Pig whey acidic protein gene is surrounded by two ubiquitously expressed genes

A 140-kb pig DNA fragment containing the whey acidic protein (WAP) gene cloned in a bacterial artificial chromosome (BAC344H5) has been shown to contain all of the cis-elements necessary for position-independent, copy-dependent and tissue-specific expression in transgenic mice. The insert from this BAC was sequenced. This revealed the presence of two other genes with quite different expression patterns in pig tissues and in transfected HC11 mouse mammary cells. The RAMP3 gene is located 15 kb upstream of the WAP gene in reverse orientation. The CPR2 gene is located 5 kb downstream of the WAP gene in the same orientation. The same locus organization was found in the human genome. The region between RAMP3 and CPR2 in the human genome contains a WAP gene-like sequence with several points of mutation which may account for the absence of WAP from human milk.     

Dorsal telencephalon-specific expression of Cre recombinase in PAC transgenic mice

The ability to restrict gene expression or disruption to specific regions of the brain would enhance understanding of the molecular basis for brain development and function. For this purpose, brain region-restricted promoters are essential. Here we report the isolation of a DNA fragment containing the Emx1 gene promoter, which is responsible for dorsal telencephalon-specific expression. The Cre recombinase gene was inserted into a mouse PAC (P1-derived artificial chromosome) Emx1-locus clone (PAC-Emx1#1 clone) and utilized to generate three transgenic mouse lines. In all three lines, especially Tg3, Cre-mediated recombination was highly restricted to Emx1-expressing cell lineages, from embryonic stages to adulthood. Immunohistochemical analyses showed that Cre protein is expressed in the dorsal telencephalon in all three lines in adulthood. Thus, the PAC-Emx1#1 clone contains essentially all regulatory elements necessary for Emx1 gene expression. Our results suggest that Emx1-Cre Tg3 mice and the PAC-Emx1#1 clone constitute powerful tools for dorsal telencephalon-specific gene manipulation.     

Transgene insertion on mouse chromosome 6 impairs function of the uterine cervix and causes failure of parturition

The molecular mechanisms controlling the initiation of parturition remain largely undefined. We report a new animal model in which parturition does not occur. A line of mice expressing a human apolipoprotein B (APOB) gene fail to deliver their young if the transgene is present in homozygous (Tg/Tg), but not in heterozygous (Tg/Wt), form. Cloning and mapping of the transgene insertion locus indicate that 10 copies of the 80-kilobase APOB genomic fragment inserted into mouse chromosome 6 result in a small, 390-base pair deletion of mouse genomic DNA. Nine other lines expressing the transgene have normal labor, suggesting that transgene insertion in this mutant line disrupted a mouse gene crucial for successful parturition. The pathophysiology of parturition failure in these animals was defined using physiological, endocrinological, and morphological techniques. Results indicate that luteolysis occurs in Tg/Tg mice but is delayed by 1 day. Delivery did not occur in mutant mice at term after spontaneous luteolysis or even after removal of progesterone action by ovariectomy or antiprogestin treatment. Biomechanical and functional studies of the uterus and cervix revealed that the primary cause of failed parturition in Tg/Tg mice was not inadequate uterine contractions of labor but, rather, a rigid, inelastic cervix at term that was abnormally rich in neutrophils and tissue monocytes. Characterization of the transgene insertional mutant, Tg/Tg, indicates that progesterone withdrawal is insufficient to complete parturition in the presence of inadequate cervical ripening at term.     

Chromosomal localization and molecular organization of human genomic fragment containing TNF/LT locus in transgenic mice

Molecular organization, copy number and chromosomal localization of human TNF/LT locus fragment were determined in genomes of two transgenic mouse lines. Genome of the first one contains two copies, organized in head-to-tail manner and determined on eighth chromosome by karyotyping; single transgene copy of the second line is observed on the fifth chromosome. These mice could serve as valuable model for studying both human tumor necrosis factor and lymphotoxin physiological functions.     

