Your search keyword '"Katta Mohan Girisha"' showing total 9 results

1. Exome sequencing in pediatric hematology: Where it falls short

Author

Robert Selvam, Periyasamy Radhakrishnan, Katta Mohan Girisha, M.V. Archana, Vivekananda Bhat, and Anju Shukla

Subjects

Pediatrics, RJ1-570

Published

2024

2. Biallelic mutations in the death domain of PIDD1 impair caspase-2 activation and are associated with intellectual disability

Author

Taimoor I. Sheikh, Nasim Vasli, Stephen Pastore, Kimia Kharizi, Ricardo Harripaul, Zohreh Fattahi, Shruti Pande, Farooq Naeem, Abrar Hussain, Asif Mir, Omar Islam, Katta Mohan Girisha, Muhammad Irfan, Muhammad Ayub, Christoph Schwarzer, Hossein Najmabadi, Anju Shukla, Valentina C. Sladky, Vincent Zoran Braun, Irmina Garcia-Carpio, Andreas Villunger, and John B. Vincent

Subjects

Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Abstract PIDD1 encodes p53-Induced Death Domain protein 1, which acts as a sensor surveilling centrosome numbers and p53 activity in mammalian cells. Early results also suggest a role in DNA damage response where PIDD1 may act as a cell-fate switch, through interaction with RIP1 and NEMO/IKKg, activating NF-κB signaling for survival, or as an apoptosis-inducing protein by activating caspase-2. Biallelic truncating mutations in CRADD—the protein bridging PIDD1 and caspase-2—have been reported in intellectual disability (ID), and in a form of lissencephaly. Here, we identified five families with ID from Iran, Pakistan, and India, with four different biallelic mutations in PIDD1, all disrupting the Death Domain (DD), through which PIDD1 interacts with CRADD or RIP1. Nonsense mutations Gln863* and Arg637* directly disrupt the DD, as does a missense mutation, Arg815Trp. A homozygous splice mutation in the fifth family is predicted to disrupt splicing upstream of the DD, as confirmed using an exon trap. In HEK293 cells, we show that both Gln863* and Arg815Trp mutants fail to co-localize with CRADD, leading to its aggregation and mis-localization, and fail to co-precipitate CRADD. Using genome-edited cell lines, we show that these three PIDD1 mutations all cause loss of PIDDosome function. Pidd1 null mice show decreased anxiety, but no motor abnormalities. Together this indicates that PIDD1 mutations in humans may cause ID (and possibly lissencephaly) either through gain of function or secondarily, due to altered scaffolding properties, while complete loss of PIDD1, as modeled in mice, may be well tolerated or is compensated for.

Published

2021

3. Extended analysis of exome sequencing data reveals a novel homozygous deletion of exons 3 and 4 in FUCA1 gene causing fucosidosis in an Indian family

Author

Michelle C. do Rosario, Greeshma Purushothama, Dhanya Lakshmi Narayanan, Shahyan Siddiqui, Katta Mohan Girisha, and Anju Shukla

Subjects

Pediatrics, Perinatology and Child Health, General Medicine, Anatomy, Genetics (clinical), Pathology and Forensic Medicine

Published

2023

4. Homozygous variant p.(Arg163Trp) in PIGH causes glycosylphosphatidylinositol biosynthesis defect with epileptic encephalopathy and delayed myelination

Author

Michelle C. do Rosario, Parneet Kaur, Katta Mohan Girisha, Stephanie Bielas, and Anju Shukla

Subjects

Glycosylphosphatidylinositols, Pediatrics, Perinatology and Child Health, Homozygote, Mutation, Humans, Membrane Proteins, Epilepsy, Generalized, General Medicine, Anatomy, Genetics (clinical), Pathology and Forensic Medicine

Published

2023

5. Loss of FOCAD, operating via the SKI messenger RNA surveillance pathway, causes a pediatric syndrome with liver cirrhosis

Author

Ricardo Moreno Traspas, Tze Shin Teoh, Pui-Mun Wong, Michael Maier, Crystal Y. Chia, Kenneth Lay, Nur Ain Ali, Austin Larson, Fuad Al Mutairi, Nouriya Abbas Al-Sannaa, Eissa Ali Faqeih, Majid Alfadhel, Huma Arshad Cheema, Juliette Dupont, Stéphane Bézieau, Bertrand Isidor, Dorrain Yanwen Low, Yulan Wang, Grace Tan, Poh San Lai, Hugues Piloquet, Madeleine Joubert, Hulya Kayserili, Kimberly A. Kripps, Shareef A. Nahas, Eric P. Wartchow, Mikako Warren, Gandham SriLakshmi Bhavani, Majed Dasouki, Renata Sandoval, Elisa Carvalho, Luiza Ramos, Gilda Porta, Bin Wu, Harsha Prasada Lashkari, Badr AlSaleem, Raeda M. BaAbbad, Anabela Natália Abreu Ferrão, Vasiliki Karageorgou, Natalia Ordonez-Herrera, Suliman Khan, Peter Bauer, Benjamin Cogne, Aida M. Bertoli-Avella, Marie Vincent, Katta Mohan Girisha, Bruno Reversade, Center for Reproductive Medicine, ACS - Heart failure & arrhythmias, and Amsterdam Reproduction & Development

