Human chromosome 21q22.2-qter carries a gene(s) responsible for downregulation of mlc2a and PEBP in Down syndrome model mice

Congenital heart disease (CHD) is a major clinical manifestation of Down syndrome (DS). We recently showed that chimeric mice containing a human chromosome 21 (Chr 21) exhibited phenotypic traits of DS, including CHD. Our previous study showed that myosin light chain-2a (mlc2a) expression was reduced in the hearts of chimeric mice and DS patients. We found that phosphatidylethanolamine binding protein (PEBP) was also downregulated in Chr 21 chimeras in this study. As mlc2a is involved in heart morphogenesis, and PEBP controls the proliferation and differentiation of different cell types, these genes are candidates for involvement in DS-CHD. The DS-CHD candidate region has been suggested to span between PFKL and D21S3, which is the STS marker near the ETS2 loci. To identify gene(s) or a gene cluster on Chr 21 responsible for the downregulation of mlc2a and PEBP, we fragmented Chr 21 at the EST2 loci, by telomere-directed chromosome truncation in homologous recombination-proficient chicken DT40 cells. The modified Chr 21 was transferred to mouse ES cells by microcell-mediated chromosome transfer (MMCT), via CHO cells. We used ES cell lines retaining the Chr 21 truncated at the ETS2 locus (Chr 21E) to produce chimeric mice and compared overall protein expression patterns in hearts of the chimeras containing the intact and the fragmented Chr 21 by two-dimensional electrophoresis. While mouse mlc2a and PEBP expression was downregulated in the chimeras containing the intact Chr 21, the expression was not affected in the Chr 21E chimeras. Therefore, we suggest that Chr 21 gene(s) distal from the ETS2 locus reduce mouse mlc2a and PEBP expression in DS model mice and DS. Thus, this chromosome engineering technology is a useful tool for identification or mapping of genes that contribute to the DS phenotypes.     

Ts65Dn -- localization of the translocation breakpoint and trisomic gene content in a mouse model for Down syndrome

Fluorescent in situ hybridization (FISH) -- using mouse chromosome paints, probes for the mouse major centromeric satellite DNA, and probes for genes on chromosomes (Chr) 16 and 17 -- was employed to locate the breakpoint in a translocation used to produce a mouse model for Down syndrome. The Ts65Dn trisomy is derived from the reciprocal translocation T(16;17)65Dn. The Ts65Dn mouse carries a marker chromosome containing the distal segment of Chr 16, a region that shows linkage conservation with human Chr 21, and the proximal end of Chr 17. This chromosome confers trisomy for most of the genes in the Chr 16 segment and Ts65Dn mice show many of the phenotypic features characteristic of Down syndrome. We used FISH on metaphase chromosomes from translocation T65Dn/+ heterozygotes and Ts65Dn mice to show that the Chr 17 breakpoint is distal to the heterochromatin of Chr 17, that the Ts65Dn marker chromosome contains a small portion of Chr 17 euchromatin, that the Chr 16 breakpoint lies between the Ncam2 and Gabpa/App genes, and that the Ts65Dn chromosome contains >80% of the human Chr 21 homologs. The significance of this finding is discussed in terms of the utility of this mouse model.     

Down syndrome mouse models are looking up

A new mouse model of Down syndrome (DS) carries a copy of human chromosome 21 (Hsa21), in addition to a full complement of mouse chromosomes. In terms of the number of trisomic genes represented, this model, known as 'Tc1', is closer to the genetic background of DS than any previous model. The Tc1 model not only recapitulates several of the DS features present in other mouse models but also exhibits heart defects that are similar to those that make trisomy 21 the leading cause of congenital heart disease in humans. Many cells in adult Tc1 mice show mosaicism - that is, the Hsa21 is lost from some cells during development - increasing the complexity of analyses using this model. Tc1 mice provide a powerful tool for investigation of the pathogenesis of trisomy 21, and a platform for analysis of similarities and differences in the evolution of gene regulation.     

