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).     

Human zinc finger gene ZNF23 (Kox16) maps to a zinc finger gene cluster on chromosome 16q22, and ZNF32 (Kox30) to chromosome region 10q23-–q24

Two members of the KOX gene family, ZNF23 (KOX16) and ZNF32 (KOX30), have been mapped by in situ hybridization to chromosome regions 16q22 and 10q23-q24, respectively. The map location of ZNF23 and ZNF32 placed these zinc finger protein genes near to chromosome loci that, under certain in vitro conditions, are expressed as fragile sites (FRA16B, FRA16C) and (FRA10D, FRA10A, FRA10B and FRA10E). Human zinc finger gene ZNF32 maps to a chromosome region on 10q23-24 in which deletions have been observed associated with malignant lymphoma on 10q22-23 and with carcinoma of the prostate on 10q24. ZNF23 is located on 16q22 in a chromosomal region that has been involved in chromosome alterations characteristic of acute myeloid leukemia. A second Kox zinc finger gene (ZNF19/KOX12) was recently mapped to the same chromosome region on human chromosome 16q22. In the analogous murine position, the murine zinc finger genes Zfp-1 and Zfp-4 are found in the syntenic 16q region of mouse chromosome 8. Thus, ZNF19 and ZNF23 might be members of an evolutionarily conserved zinc finger gene cluster located on human chromosome 16q22.     

Decreased DGCR8 Expression and miRNA Dysregulation in Individuals with 22q11.2 Deletion Syndrome

Deletion of the 1.5–3 Mb region of chromosome 22 at locus 11.2 gives rise to the chromosome 22q11.2 deletion syndrome (22q11DS), also known as DiGeorge and Velocardiofacial Syndromes. It is the most common micro-deletion disorder in humans and one of the most common multiple malformation syndromes. The syndrome is characterized by a broad phenotype, whose characterization has expanded considerably within the last decade and includes many associated findings such as craniofacial anomalies (40%), conotruncal defects of the heart (CHD; 70–80%), hypocalcemia (20–60%), and a range of neurocognitive anomalies with high risk of schizophrenia, all with a broad phenotypic variability. These phenotypic features are believed to be the result of a change in the copy number or dosage of the genes located in the deleted region. Despite this relatively clear genetic etiology, very little is known about which genes modulate phenotypic variations in humans or if they are due to combinatorial effects of reduced dosage of multiple genes acting in concert. Here, we report on decreased expression levels of genes within the deletion region of chromosome 22, including DGCR8, in peripheral leukocytes derived from individuals with 22q11DS compared to healthy controls. Furthermore, we found dysregulated miRNA expression in individuals with 22q11DS, including miR-150, miR-194 and miR-185. We postulate this to be related to DGCR8 haploinsufficiency as DGCR8 regulates miRNA biogenesis. Importantly we demonstrate that the level of some miRNAs correlates with brain measures, CHD and thyroid abnormalities, suggesting that the dysregulated miRNAs may contribute to these phenotypes and/or represent relevant blood biomarkers of the disease in individuals with 22q11DS.     

Clinical and molecular description of the prenatal diagnosis of a fetus with a maternally inherited microduplication 22q11.2 of 2.5 Mb

Microduplications of 22q11.2 have been recently characterized as a new genomic duplication syndrome showing an extremely variable phenotype ranging from normal or mild learning disability to multiple congenital defects and sharing some overlapping features with DiGeorge/Velocardiofacial syndrome (DGS/VCFS). We report on the prenatal diagnosis of a 22q11.2 microduplication in a fetus with normal development that was referred for chromosomal analysis at 17 weeks of gestation because of advanced maternal age. Pregnancy was the result of an IVF-ICSI attempt after 4 years of infertility, mainly due to severe oligoasthenoteratospermia of the father. Amniocentesis was undertaken and cytogenetic analysis revealed an apparently normal male karyotype. Multiple Ligation-dependent Probe Amplification (MLPA) revealed a microduplication in the 22q11.2 chromosome region. Parental analysis showed that the 22q11.2 microduplication has been inherited from the otherwise healthy mother. Analysis with high resolution array-CGH showed that the size of the microduplication is 2.5 Mb and revealed the genes that are duplicated, including the TBX1 gene. The parents elected to continue with the pregnancy and the infant is now five months old and shows normal development.     