荧光转基因斑马鱼Tg(ttn.2:EGFP)的构建

为了建立一种用于研究肌肉和心脏发育及其相关疾病的绿色荧光蛋白(enhanced green fluorescent protein,EGFP)转基因斑马鱼品系,本研究使用斑马鱼ttn.2基因编码区上游启动子序列和绿色荧光蛋白基因编码序列构建了重组表达载体,并将该载体和Tol2转座酶的加帽mRNA显微共注射入斑马鱼1-细胞期胚胎,通过荧光检测、遗传杂交筛选和分子鉴定等方法,成功建立了能稳定遗传的Tg(ttn.2:EGFP)转基因斑马鱼品系。荧光表达分析及原位杂交分析结果表明,绿色荧光信号在斑马鱼肌肉和心脏组织中特异表达模式与ttn.2基因的mRNA表达一致。通过反向PCR鉴定转基因表达载体在F1代斑马鱼品系中的随机整合位点,结果表明:No.33转基因品系的EGFP基因整合在斑马鱼的4号和11号染色体上,No.34转基因品系则整合在1号染色体上。该荧光转基因斑马鱼品系Tg(ttn.2:EGFP)的成功构建为肌肉和心脏发育以及相关疾病研究提供了一个新的理想实验模型。此外,绿色荧光强烈表达的斑马鱼品系还可以作为一种新的观赏鱼。     

The human growth hormone gene cluster locus control region supports position-independent pituitary- and placenta-specific expression in the transgenic mouse

The human growth hormone (hGH) cluster contains five genes. The hGH-N gene is predominantly expressed in pituitary somatotropes, whereas the remaining four genes, the chorionic somatomammotropin genes (hCS-L, hCS-A, and hCS-B) and hGH-V, are expressed selectively in the placenta. In contrast, the mouse genome contains a single pituitary-specific GH gene and lacks any GH-related CS genes. Activation of the hGH transgene in the mouse is dependent on its linkage to a previously described locus control region (LCR) located -15 to -32 kilobases upstream of the hGH cluster. The sporadic, nonreproducible expression of hCS transgenes lacking the LCR suggests that they may be dependent on hGH LCR activity as well. To determine whether the hCS genes could be expressed with appropriate placental specificity, a series of five transgenic mouse lines carrying an 87-kilobase human genomic insert encompassing the majority of the hGH gene cluster and the entire contiguous LCR was established. All of the hGH cluster genes were appropriately expressed in each of these lines. High level expression of hGH was restricted to the pituitary and hCS to the labyrinthine layer of the placenta. The expression of the GH cluster genes in their respective tissues paralleled transgene copy numbers irrespective of the transgene insertion site in the host mouse genome. These studies have extended the utility of the transgenic mouse model for the analysis of the full spectrum of hGH gene cluster activation. Further, they support a role for the hGH LCR in placental hCS, as well as pituitary hGH gene activation, and expression.     

Localization of the human thyroxine-binding globulin gene to the long arm of the X chromosome (Xq21-22).

Thyroxine-binding globulin (TBG) is the major thyroid-hormone transport protein in the plasma of most vertebrate species. A recombinant phage (lambda cTBG8) containing a cDNA insert of human TBG recently has been described. With the cDNA insert from lambda cTBG8 used as a radiolabeled probe, DNA from a series of somatic-cell hybrids containing deletions of the X chromosome was analyzed by means of blot hybridization. The results indicated that the TBG gene is located in the midportion of the long arm of the X chromosome between bands Xq11 and Xq23. The gene then was mapped to band region Xq21-22 by means of in situ hybridization to metaphase chromosomes. Sequences on the X chromosome that are homologous to the cDNA probe are contained within a single EcoRI restriction fragment of 12.5 kb in human DNA. On the basis of the intensity of the hybridization signal on Southern blots, it was determined that the human TBG cDNA probe used in the present study shares significant homology with hamster and mouse sequences. A single EcoRI restriction fragment was recognized in both hamster (8.0-kb) and mouse (5.1-kb) DNA.     

Chromosomal localization of zinc finger protein genes in man and mouse

We have determined the mouse and human chromosomal location of a gene (Zfp-3) that codes for a protein that contains potential DNA zinc-binding fingers. An analysis of the segregation of restriction fragment length polymorphisms in recombinant inbred strains and in an interspecific backcross demonstrated that Zfp-3 is located on mouse chromosome 11. Zfp-3 is very closely linked to the Trp53-1 locus but unlinked to another finger protein gene Zfp-4 located on mouse chromosome 8. In humans ZFP3 has been localized to chromosome 17p12-17pter and thus is part of the conserved linkage group between this chromosome and the distal half of mouse chromosome 11.     

