Assignment of the human fibronectin structural gene to chromosome 2

A cloned human cDNA probe for fibronectin (FN) containing 1.3 kb of the human FN coding region has been used to determine the chromosome that encodes the structural gene in human-mouse somatic cell hybrids. The results show that human chromosome 2 encodes the FN structural gene.     

Species-specific monoclonal antibodies in the assignment of the gene for human fibronectin to chromosome 2.

Using three different species-specific monoclonal antibodies we have studied, in human-mouse and human-hamster somatic cell hybrids, the correlation between the presence of different human chromosomes and the ability to release human fibronectin into the tissue culture medium. Presence of human fibronectin was determined by an affinity-radioimmunoassay. In addition, tissue culture media of the different hybrids were separated on SDS-polyacrylamide gels, the proteins were blotted onto a nitrocellulose sheet and human fibronectin visualized by an immunoenzymatic technique. Karyology and determination of isoenzyme markers of specific human chromosomes show that the ability to produce human fibronectin segregated with the presence of human chromosome 2.     

Assignment of the human ST2 gene to chromosome 2 at q11.2

The humanSt2 locus has been assigned to chromosome 2, using a human ST2 cDNA clone, by a human/rodent somatic cell hybrid mapping panel. TheSt2 locus has also been mapped to chromosome 2811.2, using a human ST2 genomic DNA clone, by in situ hybridization. The locus is very tightly linked to theIl-1r1 locus. Together with the structural similarity of ST2 to IL-1RI, these data suggest functional relationships between these two genes.     

Assignment of d-amino-acid oxidase gene to a human and a mouse chromosome

Summary. A part of d-amino-acid oxidase gene was amplified in the human and mouse by polymerase chain reaction. The amplified fragments were ligated to plasmids and then cloned. The plasmids containing the parts of d-amino-acid oxidase gene were biotinylated and hybridized to human and mouse metaphase chromosomes. The chromosomal slides were treated with fluorescein isothiocyanate (FITC)-conjugated avidin. The hybridized signals were amplified with biotinylated anti-avidin antibody and FITC-avidin. The chromosomes were counter-stained with diamidino-phenylindole for assignment of the signal to a specific band. Using this fluorescence in situ hybridization (FISH), d-amino-acid oxidase gene was assigned to human chromosome 12q23–24.1 and mouse chromosome 5E3-F. Since these regions are syntenic between human and mouse, the present results indicate that the locus for this enzyme has been conserved through evolution. Received July 11, 2000 Accepted November 10, 2000     

Assignment of the alpha B-crystallin gene to human chromosome 11

Using a human alpha B-crystallin genomic probe and human-mouse somatic cell hybrids, the human alpha B-gene was assigned to chromosome 11 and further corroborated by in situ hybridization to normal metaphase chromosomes. This assignment confirmed and regionally mapped the locus to q22.3-23.1.     

Assignment of the human parathyroid hormone gene to chromosome 11

Summary A panel of human-mouse and human-Chinese hamster cell hybrid DNA's was screened for hybridisation with a fragment of the human parathyroid hormone chromosomal gene. A 7-kilobasepair Msp I restriction fragment homologous to this probe was found to segregate with the human chromosome 11.     

Assignment of the human tyrosine aminotransferase gene to chromosome 16

Summary The liver enzyme tyrosine aminotransferase (TAT; EC 2.6.1.5) catalyzes the rate-limiting step in the catabolic pathway of tyrosine. Deficiency in TAT enzyme activity underlies the autosomally inherited disorder tyrosinemia II (Richner-Hanhart syndrome). Using a human TAT cDNA clone as hybridization probe, we have determined the chromosomal location of the TAT structural gene by Southern blot analysis of DNAs from a series of human x rodent somatic cell hybrids. The results assign the TAT gene to human chromosome 16.     

Assignment of a structural gene for beta-glucuronidase to human chromosome C7.

An electrophoretic technique was developed which allows the separation of human beta-glucuronidase (GUS EC 3.2.1.3.1) from the enzyme present in cultured murine. Chinese and Syrian hamster cells in one buffer system on Cellogel. Using this technique a number of independent human-mouse somatic cell hybrids have been analyzed for the segregation of GUS, other enzyme markers, and all human chromosomes. The results indicate that a structural gene for human beta-glucuronidase is located on chromosome C7.     

Assignment of a human DNA-repair gene associated with sister-chromatid exchange to chromosome 19

The Chinese hamster ovary (CHO) cell mutant, EM9, is defective in rejoining strand breaks, hypersensitive to chlorodeoxyuridine (CldUrd), and has a high frequency of sister-chromatid exchange (SCE). Somatic cell hybrids constructed from fusion of EM9 cells with normal human lymphocytes and fibroblasts, and selected in CldUrd, extensively segregate human chromosomes but preferentially retain markers of human chromosome 19. The SCE frequency in the hybrid clones is low as in normal CHO cells, but in CldUrd-sensitive subclones, which lose the human chromosome 19 markers, SCE frequencies return to mutant levels. We therefore assign a human gene designated repair complementing defective repair in Chinese-hamster (RCC) to chromosome 19. Since this is the second (of two) human genes complementing repair-deficiency mutations in CHO cells assigned to the 19, the assignment and organization of DNA-repair genes is discussed in the light of hemizygosity in CHO cells and the evolutionary conservation of mammalian linkage groups.     

