Specific Inhibition of Cell Wall-Bound ATPases by Fungal Suppressor from Mycosphaerella pinodes

Activities of phosphatases were found in the fractions whichwere solubilized from cell walls of both pea and cowpea seedlingswith 0.5 M NaCl. These phosphatases hydrolyzed triphosphonucleotidesin the order: UTP=CTP>GTP>ATP; and UTP=GTP>CTP=ATP,respectively. The activities of a pyrophosphatase and a p-nitrophenylphosphatasewere also detected in these fractions. The suppressor in thespore germination fluid of a pea pathogen,Mycosphaerella pinodes,inhibited all of these phosphatase activities in the fractionsolubilized from pea cell walls, but it rather enhanced onlythe activity of the ATPase among those phosphatases from thecowpea cell wall. Hydrolysis of ATP by a cell wall fractionof pea was also markedly inhibited by the suppressor, whilehydrolysis of ATP by similar fractions from cowpea, kidney beanand soybean were rather enhanced by the suppressor, as wellas by the elicitor. Thus, the cell wall-bound ATPases respondedto the suppressor species-specifically. These cell wall-boundATPases seemed to be different from the plasma membrane ATPasesin several respects. The results suggest that plants recognizethe fungal signals not only on their plasma membranes but alsoon their cell walls and, moreover that putative receptors forthe fungal signals might be located close to cell wall-boundATPases or might even be these ATPases themselves. (Received November 16, 1994; Accepted April 20, 1995)     

Specific Response of Partially Purified Cell Wall-Bound ATPases to Fungal Suppressor

It was found that NTPases were bound to cell walls of pea andcowpea. The suppressor in pycnospore germination fluid of apea pathogen, Mycosphaerella pinodes, inhibited the ATPase activityin the fraction, which was solubilized from pea cell wall with0.5% Triton X-100, in a dose-dependent manner, but rather enhancedthat from cowpea cell wall even at the concentration of 1 µgml^-1. Inhibition by the suppressor of pea cell wall-bound ATPasewas a mixed type of competitive and noncompetitive. Triton X-100PAGE and active staining of ATPase indicated that both TritonX-100 solubilized fractions contained plural molecules thathydrolyze ATP. The M_rs of cell wall-bound ATPases seem to beconsiderably different from those of plasma membranes, and thenumber of cell wall-bound ATPase molecules were different betweenpea and cowpea. The electroeluted fractions corresponding tothe bands of active-stained ATPases were also able to hydrolyzeNTP and PP_i. The respective electroeluted ATPases also showedthe species-specific response to the suppressor. These resultsmay confirm our previous concept that putative receptors forthe suppressor might tightly bind to cell wall-bound ATPaseor that the ATPase might be the receptor itself. (Received September 8, 1995; Accepted March 9, 1996)     

The Distribution of {beta}-Glycerophosphatase in Young Roots of Pisum sativum L.

The distribution of ß-glycerophosphatase activityin young roots of Pisum sativum, cultivar Alaska, has been examinedby biochemical and histochemical methods. Results obtained bythe two approaches are broadly similar, and indicate that highenzyme activity is associated with cells of the root cap, outerlayers of the cortex, differentiating xylem elements and phloemfibres, and cortical cells surrounding emerging lateral roots.The significance of this distribution in relation to a possiblefunction of ß-glycerophosphatase is discussed.     

Histochemical Localization of Alkaline Phosphatases and {beta}-Glucosidases in Cucurbitaceae

The distribution of alkaline phosphatases and ß-glucosidasesin the tissues of the stems of Colocynthls citrullus, Cucumissativus and Cucurbita pepo was studied. There was similarityin the pattern of distribution for these two groups of enzymesand that of acid phosphatases. The activities of these enzymesvaried not only from plant to plant but also from tissue totissue. However both enzymes showed increasing activity withplant age and localization was correspondingly more restricted.The significance of these localizations is discussed.     

