Human transferrin. Expression and iron modulation of chimeric genes in transgenic mice

Transferrin (TF) is a plasma protein that transports and is regulated by iron. The aim of this study was to characterize human TF gene sequences that respond in vivo to cellular signals affecting expression in various tissues and to iron administration. Chimeric genes were constructed containing 152, 622, and 1152 base pairs (bp) of the human TF5'-flanking region with the coding region of a reporter gene, CAT (chloramphenicol acetyltransferase), and introduced into the germ line of mice. Transgenes containing TF 5'-flanking sequences to -152 bp were expressed poorly in all tissues examined. In contrast, transgenes containing TF sequences to -622 or -1152 bp were expressed at high levels in brain and liver, greater than or equal to 1000-fold higher than tissues such as heart and testes. Liver and brain are major sites of endogenous TF mRNA synthesis, but liver mRNA levels are 10-fold higher than brain. A significant diminution of CAT enzymatic activity in liver accompanied iron administration in both TF(0.67) and TF(1.2)CAT transgenic mice, mimicking the decrease of transferrin in humans following iron overload. Levels of endogenous plasma transferrin also decreased in iron-treated transgenic mice. Transgenic mouse lines carrying human TF chimeric genes will be useful models for analyzing the regulation of human transferrin by iron and for determining the molecular basis of transferrin regulation throughout mammalian development into the aging process.     

Expression of the chicken transferrin gene in transgenic mice

The chicken transferrin gene was microinjected into the male pronucleus of fertilized mouse eggs, and the eggs were then implanted into foster mothers. Approximately 15%-30% of the offspring from the injected eggs carried chicken DNA sequences; restriction mapping indicated that multiple copies of the chicken gene had integrated into the genome in a tandem arrangement in most of the mice. Six of the seven mice studied expressed the chicken gene, and in five mice there was a 5 to 10 fold preferential expression of chicken transferrin mRNA in liver compared to that in other tissues. Chicken transferrin was secreted into the serum of five of the mice, where it reached steady state concentrations up to 67 micrograms/ml. Offspring from transgenic parents also expressed the chicken gene; in some cases the expression in offspring was very similar to the parent, but in one line expression in offspring had increased 2 to 4 fold.     

Expression of the human insulin gene in transgenic mice

Transgenic mice which specifically express the human insulin gene in the pancreatic beta cells have been obtained. Expression is demonstrated by the presence in the serum of human insulin (determined by a radioimmunoassay for the human C-peptide), the level of which increases upon glucose stimulus, and by the presence of human insulin mRNA in pancreas, but not in the other tissues tested. This result indicates that nucleotide sequences necessary for tissue-specific expression are within the transferred gene and/or in its vicinity. It also suggests that the regulatory molecules are quite similar if not identical in human and mouse.     

Expression of human transferrin can be regulated effectively by rabbit transferrin regulatory elements in transgenic mice

Human transferrin (hTF) belongs to the iron-binding glycoprotein family. It plays an important role in iron transport throughout the body. Transgenic mice are a good model to study how to produce functional hTF on a large-scale. We have improved the expression of hTF and investigated its regulatory mechanism in transgenic mice. Three expression constructs were prepared in which hTF expression was controlled by different regulatory cassettes of rabbit transferrin (rTF). hTF was secreted into serum of transgenic mice when its expression was controlled by the rTF promoter and enhancer, whereas the rTF enhancer in tandem with the rTF promoter repressed hTF secretion into milk. A significant inverse relationship between methylation of the rTF promoter and hTF expression was observed in liver, heart, mammary gland, and muscle of transgenic mice. The highest concentration of hTF was 700 μg/ml in milk.     

Expression of the human angiotensinogen gene in transgenic mice and transfected cells.

We have generated two lines of transgenic mice with integrated copies of a 14-kilobase pair (kb) human DNA fragment containing the angiotensinogen gene, which includes 1.3 kb of 5'- and 3'-flanking regions. In both transgenic lines, a considerable quantity of the correctly initiated and processed angiotensinogen mRNA was detected in the liver and it was detectable in heart. Unexpectedly, mRNA for the transgene was accumulated in the kidney, where is normally the minor source of angiotensinogen, to levels comparable to that in the liver. In addition, an in vitro transfection analysis suggested that the 1.3-kb 5'-flanking sequences are essential for expression of the angiotensinogen gene in hepatic and renal cells and that neither DNA segment within the 14-kb construct contributes significantly to repression of the gene expression in renal cells.     

