Sequence homology between two membrane transport ATPases, the Kdp-ATPase of Escherichia coli and the Ca2+-ATPase of sarcoplasmic reticulum

The cyanobacterium, Synechococcus sp. PCC7942, possesses two distinct genes encoding cation-transporting P-type ATPases

P-type (or E1 E2-type) ATPases comprise a large family of prokaryotic and eukaryotic proteins capable of transporting a variety of cations, and function in a wide variety of cellular processes. The present study was carried out to search for genes encoding P-type ATPases in the phototrophic cyanobacterium, Synechococcus sp. PCC7942. We succeeded in cloning two genes each encoding P-type ATPases from this bacterium. It was found that Synechococcus at least, two distinct P-type ATPases; one belongs to the family of typical prokaryotic P-type ATPases and the other markedly resembles eukaryotic P-type ATPases. An insertion mutant lacking either of these two ATPase-genes was constructed. The results showed that the growth of these mutants is hypersensitive to osmotic stress upon addition of NaCl or sorbitol to the medium.

Genetic identification of exported proteins in Streptococcus pneumoniae

A strategy was developed to mutate and genetically identify exported proteins in Streptococcus pneumoniae. Vectors were created and used to screen pneumococcal DNA in Escherichia coli and S. pneumoniae for translational gene fusions to alkaline phosphatase (PhoA). Twenty five PhoA+ pneumococcal mutants were isolated and the loci from eight of these mutants showed similarity to known exported or membrane-associated proteins. Homologues were found to: (i) protein-dependent peptide permeases, (ii) penicillin-binding proteins, (iii) Clp proteases, (iv) two-component sensor regulators, (v) the phosphoenolpyruvate: carbohydrate phosphotransferases permeases, (vi) membrane-associated dehydrogenases, (vii) P-type (E1E2-type) cation transport ATPases, (viii) ABC transporters responsible for the translocation of the RTX class of bacterial toxins. Unexpectedly one PhoA+ mutant contained a fusion to a member of the DEAD protein family of ATP-dependent RNA helicases suggesting export of these proteins.

A family of cation ATPase-like molecules from Plasmodium falciparum

We report the nucleotide and derived amino acid sequence of the ATPase 1 gene from Plasmodium falciparum. The amino acid sequence shares homology with the family of "P"-type cation translocating ATPases in conserved regions important for nucleotide binding, conformational change, or phosphorylation. The gene, which is present on chromosome 5, has a product longer than any other reported for a P-type ATPase. Interstrain analysis from 12 parasite isolates by the polymerase chain reaction reveals that a 330-bp nucleotide sequence encoding three cytoplasmic regions conserved in cation ATPases (regions a-c) is of constant length. By contrast, another 360-bp sequence which is one of four regions we refer to as "inserts" contains arrays of tandem repeats which show length variation between different parasite isolates. Polymorphism results from differences in the number and types of repeat motif contained in this insert. Inserts are divergent in sequence from other P-type ATPases and share features in common with many malarial antigens. Studies using RNA from the erythrocytic stages of the malarial life cycle suggest that ATPase 1 (including the sequence which encodes tandem repeats) is expressed at the large ring stage of development. Immunolocalization has identified ATPase 1 to be in the region of the parasite plasma membrane and pigment body. These findings suggest a possible model for the genesis of malarial antigens.

Isolation of a candidate gene for Menkes disease and evidence that it encodes a copper-transporting ATPase

Menkes disease is an X-linked disorder of copper transport characterized by progressive neurological degeneration and death in early childhood. We have isolated a candidate gene (Mc1) for Menkes disease and find qualitative or quantitative abnormalities in the mRNA in sixteen of twenty-one Menkes patients. Four patients lacking Mc1RNA showed rearrangements of the Menkes gene. The gene codes for a 1,500 amino acid protein, predicted to be a P-type cation-transporting ATPase. The gene product is most similar to a bacterial copper-transporting ATPase and additionally contains six putative metal-binding motifs at the N-terminus. The gene is transcribed in all cell types tested except liver, consistent with the expression of the Menkes defect.