A Method to Measure Hydrolytic Activity of Adenosinetriphosphatases (ATPases)

The detection of small amounts (nanomoles) of inorganic phosphate has a great interest in biochemistry. In particular, phosphate detection is useful to evaluate the rate of hydrolysis of phosphatases, that are enzymes able to remove phosphate from their substrate by hydrolytic cleavage. The hydrolysis rate is correlated to enzyme activity, an extremely important functional parameter. Among phosphatases there are the cation transporting adenosinetriphosphatases (ATPases), that produce inorganic phosphate by cleavage of the γ-phosphate of ATP. These membrane transporters have many fundamental physiological roles and are emerging as potential drug targets. ATPase hydrolytic activity is measured to test enzyme functionality, but it also provides useful information on possible inhibitory effects of molecules that interfere with the hydrolytic process. We have optimized a molybdenum-based protocol that makes use of potassium antimony (III) oxide tartrate (originally employed for phosphate detection in environmental analysis) to allow its use with phosphatase enzymes. In particular, the method was successfully applied to native and recombinant ATPases to demonstrate its reliability, validity, sensitivity and versatility. Our method introduces significant improvements to well-established experimental assays, which are currently employed for ATPase activity measurements. Therefore, it may be valuable in biochemical and biomedical investigations of ATPase enzymes, in combination with more specific tests, as well as in high throughput drug screening.     

Immunochemical Investigations with Highly Purified Glutamate Dehydrogenase from Pea Seeds by Means of the Ouchterlony Test

Monospecific antibodies have been prepared with a homogeneousprotein fraction of the main activity band of pea seed glutamatedehydrogenase. This protein precipitates with its antibodiesin a single band with complete fusion as seen by the Ouchterlonydouble-diffusion test. Identical behaviour is observed withthe protein of the adjacent activity bands of the multiple molecularforms of this enzyme and the antibodies to the former fraction.Organ-specific ‘isoenzymes’ of glutamate dehydrogenasewith preparations of pea roots and epicotyls are not detectedby this procedure. Partially purified glutamate dehydrogenasepreparations from Lemna perpusilla, Zea mays, and Oryza sativaalso precipitate with the antibodies to the pea protein. TheLemna protein is shown to be different from the pea enzyme asjudged from immunological behaviour. The pea antibodies¹ donot cross-react with glutamate dehydrogenases from Candida orbeef liver, nor do the beef liver antibodies react with thepea and Candida enzymes.     

{beta}-Naphthyl oligophosphates: Inhibitors of photophosphorylation and H+-ATPase of spinach chloroplasts

ß-Naphthyl di-, tri- or tetraphosphate inhibits photophosphorylationof spinach chloroplasts competitively with ADP, whereas ß-naphthylmonophosphate inhibits it competitively with Pi. The apparentKi of ß-naphthyl diphosphate for the ADP site was300 µM and that of ß-naphthyl monophosphatefor the Pi site was 1.45 mM. At 10 mM, both of these two organicphosphates inhibited photophosphorylation more than 90%. Noneof the above four ß-naphthyl phosphates were phosphorylatedby chloroplasts. ß-Naphthyl di-, tri- or tetraphosphateinhibits ATPase activity of isolated chloroplast coupling factor1 (CF₁) (EC 3.6.1.3 [EC] ) and light-triggered ATPase activity ofchloroplasts competitively with ATP, whereas ß-naphthylmonophosphate acts non-competitively. None of the four ß-naphthylphosphates were hydrolyzed by these two ATPase activities. Atconcentrations equal to ADP or ATP, ß-naphthyl di-,tri- or tetraphosphate inhibited these three reactions in theorder; ATPase of isolated CF₁> photophosphorylation>light-triggeredATPase of chloroplasts. The results suggest that the effect of the monophosphate isprincipally on the Pi site(s) and that of the di-, tri- or tetraphosphateis on the adenine nucleotide site(s) on the active center ofCF₁. ¹Part of this work was reported at the 1979 Annual Meeting ofthe Japanese Society of Plant Physiologists (Nagoya, April 7,1979) and the 52nd Annual Meeting of the Japanese BiochemicalSociety (Tokyo, October 7, 1979). This work was supported inpart by Grants-in-Aid for Scientific Research from the Ministryof Education, Science and Culture, Japan (311808 and 311909). (Received November 14, 1979; )     

Uncoating of clathrin-coated vesicles by uncoating ATPase from developing peas.

