Your search keyword '"Ramsahoye, Bernard"' showing total 22 results

1. Quantitative modelling predicts the impact of DNA methylation on RNA polymerase II traffic

Author

Cholewa-Waclaw, Justyna, Shah, Ruth, Webb, Shaun, Chhatbar, Kashyap, Ramsahoye, Bernard, Pusch, Oliver, Yu, Miao, Greulich, Philip, Waclaw, Bartlomiej, and Bird, Adrian P.

Published

2019

2. DNA hypomethylation leads to cGAS‐induced autoinflammation in the epidermis

Author

Beck, Mirjam A, Fischer, Heinz, Grabner, Lisa M, Groffics, Tamara, Winter, Mircea, Tangermann, Simone, Meischel, Tina, Zaussinger‐Haas, Barbara, Wagner, Patrick, Fischer, Carina, Folie, Christina, Arand, Julia, Schöfer, Christian, Ramsahoye, Bernard, Lagger, Sabine, Machat, Georg, Eisenwort, Gregor, Schneider, Stephanie, Podhornik, Alexandra, Kothmayer, Michael, Reichart, Ursula, Glösmann, Martin, Tamir, Ido, Mildner, Michael, Sheibani‐Tezerji, Raheleh, Kenner, Lukas, Petzelbauer, Peter, Egger, Gerda, Sibilia, Maria, Ablasser, Andrea, and Seiser, Christian

Published

2021

3. Requirement of DNMT1 to orchestrate epigenomic reprogramming for NPM-ALK–driven lymphomagenesis

Author

Redl, Elisa, primary, Sheibani-Tezerji, Raheleh, additional, Cardona, Crhistian de Jesus, additional, Hamminger, Patricia, additional, Timelthaler, Gerald, additional, Hassler, Melanie Rosalia, additional, Zrimšek, Maša, additional, Lagger, Sabine, additional, Dillinger, Thomas, additional, Hofbauer, Lorena, additional, Draganić, Kristina, additional, Tiefenbacher, Andreas, additional, Kothmayer, Michael, additional, Dietz, Charles H, additional, Ramsahoye, Bernard H, additional, Kenner, Lukas, additional, Bock, Christoph, additional, Seiser, Christian, additional, Ellmeier, Wilfried, additional, Schweikert, Gabriele, additional, and Egger, Gerda, additional

Published

2020

4. Activation of transcription factor circuity in 2i-induced ground state pluripotency is independent of repressive global epigenetic landscapes

Author

Shukla, Ruchi, primary, Mjoseng, Heidi K, additional, Thomson, John P, additional, Kling, Simon, additional, Sproul, Duncan, additional, Dunican, Donncha S, additional, Ramsahoye, Bernard, additional, Wongtawan, Tuempong, additional, Treindl, Fridolin, additional, Templin, Markus F, additional, Adams, Ian R, additional, Pennings, Sari, additional, and Meehan, Richard R, additional

Published

2020

5. Requirement of DNMT1 to orchestrate epigenomic reprogramming during NPM-ALK driven T cell lymphomagenesis

Author

Redl, Elisa, primary, Sheibani-Tezerji, Raheleh, additional, Hamminger, Patricia, additional, Timelthaler, Gerald, additional, Hassler, Melanie Rosalia, additional, Lagger, Sabine, additional, Dillinger, Thomas, additional, Hofbauer, Lorena, additional, Zrimšek, Maša, additional, Tiefenbacher, Andreas, additional, Kothmayer, Michael, additional, Dietz, Charles H., additional, Ramsahoye, Bernard H., additional, Kenner, Lukas, additional, Bock, Christoph, additional, Seiser, Christian, additional, Ellmeier, Wilfried, additional, Schweikert, Gabriele, additional, and Egger, Gerda, additional

Published

2020

6. ITPase Deficiency Causes a Martsolf-Like Syndrome With a Lethal Infantile Dilated Cardiomyopathy

Author

Handley, Mark T., Reddy, Kaalak, Wills, Jimi, Rosser, Elisabeth, Kamath, Archith, Halachev, Mihail, Falkous, Gavin, Williams, Denise, Cox, Phillip, Meynert, Alison, Raymond, Eleanor S., Morrison, Harris, Brown, Stephen, Allan, Emma, Aligianis, Irene, Jackson, Andrew P., Ramsahoye, Bernard H., von Kriegsheim, Alex, Taylor, Robert W., Finch, Andrew J., and FitzPatrick, David R.

