Time-Space Resolved Fluorescence Spectroscopy in Live Chlamydomonas Cells under Light-Harvesting Regulation

We report here a technical advancement that enables time-resolved fluorescence spectroscopy in spatially resolved domains of a living cell at low temperatures. The technique is based on a combination of the self-developed cryo-confocal microscope system and the streak-camera technology. An instrumental response time of ca. 24 ps was achieved. This technique was applied to reveal the light-harvesting dynamics in local domains within single Chlamydomonas reinhardtii cells. Organisms performing oxygenic photosynthesis, like Chlamydomonas , have evolved a regulation mechanism called state transitions (ST), which maintains the excitation balance between PSI and PSII. ST relies on the shuttling of light-harvesting chlorophyll protein complex II (LHCII) between the two PSs. In the present experiment, cells were induced either to state1, where LHCII is bound to PSII, or state2, where LHCII moved and is bound to PSI. After the induction of ST, cells were immediately cooled to ca. 80 K, where PSI and PSII show clearly separated fluorescence emission bands, enabling the visualization of these components separately. Based on kinetic analyses of the time-resolved fluorescence spectra in both PSI-rich and PSII-rich local domains, we concluded that (1) the intracellular inhomogeneity in the PSII/PSI fluorescence ratio comes from that in the PSII/PSI stoichiometry, not from that in the antenna sizes of the PSs, and (2) the antenna size of PSI in state2 cells may larger in intact cells than that of the isolated PSI-LHCI-LHCII super-complex reported so far.