Positional clustering of differentially expressed genes on human chromosomes 20, 21 and 22

Background  

Clusters of genes co-expressed are known in prokaryotes (operons) and were recently described in several eukaryote organisms, including Human. According to some studies, these clusters consist of housekeeping genes, whereas other studies suggest that these clustered genes exhibit similar tissue specificity. Here we further explore the relationship between co-expression and chromosomal co-localization in the human genome by analyzing the expression status of the genes along the best-annotated chromosomes 20, 21 and 22.     

Synteny mapping of five human chromosome 7 genes on bovine chromosomes 4 and 21.

Five genes on human chromosome 7 (HSA 7) were assigned to bovine chromosome 21 (BTA 21) and 4 (BTA 4) using a bovine-rodent somatic hybrid cell panel. These five genes were alpha-I subunit of adenylate cyclase-inhibiting G-protein (GNAI1), alpha/beta preprotachykinin (TAC1), reelin (RELN), c-AMP dependant protein kinase type II beta regulatory chain (PRKAR2B) and apolipoprotein A1 regulatory protein 1 (TFCOUP2). Four genes mapped to BTA 4 (GNAI1, TAC1, RELN, PRKAR2B) while one gene mapped to BTA 21 (TFCOUP2). This study confirms the synteny conservation between HSA 7 and BTA 4, finely maps the breakpoints of conserved synteny on HSA 7 and defines a new synteny conservation between HSA 7 and BTA 21.     

Mapping studies and expression of genes located on human chromosome 11, band q23

Chromosome translocations and deletions may alter cellular proto-oncogenes and result in cellular changes that are important in the pathogenesis of malignancy. The region 11q23 is frequently involved in human malignancy. Utilizing a leukemic cell line with a reciprocal translocation involving 11q23 and somatic cell hybrids derived from this cell line, we analyzed five genes assigned to 11q23: NCAM, CD3D, CD3E, THY1, and ETS1. Our data showed no evidence of direct involvement of these genes in this leukemia but enabled a partial genetic map of this important region of the human genome to be constructed: 11cen--NCAM--CD3([G, D], E)--parallel--(ETS1, THY1)--11qter.     

Genetic linkage analysis and homology relationships of genes located on human chromosome 11q.

We have used DNA polymorphisms detected by probes for 11q to order 16 genes and to determine the genetic distances between them. Our map includes the genes for CD20, tyrosinase, progesterone receptor, stromelysin, collagenase, N-CAM, dopamine-D2 receptor, apolipoproteins AI-CIII-AIV, CD3-epsilon, -delta, and -gamma, porphobilinogen deaminase, thy-1, and ets-1. These genes have previously been sequenced as well as placed on the 11q cytogenetic map, which now makes them anchor points between the cytogenetic, genetic, and physical maps of this region. The ordering and distances between these genes are of immediate use in testing hypotheses of candidate genes for human genetic diseases associated with chromosome 11q. A comparison between our genetic map and similar maps from other species defines regions of homologous synteny that may be useful in mapping human genetic disease genes localized to the 11q region. Analysis of such homology provides additional bases for speculation of the evolutionary histories of gene families in this region.     

Localization of subtelomeric sequences of human chromosomes 1q, 11p, 13q, and 16q in the higher primates

Relative phylogenetic divergence of the members of the Pongidae family has been based on genetic evidence. The recent isolation of subtelomeric probes specific for human (HSA) chromosomes 1q, 11p, 13q, and 16q has prompted us to cross hybridize these to the chromosomes of the chimpanzee (Pan troglodytes, PTR), gorilla (Gorilla gorilla, GGO), and orangutan (Pongo pygmaeus, PPY) to search for their equivalent locations in the great apes. Hybridization signals to the 1q subtelomeric DNA sequence probe were observed at the termini of human (HSA) 1q, PTR 1q, GGO 1q, PPY 1q, while the fluorescent signals to the 11p subtelomeric DNA sequence probe were observed at the termini of HSA 11p, PTR 9p, GGO 9p, and PPY 8p. Fluorescent signals to the 13q subtelomeric DNA sequence probe were observed at the termini of HSA 13q, PTR 14q, GGO 14q, and PPY 14q, and positive signals to the 16p subtelomeric DNA sequence probe were observed at the termini of HSA 16q, PTR 18q, GGO 17q, and PPY 19q. These findings apparently suggest sequence homology of these DNA families in the ape chromosomes. Obviously, analogous subtelomeric sequences exist in apes' chromosomes that apparently have been conserved through the course of differentiation of the hominoid species. This revised version was published online in July 2006 with corrections to the Cover Date.     

