Genomic Variations in ATP7B Gene in Indian Patients with Wilson Disease.

OBJECTIVE: To report genotype data of the patients with Wilson disease (WD) hailing from across several parts of India to add to the available spectrum of causative variants in ATP7B gene (ATPase copper transporting beta polypeptide gene) and associated phenotypes in the Indian population. METHODS: The entire ATP7B gene was sequenced in 58 patients with WD and additional testing was also done by MLPA to look for intragenic deletions duplications and exome sequencing to rule out genetic variations with similar phenotypic overlap. RESULTS: Of all patients, 37 patients had a total of 33 distinct pathogenic variations, including 29 in the exonic regions and 4 at intronic splice sites. Of the variations identified, six were novel. The underlying genomic variations could be identified in nearly two-thirds of the patients by sequencing the entire gene. CONCLUSIONS: This study reports the genotype-phenotype data to add to the available spectrum of causative variants in ATP7B gene. The inability to detect a pathogenic variation in some patients and the existence of phenotypic variations in individuals with the same variation suggest that additional factors or genes may play a role in causation of the disease. Further, a marked genetic heterogeneity was found in the study patients, indicating ethnic diversity of the Indian population.

COASY related pontocerebellar hypoplasia type 12: A common Indian mutation with expansion of the phenotypic spectrum.

Pontocerebellar hypoplasia (PCH) type 12 is a rare, perinatal lethal neurodegenerative genetic disorder caused by biallelic mutations in the COASY gene. Herein, we describe the clinical and neuroradiological profile of nine affected fetuses/neonates from five families identified with a common COASY: c.1486-3C>G biallelic variant. Four of the five families were identified after data reanalysis of unresolved, severe PCH like phenotype and the fifth family through collaboration. The common antenatal phenotype was cerebellar hypoplasia. Microcephaly, arthrogryposis, and intrauterine growth restriction were the shared postnatal findings. The neurological manifestations included seizures, poor sucking, and spasticity. Novel findings of corpus callosum agenesis, simplified gyral pattern, normal sized pons, optic neuropathy, and a small thorax are reported in this series. The allele frequency of the COASY: c.1486-3C>G variant was 0.62% in the available Asian Indian database. We describe this as a possible common Indian origin variant. To the best of our knowledge, this is the largest PCH12 series reported.

Deciphering the molecular landscape of microcephaly in 87 Indian families by exome sequencing.

Microcephaly is a frequent feature of neurodevelopmental disorders (NDDs). Our study presents the heterogeneous spectrum of genetic disorders in patients with microcephaly either in isolated form or in association with other neurological and extra-neural abnormalities. We present data of 91 patients from 87 unrelated families referred to our clinic during 2016-2020 and provide a comprehensive clinical and genetic landscape in the studied cohort. Molecular diagnosis using exome sequencing was made in 45 families giving a yield of 51.7%. In 9 additional families probable causative variants were detected. We identified disease causing variations in 49 genes that are involved in different functional pathways Among these, 36 had an autosomal recessive pattern, 8 had an autosomal dominant pattern (all inherited de novo), and 5 had an X-linked pattern. In 41 probands where sequence variations in autosomal recessive genes were identified 31 were homozygotes (including 16 from non-consanguineous families). The study added 28 novel pathogenic/likely pathogenic variations. The study also calls attention to phenotypic variability and expansion in spectrum as well as uncovers genes where microcephaly is not reported previously or is a rare finding. We here report phenotypes associated with the genes for ultra-rare NDDs with microcephaly namely ATRIP, MINPP1, PNPLA8, AIMP2, ANKLE2, NCAPD2 and TRIT1.

Variable neurological phenotypes of homocystinuria caused by biallelic methylenetetrahydrofolate reductase variants.

Inherited methylenetetrahydrofolate reductase (MTHFR) deficiency is associated with a wide spectrum of disorders including homocystinuria. This study aims to describe the neurological phenotypes and molecular profiles of patients with homocystinuria caused by biallelic variants in MTHFR. We report six subjects with MTHFR deficiency who presented with variable neurological phenotypes which could be viewed as a continuous spectrum. Fatal infantile encephalopathy was observed in one family, whereas another patient presented at 27 years with acute leukoencephalopathy and recovered within 3 months. Intermediate forms presenting as complicated hereditary spastic paraparesis of variable severity were observed in four subjects. Clinical and molecular information of the 207 cases reported in literature were also retrieved and analyzed. We categorized all subjects into three categories - severe, intermediate and mild forms according to the clinical presentation. In addition, a total of 286 disease-causing variations reported to date were analyzed. These included seven disease-causing variants reported in this study of which one is novel. Some genotype-phenotype correlation could be seen which corroborated with previous observations. However, inter- and intrafamilial variability was also noted. Treatment with betaine, B12 and folic acid was started in four subjects with variable outcomes.

