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Neuronal activity induces the post-translational modification of synaptic molecules, promotes localized protein synthesis within dendrites and activates gene transcription, thereby regulating synaptic function and allowing neuronal circuits to respond dynamically to experience. Evidence indicates that many of the genes that are mutated in autism spectrum disorder are crucial components of the activity-dependent signalling networks that regulate synapse development and plasticity. Dysregulation of activity-dependent signalling pathways in neurons may, therefore, have a key role in the aetiology of autism spectrum disorder.

Rett syndrome is caused by mutation of the MECP2 gene that codes for a protein that binds methylated DNA; this study reveals that MeCP2 affects the expression of long genes, which often serve neuronal functions. Role of MECP2 in Rett syndrome Autism-related Rett syndrome is caused by disruption of the MECP2 gene, which codes for a methyl-DNA binding protein, but how MECP2 may control transcription of other genes has remained unclear. Now Michael Greenberg and colleagues show that disruption of the Mecp2 gene in a mouse model and in human Rett syndrome leads to preferential upregulation of longer genes, and that these often serve neuronal functions. Further data indicate that decreasing the expression of long genes, via hypomethylation of the dinucleotide CA, attenuates Rett-related dysfunctions in cultured neurons lacking MECP2 . Disruption of the MECP2 gene leads to Rett syndrome (RTT), a severe neurological disorder with features of autism 1 . MECP2 encodes a methyl-DNA-binding protein 2 that has been proposed to function as a transcriptional repressor, but despite numerous mouse studies examining neuronal gene expression in Mecp2 mutants, no clear model has emerged for how MeCP2 protein regulates transcription 3 , 4 , 5 , 6 , 7 , 8 , 9 . Here we identify a genome-wide length-dependent increase in gene expression in MeCP2 mutant mouse models and human RTT brains. We present evidence that MeCP2 represses gene expression by binding to methylated CA sites within long genes, and that in neurons lacking MeCP2, decreasing the expression of long genes attenuates RTT-associated cellular deficits. In addition, we find that long genes as a population are enriched for neuronal functions and selectively expressed in the brain. These findings suggest that mutations in MeCP2 may cause neurological dysfunction by specifically disrupting long gene expression in the brain.

In this study, the authors show that MeCP2 interacts with the NCoR/SMRT co-repressor complex and that a discrete cluster of Rett syndrome–causing mutations in the C-terminal domain of MeCP2 disrupts this interaction, impairing transcriptional repression. Knock-in mice expressing one of these MeCP2 missense mutations exhibit severe motor phenotypes. Rett syndrome (RTT) is a severe neurological disorder that is caused by mutations in the MECP2 gene. Many missense mutations causing RTT are clustered in the DNA-binding domain of MeCP2, suggesting that association with chromatin is critical for its function. We identified a second mutational cluster in a previously uncharacterized region of MeCP2. We found that RTT mutations in this region abolished the interaction between MeCP2 and the NCoR/SMRT co-repressor complexes. Mice bearing a common missense RTT mutation in this domain exhibited severe RTT-like phenotypes. Our data are compatible with the hypothesis that brain dysfunction in RTT is caused by a loss of the MeCP2 'bridge' between the NCoR/SMRT co-repressors and chromatin.

