Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0004352 (autism)
 32,579 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Biochemical markers are crucial to the development of early diagnosis of infantile autism. The blood concentrations of neuroanalytes epinephrine, norepinephrine, dopamine, and serotonin were elevated in autistic subjects (n = 13) as compared to normal controls (n = 10). Autistic subjects had peptide patterns (peaks I-V, Sephadex G-25) that were different from those of normal controls. Methionine-enkephalin has been tentatively identified from fraction I of autistic subjects by HPLC as one of a large number of peptides that appears to be elevated. The HPLC chromatographic patterns of fraction V from all autistic subjects show a peak with retention time of 7.6 min. The HPLC of control urine fraction V revealed no comparable peaks.
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PMID:Potential biochemical markers for infantile autism. 356 94

The substrate-binding sites in membrane transporters are alternately accessible from either side of the membrane, but the molecular basis of how this alternate opening of internal and external gates is achieved is largely unknown. Here we present data indicating that, in the neuronal electrogenic sodium- and potassium-coupled glutamate transporter EAAC-1, the substrate-binding site and one of the gates, or a residue controlling the gating process, are in close physical proximity. Arginine 445, located only two residues away from a residue implicated in glutamate binding (Bendahan, A., Armon, A., Madani, N., Kavanaugh, M. P., and Kanner, B. I. (2000) J. Biol. Chem. 275, 37436-37442), has been mutated to serine (R445S). Upon expression in oocytes, measurements of l-[(3)H]-glutamate transport under voltage clamp reveal that the charge/flux ratio for l-glutamate at -60 mV is approximately 30-fold higher than that of the wild type. Also, with d-aspartate, R445S exhibits an approximately 15-fold increase in this ratio. In contrast to the wild type, the reversal potential of the substrate-dependent currents in R445S shifts to more negative potentials when either the external sodium or potassium concentration is decreased. These findings indicate that these two cations are the main current carriers in the R445S mutant. Introduction of a methionine or a glutamine, but not a lysine, at position 445 gives rise to a phenotype similar to R445S. Therefore, it seems that the elimination of a positive charge in the vicinity of the substrate-binding site converts the transporter into a glutamate-gated cation-conducting pathway.
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PMID:Arginine 445 controls the coupling between glutamate and cations in the neuronal transporter EAAC-1. 1459 97

In recent years, VIP/PACAP/secretin family has special interest. Family members are vasoactive intestinal peptide (VIP), pituitary adenylate cyclase-activating polypeptide (PACAP), secretin, glucagon, glucagon like peptide-1 (GLP(1)), GLP(2), gastric inhibitory peptide (GIP), growth hormone releasing hormone (GHRH or GRF), and peptide histidine methionine (PHM). Most of the family members present both in central nervous system (CNS) and in various peripheral tissues. The family members that are released into blood from periphery, especially gut, circulate the brain and they can cross the blood brain barrier. On the other hand, some of the members of this family that present in the brain, can cross from brain to blood and reach the peripheral targets. VIP, secretin, GLP(1), and PACAP 27 are transported into the brain by transmembrane diffusion, a non-saturable mechanism. However, uptake of PACAP 38 into the brain is saturable mechanism. While there is no report for the passage of GIP, GLP(2), and PHM, there is only one report that shows, glucagon and GHRH can cross the BBB. The passage of VIP/PACAP/secretin family members opens up new horizon for understanding of CNS effects of peripherally administrated peptides. There is much hope that those peptides may prove to be useful in the treatment of serious neurological diseases such as Alzheimer's disease, amyotropic lateral sclerosis, Parkinson's disease, AIDS related neuropathy, diabetic neuropathy, autism, stroke and nerve injury. Their benefits in various pathophysiologic conditions undoubtly motivate the development of a novel drug design for future therapeutics.
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PMID:Passage of VIP/PACAP/secretin family across the blood-brain barrier: therapeutic effects. 1513 84

The causes of autism and neurodevelopmental disorders are unknown. Genetic and environmental risk factors seem to be involved. Because of an observed increase in autism in the last decades, which parallels cumulative mercury exposure, it was proposed that autism may be in part caused by mercury. We review the evidence for this proposal. Several epidemiological studies failed to find a correlation between mercury exposure through thimerosal, a preservative used in vaccines, and the risk of autism. Recently, it was found that autistic children had a higher mercury exposure during pregnancy due to maternal dental amalgam and thimerosal-containing immunoglobulin shots. It was hypothesized that children with autism have a decreased detoxification capacity due to genetic polymorphism. In vitro, mercury and thimerosal in levels found several days after vaccination inhibit methionine synthetase (MS) by 50%. Normal function of MS is crucial in biochemical steps necessary for brain development, attention and production of glutathione, an important antioxidative and detoxifying agent. Repetitive doses of thimerosal leads to neurobehavioral deteriorations in autoimmune susceptible mice, increased oxidative stress and decreased intracellular levels of glutathione in vitro. Subsequently, autistic children have significantly decreased level of reduced glutathione. Promising treatments of autism involve detoxification of mercury, and supplementation of deficient metabolites.
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PMID:Mercury and autism: accelerating evidence? 1626 12

