乳腺上皮细胞特异性敲除Scrib基因杂合子小鼠的制作与鉴定

目的利用Cre．LoxP重组酶系统构建乳腺上皮细胞特异性敲除Serib基因杂合子小鼠,并进行鉴定,为进一步在动物整体水平研究Scrib基因在乳腺癌中的作用提供研究平台。方法将Scrib条件敲除杂合子小鼠（Scrib＋/ft小鼠）进行繁殖并鉴定,然后将鉴定结果为阳性的子代Scrib＋/ft小鼠与乳腺上皮细胞特异性表达Cre重组酶的MMTV．Cre纯合子小鼠进行杂交,鉴定其子代小鼠的基因型。结果成功繁育Scrib条件敲除小鼠和MMTV．Cre小鼠,并通过鉴定得到Scrib＋/ft小鼠,与MMTV-Cre小鼠杂交并繁殖,获得基因型为Scrib＋/ft;MMTVCre＋/-小鼠5只。结论本研究利用Cre．LoxP重组酶系统成功构建了乳腺上皮细胞特异性敲除Scrib基因杂合子小鼠,为进一步研究极性蛋白Scrib表达下调在乳腺癌发生中的作用提供了良好的动物模型。     

肥大软骨细胞特异性表达Cre重组酶转基因小鼠的建立

肥大软骨细胞是软骨细胞的终末分化形式,在软骨内成骨过程中发挥十分关键的作用。为了研究肥大软骨细胞在骨骼发育过程中的功能,我们构建了在8.2 kb小鼠X型胶原基因（Col10a1）启动子控制下表达Cre重组酶的转基因小鼠品系（Col10a1-8.2-Cre）。采用显微注射法将11.5 kb的转基因片段引入小鼠基因组,共注射受精卵328枚,获得子代鼠51只,经PCR基因型鉴定有3只在基因组上整合有Cre重组酶基因。PCR检测发现Col10a1-8.2-Cre转基因在含有肥大软骨细胞的组织中表达。为了检测Cre重组酶表达的强度和组织特异性,转基因小鼠与ROSA26报告小鼠交配。子代ROSA26;Col10a1-8.2-Cre双转基因小鼠LacZ染色检测的结果显示,Cre重组酶在所有的肥大软骨细胞中表达。原位杂交的结果验证Col10a1-8.2-Cre转基因表达在肥大区的上端。以上结果表明,我们建立的肥大软骨细胞特异性表达Cre重组酶的转基因小鼠品系可以作为一种遗传学工具,介导目的基因在肥大软骨细胞中的敲除。     

胰腺组织表达Cre重组酶转基因小鼠的建立及鉴定

组织特异性表达Cre重组酶的转基因小鼠是进行组织特异性基因剔除研究的重要工具。为了建立胰腺组织特异性Cre转基因小鼠,我们通过PCR克隆了大鼠胰岛素基因启动子,并用它指导Cre基因在胰岛细胞中的特异性表达。在Cre重组酶基因5′端添加了真核核糖体结合序列和核定位序列以使Cre重组酶能穿越核膜在细胞核中发挥功能;同时,在Cre基因3′端添加了含内含子的3′端人生长激素基因。表达载体经显微注射导入小鼠受精卵以建立转基因小鼠。PCR检测显示共获得7只Cre整合阳性的转基因首建者小鼠;RTPCR结果表明其中1只首建者小鼠的子代鼠在胰腺中转录了外源基因,进一步的Southern杂交结果表明,该转基因小鼠能够在胰腺中表达有功能的Cre重组酶。      

成骨细胞特异性表达Cre重组酶转基因小鼠的建立

构建了含有骨钙素基因启动子、Cre重组酶基因和人生长激素基因polyA的转基因载体pOC-Cre, 以显微注射的方法将4.6 kb的转基因片段OC-Cre导入小鼠受精卵。16只子代小鼠中经PCR和Southern杂交鉴定, 有2只小鼠携带外源基因, 整合率为12.5%。为了检测OC-Cre在转基因小鼠中表达的组织特异性, 将转基因首建者小鼠与基因组上携带有LoxP位点的条件性Smad4基因敲除小鼠交配, PCR结果显示, 仅在子代纯合型小鼠骨组织基因组中扩增出了Cre介导重组后的片段。将OC-Cre转基因小鼠与ROSA26报告小鼠交配, 利用LacZ染色对双转基因阳性子代小鼠进行检测, 结果显示Cre重组酶在成骨细胞中特异性表达并介导ROSA基因座LoxP位点间的重组。所有这些结果说明：所建立的OC-Cre转基因小鼠在成骨细胞中特异性表达Cre重组酶, 并能在体内介导成骨细胞基因组上LoxP位点间的重组, 是一种理想的研制成骨细胞特异性基因敲除小鼠的工具小鼠。     

