Generation and characterization of iPSC lines from Friedreich's ataxia patient (FRDA) with GAA.TTC repeat expansion in the Frataxin (FXN) gene's first intron (IGIBi016-A) and a non-FRDA healthy control individual (IGIBi017-A).

Friedreich's ataxia is a spinocerebellar degenerative disease caused by microsatellite (GAA.TTC)n repeat expansion in the first intron of FXN gene. Here, we developed iPSC lines from an FRDA patient (IGIBi016-A) and non-FRDA healthy control (IGIBi017-A). Both iPSC lines displayed typical iPSC morphology, expression of pluripotency markers, regular karyotypes (46, XY; 46, XX), capacity to grow into three germ layers, and FRDA hallmark -GAA repeat expansion and decreased FXN mRNA. Through these iPSC lines, FRDA phenotypes may be replicated in the in vitro assays, by creating neuron subtypes, cardiomyocytes and 3D organoids, for molecular and cellular biomarkers and therapeutic applications.

Generation of an Induced pluripotent stem cell (iPSC) line (IGIBi011-A) from a Spinocerebellar ataxia type 12 gait dominant patient.

The PPP2R2B gene, expressed highly in the brain, harbours trinucleotide CAG repeats in the 5'UTR region, in the range of 7-42 repeats. Individuals carrying CAG repeats greater than 43 have been associated to manifest a neurodegenerative disease condition termed as Spinocerebellar Ataxia type 12 (SCA12). An iPSC line from an adult male diagnosed with SCA12 presenting symptoms of gait (Gait Dominance) was generated. It showed pluripotency and trilineage markers without any chromosomal abnormality. This line can be utilized as an essential resource in enhancing our understanding of the molecular pathogenic mechanisms underlying SCA12 by facilitating generation of various neuronal cell types.

Genetics of Ataxias in Indian Population: A Collative Insight from a Common Genetic Screening Tool.

Cerebellar ataxias (CAs) represent a group of autosomal dominant and recessive neurodegenerative disorders affecting cerebellum with or without spinal cord. Overall, CAs have preponderance for tandem nucleotide repeat expansions as an etiological factor (10 TREs explain nearly 30-40% of ataxia cohort globally). The experience of 10 years of common genetic ataxia subtypes for ≈5600 patients' referrals (Pan-India) received at a single center is shared herein. Frequencies (in %, n) of SCA types and FRDA in the sample cohort are observed as follows: SCA12 (8.6%, 490); SCA2 (8.5%, 482); SCA1 (4.8%, 272); SCA3 (2%, 113); SCA7 (0.5%, 28); SCA6 (0.1%, 05); SCA17 (0.1%, 05), and FRDA (2.2%, 127). A significant amount of variability in TRE lengths at each locus is observed, we noted presence of biallelic expansion, co-occurrence of SCA-subtypes, and the presence of premutable normal alleles. The frequency of mutated GAA-FRDA allele in healthy controls is 1/158 (0.63%), thus an expected FRDA prevalence of 1:100 000 persons. The data of this study are relevant not only for clinical decision making but also for guidance in direction of genetic investigations, transancestral comparison of genotypes, and lastly provide insight for policy decision for the consideration of SCAs under rare disease category.

Next Generation Sequencing and Cytogenetic Based Evaluation of Indian Pierre Robin Sequence Families Reveals CNV Regions of Modest Effect and a Novel LOXL3 Mutation.

BACKGROUND: Pierre Robin Sequence (PRS) affects approximately 1 per 8500 to 14000 new-borns worldwide. Although the clinical entity is well defined, the pathogenesis of PRS is debated. The present study aims to understand the contribution of genomic imbalances and genetic variants in patients clinically diagnosed of PRS. METHODOLOGY: A total of 7 independent patients with nonsyndromic PRS thoroughly evaluated by a medical geneticist at a tertiary care hospital, were included in the study. Blood samples were collected from these patients and their family members. Array CGH was performed on all 7 patients and their respective family members for detection of underlying cytogenetic defects. Whole exome sequencing (WES) was performed for 5 families to capture single nucleotide variants or small indels. RESULTS: Cytogenetic analyses did not detect any previously reported gross chromosomal aberrations for PRS in the patient cohort. However, copy number variations (CNVs) of size <1 Mb were detected in patients which may have implications in PRS. The present study provided evidence for the occurrence of de novo deletions at 7p14.1 locus in PRS patients: further validating the candidate loci susceptibility in oral clefts. WES data identified LOXL3 as candidate gene, carrying novel deleterious variant, which is suggestive of the role of point mutations in the pathogenesis of PRS. CONCLUSION: The present study offered considerable insight into the contribution of cytogenetic defects and novel point mutation in the etiology of nonsyndromic PRS. Studies comprising large number of cases are required to fully elucidate the genetic mechanisms underlying the PRS phenotype.