Molecular analysis of severe hemophilia B in Indian families: Identification of mutational hotspot and novel variants.

INTRODUCTION: Hemophilia B is associated with molecular heterogeneity, with more than 1200 unique variants in the F9 gene. We hereby describe the mutational spectrum of severe hemophilia B patients presenting in a tertiary-care center in India. METHOD: DNA was extracted from peripheral blood samples of 35 diagnosed severe hemophilia B patients belonging to 32 families, and were subjected to Sanger sequencing. Determination of the effect of novel variants on the protein structure and correlation between genotype and phenotype was attempted using in-silico tools. RESULTS: Twenty-seven different mutations were detected in 30 probands, including 20 known and 7 novel variants. Also, we found one suspected case of whole gene deletion. The serine peptidase domain harbored most of the variants (48.1%). Inhibitory antibodies were found in two patients. CONCLUSIONS: This study provides a comprehensive mutational spectrum and mutation screening strategy by Sanger sequencing of F9 gene in severe hemophilia B patients, in a resource-constraint setting.

Homozygous Missense Variation in PNPLA8 Causes Prenatal-Onset Severe Neurodegeneration.

The patatin-like protein family plays an important role in various biological functions including lipid homeostasis, cellular growth, and signaling. Conserved across species, the patatin domain is shared by all 9 members of the PNPLA family without redundancy in the coding sequences. The defective function of PNPLA2, PNPLA6, and PNPLA9 are known to cause mitochondrial-related neurodegeneration. Recently, PNPLA8 has been associated with mitochondrial myopathy and poor weight gain with lactic acidosis in 3 unrelated families. Using whole-exome sequencing, we identified a homozygous novel missense variation c.1874A>G in the patatin domain of PNPLA8. The patient had prenatal-onset severe and progressive neurodegeneration with mortality in infancy.

Homozygosity stretches around homozygous mutations in autosomal recessive disorders: patients from nonconsanguineous Indian families.

India has a large heterogeneous population with its unique social and genetic characteristics. Tradition of marriage between specific caste groups have produced unique characteristics to the mutation spectrum of genetic disorders and may be a higher prevalence of autosomal recessive (AR) disorders in some communities. We observed that in many nonconsanguineous families with rare autosomal disorders, maternally and paternally inherited mutations are same, indicating common ancestor. In this era of genomic techniques, finding homozygous regions have become easy. It was seen that the patients with AR disorders, who were homozygous for the disease causing pathogenic / likely pathogenic variations, have large stretches (0.6-188 Mb) of homozygosity around the causative sequence variations. SNP microarray data of patients from consanguineous and nonconsanguineous families also showed that even patients from nonconsanguineous families had 3-49 Mb size regions of homozygosity. Long stretches of homozygosity around homozygous rare pathogenic variants in nonconsanguineous families with rare AR disorders supports the notion that these couples may have a common ancestor for more than six generations and the system of marriages between same groups. Hence, using the strategy of homozygosity by descent even in nonconsanguineous families can be fruitful in identifying the novel pathogenic variations and novel genes.

Twins with PEX7 related intellectual disability and cataract: Highlighting phenotypes of peroxisome biogenesis disorder 9B.

Peroxisome biogenesis disorders (PBDs) are a group of autosomal recessive disorders caused due to impaired peroxisome assembly affecting the formation of functional peroxisomes. PBDs are caused by a mutation in PEX gene family resulting in disease manifestation with extreme variability ranging from the onset of profound neurologic symptoms in newborns to progressive degenerative disease in adults. Disease causing variations in PEX7 is known to cause severe rhizomelic chondrodysplasia punctata type 1 and PBD 9B, an allelic disorder resulting in a milder phenotype, often indistinguishable from that of classic Refsum disease. This case report highlights the variability of PEX7 related phenotypes and suggests that other than RCDP1 and late onset phenotype similar to Refsum disease, some cases present with cataract and neurodevelopmetal abnormalities during childhood without chondrodysplasia or rhizomelia. This report also underlines the importance of considering PBD 9B in children presenting with neurodevelopmental abnormalities especially if they have congenital cataract.

Renpenning syndrome in an Indian patient.

Renpenning syndrome is one of the well-characterized causes of X-linked intellectual disability and is associated with microcephaly and various visceral malformations. Face is considered characteristic but the dysmorphism is subtle. Here we report an Indian adult with a very lean habitus, progressive atrophy of the upper back muscles, microcephaly, loss of cervical lordosis, and upper thoracic scoliosis. Using whole-exome sequencing, a hemizygous deletion was identified in PQBP1 that leads to a frameshift and premature termination of translation. The loss of normal curvatures of cervical and upper thoracic spine due to muscular atrophy is a characteristic feature, though it may be age dependent.