多个顺式作用元件调节血管紧张素原基因表达

血管紧张素原是最强的血管活性物质——血管紧张素Ⅱ的唯一前体,在不同的生理和病理条件下,其水平各异．为了研究血管紧张素原基因表达的调控,将人血管紧张素原基因５′端侧翼序列１．２ｋｂ同氯霉素乙酰转移酶（ＣＡＴ）基因编码序列连接,构成表达载体,并且在此基础上构建５′端系列缺失的突变表达载体,用这些表达载体转染ＨｅｐＧ２和ＣＯＳ－７,确定了正负调控元件;同时应用ＤＮＡ－蛋白质凝胶泳动检测技术,发现核蛋白质与该顺式元件的结合,从而证明多个顺式作用元件调节血管紧张素原基因的表达．     

Tissue-specific and hormonal regulation of angiotensinogen minigenes in transgenic mice.

Angiotensinogen is the precursor of the potent vasoactive peptide angiotensin II, and is therefore an important determinant of blood pressure and electrolyte homeostasis. In order to map the tissue-specific and inducible enhancer elements governing angiotensinogen gene expression in transgenic mice, we constructed minigenes containing either 0.75 kb or 4 kb or 5' flanking DNA from the BALB/c angiotensinogen gene. Sequences necessary and sufficient to mediate induction by glucocorticoids, oestrogen and bacterial endotoxin were contained on the minigene bearing 0.75 kb of DNA upstream of the capsite. This construct was also able to confer tissue specificity in the majority of organs producing angiotensinogen. In the testis and salivary gland, differences between the donor (BALB/c) and recipient (Swiss) strains were responsible for the apparently aberrant expression of the minigene constructs. The genetic lesion responsible for these expression polymorphisms has been characterized using recombinant inbred mice. An EcoRI restriction fragment length polymorphism which co-segregates with the angiotensinogen expression phenotypes into many inbred mouse strains is also described.     

Tissue-specific regulation of angiotensinogen mRNA accumulation by dexamethasone

The regulation of angiotensinogen gene expression in response to adrenalectomy and dexamethasone treatment was examined in multiple rat tissues. Angiotensinogen mRNA as quantitated by slot blot hybridization utilizing an angiotensinogen cRNA probe was most abundant in the liver with levels in the brain, kidney, and adrenal of 50, 25, and 10%, respectively. No angiotensinogen mRNA was detected in testes or heart. Although no change in the quantity of angiotensinogen mRNA was found following adrenalectomy and maintenance on 0.9% saline, dexamethasone treatment of both normal and adrenalectomized rats resulted in a time-dependent and tissue-specific accumulation of angiotensinogen mRNA. In normal animals, the hepatic response to treatment was a 4.5-fold increase in angiotensinogen mRNA by 8 h which remained 2.4-fold above basal levels by 24 h. Angiotensinogen mRNA levels in the brains of normal rats treated with dexamethasone increased only 60% by 6 h and returned to basal levels by 24 h. In contrast to the increases seen in brain and liver, angiotensinogen mRNA derived from kidney did not significantly change following dexamethasone treatment. In adrenalectomized animals, the hepatic response to dexamethasone was similar to normal animals with a 3.7-fold increase by 6 h. The accumulation in brain was greater in these animals compared to normals and increased 3-fold by 8 h. Finally, dexamethasone did not significantly increase levels in the kidney. These results clearly demonstrate glucocorticoid regulation of angiotensinogen mRNA levels in liver and brain. In contrast, the kidney, an organ known to contain glucocorticoid receptors, does not respond with increased angiotensinogen mRNA levels following glucocorticoid stimulation. These studies provide the first evidence for tissue-specific differences in the control of angiotensinogen mRNA.     

