Küpper Hendrik, Ferimazova Naila, Setlík Ivan, Berman-Frank Ilana
Mathematisch-Naturwissenschaftliche Sektion, Fachbereich Biologie, Universität Konstanz, D-78457 Konstanz, Germany.
Plant Physiol. 2004 Aug;135(4):2120-33. doi: 10.1104/pp.104.045963. Epub 2004 Aug 6.
We investigated interactions between photosynthesis and nitrogen fixation in the non-heterocystous marine cyanobacterium Trichodesmium IMS101 at the single-cell level by two-dimensional (imaging) microscopic measurements of chlorophyll fluorescence kinetics. Nitrogen fixation was closely associated with the appearance of cells with high basic fluorescence yield (F(0)), termed bright cells. In cultures aerated with normal air, both nitrogen fixation and bright cells appeared in the middle of the light phase. In cultures aerated with 5% oxygen, both processes occurred at a low level throughout most of the day. Under 50% oxygen, nitrogen fixation commenced at the beginning of the light phase but declined soon afterwards. Rapid reversible switches between fluorescence levels were observed, which indicated that the elevated F(0) of the bright cells originates from reversible uncoupling of the photosystem II (PSII) antenna from the PSII reaction center. Two physiologically distinct types of bright cells were observed. Type I had about double F(0) compared to the normal F(0) in the dark phase and a PSII activity, measured as variable fluorescence (F(v) = F(m) - F(0)), similar to normal non-diazotrophic cells. Correlation of type I cells with nitrogen fixation, oxygen concentration, and light suggests that this physiological state is connected to an up-regulation of the Mehler reaction, resulting in oxygen consumption despite functional PSII. Type II cells had more than three times the normal F(0) and hardly any PSII activity measurable by variable fluorescence. They did not occur under low-oxygen concentrations, but appeared under high-oxygen levels outside the diazotrophic period, suggesting that this state represents a reaction to oxidative stress not necessarily connected to nitrogen fixation. In addition to the two high-fluorescence states, cells were observed to reversibly enter a low-fluorescence state. This occurred mainly after a cell went through its bright phase and may represent a fluorescence-quenching recovery phase.
我们通过对叶绿素荧光动力学进行二维(成像)显微镜测量,在单细胞水平上研究了非异形海洋蓝细菌束毛藻IMS101中光合作用与固氮作用之间的相互作用。固氮作用与具有高基础荧光产量(F(0))的细胞(称为亮细胞)的出现密切相关。在通以正常空气曝气的培养物中,固氮作用和亮细胞都出现在光照阶段的中期。在通以5%氧气曝气的培养物中,这两个过程在一天的大部分时间里都处于低水平。在50%氧气条件下,固氮作用在光照阶段开始时启动,但随后很快下降。观察到荧光水平之间的快速可逆转换,这表明亮细胞升高的F(0)源于光系统II(PSII)天线与PSII反应中心的可逆解偶联。观察到两种生理上不同类型的亮细胞。I型亮细胞在暗相中的F(0)约为正常F(0)的两倍,以可变荧光(F(v)=F(m)-F(0))测量的PSII活性与正常非固氮细胞相似。I型细胞与固氮作用、氧气浓度和光照的相关性表明,这种生理状态与梅勒反应的上调有关,尽管PSII功能正常,但仍导致氧气消耗。II型细胞的F(0)超过正常F(0)的三倍以上,几乎没有通过可变荧光测量的PSII活性。它们在低氧浓度下不会出现,但在固氮期之外的高氧水平下出现,这表明这种状态代表了对氧化应激的反应,不一定与固氮作用相关。除了这两种高荧光状态外,还观察到细胞可逆地进入低荧光状态。这主要发生在细胞经历其亮相之后,可能代表荧光猝灭恢复阶段。