Characterization of the H(+)-pumping F1F0 ATPase of Vibrio alginolyticus

Bacterial Na+- or H+-coupled ATP Synthases Operating at Low Electrochemical Potential

In certain strictly anaerobic bacteria, the energy for growth is derived entirely from a decarboxylation reaction. A prominent example is Propionigenium modestum, which converts the free energy of the decarboxylation of (S)-methylmalonyl-CoA to propionyl-CoA (DeltaG degrees =-20.6 kJ/mol) into an electrochemical Na(+) ion gradient across the membrane. This energy source is used as a driving force for ATP synthesis by a Na(+)-translocating F(1)F(0) ATP synthase. According to bioenergetic considerations, approximately four decarboxylation events are necessary to support the synthesis of one ATP. This unique feature of using Na(+) instead of H(+) as the coupling ion has made this ATP synthase the paradigm to study the ion pathway across the membrane and its relationship to rotational catalysis. The membrane potential (Deltapsi) is the key driving force to convert ion translocation through the F(0) motor components into torque. The resulting rotation elicits conformational changes at the catalytic sites of the peripheral F(1) domain which are instrumental for ATP synthesis. Alkaliphilic bacteria also face the challenge of synthesizing ATP at a low electrochemical potential, but for entirely different reasons. Here, the low potential is not the result of insufficient energy input from substrate degradation, but of an inverse pH gradient. This is a consequence of the high environmental pH where these bacteria grow and the necessity to keep the intracellular pH in the neutral range. In spite of this unfavorable bioenergetic condition, ATP synthesis in alkaliphilic bacteria is coupled to the proton motive force (DeltamuH(+)) and not to the much higher sodium motive force (DeltamuNa(+)). A peculiar feature of the ATP synthases of alkaliphiles is the specific inhibition of their ATP hydrolysis activity. This inhibition appears to be an essential strategy for survival at high external pH: if the enzyme were to operate as an ATPase, protons would be pumped outwards to counteract the low DeltamuH(+), thus wasting valuable ATP and compromising acidification of the cytoplasm at alkaline pH.

Sodium ion cycling mediates energy coupling between complex I and ATP synthase

We show here sodium ion cycling between complex I from Klebsiella pneumoniae and the F(1)F(0) ATP synthase from Ilyobacter tartaricus in a reconstituted proteoliposome system. In the course of NADH oxidation by complex I, an electrochemical sodium ion gradient was established and served as a driving force for the synthesis of ATP from ADP and phosphate. In the opposite direction, the deltamu(Na(+)) generated by ATP hydrolysis could be coupled to NADH formation by reversed electron transfer from ubiquinol to NAD. For reverse electron transfer, a transmembrane voltage larger than 30 mV was obligatory. No NADH-driven proton transport into the lumen of proteoliposomes was detected. We conclude that Na(+) is used as the exclusive coupling ion by the enterobacterial complex I.

cAMP-mediated catabolite repression and electrochemical potential-dependent production of an extracellular amylase in Vibrio alginolyticus

Vibrio alginolyticus, a halophilic marine bacterium, produced an extracellular amylase with a molecular mass of approximately 56,000, and the amylase appeared to be subject to catabolite repression mediated by cAMP. The production of amylase at pH 6.5, at which the respiratory chain-linked H+ pump functions, was inhibited about 75% at 24 hours following the addition of 2 microM carbonyl cyanide m-chlorophenylhydrazone (CCCP), while the production at pH 8.5, at which the respiratory chain-linked Na+ pump functions, was only slightly inhibited by the addition of 2 microM CCCP. In contrast, the production of amylase in a mutant bacterium defective in the Na+ pump was almost completely inhibited even at pH 8.5 as well as pH 6.5 by the addition of 2 microM CCCP.

Effects of the uncI gene on expression of uncB, the gene coding for the a subunit of the F1F0 ATPase of Escherichia coli

The eight genes coding for the subunits of the E. coli F1F0 ATPase are preceded by a gene, designated uncI. A homologous gene, or a gene coding for an analagous protein, is found preceding the ATPase genes of several microorganisms. No function for the 1 gene has been described. Using lac fusions to measure gene expression in vivo, we tested the effects of deleting uncI on the expression of the adjacent gene uncB, which codes for the a subunit of the F0 sector of the ATPase. Deleting uncI reduced the expression of three uncB'-'lacZ fusion genes in vivo, but had no effect on the expression of two uncB'-'lacZ fusion genes containing a relatively smaller amount of the uncB coding region. The uncI deletion also reduced the relative synthesis of the a subunit in vitro. The I gene therefore appears to specifically affect the expression of uncB or the synthesis of the a subunit at some step after translational initiation of uncB.

