A photosystem I mutant in barley (Hordeum vulgare L.)

Targeted interruption of the psaA and psaB genes encoding the reaction-centre proteins of photosystem I in the filamentous cyanobacterium Anabaena variabilis ATCC 29413

The two reaction-centre proteins of the photosystem I (PSI) complex are encoded by two adjacent genes named psaA and psaB. We have performed targeted mutagenesis to insertionally inactivate each of these genes in the filamentous cyanobacterium Anabaena variabilis ATCC 29413. The resulting mutant strains, termed psaA::NmR and psaB::NmR, were blue because of a high ratio of phycobilin to chlorophyll and were unable to grow in light. These mutant cells also lacked chemically reducible P700 (the reaction-centre chlorophylls of PSI) and as a consequence did not exhibit any PSI-mediated photochemical activity. However, their photosystem II (PSII) complexes were fully active. The loss of the PsaA and PsaB proteins and their associated chlorophyll molecules resulted in a five- to sevenfold decrease in the chlorophyll/PSII ratio in the mutant cells relative to the wild-type cells. Interestingly, the psaB::NmR and not the psaA::NmR mutant strain retained a small fluorescence peak (77K) at 721 nm originating from chlorophyll molecule(s) presumably bound to a small amount of the PsaA protein present in the psaB mutant. These results demonstrate that this organism is suitable for the manipulation of PSI reaction-centre proteins.

Anomalous electron transport activity in a Photosystem I-deficient maize mutant

Photosynthesis mutations were induced in maize lines bearing the transposable DNA element system, Mutator. Two Photosystem I mutants (hcf101 and hcf104) which were isolated are described here. Maize plants homozygous for the hcf104 mutation are seedling lethal and exhibit a high in vivo chlorophyll fluorescence yield. They lack ∼60% of CP1, P700 and PSI-specific electron transport activity relative to normal sibling plants. The comparable depletion of these three measures of PS I content conforms to the pattern reported for many other PS I-deficient mutants. Maize plants homozygous for hcf101 are seedling lethal and also exhibit high in vivo chlorophyll fluorescence yield. They lack 80-90% of CP1 and P700 but sustain steady state levels of PS I-specific electron transport activity at 70% of normal. Previous reports of similar apparent PS I hyperactivity are discussed and an explanation for the elevated steady state level of PS I electron transport activity in hcf101 is proposed.

Characterization of a chloroplast mutation in the psaA2 gene of Chlamydomonas reinhardtii

The synthesis of polypeptides related to the CPI chlorophyll-protein complex of photosystem I has been studied by pulse-labeling experiments in twenty chloroplast mutants of Chlamydomonas reinhardtii. Three mutations of the same locus (Girard-Bascou 1987) result in the absence of these CPI-related polypeptides. Among these mutations one, (FUD26) leads to the synthesis of a new polypeptide presumed to be a truncated CPI apoprotein. The molecular characterization of this mutation in the psaA2 gene has been achieved by DNA sequencing the 3' end of this gene. The FUD26 mutation is a 4 base pair deletion resulting in frameshift and premature termination of the protein.

Comparison of the EPR properties of photosystem I iron-sulphur centres A and B in spinach and barley

The properties of Photosystem I iron-sulphur centres A and B from spinach and barley chloroplasts were investigated by electron paramagnetic resonance spectroscopy (EPR). Barley chloroplasts were shown to photoreduce significant amounts of centre B at cryogenic temperatures unlike those from spinach which only photoreduced centre A. Centre B in barley chloroplasts was also reduced by dithionite before centre A and the EPR spectrum of reduced centre B was obtained. Illumination of barley chloroplasts at 15 K where centre B was chemically reduced resulted in the reduction of centre A and the appearance of spectral features indicating interaction between the two reduced centres. The variation of behaviours of iron-sulphur centres A and B between species favours a scheme of electron flow for Photosystem I where either centre A or centre B act as parallel electron acceptors from the earlier acceptor X.