Your search keyword '"Wakeling, Matthew"' showing total 31 results

1. Chromosome 20p11.2 deletions cause congenital hyperinsulinism via the loss of FOXA2 or its regulatory elements

Author

Laver, Thomas W., Wakeling, Matthew N., Caswell, Richard C., Bunce, Benjamin, Yau, Daphne, Männistö, Jonna M. E., Houghton, Jayne A. L., Hopkins, Jasmin J., Weedon, Michael N., Saraff, Vrinda, Kershaw, Melanie, Honey, Engela M., Murphy, Nuala, Giri, Dinesh, Nath, Stuart, Tangari Saredo, Ana, Banerjee, Indraneel, Hussain, Khalid, Owens, Nick D. L., and Flanagan, Sarah E.

Published

2024

2. Paediatric diabetes subtypes in a consanguineous population: a single-centre cohort study from Kurdistan, Iraq

Author

Amaratunga, Shenali A., Hussein Tayeb, Tara, Muhamad Sediq, Rozhan N., Hama Salih, Fareda K., Dusatkova, Petra, Wakeling, Matthew N., De Franco, Elisa, Pruhova, Stepanka, and Lebl, Jan

Published

2024

3. Primate-specific ZNF808 is essential for pancreatic development in humans

Author

De Franco, Elisa, Owens, Nick D. L., Montaser, Hossam, Wakeling, Matthew N., Saarimäki-Vire, Jonna, Triantou, Athina, Ibrahim, Hazem, Balboa, Diego, Caswell, Richard C., Jennings, Rachel E., Kvist, Jouni A., Johnson, Matthew B., Muralidharan, Sachin, Ellard, Sian, Wright, Caroline F., Maddirevula, Sateesh, Alkuraya, Fowzan S., Hanley, Neil A., Flanagan, Sarah E., Otonkoski, Timo, Hattersley, Andrew T., and Imbeault, Michael

Published

2023

4. Non-coding variants disrupting a tissue-specific regulatory element in HK1 cause congenital hyperinsulinism

Author

Wakeling, Matthew N., Owens, Nick D. L., Hopkinson, Jessica R., Johnson, Matthew B., Houghton, Jayne A. L., Dastamani, Antonia, Flaxman, Christine S., Wyatt, Rebecca C., Hewat, Thomas I., Hopkins, Jasmin J., Laver, Thomas W., van Heugten, Rachel, Weedon, Michael N., De Franco, Elisa, Patel, Kashyap A., Ellard, Sian, Morgan, Noel G., Cheesman, Edmund, Banerjee, Indraneel, Hattersley, Andrew T., Dunne, Mark J., Richardson, Sarah J., and Flanagan, Sarah E.

Published

2022

5. Refinements and considerations for trio whole-genome sequence analysis when investigating Mendelian diseases presenting in early childhood

Author

French, Courtney E., Dolling, Helen, Mégy, Karyn, Sanchis-Juan, Alba, Kumar, Ajay, Delon, Isabelle, Wakeling, Matthew, Mallin, Lucy, Agrawal, Shruti, Austin, Topun, Walston, Florence, Park, Soo-Mi, Parker, Alasdair, Piyasena, Chinthika, Bradbury, Kimberley, Ellard, Sian, Rowitch, David H., and Raymond, F. Lucy

Published

2022

6. Infancy‐onset diabetes caused by de‐regulated AMPylation of the human endoplasmic reticulum chaperone BiP

Author

Perera, Luke A, Hattersley, Andrew T, Harding, Heather P, Wakeling, Matthew N, Flanagan, Sarah E, Mohsina, Ibrahim, Raza, Jamal, Gardham, Alice, Ron, David, and De Franco, Elisa

Published

2023

7. Missense substitutions at a conserved 14-3-3 binding site in HDAC4 cause a novel intellectual disability syndrome

Author

Wakeling, Emma, McEntagart, Meriel, Bruccoleri, Michael, Shaw-Smith, Charles, Stals, Karen L., Wakeling, Matthew, Barnicoat, Angela, Beesley, Clare, Hanson-Kahn, Andrea K., Kukolich, Mary, Stevenson, David A., Campeau, Philippe M., Ellard, Sian, Elsea, Sarah H., Yang, Xiang-Jiao, and Caswell, Richard C.

Published

2021

8. YIPF5 mutations cause neonatal diabetes and microcephaly through endoplasmic reticulum stress

Author

De Franco, Elisa, Lytrivi, Maria, Ibrahim, Hazem, Montaser, Hossam, Wakeling, Matthew N., Fantuzzi, Federica, Patel, Kashyap, Demarez, Celine, Cai, Ying, Igoillo-Esteve, Mariana, Cosentino, Cristina, Lithovius, Vaino, Vihinen, Helena, Jokitalo, Eija, Laver, Thomas W., Johnson, Matthew B., Sawatani, Toshiaki, Shakeri, Hadis, Pachera, Nathalie, Haliloglu, Belma, Ozbek, Mehmet Nuri, Unal, Edip, Yildirim, Ruken, Godbole, Tushar, Yildiz, Melek, Aydin, Banu, Bilheu, Angeline, Suzuki, Ikuo, Flanagan, Sarah E., Vanderhaeghen, Pierre, Senee, Valerie, Julier, Cecile, Marchetti, Piero, Eizirik, Decio L., Ellard, Sian, Saarimaki-Vire, Jonna, Otonkoski, Timo, Cnop, Miriam, and Hattersley, Andrew T.