A cytosolic ATPase (an enzyme that dissociates clathrin from clathrin-coated vesicles in the presence of ATP) was isolated from developing pea (Pisum sativum L.) cotyledons using chromatography on ATP-agarose. After chromatography on phenyl Sepharose, the fraction with uncoating activity was enriched in a doublet of 70-kD peptides. Using chromatofocusing, it was possible to produce fractions enriched in the upper component of the doublet of 70-kD peptides; these fractions still retained ATP-dependent uncoating activity. In western blot analysis, antibodies against a member of the 70-kD family of heat-shock proteins interacted with the upper component of the doublet of the 70-kD peptides from the phenyl Sepharose-purified fractions. On the basis of these data, it appears that the uncoating ATPase may be a member of the 70-kD family of heat-shock proteins. The uncoating activity removed clathrin from both pea and bovine brain clathrin-coated vesicles. The uncoating ATPase from bovine brain also uncoated coated vesicles from peas. Pea clathrin-coated vesicles that were prepared by three different methods were uncoated to different extents by the plant uncoating ATPase. Different populations of clathrin-coated vesicles from the same preparation showed differential sensitivity to the uncoating ATPase. Limited proteolysis of the clathrin light chains in the protein coat abolished the susceptibility of the clathrin-coated vesicles to the uncoating ATPase. The properties of the uncoating ATPase isolated from developing pea cotyledons are similar to those of uncoating ATPases previously described from mammalian and yeast systems. It appears that despite dissimilarities in composition of the clathrin components of the vesicles from the respective sources, uncoating is achieved by a common mechanism.     

Monovalent ion stimulated adenosine triphosphatase from oat roots

Monovalent ion stimulated ATPase activity from oat (Avena sativa) roots has been found to be associated with various membrane fractions (cell wall, mitochondrial and microsomal) of oat roots. The ATPase requires Mg²⁺ (or Mn⁺²) but is further stimulated by K⁺ and other monovalent ions. The monovalent ions are ineffective in the absence of the divalent activating cation. The ATPase has been described with respect to monovalent ion specificity, temperature, pH, substrate specificity, and Mg²⁺ and K⁺ concentrations. It was further shown that oligomycin inhibits a part of the total ATPase activity and on the basis of the oligomycin sensitivity it appears that at least 2 membrane associated ATPases are being measured. The mitochondrial fraction is most sensitive to oligomycin and the microsomal fraction is least sensitive to oligomycin. The oligomycin insensitive ATPase appears to be stimulated more by K⁺ than the oligomycin sensitive ATPase.     