Protein levels of genes encoded on chromosome 21 in fetal Down syndrome brain: challenging the gene dosage effect hypothesis (Part III)

Summary.  Down syndrome (DS) is the most frequent genetic disorder with mental retardation and caused by trisomy 21. Although the gene dosage effect hypothesis has been proposed to explain the impact of extra chromosome 21 on the pathology of DS, a series of evidence that challenge this hypothesis has been reported. The availability of the complete sequences of genes on chromosome 21 serves now as starting point to find functional information of the gene products, but information on gene products is limited so far. We therefore evaluated expression levels of six proteins whose genes are encoded on chromosome 21 (synaptojanin-1, chromosome 21 open reading frame 2, oligomycin sensitivity confering protein, peptide 19, cystatin B and adenosine deaminase RNA-specific 2) in fetal cerebral cortex from DS and controls at 18–19 weeks of gestational age using Western blot analysis. Synaptojanin-1 and C21orf2 were increased in DS, but others were comparable between DS and controls, suggesting that the DS phenotype cannot be simply explained by gene dosage effects. We are systematically quantifying all proteins whose genes are encoded on chromosome 21 in order to provide a better understanding of the pathobiochemistry of DS at the protein level. These studies are of significance as they show for the first time protein levels that are carrying out specific function in human fetal brain with DS. Received August 12, 2002 Accepted September 12, 2002 Published online January 30, 2003 Authors' address: Prof. Dr. Gert Lubec, CChem, FRSC (UK) Department of Pediatrics, University of Vienna, Waehringer Guertel 18, A-1090 Vienna, Austria, Fax: +43-1-40400-3194, E-mail: gert.lubec@akh-wien.ac.at Abbreviations: ADAR2, adenosine deaminase RNA-specific 2; C21orf2, chromosome 21 open reading frame 2; DS, Down syndrome; NSE, neuron specific enolase; OSCP, oligomycin sensitivity conferring protein; PEP-19, peptide 19     

The differentially expressed C21orf5 gene in the medial temporal-lobe system could play a role in mental retardation in Down syndrome and transgenic mice

Mental retardation represents the more invalidating pathological aspect of Down syndrome, DS, and has a hard impact in public health. Modifications in DS brain, concerning abnormal size, neuronal differentiation, and cell density, cause changes in the neurophysiology and behavior of DS patients, and could be determined by dosage imbalance of genes localized in the DS critical region, DCR. Among these genes, C21orf5 showed high homology with Caenorhabditis elegans Pad1 involved in cellular differentiation and patterning. To shed light on C21orf5 role in DS, we performed molecular characterization of human and mouse orthologs, their spatio-temporal expression during development and in adult, and overexpression in DS and transgenic mice. C21orf5 was widely expressed early in embryogenesis in the nervous system. Later, its expression became differential and increased in mesencephalon and rhomboencephalon. This developmental expression profile evolves selectively in adult brain with higher signals in hippocampus, cerebellum, perirhinal, and entorhinal cortex, compared to the other cortical regions. Cellular specificity was detected in hippocampus with higher C21orf5 mRNA level in CA3 cells. Our findings appoint C21orf5 as candidate gene for mental retardation: Its overexpression in DS cells may contribute to gene imbalance in DS.Its specific expression in normal and its mirroring pattern in transgenic mice correspond to abnormal regions in DS patients and to neurological phenotype of transgenic mice. Altered cortical lamination in transgenic mice and the Pad1 ortholog function suggest a potential role of C21orf5 in cell differentiation. Its patterned differential expression in the medial temporal-lobe system, including hippocampal formation and perirhinal cortex involved in memory storage, and learning and memory defects in the transgenic mice suggest a specialized role for C21orf5 in cognitive processes. These evidences suggest that C21orf5 is an attractive candidate gene contributing to neurological alterations responsible for mental retardation in DS patients.     