Subjects

Male, Embryology, DNA Mutational Analysis, Glycobiology, Artificial Gene Amplification and Extension, QH426-470, Biochemistry, Polymerase Chain Reaction, Mice, Medicine and Health Sciences, Pyrophosphatases, Energy-Producing Organelles, Mice, Knockout, Mammalian Genomics, Homozygote, Nucleosides, Heart, Mouse Embryonic Stem Cells, Genomics, Glycosylamines, Mitochondrial DNA, Mitochondria, Pedigree, Nucleic acids, Child, Preschool, Female, Anatomy, Cellular Structures and Organelles, Transcriptome Analysis, Research Article, Cardiomyopathy, Dilated, Forms of DNA, Bioenergetics, Research and Analysis Methods, DNA, Mitochondrial, Cataract, Intellectual Disability, Exome Sequencing, Genetics, Animals, Humans, Molecular Biology Techniques, Molecular Biology, Base Sequence, Hypogonadism, Embryos, Biology and Life Sciences, Computational Biology, DNA, Cell Biology, Genome Analysis, Inosine, Animal Genomics, Mutation, Cardiovascular Anatomy, RNA, Metabolism, Inborn Errors, Developmental Biology

Abstract

Typical Martsolf syndrome is characterized by congenital cataracts, postnatal microcephaly, developmental delay, hypotonia, short stature and biallelic hypomorphic mutations in either RAB3GAP1 or RAB3GAP2. Genetic analysis of 85 unrelated “mutation negative” probands with Martsolf or Martsolf-like syndromes identified two individuals with different homozygous null mutations in ITPA, the gene encoding inosine triphosphate pyrophosphatase (ITPase). Both probands were from multiplex families with a consistent, lethal and highly distinctive disorder; a Martsolf-like syndrome with infantile-onset dilated cardiomyopathy. Severe ITPase-deficiency has been previously reported with infantile epileptic encephalopathy (MIM 616647). ITPase acts to prevent incorporation of inosine bases (rI/dI) into RNA and DNA. In Itpa-null cells dI was undetectable in genomic DNA. dI could be identified at a low level in mtDNA without detectable mitochondrial genome instability, mtDNA depletion or biochemical dysfunction of the mitochondria. rI accumulation was detectable in proband-derived lymphoblastoid RNA. In Itpa-null mouse embryos rI was detectable in the brain and kidney with the highest level seen in the embryonic heart (rI at 1 in 385 bases). Transcriptome and proteome analysis in mutant cells revealed no major differences with controls. The rate of transcription and the total amount of cellular RNA also appeared normal. rI accumulation in RNA–and by implication rI production—correlates with the severity of organ dysfunction in ITPase deficiency but the basis of the cellulopathy remains cryptic. While we cannot exclude cumulative minor effects, there are no major anomalies in the production, processing, stability and/or translation of mRNA., Author summary Nucleotide triphosphate bases containing inosine, ITP and dITP, are continually produced within the cell as a consequence of various essential biosynthetic reactions. The enzyme inosine triphosphate pyrophosphatase (ITPase) scavenges ITP and dITP to prevent their incorporation into RNA and DNA. Here we describe two unrelated families with complete loss of ITPase function as a consequence of disruptive mutations affecting both alleles of ITPA, the gene that encodes this protein. Both of the families have a very distinctive and severe combination of clinical problems, most notably a failure of heart muscle that was lethal in infancy or early childhood. They also have features that are reminiscent of another rare genetic disorder affecting the brain and the eyes called Martsolf syndrome. We could not detect any evidence of dITP accumulation in double-stranded DNA from the nucleus in cells from the affected individuals. A low but detectable level of inosine was present in the circular double-stranded DNA present in mitochondria but this did not have any obvious detrimental effect. The inosine accumulation in RNA was detectable in the patient cells. We made both cellular and animal models that were completely deficient in ITPase. Using these reagents we could show that the highest level of inosine accumulation into RNA was seen in the embryonic mouse heart. In this tissue more than 1 in 400 bases in all RNA in the cell was inosine. In normal tissues inosine is almost undetectable using very sensitive assays. The inosine accumulation did not seem to be having a global effect on the balance of RNA molecules or proteins.