造血干细胞特异性表达Cre重组酶转基因小鼠的建立

EDAG是在胚胎发育阶段造血干细胞特异性表达的基因.为了在早期造血组织细胞中实现相关基因的条件敲除,构建了含有早期造血组织特异性表达的EDAG启动子和Cre重组酶基因的转基因EDAG-Cre表达载体质粒.通过显微注射的方法将线性化的5.6kb的EDAG-Cre转基因片段导入小鼠受精卵细胞核,获得的新生小鼠经过PCR鉴定,常规方法培育传代.结果发现,共获得了6只阳性转基因首建鼠,其中4只已经建系并稳定传代.RT-PCR分析表明Cre重组酶基因在阳性转基因小鼠的骨髓、脾脏、胸腺、外周血以及胎肝等组织中均有表达,重组酶活性也在脾和骨髓中获得确认.EDAG-Cre重组酶转基因小鼠的建立,为研究早期造血组织以及造血干细胞特异性基因条件敲除小鼠模型的建立奠定了基础.     

海马与新皮质组织特异性GABRG2基因敲除小鼠模型的构建及其在遗传性癫痫伴热性惊厥附加症中的初步研究 *

建立基于Cre/loxp重组酶系统调控的海马和新皮质特异性GABA_A受体γ2亚基(GABRG2)基因条件基因敲除小鼠模型,为深入研究海马区和新皮质GABRG2在癫痫发生中的功能作用提供动物模型.将引进的GABRG2 ^fl/wt转基因小鼠与海马和新皮质特异性表达Cre ^+/+重组酶工具鼠分别进行繁配和鉴定,然后再将2种小鼠进行杂交并对其子代小鼠的基因型进行鉴定,其子代基因型为GABRG2 ^fl/wtCre ⁺的小鼠为构建的海马区和新皮质特异性GABRG2基因条件性敲除小鼠.利用PCR技术鉴定小鼠基因型,Real-Time PCR和Western blot技术检测GABRG2基因在小鼠海马和新皮质中的mRNA水平和蛋白质水平的表达情况.PCR结果显示子代小鼠基因型符合GABRG2 ^fl/wtCre ⁺;海马与新皮质特异性GABRG2基因敲除小鼠海马和新皮质中GABRG2的mRNA水平和蛋白质水平显著低于对照组;热造模过程中,实验组小鼠癫痫发作更明显.利用Cre/Loxp技术成功构建了海马与新皮质GABRG2基因敲除小鼠,可为进一步研究GABRG2在癫痫发生中的作用机制奠定基础.     

条件性基因敲除:骨髓细胞特异性敲除Ncol2基因小鼠的建立和基因型鉴定

Ncol2是新发现的参与免疫调节的重要因子,Ncol2基因骨髓细胞特异性敲除小鼠的建立,能够有针对性的研究Ncol2基因缺失后对免疫系统的影响。根据条件性基因敲除的原理,本文利用loxp转基因小鼠和在骨髓细胞特异性表达Cre重组酶的LysMcre小鼠,繁殖建立了骨髓细胞特异性敲除Ncol2基因的小鼠,并提供了用鼠尾做基因型鉴定的简便方法。     

海马与新皮质组织特异性GABRG2基因敲除小鼠模型的构建及其在遗传性癫痫伴热性惊厥附加症中的初步研究

建立基于Cre/loxp重组酶系统调控的海马和新皮质特异性GABA_A受体γ2亚基(GABRG2)基因条件基因敲除小鼠模型,为深入研究海马区和新皮质GABRG2在癫痫发生中的功能作用提供动物模型。将引进的GABRG2~(fl/wt)转基因小鼠与海马和新皮质特异性表达Cre~+/+重组酶工具鼠分别进行繁配和鉴定,然后再将2种小鼠进行杂交并对其子代小鼠的基因型进行鉴定,其子代基因型为GABRG2~(fl/wt)Cre~+的小鼠为构建的海马区和新皮质特异性GABRG2基因条件性敲除小鼠。利用PCR技术鉴定小鼠基因型,Real-Time PCR和Western blot技术检测GABRG2基因在小鼠海马和新皮质中的mRNA水平和蛋白质水平的表达情况。PCR结果显示子代小鼠基因型符合GABRG2~(fl/wt)Cre~+;海马与新皮质特异性GABRG2基因敲除小鼠海马和新皮质中GABRG2的mRNA水平和蛋白质水平显著低于对照组;热造模过程中,实验组小鼠癫痫发作更明显。利用Cre/Loxp技术成功构建了海马与新皮质GABRG2基因敲除小鼠,可为进一步研究GABRG2在癫痫发生中的作用机制奠定基础。     