A novel mouse model for Down syndrome that harbor a single copy of human artificial chromosome (HAC) carrying a limited number of genes from human chromosome 21

Down syndrome (DS), also known as Trisomy 21, is the most common chromosome aneuploidy in live-born children and displays a complicated symptom. To date, several kinds of mouse models have been generated to understand the molecular pathology of DS, yet the gene dosage effects and gene(s)-phenotype(s) correlation are not well understood. In this study, we established a novel method to generate a partial trisomy mice using the mouse ES cells that harbor a single copy of human artificial chromosome (HAC), into which a small human DNA segment containing human chromosome 21 genes cloned in a bacterial artificial chromosome (BAC) was recombined. The produced mice were found to maintain the HAC carrying human genes as a mini-chromosome, hence termed as a Trans-Mini-Chromosomal (TMC) mouse, and HAC was transmitted for more than twenty generations independent from endogenous mouse chromosomes. The three human transgenes including cystathionine β-synthase, U2 auxiliary factor and crystalline alpha A were expressed in several mouse tissues with various expression levels relative to mouse endogenous genes. The novel system is applicable to any of human and/or mouse BAC clones. Thus, the TMC mouse carrying a HAC with a limited number of genes would provide a novel tool for studying gene dosage effects involved in the DS molecular pathogenesis and the gene(s)-phenotype(s) correlation.     

Lipoprotein secretion and triglyceride stores in the heart

The genes for apolipoprotein B and microsomal triglyceride transfer protein are expressed in mouse and human heart tissue. Why the heart would express these "lipoprotein assembly" genes has been unclear. Here we demonstrate that the beating mouse heart actually secretes spherical lipoproteins. Moreover, increased cardiac production of lipoproteins (e.g., in mice that express a human apolipoprotein B transgene) was associated with increased triglyceride secretion from the heart and decreased stores of triglycerides within the heart. Increased cardiac production of lipoproteins also reduced the pathological accumulation of triglycerides that occurs in the hearts of mice lacking long-chain acyl coenzyme A dehydrogenase. In contrast, blocking heart lipoprotein secretion (e.g., in heart-specific microsomal triglyceride transfer protein knockout mice) increased cardiac triglyceride stores. Thus, heart lipoprotein secretion helps regulate cardiac triglyceride stores and may protect the heart from the detrimental effects of surplus lipids.     

Mass-spectrometrical analysis of proteins encoded on chromosome 21 in human fetal brain

Summary. Overexpression of chromosome 21 genes is directly or indirectly responsible for the Down syndrome phenotype. In order to analyse chromosome 21 gene products (Chr21Ps), we extracted proteins from fetal human brain cortex and applied an ultracentrifugal and chromatographic prefractionation principle followed by two-dimensional gel electrophoresis (2-DE) and mass-spectrometrical analysis using high-throughput automated MALDI-TOF/TOF. Nine Chr21Ps were identified: pyridoxal kinase; superoxide dismutase [Cu/Zn] 1; carbonyl reductase 1; ES1 protein homolog, mitochondrial [Precursor]; cystathionine-beta-synthetase; T-complex protein 1, theta subunit; cystatin B; 6-phosphofructokinase; glycinamide ribonucleotide synthetase. Mass-spectrometric characterisation of Chr21Ps following separation in 2-DE gels is a useful tool for the analysis of these structures in brain, independent of antibody availability and specificity.     

Elevated Expression of the G-Protein-Activated Inwardly Rectifying Potassium Channel 2 (GIRK2) in Cerebellar Unipolar Brush Cells of a Down Syndrome Mouse Model