Separation of two types of electrogenic h-pumping ATPases from oat roots

Microsomal vesicles of oat roots (Avena sativa var Lang) were separated with a linear dextran (0.5-10%, w/w) or sucrose (25-45%, w/w) gradient to determine the types and membrane identity of proton-pumping ATPases associated with plant membranes. ATPase activity stimulated by the H⁺/K⁺ exchange ionophore nigericin exhibited two peaks of activity on a linear dextran gradient. ATPase activities or ATP-generated membrane potential (inside positive), monitored by SCN⁻ distribution, included a vanadate-insensitive and a vanadate-sensitive component. In a previous communication, we reported that ATP-dependent pH gradient formation (acid inside), monitored by quinacrine fluorescence quenching, was also partially inhibited by vanadate (Churchill and Sze 1983 Plant Physiol 71: 610-617). Here we show that the vanadate-insensitive, electrogenic ATPase activity was enriched in the low density vesicles (1-4% dextran or 25-32% sucrose) while the vanadate-sensitive activity was enriched at 4% to 7% dextran or 32% to 37% sucrose. The low-density ATPase was stimulated by Cl⁻ and inhibited by NO⁻₃ or 4,4′-diisothiocyano-2,2′-stilbene disulfonic acid (DIDS). The distribution of Cl⁻-stimulated ATPase activity in a linear dextran gradient correlated with the distribution of H⁺ pumping into vesicles as monitored by [¹⁴C]methylamine accumulation. The vanadate-inhibited ATPase was mostly insensitive to anions or DIDS and stimulated by K⁺. These results show that microsomal vesicles of plant tissues have at least two types of electrogenic, proton-pumping ATPases. The vanadate-insensitive and Cl⁻-stimulated, H⁺-pumping ATPase may be enriched in vacuolar-type membranes; the H⁺-pumping ATPase that is stimulated by K⁺ and inhibited by vanadate is most likely associated with plasma membrane-type vesicles.     

ATPase activity of partially purified P-glycoprotein from multidrug-resistant Chinese hamster ovary cells.

In vitro studies of multidrug-resistant cell lines have shown that a membrane protein, the P-glycoprotein, is responsible for resistance to a wide range of structurally and functionally dissimilar anti-cancer drugs. The amino-acid sequence of P-glycoprotein (Pgp) indicates two consensus sequences for ATP binding and the purified protein has been reported to possess a low level of ATPase activity. As part of our goal to further characterize the ATPase activity of P-glycoprotein, we have developed a procedure for rapid partial purification of the protein in a highly active form. Plasma membrane vesicles from multidrug-resistant CHRC5 Chinese hamster ovary cells were subjected to a two-step procedure involving selective extraction with different concentrations of the zwitterionic detergent CHAPS. The resulting extract was enriched in P-glycoprotein (around 30% pure) and displayed an ATPase activity (specific activity 543 nmol mg-1 min-1) that was not found in a similar preparation from drug-sensitive cells. The ATPase specific activity was over 10-fold higher than that previously reported for immunoprecipitated Pgp and 280-fold higher than that of immunoaffinity-purified Pgp. This ATPase activity could be distinguished from that of other ion-motive ATPases and membrane-associated phosphatases and is, thus, proposed to be directly attributable to P-glycoprotein. Optimal P-glycoprotein ATPase activity required Mg2+ at an ATP: Mg2+ molar ratio of 0.75:1 and the apparent Km for ATP was 0.88 mM. P-Glycoprotein ATPase could be completely inhibited by vanadate and by the sulfhydryl-modifying reagents N-ethylmaleimide, HgCl2 and p-chloromercuribenzenesulfonate. Certain drugs and chemosensitizers, including colchicine, progesterone, nifedipine, verapamil and trifluoperazine, produced up to 50% activation of P-glycoprotein ATPase activity.     

A novel isoform of ATPase c subunit from pearl millet that is differentially regulated in response to salinity and calcium

Vacuolar ATPases help in maintaining the pH of the vacuoles and thereby play a crucial role in the functioning of vacuolar sodium-proton antiporter. Though the various subunits that make V₁ and V₀ sector have been reported in plants their regulation is not understood completely. We have cloned three different isoforms of vacuolar ATPase subunit c (VHA-c) from Pennisetum glaucum with homologies among themselves varying from 38% to ∼73% at the nucleic acid level. Using real-time PCR approach we have shown that the three isoforms are regulated in a tissue-specific manner under salinity stress. While isoform III is constitutively expressed in roots and shoots and does not respond to stress, isoform I is upregulated under stress. Isoform II is expressed mainly in roots; however, under salinity stress its expression is downregulated in roots and upregulated in shoots. Tissue specific expression under salinity stress of isoform II was also seen after exogenous application of calcium. This study for the first time shows the presence of three isoforms of PgVHA-c and their differential regulation during plant development, and also under abiotic stress.     