F0F1-ATPase of Vibrio parahaemolyticus: purification using new detergents and characterization

Previous attempts to isolate a stable F0F1-ATPase complex (H(+)-translocating ATPase) from Vibrio parahaemolyticus have been unsuccessful. Using new non-ionic detergents (alkyl thiomaltosides), a stable F0F1 complex with a high specific activity (15-25 units/mg protein) was purified and characterized. The purified F0F1-ATPase consists of eight subunits (alpha, beta, gamma, delta, epsilon, a, b and c). The new detergents, in combination with sucrose (or glycerol), lipid, dithiothreitol and phenylmethylsulfonyl fluoride, effectively stabilized the F0F1 complex. The ATPase activity of the F0F1 complex was greatly increased by anions, such as SO4(2-) and SO3(2-). Sodium ion increased the activity by about 2-fold. Dicyclohexylcarbodiimide, Zn2+, 4-acetamido-4'-isothiocyanostilben-2,2'disulfonate and tetrachlorosalicylanilide inhibited F0F1-ATPase activity. Ethanol, which stimulated F1-ATPase activity, inhibited F0F1-ATPase activity. Methanol, Na3VO4 and bafilomycin A1 did not have any significant effect on F0F1-ATPase activity, although methanol, like ethanol, stimulated F1-ATPase activity.

Phylogenetic relationships of Bacteria based on comparative sequence analysis of elongation factor Tu and ATP-synthase beta-subunit genes

Comparative sequence analyses were performed on 14 genes encoding bacterial elongation factors EF-Tu and 7 genes encoding the beta-subunit of bacterial F1F0 type ATP-synthases. The corresponding predicted amino acid sequences were compared with published primary structures of homologous molecules. Phylogenetic trees were reconstructed from both data sets of aligned protein sequences and from an equivalent selection of 16S rRNA sequences by applying distance matrix and maximum parsimony methods. The EF-Tu data were in very good agreement with the rRNA data, although the resolution within the EF-Tu tree was reduced at certain phylogenetic levels. The resolution power of the ATPase beta-subunit sequence data were more reduced than those of the EF-Tu data. In comparison with the 16S rRNA tree there are minor differences in the order of adjacent branchings within the ATPase beta-subunit tree.

Subunit structure of ATP synthase from Chloroflexus aurantiacus

An ATP synthase has been isolated from green nonsulfur photosynthetic bacterium Chloroflexus aurantiacus, a representative of a lower branch of eubacteria. The enzyme, reconstituted with the bacterial lipids into proteoliposomes, is shown to catalyze [32P]Pi-ATP exchange (at a rate of 180 nmol [32P]ATP/min/mg). The ATP synthase is composed of nine polypeptide species (60, 50, 33, 19, 16.5, 15.5, 14.5, 13, and 8 kDa as determined by urea-SDS-PAGE). The catalytic part of the ATP synthase (which is detached by chloroform treatment) contains the first four polypeptides. In the intact ATP synthase the 14.5 and 13 kDa polypeptides are connected by disulfide bonds to form a heterodimer of 25 kDa.

Principles of functional and structural organization in the bacterial cell: 'compartments' and their enzymes

Most bacteria lack obvious compartmentation, i.e., structural partition of the cell into functional entities (organelles) formed by a closed biological membrane. Nevertheless, these organisms exhibit sophisticated regulation and interactions of their catabolic and anabolic pathways; they are able to exploit a great variety of carbon and energy sources, and they conserve and transform energy in an efficient manner. In a less stringent sense, 'compartments' are also present in bacteria if one accepts that bacterial 'compartments' are not necessarily surrounded by a membrane, but are rather defined as mere functional entities characterized by their structural components, their enzymes and other functional proteins such as binding proteins. This view would mean that the bacterial cell can be described as a highly organized structured system comprised of these functional entities. Regulated transport processes within 'compartments' and across boundaries involving low and high molecular mass compounds, solutes, and ions take place within the 'framework' constituted by this structured system. Special emphasis is given to the fact that many of the transport processes take place involving the functional entity 'energized membrane'. This 'framework', the structural basis for the functional potential of a bacterial cell, can be studied by electron microscopy. Advanced sample preparation techniques and imaging modes are available which keep the danger of artefact formation low; they can be applied at cellular and macromolecular levels. Recent developments in immunoelectron microscopy and affinity labelling techniques provide tools which allow to unequivocally locate enzymes and other antigens in the cell and to identify polypeptide chains in enzyme complexes. Application of these approaches in studies on cellular and macromolecular organization of bacteria and their enzyme systems confirmed some old views but also extended our knowledge. This is exemplified by a description of selected enzyme complexes located in the bacterial cytoplasm, in the cytoplasmic membrane or attached to it, in the periplasmic space, and attached to the cell wall or set free into the surrounding medium.