Subjects

Pediatric research, Diabetes mellitus -- Genetic aspects -- Causes of -- Development and progression, Microcephaly -- Genetic aspects -- Causes of -- Development and progression, Stress (Physiology) -- Genetic aspects -- Health aspects, Neonatal diseases -- Genetic aspects -- Causes of -- Development and progression, Endoplasmic reticulum -- Physiological aspects -- Health aspects, Health care industry

Abstract

Neonatal diabetes is caused by single gene mutations reducing pancreatic [beta] cell number or impairing [beta] cell function. Understanding the genetic basis of rare diabetes subtypes highlights fundamental biological processes in [beta] cells. We identified 6 patients from 5 families with homozygous mutations in the YIPF5 gene, which is involved in trafficking between the endoplasmic reticulum (ER) and the Golgi. All patients had neonatal/early-onset diabetes, severe microcephaly, and epilepsy. YIPF5 is expressed during human brain development, in adult brain and pancreatic islets. We used 3 human [beta] cell models (YIPF5 silencing in EndoC-[beta]H1 cells, YIPF5 knockout and mutation knockin in embryonic stem cells, and patient-derived induced pluripotent stem cells) to investigate the mechanism through which YIPF5 loss of function affects [beta] cells. Loss of YIPF5 function in stem cell-derived islet cells resulted in proinsulin retention in the ER, marked ER stress, and p cell failure. Partial YIPF5 silencing in EndoC-[beta]H1 cells and a patient mutation in stem cells increased the [beta] cell sensitivity to ER stress-induced apoptosis. We report recessive YIPF5 mutations as the genetic cause of a congenital syndrome of microcephaly, epilepsy, and neonatal/early-onset diabetes, highlighting a critical role of YIPF5 in [beta] cells and neurons. We believe this is the first report of mutations disrupting the ER-to-Golgi trafficking, resulting in diabetes., Introduction Neonatal diabetes mellitus develops before 6 months of age and is caused by reduced pancreatic [beta] cell number (reduced formation/increased destruction) or impaired [beta] cell function. Previous studies have [...]

Published

2020

9. MAFA missense mutation causes familial insulinomatosis and diabetes mellitus

Author

Iacovazzo, Donato, Flanagan, Sarah E., Walker, Emily, Quezado, Rosana, de Sousa Barros, Fernando Antonio, Caswell, Richard, Johnson, Matthew B., Wakeling, Matthew, Brändle, Michael, Guo, Min, Dang, Mary N., Gabrovska, Plamena, Niederle, Bruno, Christ, Emanuel, Jenni, Stefan, Sipos, Bence, Nieser, Maike, Frilling, Andrea, Dhatariya, Ketan, Chanson, Philippe, de Herder, Wouter W., Konukiewitz, Björn, Klöppel, Günter, Stein, Roland, Korbonits, Márta, and Ellard, Sian

Published

2018

10. An Amish founder variant consolidates disruption of CEP55 as a cause of hydranencephaly and renal dysplasia

Author

Rawlins, Lettie E., Jones, Hannah, Wenger, Olivia, Aye, Myat, Fasham, James, Harlalka, Gaurav V., Chioza, Barry A., Miron, Alexander, Ellard, Sian, Wakeling, Matthew, Crosby, Andrew H., and Baple, Emma L.

Published

2019

11. REVEL Is Better at Predicting Pathogenicity of Loss-of-Function than Gain-of-Function Variants.

Author

Hopkins, Jasmin J., Wakeling, Matthew N., Johnson, Matthew B., Flanagan, Sarah E., and Laver, Thomas W.

Abstract

In silico predictive tools can help determine the pathogenicity of variants. The 2015 American College of Medical Genetics and Genomics (ACMG) guidelines recommended that scores from these tools can be used as supporting evidence of pathogenicity. A subsequent publication by the ClinGen Sequence Variant Interpretation Working Group suggested that high scores from some tools were sufficiently predictive to be used as moderate or strong evidence of pathogenicity. REVEL is a widely used metapredictor that uses the scores of 13 individual in silico tools to calculate the pathogenicity of missense variants. Its ability to predict missense pathogenicity has been assessed extensively; however, no study has previously tested whether its performance is affected by whether the missense variant acts via a loss-of-function (LoF) or gain-of-function (GoF) mechanism. We used a highly curated dataset of 66 confirmed LoF and 65 confirmed GoF variants to evaluate whether this affected the performance of REVEL. 98% of LoF and 100% of GoF variants met the author-recommended REVEL threshold of 0.5 for pathogenicity, while 89% of LoF and 88% of GoF variants exceeded the 0.75 threshold. However, while 55% of LoF variants met the threshold recommended for a REVEL score to count as strong evidence of pathogenicity from the ACMG guidelines (0.932), only 35% of GoF variants met this threshold (P = 0.0352). GoF variants are therefore less likely to receive the highest REVEL scores which would enable the REVEL score to be used as strong evidence of pathogenicity. This has implications for classification with the ACMG guidelines as GoF variants are less likely to meet the criteria for pathogenicity. [ABSTRACT FROM AUTHOR]

Published

2023

12. The Role of ONECUT1 Variants in Monogenic and Type 2 Diabetes Mellitus.

Author

Russ-Silsby, James, Patel, Kashyap A., Laver, Thomas W., Hawkes, Gareth, Johnson, Matthew B., Wakeling, Matthew N., Patil, Prashant P., Hattersley, Andrew T., Flanagan, Sarah E., Weedon, Michael N., and De Franco, Elisa

Subjects

TYPE 2 diabetes, MATURITY onset diabetes of the young, MISSENSE mutation, ETIOLOGY of diabetes, GENETIC variation

Abstract

ONECUT1 (also known as HNF6) is a transcription factor involved in pancreatic development and β-cell function. Recently, biallelic variants in ONECUT1 were reported as a cause of neonatal diabetes mellitus (NDM) in two subjects, and missense monoallelic variants were associated with type 2 diabetes and possibly maturity-onset diabetes of the young (MODY). Here we examine the role of ONECUT1 variants in NDM, MODY, and type 2 diabetes in large international cohorts of subjects with monogenic diabetes and >400,000 subjects from UK Biobank. We identified a biallelic frameshift ONECUT1 variant as the cause of NDM in one individual. However, we found no enrichment of missense or null ONECUT1 variants among 484 individuals clinically suspected of MODY, in whom all known genes had been excluded. Finally, using a rare variant burden test in the UK Biobank European cohort, we identified a significant association between heterozygous ONECUT1 null variants and type 2 diabetes (P = 0.006) but did not find an association between missense variants and type 2 diabetes. Our results confirm biallelic ONECUT1 variants as a cause of NDM and highlight monoallelic null variants as a risk factor for type 2 diabetes. These findings confirm the critical role of ONECUT1 in human β-cell function. Article Highlights: We confirmed homozygous ONECUT1 variants as causative for neonatal diabetes with the identification of a third case. Rare heterozygous ONECUT1 variants were not enriched in a cohort of 484 individuals clinically suspected of having maturity-onset diabetes of the young. Heterozygous null ONECUT1 variants are significantly associated with type 2 diabetes in the UK Biobank European population. No association was observed between heterozygous ONECUT1 missense variants and type 2 diabetes in UK Biobank. [ABSTRACT FROM AUTHOR]

Published

2023

13. Evaluation of Evidence for Pathogenicity Demonstrates That BLK, KLF11, and PAX4 Should Not Be Included in Diagnostic Testing for MODY.

