•Heterocysts of morphologically and genetically distinct species are compared.•Absorption and fluorescence of photostnthetic complexes were obtained in single cells.•Photosystem I and phycocyanin are associated in the heterocyst of Rivularia.•Photosystem I is relatively stand-alone in the whole Anabaena variabilis.•Residuals of former heterocysts of Rivularia are spectroscopically characterized.Heterocyst is a nitrogen-fixing cell differentiated from a cell for oxygen-evolving photosynthesis (vegetative cell) in some filamentous cyanobacteria when fixed nitrogen (e.g., ammonia and nitrate) is limited. Heterocysts appear at multiple separated positions in a single filament with an interval of 10–20 cells in some genera (including Anabaena variabilis). In other genera, a single heterocyst appears only at the basal terminal in a filament (including Rivularia M-261). Such morphological diversity may necessitate different properties of heterocysts. However, possible differences in heterocysts have largely remained unexplored due to the minority of heterocysts among major vegetative cells. Here, we have applied spectroscopic microscopy to Rivularia and A. variabilis to analyze their thylakoid membranes in individual cells. Absorption and fluorescence spectral imaging enabled us to estimate concentrations and interconnections of key photosynthetic components like photosystem I (PSI), photosystem II (PSII) and subunits of light-harvesting phycobilisome including phycocyanin (PC). The concentration of PC in heterocysts of Rivularia is far higher than that of A. variabilis. Fluorescence quantum yield of PC in Rivularia heterocysts was found to be virtually the same as those in its vegetative cells, while fluorescence quantum yield of PC in A. variabilis heterocysts was enhanced in comparison with its vegetative cells. PSI concentration in the thylakoid membranes of heterocysts seems to remain nearly the same as those of the vegetative cells in both the species. The average stoichiometric ratio between PSI monomer and PC hexamer in Rivularia heterocysts is estimated to be about 1:1.Download high-res image (159KB)Download full-size image

Microscopic autofluorescence spectral imaging of chloroplasts in maize mesophyll cells using near-infrared laser excitation has previously shown that a photosystem I spectral component exhibits an intensity similar to that of photosystem II at ∼294 K when a continuous-wave laser at 800−820 nm is used. To establish the generality of this phenomenon, chloroplasts in Parachlorella kessleri cells (P. kessleri) were studied. A continuous-wave laser at 785 nm promoted photosystem-I-specific fluorescence in P. kessleri chloroplasts. The difference in chlorophyll fluorescence peak wavelengths between P. kessleri and maize correlated well with those observed at cryogenic temperatures. To further clarify the nature of anti-Stokes fluorescence, we studied chloroplasts in acetone-treated P. kessleri cells (in a medium containing 15% (v/v) acetone) by microscopic fluorescence and absorption spectra on a cell-by-cell basis. A continuous-wave laser at 785 nm led to significant fluorescence from acetone-treated cells, which was attributed to aggregation of chlorophylls. Anti-Stokes fluorescence spectral imaging thus seems to be effective for detection of lowest-energy trap states that are only weakly fluorescent.