Heritable fragile sites on human chromosomes. X. New folate-sensitive fragile sites: 6p23, 9p21, 9q32, and 11q23

Four new folate-sensitive fragile sites are documented at 6p23, 9p21, 9q32, and 11q23. These have all been shown to be heritable except for the one at 9p21, which has been seen only in a single individual. As with the other autosomal fragile sites, these appear to be innocuous in heterozygotes.     

Genomic organization of the human folate receptor genes on chromosome 11q13.

There has been interest in the high affinity folate receptor (FOLR) recently because of its high expression in the majority of ovarian tumors. The FOLR genes are part of a family that includes an adult gene, a fetal gene, and one or more pseudogenes, which have been localized to chromosome 11. As a step toward understanding why the adult FOLR gene product is expressed on tumors, we have determined the organization of all the human FOLR-related genes. YAC clones were isolated using the adult FOLR probe. The organization of the locus was determined by PFGE of YAC DNA and by YAC fragmentation. Four FOLR-related genes were found within 140 kb. The adult and fetal genes are not more than 23 kb apart, with the 3' end of the adult gene facing the 5' of the fetal gene. A physical map of over 900 kb of the surrounding region was also constructed. The chromosomal assignment of the FOLR locus was refined to 11q13.3-q13.5 telomeric of the FGF3 locus using fluorescence in situ hybridization.     

Molecular cloning and characterization of human Frizzled-4 on chromosome 11q14-q21.

The WNT receptors, encoded by the Frizzled genes, are implicated in a variety of cellular processes such as cell fate determination, cell polarity control, and malignant transformation. Human Frizzled-4 (FZD4) cDNAs have been cloned and characterized. FZD4 spans a total of 7392 nucleotides and encodes a 537-amino-acid protein with the N-terminal cysteine-rich domain, seven transmembrane domains, and the C-terminal S/T-X-V motif. The FZD4 mRNA of 7.7 kb in size were detected almost ubiquitously in normal human tissues and larger amounts in fetal kidney, adult heart, skeletal muscle, and ovary. Among cancer cell lines, the FZD4 mRNA level was higher in HeLa S3. The FZD4 gene has been mapped to human chromosome 11q14-q21. FZD4 is homologous to FZD9 and FZD10, and overall amino acid identity is as follows: FZD4 vs FZD9, 51.6%; FZD4 vs FZD10, 51.2%; FZD9 vs FZD10, 65.7%. FZD4 consists of two exons, while FZD9 and FZD10 consist of a single exon. FZD4 might belong to rather the independent FZD subfamily than the FZD9-FZD10 subfamily.     

Colorectal cancer linkage on chromosomes 4q21, 8q13, 12q24, and 15q22

A substantial proportion of familial colorectal cancer (CRC) is not a consequence of known susceptibility loci, such as mismatch repair (MMR) genes, supporting the existence of additional loci. To identify novel CRC loci, we conducted a genome-wide linkage scan in 356 white families with no evidence of defective MMR (i.e., no loss of tumor expression of MMR proteins, no microsatellite instability (MSI)-high tumors, or no evidence of linkage to MMR genes). Families were ascertained via the Colon Cancer Family Registry multi-site NCI-supported consortium (Colon CFR), the City of Hope Comprehensive Cancer Center, and Memorial University of Newfoundland. A total of 1,612 individuals (average 5.0 per family including 2.2 affected) were genotyped using genome-wide single nucleotide polymorphism linkage arrays; parametric and non-parametric linkage analysis used MERLIN in a priori-defined family groups. Five lod scores greater than 3.0 were observed assuming heterogeneity. The greatest were among families with mean age of diagnosis less than 50 years at 4q21.1 (dominant HLOD?=?4.51, α?=?0.84, 145.40 cM, rs10518142) and among all families at 12q24.32 (dominant HLOD?=?3.60, α?=?0.48, 285.15 cM, rs952093). Among families with four or more affected individuals and among clinic-based families, a common peak was observed at 15q22.31 (101.40 cM, rs1477798; dominant HLOD?=?3.07, α?=?0.29; dominant HLOD?=?3.03, α?=?0.32, respectively). Analysis of families with only two affected individuals yielded a peak at 8q13.2 (recessive HLOD?=?3.02, α?=?0.51, 132.52 cM, rs1319036). These previously unreported linkage peaks demonstrate the continued utility of family-based data in complex traits and suggest that new CRC risk alleles remain to be elucidated.     

