSB in Indian MPS VI patients, by Kantaputra et al. 2014 [1], reported four novel mutations of which two (p.D53N and p.W450C) were found in our study as well. Till date, nine mutations have been reported from India, through our study and the Kantaputra study. Eight out of these nine mutations have been found only in India. This suggests that the population studied by us might have its own typical set of mutations, with other populations equally likely to have their own set of mutations.