Published

2019

7. The SNF2 family ATPase LSH promotes cell-autonomous de novo DNA methylation in somatic cells

Author

Termanis, Ausma, Torrea, Natalia, Culley, Jayne, Kerr, Alastair, Ramsahoye, Bernard, and Stancheva, Irina

Subjects

Adenosine Triphosphatases, DNA methylation, epigenetics, Retroelements, Gene regulation, Chromatin and Epigenetics, DNA Helicases, Gene Expression Regulation, Developmental, Cell Differentiation, DNA Methylation, Fibroblasts, Embryo, Mammalian, Cell Line, gene silencing, Mice, Mutation, 5-Methylcytosine, NIH 3T3 Cells, chromatin, Animals, DNA (Cytosine-5-)-Methyltransferases, Gene Silencing, LSH, Promoter Regions, Genetic, Repetitive Sequences, Nucleic Acid

Abstract

Methylation of DNA at carbon 5 of cytosine is essential for mammalian development and implicated in transcriptional repression of genes and transposons. New patterns of DNA methylation characteristic of lineage-committed cells are established at the exit from pluripotency by de novo DNA methyltransferases enzymes, DNMT3A and DNMT3B, which are regulated by developmental signalling and require access to chromatin-organised DNA. Whether or not the capacity for de novo DNA methylation of developmentally regulated loci is preserved in differentiated somatic cells and can occur in the absence of exogenous signals is currently unknown. Here we demonstrate that fibroblasts derived from chromatin remodelling ATPase LSH (HELLS)-null mouse embryos, which lack DNA methylation from centromeric repeats, transposons and a number of gene promoters, are capable of re-establishing DNA methylation and silencing of miss-regulated genes upon re-expression of LSH. We also show that the ability of LSH to bind ATP and the cellular concentration of DNMT3B are critical for cell-autonomous de novo DNA methylation in somatic cells. These data suggest the existence of cellular memory that persists in differentiated cells through many cell generations and changes in transcriptional state.

Published

2016

8. Svd-SRS: A Highly Specific Algorithm for Identifying Somatic Genomic Rearrangements in Haematological Malignancy

Author

Bibby, Lloyd Ian, primary and Ramsahoye, Bernard, additional

Published

2019

9. Requirement of DNMT1 to orchestrate epigenomic reprogramming for NPM-ALK--driven lymphomagenesis.

Author

Redl, Elisa, Sheibani-Tezerji, Raheleh, de Jesus Cardona, Crhistian, Hamminger, Patricia, Timelthaler, Gerald, Hassler, Melanie Rosalia, Zrimšek, Maša, Lagger, Sabine, Dillinger, Thomas, Hofbauer, Lorena, Draganić, Kristina, Tiefenbacher, Andreas, Kothmayer, Michael, Dietz, Charles H., Ramsahoye, Bernard H., Kenner, Lukas, Bock, Christoph, Seiser, Christian, Ellmeier, Wilfried, and Schweikert, Gabriele

Published

2021

10. SAF-A Regulates Interphase Chromosome Structure through Oligomerization with Chromatin-Associated RNAs

Author

Nozawa, Ryu-Suke, Boteva, Lora, Soares, Dinesh C., Naughton, Catherine, Dun, Alison R., Buckle, Adam, Ramsahoye, Bernard, Bruton, Peter C., Saleeb, Rebecca S., Arnedo, Maria, Hill, Bill, Duncan, Rory R., Maciver, Sutherland K., and Gilbert, Nick

