Assignment of the structural gene for human beta glucuronidase to chromosome 7 and tetrameric association of subunits in the enzyme molecule.

The structural locus for human beta glucuronidase is assigned to chromosome 7, a localization based upon concordant segregation of the expression of the human enzyme and the presence of human chromosome 7 in somatic cell hybrid clones derived independently from fusions of different human and mouse cells. Hybrid clones containing only human chromosome 7 are included in this study. Electrophoresis of beta glucuronidase also has revealed that human beta glucuronidase has a tetrametric structure.     

Regional mapping on human genes for phosphoglucomutase-1 on chromosome 1 and beta-glucuronidase on chromosome 7 using mouse x human hybrids.

Two independent mouse-human somatic cell hybrid clones contained different, de novo chromosome rearrangements involving the short arm of human chromosome 1. One hybrid clone contained a translocation between human chromosomes 1 and 7; the other clone contained a rearrangement product between human chromosomes 1 and 14. Analysis of these clones for expression of genes previously assigned to chromosome 7 and to the short arm of chromosome 1 provided evidence for localization of PGM--1 in segment 1p22.1 leads to 1p31.1, AK--2, ENO--1 and UMPK in region 1pter leads to 1p31.1, and GUS in region 7 pter leads to 7q22. The results have been used to examine the relationship between cytologic and genetic map distances on the short arm of chromosome 1.     

Human β-glucuronidase: Assignment of the structural gene to chromosome 7 using somatic cell hybrids

-Glucuronidase (GUS) has become an important enzyme model for the genetic study of molecular disease, enzyme realization, and therapy, and for the biogenesis and function of the lysosome and lysosomal enzymes. The genetics of human -glucuronidase was investigated utilizing 188 primary man-mouse and man-Chinese hamster somatic cell hybrids segregating human chromosomes. Cell hybrids were derived from 16 different fusion experiments involving cells from ten different and unrelated individuals and six different rodent cell lines. The genetic relationship of GUS to 28 enzyme markers representing 19 linkage groups was determined, and chromosome studies on selected cell hybrids were performed. The evidence indicates that the -glucuronidase gene is assigned to chromosome 7 in man. Comparative linkage data in man and mouse indicate that the structural gene GUS is located in a region on chromosome 7 that has remained conserved during evolution. Involvement of other chromosomes whose genes may be important in the final expression of GUS was not observed. A tetrameric structure of human -glucuronidase was demonstrated by the formation of three heteropolymers migrating between the human and mouse molecular forms in chromosome 7 positive cell hybrids. Linkage of GUS to other lysosomal enzyme genes was investigated. -Hexosaminidase HEX _B) was assigned to chromosome 5; acid phosphatase₂ (ACP ₂) and esterase A₄ (ES-A ₄) were assigned to chromosome 11; HEX _A was not linked to GUS; and -galactosidase (-GAL) was localized on the X chromosome. These assignments are consistent with previous reports. Evidence was not obtained for a cluster of lysosomal enzyme structural genes. In demonstrating that GUS was not assigned to chromosome 9 utilizing an X/9 translocation segregating in cell hybrids, the gene coding for human adenylate kinase₁ was confirmed to be located on chromosome 9.Supported by NIH Grants HD 05196, GM 20454, and GM 06321, by NSF Grant BMS 73-07072, and by HEW Maternal and Child Health Service, Project 417.     

Chromosomal localization of seven neuronal nicotinic acetylcholine receptor subunit genes in humans.

We have determined the chromosomal location of seven human neuronal nicotinic acetylcholine receptor subunit genes by genomic Southern analysis of hamster/human somatic cell hybrid DNAs. The beta 2 subunit gene was localized to human chromosome 1, the alpha 2 and beta 3 subunit genes were localized to human chromosome 8, the alpha 3, alpha 5, and beta 4 subunit genes were localized to human chromosome 15, and the alpha 4 subunit gene was localized to human chromosome 20. Mapping of the beta 2 subunit gene to chromosome 1 establishes a syntenic group with the amylase gene locus on human chromosome 1 and mouse chromosome 3, while mapping of the alpha 3 subunit gene to chromosome 15 confirms the existence of a syntenic group with the mannose phosphate isomerase gene locus on human chromosome 15 and mouse chromosome 9.     