Signal transduction between the two regulatory components involved in the regulation of the kdpABC operon in Escherichia coli: phosphorylation-dependent functioning of the positive regulator, KdpE

The proteins KdpD and KdpE are crucial to the osmotic regulation of the kdpABC operon that is responsible for the high-affinity K+ ion transport system in Escherichia coli. We demonstrated previously that the response regulator, KdpE, is capable of undergoing phosphorylation mediated by the sensory protein kinase, KdpD. In this study, we obtained biochemical evidence supporting the view that when KdpE is phosphorylated, it takes on an active form that exhibits relatively high affinity for the kdpABC promoter, which in turn results in activation of the kdpABC operon. It was also suggested that the central hydrophobic domain of KdpD, which is conceivably responsible for membrane anchoring of this protein, plays a role in the signalling mechanism underlying KdpE phosphorylation in response to hyperosmotic stress.

The phosphorylation site of the Kdp-ATPase of Escherichia coli: site-directed mutagenesis of the aspartic acid residues 300 and 307 of the KdpB subunit

The potassium-translocating Kdp-ATPase of Escherichia coli shares common functional properties with eukaryotic P-type ATPases. The KdpB subunit has been identified as the catalytic subunit forming the phosphorylated intermediate. Substitution of Asp-307 in KdpB by Glu, Asn, Gln, Tyr, His, Ala or Ser by site-directed mutagenesis and the subsequent transfer of the point mutations to the chromosome revealed that the mutants were not functioning with respect to cell growth at low K+ concentrations and ATPase activity as well as phosphorylation capacity of the purified Kdp complex. These findings indicate that Asp-307 in KdpB is the phosphorylation site of the Kdp-ATPase. In contrast, replacement of the close but non-conserved Asp-300 by Asn or Glu has no immediate influence on the enzyme functions tested. However, the Km for K+ of the ATPase activity has been increased 30-fold compared with the wild-type enzyme.

Isolation and characterization of the high-affinity K(+)-translocating ATPase from Rhodobacter sphaeroides

Cells of the purple nonsulfur bacterium Rhodobacter sphaeroides express a high-affinity K+ uptake system when grown in media with low K+ concentrations. A vanadate-sensitive, K(+)-stimulated and Mg(2+)-stimulated ATPase was purified from membranes of these cells by solubilization with decyl-beta-D-maltoside in the presence of Escherichia coli phospholipids followed by triazine-dye affinity chromatography. This primary transport system has a substrate specificity and an inhibitor sensitivity closely similar to those of the Kdp ATPase from E. coli and is composed of three subunits with molecular masses of 70.0, 43.5, and 23.5 kDa.

The laws of cell energetics

Recent progress in membrane bioenergetics studies has resulted in the important discovery that Na+ can effectively substitute for H+ as the energy coupling ion. This means that living cells can possess three convertible energy currencies, i.e. ATP, protonic and sodium potentials. Analysis of interrelations of these components in various types of living cells allows bioenergetic laws of universal applicability to be inferred.

Phosphotransfer signal transduction between two regulatory factors involved in the osmoregulated kdp operon in Escherichia coli

The proteins KdpD and KdpE are regulatory factors critically involved in the osmotic regulation of the kdpABC operon that is responsible for a high-affinity transport system in Escherichia coli. In this study, we obtained biochemical evidence supporting the view that the KdpD protein is a sensory protein kinase that exhibits autophosphorylation and KdpE-phosphotransfer characteristics. During the course of such studies we established a procedure for purifying the KdpE protein in large quantities. We also developed a procedure for preparing cytoplasmic membrane enriched with the KdpD protein that exhibits in vitro ability with regard to phosphorylation of KdpE protein.

