Charakterisierung von apoFNR, einer weiteren Form des Sauerstoffsensors FNR aus Escherichia coli und von NreB, einem potentiellen Sauerstoffsensor aus Staphylococcus carnosus

FNR (Fumarat Nitratreduktase Regulator) ist der Sauerstoffsensor aus Escherichia coli. Bisher waren zwei Formen von FNR bekannt, der aktive Zustand, ein Dimer mit je einem [4Fe4S]-Zentrum und ein inaktiver Zustand, in dem FNR als Monomer mit je einem [2Fe2S]-Zentrum vorliegt. Die Untersuchungen dieser Arbeit geben nun Hinweise, dass es mit apoFNR eine dritte physiologische Form von FNR gibt. Es wurde die Entstehung von apoFNR aus [4Fe4S]•FNR untersucht und die biochemischen Eigenschaften von apoFNR charakterisiert. ApoFNR konnte in vitro zu [4Fe4S]•FNR rekonstituiert werden, hierbei konnte die Lagphase der Rekonstitution durch Zusatz von Glutaredoxinen zum Rekonstitutionsansatz verkürzt werden. FNR, dessen Cysteinreste in vivo unter aeroben bzw. anaeroben Bedingungen mit 4-Acetamido-4´-Maleimidylstilbene-2,2´Disulfonsäure markiert wurden, zeigt auf SDS-Gelen einen Shift zu einer höheren Masse im Vergleich zu unmarkiertem FNR. Allerdings trat in aeroben Zellen eine zusätzliche Bande bei einer niedrigeren Masse auf. Es waren hier also weniger Cysteinreste markierbar. Weiterhin wurde mit NreB ein potentieller Sauerstoffsensor aus Staphylococcus carnosus untersucht. Es wurden Hinweise auf ein Eisen-Schwefel-Zentrum vom FNR-Typ als Cofaktor gefunden. Der Einbau dieses Cofaktors war abhängig von der Anwesenheit der Cysteinreste in NreB, von der Cysteindesulfurase NifSAV und von Eisenionen. Der Cofaktor war sauerstoffempfindlich und beeinflusste die Autophosphorylierung von NreB.

The NreABC system of Staphylococcus carnosus combines nitrate and oxygen sensing by an NreA,NreB sensor complex

Staphylococcus carnosus is a facultative anaerobic bacterium which features the cytoplasmic NreABC system. It is necessary for regulation of nitrate respiration and the nitrate reductase gene narG in response to oxygen and nitrate availability. NreB is a sensor kinase of a two-component system and represents the oxygen sensor of the system. It binds an oxygen labile [4Fe-4S]2+ cluster under anaerobic conditions. NreB autophosphorylates and phosphoryl transfer activates the response regulator NreC which induces narG expression. The third component of the Nre system is the nitrate receptor NreA. In this study the role of the nitrate receptor protein NreA in nitrate regulation and its functional and physiological effect on oxygen regulation and interaction with the NreBC two-component system were detected. In vivo, a reporter gene assay for measuring expression of the NreABC regulated nitrate reductase gene narG was used for quantitative evaluation of NreA function. Maximal narG expression in wild type S. carnosus required anaerobic conditions and the presence of nitrate. Deletion of nreA allowed expression of narG under aerobic conditions, and under anaerobic conditions nitrate was no longer required for maximal induction. This indicates that NreA is a nitrate regulated inhibitor of narG expression. Purified NreA and variant NreA(Y95A) inhibited the autophosphorylation of anaerobic NreB in part and completely, respectively. Neither NreA nor NreA(Y95A) stimulated dephosphorylation of NreB-phosphate, however. Inhibition of phosphorylation was relieved completely when NreA with bound nitrate (NreA•[NO3-]) was used. The same effects of NreA were monitored with aerobically isolated Fe-S-less NreB, which indicates that NreA does not have an influence on the iron-sulfur cluster of NreB. In summary, the data of this study show that NreA interacts with the oxygen sensor NreB and controls its phosphorylation level in a nitrate dependent manner. This modulation of NreB-function by NreA and nitrate results in nitrate/oxygen co-sensing by an NreA/NreB sensory unit. It transmits the regulatory signal from oxygen and nitrate in a joint signal to target promoters. Therefore, nitrate and oxygen regulation of nitrate dissimilation follows a new mode of regulation not present in other facultative anaerobic bacteria.

Using sulfur isotope fractionation to understand the atmospheric oxidation of SO 2

Sulfate aerosol plays an important but uncertain role in cloud formation and radiative forcing of the climate, and is also important for acid deposition and human health. The oxidation of SO2 to sulfate is a key reaction in determining the impact of sulfate in the environment through its effect on aerosol size distribution and composition. This thesis presents a laboratory investigation of sulfur isotope fractionation during SO2 oxidation by the most important gas-phase and heterogeneous pathways occurring in the atmosphere. The fractionation factors are then used to examine the role of sulfate formation in cloud processing of aerosol particles during the HCCT campaign in Thuringia, central Germany. The fractionation factor for the oxidation of SO2 by ·OH radicals was measured by reacting SO2 gas, with a known initial isotopic composition, with ·OH radicals generated from the photolysis of water at -25, 0, 19 and 40°C (Chapter 2). The product sulfate and the residual SO2 were collected as BaSO4 and the sulfur isotopic compositions measured with the Cameca NanoSIMS 50. The measured fractionation factor for 34S/32S during gas phase oxidation is αOH = (1.0089 ± 0.0007) − ((4 ± 5) × 10−5 )T (°C). Fractionation during oxidation by major aqueous pathways was measured by bubbling the SO2 gas through a solution of H2 O2