Rett syndrome is caused by mutations in MeCP2, and this study identifies a site on MeCP2, T308, whose phosphorylation is regulated by neuronal activity: phosphorylation of T308 blocks the interaction of MeCP2 with the NCoR co-repressor complex, suppressing MeCP2's ability to repress transcription, and mice carrying mutations of MeCP2 T308 show Rett-syndrome-related symptoms. Causation of Rett syndrome The childhood neurodevelopmental disorder Rett syndrome is caused by mutations in MeCP2, a protein that regulates transcription in neurons. Michael Greenberg and colleagues identify a site on MeCP2, threonine 308 (T308), whose phosphorylation is regulated by neuronal activity. T308 phosphorylation blocks the interaction of MeCP2 with the NCoR co-repressor complex, suppressing MeCP2's ability to repress transcription. Mice carrying mutations of MeCP2 T308 show Rett syndrome-related symptoms, suggesting that this activity-dependent phosphorylation and regulation of MeCP2–NCoR interaction may have a causal role in Rett syndrome. Rett syndrome (RTT) is an X-linked human neurodevelopmental disorder with features of autism and severe neurological dysfunction in females. RTT is caused by mutations in methyl-CpG-binding protein 2 (MeCP2), a nuclear protein that, in neurons, regulates transcription, is expressed at high levels similar to that of histones, and binds to methylated cytosines broadly across the genome 1 , 2 , 3 , 4 , 5 . By phosphotryptic mapping, we identify three sites (S86, S274 and T308) of activity-dependent MeCP2 phosphorylation. Phosphorylation of these sites is differentially induced by neuronal activity, brain-derived neurotrophic factor, or agents that elevate the intracellular level of 3′,5′-cyclic AMP (cAMP), indicating that MeCP2 may function as an epigenetic regulator of gene expression that integrates diverse signals from the environment. Here we show that the phosphorylation of T308 blocks the interaction of the repressor domain of MeCP2 with the nuclear receptor co-repressor (NCoR) complex and suppresses the ability of MeCP2 to repress transcription. In knock-in mice bearing the common human RTT missense mutation R306C, neuronal activity fails to induce MeCP2 T308 phosphorylation, suggesting that the loss of T308 phosphorylation might contribute to RTT. Consistent with this possibility, the mutation of MeCP2 T308A in mice leads to a decrease in the induction of a subset of activity-regulated genes and to RTT-like symptoms. These findings indicate that the activity-dependent phosphorylation of MeCP2 at T308 regulates the interaction of MeCP2 with the NCoR complex, and that RTT in humans may be due, in part, to the loss of activity-dependent MeCP2 T308 phosphorylation and a disruption of the phosphorylation-regulated interaction of MeCP2 with the NCoR complex.

Infection of neonatal mice with some reovirus strains produces a disease similar to infantile biliary atresia, but previous attempts to correlate reovirus infection with this disease have yielded conflicting results. We used isogenic reovirus strains T3SA- and T3SA+, which differ solely in the capacity to bind sialic acid as a coreceptor, to define the role of sialic acid in reovirus encephalitis and biliary tract infection in mice. Growth in the intestine was equivalent for both strains following peroral inoculation. However, T3SA+ spread more rapidly from the intestine to distant sites and replicated to higher titers in spleen, liver, and brain. Strikingly, mice infected with T3SA+ but not T3SA- developed steatorrhea and bilirubinemia. Liver tissue from mice infected with T3SA+ demonstrated intense inflammation focused at intrahepatic bile ducts, pathology analogous to that found in biliary atresia in humans, and high levels of T3SA+ antigen in bile duct epithelial cells. T3SA+ bound 100-fold more efficiently than T3SA- to human cholangiocarcinoma cells. These observations suggest that the carbohydrate-binding specificity of a virus can dramatically alter disease in the host and highlight the need for epidemiologic studies focusing on infection by sialic acid-binding reovirus strains as a possible contributor to the pathogenesis of neonatal biliary atresia.

Glucose-6-phosphatase catalyzes the terminal step in the gluconeogenic and glycogenolytic pathways. Transcription of the gene encoding the glucose-6-phosphatase catalytic subunit (G6Pase) is stimulated by cAMP and glucocoriticoids whereas insulin strongly inhibits both this induction and basal G6Pase gene transcription. Previously, we have demonstrated that the maximum repression of basal G6Pase gene transcription by insulin requires two distinct promoter regions, designated A (from -271 to -199) and B (from -198 to -159). Region B contains an insulin response sequence because it can confer an inhibitory effect of insulin on the expression of a heterologous fusion gene. By contrast, region A fails to mediate an insulin response in a heterologous context, and the mutation of region B within an otherwise intact promoter almost completely abolishes the effect of insulin on basal G6Pase gene transcription. Therefore, region A is acting as an accessory element to enhance the effect of insulin, mediated through region B, on G6Pase gene transcription. Such an arrangement is a common feature of cAMP and glucocorticoid-regulated genes but has not been previously described for insulin. A combination of fusion gene and protein-binding analyses revealed that the accessory factor binding region A is hepatocyte nuclear factor-1. Thus, despite the usually antagonistic effects of cAMP/glucocorticoids and insulin, all three agents are able to use the same factor to enhance their action on gene transcription. The potential role of G6Pase overexpression in the pathophysiology of MODY3 and 5, rare forms of diabetes caused by hepatocyte nuclear factor-1 mutations, is discussed.