Immunochemical studies on biosynthesis of rat plasma angiotensinogen and its regulation by cortisol

Glucocorticosteroid hormones increase the level of rat plasma angiotensinogen by increasing its rate of synthesis. Two forms of plasma angiotensinogen have been purified differing with respect to molecular weight and affinity to concanavalin A. Immunochemical studies using antibodies raised against the separated forms of angiotensinogen revealed cross-reactivity with both antigens. Both antibodies were able to quantitatively precipitate the angiotensinogen activity present in rat serum samples. Cortisol increased the total amount of plasma renin substrate without changing the relative amounts of both angiotensinogen forms. mRNA coding for plasma angiotensinogen was determined by in vitro translation of poly(A)-containing RNA and immunochemical analysis of translation products. Angiotensinogen mRNA could be detected in total poly(A)-containing RNA isolated from rat liver, but not in mRNA isolated from brain, although angiotensinogen has been reported to be present in the latter organ. The level of hepatic mRNA coding for plasma angiotensinogen was high in rats treated with cortisol, but not detectable in animals depleted from endogenous glucocorticosteroids by bilateral adrenalectomy.     

Evolving concepts of the intrarenal renin-angiotensin system in health and disease: contributions of molecular biology.

Previous physiological and biochemical studies suggest the existence of an endogenous renin-angiotensin system (RAS) in the kidney. However, these data cannot exclude the contribution of the circulating RAS. Proof of the local synthesis of RAS components in the kidney has been obtained recently through the use of molecular biological techniques. Using Northern blot analysis, we have demonstrated the intrarenal expression of renin, angiotensinogen, and angiotensin-converting enzyme messenger RNAs. Employing in situ hybridization histochemistry, we have localized the intrarenal tissue sites of renin and angiotensinogen messenger RNA synthesis. Renin gene expression was found in cells of the juxtaglomerular apparatus. Angiotensinogen mRNA was primarily produced in the proximal convoluted tubule with lesser amounts in glomerular tufts and vasculature. These findings led us to hypothesize that the proximal tubule is a major site of renal Ang II synthesis and that locally synthesized Ang II might directly modulate tubular function. Both genes are subject to feedback regulation. Our studies showed that Ang II exerted a stimulatory effect on angiotensinogen but a negative feedback effect on renin gene expression. Dietary NaCl restriction stimulated the expression of both genes, although the onset of renin gene activation required more prolonged sodium chloride restriction. Furthermore, our data indicated that the sodium cation, irrespective of the anion, was primarily important in regulating renal angiotensinogen mRNA levels. Our studies also showed altered intrarenal renin or angiotensinogen expressions in pathophysiological states, e.g. in experimental heart failure and the spontaneously hypertensive rat. Taken together, these data support the existence of a intrarenal RAS and suggest its potential roles in the regulation of renal function in health and disease.     

Angiotensinogen production by rat hepatoma cells in culture and analysis of its regulation by techniques of somatic cell genetics

Angiotensinogen was synthesized by cells derived from the Reuber H35 rat hepatoma. Independent clones produced similar amounts of angiotensinogen, which corresponded to about four times more than expected for normal hepatocytes. The protein was secreted rapidly but could be visualized within cells using immunofluorescence. For one clone, it is shown that maximal angiotensinogen synthesis occurred during mid-exponential growth. Somatic cell genetics techniques have been used to investigate the regulation of angiotensinogen expression. Eleven clones of dedifferentiated variant hepatoma cells that failed to produce most or all of the liver specific proteins analyzed including albumin fell into two groups: Seven clones produced only 1-3% as much angiotensinogen as the differentiated clones, and four showed a reduction to 10-30%. Clones of the latter class were the only ones among the eleven analyzed that retained the potential to give rise to revertants, showing restoration of the differentiated state. All revertants fully restored angiotensinogen production, but only some of them re-expressed albumin. Somatic hybrids between differentiated hepatoma cells and one of the variants showed a substantial reduction in angiotensinogen production, whereas for some clones, albumin synthesis was fully maintained. These results show that regulation of the expression of angiotensinogen and of a second serum protein, albumin, was independent and that angiotensinogen synthesis was a faithful indicator of the general differentiation profile of all classes of clones.     