Juxta-centromeric region of human chromosome 21 is enriched for pseudogenes and gene fragments

A physical map including four pseudogenes and 10 gene fragments and spanning 500 kb in the juxta-centromeric region of the long arm of human chromosome 21 is presented. cDNA fragments isolated from a selected cDNA library were characterized and mapped to the 831B6 YAC and to two BAC contigs that cover 250 kb of the region. An 85 kb genomic sequence located in the proximal region of the map was analyzed for putative exons. Four pseudogenes were found, including psiIGSF3, psiEIF3, psiGCT-rel whose functional copies map to chromosome 1p13, chromosome 2 and chromosome 22q11, respectively. The TTLL1 pseudogene corresponds to a new gene whose functional copy maps to chromosome 22q13. Ten gene fragments represent novel sequences that have related sequences on different human chromosomes and show 97-100% nucleotide identity to chromosome 21. These may correspond to pseudogenes on chromosome 21 and to functional genes in other chromosomes. The 85 kb genomic sequence was analyzed also for GC content, CpG islands, and repetitive sequence distribution. A GC-poor L isochore spanning 40 kb from satellite 1 was observed in the most centromeric region, next to a GC-rich H isochore that is a candidate region for the presence of functional genes. The pericentric duplication of a 7.8 kb region that is derived from the 22q13 chromosome band is described. We showed that the juxta-centromeric region of human chromosome 21 is enriched for retrotransposed pseudogenes and gene fragments transferred by interchromosome duplications, but we do not rule out the possibility that the region harbors functional genes also.     

Biochemical characterisation of the proteins encoded by the DiGeorge critical region 6 (DGCR6) genes

The DiGeorge critical region 6 (DGCR6) gene exists in two highly homologous copies (DGCR6 and DGCR6L) on chromosome 22q11 and is deleted in patients with velo-cardio-facial syndrome/DiGeorge syndrome (VCFS/DGS). The DGCR6 mRNA levels are increased in metastatic mammary tumour cells and regulate the expression of neighbouring genes at the 22q11 region. Newly developed monoclonal antibodies detected predominantly nuclear phosphoproteins of approximately 25 kDa, with low expression levels in the cytoplasm. Both proteins have half-lives of about 2.5 h. Exogenously expressed DGCR6 and DGCR6L migrated with slightly different mobility in SDS-gels in accordance with two immunoreactive bands observed for the endogenous proteins. DGCR6 is found at low levels in primary human fibroblasts or peripheral blood mononuclear cells, while tumour cells, B-cells transformed by EBV as well as activated normal human T cells, contain elevated levels of the proteins. The proteins are differentially expressed in mammalian tissues, with high protein levels in heart, liver and skeletal muscle. These observations are important as some patients with DGCR6 syndrome exhibit a T-cell deficiency and/or cardiac malformations. As the DGCR6 protein(s) influence gene expression in trans, we analysed the influence of DGCR6/DGCR6L on the Epstein-Barr virus-encoded oncoproteins EBNA2 and EBNA3c in the activation of the viral LMP1 promoter, as well as LMP1-mediated activation of NFkB, but found no effect in either setting.     

Isolation of genes from the rhabdoid tumor deletion region in chromosome band 22q11.2

We employed exon trapping and large-scale genomic sequence analysis of two bacterial artificial chromosome clones to isolate genes from the region between the IGLC and BCR in chromosome 22q11.2. At the time these studies were initiated, one previously identified gene, GNAZ, was known to map to this region. Two genes, RTDR1 and RAB36, were cloned from this portion of 22q11, which is heterozygously or homozygously deleted in pediatric rhabdoid tumors of the brain, kidney and soft tissues. RTDR1 is a novel gene with a slight homology to a yeast vacuolar protein. RAB36 is a member of the Rab family of proteins. A series of primary rhabdoid tumors with chromosome 22q11 deletions were screened for mutations in the coding sequences of RTDR1, GNAZ and RAB36, but did not demonstrate any disease-specific alterations. Recently, INI1, which maps to the distal portion of the deletion region in 22q11, was identified as the candidate rhabdoid tumor suppressor gene. Further studies of RTDR1 and RAB36 are required to determine whether their absence contributes to the progression of rhabdoid tumors. Alternatively, these genes may be candidates for other diseases that map to human chromosome 22.     