Author

Laver, Thomas W., Wakeling, Matthew N., Knox, Olivia, Colclough, Kevin, Wright, Caroline F., Ellard, Sian, Hattersley, Andrew T., Weedon, Michael N., and Patel, Kashyap A.

Subjects

*PROTEINS, *GENETIC mutation, *ANIMAL experimentation, *TYPE 2 diabetes, *GENES, *DIAGNOSIS, *TRANSFERASES, *RESEARCH funding, *MICROBIAL virulence

Abstract

Maturity-onset diabetes of the young (MODY) is an autosomal dominant form of monogenic diabetes, reported to be caused by variants in 16 genes. Concern has been raised about whether variants in BLK (MODY11), KLF11 (MODY7), and PAX4 (MODY9) cause MODY. We examined variant-level genetic evidence (cosegregation with diabetes and frequency in population) for published putative pathogenic variants in these genes and used burden testing to test gene-level evidence in a MODY cohort (n = 1,227) compared with a control population (UK Biobank [n = 185,898]). For comparison we analyzed well-established causes of MODY, HNF1A, and HNF4A. The published variants in BLK, KLF11, and PAX4 showed poor cosegregation with diabetes (combined logarithm of the odds [LOD] scores ≤1.2), compared with HNF1A and HNF4A (LOD scores >9), and are all too common to cause MODY (minor allele frequency >4.95 × 10-5). Ultra-rare missense and protein-truncating variants (PTV) were not enriched in a MODY cohort compared with the UK Biobank population (PTV P > 0.05, missense P > 0.1 for all three genes) while HNF1A and HNF4A were enriched (P < 10-6). Findings of sensitivity analyses with different population cohorts supported our results. Variant and gene-level genetic evidence does not support BLK, KLF11, or PAX4 as a cause of MODY. They should not be included in MODY diagnostic genetic testing. [ABSTRACT FROM AUTHOR]

Published

2022

14. InterMine: a flexible data warehouse system for the integration and analysis of heterogeneous biological data

Author

Smith, Richard N., Aleksic, Jelena, Butano, Daniela, Carr, Adrian, Contrino, Sergio, Hu, Fengyuan, Lyne, Mike, Lyne, Rachel, Kalderimis, Alex, Rutherford, Kim, Stepan, Radek, Sullivan, Julie, Wakeling, Matthew, Watkins, Xavier, and Micklem, Gos

Published

2012

15. SavvyCNV: Genome-wide CNV calling from off-target reads.

Author

Laver, Thomas W., De Franco, Elisa, Johnson, Matthew B., Patel, Kashyap A., Ellard, Sian, Weedon, Michael N., Flanagan, Sarah E., and Wakeling, Matthew N.

Subjects

DNA copy number variations, GENETIC variation, GENETIC testing

Abstract

Identifying copy number variants (CNVs) can provide diagnoses to patients and provide important biological insights into human health and disease. Current exome and targeted sequencing approaches cannot detect clinically and biologically-relevant CNVs outside their target area. We present SavvyCNV, a tool which uses off-target read data from exome and targeted sequencing data to call germline CNVs genome-wide. Up to 70% of sequencing reads from exome and targeted sequencing fall outside the targeted regions. We have developed a new tool, SavvyCNV, to exploit this 'free data' to call CNVs across the genome. We benchmarked SavvyCNV against five state-of-the-art CNV callers using truth sets generated from genome sequencing data and Multiplex Ligation-dependent Probe Amplification assays. SavvyCNV called CNVs with high precision and recall, outperforming the five other tools at calling CNVs genome-wide, using off-target or on-target reads from targeted panel and exome sequencing. We then applied SavvyCNV to clinical samples sequenced using a targeted panel and were able to call previously undetected clinically-relevant CNVs, highlighting the utility of this tool within the diagnostic setting. SavvyCNV outperforms existing tools for calling CNVs from off-target reads. It can call CNVs genome-wide from targeted panel and exome data, increasing the utility and diagnostic yield of these tests. SavvyCNV is freely available at https://github.com/rdemolgen/SavvySuite. Author summary: We have created SavvyCNV, a new tool for calling genetic variants. Large regions of the genome can be deleted or duplicated–these variants can have important consequences, for example causing a patient's genetic disease. However, many standard genetic tests only target a small fraction of the genome and will miss variants outside of these regions. Therefore, we developed a tool to exploit sequencing data which falls outside of these regions (due to flaws in the targeting process) to call large deletions and duplications. This allows large deletions and duplications to be detected anywhere in the genome. Researchers and diagnostic laboratories can use this tool to discover more genetic variants by re-analysing their sequencing data. [ABSTRACT FROM AUTHOR]

Published

2022

16. Defunctionalization of sp3 C–Heteroatom and sp3 C–C Bonds Enabled by Photoexcited Triplet Ketone Catalysts.

Author

Gu, Yiting, Yin, Hongfei, Wakeling, Matthew, An, Juzeng, and Martin, Ruben

Published

2022

17. A homozygous TARS2 variant is a novel cause of syndromic neonatal diabetes.

Author

Donis, Russell, Patel, Kashyap A., Wakeling, Matthew N., Johnson, Matthew B., Amoli, Masha M., Yildiz, Melek, Akçay, Teoman, Aspi, Irani, Yong, James, Yaghootkar, Hanieh, Weedon, Michael N., Hattersley, Andrew T., Flanagan, Sarah E., and De Franco, Elisa