Biallelic cGMP-dependent type II protein kinase gene (PRKG2) variants cause a novel acromesomelic dysplasia.

BACKGROUND: C-type natriuretic peptide (CNP), its endogenous receptor, natriuretic peptide receptor-B (NPR-B), as well as its downstream mediator, cyclic guanosine monophosphate (cGMP) dependent protein kinase II (cGKII), have been shown to play a pivotal role in chondrogenic differentiation and endochondral bone growth. In humans, biallelic variants in NPR2, encoding NPR-B, cause acromesomelic dysplasia, type Maroteaux, while heterozygous variants in NPR2 (natriuretic peptide receptor 2) and NPPC (natriuretic peptide precursor C), encoding CNP, cause milder phenotypes. In contrast, no variants in cGKII, encoded by the protein kinase cGMP-dependent type II gene (PRKG2), have been reported in humans to date, although its role in longitudinal growth has been clearly demonstrated in several animal models. METHODS: Exome sequencing was performed in two girls with severe short stature due to acromesomelic limb shortening, brachydactyly, mild to moderate platyspondyly and progressively increasing metaphyseal alterations of the long bones. Functional characterisation was undertaken for the identified variants. RESULTS: Two homozygous PRKG2 variants, a nonsense and a frameshift, were identified. The mutant transcripts are exposed to nonsense-mediated decay and the truncated mutant cGKII proteins, partially or completely lacking the kinase domain, alter the downstream mitogen activation protein kinase signalling pathway by failing to phosphorylate c-Raf 1 at Ser43 and subsequently reduce ERK1/2 activation in response to fibroblast growth factor 2. They also downregulate COL10A1 and upregulate COL2A1 expression through SOX9. CONCLUSION: In conclusion, we have clinically and molecularly characterised a new acromesomelic dysplasia, acromesomelic dysplasia, PRKG2 type (AMDP).

Next-Generation Sequencing for Congenital Nephrotic Syndrome: A Multi-Center Cross-Sectional Study from India.

OBJECTIVE: Information on etiology of congenital nephrotic syndrome in non-Caucasian populations is limited. This study aimed to determine the genetic basis of congenital nephrotic syndrome in Indian patients. METHODS: In this observational, cross-sectional study, whole exome sequencing was performed on samples from all children diagnosed with congenital nephrotic syndrome, presenting at centers collaborating in a nationwide registry and biorepository. Analysis was targeted to focus on reported or novel, pathogenic or likely pathogenic variants in 89 genes implicated in etiology of nephrotic syndrome. Sanger sequencing was used to confirm disease-causing variants in patients and allelic segregation of compound heterozygous variants in samples from parents. Inheritance of a shared haplotype was analyzed among ten individuals carrying the most common variant. RESULTS: During 2017-2019, 34 patients with congenital nephrotic syndrome were screened. Consanguinity and similar illness in siblings were reported in eleven patients each. Homozygous or compound heterozygous, pathogenic or likely pathogenic variants were found in NPHS1 in 24 cases, including two novel variants. One patient each had homozygous pathogenic or likely pathogenic known or novel variant in NPHS2, PLCE1, OSGEP and LAMB2 genes. Patients with OSGEP and LAMB2 mutations had phenotype typical of Galloway Mowat and Pierson syndromes, respectively. Three variants in NPHS1 were common to 16 individuals. One reported variant in exon 19 (c.2600G>A; p.Gly867Asp) appears to share a common founder. CONCLUSIONS: A genetic cause was determined for 82.4% patients with congenital nephrotic syndrome. Variants in NPHS1 are most common in Indian patients and founder mutations might be present.

Generation of induced pluripotent stem cell line (IGIBi007-A) from a patient with a novel acromesomelic dysplasia, PRKG2 type (AMDP).