Chromosomal Localization and Genomic Organization of Genes Encoding Guanylyl Cyclase Receptors Expressed in Olfactory Sensory Neurons and Retina

We recently cloned three membrane guanylyl cyclases, designated GC-D, GC-E, and GC-F, from rat olfactory tissue and eye. Amino acid sequence homology suggests that they may compose a new gene subfamily of guanylyl cyclase receptors specifically expressed in sensory tissues. Their chromosomal localization was determined by mouse interspecific backcross analysis. The GC-D, GC-E, and GC-F genes (Gucy2d, Gucy2e,andGucy2f) are dispersed through the mouse genome in that they map to chromosomes 7, 11, and X, respectively. Close proximity of the mouse GC-D gene toOmp(olfactory marker protein) andHbb(hemoglobin β-chain complex) suggests that the human homolog gene maps to 11p15.4 or 11q13.4–q14.1. The human GC-F gene was localized to the long arm of chromosome Xq22 by fluorescencein situhybridization. The genomic organization of the mouse GC-E gene was determined and compared to other guanylyl cyclase genes. The mouse GC-D, GC-E, and GC-F genomic clones contain identical exon–intron boundaries within their extracellular and cytoplasmic domains, demonstrating the conservation of the gene structures. With respect to human genetic diseases, GC-E mapped to mouse chromosome 11 within a syntenic region on human chromosome 17p13 that has been linked with loci for autosomal dominant retinitis pigmentosa and Leber congenital amaurosis. No apparent disease loci have been yet linked to the locations of the GC-D or GC-F genes.     

A 1.6-Mb Microdeletion in Chromosome 17q22 Leads to NOG-Related Symphalangism Spectrum Disorder without Intellectual Disability

Microdeletions in chromosome 17q22, where the NOG gene resides, have been reported leading to the NOG-related symphalangism spectrum disorder (NOG-SSD), intellectual disability and other developmental abnormalities. In this study we reported a dominant Chinese Han family segregating with typical NOG-SSD symptoms including proximal symphalangism, conductive hearing loss, amblyopia and strabismus, but not intellectual disability. Sanger sequencing identified no pathogenic mutation in the coding regions of candidate genes NOG, GDF5 and FGF9. SNP genotyping in the genomic region surrounding NOG identified loss of heterozygosity in the affected family members. By array comparative genomic hybridization and quantitative real-time polymerase chain reaction, we identified and mapped the breakpoints of a novel 1.6-Mb microdeletion in chromosome 17q22 that included NOG and twelve other genes. It is the first microdeletion reported in chromosome 17q22 that is associated with NOG-SSD only but not with intellectual disability. Our results may help identifying the dosage sensitive genes for intellectual disability and other developmental abnormalities in chromosome 17q22. Our study also suggested that genomic deletions in chromosome 17q22 should be screened in the NOG-SSD patients in which no pathogenic mutation is identified by conventional sequencing methods.     

GNB1L, a gene deleted in the critical region for DiGeorge syndrome on 22q11, encodes a G-protein beta-subunit-like polypeptide

CATCH 22 syndromes, which include DiGeorge syndrome and Velocardiofacial syndrome, are the most common cause of congenital heart disease which involve microdeletion of 22q11. Using a strategy including EST searching, PCR amplification and 5'-RACE, we have cloned a 1487 bp cDNA fragment from human heart cDNA library. The cloned GNB1L cDNA encodes a G-protein beta-subunit-like polypeptide, and the GNB1L gene is located in the critical region for DiGeorge syndrome. A comparison of GNB1L cDNA sequence with corresponding genomic DNA sequence revealed that this gene consists of seven exons and spans an approximately 60 kb genomic region. Northern blot analysis revealed GNB1L is highly expressed in the heart.     

Mouse and Human CRKL Is Dosage Sensitive for Cardiac Outflow Tract Formation

The human chromosome 22q11.2 region is susceptible to rearrangements during meiosis leading to velo-cardio-facial/DiGeorge/22q11.2 deletion syndrome (22q11DS) characterized by conotruncal heart defects (CTDs) and other congenital anomalies. The majority of individuals have a 3 Mb deletion whose proximal region contains the presumed disease-associated gene TBX1 (T-box 1). Although a small subset have proximal nested deletions including TBX1, individuals with distal deletions that exclude TBX1 have also been identified. The deletions are flanked by low-copy repeats (LCR22A, B, C, D). We describe cardiac phenotypes in 25 individuals with atypical distal nested deletions within the 3 Mb region that do not include TBX1 including 20 with LCR22B to LCR22D deletions and 5 with nested LCR22C to LCR22D deletions. Together with previous reports, 12 of 37 (32%) with LCR22B–D deletions and 5 of 34 (15%) individuals with LCR22C–D deletions had CTDs including tetralogy of Fallot. In the absence of TBX1, we hypothesized that CRKL (Crk-like), mapping to the LCR22C–D region, might contribute to the cardiac phenotype in these individuals. We created an allelic series in mice of Crkl, including a hypomorphic allele, to test for gene expression effects on phenotype. We found that the spectrum of heart defects depends on Crkl expression, occurring with analogous malformations to that in human individuals, suggesting that haploinsufficiency of CRKL could be responsible for the etiology of CTDs in individuals with nested distal deletions and might act as a genetic modifier of individuals with the typical 3 Mb deletion.     