Subjects

*MISSENSE mutation, *DEVELOPMENTAL delay, *ETIOLOGY of diabetes, *NUCLEOTIDE sequencing, *DIABETES

Abstract

Aims Methods Results Conclusions Neonatal diabetes is a monogenic condition which can be the presenting feature of complex syndromes. The aim of this study was to identify novel genetic causes of neonatal diabetes with neurological features including developmental delay and epilepsy.We performed genome sequencing in 27 individuals with neonatal diabetes plus epilepsy and/or developmental delay of unknown genetic cause. Replication studies were performed in 123 individuals with diabetes diagnosed aged ≤1 year without a known genetic cause using targeted next‐generation sequencing.Three individuals, all diagnosed with diabetes in the first week of life, shared a rare homozygous missense variant, p.(Arg327Gln), in TARS2. Replication studies identified the same homozygous variant in a fourth individual diagnosed with diabetes at 1 year. One proband had epilepsy, one had development delay and two had both.Biallelic TARS2 variants cause a mitochondrial encephalopathy (COXPD‐21) characterised by severe hypotonia, epilepsy and developmental delay. Diabetes is not a known feature of COXPD‐21. Current evidence suggests that the p.(Arg327Gln) variant disrupts TARS2's regulation of the mTORC1 pathway which is essential for β‐cells.Our findings establish the homozygous p.(Arg327Gln) TARS2 variant as a novel cause of syndromic neonatal diabetes and uncover a role for TARS2 in pancreatic β‐cells. [ABSTRACT FROM AUTHOR]

Published

2024

18. Loss of MANF Causes Childhood-Onset Syndromic Diabetes Due to Increased Endoplasmic Reticulum Stress.

Author

Montaser, Hossam, Patel, Kashyap A., Balboa, Diego, Ibrahim, Hazem, Lithovius, Väinö, Näätänen, Anna, Chandra, Vikash, Demir, Korcan, Acar, Sezer, Ben-Omran, Tawfeg, Colclough, Kevin, Locke, Jonathan M., Wakeling, Matthew, Lindahl, Maria, Hattersley, Andrew T., Saarimäki-Vire, Jonna, and Otonkoski, Timo

Subjects

ENDOPLASMIC reticulum, HUMAN embryonic stem cells, DIABETES in children, ETIOLOGY of diabetes, DIABETES, NERVE growth factor, FLOW cytometry, RESEARCH, GENETIC mutation, IMMUNOHISTOCHEMISTRY, WESTERN immunoblotting, RESEARCH methodology, MEDICAL cooperation, EVALUATION research, COMPARATIVE studies, ENZYME-linked immunosorbent assay, RESEARCH funding, POLYMERASE chain reaction, GLUCOSE tolerance tests

Abstract

Mesencephalic astrocyte-derived neurotrophic factor (MANF) is an endoplasmic reticulum (ER)-resident protein that plays a crucial role in attenuating ER stress responses. Although MANF is indispensable for the survival and function of mouse β-cells, its precise role in human β-cell development and function is unknown. In this study, we show that lack of MANF in humans results in diabetes due to increased ER stress, leading to impaired β-cell function. We identified two patients from different families with childhood diabetes and a neurodevelopmental disorder associated with homozygous loss-of-function mutations in the MANF gene. To study the role of MANF in human β-cell development and function, we knocked out the MANF gene in human embryonic stem cells and differentiated them into pancreatic endocrine cells. Loss of MANF induced mild ER stress and impaired insulin-processing capacity of β-cells in vitro. Upon implantation to immunocompromised mice, the MANF knockout grafts presented elevated ER stress and functional failure, particularly in recipients with diabetes. By describing a new form of monogenic neurodevelopmental diabetes syndrome caused by disturbed ER function, we highlight the importance of adequate ER stress regulation for proper human β-cell function and demonstrate the crucial role of MANF in this process. [ABSTRACT FROM AUTHOR]

Published

2021

19. De Novo Mutations in Affecting eIF2 Signaling Cause Neonatal/Early-Onset Diabetes and Transient Hepatic Dysfunction.

Author

De Franco, Elisa, Caswell, Richard, Johnson, Matthew B., Wakeling, Matthew N., Amnon Zung, Vῦ Chí Dῦng, Cȃ Thi Bích Ngọc, Goonetilleke, Rajiv, Jury, Maritza Vivanco, El-Khateeb, Mohammed, Ellard, Sian, Flanagan, Sarah E., Ron, David, Hattersley, Andrew T., Zung, Amnon, Dũng, Vũ Chí, Bích Ngọc, Cấn Thị, and Vivanco Jury, Maritza

Subjects

ETIOLOGY of diabetes, HUMAN chromosome abnormality diagnosis, CELLULAR control mechanisms, NUCLEOTIDE sequencing, GENETIC disorders, PROTEIN metabolism, COMPARATIVE studies, COMPUTER simulation, DIABETES, LIVER diseases, MATHEMATICAL models, RESEARCH methodology, MEDICAL cooperation, GENETIC mutation, PROTEINS, RESEARCH, PHYSIOLOGICAL stress, DISEASE relapse, THEORY, EVALUATION research, SEQUENCE analysis

Abstract

Permanent neonatal diabetes mellitus (PNDM) is caused by reduced β-cell number or impaired β-cell function. Understanding of the genetic basis of this disorder highlights fundamental β-cell mechanisms. We performed trio genome sequencing for 44 patients with PNDM and their unaffected parents to identify causative de novo variants. Replication studies were performed in 188 patients diagnosed with diabetes before 2 years of age without a genetic diagnosis. EIF2B1 (encoding the eIF2B complex α subunit) was the only gene with novel de novo variants (all missense) in at least three patients. Replication studies identified two further patients with de novo EIF2B1 variants. In addition to having diabetes, four of five patients had hepatitis-like episodes in childhood. The EIF2B1 de novo mutations were found to map to the same protein surface. We propose that these variants render the eIF2B complex insensitive to eIF2 phosphorylation, which occurs under stress conditions and triggers expression of stress response genes. Failure of eIF2B to sense eIF2 phosphorylation likely leads to unregulated unfolded protein response and cell death. Our results establish de novo EIF2B1 mutations as a novel cause of permanent diabetes and liver dysfunction. These findings confirm the importance of cell stress regulation for β-cells and highlight EIF2B1's fundamental role within this pathway. [ABSTRACT FROM AUTHOR]

Published

2020

20. Balancing Bulkiness in Gold(I) Phosphino‐triazole Catalysis.

Author

Zhao, Yiming, Wakeling, Matthew G., Meloni, Fernanda, Sum, Tze Jing, Nguyen, Huy, Buckley, Benjamin R., Davies, Paul W., and Fossey, John S.

