Two types of Bacillus subtilis tetA(L) deletion strains reveal the physiological importance of TetA(L) in K(+) acquisition as well as in Na(+), alkali, and tetracycline resistance

The chromosomally encoded TetA(L) protein of Bacillus subtilis is a multifunctional tetracycline-metal/H(+) antiporter that also exhibits monovalent cation/H(+) antiport activity and a net K(+) uptake mode. In this study, B. subtilis mutant strains JC112 and JC112C were found to be representative of two phenotypic types of tetA(L) deletion strains that are generated in the same selection. Both strains exhibited increased sensitivity to low tetracycline concentrations as expected. The mutants also had significantly reduced ability to grow in media containing low concentrations of K(+), indicating that the net K(+) uptake mode is of physiological consequence; the deficit in JC112 was greater than in JC112C. JC112 also exhibited (i) greater impairment of Na(+)- or K(+)-dependent growth at pH 8.3 than JC112C and (ii) a greater degree of Co(+2) as well as Na(+) sensitivity. Studies were initiated to explore the possibility of two different patterns of compensatory changes in other ion-translocating transporters in these mutants. Increased expression of two loci has thus far been shown. Increased expression of czcD-trkA, a locus with a proposed involvement in K(+) uptake, occurred in both mutants. The increase was highest in the presence of Co(2+) and was higher in JC112 than in JC112C. Deletion of czcD-trkA resulted in diminished growth of the wild-type and both mutant strains at low [K(+)], supporting a significant role for this locus in K(+) uptake. Expression of yheL, which is a homologue of the Na(+)/H(+) antiporter-encoding nhaC gene from Bacillus firmus OF4, was also increased in both tetA(L) deletion strains, again with higher up-regulation in JC112. The phenotypes resulting from deletion of yheL were consistent with a modest role for YheL in Na(+)-dependent pH homeostasis in the wild type. No major role for YheL was indicated in the mutants in spite of the overexpression. The studies underscore the multiple physiological functions of TetA(L), including tetracycline, Na(+), and alkali resistance and K(+) acquisition. The studies also reveal and begin to detail the complexity of the response to mutational loss of these functions.     

TetL tetracycline efflux protein from Bacillus subtilis is a dimer in the membrane and in detergent solution

The TetL antiporter from the Bacillus subtilis inner membrane is a tetracycline-divalent cation efflux protein that is energized by the electrochemical proton gradient across the membrane. In this study, we expressed tetL in Escherichia coli and investigated the oligomeric state of TetL in the membrane and in detergent solution. Evidence for an oligomeric state of TetL emerged from SDS-PAGE and Western blot analysis of membrane samples as well as purified protein samples from cells that expressed two differently tagged TetL species. Furthermore, no formation or restoration of TetL oligomers occurred upon detergent solubilization of the membrane. Rather, oligomeric forms established in vivo persisted after solubilization. Mass spectrometry of the purified protein showed the absence of proteolysis and posttranslational modifications. Analytical size-exclusion chromatography of the purified protein revealed a dimeric TetL in dodecyl-maltoside solution. In addition, TetL dimers were found in a number of other detergents and over a wide pH range. It is therefore likely that the oligomeric form of the protein in the membrane is also a dimer.     

Effects of nonpolar mutations in each of the seven Bacillus subtilis mrp genes suggest complex interactions among the gene products in support of Na(+) and alkali but not cholate resistance

The Bacillus subtilis mrp (multiple resistance and pH) operon supports Na(+) and alkali resistance via an Na(+)/H(+) antiport, as well as cholate efflux and resistance. Among the individual mutants with nonpolar mutations in each of the seven mrp genes, only the mrpF mutant exhibited cholate sensitivity and a cholate efflux defect that were complemented by expression of the deleted gene in trans. Expression of mrpF in the mrp null (VKN1) strain also restored cholate transport and increased Na(+) efflux, indicating that MrpF does not require even low levels of other mrp gene expression for its own function. In contrast to MrpF, MrpA function had earlier seemed to depend upon at least modest expression of other mrp genes, i.e., mrpA restored Na(+) resistance and efflux to strain VK6 (a polar mrpA mutant which expresses low levels of mrpB to -G) but not to the null strain VKN1. In a wild-type background, each nonpolar mutation in individual mrp genes caused profound Na(+) sensitivity at both pH 7.0 and 8.3. The mrpA and mrpD mutants were particularly sensitive to alkaline pH even without added Na(+). While transport assays in membrane vesicles from selected strains indicated that MrpA-dependent antiport can occur by a secondary, proton motive force-dependent mechanism, the requirement for multiple mrp gene products suggests that there are features of energization, function, or stabilization that differ from typical secondary membrane transporters. Northern analyses indicated regulatory relationships among mrp genes as well. All the mrp mutants, especially the mrpA, -B, -D, -E, and -G mutants, had elevated levels of mrp RNA relative to the wild type. Expression of an upstream gene, maeN, that encodes an Na(+)/malate symporter, was coordinately regulated with mrp, although it is not part of the operon.     

