Molecular basis of cell-specific endothelial nitric-oxide synthase expression in airway epithelium

Nitric oxide (NO) plays an important role in airway function, and endothelial NO synthase (eNOS) is expressed in airway epithelium. To determine the basis of cell-specific eNOS expression in airway epithelium, studies were performed in NCI-H441 human bronchiolar epithelial cells transfected with the human eNOS promoter fused to luciferase. Transfection with 1624 base pairs of sequence 5' to the initiation ATG (position -1624) yielded a 19-fold increase in promoter activity versus vector alone. No activity was found in lung fibroblasts, which do not express eNOS. 5' deletions from -1624 to -279 had modest effects on promoter activity in H441 cells. Further deletion to -248 reduced activity by 65%, and activity was lost with deletion to -79. Point mutations revealed that the GATA binding motif at -254 is mandatory for promoter activity and that the positive regulatory element between -248 and -79 is the Sp1 binding motif at -125. Electrophoretic mobility shift assays yielded two complexes with the GATA site and three with the Sp1 site. Immunodepletion with antiserum to GATA-2 prevented formation of the slowest migrating GATA complex, and antiserum to Sp1 supershifted the slowest migrating Sp1 complex. An electrophoretic mobility shift assay with H441 versus fibroblast nuclei revealed that the slowest migrating GATA complex is unique to airway epithelium. Thus, cell-specific eNOS expression in airway epithelium is dependent on the interaction of GATA-2 with the core eNOS promoter, and the proximal Sp1 binding site is also an important positive regulatory element.     

人β—簇珠蛋白基因LCR调控元件中HS3与反式调控因子相互作用的研究

Upstream of the human epsilon-globin gene is the Locus Control Region (LCR) of the human beta-globin cluster, which consists of four DNase-I hypersensitive sites(HS1-HS4). It has been reported in transgenic experiments that HS3 preferentially regulates epsilon-globin gene expression. In order to elucidate the regulatory function of HS3 in the expression of globin gene, nuclear extracts from mouse hematopoietic tissues at several developmental stages were prepared and the binding of the nuclear factors to HS3 was analysed by using electrophoresis mobility shift assay(EMSA). Our results showed that the binding patterns of HS3 with nuclear extracts of mouse hematopoietic tissues at day 13 and day 18 of gestation were completely different; furthermore, by Southwestern Blot, the distinction between both stages was also demonstrated. It has been known that GATA and CACCC binding motifs are contained within HS3 core region. Using competitive gel-retardation assay, we found that no shift bands could be competed by using CACCC motif as a competitor. However one shift band at day 13 and day 18 of gestation could be competed respectively by using GATA motif as a competitor. We suggested that the shift bands, which could not be competed by both motifs, might be novel and stage-specific factors. In addition, by using Western Blot, we demonstrated that the two shift bands at day 13 and day 18 of gestation, competed by GATA motif, were GATA-2 and GATA-1 respectively: GATA-1 was expressed in mouse hematopoietic tissues at day 18 of gestation and not expressed at day 13 of gestation; however, GATA-2 was only expressed in mouse hematopoietic tissues at day 13 of gestation. According to these results, we speculated that HS3 might play an important role in regulation of stage-specific expression of globin genes through interaction between stage-specific nuclear factors and HS3.     

Complex regulation of the lactase-phlorizin hydrolase promoter by GATA-4

Lactase-phlorizin hydrolase (LPH), a marker of intestinal differentiation, is expressed in absorptive enterocytes on small intestinal villi in a tightly regulated pattern along the proximal-distal axis. The LPH promoter contains binding sites that mediate activation by members of the GATA-4, -5, and -6 subfamily, but little is known about their individual contribution to LPH regulation in vivo. Here, we show that GATA-4 is the principal GATA factor from adult mouse intestinal epithelial cells that binds to the mouse LPH promoter, and its expression is highly correlated with that of LPH mRNA in jejunum and ileum. GATA-4 cooperates with hepatocyte nuclear factor (HNF)-1alpha to synergistically activate the LPH promoter by a mechanism identical to that previously characterized for GATA-5/HNF-1alpha, requiring physical association between GATA-4 and HNF-1alpha and intact HNF-1 binding sites on the LPH promoter. GATA-4 also activates the LPH promoter independently of HNF-1alpha, in contrast to GATA-5, which is unable to activate the LPH promoter in the absence of HNF-1alpha. GATA-4-specific activation requires intact GATA binding sites on the LPH promoter and was mapped by domain-swapping experiments to the zinc finger and basic regions. However, the difference in the capacity between GATA-4 and GATA-5 to activate the LPH promoter was not due to a difference in affinity for binding to GATA binding sites on the LPH promoter. These data indicate that GATA-4 is a key regulator of LPH gene expression that may function through an evolutionarily conserved mechanism involving cooperativity with an HNF-1alpha and/or a GATA-specific pathway independent of HNF-1alpha.     

羟基脲诱导前后HEL细胞内GATA转录因子与人β—类珠蛋白基因调控元件 …

HEL cells, a human erythroleukemia cell line, expressing mainly the gamma-globin genes, small amount of epsilon-globin gene, but not beta-globin gene. Our previous studies demonstrated that beta-globin gene could be expressed in HEL cells induced by hydroxyurea. However, the molecular mechenism is still unknown. Here the binding patterns of GATA factors (GATA-1 and GATA-2) to the regulatory elements of human beta-globin gene were examined with the nuclear extracts from hydroxyurea-induced and uninduced HEL cells. Our results showed in EMSA assay that GATA factors could bind to the core sequence of HS2(-10681 to -10971 bp), the 3' flanking sequence of HS2 core(-10323 to -10680 bp) and the promoter of human beta-globin gene(+20 to -112 bp). However, the binding patterns between hydroxyurea-induced and uninduced HEL cells were different. Furthermore, by using Western-blot analysis, our data showed that the amount of GATA-2 was decreased in hydroxyurea-induced HEL cells. In contrast to GATA-2, the amount of GATA-1 was increased in hydroxyurea-induced HEL cells. These results showed that the different members of GATA family might play different roles during the differentiation of erythrocytes. GATA-1 may stimulate the differentiation of HEL cells, while GATA-2 can probably inhibit the differentiation of HEL cells.