Suppression of Pisatin Production and ATPase Activity in Pea Plasma Membranes by Orthovanadate, Verapamil and a Suppressor from Mycosphaerella pinodes

A pea pathogen, Mycosphaerella pinodes, secretes both an elicitorand a suppressor for the accumulation of pisatin, a major phytoalexinof pea, into the spore germination fluid. The effects of theelicitor and the suppressor on the ATPase activity in pea plasmamembranes was examined. The ATPase was sensitive to orthovanadateand dicyclohexylcarbodiimide but insensitive to nitrate andazide; it was unaffected by the elicitor but was markedly inhibitedby the suppressor (50µg.ml^–1, bovine serum albuminequivalents) or verapamil (1OOµM). The accumulation ofpisatin induced by the elicitor was delayed for 3 to 6 h inthe presence of orthovanadate or verapamil to an extent similarto that in the presence of the suppressor. The relationshipbetween the inhibition of plasma membrane ATPase activity andthe suppression of the active defense reaction that involvesthe production of pisatin in the pea plant is discussed. (Received April 16, 1990; Accepted September 6, 1990)     

Some Properties of an Acid Phosphatase Isolated from the Seed Coats of Developing Pea Seeds

An acid phosphatase (EC 3 1 3 2)isolated from the seed-coatsof developing pea seeds was estimated to have MW 30000 by gelfiltration on Sephadex G-75 It was shown to act on a broad spectrumof physiological substrates, the most preferred being ß-glycerophosphate,3-phosphoglycerate and ADP, wich all showed rates of about halfthe maximum rate shown with p-nitrophenyl phosphate (p-NPP)Another model substrate frequently used in enzyme localizationstudies, -naphthyl acid phosphate, was hydrolysed at about 30% of the rate shown with p-NPP This acid phosphatase was enhancedor stabilized by the chelators EDTA and 1, 10-phenanthrolme,unaffected by Mg²⁺ and N-ethyl maleimide, but strongly inhibitedby Zn²⁺ and F^– Both oxidized and reduced glutathione werewithout effect at low concentration and slightly inhibitoryat high concentration (15 mm) Thiol groups are clearly not involvedin regulating the activity of this acid phosphatase, a featurewhich distinguishes it from acid phosphatases from several otherplant species. Pisum sativum L, pea, acid phosphatase, seed-coats, seed development     

Comparative genomics of the FtsK-HerA superfamily of pumping ATPases: implications for the origins of chromosome segregation, cell division and viral capsid packaging

Recently, it has been shown that a predicted P-loop ATPase (the HerA or MlaA protein), which is highly conserved in archaea and also present in many bacteria but absent in eukaryotes, has a bidirectional helicase activity and forms hexameric rings similar to those described for the TrwB ATPase. In this study, the FtsK–HerA superfamily of P-loop ATPases, in which the HerA clade comprises one of the major branches, is analyzed in detail. We show that, in addition to the FtsK and HerA clades, this superfamily includes several families of characterized or predicted ATPases which are predominantly involved in extrusion of DNA and peptides through membrane pores. The DNA-packaging ATPases of various bacteriophages and eukaryotic double-stranded DNA viruses also belong to the FtsK–HerA superfamily. The FtsK protein is the essential bacterial ATPase that is responsible for the correct segregation of daughter chromosomes during cell division. The structural and evolutionary relationship between HerA and FtsK and the nearly perfect complementarity of their phyletic distributions suggest that HerA similarly mediates DNA pumping into the progeny cells during archaeal cell division. It appears likely that the HerA and FtsK families diverged concomitantly with the archaeal–bacterial division and that the last universal common ancestor of modern life forms had an ancestral DNA-pumping ATPase that gave rise to these families. Furthermore, the relationship of these cellular proteins with the packaging ATPases of diverse DNA viruses suggests that a common DNA pumping mechanism might be operational in both cellular and viral genome segregation. The herA gene forms a highly conserved operon with the gene for the NurA nuclease and, in many archaea, also with the orthologs of eukaryotic double-strand break repair proteins MRE11 and Rad50. HerA is predicted to function in a complex with these proteins in DNA pumping and repair of double-stranded breaks introduced during this process and, possibly, also during DNA replication. Extensive comparative analysis of the ‘genomic context’ combined with in-depth sequence analysis led to the prediction of numerous previously unnoticed nucleases of the NurA superfamily, including a specific version that is likely to be the endonuclease component of a novel restriction-modification system. This analysis also led to the identification of previously uncharacterized nucleases, such as a novel predicted nuclease of the Sir2-type Rossmann fold, and phosphatases of the HAD superfamily that are likely to function as partners of the FtsK–HerA superfamily ATPases.     