Subjects

Adult, Liver Cirrhosis, Liver, Tumor Suppressor Proteins, Hepatocytes, Genetics, Animals, Humans, RNA, Messenger, Syndrome, Child, Zebrafish

Abstract

Cirrhosis is usually a late-onset and life-threatening disease characterized by fibrotic scarring and inflammation that disrupts liver architecture and function. While it is typically the result of alcoholism or hepatitis viral infection in adults, its etiology in infants is much less understood. In this study, we report 14 children from ten unrelated families presenting with a syndromic form of pediatric liver cirrhosis. By genome/exome sequencing, we found recessive variants in FOCAD segregating with the disease. Zebrafish lacking focad phenocopied the human disease, revealing a signature of altered messenger RNA (mRNA) degradation processes in the liver. Using patient’s primary cells and CRISPR-Cas9-mediated inactivation in human hepatic cell lines, we found that FOCAD deficiency compromises the SKI mRNA surveillance pathway by reducing the levels of the RNA helicase SKIC2 and its cofactor SKIC3. FOCAD knockout hepatocytes exhibited lowered albumin expression and signs of persistent injury accompanied by CCL2 overproduction. Our results reveal the importance of FOCAD in maintaining liver homeostasis and disclose a possible therapeutic intervention point via inhibition of the CCL2/CCR2 signaling axis.

Published

2022

6. Bi-allelic variants in CHKA cause a neurodevelopmental disorder with epilepsy and microcephaly

Author

Chiara Klöckner, J Pedro Fernández-Murray, Mahtab Tavasoli, Heinrich Sticht, Gisela Stoltenburg-Didinger, Leila Motlagh Scholle, Somayeh Bakhtiari, Michael C Kruer, Hossein Darvish, Saghar Ghasemi Firouzabadi, Alex Pagnozzi, Anju Shukla, Katta Mohan Girisha, Dhanya Lakshmi Narayanan, Parneet Kaur, Reza Maroofian, Maha S Zaki, Mahmoud M Noureldeen, Andreas Merkenschlager, Janina Gburek-Augustat, Elisa Cali, Selina Banu, Kamrun Nahar, Stephanie Efthymiou, Henry Houlden, Rami Abou Jamra, Jason Williams, Christopher R McMaster, and Konrad Platzer

Subjects

Epilepsy, Neurodevelopmental Disorders, Report, Microcephaly, Choline Kinase, Humans, Neurology (clinical), Nervous System Malformations, Alleles

Abstract

The Kennedy pathways catalyse the de novo synthesis of phosphatidylcholine and phosphatidylethanolamine, the most abundant components of eukaryotic cell membranes. In recent years, these pathways have moved into clinical focus because four of ten genes involved have been associated with a range of autosomal recessive rare diseases such as a neurodevelopmental disorder with muscular dystrophy (CHKB), bone abnormalities and cone-rod dystrophy (PCYT1A) and spastic paraplegia (PCYT2, SELENOI). We identified six individuals from five families with bi-allelic variants in CHKA presenting with severe global developmental delay, epilepsy, movement disorders and microcephaly. Using structural molecular modelling and functional testing of the variants in a cell-based Saccharomyces cerevisiae model, we determined that these variants reduce the enzymatic activity of CHKA and confer a significant impairment of the first enzymatic step of the Kennedy pathway. In summary, we present CHKA as a novel autosomal recessive gene for a neurodevelopmental disorder with epilepsy and microcephaly.