Structure and promoter activity of an islet-specific glucose-6-phosphatase catalytic subunit-related gene. D H Ebert , L J Bischof , R S Streeper , S C Chapman , C A Svitek , J K Goldman , C E Mathews , E H Leiter , J C Hutton and R M O'Brien Department of Molecular Physiology and Biophysics, Vanderbilt University Medical School, Nashville, Tennessee 37232-0615, USA. Abstract In liver and kidney, the terminal step in the gluconeogenic pathway is catalyzed by glucose-6-phosphatase (G-6-Pase). This enzyme is actually a multicomponent system, the catalytic subunit of which was recently cloned. Numerous reports have also described the presence of G-6-Pase activity in islets, although the role of G-6-Pase in this tissue is unclear. Arden and associates have described the cloning of a novel cDNA that encodes an islet-specific G-6-Pase catalytic subunit-related protein (IGRP) (Arden SD, Zahn T, Steegers S, Webb S, Bergman B, O'Brien RM, Hutton JC: Molecular cloning of a pancreatic islet-specific glucose-6-phosphatase catalytic subunit related protein (IGRP). Diabetes 48:531-542, 1999). We screened a mouse BAC library with this cDNA to isolate the IGRP gene, which spans approximately 8 kbp of genomic DNA. The exon/intron structure of the IGRP gene has been mapped and, as with the gene encoding the liver/kidney G-6-Pase catalytic subunit, it is composed of five exons. The sizes of these exons are 254 (I), 110 (II), 112 (III), 116 (IV), and 1284 (V) bp, similar to those of the G-6-Pase catalytic subunit gene. Two interspecific backcross DNA mapping panels were used to unambiguously localize the IGRP gene (map symbol G6pc-rs) to the proximal portion of mouse chromosome 2. The IGRP gene transcription start site was mapped by primer extension analysis, and the activity of the IGRP gene promoter was analyzed in both the islet-derived HIT cell line and the liver-derived HepG2 cell line. The IGRP and G-6-Pase catalytic subunit gene promoters show a reciprocal pattern of activity, with the IGRP promoter being approximately 150-fold more active than the G-6-Pase promoter in HIT cells.

Infection of neonatal mice with some reovirus strains produces a disease similar to infantile biliary atresia, but previous attempts to correlate reovirus infection with this disease have yielded conflicting results. We used isogenic reovirus strains T3SA- and T3SA+, which differ solely in the capacity to bind sialic acid as a coreceptor, to define the role of sialic acid in reovirus encephalitis and biliary tract infection in mice. Growth in the intestine was equivalent for both strains following peroral inoculation. However, T3SA+ spread more rapidly from the intestine to distant sites and replicated to higher titers in spleen, liver, and brain. Strikingly, mice infected with T3SA+ but not T3SA- developed steatorrhea and bilirubinemia. Liver tissue from mice infected with T3SA+ demonstrated intense inflammation focused at intrahepatic bile ducts, pathology analogous to that found in biliary atresia in humans, and high levels of T3SA+ antigen in bile duct epithelial cells. T3SA+ bound 100-fold more efficiently than T3SA- to human cholangiocarcinoma cells. These observations suggest that the carbohydrate-binding specificity of a virus can dramatically alter disease in the host and highlight the need for epidemiologic studies focusing on infection by sialic acid-binding reovirus strains as a possible contributor to the pathogenesis of neonatal biliary atresia.

The perennial sunflower Helianthus tuberosus, known as Jerusalem Artichoke or Sunchoke, was cultivated in eastern North America before European contact. As such, it represents one of the few taxa that can support an independent origin of domestication in this region. Its tubers were adopted as a source of food and forage when the species was transferred to the Old World in the early 1600s, and are still used today. Despite the cultural and economic importance of this tuber crop species, its origin is debated. Competing hypotheses implicate the occurrence of polyploidization with or without hybridization, and list the annual sunflower H. annuus and five distantly related perennial sunflower species as potential parents. Here, we test these scenarios by skimming the genomes of diverse populations of Jerusalem Artichoke and its putative progenitors. We identify relationships among Helianthus taxa using complete plastomes (151 551 bp), partial mitochondrial genomes (196 853 bp) and 35S (8196 bp) and 5S (514 bp) ribosomal DNA. Our results refute the possibility that Jerusalem Artichoke is of H. annuus ancestry. We provide the first genetic evidence that this species originated recursively from perennial sunflowers of central-eastern North America via hybridization between tetraploid Hairy Sunflower and diploid Sawtooth Sunflower.