Biallelic PRKG2 (Protein Kinase, cGMP dependent Type-2) mutations cause a novel acromesomelic dysplasia PRKG2 type. We report generation of induced pluripotent stem cell line from lymphoblastoid cell lines of the patient carrying the reported frameshift mutation (p.Asn164Lysfs*2). The derived iPSC line exhibits all the features of pluripotency, free of major genetic alterations due to reprogramming process and has the capability to differentiate into three germ layers. This iPSC cell line may provide an opportunity to investigate the effect of PRKG2 mutations upon FGF (fibroblast-growth-factor) induced MAPK signalling involved in chondrocyte proliferation in-vitro and may aid in possible therapeutic screening of novel biomolecules.

Frequency spectrum of rare and clinically relevant markers in multiethnic Indian populations (ClinIndb): A resource for genomic medicine in India.

There have been concerted efforts toward cataloging rare and deleterious variants in different world populations using high-throughput genotyping and sequencing-based methods. The Indian population is underrepresented or its information with respect to clinically relevant variants is sparse in public data sets. The aim of this study was to estimate the burden of monogenic disease-causing variants in Indian populations. Toward this, we have assessed the frequency profile of monogenic phenotype-associated ClinVar variants. The study utilized a genotype data set (global screening array, Illumina) from 2795 individuals (multiple in-house genomics cohorts) representing diverse ethnic and geographically distinct Indian populations. Of the analyzed variants from Global Screening Array, ~9% were found to be informative and were either not known earlier or underrepresented in public databases in terms of their frequencies. These variants were linked to disorders, namely inborn errors of metabolism, monogenic diabetes, hereditary cancers, and various other hereditary conditions. We have also shown that our study cohort is genetically a better representative of the Indian population than its representation in the 1000 Genome Project (South Asians). We have created a database, ClinIndb, linked to the Leiden Open Variation Database, to help clinicians and researchers in diagnosis, counseling, and development of appropriate genetic screening tools relevant to the Indian populations and Indians living abroad.

Encephalopathy due to defective mitochondrial and peroxisomal fission 2 caused by a novel MFF gene mutation in a young child.

Encephalopathy due to defective mitochondrial and peroxisomal fission 2 caused by mitochondrial fission factor (MFF) gene mutation is a rare neurogenetic disorder. Pathogenic MFF mutations have been described in three reports in literature so far. We report a young child of Indian descent who presented to us with global developmental followed by regression of acquired milestones, spasticity, visual and auditory impairment, and was found to harbor a novel pathogenic homozygous MFF truncating variant c.433C>T; p.Arg145Ter. Cellular imaging of patient lymphoblastoid cell line had shown abnormal shapes of mitochondria due to fission defects. The patient has been started on mitochondrial cocktail with some improvement.

C9orf72 hexanucleotide repeat expansion in Indian patients with ALS: a common founder and its geographical predilection.

Hexanucleotide repeat expansion in C9orf72 is defined as a major causative factor for familial amyotrophic lateral sclerosis (ALS). The mutation frequency varies dramatically among populations of different ethnicity; however, in most cases, C9orf72 mutant has been described on a common founder haplotype. We assessed its frequency in a study cohort involving 593 clinically and electrophysiologically defined ALS cases. We also investigated the presence of reported Finnish haplotype among the mutation carriers. The identified common haplotype region was further screened in 192 (carrying 2-6 G4C2 repeats) and 96 (≥7 repeats) control chromosomes. The G4C2 expansion was observed in 3.2% (19/593) of total cases where 9/19 (47.4%) positive cases belonged to the eastern region of India. Haplotype analysis revealed 11 G4C2-Ex carriers shared the common haplotype (haplo-A) background spanning a region of ∼90 kbp (rs895021-rs11789520) including rs3849942 (a well-known global at-risk loci with T allele for G4C2 expansion). The other 3 G4C2-Ex cases had a different haplotype (haplo-B) with core difference from haplo-A at G4C2-Ex flanking 31 kbp region between rs3849942 and rs11789520 SNPs (allele 'C' of rs3849942 which is a nonrisk allele). Out of other five G4C2-cases, four carried the risk allele T of rs3849942 while one harbored the non-risk allele. This study establishes the prevalence of C9orf72 expansion in Indian ALS cases providing further evidence for geographical predilection. The global core risk haplotype predominated C9orf72 expansion-positive ALS cases, yet the existence of a different haplotype suggests a second lineage (haplo B), which may have been derived from the Finnish core haplotype or may imply a unique haplotype among Asians. The association of risk haplotype with normal intermediate C9orf72 alleles reinforced its role in conferring instability to the C9orf72-G4C2 region. We thus present an effective support to interpret future burden of ALS cases in India.