<i>PDXK</i> mutations cause polyneuropathy responsive to pyridoxal 5′‐phosphate supplementation

Chelban, Viorica; Wilson, Matthew P.; Warman‐Chardon, Jodi; Vandrovcová, Jana; Zanetti, M. Natalia; Zamba‐Papanicolaou, Eleni; Efthymiou, Stéphanie; Pope, Simon; Conte, Maria R.; Abis, Giancarlo; Liu, Yo‐Tsen; Tribollet, Eloise; Haridy, Nourelhoda A.; Botía, Juan A.; Ryten, Mina; Nicolaou, Paschalis; Minaidou, Anna; Christodoulou, Kyproula; Kernohan, Kristin D.; Eaton, Alison; Osmond, Matthew; Itō, Yoko; Bourque, Pierre R.; Jepson, James E.C.; Bello, Oscar; Bremner, Fion; Cordivari, Carla; Reilly, Mary M.; Foiani, Martha; Heslegrave, Amanda; Zetterberg, Henrik; Heales, Simon; Wood, Nicholas W.; Rothman, James E.; Boycott, Kym M.; Mills, Philippa; Clayton, Peter T.; Houlden, Henry

doi:10.1002/ana.25524

Cited by 58 publications

(37 citation statements)

References 68 publications

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“…Finally, a PLP (pyr-idoxal 5 0 -phosphate)-responsive primary axonal peripheral neuropathy and optic atrophy have recently been associated with recessive mutations in PDXK (MIM: 179020), encoding a gene involved in converting pyridoxal to the active form of B6, PLP. 26 Given the fact that some children with IGDs have pyridoxine-responsive seizures, this is interesting because alkaline phosphatase also converts PLP to pyridoxal, and this process is essential for B6 to reach the central nervous system (CNS). The mechanism at play in the neuropathy seen in the individuals described here would benefit from model organism studies.…”

Section: Discussionmentioning

confidence: 99%

Mutations in PIGB Cause an Inherited GPI Biosynthesis Defect with an Axonal Neuropathy and Metabolic Abnormality in Severe Cases

Murakami

Nguyen

Baratang

et al. 2019

The American Journal of Human Genetics

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Proteins anchored to the cell surface via glycosylphosphatidylinositol (GPI) play various key roles in the human body, particularly in development and neurogenesis. As such, many developmental disorders are caused by mutations in genes involved in the GPI biosynthesis and remodeling pathway. We describe ten unrelated families with bi-allelic mutations in PIGB, a gene that encodes phosphatidylinositol glycan class B, which transfers the third mannose to the GPI. Ten different PIGB variants were found in these individuals. Flow cytometric analysis of blood cells and fibroblasts from the affected individuals showed decreased cell surface presence of GPI-anchored proteins. Most of the affected individuals have global developmental and/or intellectual delay, all had seizures, two had polymicrogyria, and four had a peripheral neuropathy. Eight children passed away before four years old. Two of them had a clinical diagnosis of DOORS syndrome (deafness, onychodystrophy, osteodystrophy, mental retardation, and seizures), a condition that includes sensorineural deafness, shortened terminal phalanges with small finger and toenails, intellectual disability, and seizures; this condition overlaps with the severe phenotypes associated with inherited GPI deficiency. Most individuals tested showed elevated alkaline phosphatase, which is a characteristic of the inherited GPI deficiency but not DOORS syndrome. It is notable that two severely affected individuals showed 2-oxoglutaric aciduria, which can be seen in DOORS syndrome, suggesting that severe cases of inherited GPI deficiency and DOORS syndrome might share some molecular pathway disruptions.

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Section: Discussionmentioning

confidence: 99%

Mutations in PIGB Cause an Inherited GPI Biosynthesis Defect with an Axonal Neuropathy and Metabolic Abnormality in Severe Cases

Murakami

Nguyen

Baratang

et al. 2019

The American Journal of Human Genetics

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“…This collection consists of 109 different co-expression networks ( Supplementary Table 1 ) that belong to four different network groups: (1) the Religious Orders Study and Memory and Aging Project (ROSMAP) ( Bennett et al, 2012a , b ; De Jager et al, 2018 ) composed of four co-expression networks derived from post-mortem human frontal cortex originating from control individuals, as well as those with cognitive impairment and Alzheimer’s disease; (2) The Genotype-Tissue Expression project (GTEx) V6 and V7 ( The GTEx Consortium, 2015 ) composed of two suites of GCNs on 47 and 51 post-mortem control human tissue samples, respectively; (3) United Kingdom Brain Expression Consortium (UKBEC) ( Forabosco et al, 2013 ; UK Brain Expression Consortium, et al, 2014 ) composed of 10 microarray-based gene expression profiling networks derived from post-mortem control human brain tissue; (4) North America Brain Expression Consortium (NABEC) ( Dillman et al, 2017 ), composed of one gene co-expression network derived from post-mortem control human frontal cortex. Through CoExp, we and others have used these models to provide annotations for genes and gene sets in a variety of papers ( Chelban et al, 2017 , 2019 ; Salpietro et al, 2017 , 2018 ; Efthymiou et al, 2019 ).…”