Clarification of the structural and functional features of the osmoregulated kdp operon of Escherichia coli

Expression of the Escherichia coli kdpABC operon, which is responsible for a high-affinity potassium-uptake system, is regulated in response to a change in the medium osmolarity. In this study, we clarified the structure and function of the kdpABC promoter including its regulatory sequence at the molecular level. The canonical -35 and -10 regions determined for the promoter were not fully functional, i.e. in addition to them, a cis-acting sequence located upstream of the -35 region was essential for full activation of the promoter. This upstream sequence was demonstrated to be the target site for the trans-acting activator, KdpE.

A physical and genetic map of the Spiroplasma citri genome

A physical and genetic map of the Spiroplasma citri genome has been constructed using several restriction enzymes and pulsed field gel electrophoresis. A number of genes were subsequently localized on the map by the use of appropriate probes. The genome size of the spiroplasma estimated from restriction fragments is close to 1780 kbp, the largest of all Mollicutes studied so far. It contains multisite insertions of Spiroplasma virus 1 (SpV1) sequences. The physical and genetic map of the S. citri genome shares several features with that of other Mollicutes, especially those in the Mycoplasma mycoides cluster. This supports the finding that S. citri and these Mycoplasma spp. are phylogenetically related.

MgtA and MgtB: prokaryotic P-type ATPases that mediate Mg2+ influx

The gram-negative bacterium Salmonella typhimurium possesses three distinct Mg2+ transport systems, encoded by the corA, mgtA, and mgtB loci. The CorA transport system is the constitutive Mg2+ influx system. It can also mediate Mg2+ efflux at very high extracellular Mg2+ concentrations. In contrast, the MgtA and MgtB Mg2+ transport systems are normally expressed only at low extracellular Mg2+ concentrations. A strain of S. typhimurium was constructed by mutagenesis which lacks Mg2+ transport and requires 100 mM Mg2+ for growth. Using this strain, both the MgtA and MgtB transport systems were cloned by complementation of the strains inability to grow without Mg2+ supplementation. After sequencing and further genetic analysis, the MgtB system appears to be an operon composed of the mgtC and mgtB genes (5' to 3'). The downstream mgtB gene encodes the 102 kDa MgtB protein which by sequence analysis is clearly a P-type ATPase. Interestingly, while MgtB has relatively poor homology to other known prokaryotic P-type ATPases, it is highly homologous to mammalian reticular Ca(2+)-ATPases. MgtC is a 22.5 kDa hydrophobic membrane protein that lacks homology to any known protein. Transposon insertions in this gene abolish uptake by the MgtB transport system. We hypothesize that MgtC is a subunit of the MgtB ATPase involved either in proper insertion of MgtB into the membrane or possibly in binding of extracellular Mg2+ for delivery to the ATPase subunit. The sequence of the MgtA gene has recently been completed, and it too is a P-type ATPase more similar to eukaryotic than prokaryotic P-type ATPases. Expression of both MgtA and MgtB are highly regulated by the concentration of extracellular Mg2+. Transcription of mgtB can be increased about 1000 fold by lowering Mg2+ from 1 mM to 1 microM. Likewise, when mgtB is expressed from a multicopy plasmid, a similar decrease in extracellular Mg2+ greatly increases transport. Under growth conditions of limiting Mg2+, MgtB becomes the dominant Mg2+ influx system in S. typhimurium. Even so, since MgtB (and MgtA) mediate only influx of Mg2+, it is unclear why the cell requires energy from ATP to mediate Mg2+ entry into the cell down a large electrochemical gradient. Further studies of the structure-function and energetics of these novel Mg2+ influx P-type ATPases should yield insights into the function of P-type ATPases in general as well as information about the regulation of cellular Mg2+ fluxes.

Cloning and expression in yeast of a plant potassium ion transport system

A membrane polypeptide involved in K+ transport in a higher plant was cloned by complementation of a yeast mutant defective in K+ uptake with a complementary DNA library from Arabidopsis thaliana. A 2.65-kilobase complementary DNA conferred ability to grow on media with K+ concentration in the micromolar range and to absorb K+ (or 86Rb+) at rates similar to those in wild-type yeast. The predicted amino acid sequence (838 amino acids) has three domains: a channel-forming region homologous to animal K+ channels, a cyclic nucleotide-binding site, and an ankyrin-like region.