Characterization of the Pho89 phosphate transporter by functional hyperexpression in Saccharomyces cerevisiae

The Na(+)-coupled, high-affinity Pho89 plasma membrane phosphate transporter in Saccharomyces cerevisiae has so far been difficult to study because of its low activity and special properties. In this study, we have used a pho84Deltapho87Deltapho90Deltapho91Delta quadruple deletion strain of S. cerevisiae devoid of all transporter genes specific for inorganic phosphate, except for PHO89, to functionally characterize Pho89 under conditions where its expression is hyperstimulated. Under these conditions, the Pho89 protein is strongly upregulated and is the sole high-capacity phosphate transporter sustaining cellular acquisition of inorganic phosphate. Even if Pho89 is synthesized in cells grown at pH 4.5-8.0, the transporter is functionally active under alkaline conditions only, with a K(m) value reflecting high-affinity properties of the transporter and with a transport rate about 100-fold higher than that of the protein in a wild-type strain. Even under these hyperexpressive conditions, Pho89 is unable to sense and signal extracellular phosphate levels. In cells grown at pH 8.0, Pho89-mediated phosphate uptake at alkaline pH is cation-dependent with a strong activation by Na(+) ions and sensitivity to carbonyl cyanide m-chlorophenylhydrazone. The contribution of H(+)- and Na(+)-coupled phosphate transport systems in wild-type cells grown at different pH values was quantified. The contribution of the Na(+)-coupled transport system to the total cellular phosphate uptake activity increases progressively with increasing pH.     

The C-terminal domain of the neutral amino acid transporter SNAT2 regulates transport activity through voltage-dependent processes

SNAT (sodium-coupled neutral amino acid transporter) 2 belongs to the SLC38 (solute carrier 38) family of solute transporters. Transport of one amino acid molecule into the cell is driven by the co-transport of one Na(+) ion. The functional significance of the C-terminus of SNAT2, which is predicted to be located in the extracellular space, is currently unknown. In the present paper, we removed 13 amino acid residues from the SNAT2 C-terminus and studied the effect of this deletion on transporter function. The truncation abolished amino acid transport currents at negative membrane potentials (<0 mV), as well as substrate uptake. However, transport currents were observed at positive membrane potentials demonstrating that transport was accelerated while the driving force decreased. Membrane expression levels were normal in the truncated transporter. SNAT2(Del C-ter) (13 residues deleted from the C-terminus) showed 3-fold higher apparent affinity for alanine, and 2-fold higher Na(+) affinity compared with wild-type SNAT2, suggesting that the C-terminus is not required for high-affinity substrate and Na(+) interaction with SNAT2. The pH sensitivity of amino acid transport was retained partially after the truncation. In contrast with the truncation after TM (transmembrane domain) 11, the deletion of TM11 resulted in an inactive transporter, most probably due to a defect in cell surface expression. Taken together, the results demonstrate that the C-terminal domain of SNAT2 is an important voltage regulator that is required for a normal amino acid translocation process at physiological membrane potentials. However, the C-terminus appears not to be involved in the regulation of membrane expression.     

