Na+ binding of V-type Na+-ATPase in Enterococcus hirae

Rotation catalysis theory has been successfully applied to the molecular mechanism of the ATP synthase (F(0)F(1)-ATPase) and probably of the vacuolar ATPase. We investigated the ion binding step to Enterococcus hirae Na(+)-translocating V-ATPase. The kinetics of Na(+) binding to purified V-ATPase suggested 6 +/- 1 Na(+) bound/enzyme molecule, with a single high affinity (K(d(Na(+()))) = 15 +/- 5 micrometer). The number of cation binding sites is consistent with the model that V-ATPase proteolipids form a rotor ring consisting of hexamers, each having one cation binding site. Release of the bound (22)Na(+) from purified molecules in a chasing experiment showed two phases: a fast component (about two-thirds of the total amount of bound Na(+); k(exchange) > 1.7 min(-1)) and a slow component (about one-third of the total; k(exchange) = 0.16 min(-1)), which changes to the fast component by adding ATP or ATPgammaS. This suggested that about two-thirds of the Na(+) binding sites of the Na(+)-ATPase are readily accessible from the aqueous phase and that the slow component is important for the transport reaction.     

Deletion analysis of the subunit genes of V-type Na+-ATPase from Enterococcus hirae

The V1Vo-ATPase from Enterococcus hirae catalyzes ATP hydrolysis coupled with sodium translocation. Mutants with deletions of each of 10 subunits (NtpA, B, C, D, E, F, G, H, I, and K) were constructed by insertion of a chloramphenicol acetyltransferase gene into the corresponding subunit gene in the genome. Measurements of cell growth rates, 22Na+ efflux activities, and ATP hydrolysis activities of the membranes of the deletion mutants indicated that V-ATPase requires nine of the subunits, the exception being the NtpH subunit. The results of Western blotting and V1-ATPase dissociation analysis suggested that the A, B, C, D, E, F, and G subunits constitute the V1 moiety, whereas the V0 moiety comprises the I and K subunits.     

Nucleotide-binding sites in V-type Na+-ATPase from Enterococcus hirae

Enterococcus hirae V-ATPase, in contrast to most V-type ATPases, is resistant to N-ethylmaleimide (NEM). Alignment of the amino acid sequences of NtpA suggests that the NEM-sensitive Cys of V-type ATPases is replaced by Ala in E. hirae V-ATPase. Consistent with this prediction, the V-ATPase became sensitive upon substitution of the Ala with Cys. The three-dimensional structure of the NtpB subunit of V-ATPase was modeled based on the structure of the corresponding subunit (alpha subunit) of bovine F(1)-ATPase by homology modeling. Overall, the 3D structure of the subunit resembled that of alpha subunit of bovine F(1)-ATPase. The NtpB subunit, which lacks the P-loop consensus sequence for nucleotide binding, was predicted to bind a nucleotide at the modeled nucleotide-binding site. Experimental data supported the prediction that the E. hirae V-ATPase had about six nucleotide-binding sites.     

Significance of the glutamate-139 residue of the V-type Na+-ATPase NtpK subunit in catalytic turnover linked with salt tolerance of Enterococcus hirae

A Glu139Asp mutant of the NtpK subunit (kE139D) of Enterococcus hirae vacuolar-type ATPase (V-ATPase) lost tolerance to sodium but not to lithium at pH 10. Purified kE139D V-ATPase retained relatively high specific activity and affinity for the lithium ion compared to the sodium ion. The kE139 residue of V-ATPase is indispensable for its enzymatic activity that is linked with the salt tolerance of enterococci.     

Identification of nucleotide binding sites in V-type Na+-ATPase from Enterococcus hirae

A and B subunits of the V-type Na+-ATPase from Enterococcus hirae were suggested to possess nucleotide binding sites (Murata, T. et al., J. Biochem., 132, 789-794 (2002)), although the B subunit did not have the consensus sequence for nucleotide binding. To further characterize the binding sites in the V-ATPase, we did the photoaffinity labeling study using 8-azido-[alpha-32P]ATP. A and B subunits were labeled with 8-azido-[alpha-32P]ATP when analysed with SDS polyacrylamide gel electrophoresis. The peptide fragment of A subunit obtained by lysyl endopeptidase digestion after labeling showed a molecular size of 9 kDa and its amino acid sequencing revealed that it corresponded to residues Arg423-Lys494. The peptide fragment from B subunit after photoaffinity labeling and lysyl endopeptidase digestion showed the size of 5 kDa and corresponded to residues Phe404-Lys443. In our structure model, these peptides were close to the adenine ring of ATP. We suggest that non-catalytic B subunit of E. hirae V-ATPase has a nucleotide binding site, similarly to eukaryotic V-ATPases and F-ATPases.     