Cre重组酶表达载体的构建及其在转基因小鼠胰腺中的表达

组织特异性表达Cre重组酶的转基因小鼠是进行组织特异性条件敲除研究的关键。采用PCR扩增大鼠胰岛素基因705bp启动子指导发胰岛细胞中特异表达;同时采用改构的Cre重组酶基因,在其5'端添加有真核核糖体结合序列和核定位序列使Cre重组酶能穿越核膜在细胞核能发挥功能;同时,为了保证原核基因Cre能在真核系统顺利表达,在其3'端添加含内含子的人生长激素基因。构建的表达载体在去除原核序列后用显微注射方法转基因小鼠,在出生的27只仔鼠中,PCR检测共获得7只Cre整合阳性的转基因小鼠,整合率26％。这种Cre转基因小鼠与基因组小携带LoxP位点的条件基因打靶小鼠交配,在胰腺组织中可以检测到Cre介导的重组,表明Cre在转基因小鼠胰腺中有表达。     

特异性检测胰腺组织表达Cre重组酶转基因小鼠的方法

利用组织特异性分子标志物启动子调控Cre重组酶,研制了6种在不同组织中特异性表达Cre重组酶的转基因小鼠.这些转基因小鼠的基因型鉴定均使用设计在Cre基因编码区的通用引物.为了特异性检测胰腺组织表达Cre重组酶的转基因小鼠,在大鼠胰岛素RIP启动子上和Cre基因上设计1对引物进行PCR扩增,并通过凝胶电泳进行分析.PCR结果显示,设计在Cre基因上的通用引物可以从6种不同组织特异性Cre重组酶转基因小鼠基因组DNA中扩增获得480 bp产物;利用本研究设计的特异性引物可以从胰腺组织表达Cre重组酶转基因小鼠基因组DNA中扩增200 bp的目的条带.这一结果表明,利用特异性引物进行PCR反应,可有效地将胰腺组织表达Cre重组酶转基因小鼠与其他多种组织的Cm重组酶转基因小鼠鉴别开来.     

Molecular identity and gene expression of aldosterone synthase cytochrome P450

11Beta-hydroxylase (CYP11B1) of bovine adrenal cortex produced corticosterone as well as aldosterone from 11-deoxycorticosterone in the presence of the mitochondrial P450 electron transport system. CYP11B1s of pig, sheep, and bullfrog, when expressed in COS-7 cells, also performed corticosterone and aldosterone production. Since these CYP11B1s are present in the zonae fasciculata and reticularis as well as in the zona glomerulosa, the zonal differentiation of steroid production may occur by the action of still-unidentified factor(s) on the enzyme-catalyzed successive oxygenations at C11- and C18-positions of steroid. In contrast, two cDNAs, one encoding 11beta-hydroxylase and the other encoding aldosterone synthase (CYP11B2), were isolated from rat, mouse, hamster, guinea pig, and human adrenals. The expression of CYP11B1 gene was regulated by cyclic AMP (cAMP)-dependent signaling, whereas that of CYP11B2 gene by calcium ion-signaling as well as cAMP-signaling. Salt-inducible protein kinase, a cAMP-induced novel protein kinase, was one of the regulators of CYP11B2 gene expression.     

Ontogeny of angiotensin II type 1 receptor and cytochrome P450(c11) in the sheep adrenal gland

In the present study we investigated the ontogeny of the expression of the type 1 angiotensin receptor (AT(1)R mRNA) and the zonal localization of AT(1)R immunoreactivity (AT(1)R-ir) and cytochrome P450(c11) (CYP11B-ir) in the sheep adrenal gland. In the adult sheep and in the fetus from as early as 90 days gestation, intense AT(1)R-ir was observed predominantly in the zona glomerulosa and to a lesser extent in the zona fasciculata, and it was not detectable in the adrenal medulla. AT(1)R mRNA decreased 4-fold between 105 days and 120 days, whereas AT(1)R mRNA levels remained relatively constant between 120 days and the newborn period. In contrast, both in the adult sheep and in the fetal sheep from as early as 90 days gestation, intense CYP11B-ir was consistently detected throughout the adrenal cortex and in steroidogenic cells that surround the central adrenal vein. In conclusion, we speculate that the presence of AT(1)R in the zona fasciculata, and the higher levels of expression of AT(1)R at around 100 days gestation, may suggest that suppression of CYP17 is mediated via AT(1)R at this time. The abundant expression of AT(1)R-ir and CYP11B-ir in the zona glomerulosa of the fetal sheep adrenal gland would also suggest that lack of angiotensin II stimulation of aldosterone secretion is not due to an absence of AT(1)R or CYP11B in the zona glomerulosa.     

