Abstract
The nuclear atpC1 gene encoding the gamma subunit of the plastid ATP synthase has been inactivated by T-DNA insertion mutagenesis in Arabidopsis thaliana. In the seedling-lethal dpa1 (deficiency of plastid ATP synthase 1) mutant, the absence of detectable amounts of the gamma subunit destabilizes the entire ATP synthase complex. The expression of a second gene copy, atpC2, is unaltered in dpa1 and is not sufficient to compensate for the lack of atpC1 expression. However, in vivo protein labeling analysis suggests that assembly of the ATP synthase alpha and beta subunits into the thylakoid membrane still occurs in dpa1. As a consequence of the destabilized ATP synthase complex, photophosphorylation is abolished even under reducing conditions. Further effects of the mutation include an increased light sensitivity of the plant and an altered photosystem II activity. At low light intensity, chlorophyll fluorescence induction kinetics is close to those found in wild type, but non-photochemical quenching strongly increases with increasing actinic light intensity resulting in steady state fluorescence levels of about 60% of the minimal dark fluorescence. Most fluorescence quenching relaxed within 3 min after dark incubation. Spectroscopic and biochemical studies have shown that a high proton gradient is responsible for most quenching. Thylakoids of illuminated dpa1 plants were swollen due to an increased proton accumulation in the lumen. Expression profiling of 3292 nuclear genes encoding mainly chloroplast proteins demonstrates that most organelle functions are down-regulated. On the contrary, the mRNA expression of some photosynthesis genes is significantly up-regulated, probably to compensate for the defect in dpa1.
Highlights
The nuclear atpC1 gene encoding the ␥ subunit of the plastid ATP synthase has been inactivated by T-DNA insertion mutagenesis in Arabidopsis thaliana
The plastid ATP synthase complex consists of nine different subunits, four of them are localized in the membrane integral CF0 subcomplex (a, b, bЈ, and c14) which is responsible for proton translocation, and five subunits constitute the extrinsic CF1 subcomplex (␣3, 3, ␥, ␦, and ⑀) which forms the catalytic entity [3, 4]
Identification and Phenotype of the Dpa1 Mutant—The F2 progeny of 1100 EMS-treated seeds and 75 preselected pale mutants from T-DNA collections [53] obtained from the Arabidopsis Biological Resource Centre (Ohio State University, Columbus, OH) have been used for screening. 87 mutant plants were selected by their non-photoautotrophic growth on soil
Summary
The oligonucleotides 5Ј-CAGTCGAATCTTGATGACCGTCGATGATG-3Ј and 5Ј-GTTCGTCGAGAATCAGAGTGGCTC-3Ј were used as a simple sequence length polymorphism marker Cer452226 [25] located 850 kb upstream of the atpC1 gene on the bacterial artificial chromosome F4C21 This marker is polymorphic between Landsberg and Wassilewskija producing 203and 285-bp PCR products, respectively. Immmunological and Translation Analyses—Thylakoid membrane proteins of 3-week-old plants were isolated as described [39]. For in vivo labeling analysis intact leaves of 3-week-old plants were immersed in a 1⁄2ϫ MS solution containing 50 Ci of [35S]methionine for 20 min [42]. CDNA probes were synthesized by using a mixture of oligonucleotides matching the 3292 genes in antisense orientation as primer, and hybridized to the gene sequence tags array as described previously [48, 49]. Energy transfer fluorochrome dideoxynucleotide labeling [51] was used for detection of sequencing products using the ABI 377 system (Applied Biosystems)
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