Subjects

*CATALYSIS, *GOLD, *VALENCE (Chemistry), *TRIAZOLES, *X-ray diffraction

Abstract

The syntheses of a series of 1‐phenyl‐5‐phosphino 1,2,3‐triazoles are disclosed, within which, the phosphorus atom (at the 5‐position of a triazole) is appended by one, two or three triazole motifs, and the valency of the phosphorus(III) atom is completed by two, one or zero ancillary (phenyl or cyclohexyl) groups respectively. This series of phosphines was compared with tricyclohexylphosphine and triphenylphosphine to study the effect of increasing the number of triazoles appended to the central phosphorus atom from zero to three triazoles. Gold(I) chloride complexes of the synthesised ligands were prepared and analysed by techniques including single‐crystal X‐ray diffraction structure determination. Gold(I) complexes were also prepared from 1‐(2,6‐dimethoxy)‐phenyl‐5‐dicyclohexyl‐phosphino 1,2,3‐triazole and 1‐(2,6‐dimethoxy)‐phenyl‐5‐diphenyl‐phosphino 1,2,3‐triazole ligands. The crystal structures thus obtained were examined using the SambVca (2.0) web tool and percentage buried volumes determined. The effectiveness of these gold(I) chloride complexes to serve as precatalysts for alkyne hydration were assessed. Furthermore, the regioselectivity of hydration of but‐1‐yne‐1,4‐diyldibenzene was probed. [ABSTRACT FROM AUTHOR]

Published

2019

21. Trisomy 21 Is a Cause of Permanent Neonatal Diabetes That Is Autoimmune but Not HLA Associated.

Author

Johnson, Matthew B., De Franco, Elisa, Greeley, Siri Atma W., Letourneau, Lisa R., Gillespie, Kathleen M., Wakeling, Matthew N., Ellard, Sian, Flanagan, Sarah E., Patel, Kashyap A., Hattersley, Andrew T., and International DS-PNDM Consortium

Subjects

DOWN syndrome, TRISOMY 18 syndrome, TYPE 1 diabetes, DIABETES in children, PEOPLE with Down syndrome, DIABETES, COMPARATIVE studies, RESEARCH methodology, MEDICAL cooperation, GENETIC mutation, RESEARCH, EVALUATION research, SEQUENCE analysis, DISEASE complications

Abstract

Identifying new causes of permanent neonatal diabetes (PNDM) (diagnosis <6 months) provides important insights into β-cell biology. Patients with Down syndrome (DS) resulting from trisomy 21 are four times more likely to have childhood diabetes with an intermediate HLA association. It is not known whether DS can cause PNDM. We found that trisomy 21 was seven times more likely in our PNDM cohort than in the population (13 of 1,522 = 85 of 10,000 observed vs. 12.6 of 10,000 expected) and none of the 13 DS-PNDM patients had a mutation in the known PNDM genes that explained 82.9% of non-DS PNDM. Islet autoantibodies were present in 4 of 9 DS-PNDM patients, but DS-PNDM was not associated with polygenic susceptibility to type 1 diabetes (T1D). We conclude that trisomy 21 is a cause of autoimmune PNDM that is not HLA associated. We propose that autoimmune diabetes in DS is heterogeneous and includes coincidental T1D that is HLA associated and diabetes caused by trisomy 21 that is not HLA associated. [ABSTRACT FROM AUTHOR]

Published

2019

22. NAD(P)HX dehydratase (NAXD) deficiency: a novel neurodegenerative disorder exacerbated by febrile illnesses.

Author

Bergen, Nicole J Van, Guo, Yiran, Rankin, Julia, Paczia, Nicole, Becker-Kettern, Julia, Kremer, Laura S, Pyle, Angela, Conrotte, Jean-François, Ellaway, Carolyn, Procopis, Peter, Prelog, Kristina, Homfray, Tessa, Baptista, Júlia, Baple, Emma, Wakeling, Matthew, Massey, Sean, Kay, Daniel P, Shukla, Anju, Girisha, Katta M, and Lewis, Leslie E S

Abstract

Physical stress, including high temperatures, may damage the central metabolic nicotinamide nucleotide cofactors [NAD(P)H], generating toxic derivatives [NAD(P)HX]. The highly conserved enzyme NAD(P)HX dehydratase (NAXD) is essential for intracellular repair of NAD(P)HX. Here we present a series of infants and children who suffered episodes of febrile illness-induced neurodegeneration or cardiac failure and early death. Whole-exome or whole-genome sequencing identified recessive NAXD variants in each case. Variants were predicted to be potentially deleterious through in silico analysis. Reverse-transcription PCR confirmed altered splicing in one case. Subject fibroblasts showed highly elevated concentrations of the damaged cofactors S-NADHX, R-NADHX and cyclic NADHX. NADHX accumulation was abrogated by lentiviral transduction of subject cells with wild-type NAXD. Subject fibroblasts and muscle biopsies showed impaired mitochondrial function, higher sensitivity to metabolic stress in media containing galactose and azide, but not glucose, and decreased mitochondrial reactive oxygen species production. Recombinant NAXD protein harbouring two missense variants leading to the amino acid changes p.(Gly63Ser) and p.(Arg608Cys) were thermolabile and showed a decrease in Vmax and increase in KM for the ATP-dependent NADHX dehydratase activity. This is the first study to identify pathogenic variants in NAXD and to link deficient NADHX repair with mitochondrial dysfunction. The results show that NAXD deficiency can be classified as a metabolite repair disorder in which accumulation of damaged metabolites likely triggers devastating effects in tissues such as the brain and the heart, eventually leading to early childhood death. [ABSTRACT FROM AUTHOR]