Relationship of K+-Uptaking System with H+-Translocating ATPase in Enterococcus hirae, Grown at a High or Low Alkaline pH

Potassium ion pool was studied in glycolyzing Enterococcus hirae, grown at high or low alkaline pH (pH 9.5 and 8.0, respectively). Energy-dependent increase of K⁺ pool was lower for the wild-type cells, grown at pH 9.5, than that for the cells grown at pH 8.0. It was inhibited by N,N′-dicyclohexylcarbodiimide (DCCD). The stoichiometry of DCCD-inhibited K⁺ influx to DCCD-inhibited H⁺ efflux for the wild-type cells, grown at pH 9.5 or 8.0, was fixed for different K⁺ external activity. DCCD-inhibited ATPase activity of membrane vesicles was significantly stimulated by K⁺ for the wild-type cells grown at pH 9.5, and required K⁺ for the wild-type cells grown at pH 8.0, while the levels of α and β subunits of the F₁ and b subunit of the F₀ were lower for the cells grown at pH 9.5 than that for the cells grown at pH 8.0. Such an ATPase activity was residual in membrane vesicles from the atpD mutant with a nonfunctional F₀F₁. ATPase activity of membrane vesicles from the mutant with defect in Na⁺-ATPase was higher for the cells grown at pH 9.5 than that for the cells grown at pH 8.0, and was inhibited by DCCD. An energy-dependent increase of K⁺ pool in this bacterium, grown at a high or low alkaline pH, is assumed to occur through a K⁺ uptaking system, most probably the Trk. The latter functions in a closed relationship with the H⁺-translocating ATPase F₀F₁. Received: 30 June 1997 / Accepted: 4 August 1997     

Arginine 383 is a crucial residue in ABCG2 biogenesis

ABCG2 is an ATP-binding cassette half-transporter initially identified in multidrug-resistant cancer cell lines and recently suggested to play an important role in pharmacokinetics. Here we report studies of a conserved arginine predicted to localize near the cytoplasmic side of TM1. First, we determined the effect of losing charge and bulk at this position via substitutions with glycine and alanine. The R383G mutant when transfected into HEK cells was not detectable on immunoblot or by functional assay, while the R383A mutant exhibited detectable but significantly decreased levels compared to wild-type, partial retention in the ER and altered glycosylation. Efflux of the ABCG2-substrates mitoxantrone and pheophorbide a was observed. Our experiments suggested rapid degradation of the R383A mutant by the proteasome via a kifunensine-insensitive pathway. Interestingly, overnight treatment of the R383A mutant with mitoxantrone assisted in protein maturation as evidenced by a shift to the N-glycosylated form. The R383A mutant when expressed in insect cells, though detected on the surface, had no measurable ATPase activity. In addition, substitution with the positively charged lysine resulted in significantly decreased protein expression levels in HEK cells, while retaining function. In conclusion, arginine 383 is a crucial residue for ABCG2 biogenesis, where even the most conservative mutations have a large impact.     

The membrane domain of the Na+-motive V-ATPase from Enterococcus hirae contains a heptameric rotor

In F-ATPases, ATP hydrolysis is coupled to translocation of ions through membranes by rotation of a ring of c subunits in the membrane. The ring is attached to a central shaft that penetrates the catalytic domain, which has pseudo-3-fold symmetry. The ion translocation pathway lies between the external circumference of the ring and another hydrophobic protein. The H+ or Na+:ATP ratio depends upon the number of ring protomers, each of which has an essential carboxylate involved directly in ion translocation. This number and the ratio differ according to the source, and 10, 11, and 14 protomers have been found in various enzymes, with corresponding calculated H+ or Na+:ATP ratios of 3.3, 3.7, and 4.7. V-ATPases are related in structure and function to F-ATPases. Oligomers of subunit K from the Na+-motive V-ATPase of Enterococcus hirae also form membrane rings but, as reported here, with 7-fold symmetry. Each protomer has one essential carboxylate. Thus, hydrolysis of one ATP provides energy to extrude 2.3 sodium ions. Symmetry mismatch between the catalytic and membrane domains appears to be an intrinsic feature of both V- and F-ATPases.     