Subjects

fungi, Journal Article

Abstract

Higher eukaryotic chromosomes are organized into topologically constrained functional domains; however, the molecular mechanisms required to sustain these complex interphase chromatin structures are unknown. A stable matrix underpinning nuclear organization was hypothesized, but the idea was abandoned as more dynamic models of chromatin behavior became prevalent. Here, we report that scaffold attachment factor A (SAF-A), originally identified as a structural nuclear protein, interacts with chromatin-associated RNAs (caRNAs) via its RGG domain to regulate human interphase chromatin structures in a transcription-dependent manner. Mechanistically, this is dependent on SAF-A’s AAA+ ATPase domain, which mediates cycles of protein oligomerization with caRNAs, in response to ATP binding and hydrolysis. SAF-A oligomerization decompacts large-scale chromatin structure while SAF-A loss or monomerization promotes aberrant chromosome folding and accumulation of genome damage. Our results show that SAF-A and caRNAs form a dynamic, transcriptionally responsive chromatin mesh that organizes large-scale chromosome structures and protects the genome from instability.

Published

2017

11. MeCP2 recognizes cytosine methylated tri-nucleotide and di-nucleotide sequences to tune transcription in the mammalian brain

Author

Lagger, Sabine, Connelly, John C., Schweikert, Gabriele, Webb, Shaun, Selfridge, Jim, Ramsahoye, Bernard H., Yu, Miao, He, Chuan, Sanguinetti, Guido, Sowers, Lawrence C., Walkinshaw, Malcolm D., and Bird, Adrian

Subjects

Male, Methyl-CpG-Binding Protein 2, Oligonucleotides, Biochemistry, Epigenesis, Genetic, Database and Informatics Methods, Mice, Trinucleotide Repeats, Medicine and Health Sciences, Dinucleotide Repeats, DNA methylation, Mammalian Genomics, Nucleotides, Brain, Genomics, Chromatin, Nucleic acids, Epigenetics, Anatomy, DNA modification, Sequence Analysis, Chromatin modification, Research Article, Chromosome biology, Protein Binding, congenital, hereditary, and neonatal diseases and abnormalities, Cell biology, lcsh:QH426-470, Bioinformatics, Hypothalamus, Research and Analysis Methods, Transfection, Cytosine, Sequence Motif Analysis, mental disorders, Genetics, Rett Syndrome, Animals, Molecular Biology Techniques, Molecular Biology, DNA sequence analysis, Biology and life sciences, DNA, Settore FIS/07 - Fisica Applicata(Beni Culturali, Ambientali, Biol.e Medicin), nervous system diseases, Mice, Inbred C57BL, lcsh:Genetics, Animal Genomics, CpG Islands, Gene expression

Abstract

Mutations in the gene encoding the methyl-CG binding protein MeCP2 cause several neurological disorders including Rett syndrome. The di-nucleotide methyl-CG (mCG) is the classical MeCP2 DNA recognition sequence, but additional methylated sequence targets have been reported. Here we show by in vitro and in vivo analyses that MeCP2 binding to non-CG methylated sites in brain is largely confined to the tri-nucleotide sequence mCAC. MeCP2 binding to chromosomal DNA in mouse brain is proportional to mCAC + mCG density and unexpectedly defines large genomic domains within which transcription is sensitive to MeCP2 occupancy. Our results suggest that MeCP2 integrates patterns of mCAC and mCG in the brain to restrain transcription of genes critical for neuronal function., Author summary Rett Syndrome is a severe neurological disorder found in approximately 1:10.000 female births. The gene causing most cases of Rett Syndrome has been identified as methyl-CG binding protein 2 (MeCP2) which is an epigenetic reader protein, classically characterized as binding to CpG methylated (mCG) di-nucleotides. Although much research has focused on the binding capacities of MeCP2, its exact mode of action is still controversial. Here we show, that in addition to the classical mCG motif, frequently occurring mCAC tri-nucleotides are also bound by MeCP2. We additionally discover large genomic regions of high mCG + mCAC density that contain neuro-disease relevant genes sensitive to MeCP2 loss or overexpression. Our results re-emphasize MeCP2’s original proposed function as a transcriptional repressor whose purpose is to maintain the delicate balance of neuronal gene expression.

