The human homolog of insect-derived growth factor, CECR1, is a candidate gene for features of cat eye syndrome

Cat eye syndrome (CES) is a developmental disorder with multiple organ involvement, associated with the duplication of a 2-Mb region of 22q11.2. Using exon trapping and genomic sequence analysis, we have isolated and characterized a gene, CECR1, that maps to this critical region. The protein encoded by CECR1 is similar to previously identified novel growth factors: IDGF from Sarcophaga peregrina (flesh fly) and MDGF from Aplysia californica (sea hare). The CECR1 gene is alternatively spliced and expressed in numerous tissues, with most abundant expression in human adult heart, lung, lymphoblasts, and placenta as well as fetal lung, liver, and kidney. In situ hybridization of a human embryo shows specific expression in the outflow tract and atrium of the developing heart, the VII/VIII cranial nerve ganglion, and the notochord. The location of this gene in the CES critical region and its embryonic expression suggest that the overexpression of CECR1 may be responsible for at least some features of CES, particularly the heart defects.     

Prenatal diagnosis and molecular cytogenetic characterization of mosaicism for a small supernumerary marker chromosome derived from chromosome 22 associated with cat eye syndrome

We present prenatal diagnosis of mosaicism for a small supernumerary marker chromosome (sSMC) derived from chromosome 22 associated with cat eye syndrome (CES) using cultured amniocytes in a pregnancy with fetal microcephaly, intrauterine growth restriction, left renal hypoplasia, total anomalous pulmonary venous return with dominant right heart and right ear deformity. The sSMC was bisatellited and dicentric, and was characterized by multiplex ligation-dependent probe amplification (MLPA) and array comparative genomic hybridization (aCGH). The SALSA MLPA P250-B1 DiGeorge Probemix showed duplication of gene dosage in the CES region. aCGH showed a 1.26-Mb duplication at 22q11.1–q11.21 encompassing CECR1–CECR7. The sSMC was likely inv dup(22) (q11.21). Prenatal diagnosis of an sSMC(22) at amniocentesis should alert CES. MLPA, aCGH and fetal ultrasound are useful for rapid diagnosis of CES in case of prenatally detected sSMC(22).     

Transgenic expression of <Emphasis Type="Italic">CECR1</Emphasis> adenosine deaminase in mice results in abnormal development of heart and kidney

Cat eye syndrome is a rare developmental defect associated with duplication of chromosome 22q11. The patients demonstrate specific abnormalities of heart, kidney, and eye. Here we attempted to produce a model for this defect by expressing CECR1 adenosine deaminase, a gene duplicated in cat eye syndrome patients, in mice. The transgenic mice expressed CECR1 under the control of either β-actin promoter for ubiquitous expression or myosin heavy chain for heart-specific expression. The transgenics expressing CECR1 in the heart demonstrated high rate of embryonic and neonatal lethality. The mice from all the lines examined showed enlargement of the heart. Abnormalities of the kidney and eye were also detected in mice expressing CECR1 under control of the actin promoter.     

Opossum carboxylesterases: sequences,phylogeny and evidence for <Emphasis Type="Italic">CES</Emphasis> gene duplication events predating the marsupial-eutherian common ancestor

Background  

Carboxylesterases (CES) perform diverse metabolic roles in mammalian organisms in the detoxification of a broad range of drugs and xenobiotics and may also serve in specific roles in lipid, cholesterol, pheromone and lung surfactant metabolism. Five CES families have been reported in mammals with human CES1 and CES2 the most extensively studied. Here we describe the genetics, expression and phylogeny of CES isozymes in the opossum and report on the sequences and locations of CES1, CES2 and CES6 'like' genes within two gene clusters on chromosome one. We also discuss the likely sequence of gene duplication events generating multiple CES genes during vertebrate evolution.     

The Gene for Death Agonist BID Maps to the Region of Human 22q11.2 Duplicated in Cat Eye Syndrome Chromosomes and to Mouse Chromosome 6

Cat eye syndrome (CES) is associated with a duplication of a segment of human chromosome 22q11.2. Only one gene,ATP6E, has been previously mapped to this duplicated region. We now report the mapping of the human homologue of the apoptotic agonistBidto human chromosome 22 near locus D22S57 in the CES region. Dosage analysis demonstrated thatBIDis located just distal to the CES region critical for the majority of malformations associated with the syndrome (CESCR), as previously defined by a single patient with an unusual supernumerary chromosome. However,BIDremains a good candidate for involvement in CES-related mental impairment, and its overexpression may subtly add to the phenotype of CES patients. Our mapping of murineBidconfirms that the synteny of the CESCR and the 22q11 deletion syndrome critical region immediately telomeric on human chromosome 22 is not conserved in mice.Bidand adjacent geneAtp6ewere found to map to mousechromosome 6, while the region homologous to the DGSCR is known to map to mouse chromosome 16.     

