Homozygous deletion of <i>TRMT10A</i> as part of a contiguous gene deletion in a syndrome of failure to thrive, delayed puberty, intellectual disability and diabetes mellitus

Zung, Amnon; Kori, Michal; Burundukov, Ella; Ben-Yosef, Tamar; Tatoor, Yasmin; Granot, Esther

doi:10.1002/ajmg.a.37341

Cited by 38 publications

(44 citation statements)

References 18 publications

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“… had hypoglycaemia, as did the individual reported by Zung et al . ; however, no hypoglycaemia was reported in our patients or in those reported by Igoillo‐Esteve et al . .…”

Section: Discussioncontrasting

confidence: 74%

“… and Zung et al . . All the individuals had intellectual disability, and epilepsy was common except in the individual reported by Zung et al.…”

Section: Discussionmentioning

confidence: 84%

“…More recently, Zung et al . described an individual with TRMT10A deletion with failure to thrive, delayed puberty, intellectual disability and diabetes. In the present paper, we report the eighth and ninth individual from the fourth family known to have this syndrome as a result of a TRMT10A mutation.…”

Section: Discussionmentioning

confidence: 99%

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tRNA methyltransferase homologue gene TRMT10A mutation in young adult‐onset diabetes with intellectual disability, microcephaly and epilepsy

et al. 2016

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BackgroundA syndrome of young‐onset diabetes mellitus associated with microcephaly, epilepsy and intellectual disability caused by mutations in the tRNA methyltransferase 10 homologue A (TRMT10A) gene has recently been described.Case reportWe report two siblings from the fourth family reported to have diabetes mellitus as a result of a TRMT10A mutation. A homozygous nonsense mutation p.Glu27Ter in TRMT10A was identified using targeted next‐generation sequencing and confirmed by PCR/Sanger sequencing. Diabetes was diagnosed while the subjects were in their 20s and was characterized by insulin resistance. Epilepsy and intellectual disability were features in common. Mild microcephaly was present at birth but their final head circumferences were normal.ConclusionOur report provides independent confirmation of the role of TRMT10A mutations in this syndrome and expands its phenotypic description. TRMT10A sequencing should be considered in children or adults with young‐onset diabetes who have a history of intellectual disability, microcephaly and epilepsy. This report also shows the advantages of using a targeted panel to identify previously unsuspected monogenic diabetes among young‐onset non‐insulin‐dependent diabetes in the absence of obesity and autoimmunity.

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“… had hypoglycaemia, as did the individual reported by Zung et al . ; however, no hypoglycaemia was reported in our patients or in those reported by Igoillo‐Esteve et al . .…”

Section: Discussioncontrasting

confidence: 74%

“… and Zung et al . . All the individuals had intellectual disability, and epilepsy was common except in the individual reported by Zung et al.…”

Section: Discussionmentioning

confidence: 84%

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tRNA methyltransferase homologue gene TRMT10A mutation in young adult‐onset diabetes with intellectual disability, microcephaly and epilepsy

et al. 2016

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“…In accordance with its localized function, mutations in TRMT10C cause mitochondrial disorders [166]. Association of mutations in TRMT10A with microcephaly and young onset diabetes reaffirms its regulatory role in lineage differentiation [167,168,169,170,171]. Basal levels of TRMT10A protein expression is observed in all tissues but is enriched in brain and pancreatic β cells accounting for the tissue-specific developmental disorders [167].…”

Section: Amplification and Diversification Of Eukaryal Trna Methymentioning

confidence: 99%

Factors That Shape Eukaryotic tRNAomes: Processing, Modification and Anticodon–Codon Use

Maraia

Arimbasseri

2017

Biomolecules

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Transfer RNAs (tRNAs) contain sequence diversity beyond their anticodons and the large variety of nucleotide modifications found in all kingdoms of life. Some modifications stabilize structure and fit in the ribosome whereas those to the anticodon loop modulate messenger RNA (mRNA) decoding activity more directly. The identities of tRNAs with some universal anticodon loop modifications vary among distant and parallel species, likely to accommodate fine tuning for their translation systems. This plasticity in positions 34 (wobble) and 37 is reflected in codon use bias. Here, we review convergent evidence that suggest that expansion of the eukaryotic tRNAome was supported by its dedicated RNA polymerase III transcription system and coupling to the precursor-tRNA chaperone, La protein. We also review aspects of eukaryotic tRNAome evolution involving G34/A34 anticodon-sparing, relation to A34 modification to inosine, biased codon use and regulatory information in the redundancy (synonymous) component of the genetic code. We then review interdependent anticodon loop modifications involving position 37 in eukaryotes. This includes the eukaryote-specific tRNA modification, 3-methylcytidine-32 (m3C32) and the responsible gene, TRM140 and homologs which were duplicated and subspecialized for isoacceptor-specific substrates and dependence on i6A37 or t6A37. The genetics of tRNA function is relevant to health directly and as disease modifiers.

