Project description:Down syndrome (DS) is the most common genetic form of intellectual disability with additional clinical features, caused by the presence of an additional copy of human chromosome 21 (Hsa21). A few number of patients with DS features, carry partial duplication of Hsa21 and their study provided novel insights into genotype–phenotype correlations. Despite the progress of genome analysis, the rareness of patients with partial duplication, and the human genetic heterogeneity, makes difficult to achieve a more detailed phenotypic map at present. As a complementary approach, we screened the in vivo DS mouse library with highly standardized behavioural tests, magnetic resonance imaging (MRI) and digged into hippocampal gene expression to go further in dissecting the genotype–phenotype correlations and in deciphering misregulated genes, functional pathways and biological cascades in DS models. Altogether this approach bring novel insights into the field. First, we unravelled the complexity of the genetic interactions between different regions of the chromosome 21 and how they play an important role in modulating the outcome of the behavioural and molecular phenotypes. Then, in depth analysis of misregulated expressed genes involved in synaptic dysfunction highlitghed six biological cascades centered around DYRK1A, GSK3beta, NPY, RHOA, NPAS4 and the SNARE complex. Finally, we provide a novel vision of the existing altered gene-gene crosstalk and molecular mechanisms that could be at play for both the DS clinical features and the rescue mechanisms by targeting specific hubs or well connected nodes that may be central to advance in our understanding of DS and therapies development.

Project description:Down syndrome (DS) is the most common genetic form of intellectual disability with additional clinical features, caused by the presence of an additional copy of human chromosome 21 (Hsa21). A few number of patients with DS features, carry partial duplication of Hsa21 and their study provided novel insights into genotype–phenotype correlations. Despite the progress of genome analysis, the rareness of patients with partial duplication, and the human genetic heterogeneity, makes difficult to achieve a more detailed phenotypic map at present. As a complementary approach, we screened the in vivo DS mouse library with highly standardized behavioural tests, magnetic resonance imaging (MRI) and digged into hippocampal gene expression to go further in dissecting the genotype–phenotype correlations and in deciphering misregulated genes, functional pathways and biological cascades in DS models. Altogether this approach bring novel insights into the field. First, we unravelled the complexity of the genetic interactions between different regions of the chromosome 21 and how they play an important role in modulating the outcome of the behavioural and molecular phenotypes. Then, in depth analysis of misregulated expressed genes involved in synaptic dysfunction highlitghed six biological cascades centered around DYRK1A, GSK3beta, NPY, RHOA, NPAS4 and the SNARE complex. Finally, we provide a novel vision of the existing altered gene-gene crosstalk and molecular mechanisms that could be at play for both the DS clinical features and the rescue mechanisms by targeting specific hubs or well connected nodes that may be central to advance in our understanding of DS and therapies development.

Project description:Down syndrome (DS) is the most common genetic form of intellectual disability with additional clinical features, caused by the presence of an additional copy of human chromosome 21 (Hsa21). A few number of patients with DS features, carry partial duplication of Hsa21 and their study provided novel insights into genotype–phenotype correlations. Despite the progress of genome analysis, the rareness of patients with partial duplication, and the human genetic heterogeneity, makes difficult to achieve a more detailed phenotypic map at present. As a complementary approach, we screened the in vivo DS mouse library with highly standardized behavioural tests, magnetic resonance imaging (MRI) and digged into hippocampal gene expression to go further in dissecting the genotype–phenotype correlations and in deciphering misregulated genes, functional pathways and biological cascades in DS models. Altogether this approach bring novel insights into the field. First, we unravelled the complexity of the genetic interactions between different regions of the chromosome 21 and how they play an important role in modulating the outcome of the behavioural and molecular phenotypes. Then, in depth analysis of misregulated expressed genes involved in synaptic dysfunction highlitghed six biological cascades centered around DYRK1A, GSK3beta, NPY, RHOA, NPAS4 and the SNARE complex. Finally, we provide a novel vision of the existing altered gene-gene crosstalk and molecular mechanisms that could be at play for both the DS clinical features and the rescue mechanisms by targeting specific hubs or well connected nodes that may be central to advance in our understanding of DS and therapies development.