Combined immunization with fusion genes of mutated E7 gene of human papillomavirus type 16 did not enhance antitumor effect

BACKGROUND: The E7 oncoprotein of human papillomavirus type 16 (HPV16) is frequently used as a model tumor-associated antigen. Its immunogenicity has been substantially enhanced by fusion with several proteins of various origins and functions. Different mechanisms have been responsible for increased vaccination efficacy of fusion proteins. METHODS AND RESULTS: We linked E7 and its mutated form (E7GGG) with the mouse heat-shock protein 70.1 (HSP70.1). Enhanced immunogenicity of both fusion genes administered via a gene gun was demonstrated by protection of C57BL/6 mice against oncogenic MHC class I positive TC-1 cells producing the HPV16 E7 oncoprotein but not against the MHC class I negative TC-1/A9 subline. To assess if the efficacy of E7-based DNA vaccines could be increased by combination of various fusion genes, we combined the HSP70.1 fusion genes (i.e. E7HSP or E7GGGHSP) with the fusion construct linking E7GGG with targeting signals of lysosome-associated membrane protein 1 (Sig/E7GGG/LAMP-1). Treatment of mice 4 days after TC-1 cell inoculation showed moderately higher immunization potency of HSP70.1 fusion genes in comparison with the Sig/E7GGG/LAMP-1 gene. Any combination of two fusion genes given in the same gene gun shot neither was more effective compared with single genes nor protected mice against TC-1/A9 cells. As fusion of E7GGG with E. coli glucuronidase (E7GGG.GUS) had been previously proven to provide partial protection from TC-1/A9-induced tumors, we also combined E7GGGHSP with E7GGG.GUS. The genes were inoculated either in mix in two gene gun shots or separately each gene in one shot into opposite sides of the abdomen. Neither mode of combined immunization induced higher protection than E7GGG.GUS alone. However, doubling the DNA dose considerably enhanced the antitumor efficacy of E7GGG.GUS. CONCLUSIONS: We constructed highly immunogenic fusions of HPV16 E7 and E7GGG with mouse HSP70.1. Furthermore, we substantially enhanced protection against TC-1/A9 cells with downregulated MHC class I expression by doubling the pBSC/E7GGG.GUS dose, but we failed to demonstrate a beneficial effect of any combination of two fusion genes with different mechanisms causing enhancement of HPV16 E7 immunogenicity.     

A human T-cell antigen receptor beta chain gene maps to chromosome 7.

cDNA clones which encode the human and mouse T cell antigen receptor beta chain gene have previously been isolated. We have used a mouse cDNA clone to map the chromosomal position of a human beta chain gene. Southern blot analysis of DNA prepared from somatic cell hybrids has assigned this gene to chromosome 7. The use of a hybrid containing a chromosome 7 translocation has further localised this gene to the region 7q22-qter.     

The T cell receptor beta chain genes are located on chromosome 6 in mice and chromosome 7 in humans

Homologous clones that encode the beta chain of the T cell antigen receptor have been isolated recently from both murine and human cDNA libraries. These cDNA clones have been used in connection with interspecies hybrid cell lines to determine that the murine T cell receptor gene is located on chromosome 6 and the human gene on chromosome 7. In situ hybridization confirms these data and further localizes these genes to band B of chromosome 6 in the mouse and bands 7p13-21 in the human genome. The organization of the T cell antigen receptor J beta gene segments and C beta genes appears to be conserved, since very few intraspecies polymorphisms of restriction fragment length have been detected in either mouse or human DNA.     