SUMMARY 1. Down syndrome (DS) arises from the presence of three copies of chromosome (Chr.) 21. Fine motor learning deficits found in DS from childhood to adulthood result from expression of extra genes on Chr. 21, however, it remains unclear which if any of these genes are the specific causes of the cognitive and motor dysfunction. DS cerebellum displays morphological abnormalities that likely contribute to the DS motor phenotype.2. The G-protein-activated inwardly rectifying potassium channel subunit 2 (GIRK2) is expressed in cerebellum and can shunt dendritic conductance and attenuate postsynaptic potentials. We have used an interbreeding approach to cross a genetic mouse model of DS (Ts65Dn) with Girk2 knockout mice and examined its relative expression level by quantitative real-time RT-PCR, Western blotting and immunohistochemistry.3. We report here for the first time that GIRK2 is expressed in unipolar brush cells, which are excitatory interneurons of the vestibulocerebellum and dorsal cochlear nucleus. Analysis of disomic-Ts65Dn/Girk2^(+/+/−) and heterozygous-Diploid/Girk2^(+/−) mice shows that GIRK2 expression in Ts65Dn lobule X follows gene dosage. The lobule X of Ts65Dn mice contain greater numbers of unipolar brush cells co-expressing GIRK2 and calretinin than the control mouse groups.4. These results demonstrate that gene triplication can impact specific cell types in the cerebellum. We hypothesize that GIRK2 overexpression will adversely affect cerebellar circuitry in Ts65Dn vestibulocerebellum and dorsal cochlear nucleus due to GIRK2 shunting properties and its effects on resting membrane potential.While Dr. Julius Axelrod’s impact on the development of Neuroscience was significant, one of his major contributions was made indirectly through the people close to him that he influenced. Being a Section Chief and colleague to Julie in the Laboratory of Clinical Science at the National Institute of Mental Health was one of the great honors of my life. It was always a joy observing humility, friendliness and concern of all problems big or small. At laboratory seminars it was a pleasure to watch Julie’s ideas and intuitions that often generated a tremendous amount of good science. He taught all of us how to be curious, incisive and imaginative, and above all to “keep it simple.” His delight in science was contagious. DMJ     

Genomic organization and expression profile of the human and mouse <Emphasis Type="Italic">WAVE</Emphasis> gene family

The WAVE gene family, which contains three members, has been shown to play a major role in the actin polymerization and cytoskeleton organization processes. We have identified the WAVE3 gene from Chromosome (Chr) 13q12, as being involved in one of the breakpoints of a t(1:13)(q21:q12) reciprocal translocation, in a patient with ganglioneuroblastoma (Sossey-Alaoui et al. 2002; Oncogene 21: 5967–5974). We have also reported the cloning of the mouse Wave3. During our analysis of the human gene map, we also noted that WAVE2 maps to Chr region lp35-36, which frequently undergoes loss of heterozygosity and deletion in advanced stage neuroblastoma. These data clearly indicate a possible involvement of the WAVE genes in the pathogenesis of neuroblastoma. In this study, we report the complete genomic organization and expression profile of the three human WAVE genes and their mouse orthologs. We show that the WAVE genes have distinctive expression patterns in both adult and fetal human and mouse tissues. We also show a high level of conservation between these genes, in both the nucleotide and protein sequences. We finally show that the genomic structure is highly conserved among these genes and that the mouse Wave genes map to chromosome regions that have synteny in the human genome. The gene content in these syntenic regions is also conserved, suggesting that the WAVE genes are derived from a common ancient ancestor by genome duplication. The genomic characterization and expression analysis of the WAVE genes provide the basis towards understanding the function of these genes. It also provides the first steps towards the development of mouse models for the role of the WAVE genes in actin and cytoskeleton organization in general, and in the development of neuroblastoma in particular.     

Beta 1-adrenergic receptor polymorphisms confer differential function and predisposition to heart failure

Catecholamines stimulate cardiac contractility through beta(1)-adrenergic receptors (beta(1)-ARs), which in humans are polymorphic at amino acid residue 389 (Arg/Gly). We used cardiac-targeted transgenesis in a mouse model to delineate mechanisms accounting for the association of Arg389 with human heart failure phenotypes. Hearts from young Arg389 mice had enhanced receptor function and contractility compared with Gly389 hearts. Older Arg389 mice displayed a phenotypic switch, with decreased beta-agonist signaling to adenylyl cyclase and decreased cardiac contractility compared with Gly 389 hearts. Arg389 hearts had abnormal expression of fetal and hypertrophy genes and calcium-cycling proteins, decreased adenylyl cyclase and G alpha(s) expression, and fibrosis with heart failure This phenotype was recapitulated in homozygous, end-stage, failing human hearts. In addition, hemodynamic responses to beta-receptor blockade were greater in Arg389 mice, and homozygosity for Arg389 was associated with improvement in ventricular function during carvedilol treatment in heart failure patients. Thus the human Arg389 variant predisposes to heart failure by instigating hyperactive signaling programs leading to depressed receptor coupling and ventricular dysfunction, and influences the therapeutic response to beta-receptor blockade.