Autism is a severe developmental disorder with poorly understood etiology. Oxidative stress in autism has been studied at the membrane level and also by measuring products of lipid peroxidation, detoxifying agents (such as glutathione), and antioxidants involved in the defense system against reactive oxygen species (ROS). Lipid peroxidation markers are elevated in autism, indicating that oxidative stress is increased in this disease. Levels of major antioxidant serum proteins, namely transferrin (iron-binding protein) and ceruloplasmin (copper-binding protein), are decreased in children with autism. There is a positive correlation between reduced levels of these proteins and loss of previously acquired language skills in children with autism. The alterations in ceruloplasmin and transferrin levels may lead to abnormal iron and copper metabolism in autism. The membrane phospholipids, the prime target of ROS, are also altered in autism. The levels of phosphatidylethanolamine (PE) are decreased, and phosphatidylserine (PS) levels are increased in the erythrocyte membrane of children with autism as compared to their unaffected siblings. Several studies have suggested alterations in the activities of antioxidant enzymes such as superoxide dismutase, glutathione peroxidase, and catalase in autism. Additionally, altered glutathione levels and homocysteine/methionine metabolism, increased inflammation, excitotoxicity, as well as mitochondrial and immune dysfunction have been suggested in autism. Furthermore, environmental and genetic factors may increase vulnerability to oxidative stress in autism. Taken together, these studies suggest increased oxidative stress in autism that may contribute to the development of this disease. A mechanism linking oxidative stress with membrane lipid abnormalities, inflammation, aberrant immune response, impaired energy metabolism and excitotoxicity, leading to clinical symptoms and pathogenesis of autism is proposed.
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PMID:Oxidative stress in autism. 1676 63

Autism is a behaviorally defined neurodevelopmental disorder usually diagnosed in early childhood that is characterized by impairment in reciprocal communication and speech, repetitive behaviors, and social withdrawal. Although both genetic and environmental factors are thought to be involved, none have been reproducibly identified. The metabolic phenotype of an individual reflects the influence of endogenous and exogenous factors on genotype. As such, it provides a window through which the interactive impact of genes and environment may be viewed and relevant susceptibility factors identified. Although abnormal methionine metabolism has been associated with other neurologic disorders, these pathways and related polymorphisms have not been evaluated in autistic children. Plasma levels of metabolites in methionine transmethylation and transsulfuration pathways were measured in 80 autistic and 73 control children. In addition, common polymorphic variants known to modulate these metabolic pathways were evaluated in 360 autistic children and 205 controls. The metabolic results indicated that plasma methionine and the ratio of S-adenosylmethionine (SAM) to S-adenosylhomocysteine (SAH), an indicator of methylation capacity, were significantly decreased in the autistic children relative to age-matched controls. In addition, plasma levels of cysteine, glutathione, and the ratio of reduced to oxidized glutathione, an indication of antioxidant capacity and redox homeostasis, were significantly decreased. Differences in allele frequency and/or significant gene-gene interactions were found for relevant genes encoding the reduced folate carrier (RFC 80G > A), transcobalamin II (TCN2 776G > C), catechol-O-methyltransferase (COMT 472G > A), methylenetetrahydrofolate reductase (MTHFR 677C > T and 1298A > C), and glutathione-S-transferase (GST M1). We propose that an increased vulnerability to oxidative stress (endogenous or environmental) may contribute to the development and clinical manifestations of autism.
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PMID:Metabolic endophenotype and related genotypes are associated with oxidative stress in children with autism. 1691 39

There is strong evidence for a genetic predisposition to autism and an intense interest in discovering heritable risk factors that disrupt gene function. Based on neurobiological findings and location within a chromosome 7q31 autism candidate gene region, we analyzed the gene encoding the pleiotropic MET receptor tyrosine kinase in a family based study of autism including 1,231 cases. MET signaling participates in neocortical and cerebellar growth and maturation, immune function, and gastrointestinal repair, consistent with reported medical complications in some children with autism. Here, we show genetic association (P = 0.0005) of a common C allele in the promoter region of the MET gene in 204 autism families. The allelic association at this MET variant was confirmed in a replication sample of 539 autism families (P = 0.001) and in the combined sample (P = 0.000005). Multiplex families, in which more than one child has autism, exhibited the strongest allelic association (P = 0.000007). In case-control analyses, the autism diagnosis relative risk was 2.27 (95% confidence interval: 1.41-3.65; P = 0.0006) for the CC genotype and 1.67 (95% confidence interval: 1.11-2.49; P = 0.012) for the CG genotype compared with the GG genotype. Functional assays showed that the C allele results in a 2-fold decrease in MET promoter activity and altered binding of specific transcription factor complexes. These data implicate reduced MET gene expression in autism susceptibility, providing evidence of a previously undescribed pathophysiological basis for this behaviorally and medically complex disorder.
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PMID:A genetic variant that disrupts MET transcription is associated with autism. 1707 42