The products of the kdpDE operon are required for expression of the Kdp ATPase of Escherichia coli

The expression of the Kdp system for K+ uptake in Escherichia coli requires the products of two genes, kdpD and kdpE. These genes constitute an operon adjacent to the kdpABC operon that encodes the three membrane protein subunits of Kdp. Both operons are transcribed in the same direction and overlap; the kdpDE promoter is in kdpC, the last gene of the kdpABC operon. Transcription of the kdpDE operon is at a low level when Kdp is not expressed; transcription increases about 10-fold when kdpABC is turned on, indicating significant read-through of the kdpDE operon by transcripts beginning at the promoter of kdpABC operon. The proximal region of the kdpD gene is the site of most mutations that lead to constitutive expression of the kdpABC operon.

KdpD and KdpE, proteins that control expression of the kdpABC operon, are members of the two-component sensor-effector class of regulators

The Kdp system of Escherichia coli, a transport ATPase with high affinity for potassium, is expressed when turgor pressure is low. Expression requires KdpD, a 99-kDa membrane protein, and KdpE, a 25-kDa soluble cytoplasmic protein. The sequences of KdpD and KdpE show they are members of the sensor-effector class of regulatory proteins: the C-terminal half of KdpD is homologous to sensors such as EnvZ and PhoR, and KdpE is homologous to effectors such as OmpR and PhoB. The predicted structure of KdpD suggests that it is anchored to the membrane by four membrane-spanning segments near its middle, with both C- and N-terminal portions in the cytoplasm. Subcellular fractionation confirms the expected location of the protein in the inner membrane. The N-terminal region has no homology to known proteins and is the site of mutations that make Kdp expression partially constitutive; this portion may serve to sense turgor pressure. Since several other sensor-effectors have been shown to mediate control through phosphorylation, this mechanism is proposed to control expression of Kdp.

Surface presentation of Shigella flexneri invasion plasmid antigens requires the products of the spa locus

An avirulent, invasion plasmid insertion mutant of Shigella flexneri 5 (pHS1059) was restored to the virulence phenotype by transformation with a partial HindIII library of the wild-type invasion plasmid constructed in pBR322. Western immunoblot analysis of pHS1059 whole-cell lysates revealed that the synthesis of the invasion plasmid antigens VirG, IpaA, IpaB, IpaC, and IpaD was similar to that seen in the corresponding isogenic S. flexneri 5 virulent strain, M90T. IpaB and IpaC, however, were not present on the surface of pHS1059 as was found in M90T, suggesting that the transport or presentation of the IpaB and IpaC proteins onto the bacterial surface was defective in the mutant. pHS1059 was complemented by pWR266, which carried contiguous 1.2- and 4.1-kb HindIII fragments of the invasion plasmid. pHS1059(pWR266) cells were positive in the HeLa cell invasion assay as well as colony immunoblot and enzyme-linked immunosorbent assays, using monoclonal antibodies to IpaB and IpaC. These studies established that the antigens were expressed on the surface of the transformed bacteria. In addition, water extraction of pHS1059 and pHS1059(pWR266) whole cells, which can be used to remove IpaB and IpaC antigens from the surface of wild-type M90T bacteria, yielded significant amounts of these antigens from pHS1059(pWR266) but not from pHS1059. Minicell and DNA sequence analysis indicated that several proteins were encoded by pWR266, comprising the spa loci, which were mapped to a region approximately 18 kb upstream of the ipaBCDAR gene cluster. Subcloning and deletion analysis revealed that more than one protein was involved in complementing the Spa- phenotype in pHS1059. One of these proteins, Spa47, showed striking homology to ORF4 of the Bacillus subtilis flaA locus and the fliI gene sequence of Salmonella typhimurium, both of which bear strong resemblance to the alpha and beta subunits of bacterial, mitochondrial, and chloroplast proton-translocating F0F1 ATPases.