Immunocytochemical localization of albumin,transferrin, angiotensinogen and kininogens during the initial stages of the rat liver differentiation

Summary Rat albumin, transferrin, angiotensinogen, T kininogen (TKg) and high molecular weight kininogen (HKg) gene expression was examined immunocytochemically in embryonic and fetal livers. All these plasmatic proteins, angiotensinogen excepted, are detected as early as day 11 of gestation in intestine epithelial cells and embryonic hepatocytes. Angiotensinogen becomes expressible only at day 13 of gestation. During the early fetal period, the protein immunostaining increases strikingly in parallel with the hepatocyte differentiation. Albumin and transferrin are highly expressed comparatively to kininogens and angiotensinogen. For the first time, specific HKg is demonstrated in the rat liver.     

Immunocytochemical localization of albumin, transferrin, angiotensinogen and kininogens during the initial stages of the rat liver differentiation

Rat albumin, transferrin, angiotensinogen, T kininogen (TKg) and high molecular weight kininogen (HKg) gene expression was examined immunocytochemically in embryonic and fetal livers. All these plasmatic proteins, angiotensinogen excepted, are detected as early as day 11 of gestation in intestine epithelial cells and embryonic hepatocytes. Angiotensinogen becomes expressible only at day 13 of gestation. During the early fetal period, the protein immunostaining increases strikingly in parallel with the hepatocyte differentiation. Albumin and transferrin are highly expressed comparatively to kininogens and angiotensinogen. For the first time, specific HKg is demonstrated in the rat liver.     

Effects of glucocorticoids and antiglucocorticoid on angiotensinogen production by hepatoma cells in culture

Angiotensinogen is synthesized in large amounts by Fao cells derived from the Reuber H35 rat hepatoma in a medium enriched with 5% fetal bovine serum (FBS). Treatment of FBS with dextran-coated charcoal removed endogenous steroids without modifying angiotensinogen production. This treatment allowed the study of the effects of steroids on angiotensinogen production. Hydrocortisone increased the angiotensinogen synthesis in a dose-dependent manner. The antiglucocorticoid RU 38486 did not change the basal rate of angiotensinogen production but inhibited the stimulation by hydrocortisone. Similar results were obtained with dexamethasone. Angiotensinogen biosynthesis seems to be regulated by two distinct mechanisms: (a) glucocorticoid independent, controlling the basal rate of angiotensinogen production and (b) glucocorticoid dependent, mediating the increased rate of angiotensinogen production upon glucocorticoid treatment.     

Effects of glucocorticoids and antiglucocorticoid on angiotensinogen production by hepatoma cells in culture

Summary Angiotensinogen is synthesized in large amounts by Fao cells derived from the Reuber H35 rat hepatoma in a medium enriched with 5% fetal bovine serum (FBS). Treatment of FBS with dextran-coated charcoal removed endogenous steroids without modifying angiotensinogen production. This treatment allowed the study of the effects of steroids on angiotensinogen production. Hydrocortisone increased the angiotensinogen synthesis in a dosedependent manner. The antiglucocorticoid RU 38486 did not change the basal rate of angiotensinogen production but inhibited the stimulation by hydrocortisone. Similar results were obtained with dexamethasone. Angiotensinogen biosynthesis seems to be regulated by two distinct mechanisms: (a) glucocorticoid independent, controlling the basal rate of angiotensinogen production and (b) glucocorticoid dependent, mediating the increased rate of angiotensinogen production upon glucocorticoid treatment. This work was supported in part by a grnat from Inserm (CRL 824022).     