Primary structure of the alpha-subunit of vacuolar-type Na(+)-ATPase in Enterococcus hirae. Amplification of a 1000-bp fragment by polymerase chain reaction.

A 1000-bp fragment of Enterococcus hirae genomic DNA was amplified by the polymerase chain reaction method, using the oligonucleotide primers designed from amino acid sequences of both amino-terminal and a tryptic fragment of the Na(+)-ATPase alpha-subunit in this organism. DNA sequencing of this product revealed that the amino acid sequence of Na(+)-ATPase alpha-subunit is highly homologous to the corresponding sequences of large (alpha) subunits of vacuolar (archaebacterial) type H(+)-ATPases, supporting our proposal [Kakinuma, Y. and Igarashi, K. (1990) FEBS Lett. 271, 97-101] that the Na(+)-ATPase of this organism belongs to the vacuolar-type ATPase.     

The side chain of ubiquinone plays a critical role in Na+ translocation by the NADH-ubiquinone oxidoreductase (Na+-NQR) from Vibrio cholerae

The Na⁺-pumping NADH-ubiquinone (UQ) oxidoreductase (Na⁺-NQR) is an essential bacterial respiratory enzyme that generates a Na⁺ gradient across the cell membrane. However, the mechanism that couples the redox reactions to Na⁺ translocation remains unknown. To address this, we examined the relation between reduction of UQ and Na⁺ translocation using a series of synthetic UQs with Vibrio cholerae Na⁺-NQR reconstituted into liposomes. UQ₀ that has no side chain and UQ_CH3 and UQ_C2H5, which have methyl and ethyl side chains, respectively, were catalytically reduced by Na⁺-NQR, but their reduction generated no membrane potential, indicating that the overall electron transfer and Na⁺ translocation are not coupled. While these UQs were partly reduced by electron leak from the cofactor(s) located upstream of riboflavin, this complete loss of Na⁺ translocation cannot be explained by the electron leak. Lengthening the UQ side chain to n-propyl (C₃H₇) or longer significantly restored Na⁺ translocation. It has been considered that Na⁺ translocation is completed when riboflavin, a terminal redox cofactor residing within the membrane, is reduced. In this view, the role of UQ is simply to accept electrons from the reduced riboflavin to regenerate the stable neutral riboflavin radical and reset the catalytic cycle. However, the present study revealed that the final UQ reduction via reduced riboflavin makes an important contribution to Na⁺ translocation through a critical role of its side chain. Based on the results, we discuss the critical role of the UQ side chain in Na⁺ translocation.     

Bacterial virulence plays a crucial role in MRSA sepsis

Bacterial sepsis is a major global cause of death. However, the pathophysiology of sepsis has remained poorly understood. In industrialized nations, Staphylococcus aureus represents the pathogen most commonly associated with mortality due to sepsis. Because of the alarming spread of antibiotic resistance, anti-virulence strategies are often proposed to treat staphylococcal sepsis. However, we do not yet completely understand if and how bacterial virulence contributes to sepsis, which is vital for a thorough assessment of such strategies. We here examined the role of virulence and quorum-sensing regulation in mouse and rabbit models of sepsis caused by methicillin-resistant S. aureus (MRSA). We determined that leukopenia was a predictor of disease outcome during an early critical stage of sepsis. Furthermore, in device-associated infection as the most frequent type of staphylococcal blood infection, quorum-sensing deficiency resulted in significantly higher mortality. Our findings give important guidance regarding anti-virulence drug development strategies for the treatment of staphylococcal sepsis. Moreover, they considerably add to our understanding of how bacterial sepsis develops by revealing a critical early stage of infection during which the battle between bacteria and leukocytes determines sepsis outcome. While sepsis has traditionally been attributed mainly to host factors, our study highlights a key role of the invading pathogen and its virulence mechanisms.     