Epitope mapping by amino-acid-sequence-specific antibodies reveals that both ends of the alpha subunit of Na+/K(+)-ATPase are located on the cytoplasmic side of the membrane

Right-side-out vesicles of pig kidney microsomes and amino-acid-sequence-specific antibodies were used to probe the sidedness of the C-terminus and the N-terminus of the catalytic alpha subunit of Na+/K(+)-ATPase. Polyclonal antibodies were raised in rabbits against the peptide corresponding to the N-terminal sequence GRDKYEPAAVSE (peptide 1-12) and against peptides corresponding to the C-terminal sequences IFVYDEVRKLIIRRR (peptide 991-1005) and RPGGWVEKETYY (peptide 1005-1016). These antibodies were purified by affinity chromatography on the respective peptide-Sepharose columns. Moreover, antibodies against the N-terminal dodecapeptide GRDKYEPAAVSE were obtained by affinity purification from heteroclonal antibodies against the alpha subunit of pork kidney Na+/K(+)-ATPase. These antibodies reacted with native as well as SDS-denaturated Na+/K(+)-ATPase. When the antibodies were used to probe the sidedness of the sequences in right-side-out vesicles of pig kidney microsomes, the N-terminal peptide 1-12 as well as the C-terminal peptides 991-1005 and 1005-1016 were found on the cytosolic side. Concanavalin A, however, which interacts with the beta subunit, a glycoprotein, reacted with the outside of right-side-out vesicles.

Salmonella typhimurium mutants defective in flagellar filament regrowth and sequence similarity of FliI to F0F1, vacuolar, and archaebacterial ATPase subunits

Many flagellar proteins are exported by a flagellum-specific export pathway. In an initial attempt to characterize the apparatus responsible for the process, we designed a simple assay to screen for mutants with export defects. Temperature-sensitive flagellar mutants of Salmonella typhimurium were grown at the permissive temperature (30 degrees C), shifted to the restrictive temperature (42 degrees C), and inspected in a light microscope. With the exception of switch mutants, they were fully motile. Next, cells grown at the permissive temperature had their flagellar filaments removed by shearing before the cells were shifted to the restrictive temperature. Most mutants were able to regrow filaments. However, flhA, fliH, fliI, and fliN mutants showed no or greatly reduced regrowth, suggesting that the corresponding gene products are involved in the process of flagellum-specific export. We describe here the sequences of fliH, fliI, and the adjacent gene, fliJ; they encode proteins with deduced molecular masses of 25,782, 49,208, and 17,302 Da, respectively. The deduced sequence of FliI shows significant similarity to the catalytic beta subunit of the bacterial F0F1 ATPase and to the catalytic subunits of vacuolar and archaebacterial ATPases; except for limited similarity in the motifs that constitute the nucleotide-binding or catalytic site, it appears unrelated to the E1E2 class of ATPases, to other proteins that mediate protein export, or to a variety of other ATP-utilizing enzymes. We hypothesize that FliI is either the catalytic subunit of a protein translocase for flagellum-specific export or a proton translocase involved in local circuits at the flagellum.

Systematic characterization of curved DNA segments randomly cloned from Escherichia coli and their functional significance

In addition to the set of curved DNA segments isolated previously from Escherichia coli, another set of curved DNA segments has now been isolated. To gain an insight into the functional significance of these curved DNA sequences, systematic analyses were carried out, which included not only mapping of the precise locations of the segments on the E. coli chromosome but also clarification of the gene organization in the chromosomal regions surrounding the curved DNA sequences. It was demonstrated that most of the curved DNA sequences, which have been characterized so far, appear to be located immediately upstream of the coding sequences of adjacent genes. It was also demonstrated that an E. coli histone-like protein, named H-NS (or H1a), exhibits a strong affinity for naturally occurring curved DNA sequences in regions upstream promoters.