The Genomic Structure of an Insertional Mutation in the Dystonia Musculorum Locus

We have previously identified a line of transgenic mice, Tg4, in which an hsp68-lacZ hybrid gene has inserted into the dystonia musculorum (dt) locus on chromosome 1. We have confirmed the localization of the Tg4 integration site to the proximal region of mouse chromosome 1 by interspecific backcross analysis. One end of the integration complex has been cloned and we have used single-copy probes from the flanking region to screen a mouse genomic library. Several overlapping lambda phage clones have been isolated and arranged into a contig spanning 75 kb of genomic DNA. Probes from the genomic contig have enabled us to characterize the wildtype and Tg4 loci. We report that the integration of the transgene was accompanied by a deletion of 45 kb of host genomic sequences with no other detectable rearrangement in the Tg4 genome.     

Hyperinsulinemia in transgenic mice carrying multiple copies of the human insulin gene

We are investigating human insulin gene expression in transgenic mice. An 8.8 kilobase (kb) human genomic DNA fragment, including the insulin gene (1.4 kb) and 2 kb of 5' human flanking sequences, was introduced into mouse embryos by pronuclear microinjection. Two lines of transgenic mice have been established, both of which carry the intact human gene in multiple copies. Animals from both lines have significantly higher insulin levels than control mice, and the degree of hyperinsulinemia shows a positive correlation with human gene copy number in the two lines. Expression of the human gene is confirmed by the detection of human C-peptide in plasma. Tissue specificity of expression is maintained, with human insulin mRNA detectable only in the pancreas. The transgenics maintain normal fasting blood glucose in spite of their high insulin levels, but preliminary studies show them to be glucose intolerant when given a glucose load. These mice provide a model system for further studies on the regulation of insulin gene expression and on the effects of chronic hyperinsulinemia on glucose homeostasis.     

Human BAC-mediated rescue of the Friedreich ataxia knockout mutation in transgenic mice

Three independent transgenic mouse lines were generated with the human Friedreich ataxia gene, FRDA, in an 188-kb bacterial artificial chromosome (BAC) genomic sequence. Three copies of the transgene per diploid mouse genome were integrated in a single site in each mouse line. Transgenic mice were mated with mice heterozygous for a knockout mutation of the murine Frda gene, to generate mice homozygous for the Frda knockout mutation and hemizygous or homozygous for the human transgene. Rescue of the embryonic lethality that is associated with homozygosity for the Frda knockout mutation was observed in all three lines. Rescued mice displayed normal behavioral and biochemical parameters. RT-PCR analysis demonstrated that human FRDA mRNA is expressed in all the lines. The relative expression of the human FRDA and mouse Frda genes showed a similar pattern in different tissues in all three lines, indicating position-independent control of expression of the human FRDA transgene. However, large differences in the human:mouse mRNA ratio were observed between different tissues in all three lines. The human transgene is expressed at much higher levels in the brain, liver, and skeletal muscle than the endogenous gene, while expression of the human transgene in blood is only 25–30% of the mouse gene. These studies will facilitate the development of humanized mouse models of Friedreich ataxia through introduction of a GAA trinucleotide expansion or specific known point mutations in the normal human FRDA locus and the study of the regulation of gene expression from the FRDA locus.     

The human desmin and vimentin genes are located on different chromosomes

We have used somatic cell hybrids of Chinese hamster X man and mouse X man to localize the genes (des and vim) encoding the intermediate filaments desmin and vimentin in the human genome. Southern blots of DNA prepared from each cell line were screened with hamster cDNA probes specific for des and vim genes, respectively. The single-copy human des gene is located on chromosome 2, and the single-copy human vim gene is assigned to chromosome 10. Partial restriction maps of the two human genomic loci are presented. A possible correlation of the des locus with several reported hereditary myopathies is discussed.     

Identification of a putative gamma-aminobutyric acid (GABA) receptor subunit rho2 cDNA and colocalization of the genes encoding rho2 (GABRR2) and rho1 (GABRR1) to human chromosome 6q14-q21 and mouse chromosome 4.