The angiotensinogen gene of Swiss mice is closely linked to a retrovirus-like element

Angiotensinogen is cleaved by renin and angiotensin-converting enzyme to liberate the potent vasocontrictor peptide angiotensin II. We have recently identified a cis-acting genetic lesion associated with high levels of angiotensinogen mRNA in the testis and salivary gland of Swiss mice. To determine the molecular basis of this mutation, the Swiss angiotensinogen gene was cloned, and its structure was compared to that from a low-expressing strain (BALB/c). I show that a retrovirus-like element belonging to the intracisternal A-particle gene family has been inserted 9 kb upstream from the cap site of the Swiss angiotensinogen gene. This intracisternal A-particle, named IAP-Agt, segregated concordantly with angiotensinogen expression phenotypes in CXB recombinant inbred mice. However, genomic Southern analysis showed that IAP-Agt was present in some, but not all, inbred laboratory mouse strains displaying high levels of angiotensinogen gene expression. On the basis of this evolutionary evidence, it is unlikely that IAP-Agt is the cause of the angiotensinogen mutation. It is intriguing that Ren-2, the duplicated mouse renin gene, is expressed to high levels in the male salivary gland and also contains a transposed intracisternal A-particle genome.     

Tissue specific hormonal regulation of the rat angiotensinogen gene expression

Angiotensinogen is the precursor of the most potent pressor substance, angiotensin. Angiotensinogen levels are increased in some forms of human hypertension. Its levels are modulated by various factors including glucocorticoids, estrogens, and prostaglandins. We have recently reported the isolation of a human angiotensinogen cDNA clone and provided evidence for the presence of its mRNA in rat liver, brain, and heart. In this communication we report the effect of dexamethasone and estradiol on angiotensinogen mRNA levels in rat liver, brain, and heart. Our results indicate that angiotensinogen levels are increased to different extents in these three tissues as a result of glucocorticoid or estrogen administration.     

Relative contribution of promoter and intragenic sequences in the hormonal regulation of rat beta-casein transgenes

In order to identify DNA sequences responsible for the regulation beta-casein gene expression, lines of transgenic mice bearing the entire rat beta-casein gene and two rat beta-casein promoter chloramphenicol acetyltransferase (CAT) fusion genes have been established. All three transgenes have been shown previously to be regulated in a tissue- and stage specific manner. To investigate the relative contribution of promoter and intragenic sequences in the hormonal regulation of the beta-casein gene, mammary explant cultures derived from these lines of mice have now been performed, and the effects of PRL and glucocorticoids on transgene as compared with endogenous beta-casein gene expression have been quantified. After the addition of PRL to cultures performed in the presence of insulin and glucocorticoids, a 25- to 40-fold induction of endogenous mouse beta-casein mRNA was observed after 48 hr. A comparable greater than 25-fold induction of transgene expression after PRL addition was observed in explant cultures derived from a line of mice expressing the entire rat beta-casein gene. In contrast, PRL addition elicited only a 1- to 4.5-fold increase in CAT activity in cultures derived from two lines of mice bearing casein-CAT fusion genes with either 524 or 2300 base pairs of 5'-flanking DNA. In the presence of insulin, glucocorticoid or PRL addition alone increased endogenous beta-casein gene expression 2- to 2.5-fold and 5- to 10-fold, respectively, but only a 1.2- to 2.5-fold induction of CAT activity was observed for each hormone.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulated expression of chimaeric genes containing the 5''-flanking regions of human growth hormone-related genes in transiently transfected rat anterior pituitary tumor cells.

The expression and hormonal regulation of chimaeric genes containing the 5'-flanking regions of the normal human growth hormone (hGH-1), the variant hGH (hGH-2) and chorionic somatomammotropin (hCS-1) genes fused to the chloramphenicol acetyl transferase (CAT) gene has been examined after transient transfection into cultured rat pituitary (GC), and non-pituitary (HeLa and Rat 2) tumor cells. As assessed by levels of CAT activity, the hGH-1 and hCS-1 gene hybrids were expressed at 5- to 25-fold higher levels in GC cells than in HeLa or Rat 2 cells. The hGH-2 gene hybrid was expressed at very low levels in all 3 cell types. Triiodothyronine treatment of transiently transfected GC cells had little effect on CAT activity from the hGH-1 gene hybrid but increased CAT activity from the hCS-1 gene hybrid. A slight but significant increase in CAT expression was detected with both genes after dexamethasone treatment. The data indicate that elements present on the hGH-1 and hCS-1 genes' 5'-flanking DNA are required for the efficient expression of these genes in GC cells.