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Drug
Enzyme
Compound
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Target Concepts:
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Query: UMLS:C0085584 (
encephalopathy
)
18,178
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Alaskan Husky
Encephalopathy
(AHE) has been previously proposed as a mitochondrial
encephalopathy
based on neuropathological similarities with human Leigh Syndrome (LS). We studied 11 Alaskan Husky dogs with AHE, but found no abnormalities in respiratory chain enzyme activities in muscle and liver, or mutations in mitochondrial or nuclear genes that cause LS in people. A genome wide association study was performed using eight of the affected dogs and 20 related but unaffected control AHs using the Illumina canine HD array. SLC19A3 was identified as a positional candidate gene. This gene controls the uptake of thiamine in the CNS via expression of the thiamine
transporter protein
THTR2. Dogs have two copies of this gene located within the candidate interval (SLC19A3.2 - 43.36-43.38 Mb and SLC19A3.1 - 43.411-43.419 Mb) on chromosome 25. Expression analysis in a normal dog revealed that one of the paralogs, SLC19A3.1, was expressed in the brain and spinal cord while the other was not. Subsequent exon sequencing of SLC19A3.1 revealed a 4bp insertion and SNP in the second exon that is predicted to result in a functional protein truncation of 279 amino acids (c.624 insTTGC, c.625 C>A). All dogs with AHE were homozygous for this mutation, 15/41 healthy AH control dogs were heterozygous carriers while 26/41 normal healthy AH dogs were wild type. Furthermore, this mutation was not detected in another 187 dogs of different breeds. These results suggest that this mutation in SLC19A3.1, encoding a thiamine
transporter protein
, plays a critical role in the pathogenesis of AHE.
...
PMID:Genome-wide association analysis identifies a mutation in the thiamine transporter 2 (SLC19A3) gene associated with Alaskan Husky encephalopathy. 2346 84
Glucose transporter 1 deficiency syndrome (GLUT1-DS) is an inborn error of metabolism caused by impaired glucose transport through blood brain barrier due to mutation in SLC2A1 gene, encoding
transporter protein
. Clinical spectrum includes various signs and symptoms, ranging from severe epileptic
encephalopathy
to movement disorders. The diagnosis of GLUT1-DS requires hypoglycorrhachia in the presence of normoglycaemia with a reduced cerebrospinal fluid (CSF):plasma glucose ratio. The absence of pathogenic mutation in SLC2A1 gene does not exclude the diagnosis. This case report describes a patient with late onset GLUT1-DS with a novel sporadic mutation c.539T>A, p.Met180Lys in exon 5 of the SLC2A1 gene. The dominating clinical features were epilepsy and paroxysmal dyskinesias provoked by infection, emotional stress and fasting. The ictal EEG was characterized by generalized paroxysmal 3-3.5Hz spike-slow wave complexes (absences). Treatment with ketogenic diet showed clinical improvement with the reduction of paroxysmal dyskinesias.
...
PMID:Novel mutation in a patient with late onset GLUT1 deficiency syndrome. 2792 75
Glycine constitutes a major inhibitory neurotransmitter predominantly in caudal regions of the CNS. The extracellular glycine concentration is regulated synergistically by two high affinity, large capacity transporters GlyT1 and GlyT2. Both proteins are encoded by single genes SLC6A9 and SLC6A5, respectively. Mutations within the SLC6A5 gene encoding for GlyT2 have been demonstrated to be causative for hyperekplexia (OMIM #614618), a complex neuromuscular disease, in humans. In contrast, mutations within the SLC6A9 gene encoding for GlyT1 have been associated with GlyT1
encephalopathy
(OMIM #601019), a disease causing severe postnatal respiratory deficiency, muscular hypotonia and arthrogryposis. The consequences of the respective GlyT1 mutations on the function of the
transporter protein
, however, have not yet been analysed. In this study we present the functional characterisation of three previously published GlyT1 mutations, two mutations predicted to cause truncation of GlyT1 (GlyT1
Q573
* and GlyT1
K310F+fs
*
31
) and one predicted to cause an amino acid exchange within transmembrane domain 7 of the transporter (GlyT1
S407G
), that are associated with GlyT1
encephalopathy
. Additionally, the characterization of a novel mutation predicted to cause an amino acid exchange within transmembrane domain 1 (GlyT1
V118M
) identified in two fetuses showing increased nuchal translucency and arthrogryposis in routine ultrasound scans is demonstrated. We show that in recombinant systems the two presumably truncating mutations resulted in an intracellular retained GlyT1 protein lacking the intracellular C-terminal domain. In both cases this truncated protein did not show any residual transport activity. The point mutations, hGlyT1
S407G
and hGlyT1
V118M
, were processed correctly, but showed severely diminished activity, thus constituting a functional knock-out in-vivo. Taken together our data demonstrate that all analysed mutations of GlyT1 that have been identified in GlyT1
encephalopathy
patients cause severe impairment of transporter function. This is consistent with the idea that loss of GlyT1 function is indeed causal for the disease phenotype.
...
PMID:GlyT1 encephalopathy: Characterization of presumably disease causing GlyT1 mutations. 3271 1