Expression of a chimeric stilbene synthase gene in transgenic wheat lines

A chimeric stilbene synthase (sts)gene was transferred into wheat. Stilbene synthases play a role in the defence against fungal diseases in some plant species (e.g. groundnut or grapevine) by producing stilbenetype phytoalexins like resveratrol. Resveratrol is also claimed to have positive effects to human health. Embryogenic scutellar calli derived from immature embryos of the two commercial German spring wheat cultivars Combi and Hanno were used as target tissue for cotransformation by microprojectile delivery. The selectable marker/reporter gene constructs contained the bargene either driven by the ubiquitinpromoter from maize (pAHC 25, also containing the uidAgene driven by the ubiquitinpromoter), or by the actinpromoter (pDM 302) from rice. The cotransferred plasmid pStil 2 consisted of a grapevine stscoding region driven by the ubiquitin promoter. Eight transgenic Combi and one Hanno T_Oplant were obtained and, except one Combi T_Oplant, found to be cotransformants due to the integration of both the stsgene and the selectable marker or reporter genes. Expression of the stsgene was proven by RTPCR, and, for the first time, by detection of the stilbene synthase product resveratrol by HPLC and mass spectrometry. The stsgene was expressed in four of the seven transgenic Combi T_{_o}plants. Two of the respective T₁progenies segregated in a Mendelian manner were still expressing the gene. Investigations into methylation of the stsgene showed that in three nonexpressing progenies inactivation was paralleled by methylation.     

Tissue-specific and developmentally regulated expression of a chimeric actin-globin gene in transgenic mice.

A chimeric plasmid containing about 2/3 of the rat skeletal muscle actin gene plus 730 base pairs of its 5' flanking sequences fused to the 3' end of a human embryonic globin gene (D. Melloul, B. Aloni, J. Calvo, D. Yaffe, and U. Nudel, EMBO J. 3:983-990, 1984) was inserted into mice by microinjection into fertilized eggs. Eleven transgenic mice carrying the chimeric gene with or without plasmid pBR322 DNA sequences were identified. The majority of these mice transmitted the injected DNA to about 50% of their progeny. However, in transgenic mouse CV1, transmission to progeny was associated with amplification or deletion of the injected DNA sequences, while in transgenic mouse CV4 transmission was distorted, probably as a result of insertional mutagenesis. Tissue-specific expression was dependent on the removal of the vector DNA sequences from the chimeric gene sequences prior to microinjection. None of the transgenic mice carrying the chimeric gene together with plasmid pBR322 sequences expressed the introduced gene in striated muscles. In contrast, the six transgenic mice carrying the chimeric gene sequences alone expressed the inserted gene specifically in skeletal and cardiac muscles. Moreover, expression of the chimeric gene was not only tissue specific, but also developmentally regulated. Similar to the endogenous skeletal muscle actin gene, the chimeric gene was expressed at a relatively high level in cardiac muscle of neonatal mice and at a significantly lower level in adult cardiac muscle. These results indicate that the injected DNA included sufficient cis-acting control elements for its tissue-specific and developmentally regulated expression in transgenic mice.     

Expression of a functional mouse-human chimeric anti-CD19 antibody in the milk of transgenic mice

Human B cell lymphomas are suitable targets for immunotherapy. Clinical trials with mouse-human chimeric B cell-specific monoclonal antibodies (mAbs) have already shown promising results. However, limitations for their use in clinical trials can be the lack of sufficient amounts and high production costs. Expression of mAbs in the mammary gland of transgenic animals provides an economically advantageous possibility for production of sufficient quantities of a promising antibody for clinical trials and beyond. In this paper, we show the feasibility of this approach, by generating transgenic mice expressing mouse-human chimeric anti-CD19 mAbs in their milk. Mouse anti-CD19 variable (V) region genes were combined with human IgG1 heavy (H) and kappa light (L) chain constant (C) region genes and fused to the bovine -lactoglobulin (BLG) promoter in two separate expression cassettes. Co-injection resulted in five transgenic lines. In one of these lines completely assembled chimeric mAbs were secreted into the milk, at an approximate level of 0.5mg/ml. These mAbs were able to bind specifically to the CD19 surface antigen on human B cells.     