ECA3, a Golgi-localized P2A-type ATPase, plays a crucial role in manganese nutrition in Arabidopsis

Calcium (Ca) and manganese (Mn) are essential nutrients required for normal plant growth and development, and transport processes play a key role in regulating their cellular levels. Arabidopsis (Arabidopsis thaliana) contains four P(2A)-type ATPase genes, AtECA1 to AtECA4, which are expressed in all major organs of Arabidopsis. To elucidate the physiological role of AtECA2 and AtECA3 in Arabidopsis, several independent T-DNA insertion mutant alleles were isolated. When grown on medium lacking Mn, eca3 mutants, but not eca2 mutants, displayed a striking difference from wild-type plants. After approximately 8 to 9 d on this medium, eca3 mutants became chlorotic, and root and shoot growth were strongly inhibited compared to wild-type plants. These severe deficiency symptoms were suppressed by low levels of Mn, indicating a crucial role for ECA3 in Mn nutrition in Arabidopsis. eca3 mutants were also more sensitive than wild-type plants and eca2 mutants on medium lacking Ca; however, the differences were not so striking because in this case all plants were severely affected. ECA3 partially restored the growth defect on high Mn of the yeast (Saccharomyces cerevisiae) pmr1 mutant, which is defective in a Golgi Ca/Mn pump (PMR1), and the yeast K616 mutant (Deltapmc1 Deltapmr1 Deltacnb1), defective in Golgi and vacuolar Ca/Mn pumps. ECA3 also rescued the growth defect of K616 on low Ca. Promoter:beta-glucuronidase studies show that ECA3 is expressed in a range of tissues and cells, including primary root tips, root vascular tissue, hydathodes, and guard cells. When transiently expressed in Nicotiana tabacum, an ECA3-yellow fluorescent protein fusion protein showed overlapping expression with the Golgi protein GONST1. We propose that ECA3 is important for Mn and Ca homeostasis, possibly functioning in the transport of these ions into the Golgi. ECA3 is the first P-type ATPase to be identified in plants that is required under Mn-deficient conditions.     

Phosphorylation of small subunit plays a crucial role in the regulation of RuBPCase in moss and spinach

RuBPCase has been purified to electrophoretic homogeneity from moss and spinach. On denaturing SDS-polyacrylamide gels the purified enzyme revealed two discrete bands, thereby indicating the presence of large and small subunits. The phosphoprotein nature of RuBPCase was proved by in vivo labelling of enzyme with [³²P]orthophosphate. Autoradiographic analysis of ³²P-labelled RuBPCase on SDS-PAG demonstrated that phosphorylation was restricted to the small subunit. Dephosphorylation of purified RuBPCase with alkaline phosphatase resulted in a dramatic decline (70% decrease) in the biological activity of the enzyme. Fractionation of the dephosphorylated enzyme on denaturing gels revealed only the presence of large subunits of RuBPCase. Thus it became evident that dephosphorylation of RuBPCase brings about the dissociation of small subunits from the catalytic large subunits (octamer). The dephosphorylated small subunits were isolated as dimers. These results clearly indicate that phosphorylation of small subunits is mandatory for the reconstitution of holoenzyme and hence crucial for the activation of RuBPCase.     

Indispensable glutamic acid residue-139 of NtpK proteolipid in the reaction of vacuolar Na(+)-translocating ATPase in Enterococcus hirae.

Enterococcus hirae vacuolar ATPase catalyzes translocation of Na+ or Li+ coupled with ATP hydrolysis. It is suggested that the glutamic acid residue (Glu139) of NtpK proteolipid subunit of this multisubunit enzyme is the binding site of these ions for translocation. Here we established a complementation system for the ntpK gene with its deletion mutant, and found that the ATPase activity disappeared upon replacement of Glu139 by aspartic acid. The side-chain length of this acidic residue of NtpK is thus important for this ATPase reaction.     

The d subunit plays a central role in human vacuolar H+-ATPases

The multi-subunit vacuolar-type H⁺-ATPase consists of a V₁ domain (A–H subunits) catalyzing ATP hydrolysis and a V₀ domain (a, c, c', c", d, e) responsible for H⁺ translocation. The mammalian V₀ d subunit is one of the least-well characterized, and its function and position within the pump are still unclear. It has two different forms encoded by separate genes, d1 being ubiquitous while d2 is predominantly expressed at the cell surface in kidney and osteoclast. To determine whether it forms part of the pump’s central stalk as suggested by bacterial A-ATPase studies, or is peripheral as hypothesized from a yeast model, we investigated both human d subunit isoforms. In silico structural modelling demonstrated that human d1 and d2 are structural orthologues of bacterial subunit C, despite poor sequence identity. Expression studies of d1 and d2 showed that each can pull down the central stalk’s D and F subunits from human kidney membrane, and in vitro studies using D and F further showed that the interactions between these proteins and the d subunit is direct. These data indicate that the d subunit in man is centrally located within the pump and is thus important in its rotary mechanism.     

