Added subunit beta of CF1 as well as gamma/delta/epsilon restore photophosphorylation in partially CF1-depleted thylakoids

The regulatory functions of the gamma and epsilon subunits from chloroplast CF1 are transferred to the core complex, alpha3beta3, from thermophilic bacterial F1

The expression plasmids for the subunit gamma (gamma(c)) and the subunit epsilon (epsilon(c)) of chloroplast coupling factor (CF1) from spinach were constructed, and the desired proteins were expressed in Escherichia coli. Both expressed subunits were obtained as inclusion bodies. When recombinant gamma(c) was mixed with recombinant alpha and beta subunits of F1 from thermophilic Bacillus PS3 (TF1), a chimeric subunit complex (alpha3beta3gamma(c)) was reconstituted and it showed significant ATP hydrolysis activity. The ATP hydrolysis activity of this complex was enhanced in the presence of dithiothreitol and suppressed by the addition of CuCl2, which induces formation of a disulfide bond between two cysteine residues in gamma(c). Hence, this complex has similar modulation characteristics as CF1. The effects of recombinant epsilon(c) and epsilon subunit from TF1 (epsilon(t)) on alpha3beta3gamma(c) were also investigated. Epsilon(c) strongly inhibited the ATP hydrolysis activity of chimeric alpha3beta3gamma(c) complex but epsilon(t) did not. The inhibition was abolished and the ATP hydrolysis activity was recovered when methanol was added to the assay medium. The addition of epsilon(c) or epsilon(t) to the alpha3beta3gamma(t) complex, which is the authentic subunit complex from TF1, resulted in weak stimulation of the ATP hydrolysis activity. These results suggest that (a) the specific regulatory function of gamma(c) can be transferred to the bacterial subunit complex; (b) the interaction between the gamma(c) subunit and epsilon(c) strongly affects the enzyme activity, which was catalyzed at the catalytic sites that reside on the alpha3beta3 core.

Reassembly of Synechocystis sp. PCC 6803 F1-ATPase from its over-expressed subunits

Subunits alpha, beta, and gamma of the F1-part of cyanobacterial F0F1-ATPase have been cloned into expression vectors. Over-expressed subunit beta was found soluble in the cytoplasmic fraction of Escherichia coli cells under appropriate culture and induction conditions and was purified from cell extracts. Recombinant alpha and gamma subunits precipitated into inclusion bodies and had to be solubilized, purified and refolded. The correct folding and functional integrity of the alpha and beta subunits was monitored by their ability to bind nucleotides. Active cyanobacterial F1-ATPase was assembled from its purified subunits alpha, beta, gamma, delta and epsilon. The reassembled enzyme reconstituted ATP synthesis in F1-depleted thylakoid membranes of Synechocystis sp. PCC 6803 and hydrolyzed ATP.

Purification and characterization of the inhibitory subunit (delta) of the ATP-synthase from Micrococcus luteus

Subunit delta was isolated from the ATP-synthase from Micrococcus luteus strain (ATCC 4698). delta, in the case of M. luteus F0F1-ATPase, acts as an inhibitor of ATP hydrolysis and thus resembles subunits in E. coli and chloroplast ATP-synthase. After treatment with 1.5 M LiCl the ATP-synthase dissociated, and subsequently subunit delta (27 kDa) was purified by hydrophobic interaction chromatography. Inhibition of ATP-synthase lacking delta by addition of delta showed non-competitive kinetics with a Ki of approximately 5.9 nM. Subunit epsilon from chloroplast F1, which corresponds functionally to the M. luteus F0F1-delta, and chloroplast delta were tested for ATPase inhibitory activity by addition to the partially delta-depleted ATP-synthase from M. luteus. CF1-epsilon inhibited M. luteus ATP-synthase up to 80%, whereas CF1-delta did not show any influence.

The role of the stalk in the coupling mechanism of F1F0-ATPases

The extrinsic and intrinsic membrane sectors of F1F0-ATPases are linked by a slender stalk 40-50 A in length. The stalk transmits the energy produced by oxidative or photosynthetic phosphorylation from the intrinsic sector, F0, to the catalytic sites in the extrinsic F1 sector. How this is achieved is unknown, but long-range conformational changes linked to transmembrane proton transport may be involved. In bacterial and chloroplast F1F0-ATPases, the stalk is probably a composite of subunits delta and epsilon, part of the gamma-subunit, and the extrinsic membrane domains of 2 subunits (identical or non-identical according to the species) that are bound to the membrane by their N-terminal regions. The stalk in the bovine mitochondrial enzyme appears to be more complex, and the gamma, delta, epsilon, OSCP, F6, b and d subunits all contribute to it. A bovine stalk complex has been assembled in vitro from bacterially expressed OSCP, F6, b and d, both in the presence and in the absence of F1-ATPase. One molecule of each of these subunits is present in the assembled complex, as there is also in each native F1F0-ATPase assembly. Providing that suitable crystals can be obtained, the stalk complex and the F1.stalk complex may permit the high resolution structure of bovine F1-ATPase to be extended into the stalk domain.

Complementation of Escherichia coli unc mutant strains by chloroplast and cyanobacterial F1-ATPase subunits

The genes encoding the five subunits of the F1 portion of the ATPases from both spinach chloroplasts and the cyanobacterium Synechocystis sp. PCC 6803 were cloned into expression vectors and expressed in Escherichia coli. The recombinant subunits formed inclusion bodies within the cells. Each particular subunit was expressed in the respective unc mutant, each unable to grow on non-fermentable carbon sources. The following subunits restored growth under conditions of oxidative phosphorylation: alpha (both sources, cyanobacterial subunit more than spinach subunit), beta (cyanobacterial subunit only), delta (both spinach and Synechocystis), and epsilon (both sources), whereas no growth was achieved with the gamma subunits from both sources. Despite a high degree of sequence homology the large subunits alpha and beta of spinach and cyanobacterial F1 were not as effective in the substitution of their E. coli counterparts. On the other hand, the two smallest subunits of the E. coli ATPase could be more effectively replaced by their cyanobacterial or chloroplast counterparts, although the sequence identity or even similarity is very low. We attribute these findings to the different roles of these subunits in F1: The large alpha and beta subunits contribute to the catalytic centers of the enzyme, a function rendering them very sensitive to even minor changes. For the smaller delta and epsilon subunits it was sufficient to maintain a certain tertiary structure during evolution, with little emphasis on the conservation of particular amino acids.