Specific expression of an elastase-human growth hormone fusion gene in pancreatic acinar cells of transgenic mice

Transfection of genes into tissue culture cell lines has demonstrated that relatively short DNA sequences can allow expression of immunoglobulin, insulin and chymotrypsin genes in their appropriate cell types. A definitive test of cell-specific gene expression, however, requires testing genes in every possible cell type, an experiment performed easily by introducing the gene in question into the germ line of an animal. Transfer of intact genes into mice has demonstrated that a mouse immunoglobulin kappa gene is expressed specifically in B lymphocytes, a rat elastase I gene is expressed specifically in pancreas and a chicken transferrin gene is expressed preferentially in liver. Mouse metallothionein-growth hormone fusion genes introduced into mice are preferentially expressed in the liver, consistent with the expression of endogenous metallothionein genes, but initial experiments with beta-globin genes have not revealed proper regulation. To identify the DNA elements required for pancreas-specific expression of the rat elastase I gene, we joined the 5'-flanking region of this gene to the human growth hormone (hGH) structural gene and introduced the fusion gene into mice. Here we demonstrate that a fusion gene containing only 213 base pairs (bp) of elastase I gene sequence directs expression of hGH in pancreatic acinar cells.     

Novel developmental specificity in the nervous system of transgenic animals expressing growth hormone fusion genes

The development of methods for introducing foreign genes into the germ line of mice provides an approach for studying mechanisms underlying inducible and developmental gene regulation. Transgenic animals expressing foreign genes have thus been used to test models of the role played by specific DNA sequences in determining cell-specific expression. Results from these experiments suggest that tissue-specific expression is the consequence of a cis-acting regulatory sequence. However, these results do not exclude the possibility that cell-specific expression of some genes might be 'coded' by combinations of regulatory elements. We have previously described the production of transgenic mice from eggs microinjected with metallothionein-I/growth hormone (MGH) fusion genes, and now demonstrate that the juxtaposition of sequences from two different genes can be deciphered by cells to generate novel tissue specificities. Although expression of the endogenous metallothionein and growth hormone genes has not been detected in neuronal cells, transgenic mice clearly express an MGH fusion gene in a restricted subset of neurones. These results suggest a model in which tissue-specific patterns of expression of certain genes are determined by combinations of cis-acting regulatory sequences.     

Production of transgenic rabbits, sheep and pigs by microinjection

Direct microinjection has been used to introduce foreign DNA into a number of terminally differentiated cell types as well as embryos of several species including sea urchin, Candida elegans, Xenopus, Drosophila and mice. Various genes have been successfully introduced into mice including constructs consisting of the mouse metallothionein-I (MT) promoter/regulator region fused to either the rat or human growth hormone (hGH) structural genes. Transgenic mice harbouring such genes commonly exhibit high, metal-inducible levels of the fusion messenger RNA in several organs, substantial quantities of the foreign growth hormone in serum and enhanced growth. In addition, the gene is stably incorporated into the germ line, making the phenotype heritable. Because of the scientific importance and potential economic value of transgenic livestock containing foreign genes, we initiated studies on large animals by microinjecting the fusion gene, MT-hGH, into the pronuclei or nuclei of eggs from superovulated rabbits, sheep and pigs. We report here integration of the gene in all three species and expression of the gene in transgenic rabbits and pigs.     

Characterization of cDNA and genomic clones encoding the precursor to rat hypothalamic growth hormone-releasing factor

Growth hormone-releasing factor (GHRF) is a hypothalamic peptide which positively regulates the synthesis and secretion of growth hormone in the anterior pituitary. The amino-acid sequence of a 43-residue GHRF peptide isolated from rat hypothalamus was recently determined. Immunocytochemical techniques have been used to localize GHRF-containing cell bodies and nerve fibres largely to the medial-basal region of the rat hypothalamus. The rat has also been used extensively as an animal model to study the effects of GHRF on growth hormone synthesis and secretion and on somatic growth. To pursue questions concerning the biosynthesis of GHRF, the expression of the ghrf gene, and its regulation in the hypothalamus by neural and hormonal influences, we have now isolated and characterized both complementary DNA and genomic clones encoding rat hypothalamic GHRF. The rat ghrf gene spans nearly 10 kilobases (kb) of rat genomic DNA, contains 5 exons and encodes a 104-amino-acid precursor to the rat GHRF peptide. Comparison with previously characterized human ghrf cDNA and genomic clones has allowed patterns of conservation of amino-acid and nucleotide sequences between the human and rat GHRFs to be determined.     