The cloning and DNA sequence of the gene for the glutathione-regulated potassium-efflux system KefC of Escherichia coli

The kefC gene of Escherichia coli encodes a potassium-efflux system that is regulated by glutathione metabolites. The close proximity of the E. coli kefC gene to the folA gene, encoding dihydrofolate reductase, has been utilized to clone the structural gene for the system from a Clarke-Carbon plasmid. The cloned gene has been refined to a region of DNA approximately 2.1 kb in length using exonuclease III-generated deletions and random MudII1734 (lacZ) insertions. The direction of transcription has been deduced from the orientation of the Mu insertions in the cloned DNA. A hybrid protein consisting of approximately two thirds of the KefC protein fused to beta-galactosidase has been shown to be membrane-located. The DNA sequence of the gene has been determined and an open reading frame of 1.86 kb has been located which could encode a protein of 620 amino acids (79010 Da). Using the T7 expression system a membrane protein, of apparent molecular mass 55-60 kDa, has been shown to be encoded by the kefC gene. The predicted protein sequence shows a highly hydrophobic amino-terminus and a strongly hydrophilic carboxy-terminus. Comparison of the amino acid sequence of the kefC gene product with those of two glutathione-utilizing enzymes, glyoxalase and dehalogenase, has revealed some similarities.

The bacterial Kdp K(+)-ATPase and its relation to other transport ATPases, such as the Na+/K(+)- and Ca2(+)-ATPases in higher organisms

The Kdp system is a three-subunit member of the E1-E2 family of transport ATPases. There is sequence homology of the 72 kDa KdpB protein, the largest subunit of Kdp, with the other members of this family. The predicted structure of the 21 kDa KdpC subunit resembles that of the beta subunit of the Na+,K(+)-ATPase, suggesting that these subunits may have a similar function. The 59 kDa KdpA subunit has no known homologue; it is very hydrophobic and is predicted to cross the membrane 10-12 times. Genetic studies implicate this subunit in the binding of K+. As the binding site must be close to the beginning of the transmembrane channel, we suggest that KdpA also forms most or all of the latter. KdpA may have evolved from a K+/H+ antiporter that was recruited by the KdpB precursor to achieve the high affinity and specificity for K+, and the activation of transport by low turgor pressure characteristic of Kdp. Turgor pressure controls the expression of Kdp. This action is dependent on the 70 kDa KdpD and 23 kDa KdpE proteins. We are in the process of sequencing these genes. KdpE is homologous to the smaller protein of other members of a family of pairs of regulatory proteins implicated in control of a variety of bacterial processes such as porin synthesis, phosphate regulon expression, nitrogen metabolism, chemotaxis and nodule formation.

Amplification of the phosphorylation site-ATP-binding site cDNA fragment of the Na+,K(+)-ATPase and the Ca2(+)-ATPase of Drosophila melanogaster by polymerase chain reaction

In vitro DNA-amplification technique has been utilized to generate a 430 bp fragment of the Na+,K(+)-ATPase, and a 550 bp fragment of a Ca2(+)-ATPase (the sarcoplasmic reticulum-type) of Drosophila melanogaster. The oligonucleotide primers for the DNA-amplification (Polymerase Chain Reaction) had been designed on the basis of amino acid sequence motifs--the phosphorylation site and the ATP-binding site--conserved among members of the ATPase protein family. Using the amplified cDNA-segments as probes, we demonstrated that there is one Na+,K(+)-ATPase and one Ca2(+)-ATPase (sarcoplasmic reticulum-type) gene in the Drosophila genome. Three different mRNA species are processed from the Na+,K(+)-ATPase gene and one from the Ca2(+)-ATPase gene. Developmental control in expression of the Ca2(+)-ATPase gene was observed.