Expression of a chimeric nitrate reductase gene in transgenic lettuce reduces nitrate in leaves

 Transgenic plants of four glasshouse-grown lettuce cultivars ('Cortina', 'Evola', 'Flora' and 'Luxor') were obtained by co-cultivating excised cotyledons with Agrobacterium tumefaciens. The Agrobacterium strain LBA4404 contained the binary vector pBCSL16, which carried a nitrate reductase (nia) cDNA linked to CaMV promoter and terminator sequences, and the neomycin phosphotransferase II (nptII) gene. Transformed shoots were selected by their ability to root on medium containing kanamycin sulphate, by a positive NPTII assay and by PCR analysis. The presence of the nia cDNA in transgenic lettuce was confirmed by nitrate reductase (NR) enzymatic assay, a reduction in the nitrate content of leaves and by Southern hybridisation. PCR analysis of cDNA fragments from transgenic plants confirmed that both nia and nptII genes were expressed in first seed-generation (T1) lettuce plants. The commercial importance of reduced nitrate concentrations in lettuce is discussed. Received: 7 January 1998 / Revision received: 24 February 1998 / Accepted: 22 March 1999     

Expression of the human insulin gene in the gastric G cells of transgenic mice

The goal of this study was to engineer gastrin-producing G cells of the gastric antrum to produce insulin. A pGas-Ins chimeric gene in which the gastrin promoter drives expression of the human insulin gene was constructed and was validated by transient transfection of GH4 and AGS cells. RT-PCR analysis and sequencing revealed three forms of differentially spliced insulin mRNA in GH4 cells transiently transfected by pGas-Ins. Gas-Ins transgenic mice were generated utilizing this chimeric gene. Northern blot analysis, in situ hybridization, and immunohistochemistry demonstrated expression of the human insulin gene specifically in antral G cells. Northern blot analysis demonstrated that the shortest of the insulin mRNA three forms is predominantly expressed in stomach tissue. RT-PCR analysis also showed expression of the transgene in colon, pancreas, and brain tissues that was undetectable by northern analysis. We conclude that gastrin promoter can be used for targeting expression of human insulin to antral G cells and that antral G cells can express human insulin. Further refining of the chimeric gene design is required to enhance expression.     

Bovine prolactin promotes the expression of human transferrin in the milk of transgenic mice

The bovine prolactin vector was injected directly into the mammary glands of mice carrying the human transferrin transgene to investigate its effect on the production of human transferrin in milk. The mean levels of human transferrin in two experimental groups were increased by approx. 60% compared with the control group: 1143 ± 196 ng/ml (experimental group 1; two injections) and 1160 ± 189 ng/ml (experimental group 2; three injections) versus 714 ± 75 ng/ml (control group). These findings suggest the potential utility of the prolactin vector for efficient expression of valuable pharmaceutical proteins in transgenic animal mammary glands.     

Expression of a chimeric CaMV 35S Bacillus thuringiensis insecticidal protein gene in transgenic tobacco

Insecticidal transgenic tobacco plants containing a truncated Bacillus thuringiensis cryIA(b) crystal protein (ICP) gene expressed from the CaMV 35S promoter were analyzed for ICP gene expression under field and greenhouse conditions over the course of a growing season. We present new information on temporal and tissue-specific expression of a CaMV 35S/cryIA(b) gene. Levels of cryIA(b) protein and mRNA were compared in both homozygous and hemizygous lines throughout plant development. Levels of ICP mRNA and protein increased during plant development with a pronounced rise in expression at the time of flowering. Homozygous ICP lines produced higher levels of ICP than the corresponding hemizygous lines. ELISA analysis of different tissues in the tobacco plant showed ICP gene expression in most tissues with a predominance of ICP in older tissue. All transgenic ICP tobacco lines which were studied in the field and greenhouse contained 400 ng to 1 g ICP per gram fresh weight in leaves from the mid-section of the plant at flowering. The amounts of ICP produced by field lines were directly comparable to levels observed in greenhouse-grown plants.     

Expression of a chimeric CaMV 35S Bacillus thuringiensis insecticidal protein gene in transgenic tobacco

Erratum

Expression of a chimeric CaMV 35S Bacillus thuringiensis insecticidal protein gene in transgenic tobacco