Project description:Down syndrome (DS) is the most common genetic form of intellectual disability with additional clinical features, caused by the presence of an additional copy of human chromosome 21 (Hsa21). A few number of patients with DS features, carry partial duplication of Hsa21 and their study provided novel insights into genotype–phenotype correlations. Despite the progress of genome analysis, the rareness of patients with partial duplication, and the human genetic heterogeneity, makes difficult to achieve a more detailed phenotypic map at present. As a complementary approach, we screened the in vivo DS mouse library with highly standardized behavioural tests, magnetic resonance imaging (MRI) and digged into hippocampal gene expression to go further in dissecting the genotype–phenotype correlations and in deciphering misregulated genes, functional pathways and biological cascades in DS models. Altogether this approach bring novel insights into the field. First, we unravelled the complexity of the genetic interactions between different regions of the chromosome 21 and how they play an important role in modulating the outcome of the behavioural and molecular phenotypes. Then, in depth analysis of misregulated expressed genes involved in synaptic dysfunction highlitghed six biological cascades centered around DYRK1A, GSK3beta, NPY, RHOA, NPAS4 and the SNARE complex. Finally, we provide a novel vision of the existing altered gene-gene crosstalk and molecular mechanisms that could be at play for both the DS clinical features and the rescue mechanisms by targeting specific hubs or well connected nodes that may be central to advance in our understanding of DS and therapies development.

Project description:Down syndrome (DS) is the most common genetic form of intellectual disability with additional clinical features, caused by the presence of an additional copy of human chromosome 21 (Hsa21). A few number of patients with DS features, carry partial duplication of Hsa21 and their study provided novel insights into genotype–phenotype correlations. Despite the progress of genome analysis, the rareness of patients with partial duplication, and the human genetic heterogeneity, makes difficult to achieve a more detailed phenotypic map at present. As a complementary approach, we screened the in vivo DS mouse library with highly standardized behavioural tests, magnetic resonance imaging (MRI) and digged into hippocampal gene expression to go further in dissecting the genotype–phenotype correlations and in deciphering misregulated genes, functional pathways and biological cascades in DS models. Altogether this approach bring novel insights into the field. First, we unravelled the complexity of the genetic interactions between different regions of the chromosome 21 and how they play an important role in modulating the outcome of the behavioural and molecular phenotypes. Then, in depth analysis of misregulated expressed genes involved in synaptic dysfunction highlitghed six biological cascades centered around DYRK1A, GSK3beta, NPY, RHOA, NPAS4 and the SNARE complex. Finally, we provide a novel vision of the existing altered gene-gene crosstalk and molecular mechanisms that could be at play for both the DS clinical features and the rescue mechanisms by targeting specific hubs or well connected nodes that may be central to advance in our understanding of DS and therapies development.

Project description:Down syndrome (DS) is the most common genetic form of intellectual disability with additional clinical features, caused by the presence of an additional copy of human chromosome 21 (Hsa21). A few number of patients with DS features, carry partial duplication of Hsa21 and their study provided novel insights into genotype–phenotype correlations. Despite the progress of genome analysis, the rareness of patients with partial duplication, and the human genetic heterogeneity, makes difficult to achieve a more detailed phenotypic map at present. As a complementary approach, we screened the in vivo DS mouse library with highly standardized behavioural tests, magnetic resonance imaging (MRI) and digged into hippocampal gene expression to go further in dissecting the genotype–phenotype correlations and in deciphering misregulated genes, functional pathways and biological cascades in DS models. Altogether this approach bring novel insights into the field. First, we unravelled the complexity of the genetic interactions between different regions of the chromosome 21 and how they play an important role in modulating the outcome of the behavioural and molecular phenotypes. Then, in depth analysis of misregulated expressed genes involved in synaptic dysfunction highlitghed six biological cascades centered around DYRK1A, GSK3beta, NPY, RHOA, NPAS4 and the SNARE complex. Finally, we provide a novel vision of the existing altered gene-gene crosstalk and molecular mechanisms that could be at play for both the DS clinical features and the rescue mechanisms by targeting specific hubs or well connected nodes that may be central to advance in our understanding of DS and therapies development.

Project description:Down syndrome (DS) is the most common genetic form of intellectual disability with additional clinical features, caused by the presence of an additional copy of human chromosome 21 (Hsa21). A few number of patients with DS features, carry partial duplication of Hsa21 and their study provided novel insights into genotype–phenotype correlations. Despite the progress of genome analysis, the rareness of patients with partial duplication, and the human genetic heterogeneity, makes difficult to achieve a more detailed phenotypic map at present. As a complementary approach, we screened the in vivo DS mouse library with highly standardized behavioural tests, magnetic resonance imaging (MRI) and digged into hippocampal gene expression to go further in dissecting the genotype–phenotype correlations and in deciphering misregulated genes, functional pathways and biological cascades in DS models. Altogether this approach bring novel insights into the field. First, we unravelled the complexity of the genetic interactions between different regions of the chromosome 21 and how they play an important role in modulating the outcome of the behavioural and molecular phenotypes. Then, in depth analysis of misregulated expressed genes involved in synaptic dysfunction highlitghed six biological cascades centered around DYRK1A, GSK3beta, NPY, RHOA, NPAS4 and the SNARE complex. Finally, we provide a novel vision of the existing altered gene-gene crosstalk and molecular mechanisms that could be at play for both the DS clinical features and the rescue mechanisms by targeting specific hubs or well connected nodes that may be central to advance in our understanding of DS and therapies development.