Prediction of transmembrane topology of F0 proteins from Escherichia coli F1F0 ATP synthase using variational and hydrophobic moment analyses

The a subunit, a membrane protein from the E. coli F1F0 ATP synthase has been examined by Fourier analysis of hydrophobicity and of amino-acid residue variation. The amino-acid sequences of homologous subunits from Vibrio alginolyticus, Saccharomyces cerevisiae, Neurospora crassa, Aspergillus nidulans, Schizosaccharomyces pombe and Candida parapsilosis were used in the variability analysis. By Fourier analysis of sequence variation, two transmembrane helices are predicted to have one face in contact with membrane lipids, while the other spans are predicted to be more shielded from the lipids by protein. By Fourier analysis of hydrophobicity, six amphipathic alpha-helical segments are predicted in extra-membrane regions, including the region from Glu-196 to Asn-214. Fourier analysis of sequence variation in the b- and the c-subunits of the Escherichia coli F1F0 ATP synthase indicates that the single transmembrane span of the b-subunit and the C-terminal span of the c subunit each have a face in contact with membrane lipids. On the basis of this analysis topographical models for the a- and c-subunits and for the F0 complex are proposed.

Catabolite repression of the H(+)-translocating ATPase in Vibrio parahaemolyticus

Cells of Vibrio parahaemolyticus grown in the presence of glucose showed reduced (by about 40%) oxidative phosphorylation. With this observation as a basis, we examined the effect of glucose on the level of H(+)-translocating ATPase. The addition of glucose to the growth medium reduced the specific activity and the amount of the H(+)-translocating ATPase in membrane vesicles of V. parahaemolyticus. These reductions were reversed by adding cyclic AMP (cAMP) to the growth medium. We cloned some parts of the unc genes encoding subunits of the H(+)-translocating ATPase of V. parahaemolyticus by means of the polymerase chain reaction. Using an amplified DNA fragment, we carried out Northern (RNA) blot analysis and found that glucose reduced the mRNA level of the H(+)-translocating ATPase gene by about 40% and that cAMP restored it. We determined the DNA sequence of the unc promoter region of V. parahaemolyticus and found a consensus sequence for the cAMP receptor protein-cAMP-binding site. Such a sequence was also found in the promoter region of the unc operon of Vibrio alginolyticus but not in its counterpart in Escherichia coli. We observed a similar reduction in the level of ATPase due to glucose in V. alginolyticus. In E. coli, however, reductions in the ATPase and the unc mRNA levels were not observed. Thus, the unc operon is controlled by cAMP-regulated catabolite repression in V. parahaemolyticus and V. alginolyticus but not in E. coli. Catabolite repression of the unc operon in V. parahaemolyticus is not severe.

A sodium-stimulated ATP synthase in the acetogenic bacterium Acetobacterium woodii

Experiments with resting cells of Acetobacterium woodii were performed to elucidate the coupling ion used by the ATP synthase. A. woodii synthesized ATP in response to an artificial delta pH, indicating the presence of a proton-translocating ATPase. On the other hand, a delta pNa, as well as a proton diffusion potential, could serve as a driving force for ATP synthesis with the latter strictly dependent on Na+. These results are indicative for the presence of a Na(+)-translocating ATP synthase in A. woodii.

Biochemical topology: from vectorial metabolism to morphogenesis

In living cells, many biochemical processes are spatially organized: they have a location, and often a direction, in cellular space. In the hands of Peter Mitchell and Jennifer Moyle, the chemiosmotic formulation of this principle proved to be the key to understanding biological energy transduction and related aspects of cellular physiology. For H. E. Huxley and A. F. Huxley, it provided the basis for unravelling the mechanism of muscle contraction; and vectorial biochemistry continues to reverberate through research on cytoplasmic transport, motility and organization. The spatial deployment of biochemical processes serves here as a point of departure for an inquiry into morphogenesis and self-organization during the apical growth of fungal hyphae.

Na(+)-coupled alternative to H(+)-coupled primary transport systems in bacteria

Protons are the most common coupling ions in bacterial energy conversions. However, while many organisms, such as the alkaliphilic Bacilli, employ H(+)-bioenergetics for electron transport phosphorylation, they use Na+ as the coupling ion for transport and flagellar movement. The Na+ gradient required for these bioenergetic functions is established by the secondary Na+/H+ antiporter. In contrast, Vibrio alginolyticus and methanogenic bacteria have primary pumps for both H+ and Na+. They use the proton gradient for ATP synthesis while other, less energy-consuming membrane reactions are powered by the Na+ gradient. In a third mode, some anaerobic bacteria possess decarboxylases acting as primary Na+ pumps. For instance, in Klebsiella pneumoniae, the Na+ gradient established by oxaloacetate decarboxylase is used for the uptake of the growth substrate citrate, and Propionigenium modestum consumes the energy of the Na+ gradient formed by methylmalonyl-CoA decarboxylase directly for ATP synthesis.

F0F1-ATPase from Vibrio alginolyticus. Subunit composition and proton pumping activity

An F0F1-ATPase was isolated from the membranes of the marine bacterium Vibrio alginolyticus. Homology between the subunits of the F0-complexes from E. coli and V. alginolyticus was found using antibodies against subunits a, b and c of the E. coli F0F1-ATPase. The F0F1-complex from V. alginolyticus was reconstituted into proteoliposomes, which were competent in ATP-dependent proton uptake. This process was inhibited by triphenyltin, DCCD, and venturicidin. Na+ did not affect proton translocation.