Partial trisomy for the segment 21(q11----qter) resulting from a de novo translocation between chromosomes 5 and 21

A 3 1/2-year-old boy is described whose Down syndrome resulted from partial 21 trisomy through unbalanced de novo translocation between the long arm of chromosome 21 and the short arm end of a No. 5: 46,XY,t(5;21)(p15;q11). This case is discussed and compared with 17 others collected from the literature, some of which derived from a maternal balanced translocation.     

Identification of a haplosufficient 3.6-Mb region in human chromosome 11q14.3-->q21

Cytogenetic deletions are almost always associated with phenotypic abnormality and are very rarely transmitted. We have located a hitherto undescribed, familial deletion involving the region 11q14.3-->q21 in five individuals in a three-generation kindred. Four of the deletion carriers show no phenotypic abnormality; the other, who is the proband, was investigated for short stature and poor academic progress. In view of the apparent innocuous nature of this genetic imbalance, the deletion was investigated in detail to determine its size (3.6 Mb) and location with reference to molecular markers and genetic content. The deleted region is described by a contig of 37 BACS including the flanking regions, which we have assembled. Several possible contributory factors are considered, which might explain the lack of clinical significance of this large deletion. It is notable that there are few genes in this region and none have known functions. All most likely have copies elsewhere in the genome and a number of other hypothetical genes appear to be members of certain gene families, i.e. none is unique. Part of the region (1 Mb) is also duplicated at the pericentromeric region 11p11. Given the very low proportion of the genome occupied by single copy genes and their uneven distribution, regions such as this, which appear to be functionally haplosufficient, may be more common than hitherto recognised.     

Amplicons on human chromosome 11q are located in the early/late-switch regions of replication timing

Amplicons are frequently found in human tumor genomes, but the mechanism of their generation is still poorly understood. We previously measured the replication timing of the genes along the entire length of human chromosomes 11q and 21q and found that many "disease-related" genes are located in timing-transition regions. In this study, further scrutiny of the updated replication-timing map of human chromosome 11q revealed that both amplicons on human chromosomal bands 11q13 and 11q22 are located in the early/late-switch regions of replication timing in two human cell lines (THP-1 and Jurkat). Moreover, examination of synteny in the human and mouse genomes revealed that synteny breakage in both genomes occurred primarily at the early/late-switch regions of replication timing that we had identified. In conclusion, we found that the early/late-switch regions of replication timing coincided with "unstable" regions of the genome.     

Replication of autism linkage: fine-mapping peak at 17q21

Autism is a heritable but genetically complex disorder characterized by deficits in language and in reciprocal social interactions, combined with repetitive and stereotypic behaviors. As with many genetically complex disorders, numerous genome scans reveal inconsistent results. A genome scan of 345 families from the Autism Genetic Resource Exchange (AGRE) (AGRE_1), gave the strongest evidence of linkage at 17q11-17q21 in families with no affected females. Here, we report a full-genome scan of an independent sample of 91 AGRE families with 109 affected sibling pairs (AGRE_2) that also shows the strongest evidence of linkage to 17q11-17q21 in families with no affected females. Taken together, these samples provide a replication of linkage to this chromosome region that is, to our knowledge, the first such replication in autism. Fine mapping at 2-centimorgan (cM) intervals in the combined sample of families with no affected females reveals a linkage peak at 66.85 cM, which places this locus at 17q21.     

Partial trisomy 21 with 45 chromosomes due to translocation of two chromosomes 21 onto a chromosome 14 : 45,XX-14,-21,+t(14q21q21q) (author's transl)

A patient with the phenotype of trisomy 21 and increased activity of superoxide dismutase A is reported with partial trisomy for the distal portion of 21q. The exceptional feature in this case is a 45-chromosome karyotype due to the translocation of two chromosomes 21 onto the distal end of 14q.     

Complex chromosomal rearrangement involving chromosomes 11, 13 and 21

In the present report we describe a complex chromosomal rearrangement, resulting in a distal 11p monosomy, in a 7-month-old severely retarded girl with a non-specific phenotype. In this complex chromosomal rearrangement chromosomes 11, 13 and 21 are involved in the translocation of the long arm of chromosome 21 on the short arm of chromosome 13 and translocation of the short arm and satellites of chromosome 21 on the short arm of chromosome 11.