Assignment of the human cytochrome c1 gene to chromosome 8

We previously isolated a cDNA clone for human cytochrome c1. The insert DNA of approximately 950 bp from this clone was used as a probe to identify the cytochrome c1 gene. High molecular weight DNAs extracted from a panel of 14 independent human-mouse somatic cell hybrids were digested with BamHI and analyzed by Southern blot hybridization. The results indicated that the gene for human cytochrome c1 is located on chromosome 8.     

Assignment of a human DNA double-strand break repair gene (XRCC5) to chromosome 2.

The Chinese hamster ovary (CHO-K1) cell mutant XRS-6 is defective in rejoining of DNA double-strand breaks and is hypersensitive to X-rays, gamma-rays, and bleomycin. Radiation resistance or sensitivity of somatic cell hybrids constructed from the fusion of XRS-6 cells with primary human fibroblasts strongly correlated with the retention of human chromosome 2 isozyme and molecular markers. Discordancies between some chromosome 2 markers and the radiation resistance phenotype in some of the hybrid cells suggested the location of the X-ray repair cross complementing 5 (XRCC5) gene on the p arm of chromosome 2. Introduction of human chromosome 2 by microcell-mediated chromosome transfer into the radiation-sensitive XRS-6 cells resulted in hybrid cells in which the radiation sensitivity was complemented. The chromosome 2p origin of the complementing human DNA in the microcell hybrids was supported by fluorescent in situ hybridization analysis of human metaphases using human DNA amplified from the hybrids by inter-Alu-PCR as chromosome-painting probes. XRCC5 is therefore provisionally assigned to human chromosome 2p.     

Assignment of the human gene for hexosaminidase B to chromosome 5

Mouse-human somatic cell hybrids between different mouse and human cells were studied for the expression of human hexosaminidases A and B activities. The expression of human hexosaminidase B in the hybrids was found to segregate concordantly with the presence of the human chromosome 5. Mouse-human hybrid clones containing either the human chromosomes 5 and 7 only or the human chromosome 7 only were also included in this study. Expression of human hexosaminidase B activity was detected only in those clones containing human chromosome 5. These results indicate that the gene(s) for human hexosaminidase B is located on chromosome 5. No hexosaminidase A activity was detected in clones which contained either human chromosomes 5 and 7 or chromosome 7.     

Assignment of the human gene for histidine-rich glycoprotein to chromosome 3

Histidine-rich glycoprotein (HRG) is a monomeric plasma glycoprotein involved in the modulation of coagulation and fibrinolysis. Using Southern analysis of human-rodent somatic cell hybrid DNA with a human HRG-specific cDNA probe, the HRG gene was assigned to chromosome 3. One hybrid that was known to contain only a segment of chromosome 3 also reacted positively with the HRG probe. Hybridization analysis with a set of chromosome 3-specific probes showed that the segment of chromosome 3 present in this hybrid is missing the region pter-p14, which indicates that HRG is not located in this region. No restriction fragment length polymorphisms were detected for HRG with 10 commonly used restriction enzymes.     

Assignment of the human gene for phosphoglycolate phosphatase to chromosome 16

Summary Seventeen independently derived primary mouse-human hybrid clones were scored for the expression of human phosphoglycolate phosphatase (PGP) by electrophoresis and for the presence of human chromosomes with the aid of Q banding. The correlation of biochemical and cytogenetic analyses shows that the segregation of human PGP in these hybrids is concordant only with human chromosome 16, thus enabling the assignment of the genetic locus for PGP to human chromosome 16.     

Assignment of the human indoleamine 2,3-dioxygenase gene to chromosome 8 using the polymerase chain reaction

In order to identify the chromosomal assignment for the human indoleamine 2,3-dioxygenase (IDO) gene, we performed the polymerase chain reaction (PCR) using somatic cell hybrids and screened for the presence of amplified products. The results indicate that the human IDO gene can be assigned to chromosome 8.     

Assignment of human pepsinogen C (PGC) gene to chromosome 6

cDNA of rat pepsinogen C (PGC) hybridizes to, among others, a 3.2-kb band in Southern blot analysis of BamHI-cleaved human genomic DNA. This property was employed to localize the human PGC gene. Use of flow-sorted human chromosomes and 12 human x mouse somatic cell hybrid lines demonstrated that the gene is located on chromosome 6.     

Assignment of the structural gene coding for albumin to human chromosome 4

Summary Albumin is a developmentally regulated serum protein synthesized in the liver mainly during adulthood. Family studies using variant forms of albumin established autosomal linkage between albumin and group-specific component protein (GS). Since GC has been assigned to human chromosome 4, albumin can be indirectly assigned to the same chromosome; however no direct assignment has been made. Recently, the human albumin cDNA probe has been isolated and characterized. It thus permits a direct chromosomal assignment of the albumin gene in the human genome. When the cDNA probe was hybridized to the HindIII digested total human DNA, an intense band at 6.8 kb was present. When the probe was hybridized to the HindIII digested Chinese hamster CHO-K1 DNA, a less intense band at 3.5 kb was found, plus three other faint bands. When the probe was hybridized to a series of human/CHO-K1 cell hybrids retaining a complete hamster genome and various combinations of human chromosomes, it was evident that hybrids containing human albumin gene sequences could be readily distinguished from hybrids containing no human albumin gene. Analysis of 22 primary cell hybrids for the presence or absence of human albumin sequences has assigned the albumin gene to human chromosome 4. Similar results were obtained using another restriction endonuclease EcoR1. Thus, by direct assay of the genomic albumin gene sequences in the cell hybrids, we provide evidence for a direct assignment of the structural gene for human albumin to chromosome 4.