Identification of regulatory variants of carboxylesterase 1 (CES1): A proof-of-concept study for the application of the Allele-Specific Protein Expression (ASPE) assay in identifying cis-acting regulatory genetic polymorphisms

It is challenging to study regulatory genetic variants as gene expression is affected by both genetic polymorphisms and non-genetic regulators. The mRNA allele-specific expression (ASE) assay has been increasingly used for the study of cis-acting regulatory variants because cis-acting variants affect gene expression in an allele-specific manner. However, poor correlations between mRNA and protein expressions were observed for many genes, highlighting the importance of studying gene expression regulation at the protein level. In the present study, we conducted a proof-of-concept study to utilize a recently developed allele-specific protein expression (ASPE) assay to identify the cis-acting regulatory variants of CES1 using a large set of human liver samples. The CES1 gene encodes for carboxylesterase 1 (CES1), the most abundant hepatic hydrolase in humans. Two cis-acting regulatory variants were found to be significantly associated with CES1 ASPE, CES1 protein expression, and its catalytic activity on enalapril hydrolysis in human livers. Compared to conventional gene expression-based approaches, ASPE demonstrated an improved statistical power to detect regulatory variants with small effect sizes since allelic protein expression ratios are less prone to the influence of non-genetic regulators (e.g., diseases and inducers). This study suggests that the ASPE approach is a powerful tool for identifying cis-regulatory variants.     

Horse carboxylesterases: Evidence for six CES1 and four families of CES genes on chromosome 3

Carboxylesterases (CES) are responsible for the detoxification of a wide range of drugs and xenobiotics, and may contribute to cholesterol, fatty acid and lung surfactant metabolism. In this study, in silico methods were used to predict the amino acid sequences, secondary and tertiary structures, and gene locations for horse CES genes and encoded proteins, using data from the recently completed horse genome project. Evidence was obtained for six CES1 genes closely localised on horse chromosome 3, for which the predicted CES1 gene products are ≥ 74% identical. The horse genome also showed evidence for three other CES gene classes: CES5, located in tandem with the CES1 gene cluster; and CES2 and CES3, located more than 9 million base pairs downstream on chromosome 3. Horse CES2, CES3 and CES5 gene products shared 42–46% identity with each other, and with the CES1 protein subunits. Sequence alignments of these enzymes demonstrated key enzyme and family specific CES protein sequences reported for human CES1, CES2, CES3 and CES5. In addition, predicted secondary and tertiary structures for horse CES1, CES2, CES3 and CES5 subunits showed extensive conservation with human CES1. Phylogenetic analyses demonstrated the relationships and potential evolutionary origins of the horse CES sequences with previously reported sequences for human and other mammalian CES gene products. Several CES1 gene duplication events have apparently occurred following the appearance of the ‘dawn’ horse ~ 55 million years ago.     

Identification and Cloning of the Human Homolog (JAG1) of the RatJagged1Gene from the Alagille Syndrome Critical Region at 20p12

Notch proteins are a family of closely related transmembrane receptors proven to be instrumental in cell fate decisions. Recently, Notch ligands Delta and Jagged have been identified inDrosophilaand rat, respectively. We have isolated the human homolog of the ratJagged1gene,JAG1,from a CpG island in a YAC clone covering the Alagille syndrome critical region at chromosome 20p12 (tel–SNAP–D20S186–cen). Alagille syndrome is an autosomal dominant disorder characterized by neonatal jaundice, paucity of intrahepatic bile ducts, and abnormalities of the heart, skeleton, and eyes. The humanJagged1(JAG1), therefore, appears to be a strong candidate gene for this disease. Here we describe the identification, full-length cDNA cloning, expression patterns, and precise physical location of this gene within the Alagille syndrome critical region.     