Published

2022

7. Novel biallelic variants expand the SLC5A6-related phenotypic spectrum

Author

Tess Holling, Sheela Nampoothiri, Bedirhan Tarhan, Pauline E. Schneeberger, Kollencheri Puthenveettil Vinayan, Dhanya Yesodharan, Arun Grace Roy, Periyasamy Radhakrishnan, Malik Alawi, Lindsay Rhodes, Katta Mohan Girisha, Peter B. Kang, and Kerstin Kutsche

Subjects

Peripheral neuropathies, Symporters, Genetics research, Sodium, Genetics, Biotin, Humans, Membrane Transport Proteins, Vitamins, Article, Pantothenic Acid, Genetics (clinical)

Abstract

The sodium (Na+):multivitamin transporter (SMVT), encoded by SLC5A6, belongs to the sodium:solute symporter family and is required for the Na+-dependent uptake of biotin (vitamin B7), pantothenic acid (vitamin B5), the vitamin-like substance α-lipoic acid, and iodide. Compound heterozygous SLC5A6 variants have been reported in individuals with variable multisystemic disorder, including failure to thrive, developmental delay, seizures, cerebral palsy, brain atrophy, gastrointestinal problems, immunodeficiency, and/or osteopenia. We expand the phenotypic spectrum associated with biallelic SLC5A6 variants affecting function by reporting five individuals from three families with motor neuropathies. We identified the homozygous variant c.1285 A > G [p.(Ser429Gly)] in three affected siblings and a simplex patient and the maternally inherited c.280 C > T [p.(Arg94*)] variant and the paternally inherited c.485 A > G [p.(Tyr162Cys)] variant in the simplex patient of the third family. Both missense variants were predicted to affect function by in silico tools. 3D homology modeling of the human SMVT revealed 13 transmembrane helices (TMs) and Tyr162 and Ser429 to be located at the cytoplasmic facing region of TM4 and within TM11, respectively. The SLC5A6 missense variants p.(Tyr162Cys) and p.(Ser429Gly) did not affect plasma membrane localization of the ectopically expressed multivitamin transporter suggesting reduced but not abolished function, such as lower catalytic activity. Targeted therapeutic intervention yielded clinical improvement in four of the five patients. Early molecular diagnosis by exome sequencing is essential for timely replacement therapy in affected individuals.

Published

2022

8. Variants in the zinc transporter TMEM163 cause a hypomyelinating leukodystrophy

Author

Michelle C do Rosario, Guillermo Rodriguez Bey, Bruce Nmezi, Fang Liu, Talia Oranburg, Ana S A Cohen, Keith A Coffman, Maya R Brown, Kirill Kiselyov, Quinten Waisfisz, Myrthe T Flohil, Shahyan Siddiqui, Jill A Rosenfeld, Alejandro Iglesias, Katta Mohan Girisha, Nicole I Wolf, Quasar Saleem Padiath, Anju Shukla, Human genetics, CCA - Cancer biology and immunology, Pediatrics, and Amsterdam Neuroscience - Cellular & Molecular Mechanisms

Subjects

Zinc, Pelizaeus-Merzbacher Disease, Mutation, Missense, Humans, Membrane Proteins, Neurology (clinical), Myelin Sheath

Abstract

Hypomyelinating leukodystrophies comprise a subclass of genetic disorders with deficient myelination of the CNS white matter. Here we report four unrelated families with a hypomyelinating leukodystrophy phenotype harbouring variants in TMEM163 (NM_030923.5). The initial clinical presentation resembled Pelizaeus–Merzbacher disease with congenital nystagmus, hypotonia, delayed global development and neuroimaging findings suggestive of significant and diffuse hypomyelination. Genomic testing identified three distinct heterozygous missense variants in TMEM163 with two unrelated individuals sharing the same de novo variant. TMEM163 is highly expressed in the CNS particularly in newly myelinating oligodendrocytes and was recently revealed to function as a zinc efflux transporter. All the variants identified lie in highly conserved residues in the cytoplasmic domain of the protein, and functional in vitro analysis of the mutant protein demonstrated significant impairment in the ability to efflux zinc out of the cell. Expression of the mutant proteins in an oligodendroglial cell line resulted in substantially reduced mRNA expression of key myelin genes, reduced branching and increased cell death. Our findings indicate that variants in TMEM163 cause a hypomyelinating leukodystrophy and uncover a novel role for zinc homeostasis in oligodendrocyte development and myelin formation.

Published

2022

9. Genomic Testing for Diagnosis of Genetic Disorders in Children: Chromosomal Microarray and Next-Generation Sequencing

Author

Dhanya Lakshmi, Narayanan and Katta Mohan, Girisha

Subjects

Intellectual Disability, High-Throughput Nucleotide Sequencing, Humans, Genetic Testing, Autistic Disorder, Child, Microarray Analysis

Abstract

Chromosomal microarray and Next-generation sequencing are two widely used genomic tests that have improved the diagnosis of children with a genetic condition. Chromosomal microarray has become a first-tier test in evaluating children with intellectual disability, multiple malformations and autism due to its higher yield and resolution. Next generation sequencing, that includes targeted panel testing, exome sequencing and whole genome sequencing ends diagnostic odyssey in 25-30% of unselected children with rare monogenic syndromes, especially when the condition is genetically heterogeneous. This article provides a review of these genomic tests for pediatricians.

Published

2020