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“…Notably, defects in tRNA modification have emerged as the cause of diverse neurological and neurodevelopmental disorders, thereby highlighting the critical role of tRNA modification in human health and physiology (Angelova et al, 2018; Ramos & Fu, 2019). In particular, the brain appears to be sensitive to any perturbation in translation efficiency and fidelity brought about by defects in tRNA modifications, as evidenced from the numerous cognitive disorders linked to tRNA modification enzymes such as: the Elongator complex (Hawer et al, 2018; Kojic & Wainwright, 2016); ADAT3 (Alazami et al, 2013; El‐Hattab et al, 2016; Ramos, Han, et al, 2019); NSUN2 (Abbasi‐Moheb et al, 2012; Khan et al, 2012; Martinez et al, 2012); FTSJ1 (Dai et al, 2008; Freude et al, 2004; Froyen et al, 2007; Gong et al, 2008; Guy et al, 2015; Ramser et al, 2004; Takano et al, 2008); WDR4 (Chen et al, 2018; Shaheen et al, 2015; Trimouille et al, 2018); KEOPS complex (Braun et al, 2017); PUS3 (Abdelrahman, Al‐Shamsi, Ali, & Al‐Gazali, 2018; Shaheen, Han, et al, 2016); CTU2 (Shaheen, Al‐Salam, El‐Hattab, & Alkuraya, 2016; Shaheen, Mark, et al, 2019); TRMT10A (Gillis et al, 2014; Igoillo‐Esteve et al, 2013; Narayanan et al, 2015; Yew, McCreight, Colclough, Ellard, & Pearson, 2016; Zung et al, 2015); PUS7 (de Brouwer et al, 2018; Shaheen, Tasak, et al, 2019); and ALKBH8 (Monies, Vagbo, Al‐Owain, Alhomaidi, & Alkuraya, 2019).…”

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confidence: 99%

An intellectual disability‐associated missense variant in TRMT1 impairs tRNA modification and reconstitution of enzymatic activity

et al. 2020

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The human TRMT1 gene encodes an RNA methyltransferase enzyme responsible for catalyzing dimethylguanosine (m2,2G) formation in transfer RNAs (tRNAs). Frameshift mutations in TRMT1 have been shown to cause autosomal-recessive intellectual disability (ID) in the human population but additional TRMT1 variants remain to be characterized. Here, we describe a homozygous TRMT1 missense variant in a patient displaying developmental delay, ID, and epilepsy. The missense variant changes an arginine residue to a cysteine (R323C) within the methyltransferase domain and is expected to perturb protein folding. Patient cells expressing TRMT1-R323C exhibit a deficiency in m2,2G modifications within tRNAs, indicating that the mutation causes loss of function. Notably, the TRMT1 R323C mutant retains tRNA binding but is unable to rescue m2,2G formation in TRMT1-deficient human cells. Our results identify a pathogenic point mutation in TRMT1 that perturbs tRNA modification activity and demonstrate that m2,2G modifications are disrupted in the cells of patients with TRMT1-associated ID disorders.

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Homozygous deletion of TRMT10A as part of a contiguous gene deletion in a syndrome of failure to thrive, delayed puberty, intellectual disability and diabetes mellitus

Cited by 38 publications

References 18 publications

tRNA methyltransferase homologue gene TRMT10A mutation in young adult‐onset diabetes with intellectual disability, microcephaly and epilepsy

tRNA methyltransferase homologue gene TRMT10A mutation in young adult‐onset diabetes with intellectual disability, microcephaly and epilepsy

Factors That Shape Eukaryotic tRNAomes: Processing, Modification and Anticodon–Codon Use

An intellectual disability‐associated missense variant in TRMT1 impairs tRNA modification and reconstitution of enzymatic activity

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