Site-independent expression of the chicken beta A-globin gene in transgenic mice

The level of expression of exogenous genes carried by transgenic mice typically varies from mouse to mouse and can be quite low. This behaviour is attributed to the influence of the mouse chromatin near the site of transgene integration. This 'position effect' has been seen in transgenic mice carrying the human beta-globin gene. It was however, abolished when DNase I hypersensitive sites (normally found 65 to 44 kilobases (kb) upstream) were linked to the human beta-globin transgene. Thus, the upstream DNA (previously named a dominant control or locus activation region, now denoted a locus control region) conferred the ability to express human beta-globin at high levels dependent on copy number on every mouse carrying the construct. We report here an investigation of chicken beta A-globin gene expression in transgenic mice. A 4.5-kb fragment carrying the beta A-globin gene and its downstream enhancer, without any far upstream elements, is sufficient to ensure that every transgenic mouse expresses chicken globin messenger RNA at levels proportional to the transgene copy number. Thus the chicken DNA elements that allow position-independent expression can function in mice. In marked contrast to the human beta cluster, these elements are no farther than 2 kb from the gene. The location of the elements within the cluster demonstrates that position independence can be mediated by DNA that does not define a gene cluster boundary.     

Stimulation of food intake in rats by centrally administered hypothalamic growth hormone-releasing factor

Hypothalamic growth hormone-releasing factors (GRFs) have been purified recently from human pancreatic (hp) tumours and from rat hypothalamus (rh). GRF peptides have strong homology with peptides of the glucagon, vasoactive intestinal polypeptide and PHI-27 family. Aside from their potent actions on release of somatotropin, no other biological actions of GRFs have been reported. GRF has been localized in neurones bordering the ventromedial hypothalamic nucleus, a region associated frequently with experimental analysis of feeding behaviour. We now report that intracerebroventricularly (i.c.v.)-administered rhGRF and hpGRF(1-40) in doses of 0.2, 2.0 and 20.0 pmol, produced an increase in food intake in hungry rats. This effect seemed to be specific to GRF as i.c.v. injections of a structurally related but physiologically inactive peptide in the same doses had no effect on feeding. In addition, peripheral injections of rhGRF or growth hormone had no effect on food intake, suggesting that the present effects may be mediated centrally. Injections (i.c.v.) of rhGRF (0.2, 2.0 and 20.0 pmol) had no effect on general activity, suggesting that GRF does not produce nonspecific arousal.     

Specific expression of a foreign beta-globin gene in erythroid cells of transgenic mice

The globin gene family represents an attractive system for the study of gene regulation during mammalian development, as its expression is subject to both tissue-specific and temporal regulation. While many aspects of globin gene structure and expression have been described extensively, relatively little is known about the cis-acting DNA sequences involved in the developmental regulation of globin gene expression. To begin to experimentally define these regulatory sequences, we have taken the approach of introducing cloned globin genes into the mouse germ line and examining their expression in the resulting transgenic animals. Here we describe a series of transgenic mice carrying a hybrid mouse/human adult beta-globin gene, several of which express the gene exclusively or predominantly in erythroid tissues. These studies demonstrate that regulatory sequences closely linked to the beta-globin gene are sufficient to specify a correct pattern of tissue-specific expression in a developing mouse, when the gene is integrated at a subset of foreign chromosomal positions.     

cDNA sequence and chromosomal localization of human platelet-derived growth factor A-chain and its expression in tumour cell lines

The amino-acid sequence of the precursor of the human tumour cell line-derived platelet-derived growth factor (PDGF) A-chain has been deduced from complementary DNA clones and the gene localized to chromosome 7. The protein shows extensive homology to the PDGF B-chain precursor. Expression of the PDGF A-chain gene is independent of that of the PDGF B-chain in a number of human tumour cell lines, and secretion of a PDGF-like growth factor of relative molecular mass 31,000 correlates with expression of A- but not B-chain messenger RNA.     