Cloning and characterization of a novel human ubiquitin-specific protease, a homologue of murine UBP43 (Usp18)

The ubiquitin-specific proteases (UBP) are a family of enzymes that cleave ubiquitin from ubiquitinated protein substrates. We have recently cloned UBP43, a novel member of this family from AML1-ETO knock-in mice. To analyze the role of UBP43 in hematopoiesis and leukemogenesis, we have cloned a full-length human UBP43 cDNA by screening a human monocytic cDNA library as well as by 5'- and 3'-rapid amplification of cDNA ends analyses. This cDNA encodes a polypeptide of 372 amino acids with all of the structural motifs of a deubiquitinating enzyme. The human UBP43 mRNA is strongly expressed in human liver and thymus. Transfection analysis has demonstrated that UBP43 is a nuclear protein. Interestingly, the gene encoding human UBP43 maps to chromosome 22q11.2. This region, known as DiGeorge syndrome critical region, contains a minimal area of 2 Mb and is consistently deleted in DiGeorge syndrome and related disorders. The syndrome is marked by thymic aplasia or hypoplasia, parathyroid hypoplasia, or congenital cardiac abnormalities. Taken together, our results broaden the understanding of a new human ubiquitin-specific protease, UBP43, and suggest that this gene may also be related to DiGeorge syndrome.     

Assignment of the βB1 Crystallin Gene (CRYBB1) to Human Chromosome 22 and Mouse Chromosome 5

By using primers complementary to the rat βB1 crystallin gene sequence, we amplified exons 5 and 6 of the orthologous human gene (CRYBB1). The amplified human segments displayed greater than 88% sequence homology to the corresponding rat and bovine sequences.CRYBB1was assigned to the group 5 region in 22q11.2–q12.1 by hybridizing the exon 6 PCR product to somatic cell hybrids containing defined portions of human chromosome 22. The exon 5 and exon 6 PCR products ofCRYBB1were used to localize, by interspecific backcross mapping, the mouse gene (Crybb1) to the central portion of chromosome 5. Three other β crystallin genes (βB2(−1), βB3, and βA4) have previously been mapped to the same regions in human and mouse. We demonstrate that the βB1 and βA4 crystallin genes are very closely linked in the two species. These assignments complete the mapping and identification of the human and mouse homologues of the major β crystallins genes that are expressed in the bovine lens.     

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     

FRG1, a gene in the FSH muscular dystrophy region on human chromosome 4q35, is highly conserved in vertebrates and invertebrates

The human FRG1 gene maps to human chromosome 4q35 and was identified as a candidate for facioscapulohumeral muscular dystrophy. However, FRG1 is apparently not causally associated with the disease and as yet, its function remains unclear. We have cloned homologues of FRG1 from two additional vertebrates, the mouse and the Japanese puffer fish Fugu rubripes, and investigated the genomic organization of the genes in the two species. The intron/exon structure of the genes is identical throughout the protein coding region, although the Fugu gene is five times smaller than the mouse gene. We have also identified FRG1 homologues in two nematodes; Caenorhabditis elegans and Brugia malayi. The FRG1 protein is highly conserved and contains a lipocalin sequence motif, suggesting it may function as a transport protein.     

An expressed β-tubulin gene, TUBB, is located on the short arm of human chromosome 6 and two related sequences are dispersed on chromosomes 8 and 13

The chromosomal assignments of an expressed β-tubulin gene and two related sequences have been determined by Southern blot analysis of DNA from a panel of human X Chinese hamster somatic cell hybrids cleaved with Hind III or EcoR I. Probes containing the 3′ untranslated regions of the expressed gene M40 and of pseudogene 21β were used to localize the M40 sequence (gene symbol TUBB) to chromosome 6 region 6p21 → 6pter, the 21β pseudogene (TUBBP1) to chromosome 8 region 8q21 → 8pter and a third related sequence (TUBBP2) to chromosome 13. Asynteny of expressed genes and related processed pseudogenes has now been demonstrated for several gene families.