spectra of free chlorophyll
a (
blue) and
b (
red) in a solvent. The spectra of chlorophyll molecules are slightly modified
in vivo depending on specific pigment-protein interactions. Chlorophyll is vital for
photosynthesis, which allows plants to absorb energy from
light. Chlorophyll molecules are arranged in and around
photosystems that are embedded in the
thylakoid membranes of
chloroplasts. In these complexes, chlorophyll serves three functions: • The function of the vast majority of chlorophyll (up to several hundred molecules per photosystem) is to absorb light. • Having done so, these same centers execute their second function: The transfer of that energy by
resonance energy transfer to a specific chlorophyll pair in the
reaction center of the photosystems. • This specific pair performs the final function of chlorophylls: Charge separation, which produces the unbound protons (H) and electrons (e) that separately propel biosynthesis. The two currently accepted photosystem units are and which have their own distinct reaction centres, named
P700 and
P680, respectively. These centres are named after the wavelength (in
nanometers) of their red-peak absorption maximum. The identity, function and spectral properties of the types of chlorophyll in each photosystem are distinct and determined by each other and the protein structure surrounding them. The function of the reaction center of chlorophyll is to absorb light energy and transfer it to other parts of the photosystem. The absorbed energy of the photon is transferred to an electron in a process called charge separation. The removal of the electron from the chlorophyll is an oxidation reaction. The chlorophyll donates the high energy electron to a series of molecular intermediates called an
electron transport chain. The charged reaction center of chlorophyll (P680+) is then reduced back to its ground state by accepting an electron stripped from water. The electron that reduces P680+ ultimately comes from the oxidation of water into O2 and H+ through several intermediates. This reaction is how photosynthetic organisms such as plants produce O2 gas, and is the source for practically all the O2 in Earth's atmosphere. Photosystem I typically works in series with Photosystem II; thus the P700+ of Photosystem I is usually reduced as it accepts the electron, via many intermediates in the thylakoid membrane, by electrons coming, ultimately, from Photosystem II. Electron transfer reactions in the thylakoid membranes are complex, however, and the source of electrons used to reduce P700+ can vary. The electron flow produced by the reaction center chlorophyll pigments is used to pump H+ ions across the thylakoid membrane, setting up a
proton-motive force a chemiosmotic potential used mainly in the production of
ATP (stored chemical energy) or to reduce NADP+ to
NADPH. NADPH is a universal
agent used to reduce CO2 into sugars as well as other biosynthetic reactions. Reaction center chlorophyll–protein complexes are capable of directly absorbing light and performing charge separation events without the assistance of other chlorophyll pigments, but the probability of a single chlorophyll molecule doing so under a given light intensity is small. Thus, the other chlorophylls in the photosystem and antenna pigment proteins all cooperatively absorb and funnel light energy to the reaction center. Besides chlorophyll
a, there are other pigments, called
accessory pigments, which occur in these pigment–protein antenna complexes. These pigments complement chlorophyll by absorbing photons at wavelengths outside of chlorophyll's narrow absorption spectrum and deliver additional electrons to the photosystem. ==Chemical structure==