Published

2019

23. Annotating high-impact 5′untranslated region variants with the UTRannotator.

Author

Zhang, Xiaolei, Wakeling, Matthew, Ware, James, and Whiffin, Nicola

Subjects

*PROTEIN expression, *OPEN reading frames (Genetics), *FORECASTING

Abstract

Summary Current tools to annotate the predicted effect of genetic variants are heavily biased towards protein-coding sequence. Variants outside of these regions may have a large impact on protein expression and/or structure and can lead to disease, but this effect can be challenging to predict. Consequently, these variants are poorly annotated using standard tools. We have developed a plugin to the Ensembl Variant Effect Predictor, the UTRannotator, that annotates variants in 5 ′ untranslated regions (5 ′ UTR) that create or disrupt upstream open reading frames. We investigate the utility of this tool using the ClinVar database, providing an annotation for 31.9% of all 5 ′ UTR (likely) pathogenic variants, and highlighting 31 variants of uncertain significance as candidates for further follow-up. We will continue to update the UTRannotator as we gain new knowledge on the impact of variants in UTRs. Availability and implementation UTRannotator is freely available on Github: https://github.com/ImperialCardioGenetics/UTRannotator. Supplementary information Supplementary data are available at Bioinformatics online. [ABSTRACT FROM AUTHOR]

Published

2021

24. Comprehensive screening shows that mutations in the known syndromic genes are rare in infants presenting with hyperinsulinaemic hypoglycaemia.

Author

Laver, Thomas W., Wakeling, Matthew N., Hua, Janet Hong Yeow, Houghton, Jayne A. L., Hussain, Khalid, Ellard, Sian, and Flanagan, Sarah E.

Subjects

*GENES, *MOLECULAR genetics, *HYPERINSULINISM, *HYPOGLYCEMIA, *BLOOD sugar, *ENDOCRINE diseases, *PANCREATIC diseases

Abstract

Summary: Objective: Hyperinsulinaemic hypoglycaemia (HH) can occur in isolation or more rarely feature as part of a syndrome. Screening for mutations in the "syndromic" HH genes is guided by phenotype with genetic testing used to confirm the clinical diagnosis. As HH can be the presenting feature of a syndrome, it is possible that mutations will be missed as these genes are not routinely screened in all newly diagnosed individuals. We investigated the frequency of pathogenic variants in syndromic genes in infants with HH who had not been clinically diagnosed with a syndromic disorder at referral for genetic testing. Design: We used genome sequencing data to assess the prevalence of mutations in syndromic HH genes in an international cohort of patients with HH of unknown genetic cause. Patients: We undertook genome sequencing in 82 infants with HH without a clinical diagnosis of a known syndrome at referral for genetic testing. Measurements: Within this cohort, we searched for the genetic aetiologies causing 20 different syndromes where HH had been reported as a feature. Results: We identified a pathogenic KMT2D variant in a patient with HH diagnosed at birth, confirming a genetic diagnosis of Kabuki syndrome. Clinical data received following the identification of the mutation highlighted additional features consistent with the genetic diagnosis. Pathogenic variants were not identified in the remainder of the cohort. Conclusions: Pathogenic variants in the syndromic HH genes are rare; thus, routine testing of these genes by molecular genetics laboratories is unlikely to be justified in patients without syndromic phenotypes. [ABSTRACT FROM AUTHOR]

Published

2018

25. Diagnosis of lethal or prenatal-onset autosomal recessive disorders by parental exome sequencing.

Author

Stals, Karen L., Wakeling, Matthew, Baptista, Júlia, Caswell, Richard, Parrish, Andrew, Rankin, Julia, Tysoe, Carolyn, Jones, Garan, Gunning, Adam C., Lango Allen, Hana, Bradley, Lisa, Brady, Angela F., Carley, Helena, Carmichael, Jenny, Castle, Bruce, Cilliers, Deirdre, Cox, Helen, Deshpande, Charu, Dixit, Abhijit, and Eason, Jacqueline

Abstract

Objective: Rare genetic disorders resulting in prenatal or neonatal death are genetically heterogeneous, but testing is often limited by the availability of fetal DNA, leaving couples without a potential prenatal test for future pregnancies. We describe our novel strategy of exome sequencing parental DNA samples to diagnose recessive monogenic disorders in an audit of the first 50 couples referred.Method: Exome sequencing was carried out in a consecutive series of 50 couples who had 1 or more pregnancies affected with a lethal or prenatal-onset disorder. In all cases, there was insufficient DNA for exome sequencing of the affected fetus. Heterozygous rare variants (MAF < 0.001) in the same gene in both parents were selected for analysis. Likely, disease-causing variants were tested in fetal DNA to confirm co-segregation.Results: Parental exome analysis identified heterozygous pathogenic (or likely pathogenic) variants in 24 different genes in 26/50 couples (52%). Where 2 or more fetuses were affected, a genetic diagnosis was obtained in 18/29 cases (62%). In most cases, the clinical features were typical of the disorder, but in others, they result from a hypomorphic variant or represent the most severe form of a variable phenotypic spectrum.Conclusion: We conclude that exome sequencing of parental samples is a powerful strategy with high clinical utility for the genetic diagnosis of lethal or prenatal-onset recessive disorders. © 2017 The Authors Prenatal Diagnosis published by John Wiley & Sons Ltd. [ABSTRACT FROM AUTHOR]

Published

2018

26. A biallelic loss‐of‐function PDIA6 variant in a second patient with polycystic kidney disease, infancy‐onset diabetes, and microcephaly.

Author

De Franco, Elisa, Wakeling, Matthew N., Frew, Russel D., Russ‐Silsby, James, Peters, Catherine, Marks, Stephen D., Hattersley, Andrew T., and Flanagan, Sarah E.