Chromosomal localization of the genes encoding two forms of the G protein beta polypeptide, beta 1 and beta 3, in man

The signal-transducing G proteins are heterotrimers composed of three subunits, alpha, beta, and gamma. Multiple distinctive forms of the alpha, beta, and gamma subunits, each encoded by a distinct gene, have been described. To investigate further the structural diversity of the beta subunits, we recently cloned and characterized a novel cDNA encoding a third form of the G protein beta subunit, which we have termed beta 3. The protein corresponding to beta 3 has not yet been identified. The three forms of the beta subunit show 81-90% amino acid sequence identity. Previous studies had localized the human genes for the beta 1 and beta 2 subunits to chromosomes 1 and 7, respectively. The present studies were designed to determine whether the gene encoding beta 3 is linked to either the beta 1 or the beta 2 gene. Genomic DNA was isolated from a panel of rodent-human hybrid cell lines and analyzed by hybridization to cDNAs for beta 1 and beta 3. Discordancy analysis allowed assignment of the beta 3 gene to chromosome 12 and confirmed the previous assignment of the beta 1 gene to chromosome 1. These results were confirmed and extended by using in situ chromosome hybridization, which permitted the regional localization of the beta 1 gene to 1pter----p31.2 and the beta 3 gene to 12pter----p12.3. Digestion of human genomic DNA with 10 restriction enzymes failed to disclose a restriction fragment length polymorphism for the beta 3 gene. These data indicate that there is considerable diversity in the genomic organization of the beta subunit family.     

beta2-microglobulin locus on human chromosome 15.

We have developed an autoradiographic/electrophoretic assay capable of distinguishing mouse and human beta2-microglobulin (beta2m) in spent culture media. The method is applicable to mouse and human lines and to hybrid cell lines made from them. With this technique, mouse/human hybrid cell lines were tested for the presence of human beta2m. Isozyme and karyotype analyses were also carried out with the hybrids. The combined results of these studies show that the structural gene for human beta2m is on the long arm of chromosome 15.     

Expression of foreign genes, GUS and hygromycin resistance, in the halophyte Kosteletzkya virginica in response to bombardment with the Particle Inflow Gun

A ‘Particle Inflow Gun’ was constructed to introducethe glucuronidase (GUS) and hygromycin resistance genes intohalophytic suspension cells of Kosteletzkya virginica. The transientexpression of the GUS gene was associated with the cell cultureconditions, physical parameters during the use of the ParticleInflow Gun, and different promoters coupled to GUS. When theCaMV35S promoter was used, the cells adapted at 85 mM NaCl hada similar gene transfer efficiency to those of the non-salt-adaptedcontrol, while expression was less in the 170 mM and 255 mMNaCl-adapted cells. Both elevating bombardment pressure to 1.65mPa and shortening the distance between the cells and the particleholder from 21 cm to 9 cm enhanced GUS expression in the cellsgrown in four salinity treatments. An ABA-responsive promoterinduced the expression of the GUS gene either with 10^–4M ABA or with salts in the post-bombardment medium in both controland NaCl-adapted cell tines. Stable transgenic callus lineswere isolated by using hygromycin containing medium after bombardingthe suspension cells with the Particle Inflow Gun. The presenceof the GUS gene in stable transformants was confirmed not onlyby histochemical and fluorimetric assays for the GUS activity,but also by Southern hybridization of RT-PCR amplified mANA. Key words: Transgenic hatophyte, Particle Inflow Gun, bombardment, salt tolerance, transformation     

Quantitation of the viral DNA present in somatic cell hybrids between mouse and SV40-transformed human cells

Recent studies of somatic cell hybrids between mouse cells and SV40-transformed human cells have demonstrated a correlation between the expression of SV40 T-antigen and the presence of human chromosome 7. We have used two types of nucleic acid hybridization procedures to detect and quantitate the presence of viral DNA sequences in the DNA of the hybrid cell clones. Results of reassociation kinetics as well as hybridization with a single-strand probe indicate that SV40 DNA is present only in those hybrid clones which both contain human chromosome 7 and express the SV40 T-antigen. SV40 DNA was not detectable either in the clones which had lost human chromosome 7, or in the rare clones which retain human chromosome 7 but which do not express T-antigen. We have thus extended the correlation between human chromosome 7 and the SV40 T-antigen to the presence of integrated SV40 DNA in somatic cell hybrid clones.     