Published

2017

12. Spirit 2: Final 5 Year Analysis of the UK National Cancer Research Institute Randomized Study Comparing Imatinib with Dasatinib in Patients with Newly Diagnosed Chronic Phase CML

Author

O'Brien, Stephen, primary, Cork, Leanne, additional, Bandeira, Valeria, additional, Bescoby, Ruth, additional, Foroni, Letizia, additional, Alaily, Lynn, additional, Osborne, Wendy, additional, Bell-Gorrod, Helen, additional, Latimer, Nicholas, additional, Apperley, Jane, additional, Hedgley, Corinne, additional, Syzdlo, Richard, additional, Byrne, Jennifer, additional, Pocock, Christopher, additional, Ramsahoye, Bernard, additional, Zwingers, Thomas, additional, Wason, James, additional, Copland, Mhairi, additional, and Clark, Richard, additional

Published

2018

13. Quantitative modelling predicts the impact of DNA methylation on RNA polymerase II traffic

Author

Cholewa-Waclaw, Justyna, primary, Shah, Ruth, additional, Webb, Shaun, additional, Chhatbar, Kashyap, additional, Ramsahoye, Bernard, additional, Pusch, Oliver, additional, Yu, Miao, additional, Greulich, Philip, additional, Waclaw, Bartlomiej, additional, and Bird, Adrian, additional

Published

2018

14. ITPase Deficiency Causes Martsolf Syndrome With a Lethal Infantile Dilated Cardiomyopathy

Author

Handley, Mark T., primary, Reddy, Kaalak, additional, Wills, Jimi, additional, Rosser, Elisabeth, additional, Kamath, Archith, additional, Halachev, Mihail, additional, Falkous, Gavin, additional, Williams, Denise, additional, Cox, Phillip, additional, Meynert, Alison, additional, Raymond, Eleanor S., additional, Morrison, Harris, additional, Brown, Stephen, additional, Allan, Emma, additional, Aligianis, Irene, additional, Jackson, Andrew P, additional, Ramsahoye, Bernard H, additional, von Kriegsheim, Alex, additional, Taylor, Robert W., additional, Finch, Andrew J., additional, and FitzPatrick, David R., additional

Published

2018

15. DNA methylation protocols

Author

Mills, Ken I., Ramsahoye, Bernard H., Mills, Ken I., and Ramsahoye, Bernard H.

Published

2017

16. SAF-A Regulates Interphase Chromosome Structure through Oligomerization with Chromatin-Associated RNAs

Author

Nozawa, Ryu-Suke, primary, Boteva, Lora, additional, Soares, Dinesh C., additional, Naughton, Catherine, additional, Dun, Alison R., additional, Buckle, Adam, additional, Ramsahoye, Bernard, additional, Bruton, Peter C., additional, Saleeb, Rebecca S., additional, Arnedo, Maria, additional, Hill, Bill, additional, Duncan, Rory R., additional, Maciver, Sutherland K., additional, and Gilbert, Nick, additional

Published

2017

17. Domains of methylated CAC and CG target MeCP2 to tune transcription in the brain

Author

Lagger, Sabine, primary, Connelly, John C, additional, Schweikert, Gabriele, additional, Webb, Shaun, additional, Selfridge, Jim, additional, Ramsahoye, Bernard H, additional, Yu, Miao, additional, DeSousa, Dina, additional, Seiser, Christian, additional, He, Chuan, additional, Sanguinetti, Guido, additional, Sowers, Lawrence C, additional, Walkinshaw, Malcolm D, additional, and Bird, Adrian, additional