The large subunit of bacteriophage lambda's terminase plays a role in DNA translocation and packaging termination

The DNA packaging enzyme of bacteriophage lambda, terminase, is a heteromultimer composed of a small subunit, gpNu1, and a large subunit, gpA, products of the Nu1 and A genes, respectively. The role of terminase in the initial stages of packaging involving the site-specific binding and cutting of the DNA has been well characterized. While it is believed that terminase plays an active role in later post-cleavage stages of packaging, such as the translocation of DNA into the head shell, this has not been demonstrated. Accordingly, we undertook a generalized mutagenesis of lambda's A gene and found ten lethal mutations, nine of which cause post-cleavage packaging defects. All were located in the amino-terminal two-thirds of gpA, separate from the carboxy-terminal region where mutations affecting the protein's endonuclease activity have been found. The mutants fall into five groups according to their packaging phenotypes: (1) two mutants package part of the lambda chromosome, (2) one mutant packages the entire chromosome, but very slowly compared to wild-type, (3) two mutants do not package any DNA, (4) four mutants, though inviable, package the entire lambda chromosome, and (5) one mutant may be defective in both early and late stages of DNA packaging. These results indicate that gpA is actively involved in late stages of packaging, including DNA translocation, and that this enzyme contains separate functional domains for its early and late packaging activities.     

Differential expression of a subunit isoforms of the vacuolar-type proton pump ATPase in mouse endocrine tissues

Vacuolar-type proton ATPase (V-ATPase) is a multi-subunit enzyme that couples ATP hydrolysis to the translocation of protons across membranes. Mammalian cells express four isoforms of the a subunit of V-ATPase. Previously, we have shown that V-ATPase with the a3 isoform is highly expressed in pancreatic islets and is located in the membranes of insulin-containing granules in the β cells. The a3 isoform functions in the regulation of hormone secretion. In this study, we have examined the distribution of a subunit isoforms in endocrine tissues, including the adrenal, parathyroid, thyroid, and pituitary glands, with isoform-specific antibodies. We have found that the a3 isoform is strongly expressed in all these endocrine tissues. Our results suggest that functions of the a3 isoform are commonly involved in the process of exocytosis in regulated secretion. This research was supported in part by Grants-in-Aid from the Ministry of Education, Science, and Culture of Japan and by the Hayashi, Takeda, and Noda Foundations.     

Sarkosyl is a good regeneration reagent for studies on vacuolar-type ATPase subunit interactions in Biacore experiments

Biacore is widely used for studies on protein–protein interaction in which regeneration is one of the most important steps. Here we introduce the anionic detergent sodium lauroyl sarcosinate (sarkosyl), which works satisfactorily as a regeneration reagent. After regeneration by the mild detergent, the subsequent binding experiment was reproducible without any degradation of the ligand. This regeneration condition can be employed for diverse combinations of ligand–analyte binding interactions and optimized as required.     

The active site region plays a critical role in Na+ binding to thrombin

The catalytic activity of thrombin and other enzymes of the blood coagulation and complement cascades is enhanced significantly by binding of Na⁺ to a site >15 Å away from the catalytic residue S195, buried within the 180 and 220 loops that also contribute to the primary specificity of the enzyme. Rapid kinetics support a binding mechanism of conformational selection where the Na⁺-binding site is in equilibrium between open (N) and closed (N^∗) forms and the cation binds selectively to the N form. Allosteric transduction of this binding step produces enhanced catalytic activity. Molecular details on how Na⁺ gains access to this site and communicates allosterically with the active site remain poorly defined. In this study, we show that the rate of the N∗→N transition is strongly correlated with the analogous E∗→E transition that governs the interaction of synthetic and physiologic substrates with the active site. This correlation supports the active site as the likely point of entry for Na⁺ to its binding site. Mutagenesis and structural data rule out an alternative path through the pore defined by the 180 and 220 loops. We suggest that the active site communicates allosterically with the Na⁺ site through a network of H-bonded water molecules that embeds the primary specificity pocket. Perturbation of the mobility of S195 and its H-bonding capabilities alters interaction with this network and influences the kinetics of Na⁺ binding and allosteric transduction. These findings have general mechanistic relevance for Na⁺-activated proteases and allosteric enzymes.