Transmembrane segments of the P-type cation-transporting ATPases. A comparative study

The transmembrane segments predicted for the Neurospora H-ATPase are laid out diagrammatically in Figure 10. Although the eight segments have arbitrarily been compressed into rectangles of the same size, they range in length from 20 residues (II) to 30 residues (IV and VI), so the corresponding helices must vary in length as well. Notable features of the model include the charged residues located just outside the plane of the membrane, with a clear excess of negative charges (5-, 1+) at the extracellular surface and a slight excess of positive charges (4+, 3-) at the cytoplasmic surface. There are also a conspicuous number of bulky residues (tryptophan, phenylalanine, and tyrosine) just inside the plane of the membrane. Within the bilayer, most of the helices are noticeably amphipathic, consistent with the expectation that at least some of them stack together to form a channel-like structure with a hydrophobic surface and a hydrophilic core. The charged residues predicted to lie within the membrane are listed in Table 2, which is a summary of data from eight of the P-type ATPases; the S. cerevisiae and S. pombe enzymes have not been included because they are nearly identical in this respect to the Neurospora enzyme. Interestingly, all of the ATPases have more membrane-embedded negative charges (5 to 8) than positive ones (0 to 4), a pattern that may be connected with their role as cation transporters. Certainly, other unrelated transport proteins have a rather different pattern of positive and negative charges: for example, the mammalian glucose transporter (1+, 2-), Na-glucose transporter (3+, 3-), and the E. coli lac permease (11+, 7-). The actual positioning of the negative charges in the P-type ATPases does not make it easy to single out the functionally important ones, however. The glutamyl residue in segment I is present in the fungal, plant, and Leishmania H-ATPases but not in the gastric H,K-ATPase. The same is true for the aspartate in segment II, except that it also appears in the muscle and brain Ca-ATPases. A glutamate is found at one end of segment III in the E. coli and fungal enzymes and at the other end in Arabidopsis; in segment IV, another glutamate appears in a well-conserved region in the Leishmania and mammalian enzymes but not in the bacterial, fungal, or plant ones.(ABSTRACT TRUNCATED AT 400 WORDS)

Protein phosphorylation and regulation of adaptive responses in bacteria

Bacteria continuously adapt to changes in their environment. Responses are largely controlled by signal transduction systems that contain two central enzymatic components, a protein kinase that uses adenosine triphosphate to phosphorylate itself at a histidine residue and a response regulator that accepts phosphoryl groups from the kinase. This conserved phosphotransfer chemistry is found in a wide range of bacterial species and operates in diverse systems to provide different regulatory outputs. The histidine kinases are frequently membrane receptor proteins that respond to environmental signals and phosphorylate response regulators that control transcription. Four specific regulatory systems are discussed in detail: chemotaxis in response to attractant and repellent stimuli (Che), regulation of gene expression in response to nitrogen deprivation (Ntr), control of the expression of enzymes and transport systems that assimilate phosphorus (Pho), and regulation of outer membrane porin expression in response to osmolarity and other culture conditions (Omp). Several additional systems are also examined, including systems that control complex developmental processes such as sporulation and fruiting-body formation, systems required for virulent infections of plant or animal host tissues, and systems that regulate transport and metabolism. Finally, an attempt is made to understand how cross-talk between parallel phosphotransfer pathways can provide a global regulatory curcuitry.

Nature and site of phospholamban regulation of the Ca2+ pump of sarcoplasmic reticulum

The rapid removal of Ca2+ ions from the cytosol, necessary for the efficient relaxation of cardiac muscle cells, is performed by the Ca2+-pumping ATPase of the sarcoplasmic reticulum. The calcium pump is activated by cyclic AMP- and calmodulin-dependent phosphorylation of phospholamban, an integral membrane protein of the sarcoplasmic reticulum. Using a heterobifunctional crosslinking agent which can be cleaved and photoactivated, we provide evidence for a direct interaction between the two proteins. Only the non-phosphorylated form of phospholamban interacts with the ATPase, demonstrating that phospholamban is an endogenous inhibitor that is removed from the ATPase by phosphorylation. Non-phosphorylated phospholamban interacts only with the calcium-free conformation of the ATPase and is released when it is converted to the calcium-bound state. We localized the site of interaction to a single peptide isolated after cyanogen bromide cleavage of the ATPase. The peptide derives from a domain just C-terminal to the aspartyl phosphate of the active site. This domain is unique to ATPases of the sarcoplasmic reticulum in that it has no homology with any other phosphorylation-type ion pump. The domain occurs in both slow- and fast-twitch isoforms of the ATPase, even though phospholamban is not expressed in fast-twitch muscles.