Published

2016

18. The SNF2 family ATPase LSH promotes cell-autonomousde novoDNA methylation in somatic cells

Author

Termanis, Ausma, primary, Torrea, Natalia, additional, Culley, Jayne, additional, Kerr, Alastair, additional, Ramsahoye, Bernard, additional, and Stancheva, Irina, additional

Published

2016

19. G9a/GLP Complex Maintains Imprinted DNA Methylation in Embryonic Stem Cells

Author

Zhang, Tuo, primary, Termanis, Ausma, additional, Özkan, Burak, additional, Bao, Xun X., additional, Culley, Jayne, additional, de Lima Alves, Flavia, additional, Rappsilber, Juri, additional, Ramsahoye, Bernard, additional, and Stancheva, Irina, additional

Published

2016

20. Nanog Requires BRD4 to Maintain Murine Embryonic Stem Cell Pluripotency and Is Suppressed by Bromodomain Inhibitor JQ1 Together with Lefty1

Author

Horne, Gillian A., primary, Stewart, Helen J.S., additional, Dickson, Jacqueline, additional, Knapp, Stefan, additional, Ramsahoye, Bernard, additional, and Chevassut, Timothy, additional

Published

2015

21. Identifying somatic structural rearrangements in leukaemia by tumour-only paired-end whole genome sequencing

Author

Bibby, Lloyd, Ramsahoye, Bernard, and Gilbert, Nicholas

Abstract

Our understanding of the molecular pathogenesis of acute and chronic leukaemia has been greatly advanced by high-throughput next generation DNA sequencing. Nowadays, lymphoid, and myeloid malignancies are characterised by many somatically acquired genomic structural rearrangements including chromosomal translocations, inversions, large deletions or insertions, and internal tandem duplications, as well as chromosomal copy number changes. The ultimate effect of these is the deregulation of oncogenes or tumour suppressor genes which promotes transformation to disease. Clinically, the presence of structural abnormalities in a leukaemia patient's tumour genome predict treatment response and patient survival, so it is necessary to conduct investigations at presentation to better understand a patient's tumour genome and inform patient risk stratification and care. The detection of the genomic structural rearrangements vital for clinical management are currently detected using conventional cytogenetic analysis (G-banding), and many structural rearrangements can be detected in this manner, but many others are too subtle and evade detection. Gene-centric techniques such as PCR or FISH can focus detection on specific rearrangements to confirm or refute their presence in a genome, but other less common potentially significant rearrangements will be missed simply because they are not known to be looked for. Overall, conventional cytogenetic techniques are laborious and time consuming, and are of inadequate through-put to determine all genomic rearrangements present in a sample with ease. With the development of 2 x 150 bp paired-end whole genome sequencing however, it is theoretically possible to identify all disease-relevant structural abnormalities with base-pair precision and resolution in a single experiment, reducing the cost and time spent per mutation to generate a complete genomic profile from which clinical decisions can be made. Effective whole genome sequencing analysis is not trivial however, and many approaches outside of clinical practice rely on sequencing both a tumour DNA sample and patient-matched germline DNA sample to discriminate the somatic rearrangements from polymorphic structural variants restricted to the tumour. Similarly, paired tumour and germline DNA sequencing is relied upon to limit the number of technical artefacts that otherwise masquerade as structural rearrangements when analysed by the current publicly available structural variant calling algorithms. Without paired-sample DNA sequencing, current computational approaches detect thousands of structural abnormalities in a single patient by comparison to the reference genome. Most of which are simply not real somatic changes and have the potential to mislead and waste resources in their confirmation. However, the collection of a matched germline DNA sample is simply impractical in haematology-oncology as there is no suitable tissue in which to easily sample, limiting the uptake of whole genome sequencing as a suitable replacement for cytogenetics. The associated costs of sequencing a second DNA sample further limits the use of whole genome sequencing in clinical practice also. Therefore, novel methods and analytical approaches for the detection of structural rearrangements in leukaemia without a germline DNA sample in which to compare to is an unmet clinical need. To that end, we have developed a computational method to detect and identify somatic structural rearrangements of clinical significance in leukaemia, using a tumour-only paired-end whole genome sequencing approach. This approach was developed using a 64-core computer server to enable massively parallel data processing, but the algorithm is scalable and can be implemented on systems with fewer resources. This approach uses discordant and split reads to identify and model structural rearrangements in paired-end whole genome sequencing data but differs from other less specific algorithms because it performs a series of internal validation steps to identify only those discordant split reads that give reliable evidence of structural rearrangement. To identify structural polymorphisms which persist after structural variant detection, each putative breakpoint sequence is compared with publicly available databases of polymorphic structural variation. This approach has been tested on 17 tumour-only leukaemia samples obtained at presentation and demonstrates a higher rate of specificity than the current structural variant algorithms available. It also exceeds the level of sensitivity of cytogenetics. This work demonstrates the superiority of whole genome sequencing in a clinical setting, and the ease of which tumour-only whole genome sequencing analysis can be conducted routinely in clinical haematology-oncology.