Impact of the Mg<Superscript>2+</Superscript>-citrate transporter CitM on heavy metal toxicity in <Emphasis Type="Italic">Bacillus subtilis</Emphasis>

Bacillus subtilis possesses a secondary transporter, CitM, that is specific for the complex of citrate and Mg(2+) but is also capable of transporting citrate in complex with the heavy metal ions Zn(2+), Ni(2+) and Co(2+). We report on the impact of CitM activity on the toxicity of Zn(2+), Ni(2+) and Co(2+) in B. subtilis. In a citM deletion mutant or under conditions in which CitM is not expressed, the toxic effects of the metals were reduced by the presence of citrate in the medium. In contrast, the presence of citrate dramatically enhanced toxicity when the Mg(2+)-citrate transporter was present in the membrane. It is demonstrated that the complex of Ni(2+) and citrate is transported into the cell and that the uptake is responsible for the enhanced toxicity. At toxic concentrations of the metal ions, the cultures adapted by developing tolerance against these ions. Tolerant cells isolated by exposure to one of the metal ions remained tolerant after growth in the absence of toxic metal ions and were cross-tolerant against the other two toxic ions. Tolerant strains were shown to contain point mutations in the citM gene, which resulted in premature termination of translation.     

High-Frequency RecA-Dependent and -Independent Mechanisms of Congo Red Binding Mutations in Yersinia pestis

Yersinia pestis, which causes bubonic and pneumonic plague, forms pigmented red colonies on Congo red (CR) dye agar. The hmsHFRS genes required for CR binding (Crb(+)) are genetically linked to virulence-associated genes encoding a siderophore uptake system. These genes are contained in a 102-kb chromosomal pgm locus that is lost in a high-frequency deletion event, resulting in loss of the Crb(+) phenotype. We constructed a recA mutant strain of Y. pestis KIM10+ (YPRA) to test whether the high frequency Crb mutants result from a RecA-mediated deletion of the IS100-flanked pgm locus. Two Pgm-associated phenotypes (Crb(+) and pesticin sensitivity [Pst(s)]) were used as markers for the presence of the pgm locus in the RecA(+) KIM10+ and RecA(-) YPRA strains. In KIM10+, both phenotypes were lost at a very high (2 x 10(-3)) frequency, due to the deletion of the entire pgm locus. In YPRA, the Crb(+) phenotype was still lost at a high frequency (4.5 x 10(-5)), although the loss of the Pst(s) phenotype occurred at spontaneous antibiotic resistance mutation frequencies (2 x 10(-7)). These RecA-independent Crb(-) mutants were caused by mutations in both the hmsHFRS locus and in a newly identified gene, hmsT. Nonpigmented Yersinia pseudotuberculosis and Escherichia coli strains transformed with both hmsT and hmsHFRS became Crb(+). This study demonstrates that in a laboratory culture, the Crb(+) phenotype is unstable, independent of the pgm locus deletion. We propose that a lack of selection for the CR-binding ability of Y. pestis in vitro may contribute to the mutation frequencies observed at the hmsHFRS and hmsT loci.     

Homologous protein subunits from Escherichia coli NADH:quinone oxidoreductase can functionally replace MrpA and MrpD in Bacillus subtilis

The complex I subunits NuoL, NuoM and NuoN are homologous to two proteins, MrpA and MrpD, from one particular class of Na+/H+ antiporters. In many bacteria MrpA and MrpD are encoded by an operon comprising 6-7 conserved genes. In complex I these protein subunits are prime candidates for harboring important parts of the proton pumping machinery. Deletion of either mrpA or mrpD from the Bacillus subtilis chromosome resulted in a Na+ and pH sensitive growth phenotype. The deletion strains could be complemented in trans by their respective Mrp protein, but expression of MrpA in the B. subtilis ΔmrpD strain and vice versa did not improve growth at pH 7.4. This corroborates that the two proteins have unique specific functions. Under the same conditions NuoL could rescue B. subtilis ΔmrpA, but improved the growth of B. subtilis ΔmrpD only slightly. NuoN could restore the wild type properties of B. subtilis ΔmrpD, but had no effect on the ΔmrpA strain. Expression of NuoM did not result in any growth improvement under these conditions. This reveals that the complex I subunits NuoL, NuoM and NuoN also demonstrate functional specializations. The simplest explanation that accounts for all previous and current observations is that the five homologous proteins are single ion transporters. Presumably, MrpA transports Na+ whereas MrpD transports H+ in opposite directions, resulting in antiporter activity. This hypothesis has implications for the complex I functional mechanism, suggesting that one Na+ channel, NuoL, and two H+ channels, NuoM and NuoN, are present.     