F- and V-type ATPases in the hyperthermophilic bacterium Thermotoga neapolitana

Two gene clusters encoding F- or V-type ATPases were found in genomic DNA of the hyperthermophilic bacterium Thermotoga neapolitana. The subunit genes of each ATPase formed an operon. While the gene arrangement in the operon of the F-type ATPase resembled those in eukaryotic organelles and bacteria, that of the V-type ATPase was different from those reported for archaea, bacteria, or eukaryotes. Both ATPases were found to be expressed in the cells of T. neapolitana by Western blot analysis. Although V-type ATPase could not be rendered soluble, F-type ATPase was solubilized with 1% Triton X-100 and characterized. This is the first report of the coexistence of both F- and V-type ATPases in hyperthermophilic bacteria. It has recently been shown by a genome analysis that Thermotoga maritima has no V-type ATPase gene cluster but does have an F-type ATPase gene cluster; however, part of a gene for the D-subunit of the V-type ATPase gene has been reported in the T. maritima genome. Evolution of the two types of ATPases in Thermotoga is discussed.     

Distribution of ATPases in wheat root membranes separated by phase partition

The distribution of divalent cation stimulated ATPase activity in relation to the distribution of other enzyme activities was studied for membrane fractions from wheat roots ( Tritium aestivum L . cv. Svenno). A homogenate from dark grown plants was fractionated by differential centrifugation at 1000 g , 10,000 g , 30,000 g and 60,000 g (1, 10, 30 and 60 KP fractions), followed by partition in an aqueous polymer two-phase system, using polyethylene glycol 4000/dextran T500 concentrations of 5.7/5.7, 5.9/5.9, 6.1/6.1, 6.3/6.3 and 6.5/6.5% (w/w). The 30 KP fraction was also separated by counter-current distribution id a 6.3/6.3% two-phase system. Protein and activities of Ca²⁺, Mg²⁺, and Mn²⁺ stimulated ATPases. cytochrome oxidase, light induced absorbance change (LIAC) related to cyt b reductions, inosine diphosphatase and NADH dependent antimycin A insensitive cytochrome c reductase were measured.
The partition of ATPase activities stimulated by Ca²⁺, Mg²⁺ or Mn²⁺ was similar at all polymer concentrations tested, indicating: a low cation specificity of the dominating ATPases. The distribution of ATPases. agreed with different marker enzymes in different centrifuge fractions. Divalent cation stimulated ATPases were evidently related to several of the organelles. In the different fractions the distribution of ATPase activity should then follow that of the marker enzyme of the dominant organelle. From studies with different polymer concentrations the 6.3/6.3-system was selected for further separation of the membranes in the 30 KP fraction by counter-current distribution. By this method one fraction was obtained, which probably consisted of plasmalemma and was free from mitochondrial material. Indications for plasmalemma in this fraction were a) similar partition as protoplasts and b) high LIAC activity.     