Section: Resultsmentioning

confidence: 99%

CoExp: A Web Tool for the Exploitation of Co-expression Networks

et al. 2021

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Gene co-expression networks are a powerful type of analysis to construct gene groupings based on transcriptomic profiling. Co-expression networks make it possible to discover modules of genes whose mRNA levels are highly correlated across samples. Subsequent annotation of modules often reveals biological functions and/or evidence of cellular specificity for cell types implicated in the tissue being studied. There are multiple ways to perform such analyses with weighted gene co-expression network analysis (WGCNA) amongst one of the most widely used R packages. While managing a few network models can be done manually, it is often more advantageous to study a wider set of models derived from multiple independently generated transcriptomic data sets (e.g., multiple networks built from many transcriptomic sources). However, there is no software tool available that allows this to be easily achieved. Furthermore, the visual nature of co-expression networks in combination with the coding skills required to explore networks, makes the construction of a web-based platform for their management highly desirable. Here, we present the CoExp Web application, a user-friendly online tool that allows the exploitation of the full collection of 109 co-expression networks provided by the CoExpNets suite of R packages. We describe the usage of CoExp, including its contents and the functionality available through the family of CoExpNets packages. All the tools presented, including the web front- and back-ends are available for the research community so any research group can build its own suite of networks and make them accessible through their own CoExp Web application. Therefore, this paper is of interest to both researchers wishing to annotate their genes of interest across different brain network models and specialists interested in the creation of GCNs looking for a tool to appropriately manage, use, publish, and share their networks in a consistent and productive manner.

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“…We evaluated the reasons for prior noninclusion of detected genes in the NMD‐panel to uncover the most frequent reasons for missed panel diagnosis. Our analysis showed that 50% (5/10) of genes were only recently identified as associated with their respective phenotypes, with first reports in the past three years: AGTPBP1 (AR childhood‐onset neurodegeneration with cerebellar atrophy; MIM# 618276; Shashi et al, 2018), ADPRS (AR stress‐induced childhood‐onset neurodegeneration with variable ataxia and seizures; MIM# 618170) (Ghosh et al, 2018), FDXR (AR optic atrophy‐ataxia‐peripheral neuropathy‐global developmental delay syndrome; ORPHA:543470; Peng et al, 2017), PDXK (AR hereditary motor and sensory neuropathy type VIC with optic atrophy; MIM# 618511; Chelban et al, 2019), VPS13D (AR spinocerebellar ataxia 4; MIM# 607317; Gauthier et al, 2018; Seong et al, 2018). The other half was not included due to phenotypic discordance: ARSA (AR metachromatic leukodystrophy; MIM# 250100) was not included because of its characteristic cranial MRI abnormalities usually leading to single‐gene testing (van Rappard et al, 2015), DNM1L (AD/AR encephalopathy due to defective mitochondrial and peroxisomal fission 1; MIM# 614388), ECHS1 (AR mitochondrial short‐chain enoyl‐CoA hydratase‐1 deficiency; MIM# 616277), and SEPSECS (AR pontocerebellar hypoplasia type 2D; MIM# 613811) were not included because of clinical presentation where pure NMD features are not typically most prominent.…”

Section: Resultsmentioning

confidence: 99%

Genomic variants causing mitochondrial dysfunction are common in hereditary lower motor neuron disease

et al. 2021

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Hereditary lower motor neuron diseases (LMND) other than 5q‐spinal muscular atrophy (5q‐SMA) can be classified according to affected muscle groups. Proximal and distal forms of non‐5q‐SMA represent a clinically and genetically heterogeneous spectrum characterized by significant overlaps with axonal forms of Charcot–Marie–Tooth (CMT) disease. A consensus for the best approach to molecular diagnosis needs to be reached, especially in light of continuous novel gene discovery and falling costs of next‐generation sequencing (NGS). We performed exome sequencing (ES) in 41 families presenting with non‐5q‐SMA or axonal CMT, 25 of which had undergone a previous negative neuromuscular disease (NMD) gene panel analysis. The total diagnostic yield of ES was 41%. Diagnostic success in the cohort with a previous NMD‐panel analysis was significantly extended by ES, primarily due to novel gene associated‐phenotypes and uncharacteristic phenotypic presentations. We recommend early ES for individuals with hereditary LMND presenting uncharacteristic or significantly overlapping features. As mitochondrial dysfunction was the underlying pathomechanism in 47% of the solved individuals, we highlight the sensitivity of the anterior horn cell and peripheral nerve to mitochondrial imbalance as well as the necessity to screen for mitochondrial disorders in individuals presenting predominant lower motor neuron symptoms.

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PDXK mutations cause polyneuropathy responsive to pyridoxal 5′‐phosphate supplementation

Cited by 58 publications

References 68 publications

Mutations in PIGB Cause an Inherited GPI Biosynthesis Defect with an Axonal Neuropathy and Metabolic Abnormality in Severe Cases

Mutations in PIGB Cause an Inherited GPI Biosynthesis Defect with an Axonal Neuropathy and Metabolic Abnormality in Severe Cases

CoExp: A Web Tool for the Exploitation of Co-expression Networks

Genomic variants causing mitochondrial dysfunction are common in hereditary lower motor neuron disease

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