A viable Bacillus subtilis strain without functional extracytoplasmic function sigma genes

We constructed a Bacillus subtilis Marburg strain that harbors deletion mutations in all seven extracytoplasmic function (ECF) sigma genes. The strain shows wild-type growth at 37 degrees C both in a complex and in a synthetic medium and exhibits wild-type sporulation. ECF sigma genes of B. subtilis are dispensable as long as no stress is imposed, although they seem to be required for quick response to stresses.     

The activity profile of the NhaD-type Na+(Li+)/H+ antiporter from the soda Lake Haloalkaliphile Alkalimonas amylolytica is adaptive for the extreme environment

In extreme alkaliphiles, Na(+)/H(+) antiporters play a central role in the Na(+) cycle that supports pH homeostasis, Na(+) resistance, solute uptake, and motility. Properties of individual antiporters have only been examined in extremely alkaliphilic soil Bacillus spp., whereas the most alkaline natural habitats usually couple high pH with high salinity. Here, studies were conducted on a Na(+)(Li(+))/H(+) antiporter, NhaD, from the soda lake haloalkaliphile Alkalimonas amylolytica. The activity profile of A. amylolytica NhaD at different pH values and Na(+) concentrations reflects its unique natural habitat. In membrane vesicles from antiporter-deficient Escherichia coli EP432 (DeltanhaA DeltanhaB), the pH optimum for NhaD-dependent Na(+)(Li(+))/H(+) antiport was at least 9.5, the highest pH that could be tested; no activity was observed at pH < or =8.5. NhaD supported low Na(+)/H(+) antiport activity at pH 9.5 that was detectable over a range of Na(+) concentrations from 10 mM to at least 800 mM, with a 600 mM optimum. Although A. amylolytica nhaD was isolated by complementing the Li(+) sensitivity of the triple mutant E. coli strain KNabc (DeltanhaA DeltanhaB DeltachaA), sustained propagation of nhaD-bearing plasmids in this strain resulted in a glycine (Gly(327))-->serine mutation in a putative cytoplasmic loop of the mutant transporter. The altered activity profile of NhaD-G327S appears to be adaptive to the E. coli setting: a much higher activity than wild-type NhaD at Na(+) concentrations up to 200 mM but lower activity at 400 to 600 mM Na(+), with a pH optimum and minimal pH for activity lower than those of wild-type NhaD.     

Functions of tetracycline efflux proteins that do not involve tetracycline

Tet(L) and Tet(K) are specific antibiotic-resistance determinants. They catalyze efflux of a tetracycline(Tc)-divalent metal complex in exchange for protons, as do other Tet efflux proteins. These Tet proteins also catalyze Na+ and K+ exchange for protons. Each of the "cytoplasmic substrates", Na+, K+ and the Tc-metal ion complex, can also be exchanged for K+, a catalytic mode that accounts for the long-recognized K+ uptake capacity conferred by some Tet proteins. The multiple catalytic modes of Tet(L) and Tet(K) provide potential new avenues for development of inhibitors of these efflux systems as well as avenues for exploration of structure-function relationships. The multiple catalytic modes of Tet(L), which is chromosomally encoded in Bacillus subtilis, also correspond to diverse physiological roles, including roles in antibiotic-, Na+-, and alkali-resistance as well as K+ acquisition. The use of K+ as an external coupling ion may contribute not only to the organism's K+ uptake capacity but also to its ability to exclude Na+ and Tc at elevated pH values. Regulation of the chromosomal tetL gene by Tc has been proposed to involve a translational re-initiation mechanism that is novel for an antibiotic-resistance gene and increases Tet expression seven-fold. Other elements of tetL expression and its regulation are already evident, including gene amplification and use of multiple promoters. However, further studies are required to clarify the full panoply of regulatory mechanisms, and their integration to ensure different levels of tetL expression that are optimal for its different functions. It will also be of interest to investigate the implications of Tet(L) and Tet(K) multifunctionality on the emergence and persistence of these antibiotic-resistance genes.     

Role of the nhaC-encoded Na+/H+ antiporter of alkaliphilic Bacillus firmus OF4.