Project description:Down syndrome (DS) is the most common genetic form of intellectual disability with additional clinical features, caused by the presence of an additional copy of human chromosome 21 (Hsa21). A few number of patients with DS features, carry partial duplication of Hsa21 and their study provided novel insights into genotype–phenotype correlations. Despite the progress of genome analysis, the rareness of patients with partial duplication, and the human genetic heterogeneity, makes difficult to achieve a more detailed phenotypic map at present. As a complementary approach, we screened the in vivo DS mouse library with highly standardized behavioural tests, magnetic resonance imaging (MRI) and digged into hippocampal gene expression to go further in dissecting the genotype–phenotype correlations and in deciphering misregulated genes, functional pathways and biological cascades in DS models. Altogether this approach bring novel insights into the field. First, we unravelled the complexity of the genetic interactions between different regions of the chromosome 21 and how they play an important role in modulating the outcome of the behavioural and molecular phenotypes. Then, in depth analysis of misregulated expressed genes involved in synaptic dysfunction highlitghed six biological cascades centered around DYRK1A, GSK3beta, NPY, RHOA, NPAS4 and the SNARE complex. Finally, we provide a novel vision of the existing altered gene-gene crosstalk and molecular mechanisms that could be at play for both the DS clinical features and the rescue mechanisms by targeting specific hubs or well connected nodes that may be central to advance in our understanding of DS and therapies development.

Project description:Down syndrome (DS) is the most common genetic form of intellectual disability with additional clinical features, caused by the presence of an additional copy of human chromosome 21 (Hsa21). A few number of patients with DS features, carry partial duplication of Hsa21 and their study provided novel insights into genotype–phenotype correlations. Despite the progress of genome analysis, the rareness of patients with partial duplication, and the human genetic heterogeneity, makes difficult to achieve a more detailed phenotypic map at present. As a complementary approach, we screened the in vivo DS mouse library with highly standardized behavioural tests, magnetic resonance imaging (MRI) and digged into hippocampal gene expression to go further in dissecting the genotype–phenotype correlations and in deciphering misregulated genes, functional pathways and biological cascades in DS models. Altogether this approach bring novel insights into the field. First, we unravelled the complexity of the genetic interactions between different regions of the chromosome 21 and how they play an important role in modulating the outcome of the behavioural and molecular phenotypes. Then, in depth analysis of misregulated expressed genes involved in synaptic dysfunction highlitghed six biological cascades centered around DYRK1A, GSK3beta, NPY, RHOA, NPAS4 and the SNARE complex. Finally, we provide a novel vision of the existing altered gene-gene crosstalk and molecular mechanisms that could be at play for both the DS clinical features and the rescue mechanisms by targeting specific hubs or well connected nodes that may be central to advance in our understanding of DS and therapies development.

Project description:Down syndrome (DS) is caused by triplication of Human chromosome 21 (Hsa21) and associated with an array of deleterious phenotypes, including mental retardation, heart defects and immunodeficiency. Spatio-temporal patterns of genome-wide expression are critical to the understanding of DS. We used a Human Exon microarray to characterize gene expression in peripheral blood cells derived from DS and control individuals from two age groups: neonate (N) and child (C). A total of 174 transcript clusters (gene-level) with eight located on Hsa21 in N group and 383 transcript clusters including 57 on Hsa21 in C group were significantly dysregulated in DS individuals. Except for 22 commonly dysregulated genes in the two groups, the remaining dysregulated genes were different between N and C groups, reflecting temporally dynamic variation in gene expression in DS. Dramatically fewer dysregulated Hsa21 genes in N group than those in C group suggested that triplication of Hsa21 per se induces a moderate deregulation at early developmental stages. Further functional analysis revealed that the dysregulated genes in DS were significantly enriched in two KEGG pathways in N group and six pathways in C group. These pathways included leukocyte trans-endothelial migration, B cell receptor signaling pathway and primary immunodeficiency, etc., which causally implicated dysfunctional immunity in DS. Our results provided a comprehensive picture of expression patterns of DS at the two developmental stages and point towards candidate genes and molecular pathways potentially associated with the immune dysfunction in DS. All 37 samples, including 15 DS patients and 22 control individuals were analysized and divided into two age-matched groups: N group (5 DS versus 7 control individuals, age: 3 days to 38 days) and C group (10 DS versus 15 control individuals, age: 1 year to 13 years). N group includes DS (D11-D15) and Control (C16-C22), and C group includes DS (D1-D10) and Control (C1-C15).