Published

2021

22. ITPase deficiency causes a Martsolf-like syndrome with a lethal infantile dilated cardiomyopathy.

Author

Handley MT, Reddy K, Wills J, Rosser E, Kamath A, Halachev M, Falkous G, Williams D, Cox P, Meynert A, Raymond ES, Morrison H, Brown S, Allan E, Aligianis I, Jackson AP, Ramsahoye BH, von Kriegsheim A, Taylor RW, Finch AJ, and FitzPatrick DR

Subjects

Animals, Base Sequence, Child, Preschool, DNA Mutational Analysis, DNA, Mitochondrial genetics, DNA, Mitochondrial metabolism, Female, Homozygote, Humans, Inosine metabolism, Male, Mice, Mice, Knockout, Mouse Embryonic Stem Cells enzymology, Mutation, Pedigree, Pyrophosphatases genetics, RNA genetics, RNA metabolism, Exome Sequencing, Cardiomyopathy, Dilated enzymology, Cardiomyopathy, Dilated genetics, Cataract enzymology, Cataract genetics, Hypogonadism enzymology, Hypogonadism genetics, Intellectual Disability enzymology, Intellectual Disability genetics, Metabolism, Inborn Errors enzymology, Metabolism, Inborn Errors genetics, Pyrophosphatases deficiency

Abstract

Typical Martsolf syndrome is characterized by congenital cataracts, postnatal microcephaly, developmental delay, hypotonia, short stature and biallelic hypomorphic mutations in either RAB3GAP1 or RAB3GAP2. Genetic analysis of 85 unrelated "mutation negative" probands with Martsolf or Martsolf-like syndromes identified two individuals with different homozygous null mutations in ITPA, the gene encoding inosine triphosphate pyrophosphatase (ITPase). Both probands were from multiplex families with a consistent, lethal and highly distinctive disorder; a Martsolf-like syndrome with infantile-onset dilated cardiomyopathy. Severe ITPase-deficiency has been previously reported with infantile epileptic encephalopathy (MIM 616647). ITPase acts to prevent incorporation of inosine bases (rI/dI) into RNA and DNA. In Itpa-null cells dI was undetectable in genomic DNA. dI could be identified at a low level in mtDNA without detectable mitochondrial genome instability, mtDNA depletion or biochemical dysfunction of the mitochondria. rI accumulation was detectable in proband-derived lymphoblastoid RNA. In Itpa-null mouse embryos rI was detectable in the brain and kidney with the highest level seen in the embryonic heart (rI at 1 in 385 bases). Transcriptome and proteome analysis in mutant cells revealed no major differences with controls. The rate of transcription and the total amount of cellular RNA also appeared normal. rI accumulation in RNA-and by implication rI production-correlates with the severity of organ dysfunction in ITPase deficiency but the basis of the cellulopathy remains cryptic. While we cannot exclude cumulative minor effects, there are no major anomalies in the production, processing, stability and/or translation of mRNA., Competing Interests: The authors have declared that no competing interests exist.

Published

2019