Effects of dietary soy and estrous cycle on adrenal cytochrome p450 1B1 expression and DMBA metabolism in adrenal glands and livers in female Sprague-Dawley rats

Cytochrome p450 1B1 (CYP1B1) has been shown to be important in the bioactivation of 7,12-dimethylbenz[a]anthracene (DMBA) to an adrenal toxin in rats. We investigated the effects of diet and stage of estrous cycle on CYP1B1 expression in rat adrenal glands and on DMBA metabolism by rat adrenal and hepatic microsomes. Female Sprague-Dawley (SD) rats were placed on either standard soy-containing NIH-31 rat chow or soy- and alfalfa-free 5K96 diet from postnatal day (PND) 21 until sacrifice at PND50+/-5. Stage of estrous at sacrifice was assessed by vaginal cytology and confirmed by histological examination of the vagina. Dietary soy at the level present in NIH-31 diet did not affect serum estrogen and progesterone levels. Immunohistochemical analysis confirmed that CYP1B1 was exclusively expressed in the zona fasciculata and zona reticularis in adrenal cortex, which are the regions vulnerable to DMBA-induced adrenal necrosis. Adrenal CYP1B1 protein expression, 3H-DMBA depletion, and formation of DMBA-3,4-, and -8,9-dihydrodiols by adrenal microsomes were greater in animals fed 5K96 diet, and the stage of the estrous cycle affected these parameters only in the soy-free 5K96 diet. In hepatic microsomes, the formation of DMBA-3,4-dihydrodiol, 7-hydroxy- and 12-hydroxy-DMBA were lower in animals fed NIH-31 diet than in those fed 5K96 diet. Thus, dietary soy and the estrous cycle appear to regulate adrenal CYP1B1 expression and DMBA metabolism by both adrenal and hepatic microsomes. The use of different basal diets containing variable levels of soy components may affect certain toxicity assessments.     

New aspects on primary aldosteronism

The adrenal cortex synthesizes and releases steroid hormones, mainly mineralocorticoids and glucocorticoids. There is a functional zonation of the adrenal cortex and steroid synthesis is thoroughly regulated. Overproduction of aldosterone, primary aldosteronism, may be much more common than previously known and may be responsible for 10% of essential hypertension. Primary aldosteronism is characterized by autonomous production of aldosterone, suppressed renin activity, hypokalemia, and hypertension. The two most common forms are unilateral adenoma and bilateral hyperplasia. In spite of thorough clinical workup and careful histopathology it is often difficult to differentiate between adenoma and hyperplasia. The gene CYP11B2 encodes the steroid synthesizing enzymes for aldosterone production, while the genes CYP17 and CYP11B1 are needed for cortisol production. Most normal controls show expression of CYP11B2 in zona glomerulosa. Expression of CYP11B1 and CYP17 is seen in zona fasciculata and reticularis, whereas the expression of CYP21 is present in all three cortical layers. Adenomas from patients with primary aldosteronism show considerable variation in the expression of CYP11B2. Adenomas from patients with Cushing's syndrome have a strong expression of CYP11B1 and CYP17. In a patient material of 29 cases of primary aldosteronism, 4 patients had small nodules detected with expression of CYP11B2 gene. These nodules were not visualized on CT, whereas adrenal masses seen on CT in these patients showed CYP11B1 and CYP17 gene expression. This suggests that these small nodules are responsible for the aldosterone production and this is characteristic of nodular hyperplasia in patients with primary aldosteronism. In conclusion, this method to visualize mRNA gene expression of steroidogenic enzymes, and especially expression of CYP11B2, has increased the knowledge of adrenal pathophysiology. The results emphasize the value to include functional studies (venous sampling and/or scintigraphy) in the preoperative work up of patients with primary aldosteronism.     