Amino acids bracketing the predicted transmembrane domains of membrane proteins

The cell membrane is a complex mixture of several classes of biomolecules but amino acids and lipids are the main constituents. For this reason we are establishing a data base of transmembrane proteins with the intent of using the data base to identify interfacial peptide sequences useful for studying protein-lipid interactions at membrane interfaces. Our present intention is to characterize transmembrane peptides and amino acids found near the membrane interface. A data base containing only signal peptides is available (G. von Heijne, Prot. Seq. Data Anal. 1:41-42, 1987).

Characterization of a cysteine-containing peptide after affinity labelling of Ca2+-ATPase of sarcoplasmic reticulum with the disulfide of 3'(2')-O-biotinyl-thioinosine triphosphate

3'(2')-O-Biotinyl-thioinosine triphosphate is a substrate of the Ca2+ pump of sarcoplasmic reticulum. Its disulfide inactivates the Ca2+-ATPase with two different velocities. The rapidly inactivated sulfhydryl group cannot be protected by ATP and is therefore considered to be outside the ATP binding site. The slowly reacting sulfhydryl group interacts with the disulfide of 3'(2')-O-biotinyl-thioinosine triphosphate with a dissociation constant of Kd = 137 microM and an inactivation velocity constant of 1.7 X 10(-3) s-1. It is protected by ATP with two different dissociation constants of the enzyme-ATP complex of Kd = 221 microM and 1130 microM. The slowly reacting sulfhydryl group is therefore considered to be part of the ATP binding site. Since it was impossible to isolate a tryptic peptide by affinity purification on matrix-bound avidin after affinity labelling with the disulfide of 3'(2')-O-biotinyl-thioinosine triphosphate, differential labelling with iodo[2-14C]acetic acid after affinity labelling with the disulfide of 3'(2')-O-biotinyl-thioinosine triphosphate was carried out. Tryptic digestion and FPLC purification led to the isolation of a radioactive carboxymethyl derivative of the cysteine-containing peptide ANACNSVIR. This peptide is equivalent to the cDNA-derived sequence 468-476 of Ca2+-ATPase [Brandl et al. (1986) Cell 44, 597-607] and is located between the phosphorylation site, Asp351, and Lys515, a part of the putative purine binding subsite of ATP. Although the carboxymethylation of Cys471 is hindered by (biotinyl-s6ITP)2, the strong dilution of the specific radioactivity of iodo[2-14C]acetic acid in the isolated peptide 468-476 argues against its direct interaction with the ATP analogue. It is therefore proposed that Cys471 undergoes ATP-dependent conformational changes.

Cadmium resistance from Staphylococcus aureus plasmid pI258 cadA gene results from a cadmium-efflux ATPase

Cadmium resistance specified by the cadA determinant of Staphylococcus aureus plasmid pI258 results from the functioning of a cadmium-efflux system. In the nucleotide sequence of the DNA fragment containing the cadA determinant, two open reading frames were identified. The larger one, corresponding to a predicted polypeptide of 727 amino acid residues, is necessary and sufficient for expression of cadmium resistance. Comparison of the CadA amino acid sequence with known protein sequences suggested that CadA is a member of the E1E2 cation-translocating ATPases, similar to the K+-uptake ATPases of Gram-positive and Gram-negative bacteria. The sequence homology is lower but significant with other E1E2-type ATPases, including the H+-efflux ATPases of eukaryotic microbes and the Ca2+- and Na+/K+-ATPases of animals. A frame-shift mutation in the middle of the gene destroys the Cd2+-resistance phenotype. A detailed model for the putative CadA ATPase based on homologies to other E1E2 ATPases is presented and discussed.