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TRIT1 encodes a tRNA isopentenyl transferase that allows a strong interaction between the mini helix and the codon. Recent reports support the TRIT1 bi-allelic alterations as the cause of an autosomal recessive disorder, named combined oxydative phophorylation deficiency 35, with microcephaly, developmental disability, and epilepsy. The phenotype is due to decreased mitochondrial function, with deficit of i6A37 in cytosolic and mitochondrial tRNA. Only 10 patients have been reported. We report on two new patients with four novel variants, and confirm the published clinical TRIT1 deficient phenotype stressing the possibility of both very severe, with generalized pharmaco-resistant seizures, and mild phenotypes.

Mitochondrial protein synthesis requires three elongation factors including EF-Tu (TUFM; OMIM 602389), EF-Ts (TSFM; OMIM 604723), and EF-G1 (GFM1; OMIM 606639). Pathogenic variants in any of these three members result in defective mitochondrial translation which can impart an oxidative phosphorylation (OXPHOS) deficiency. In this study, we investigated a consanguineous Pakhtun Pakistani family. There were four affected siblings at the time of this study and one affected girl had died in infancy. The index patient had severe intellectual disability, global developmental delay, dystonia, no speech development, feeding difficulties, and nystagmus. MRI brain presented thinning of corpus callosum and polymicrogyria. Whole exome sequencing revealed a novel compound heterozygous variant in GFM1 located on chromosome 3q25.32. Sanger sequencing confirmed recessive segregation of the maternal (NM_001308164.1:c.409G > A; p.Val137Met) and paternal (NM_001308164.1:c.1880G > A; p.Arg627Gln) variants in all the four affected siblings. These variants are classified as \"likely-pathogenic\" according to the recommendation of ACMG/AMP guideline. GFM1 alterations mostly lead to severe phenotypes and the patients may die in early neonatal life; however, four of the affected siblings had survived till the ages of 10-17 years, without developing any life-threatening conditions. Mostly, in cousin marriages, the pathogenic variants are identical-by-descent, and affected siblings born to such parents are homozygous. Three homozygous variants were shortlisted in the analysis of the WES data, but Sanger sequencing did not confirm their segregation with the disease phenotype. This is the first report from Pakistan expanding pathogenicity of GFM1 gene.

Combined oxidative phosphorylation deficiency 35 (COXPD35) is a rare autosomal recessive disorder associated with homozygous or compound heterozygous mutations in the tRNA isopentenyltransferase (TRIT1) gene in chromosome 1p34.2. To date, only 10 types of allelic variants in the TRIT1 gene have been previously reported in 9 patients with COXPD35. Herein, we describe a case with a novel homozygous missense variant in TRIT1. A 6-year, 6-month-old boy presented with global developmental delay, microcephaly, intractable seizures, and failure to thrive. The other main clinical manifestations were intellectual disability, spastic tetraparesis, truncal hypotonia, malnutrition, polyuria and polydipsia, ketotic hypoglycemia, dysmorphic facial features, strabismus, bicuspid aortic valve, and nephrolithiasis. The detailed biochemical, radiological, and metabolic evaluations were unremarkable. Chromosomal analysis confirmed a normal male 46,XY karyotype and the array comparative genomic hybridization analysis revealed no abnormalities. We identified a novel homozygous missense variant of c.246G>C (p.Met82Ile) in the TRIT1 gene, and the variant was confirmed by Sanger sequencing. The present case is the first report describing strabismus, ketotic hypoglycemia, nephrolithiasis, and bicuspid aortic valve in TRIT1-related COXPD35. This study expands the genotype-phenotype spectrum of TRIT1-related COXPD35.

Complement C1q binding protein (C1QBP, p32) is primarily localized in mitochondrial matrix and associated with mitochondrial oxidative phosphorylative function. C1QBP deficiency presents as a mitochondrial disorder involving multiple organ systems. Recently, disease associated C1QBP mutations have been identified in patients with a combined oxidative phosphorylation deficiency taking an autosomal recessive inherited pattern. The clinical spectrum ranges from intrauterine growth restriction to childhood (cardio) myopathy and late-onset progressive external ophthalmoplegia. This review summarizes the physiological functions of C1QBP, its mutation-associated mitochondrial cardiomyopathy shown in the reported available patients and current experimental disease platforms modeling these conditions.