High expression of human serum albumin in milk of trans- genie mice directed by the goat p-casein gene promoter region

We have constructed a mammary gland expression vector that contained the goat β-casein gene pro-moter, 5'upstream regulatory region, exons 1, 2, intron 1 as well as the human serum albumin (hALB) mini-gene (including the full-long sequences of hALB cDNA and its intron 1). Injection of the vector into mouse tail veins showed that the recombinant construct was expressed only in mammary glands. The vector was microinjected into the mouse fertilized eggs, followed by transferring the eggs into the foster mice. 33 F0 mice were obtained. Of the 33, 8 mice (5 , 3 ) were transgenic with hALB gene integration identified by PCR as well as Southern blot hybridization. The integration rate was 24.2% (8/33). Western blot analysis showed that 3 female transgenic mice had hALB expression in their milk. The hALB contents in milk reached 3.54, 0.21 and 3.03 g/L, respectively.     

Effect of HS2 and HS3 elements on erythroid-specific expression in transgenic mice

The expression plasmids CMV/GFP, HS2ALL, HS3ALL and HS23ALL were selected to investigate the effect of HS2 and HS3 element on erythroid-specific expression in transgenic mice. These plasmids were digested with restriction enzymes and purified. And five DNA fragments, CMV/GFP, HS2/GFP, CMV/HS2/GFP, HS23/GFP and HS3/GFP were obtained. After purification, the above DNA fragments were microinjected into the pre-nuclei of the mice fertilized eggs and transgenic mice were generated, with an integration rate of 10.89%. The green fluorescence protein(GFP) expression in many transgenic mouse tissues was determined by FACS analysis. The results showed that the HS2 and 1.7 kb of β-globin gene promoter were sufficient for the erythroid-specific expression of β-globin gene. The GFP expression of different recombinant constructs was also analyzed in blood of all the transgenic mice with FACS. The results indicated that HS2 and HS3 had the same enhancement activity on the regulation of β-globin gene expression. Moreover, these two elements showed a significant synergistic effect on gene expression at the transgenic mouse level, although the GFP expression varied largely among different transgenic mouse litters.     

Binding sites for growth hormone releasing factor on rat anterior pituitary cells

Growth hormone releasing factors (GRFs) have been isolated from human pancreatic tumours (hGRF) and rat hypothalamus (rhGRF). The response to GRF at the pituitary level can be modulated by other factors, including glucocorticoids, thyroid hormones, somatostatin and other neuropeptides and somatomedins. Glucocorticoids enhance GRF-induced growth hormone (GH) secretion in primary cultures of rat anterior pituitary cells, and the synthetic glucocorticoid dexamethasone has recently been shown to increase the amounts of GH released in freely moving rats in response to submaximal doses of intravenous GRF. To investigate whether somatotroph sensitivity to GRF is modulated at its receptor level, we have developed a radioreceptor assay using an iodinated analogue of hGRF as radioligand. We report here that the relative binding affinities of rGRF, hGRF and the two analogues are correlated with their in vitro biological potencies. Further, the number of GRF binding sites is drastically decreased in cells deprived of glucocorticoids either in vivo or in vitro.     

Regulation of human insulin gene expression in transgenic mice

Insulin is a polypeptide hormone of major physiological importance in the regulation of fuel homeostasis in animals (reviewed in refs 1,2). It is synthesized by the beta-cells of pancreatic islets, and circulating insulin levels are regulated by several small molecules, notably glucose, amino acids, fatty acids and certain pharmacological agents. Insulin consists of two polypeptide chains (A and B, linked by disulphide bonds) that are derived from the proteolytic cleavage of proinsulin, generating equimolar amounts of the mature insulin and a connecting peptide (C-peptide). Humans, like most vertebrates, contain one proinsulin gene, although several species, including mice and rats, have two highly homologous insulin genes. We have studied the regulation of serum insulin levels and of insulin gene expression by generating a series of transgenic mice containing the human insulin gene. We report here that the human insulin gene is expressed in a tissue-specific manner in the islets of these transgenic mice, and that serum human insulin levels are properly regulated by glucose, amino acids and tolbutamide, an oral hypoglycaemic agent.     