A human homologue of the Drosophila melanogaster sluggish-A (proline oxidase) gene maps to 22q11.2, and is a candidate gene for type-I hyperprolinaemia

We have cloned the complete coding region for a human homologue of the Drosophila melanogaster sluggish-A and yeast PUT1 genes, previously shown to encode proline oxidase activity in these organisms. The predicted 516-residue human protein shows strong homology (51% amino acid sequence identity) to the D. melanogaster protein, indicating that this new human gene may encode proline oxidase. Northern analysis shows that the gene is expressed in human lung, skeletal muscle and brain, to a lesser extent in heart and kidney, and weakly in liver, placenta and pancreas. The gene was mapped by fluorescence in situ hybridization and by in situ hybridization with a [³H]-labelled DNA probe to chromosome 22q11.2, a region previously implicated in type-I hyperprolinaemia in a case of CATCH 22 syndrome, a contiguous gene deletion syndrome involving 22q11. Taken together, the evidence indicates that this new human gene is a good candidate gene for type-I hyperprolinaemia. In view of the neurological phenotype of the D. melanogaster sluggish-A mutant, it is of interest that schizophrenia and bipolar disorder susceptibility genes also map in this region. Received: 14 April 1997 / Accepted: 17 June 1997     

DNA Sequence, Chromosomal Localization, and Tissue Expression of the Mouse Proteasome SubunitLmp10(Psmb10) Gene

Proteasomes are nonlysosomal multicatalytic proteases involved in antigen processing. Three of the 10 mammalian proteasome β subunits (LMP2, LMP7, and LMP10) are induced by IFN-γ. Two of these (LMP2 and LMP7) are encoded in the major histocompatibility complex of both human (chromosome 6) and mouse (chromosome 17). However, the human homologue ofLmp10, MECL1,is found on chromosome 16. Here we show that in mice,Lmp10is a single-copy gene localized to chromosome 8, in a region of conserved synteny with human chromosome 16. Sequencing of a 129/SvJ strain genomic clone revealed that the gene has eight exons spanning 2.3 kb. Characterization of a full-length mouse cDNA clone indicates thatLmp10encodes a protein of 273 amino acids with a calculated molecular weight of 29 kDa and an isoelectric point of 6.86. Northern analysis ofLmp2, Lmp7,andLmp10showed expression in heart, liver, thymus, lung, and spleen, but not in brain, kidney, skeletal muscle, or testis.     

Genetic variation in human carboxylesterase CES1 confers resistance to hepatic steatosis

Obesity often leads non-alcoholic fatty liver disease, insulin resistance and hyperlipidemia. Expression of carboxylesterase CES1 is positively correlated with increased lipid storage and plasma lipid concentration. Here we investigated structural and metabolic consequences of a single nucleotide polymorphism in CES1 gene that results in p.Gly143Glu amino acid substitution. We generated a humanized mouse model expressing CES1^WT (control), CES1^G143E and catalytically dead CES1^S221A (negative control) in the liver in the absence of endogenous expression of the mouse orthologous gene. We show that the CES1^G143E variant exhibits only 20% of the wild-type lipolytic activity. High-fat diet fed mice expressing CES1^G143E had reduced liver and plasma triacylglycerol levels. The mechanism by which decreased CES1 activity exerts this hypolipidemic phenotype was determined to include decreased very-low density lipoprotein secretion, decreased expression of hepatic lipogenic genes and increased fatty acid oxidation as determined by increased plasma ketone bodies and hepatic mitochondrial electron transport chain protein abundance. We conclude that attenuation of human CES1 activity provides a beneficial effect on hepatic lipid metabolism. These studies also suggest that CES1 is a potential therapeutic target for non-alcoholic fatty liver disease management.     

Cloning and tissue expression of the mouse ortholog of AIM1, a βγ-crystallin superfamily member

We report the isolation of the murine ortholog of AIM1, a human gene whose expression is associated with the reversal of tumorigenicity in an experimental model of melanoma. Mouse and human AIM1 are more than 90% identical in amino acid sequence in the βγ-crystallin repeats and the C-terminal domain, and more than 75% identical in the extended N-terminal domain. Consistent with the isolated cDNA representing the authentic AIM1 ortholog, linkage analysis localized mouse Aim1 to proximal mouse Chromosome (Chr) 10 in a conserved linkage group with genes localized to human Chr band 6q21. Searches of EST databases identified a second AIM1-like gene in both mouse and human, suggesting the existence of a gene family. Northern analysis demonstrates Aim1 is expressed most abundantly in adult skin, lung, heart, liver, and kidney and is temporally regulated during embryogenesis. Aim1 is expressed highly in the shaft region of the hair follicles and the presumptive ectoderm, but not at detectable levels in melanocytes or melanocyte precursor cells. Received: 18 February 1998 / Accepted: 8 May 1998