通过DNA改组技术获得高活性β-葡萄糖苷酸酶

β 葡萄糖苷酸酶是在植物转基因中广泛应用的报告基因 .以质粒pBI12 1中的GUS基因为基础 ,利用DNA改组方法 ,经DNaseⅠ降解 ,PrimerlessPCR ,PrimerPCR对GUS基因进行了突变和改组 ,然后将改组的GUS基因连接到原核表达载体pG2 5 1中 ,构建了库容为 10 8的突变体库 .经过活性的筛选 ,得到活性提高的克隆 ,再以此为基础 ,经过新的改组、筛选得到活性大幅度提高的克隆GUS2 4 .基因测序显示 ,GUS2 4与GUS基因之间的同源性为 99 7% ,共有 6个核苷酸位点发生了改变 ,分别是 :379位的A突变为G ,396位的T突变为C ,711位的G突变为A ,95 8位T突变为C ,990位的T突变为C ,1649位的A突变为G .核苷酸序列推导的氨基酸序列显示 ,3个氨基酸发生了突变 ,12 7位的Ser突变为Gly ,32 0位的Trp突变为Arg ,5 5 0位的Asn突变为Ser.X gluc染色检测和荧光测活结果显示GUS2 4基因表达的 β 葡萄糖苷酸酶基较GUS基因表达产物活性提高 3倍     

The GABAA receptor beta 3 subunit gene: characterization of a human cDNA from chromosome 15q11q13 and mapping to a region of conserved synteny on mouse chromosome 7.

A cDNA encoding the human GABAA receptor beta 3 subunit has been isolated from a brain cDNA library and its nucleotide sequence has been determined. This gene, GABRB3, has recently been mapped to human chromosome 15q11q13, the region deleted in Angelman and Prader-Willi syndromes. The association of distinct phenotypes with maternal versus paternal deletions of this region suggests that one or more genes in this region show parental-origin-dependent expression (genetic imprinting). Comparison of the inferred human beta 3 subunit amino acid sequence with beta 3 subunit sequences from rat, cow, and chicken shows a very high degree of evolutionary conservation. We have used this cDNA to map the mouse beta 3 subunit gene, Gabrb-3, in recombinant inbred strains. The gene is located on mouse chromosome 7, very closely linked to Xmv-33 between Tam-1 and Mtv-1, where two other genes from human 15q11q13 have also been mapped. This provides further evidence for a region of conserved synteny between human chromosome 15q11q13 and mouse chromosome 7. Proximal and distal regions of mouse chromosome 7 show genetic imprinting effects; however, the region of homology with human chromosome 15q11q13 has not yet been associated with these effects.     

Localization of a beta-crystallin gene, Hu beta A3/A1 (gene symbol: CRYB1), to the long arm of human chromosome 17

We have assigned a human beta-crystallin gene, Hu beta A3/A1 (gene symbol: CRYB1), to chromosome 17 using a panel of 19 human-hamster somatic cell hybrids and blot-hybridization analysis of cell hybrid DNA. Positive probe-hybridization signal was detected in a hybrid that had lost the short arm of human chromosome 17 but retained the long arm, translocated to a hamster chromosome. In addition, in situ hybridization analysis of metaphase chromosome spreads of this cell line suggested that the most probable location for CRYB1 is on the long arm of chromosome 17, in the region q21.     

GUS在植物基因功能研究中的应用和优化

β-葡糖醛酸酶(GUS)报告系统是现代分子生物学研究领域中被广泛使用的一种重要工具,在解析基因时空表达调控的研究中发挥着重要作用.本文概述了报告基因GUS的生化特性及检测手段,从启动子元件鉴定、基因诱捕、无标记转基因技术等方面论述GUS的应用现状和优势,并针对内源GUS、GUS抑制因子等问题和改进优化手段进行了分析,为该技术在植物功能基因研究中进一步拓展提供新线索和思路.     