Disorders of the aldosterone synthase and steroid 11beta-hydroxylase deficiencies

The most potent corticosteroids are 11beta-hydroxylated compounds. In humans, two cytochrome P450 isoenzymes with 11beta-hydroxylase activity, catalysing the biosynthesis of cortisol and aldosterone, are present in the adrenal cortex. CYP11B1, the gene encoding 11beta-hydroxylase (P450c11), is expressed on high levels in the zona fasciculata and is regulated by ACTH. CYP11B2, the gene encoding aldosterone synthase (P450c11Aldo), is expressed in the zona glomerulosa under primary control of the renin-angiotensin system. Aldosterone synthase has 11beta-hydroxylase activity as well as 18-hydroxylase activity and 18-oxidase activity. The substrate for CYP11B2 is 11-deoxycorticosterone, that of CYP11B1 is 11-deoxycortisol. Mutations in CYP11B1 cause congenital adrenal hyperplasia (CAH) due to 11beta-hydroxylase deficiency. This disorder is characterized by androgen excess and hypertension. Mutations in CYP11B2 cause congenital hypoaldosteronism (aldosterone synthase deficiency) which is characterized by life-threatening salt loss, failure to thrive, hyponatraemia and hyperkalaemia in early infancy. Both disorders have an autosomal recessive inheritance. Classical and nonclassical forms of 11beta-hydroxylase deficiency can be distinguished. Studies in heterozygotes for classical 11beta-hydroxylase deficiency show inconsistent results with no or only mild hormonal abnormalities (elevated plasma levels of 11-deoxycortisol after ACTH stimulation). In infants with congenital hypoaldosteronism, a comparable frequency of 18-hydroxylase deficiency (aldosterone synthase deficiency type I) and of 18-oxidase deficiency (aldosterone synthase deficiency type II) can be found. Molecular genetic studies of the CYP11B1 and CYP11B2 genes in 11beta-hydroxylase deficiency or aldosterone synthase deficiency have led to the identification of several mutations. Transfection experiments showed loss of enzyme activity in vitro. In some of the patients with 18-oxidase deficiency (aldosterone synthase deficiency type II) no mutations in the CYP11B2 gene were identified. Refined methods for steroid determination are the basis for the diagnosis of inborn errors of steroidogenesis. Molecular genetic studies are complementary; on the one hand, they have practical importance for the prenatal diagnosis of virilizing CAH forms and on the other hand, they are of theoretical importance in terms of our understanding of the functioning of cytochrome P450 enzymes. Copyrightz1999S.KargerAG, Basel     

Calf adrenocortical fasciculata cells secrete aldosterone when placed in primary culture

Aldosterone production occurs in the outer area of the adrenal cortex, the zona glomerulosa. The glucocortocoids cortisol and corticosterone, depending upon the species, are synthesized in the inner cortex, the zona fasciculata. Calf zona glomerulosa cells rapidly lose the ability to synthesize aldosterone when placed in primary culture unless they are incubated in the presence of the antioxidants butylated hydroxyanisol and selenous acid, the radioprotectant DMSO, and the cytochrome P-450 inhibitor metyrapone. In the presence of these additives, calf zona fasciculata cells in primary culture synthesize aldosterone at rates which can approach those from cells isolated from the zona glomerulosa. Calf zona glomerulosa and fasciculata cells both responded well to ACTH and angiotensin II, but the zona fasciculata cells respond very poorly compared to glomerulosa cells to increased potassium in the media. Rat zona fasciculata cells in primary culture under similar conditions did not synthesize aldesterone, suggesting that the regulation of the expression of the enzymes responsible for the biosynthesis of aldosterone in the two species is different. Two distinct cytochrome P-450 cDNAs which hydroxylate deoxycorticosterone at the 11β position have been described in the rat, human and mouse. Both cytochrome P-450 cDNAs have been cloned and expressed in non-steroidogenic cells, but only one is expressed in the zona glomerulosa and only this glomerulosa cytochrome P450 can further hydroxylate deoxycorticosterone to generate aldosterone. Two bovine adrenal cDNAs have been described with 11β-hydroxylase activity and their expression products in transiently transfected COS cells can convert deoxycorticosterone into aldosterone. Both enzymes are expressed in all zones of the adrenal cortex. Zonal regulation of aldosterone synthesis in the bovine adrenal gland may be due to an 11β-hydroxylase with aldosterone synthesizing capacity which has not yet been isolated. Alternatively, a single enzyme might be responsible for the several hydroxylations in the pathway between deoxycorticosterone and aldosterone and zonal synthesis might be controlled by unknown factors regulating the expression of C-18 hydroxylation. The incubation of zona fasciculata with antioxidants and metyrapone results in atypical expression of this activity by an unclear mechanism.