Mutations within the C-terminus of the gamma subunit of the photosynthetic F1-ATPase activate MgATP hydrolysis and attenuate the stimulatory oxyanion effect

A conformational change of the γ subunit indirectly regulates the activity of cyanobacterial F1-ATPase

The central shaft of the catalytic core of ATP synthase, the γ subunit consists of a coiled-coil structure of N- and C-terminal α-helices, and a globular domain. The γ subunit of cyanobacterial and chloroplast ATP synthase has a unique 30-40-amino acid insertion within the globular domain. We recently prepared the insertion-removed α(3)β(3)γ complex of cyanobacterial ATP synthase (Sunamura, E., Konno, H., Imashimizu-Kobayashi, M., and Hisabori, T. (2010) Plant Cell Physiol. 51, 855-865). Although the insertion is thought to be located in the periphery of the complex and far from catalytic sites, the mutant complex shows a remarkable increase in ATP hydrolysis activity due to a reduced tendency to lapse into ADP inhibition. We postulated that removal of the insertion affects the activity via a conformational change of two central α-helices in γ. To examine this hypothesis, we prepared a mutant complex that can lock the relative position of two central α-helices to each other by way of a disulfide bond formation. The mutant obtained showed a significant change in ATP hydrolysis activity caused by this restriction. The highly active locked complex was insensitive to N-dimethyldodecylamine-N-oxide, suggesting that the complex is resistant to ADP inhibition. In addition, the lock affected ε inhibition. In contrast, the change in activity caused by removal of the γ insertion was independent from the conformational restriction of the central axis component. These results imply that the global conformational change of the γ subunit indirectly regulates complex activity by changing both ADP inhibition and ε inhibition.

Reactive oxygen species affect ATP hydrolysis by targeting a highly conserved amino acid cluster in the thylakoid ATP synthase γ subunit

The vast majority of organisms produce ATP by a membrane-bound rotating protein complex, termed F-ATP synthase. In chloroplasts, the corresponding enzyme generates ATP by using a transmembrane proton gradient generated during photosynthesis, a process releasing high amounts of molecular oxygen as a natural byproduct. Due to its chemical properties, oxygen can be reduced incompletely which generates several highly reactive oxygen species (ROS) that are able to oxidize a broad range of biomolecules. In extension to previous studies it could be shown that ROS dramatically decreased ATP synthesis in situ and affected the CF1 portion in vitro. A conserved cluster of three methionines and a cysteine on the chloroplast γ subunit could be identified by mass spectrometry to be oxidized by ROS. Analysis of amino acid substitutions in a hybrid F1 assembly system indicated that these residues were exclusive catalytic targets for hydrogen peroxide and singlet oxygen, although it could be deduced that additional unknown amino acid targets might be involved in the latter reaction. The cluster was tightly integrated in catalytic turnover since mutants varied in MgATPase rates, stimulation by sulfite and chloroplast-specific γ subunit redox-modulation. Some partial disruptions of the cluster by mutagenesis were dominant over others regarding their effects on catalysis and response to ROS.

Interaction of pyrophosphate with catalytic and noncatalytic sites of chloroplast ATP synthase

The effect of pyrophosphate (PP(i)) on labeled nucleotide incorporation into noncatalytic sites of chloroplast ATP synthase was studied. In illuminated thylakoid membranes, PP(i) competed with nucleotides for binding to noncatalytic sites. In the dark, PP(i) was capable of tight binding to noncatalytic sites previously vacated by endogenous nucleotides, thereby preventing their subsequent interaction with ADP and ATP. The effect of PP(i) on ATP hydrolysis kinetics was also elucidated. In the dark at micromolar ATP concentrations, PP(i) inhibited ATPase activity of ATP synthase. Addition of PP(i) to the reaction mixture at the step of preliminary illumination inhibited high initial activity of the enzyme, but stimulated its activity during prolonged incubation. These results indicate that the stimulating effect of PP(i) light preincubation with thylakoid membranes on ATPase activity is caused by its binding to ATP synthase noncatalytic sites. The inhibition of ATP synthase results from competition between PP(i) and ATP for binding to catalytic sites.

The role of specific beta-gamma subunit interactions in oxyanion stimulation of the MgATP hydrolysis of a hybrid photosynthetic F1-ATPase

Pairs of cysteine residues were introduced into the twisted N- and C-terminal helices of the gamma subunit of the chloroplast F1-ATPase to test, via disulfide cross-linking, potential inter-helical movements involved in catalysis of ATP hydrolysis. The extent of disulfide cross-linking was determined by estimating the amount of free sulfhydryl available for labeling with fluoresceinyl maleimide before and after cross-linking. Significant disulfide formation (50-75%) was observed between cysteines introduced at positions 30 and 31 in the N-terminal helix and 276 and 278 in the C-terminal helix. Cross-linking had no apparent effect on catalysis, therefore eliminating the involvement of large-scale inter-helical movements within this region of the gamma subunit in cooperative ATP hydrolysis. However, the presence of the two cysteines together in the gammaV31C/A276C double mutant, irrespective of whether or not they were cross-linked together, lowered the MgATPase activity by more than 70% and completely eliminated the well-known activating effect of the oxyanion sulfite. The CaATPase activity was unaffected. Similar but less pronounced effects were seen with the gammaK30C/A276C double mutant. The results indicate that residues at or near positions 31 and 276 within the twisted helical pair of the gamma subunit are required to overcome Mg2+ inhibition of ATP hydrolysis. These residues are likely to be involved in forming a point of contact between the gamma and beta subunits that is responsible for this effect.