Screening of a genomic DNA library with a portion of the cDNA encoding the gamma-aminobutyric acid (GABA) receptor subunit rho1 identified two distinct clones. DNA sequencing revealed that one clone contained a single exon from the rho1 gene (GABBR1) while the second clone encompassed an exon with 96% identity to the rho1 gene. Screening of a human retina cDNA library with oligonucleotides specific for the exon in the second clone identified a 3-kb cDNA with an open reading frame of 1395 bp. The predicted amino acid sequence of this cDNA demonstrates 30 to 38% similarity to alpha, beta, gamma, and delta GABA receptor subunits and 74% similarity to the GABA rho1 subunit suggesting that the newly isolated cDNA encodes a new member of the rho subunit family, tentatively named GABA rho2. Polymerase chain reaction (PCR) amplification of rho1 and rho2 gene sequences from DNA of three somatic cell hybrid panels maps both genes to human chromosome 6, bands q14 to q21. Tight linkage was also demonstrated between restriction fragment length variants (RFLVs) from each rho gene and the Tsha locus on mouse chromosome 4, which is homologous to the CGA locus on human chromosome 6q12-q21. These two lines of evidence confirm that GABRR1 and newly identified GABRR2 map to the same region on human chromosome 6. This close physical association and high degree of sequence similarity raises the possibility that one rho gene arose from the other by duplication.     

Complementation of α-thalassaemia in α-globin Knockout Mice with a 191 kb Transgene Containing the Human α-Globin Locus

alpha-thalassaemia is an inherited blood disorder caused by a decrease in the synthesis of alpha-globin due to mutations in one or both of the alpha-globin genes located on human chromosome 16. A 191 kb transgene derived from a sequenced bacterial artificial chromosome (BAC) clone carrying the human alpha-globin gene cluster, together with about 100 kb of sequence upstream of DNase1 hypersensitive site HS-40 and 30 kb downstream of the alpha1-globin gene, was introduced into fertilised mouse oocytes by pronuclear microinjection. Three transgenic founder mice were obtained. Analysis of one transmitting line by fluorescent in situ hybridisation and quantitative PCR demonstrated a single copy integration of the human alpha-globin transgene on chromosome 1. Analysis of haemoglobins from the peripheral blood by cellulose acetate electrophoresis and high performance liquid chromatography (HPLC) demonstrated synthesis of human alpha-globin to about 36% of the level of each mouse alpha-globin locus. Breeding of transgenic mice with mice heterozygous for a knockout (KO) deletion of both murine alpha-globin genes showed that the human alpha-globin locus restored haemoglobin levels and red cell distribution width to normal in double heterozygous mice and significantly normalised other haematological parameters. Interestingly the human transgene also induced a significant increase in red cell production and haematocrit above wild type values. This is the first report demonstrating complementation of a murine alpha-globin KO mutation by human alpha-globin gene expression from an intact human alpha-globin locus. The transgenic mouse model described in this report should be very useful for the study of human alpha-globin gene regulation and for the development of strategies to down regulate alpha-globin production as a means of ameliorating the severity of beta-thalassaemia.     

Assigning the polymorphic human insulin gene to the short arm of chromosome 11 by chromosome sorting

Summary We have determined the subchromosomal location of the human insulin gene by analyzing DNA isolated from sorted human metaphase chromosomes. Metaphase chromosome suspensions were sorted into fractions according to relative Hoechst fluorescence intensity by the fluorescence activated chromosome sorter. The chromosomal DNA in each fraction was characterized by restriction endonuclease analysis. Initial sorts indicated that the insulin gene-containing fragment resided in a fraction containing chromosomes 9, 10, 11 and 12. Studies of cell lines that contained chromosome translocations permitted the assignment of the insulin gene to a derivative chromosome that contains portions of the short arm of chromosome 11. Simultaneous sorting of the normal homolog from this small derivative chromosome separated the two different sized insulin gene-containing restriction fragments in this individual. These data indicate that the two restriction fragments represent insulin gene polymorphism and not duplicate gene loci.     

Accumulation of human apolipoprotein E in the plasma of transgenic mice

Three separate lines of transgenic mice were created with integrated copies of an 11.1-kilobase pair human DNA fragment containing the apolipoprotein (apo) E gene. The endogenous mouse apoE gene is primarily expressed in the liver with varying levels of expression in other tissues. However, in all three transgenic lines high levels of human apoE mRNA were detected only in the kidney, with lower levels found in the liver and other tissues; despite this profile of human apoE mRNA, human apoE was found in the plasma of the transgenic mice at levels comparable to those found in human plasma. All of the human apoE in the plasma of the transgenic mice was associated with lipoproteins. These results suggest that the domain responsible for the high level of apoE expression in liver lies outside of the microinjected DNA fragment and that an ectopic site of expression of an introduced gene may be permissive for the accumulation of its protein in plasma.