Comparison of Plasma Membrane and Tonoplast H+-Translocating ATPases in Phaseolus mungo L. Roots

Two membrane fractions were obtained from 16%/26% and 34%/40%interfaces following discontinuous sucrose density gradientcentrifugation of a 10,000–80,000xg pellet from mung bean(Phaseolus mungo L.) roots. The ATPases in the fractions differedfrom each other in their sensitivity toward various inhibitors,activation with salts, dependence of activity on pH, and K_mfor ATP.Mg²⁺. Judging from their sensitivity toward inhibitors,the ATPases in the low and high density membranes are consideredmainly of tonoplast and plasma membrane origin, respectively.Both ATPases were activated by gramicidin D and nigericin. ATP-inducedquenching of quinacrine fluorescence in both fractions requiredMg²⁺ and permeant anions such as Cl^– and quenching wascollapsed by carbonylcyanide p-trifluoromethoxyphenyl hydrazone.The sensitivities of quenching to the inhibitors were essentiallythe same as those of ATPase activity in the membranes. Thesefindings suggest the involvement of ATPases in H⁺-pumping acrossa plasma membrane and tonoplast. (Received April 12, 1985; Accepted October 11, 1985)     

Effect of diabetes mellitus on epididymal enzymes of adult rats.

Diabetes mellitus caused significant reduction in serum testosterone and accessory sex glands weight. The sperm content of epididymal regions also decreased. Among the epididymal regions, the cauda epididymidal tissue alone showed significant reduction in Na(+)-K+ ATPase activity. However, Mg2+ ATPase activity was lowered in caput epididymidis only. Specific activity of Ca2+ ATPase significantly decreased in caput and cauda epididymides. All three ATPases decreased significantly in caput epididymidal spermatozoa leaving cauda epididymidal spermatozoa unaffected. Specific activity of alkaline phosphatase was suppressed in caput epididymidis and in the spermatozoa collected from caput and cauda epididymides, while the acid phosphatase was unaffected. In general, the results are suggestive of definite influence of diabetes on epididymal phosphatases which is region specific. Diabetes induced decrease in phosphatases may have an impact on secretory and absorptive functions of epididymis and thus on sperm maturation.     

Transport ATPases into the year 2008: a brief overview related to types, structures, functions and roles in health and disease

Transport ATPases can be lumped into four distinct types, P, F, V, and ABC, with the first three designated 20 years ago (Pedersen, P.L. and Carafoli, E., Trends Biochem. Sci. 12, 146–150, 1987) and the ABC type included more recently. The mini-reviews (>20) that comprise this volume of the Journal of Bioenergetics and Biomembranes describe work presented at the 2007 FASEB Conference (6th) on Transport ATPases (Kathleen Sweadner, Chair; Rajini Rao, Co-Chair). Since these conferences began in 1997, the “transport ATPase field” has seen tremendous progress. Advances include a much better understanding of the structure, mechanism, and regulation of each of the four major ATPase types as well as their physiological and medical relevance. In fact, the transport ATPase field has entered a new era in which work on these enzymes is likely to contribute to new therapies for multiple diseases that affect both people and animals. Among these are cancer and heart disease, mitochondrial diseases, osteoporosis, macromolecular degeneration, immune deficiency, cystic fibrosis, diabetes, ulcers, nephro-toxicity, hearing loss, skin disorders, lupus, and malaria. In addition, as several members of the transport ATPase family include those involved in drug resistance their study may help alleviate this recurring problem in drug development. Finally, the transport ATPase field is also paving the way for nanotechnology focused on nano-motors with work on the F-type ATPases (F₀F₁) leading the way. These ATPases driven in reverse by a proton gradient have the capacity to interconvert electrochemical energy into mechanical energy and finally into chemical energy conserved in the terminal bond of ATP. In mammalian mitochondria these events occur on a larger complex or “nano-machine” called the “ATP synthasome” that consists of the ATP synthase in complex formation with carriers for P_i and ADP/ATP.