Chromosome assignment of genes encoding the alpha and beta subunits of glycoprotein hormones in man and mouse

The chromosomal locations of the genes for the common alpha subunit of the glycoprotein hormones and the beta subunit of chorionic gonadotropin in humans and mice have been determined by restriction enzyme analysis of DNA isolated from somatic cell hybrids. The CG alpha gene (CGA), detected as a 15-kb BamHI fragment in human DNA by hybridization to CG alpha cDNA, segregated with the chromosome 6 enzyme markers ME1 (malic enzyme, soluble) and SOD2 (superoxide dismutase, mitchondrial) and an intact chromosome 6 in human-rodent hybrids. Cell hybrids containing portions of chromosome 6 allowed the localization of CGA to the q12 leads to q21 region. The greater than 30- and 6.5-kb BamHI CGB fragments hybridizing to human CG beta cDNA segregated concordantly with the human chromosome 19 marker enzymes PEPD (peptidase D) and GPI (glucose phosphate isomerase) and a normal chromosome 19 in karyotyped hybrids. A KpnI-HindIII digest of cell hybrid DNAs indicated that the multiple copies of the CG beta gene are all located on human chromosome 19. In the mouse, the alpha subunit gene, detected by a mouse thyrotropin (TSH) alpha subunit probe, and the CG beta-like sequences (CG beta-LH beta), detected by the human CG beta cDNA probe, are on chromosomes 4 and 7, respectively.     

猪心脏脂肪酸结合蛋白基因PCR-RFLP分子标记研究

利用PCR-RFLP分子标记技术,检测了杜洛克、长白、大白、内江、荣昌、汉江黑、汉白、八眉和野猪共计265头猪心脏脂肪酸结合蛋白基因5'上游区和第二内含子区的遗传变异。结果表明,在HinfI-RFLP位点上,上述猪种和野猪均存在多态性,等位基因H的频率分别为0.7500,0.7188,0.9167,0.3333,0.1250,0.6909,0.1167,0.8500和0.9375;除汉江黑猪(P<0.05)和野猪(P<0.01)外,其余的猪种基因频率和基因型频率都处于Hardy-Weinderg平衡状态(P>0.05);大白、八眉、汉江黑、汉白和野猪表现为低度多态(PIC<0.25),杜洛克、长白、内江和荣昌猪为中度多态性(0.25相似文献   

β‐glucuronidase of family‐2 glycosyl hydrolase: A missing member in plants

Glycosyl hydrolases hydrolyze the glycosidic bond in carbohydrates or between a carbohydrate and a non‐carbohydrate moiety. β‐glucuronidase (GUS) is classified under two glycosyl hydrolase families (2 and 79) and the family‐2 β‐glucuronidase is reported in a wide range of organisms, but not in plants. The family‐79 endo-β-glucuronidase (heparanase) is reported in microorganisms, vertebrates and plants. The E. coli family‐2 β‐glucuronidase (uidA) had been successfully devised as a reporter gene in plant transformation on the basis that plants do not have homologous GUS activity. On the contrary, histochemical staining with X‐Gluc was reported in wild type (non-transgenic) plants. Data shows that, family‐2 β‐glucuronidase homologous sequence is not found in plants. Further, β‐glucuronidases of family‐2 and 79 lack appreciable sequence similarity. However, the catalytic site residues, glutamic acid and tyrosine of the family‐2 β‐glucuronidase are found to be conserved in family‐79 β‐glucuronidase of plants. This led to propose that the GUS staining reported in wild type plants is largely because of the broad substrate specificity of family‐79 β-glucuronidase on X‐Gluc and not due to the family‐2 β‐glucuronidase, as the latter has been found to be missing in plants.