编码Synechococcus sp. PCC 7002 FNR 中FNR区的基因克隆及其在大肠杆菌中的表达

用ＰＣＲ的方法克隆出了编码蓝细菌Ｓｙｎｅｃｈｏｃｏｃｃｕｓｓｐ．ＰＣＣ７００２ＦＮＲ中ＦＮＲ区的基因ｐｅｔＨＬ,克隆到达载体ｐＥＴ３ａ上,转化大肠杆菌ＢＬ２１（ＤＥ３）后实现了大量表达。重组ＦＮＲ区（ｒＦＮＲＤ）经ＤＥＡＥＳｅｐｈｄｅｘＡ５０离子交换层析及ＳｅｐｈａｄｅｘＧ１００凝胶层析得到大量的电泳均一的ｒＦＮＲＤ。Ｎ末端氨基酸序列分析表明,表达产物确为ｐｅｔＨＬ所编码。且起始Ｍｅｔ翻译后未被除去。ｒＦＮＲＤ与ｒＦＮＲ的吸收光谱相同,其黄递酶活性的最适ｐＨ和最适温度也相同。ｒＦＮＲＤ能在体外催化电子从Ｐ７００到ＮＡＤＰ＋的传递     

FNRD在聚球藻7002中的表达及其性质研究

置于Lac启动子和Kan启动子控制之下的petHL基因分别转化蓝细菌Synechococcussp.PCC7002,从Southern blot分析结果推断,petHL已整合到蓝细菌染色体DNA上。Western blot分析表明,转入蓝细菌体内的petHL基因得到了表达,且Kan启动子启动该基因表达的效率高于Lac启动子。内源FNRD表现出与FNR全酶相同的稳定性。Triton X-114分相实验结果显示,部分FNRD可进入Triton X-114相,推测这些分子可能发生了脂酰化修饰。同时FNRD在体内可能参与了光合电子传递而使光合放氧速率增加。     

Role of glutathione in the formation of the active form of the oxygen sensor FNR ([4Fe-4S].FNR) and in the control of FNR function.

The oxygen sensor regulator FNR (fumarate nitrate reductase regulator) of Escherichia coli is known to be inactivated by O2 as the result of conversion of a [4Fe-4S] cluster of the protein into a [2Fe-2S] cluster. Further incubation with O2 causes loss of the [2Fe-2S] cluster and production of apoFNR. The reactions involved in cluster assembly and reductive activation of apoFNR isolated under anaerobic or aerobic conditions were studied in vivo and in vitro. In a gshA mutant of E. coli that was completely devoid of glutathione, the O2 tension for the regulatory switch for FNR-dependent gene regulation was decreased by a factor of 4-5 compared with the wild-type, suggesting a role for glutathione in FNR function. In isolated apoFNR, glutathione could be used as the reducing agent for HS- formation required for [4Fe-4S] assembly by cysteine desulfurase (NifS), and for the reduction of cysteine ligands of the FeS cluster in FNR. Air-inactivated FNR (apoFNR without FeS) could be reconstituted to [4Fe-4S].FNR by the same reaction as used for apoFNR isolated under anaerobic conditions. The in vivo effects of glutathione on FNR function and the role of glutathione in the formation of active [4Fe-4S].FNR in vitro suggest an important role for glutathione in the de novo assembly of FNR and in the reductive activation of air-oxidized FNR under anaerobic conditions.     

Phenotypic repertoire of the FNR regulatory network in Escherichia coli

The FNR protein in Escherichia coli is an O(2) sensor that modifies global gene expression to adapt the cell to anaerobic growth. Regulation of FNR involves continuous cycling of the protein between its active and inactive states under aerobic conditions without apparent function. This raises the question of what benefit to the overall life cycle might compensate for the cost of cycling and reveals that the role of this process is poorly understood. To address this problem, we introduce the concept of a 'system design space', which provides a rigorous definition of phenotype at the molecular level and a means of visualizing the phenotypic repertoire of the system. Our analysis reveals undesirable and desirable phenotypes with an optimal constellation of parameter values for the system. To facilitate a more concrete understanding of what the design space represents, we analyse mutations that alter the apparent dimerization rate constant of FNR. We show that our estimated wild-type value of this rate constant, which is difficult to measure in situ, is located within this constellation and that the behaviour of the system is compromised in mutants if the value of the apparent dimerization rate constant lies beyond the bounds of this optimal constellation.     

Isolation of intact FNR protein (Mr 30 000) of Escherichia coli

FNR, the activator of anaerobic respiratory genes of Escherichia coli, has previously only been isolated as a protein of Mr 29,000, which lacks nine N-terminal amino acid residues. The underlying proteolytic events have been studied with the aim of isolating intact FNR and determining whether cleavage is the result of a physiologically significant intracellular processing mechanism or proteolytic degradation during isolation. The FNR protein was present in aerobically and anaerobically grown bacteria as the intact protein (Mr 30,000). Proteolysis only occurred during and shortly after disruption of the bacteria. The production of FNR (Mr 29,000) must therefore be regarded as an isolation artefact. The proteolysis was caused by a protease which is located outside the cytoplasmic membrane or activated upon disruption of the membrane. Protease inhibitors directed against serine, cysteine or metalloproteases failed to prevent cleavage of FNR. In E. coli strain CAG627, proteolysis was greatly reduced making it possible to isolate FNR of Mr 30,000. The N-terminal sequence of FNR (Mr 30,000) was identical to that predicted from the fnr gene starting with the initiating methionine residue and including a four-cysteine cluster (16)Cys-X3-Cys-X2-Cys-X5-Cys(29).