Folate has long been implicated in both the metabolism of neurotransmitter molecules, and as an agonist with a direct effect upon neuronal tissue. Folates mediate transfer of one-carbon units into major biosynthetic pathways. From a developmental perspective, the most important reactions are de novo methionine and thymine synthesis, critical for DNA expression and elaboration, respectively. Dihydrofolate reductase (DHFR) is the sole enzyme responsible for maintaining the reduced state of the vitamin needed for these two pathways. Here, we report that the 19bp-deletion polymorphism of DHFR acts independently (OR 2.69, 95% CI; 1.00-7.28, p<0.05) and in concert with related folate polymorphisms as a significant risk factor for autism. Possible consequences of this are discussed in the context of the interaction between folate and the glutamatergic nervous system, an area of promising candidate genes for contributing to autism.
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PMID:Preliminary evidence for involvement of the folate gene polymorphism 19bp deletion-DHFR in occurrence of autism. 1759 97

An integrated metabolic profile reflects the combined influence of genetic, epigenetic, and environmental factors that affect the candidate pathway of interest. Recent evidence suggests that some autistic children may have reduced detoxification capacity and may be under chronic oxidative stress. Based on reports of abnormal methionine and glutathione metabolism in autistic children, it was of interest to examine the same metabolic profile in the parents. The results indicated that parents share similar metabolic deficits in methylation capacity and glutathione-dependent antioxidant/detoxification capacity observed in many autistic children. Studies are underway to determine whether the abnormal profile in parents reflects linked genetic polymorphisms in these pathways or whether it simply reflects the chronic stress of coping with an autistic child.
J Autism Dev Disord 2008 Nov
PMID:Abnormal transmethylation/transsulfuration metabolism and DNA hypomethylation among parents of children with autism. 1851 36

The inverse association between maternal folate status and incidence of infants born with neural tube defects (NTD's) was recognized over twenty years ago and led the US health agencies in the early 1990s to recommend that women of childbearing age consume 400 microg of folic acid each day. The FDA followed by mandating that certain foods be fortified with folic acid and this has resulted in a significant enhancement of maternal folate status to levels that are often difficult to otherwise achieve naturally. At least one study indicates that this has decreased the incidence of NTD's. However, this same time period directly coincides with what many feel is the apparent beginning and continuous increase in the prevalence of Autism and related Autism Spectrum Disorders (ASD's) in the US. Are these similar time frames of changes in maternal folate status and possible Autism prevalence a random event or has improved maternal (and fetal) folate status during pregnancy played a role? It is not only plausible but highly likely. A particular polymorphic form to a key enzyme required to activate folate for methylation in neurodevelopment, 5-methylenetetrahydrofolate reductase (MTHFR), demonstrates reduced activity under low or normal folate levels but normal activity under conditions of higher folate nutritional status. A consequence of the presence of the polymorphic form of this enzyme during normal or reduced folate status are higher plasma homocysteine levels than noncarriers and the combination of these factors have been shown in several studies to result in an increase rate of miscarriage via thrombotic events. However, the incidence of hyperhomocysteinemia in the presence of the polymorphism is reduced under the common condition of enhanced folate status and thereby masks the latent adverse effects of the presence of this enzyme form during pregnancy. Of great importance is that this polymorphism, although common in the normal population, is found in significantly higher frequency in Autisic individuals. It is hypothesized here that the enhancement of maternal folate status before and during pregnancy in the last 15 years has altered natural selection by increasing survival rates during pregnancy of infants possessing the MTHFR C677T polymorphism, via reduction in hyperhomocysteinemia associated with this genotype and thereby miscarriage rates. This also points directly to an increased rate of births of infants with higher postnatal requirements for folic acid needed for normal methylation during this critical neurodevelopmental period. If these numbers have increased then so have the absolute number of infants that after birth fail to maintain the higher folate status experienced in utero thus leading to an increased number of cases of developmental disorders such as Autism. Detection of the C677T polymorphism as well as other methionine cycle enzymes related to folate metabolism and methylation at birth as part of newborn screening programs could determine which newborns need be monitored and maintained on diets or supplements that ensure adequate folate status during this critical postnatal neurodevelopment period.
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PMID:Has enhanced folate status during pregnancy altered natural selection and possibly Autism prevalence? A closer look at a possible link. 1851 30


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