MT—hGH基因注入小鼠受精卵的研究

用显微注射法，将MT－hGH融合基因注入昆明白小鼠受精卵雄原核中，受注的原核卵经体外培养发育的198枚2细胞胚、45枚桑椹胚和161枚胚泡，移植到54只假孕受体，其中16只妊娠产仔只，存活到供试的仔鼠25只，小鼠长到3个月后，切尾制备DNA，经DNA斑点杂交和Southern印迹杂交检测基因整合情况，25只小鼠中3只有融合基因整合，称为转基因小鼠，仔鼠21日龄离乳后饮水中加入锌（Za^ )，以诱导融合基因表达，85日龄时，转基因小鼠体重比对照组重32．0％，还讨论了基因整合方式对胚胎发育的影响。     

A prolactin-inhibiting factor within the precursor for human gonadotropin-releasing hormone

The cloned complementary DNA sequence encoding the human gonadotropin-releasing hormone (GnRH) precursor protein was used to construct an expression vector for the bacterial synthesis of the 56-amino acid GnRH-associated peptide (GAP). GAP was found to be a potent inhibitor of prolactin secretion and to stimulate the release of gonadotropins in rat pituitary cell cultures. Active immunization with peptides corresponding to GAP sequences led to greatly increased prolactin secretion in rabbits.     

转基因动物检测方法的比较研究

用兔乳清酸性蛋白基因启动子及其远端上游区、免乳清酸性蛋白基因终止子及人瘦蛋白基因cDNA经一系列的亚克隆(Subcloning)构建了用于在转基因动物乳腺中表达人瘦蛋白的特异性表达载体，并采用显微注射的方法制作转基因小鼠动物模型。本文报道在检测转基因小鼠时出现的问题及其解决方案。     

High expression of human serum albumin in milk of transgenic mice directed by the goat β-casein gene promoter region

We have constructed a mammary gland expression vector that contained the goat β-casein gene promoter, 5′upstream regulatory region, exons 1,2, intron 1 as well as the human serum albumin (hALB) mini-gene (including the full-long sequences of hALB cDNA and its intron 1). Injection of the vector into mouse tail veins showed that the recombinant construct was expressed only in mammary glands. The vector was microinjected into the mouse fertilized eggs, followed by transferring the eggs into the foster mice. 33 F₀ mice were obtained. Of the 33, 8 mice (5♀, 3 ♂) were transgenic with hALB gene integration identified by PCR as well as Southern blot hybridization. The integration rate was 24.2% (8/33). Western blot analysis showed that 3 female transgenic mice had hALB expression in their milk. The hALB contents in milk reached 3.54, 0.21 and 3.03 g/L, respectively.     

Developmental regulation of a cloned adult beta-globin gene in transgenic mice

At different stages of mammalian development, distinct embryonic, fetal and adult haemoglobins are synthesized in erythroid cells, a process termed haemoglobin switching. The cellular and molecular mechanisms controlling haemoglobin switching have been intensively studied, but remain poorly understood. To study the developmental regulation of globin gene expression, we have produced transgenic mice in which cloned globin genes are present in erythroid cells throughout development. Recently, we reported that adult mice in several transgenic lines carrying a hybrid mouse/human adult beta-globin gene, expressed the gene in a correct tissue-specific manner. This finding raised the question of whether an exogenous globin gene could also be subject to appropriate stage-specific regulation. We report here that the hybrid beta-globin gene, like the endogenous adult beta-globin genes, is inactive in yolk sac-derived embryonic erythroid cells and is expressed for the first time in fetal liver erythroid cells. Our results indicate that a stage-specific pattern of expression can be conferred by cis-acting regulatory elements closely linked to an adult beta-globin gene. They also suggest that the embryonic and adult beta-globin genes in the mouse are activated (or repressed) by distinct trans-acting regulatory factors present in embryonic, fetal and adult erythroid cells.