In this study, we aimed to establish the mitochondrial etiology of the proband\'s progressive neurodegenerative disease suggestive of an atypical Leigh syndrome, by determining the proband\'s pathogenic variants. Brain MRI showed a constellation of multifocal temporally disparate lesions in the cerebral deep gray nuclei, brainstem, cerebellum, spinal cord along with rhombencephalic atrophy, and optic nerve atrophy. Single voxel 1H MRS performed concurrently over the left cerebral deep gray nuclei showed a small lactate peak, increased glutamate and citrate elevation, elevating suspicion of a mitochondrial etiology. Whole exome sequencing revealed three heterozygous nuclear variants mapping in three distinct genes known to cause Leigh syndrome. Our mitochondrial bioenergetic investigations revealed an impaired mitochondrial energy metabolism. The proband\'s overall ATP deficit is further intensified by an ineffective metabolic reprogramming between oxidative phosphorylation and glycolysis. The deficient metabolic adaptability and global energy deficit correlate with the proband\'s neurological symptoms congruent with an atypical Leigh syndrome. In conclusion, our study provides much needed insights to support the development of molecular diagnostic and therapeutic strategies for atypical Leigh syndrome.

Mitochondrial diseases constitute a group of heterogeneous hereditary diseases caused by impairments in mitochondrial oxidative phosphorylation and abnormal cellular energy metabolism. C1QBP plays an important role in mitochondrial homeostasis. In this study, clinical, laboratory examinations, 12-lead electrocardiographic, ultrasonic cardiogram, and magnetic resonance imaging data were collected from four members of a Chinese family. Whole exome were amplified and sequenced for the proband. The structure of protein encoded by the mutation was predicted using multiple software programs. The proband was a 14-year old boy with myocardial hypertrophy, exercise intolerance, ptosis, and increased lactate. His 9-year old brother exhibited similar clinical manifestations while the phenomenon of ptosis was not as noticeable as the proband. The onset of this disease was in infancy in both cases. They were born after uneventful pregnancies of five generation blood relative Chinese parents. A homozygous mutation (Leu275Phe) in the C1QBP gene was identified in both brothers in an autosomal recessive inherited pattern. Their parents were heterozygous mutation carriers without clinical manifestations. We demonstrated that a homozygous C1QBP- P.Leu275Phe mutation in an autosomal recessive inherited mode of inheritance caused early onset combined oxidative phosphorylation deficiency 33 (COXPD 33) (OMIM:617713) in two brothers from a Chinese family.

BACKGROUND: Combined oxidative phosphorylation deficiency 35 (COXPD 35) is a very rare autosomal recessive disorder caused by homozygous or compound heterozygous mutations in the TRIT1 gene on chromosome 1p34. Only six cases of COXPD 35 and six allelic variants of TRIT1 gene mutations have been reported worldwide.
METHODS: We describe two siblings who presented with similar clinical features including severe intellectual disability and epilepsy with onset of symptom in early infancy.
RESULTS: The whole exome sequencing results revealed a compound heterozygous novel variant, c.979G > A (p.Glu327Lys) and c.682 + 2 T > C, on TRIT1 exon 8 and intron 5, respectively, which was confirmed by Sanger sequencing. Protein structure analysis revealed that the p.Glu327Lys variant disrupts the conformation and electrostatic charge of the zinc-finger motif in the tRNA isopentenyltransferase (IPT), impairing binding of the mutant IPT to specific DNA sequences.
CONCLUSIONS: This is the first report of two Korean siblings with COXPD 35 with two novel variants in TRIT1. This study will help to understand the various phenotypic spectra in patients with COXPD 35 and to expand knowledge on the mechanisms of the disease based on genetic features.

A homozygous missense mutation (c.822G>C) was found in the gene encoding the mitochondrial asparaginyl-tRNA synthetase (NARS2) in two siblings born to consanguineous parents. These siblings presented with different phenotypes: one had mild intellectual disability and epilepsy in childhood, whereas the other had severe myopathy. Biochemical analysis of the oxidative phosphorylation (OXPHOS) complexes in both siblings revealed a combined complex I and IV deficiency in skeletal muscle. In-gel activity staining after blue native-polyacrylamide gel electrophoresis confirmed the decreased activity of complex I and IV, and, in addition, showed the presence of complex V subcomplexes. Considering the consanguineous descent, homozygosity mapping and whole-exome sequencing were combined revealing the presence of one single missense mutation in the shared homozygous region. The c.822G>C variant affects the 3\' splice site of exon 7, leading to skipping of the whole exon 7 and a part of exon 8 in the NARS2 mRNA. In EBV-transformed lymphoblasts, a specific decrease in the amount of charged mt-tRNA(Asn) was demonstrated as compared with controls. This confirmed the pathogenic nature of the variant. To conclude, the reported variant in NARS2 results in a combined OXPHOS complex deficiency involving complex I and IV, making NARS2 a new member of disease-associated aaRS2.