THEORETICAL ASSESSMENT OF ALTERNATIVE MECHANISMS FOR NONPHOTOCHEMICAL QUENCHING OF PS-II FLUORESCENCE IN BARLEY LEAVES

The components of non-photochemical chlorophyll fluorescence quenching (qN) in barley leaves have been quantified by a combination of relaxation kinetics analysis and 77 K fluorescence measurements (Walters RG and Horton P 1991). Analysis of the behaviour of chlorophyll fluorescence parameters and oxygen evolution at low light (when only state transitions - measured as qN(t) - are present) and at high light (when only photoinhibition - measured as qN(i) - is increasing) showed that the parameter qN(t) represents quenching processes located in the antenna and that qN(i) measures quenching processes located in the reaction centre but which operate significantly only when those centres are closed. The theoretical predictions of a variety of models describing possible mechanisms for high-energy-state quenching, measured as the residual quenching, qN(e), were then tested against the experimental data for both fluorescence quenching and quantum yield of oxygen evolution. Only one model was found to agree with these data, one in which antennae exist in two states, efficient in either energy transfer or energy dissipation, and in which those photosynthetic units in a dissipative state are unable to exchange energy with non-dissipative units.