Marschall C, Labrousse V, Kreimer M, Weichart D, Kolb A, Hengge-Aronis R
Department of Biology, University of Konstanz, Germany.
J Mol Biol. 1998 Feb 20;276(2):339-53. doi: 10.1006/jmbi.1997.1533.
The general stress-induced sigma subunit sigma s of Escherichia coli RNA polymerase is closely related to the vegetative sigma factor sigma 70. In view of their very similar promoter specificity in vitro, it is unclear how sigma factor selectivity in the expression of sigma s-dependent genes is generated in vivo. The csiD gene is such a strongly sigma s-dependent gene. In contrast to sigma s, which is induced in response to many different stresses, csiD, whose expression is driven from a single promoter, is induced by carbon starvation only. To our knowledge, the csiD promoter is the first characterized promoter which is not only exclusively dependent on sigma s-containing RNA polymerase (E sigma s), but also requires an activator, cAMP-CRP. In addition, leucine-responsive regulatory protein (Lrp) acts as a positive modulator of csiD expression. Also in vitro, E sigma s is more efficient than E sigma 70 in csiD promoter binding, open complex formation and run-off transcription, which might be due to the poor match of the csiD -35 region to the sigma 70 consensus and to transcription by E sigma s being less dependent on contacts in this region. By DNase I protection experiments, a cAMP-CRP binding site centered at -68.5 nucleotides upstream of the csiD transcriptional start site was identified. While cAMP-CRP stimulates E sigma 70 binding, it does not promote open complex formation by E sigma 70, but does so in conjunction with E sigma s. With linear templates, cAMP-CRP significantly stimulates E sigma s-mediated in vitro transcription, whereas transcription by E sigma 70 is negligible and hardly stimulated by cAMP-CRP. These findings may reflect different or less stringent positional requirements for an activator site for E sigma s than for E sigma 70, and indicate that cAMP-CRP contributes to sigma factor selectivity at the csiD promoter. In vitro transcription experiments with super-coiled templates, however, revealed significant cAMP-CRP-stimulated transcription also by E sigma 70. Yet, under these conditions, H-NS was found to restore E sigma s specificity by strongly interfering with cAMP-CRP/E sigma 70-dependent transcription. Lrp strongly and cooperatively binds to multiple sites located between positions -14 and -102 (in a way that suggests DNA wrapping around multiple Lrp molecules) and moderately stimulates in vitro transcription, especially with E sigma s. In summary, we conclude that the csiD promoter has an intrinsic preference for E sigma s, but that also protein factors such as cAMP-CRP, Lrp and probably H-NS as well as DNA conformation contribute to its strong E sigma s selectivity. Furthermore, this strong E sigma s preference in combination with a requirement for high concentrations of the essential activator cAMP-CRP ensures csiD expression under conditions of carbon starvation, but not other stress conditions.
大肠杆菌RNA聚合酶的一般应激诱导型σ亚基σs与营养型σ因子σ70密切相关。鉴于它们在体外具有非常相似的启动子特异性,目前尚不清楚在体内如何产生σs依赖性基因表达中的σ因子选择性。csiD基因就是这样一个强烈依赖σs的基因。与响应多种不同应激而被诱导的σs不同,csiD仅由碳饥饿诱导,其表达由单一启动子驱动。据我们所知,csiD启动子是第一个被表征的启动子,它不仅完全依赖于含σs的RNA聚合酶(Eσs),还需要一种激活剂cAMP-CRP。此外,亮氨酸响应调节蛋白(Lrp)作为csiD表达的正调节剂。同样在体外,Eσs在csiD启动子结合、开放复合物形成和延伸转录方面比Eσ70更有效,这可能是由于csiD -35区域与σ70共有序列的匹配性较差,以及Eσs转录对该区域接触的依赖性较小。通过DNase I保护实验,在csiD转录起始位点上游-68.5个核苷酸处确定了一个cAMP-CRP结合位点。虽然cAMP-CRP刺激Eσ70结合,但它不促进Eσ70形成开放复合物,而是与Eσs一起促进。对于线性模板,cAMP-CRP显著刺激Eσs介导的体外转录,而Eσ70介导的转录可忽略不计,且几乎不受cAMP-CRP刺激。这些发现可能反映了Eσs对激活剂位点的位置要求与Eσ70不同或不那么严格,并表明cAMP-CRP有助于csiD启动子处的σ因子选择性。然而,超螺旋模板的体外转录实验表明,Eσ70也能被cAMP-CRP显著刺激转录。然而,在这些条件下,发现H-NS通过强烈干扰cAMP-CRP/Eσ70依赖性转录来恢复Eσs特异性。Lrp强烈且协同地结合位于-14至-102位之间的多个位点(其方式表明DNA围绕多个Lrp分子缠绕),并适度刺激体外转录,尤其是与Eσs一起时。总之,我们得出结论,csiD启动子对Eσs具有内在偏好,但诸如cAMP-CRP、Lrp以及可能还有H-NS等蛋白质因子以及DNA构象也有助于其强烈的Eσs选择性。此外,这种对Eσs的强烈偏好与对高浓度必需激活剂cAMP-CRP的需求相结合,确保了在碳饥饿条件下而非其他应激条件下csiD的表达。
