Publication Date:
2018
abstract:
Photosystems I and II convert solar energy into the chemical energy that powers life. Chlorophyll a photochemistry, using red light (680 to 700 nm), is near universal and is considered to define the energy "red limit" of oxygenic photosynthesis. We present biophysical studies on the photosystems from a cyanobacterium grown in far-red light (750 nm). The few long-wavelength chlorophylls present are well resolved from each other and from the majority pigment, chlorophyll a. Charge separation in photosystem I and II uses chlorophyll f at 745 nm and chlorophyll f (or d) at 727 nm, respectively. Each photosystem has a few even longer-wavelength chlorophylls f that collect light and pass excitation energy uphill to the photochemically active pigments. These photosystems function beyond the red limit using far-red pigments in only a few key positions. 2017 © The Authors
Iris type:
01.01 Articolo in rivista
Keywords:
chlorophyll; chlorophyll a; chlorophyll f; thylakoid membrane protein; unclassified drug; chlorophyll; chlorophyll a; chlorophyll f; biophysics; chlorophyll; cyanobacterium; light intensity; photochemistry; photosynthesis; pigment; separation; wavelength; Acaryochloris; Article; chemical structure; Chroococcidiopsis thermalis; cyanobacterium; excitation; far red light; nonhuman; photochemistry; photosynthesis; photosystem I; photosystem II; pigmentation; priority journal; solar energy; spectral sensitivity; thermoluminescence; analogs and derivatives; chemistry; growth; development and aging; light; metabolism; photosynthesis; radiation response; Chlorophyll; Cyanobacteria; Light; Photosynthesis; Photosystem I Protein Complex; Photosystem II Protein Complex
List of contributors:
Santabarbara, Stefano
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