Subjects

*POLYCYSTIC kidney disease, *MICROCEPHALY, *PANCREATIC beta cells, *DIABETES, *TYPE 1 diabetes, *FETAL growth retardation

Abstract

Infancy-onset diabetes, microcephaly, PDIA6, polycystic kidney disease, whole genome sequencing, transcript Keywords: infancy-onset diabetes; microcephaly; PDIA6; polycystic kidney disease; transcript; whole genome sequencing EN infancy-onset diabetes microcephaly PDIA6 polycystic kidney disease transcript whole genome sequencing 457 458 2 10/13/22 20221101 NES 221101 We report a second patient with intrauterine growth retardation, congenital polycystic kidney disease, infancy-onset diabetes, microcephaly, and liver fibrosis caused by a homozygous PDIA6 loss-of-function variant. A biallelic loss-of-function PDIA6 variant in a second patient with polycystic kidney disease, infancy-onset diabetes, and microcephaly. [Extracted from the article]

Published

2022

27. Assimilation of vertical motion from simulated cloudy satellite imagery in an idealized single column model.

Author

Wakeling, Matthew, Eyre, John, Hughes, Sue, and Roulstone, Ian

Subjects

*ATMOSPHERIC models, *VERTICAL motion, *REMOTE-sensing images, *INFRARED radiation, *CLOUDS

Abstract

Satellite infrared sounders are invaluable tools for making observations of the structure of the atmosphere. They provide much of the observational data used to initialize atmospheric models, especially in regions that do not have extensive surface-based observing systems, such as oceans. However, information is lacking in the presence of cloud, as the cloud layer is opaque to infrared radiation. This means that where information is most desired (such as in a developing storm) it is often in the shortest supply. In order to explore the mathematics of assimilating data from cloudy radiances, a study has been performed using an idealized single-column atmospheric model. The model simulates cloud development in an atmosphere with vertical motion, allowing the characteristics of a 2D-Var data assimilation system using a single simulated infrared satellite observation taken multiple times to be studied. The strongly nonlinear nature of cloud formation poses a challenge for variational methods. The adjoint method produces an accurate gradient for the cost function and minimization is achieved using preconditioned conjugate gradients. The conditioning is poor and varies strongly with the atmospheric variables and the cost function has multiple minima, but acceptable results are achieved. The assimilation system is provided with a prior forecast simulated by adding random correlated Gaussian error to the truth. Assimilating observations comparable to those available from current geostationary satellites allows vertical motion to be retrieved with an error of less than a centimetre per second in most conditions. Moreover, evaluating the second derivative of the cost function at the minimum provides an estimate of the uncertainty in the retrieval. This allows atmospheric states that do not provide sufficient information for retrieval of vertical motion to be detected (such as a cloudless atmosphere or a non-moving opaque cloud layer in the upper troposphere). Retrieval is most accurate with upwards motion. [ABSTRACT FROM AUTHOR]

Published

2015

28. 360-OR: A Novel Genetic Syndrome of Early-Onset Diabetes, Microcephaly, and Epilepsy Due to Homozygous YIPF5 Mutations.

Author

LYTRIVI, MARIA, FRANCO, ELISA DE, PATEL, KASHYAP A., ESTEVE, MARIANA IGOILLO, COSENTINO, CRISTINA, WAKELING, MATTHEW N., HALILOGLU, BELMA, YILDIZ, MELEK, GODBOLE, TUSHAR, HATTERSLEY, ANDREW T., and CNOP, MIRIAM

Abstract

Neonatal diabetes is caused by single gene mutations affecting fundamental β-cell function pathways. 20% of cases of neonatal diabetes remain genetically unexplained. Our aim was to explore the genetic basis of a syndrome characterized by neonatal diabetes, microcephaly and epilepsy, present in 2 unrelated patients. The Turkish and Indian patients were born to consanguineous parents. Using whole genome sequencing, we found that they had homozygous likely deleterious variants (missense, p.(Ala181Val) and in-frame deletion p.(Lys106del)) in YIPF5. We then performed replication studies in 112 patients with neonatal diabetes by targeted next generation sequencing. These identified 2 homozygous YIPF5 mutations (p.(Trp218Arg) and p.(Ile98Ser)) in 3 patients (2 siblings) with early-onset diabetes, epilepsy and microcephaly. In functional studies, YIPF5 was expressed in human islets and fetal brain cortex, as evaluated by qPCR and in situ hybridization. Because YIPF5 is involved in endoplasmic reticulum (ER)-to-Golgi trafficking, we examined the impact of YIPF5 loss-of-function on β-cell survival during ER stress. YIPF5 was silenced in the human β-cell line EndoC-βH1 and in human islets. YIPF5 silencing sensitized β cells to apoptosis induced by the ER stressors thapsigargin and brefeldin A. The ER stressors enhanced CHOP, BiP and spliced XBP1 expression in YIPF5-depleted cells, indicating increased ER stress signaling. Expression of the proapoptotic proteins PUMA and DP5 was also enhanced by YIPF5 silencing. CHOP and DP5 knockdown partially protected YIPF5-deficient cells from apoptosis, suggesting that they mediate apoptosis. In conclusion, homozygous loss-of-function mutations in YIPF5 are a novel cause of early-onset diabetes, microcephaly and epilepsy. This syndrome unveils a critical role of YIPF5 and ER-to-Golgi trafficking in the function and survival of human β-cells and neurons. Disclosure: M. Lytrivi: None. E. De Franco: Other Relationship; Self; Novo Nordisk Foundation. K.A. Patel: None. M. Igoillo Esteve: None. C. Cosentino: None. M.N. Wakeling: None. B. Haliloglu: None. M. Yildiz: None. T. Godbole: None. A.T. Hattersley: None. M. Cnop: None. Funding: Fonds Erasme for Medical Research; European Union (667191); Fonds National de la Recherche Scientifique; Brussels-Capital Region Innoviris [ABSTRACT FROM AUTHOR]

Published

2019

29. The p.(Gly111Arg) ABCC8 Variant: A Founder Mutation Causing Congenital Hyperinsulinism in the Indian Agarwal Community.

Author

Jain, Vandana, Radha, Venkatesan, Mohan, Viswanathan, Wakeling, Matthew N., Bennett, Jasmin J., and Flanagan, Sarah E.

Subjects

*MEDICAL sciences, *MEDICAL genetics, *HUMAN genetics, *GENETIC variation, *MOLECULAR genetics

Abstract

The article discusses the p.(Gly111Arg) ABCC8 variant as a founder mutation causing congenital hyperinsulinism in the Indian Agarwal community. The study identifies individuals with this variant, predominantly from the Agarwal community, and highlights the genetic homogeneity within this group due to clan exogamy and caste endogamy practices. The findings suggest that the p.(Gly111Arg) variant is a founder variant in the Agarwal community, enabling rapid prenatal screening and molecular diagnosis for congenital hyperinsulinism in this population. [Extracted from the article]

Published

2024

30. Bi-allelic CAMSAP1 variants cause a clinically recognizable neuronal migration disorder.

Author

Khalaf-Nazzal, Reham, Fasham, James, Inskeep, Katherine A., Blizzard, Lauren E., Leslie, Joseph S., Wakeling, Matthew N., Ubeyratna, Nishanka, Mitani, Tadahiro, Griffith, Jennifer L., Baker, Wisam, Al-Hijawi, Fida', Keough, Karen C., Gezdirici, Alper, Pena, Loren, Spaeth, Christine G., Turnpenny, Peter D., Walsh, Joseph R., Ray, Randall, Neilson, Amber, and Kouranova, Evguenia

Subjects

*TUBULINS, *AXONAL transport, *NEURONAL differentiation, *CORPUS callosum, *PERINATAL death, *NEURAL stem cells, *DYSPLASIA, *MICROTUBULES

Abstract

Non-centrosomal microtubules are essential cytoskeletal filaments that are important for neurite formation, axonal transport, and neuronal migration. They require stabilization by microtubule minus-end-targeting proteins including the CAMSAP family of molecules. Using exome sequencing on samples from five unrelated families, we show that bi-allelic CAMSAP1 loss-of-function variants cause a clinically recognizable, syndromic neuronal migration disorder. The cardinal clinical features of the syndrome include a characteristic craniofacial appearance, primary microcephaly, severe neurodevelopmental delay, cortical visual impairment, and seizures. The neuroradiological phenotype comprises a highly recognizable combination of classic lissencephaly with a posterior more severe than anterior gradient similar to PAFAH1B1(LIS1)- related lissencephaly and severe hypoplasia or absence of the corpus callosum; dysplasia of the basal ganglia, hippocampus, and midbrain; and cerebellar hypodysplasia, similar to the tubulinopathies, a group of monogenic tubulin-associated disorders of cortical dysgenesis. Neural cell rosette lineages derived from affected individuals displayed findings consistent with these phenotypes, including abnormal morphology, decreased cell proliferation, and neuronal differentiation. Camsap1 -null mice displayed increased perinatal mortality, and RNAScope studies identified high expression levels in the brain throughout neurogenesis and in facial structures, consistent with the mouse and human neurodevelopmental and craniofacial phenotypes. Together our findings confirm a fundamental role of CAMSAP1 in neuronal migration and brain development and define bi-allelic variants as a cause of a clinically distinct neurodevelopmental disorder in humans and mice. We describe bi-allelic variants in CAMSAP1 , which encodes a molecule crucially important for minus-end microtubule stabilization, as a cause of a clinically recognizable, syndromic neuronal migration disorder with similarities to the "tubulinopathies." Camsap1 −/− mice displayed increased perinatal mortality, and proband-derived neural cell rosette lineages showed decreased cell proliferation and differentiation. [ABSTRACT FROM AUTHOR]

Published

2022

31. YIPF5 mutations cause neonatal diabetes and microcephaly through endoplasmic reticulum stress.

Author

Franco, Elisa De, Lytrivi, Maria, Ibrahim, Hazem, Montaser, Hossam, Wakeling, Matthew N., Fantuzzi, Federica, Patel, Kashyap, Demarez, Céline, Ying Cai, Igoillo-Esteve, Mariana, Cosentino, Cristina, Lithovius, Väinö, Vihinen, Helena, Jokitalo, Eija, Laver, Thomas W., Johnson, Matthew B., Sawatani, Toshiaki, Shakeri, Hadis, Pachera, Nathalie, and Haliloglu, Belma

Subjects

*ENDOPLASMIC reticulum, *INDUCED pluripotent stem cells, *ETIOLOGY of diabetes, *EMBRYONIC stem cells, *GENETIC mutation, *EPILEPSY, *INSULINOMA

Abstract

Neonatal diabetes is caused by single gene mutations reducing pancreatic β cell number or impairing β cell function. Understanding the genetic basis of rare diabetes subtypes highlights fundamental biological processes in β cells. We identified 6 patients from 5 families with homozygous mutations in the YIPF5 gene, which is involved in trafficking between the endoplasmic reticulum (ER) and the Golgi. All patients had neonatal/early-onset diabetes, severe microcephaly, and epilepsy. YIPF5 is expressed during human brain development, in adult brain and pancreatic islets. We used 3 human β cell models (YIPF5 silencing in EndoC-βH1 cells, YIPF5 knockout and mutation knockin in embryonic stem cells, and patient-derived induced pluripotent stem cells) to investigate the mechanism through which YIPF5 loss of function affects β cells. Loss of YIPF5 function in stem cell-derived islet cells resulted in proinsulin retention in the ER, marked ER stress, and β cell failure. Partial YIPF5 silencing in EndoC-βH1 cells and a patient mutation in stem cells increased the β cell sensitivity to ER stress-induced apoptosis. We report recessive YIPF5 mutations as the genetic cause of a congenital syndrome of microcephaly, epilepsy, and neonatal/early-onset diabetes, highlighting a critical role of YIPF5 in β cells and neurons. We believe this is the first report of mutations disrupting the ER-to-Golgi trafficking, resulting in diabetes. [ABSTRACT FROM AUTHOR]

Published

2020