Application of protoplast transformation and single- and double-crossover mutagenesis protocols to alkaliphilic Bacillus firmus OF4811M (an auxotrophic strain of B. firmus OF4) facilitated the extension of the sequence of the previously cloned nhaC gene, which encodes an Na+/H+ antiporter, and the surrounding region. The nhaC gene is part of a likely 2-gene operon encompassing nhaC and a small gene that was designated nhaS; the operon is preceded by novel direct repeats. The predicted alkaliphile NhaC, based on the extended sequence analysis, would be a membrane protein with 462 amino acid residues and 12 transmembrane segments that is highly homologous to the deduced products of homologous genes of unknown function from Bacillus subtilis and Haemophilus influenzae. The full-length version of nhaC complemented the Na+-sensitive phenotype of an antiporter-deficient mutant strain of Escherichia coli but not the alkali-sensitive growth phenotypes of Na+/H+-deficient mutants of either alkaliphilic B. firmus OF4811M or B. subtilis. Indeed, NhaC has no required role in alkaliphily, inasmuch as the nhaC deletion strain of B. firmus OF4811M, N13, grew well at pH 10.5 at Na+ concentrations equal to or greater than 10 mM. Even at lower Na+ concentrations, N13 exhibited only a modest growth defect at pH 10.5. This was accompanied by a reduced capacity to acidify the cytoplasm relative to the medium compared to the wild-type strain or to N13 complemented by cloned nhaC. The most notable deficiency observed in N13 was its poor growth at pH 7.5 and Na+ concentrations up to 25 mM. During growth at pH 7.5, NhaC is apparently a major component of the relatively high affinity Na+/H+ antiport activity available to extrude the Na+ and to confer some initial protection in the face of a sudden upshift in external pH, i.e., before full induction of additional antiporters. Consistent with the inference that NhaC is a relatively high affinity, electrogenic Na+/H+ antiporter, N13 exhibited a defect in diffusion potential-energized efflux of 22Na+ from right-side-out membrane vesicles from cells that were preloaded with 2 mM Na+ and energized at pH 7.5. When the experiment was conducted with vesicles loaded with 25 mM Na+, comparable efflux was observed in preparations from all the strains.     

A Crh-specific function in carbon catabolite repression in Bacillus subtilis

Carbon catabolite repression in Bacillus subtilis is mediated by phosphorylation of the phosphoenolpyruvate:carbohydrate phosphotransferase system intermediate HPr at a serine residue catalyzed by HPr kinase. The orthologous protein Crh functions in a similar way, but, unlike HPr, it is not functional in carbohydrate uptake. A specific function for Crh is not known. The role of HPr and Crh in repressing the citM gene encoding the Mg(2+)-citrate transporter was investigated during growth of B. subtilis on different carbon sources. In glucose minimal medium, full repression was supported by both HPr and Crh. Strains deficient in Crh or the regulatory function of HPr revealed the same repression as the wild-type strain. In contrast, in a medium containing succinate and glutamate, repression was specifically mediated via Crh. Repression was relieved in the Crh-deficient strain, but still present in the HPr mutant strain. The data are the first demonstration of a Crh-specific function in B. subtilis and suggest a role for Crh in regulation of expression during growth on substrates other than carbohydrates.     

Chromosomal tetA(L) gene of Bacillus subtilis: regulation of expression and physiology of a tetA(L) deletion strain.

Deletion of the tetA(L) chromosomal region of Bacillus subtilis in a strain designated JC112 increased the strain's sensitivity to low tetracycline concentrations. It also resulted in phenotypic changes that correlate with the previously found role of TetA(L) in mediating electrogenic NA+/H+ antiport. Growth of JC112 was impaired relative to that of the wild type at both pH 7.0 and 8.3; Na(+)- and K(+)-dependent pH homeostases were impaired at alkaline pH. The phenotype of JC112 was complemented by plasmid-borne tetA(L) and related tet(K) genes; the antiport activity conferred by the tet(K) gene had an apparently higher preference for K+ over Na+ than that conferred by tetA(L). The data were consistent with TetA(L) being the major Na+(K+)/H+ antiporter involved in pH homeostasis in B. subtilis as well as a significant Na+ extrusion system. The phenotype of JC112 was much more pronounced than that of an earlier transposition mutant, JC111, with a disruption in the putative tetA(L) promoter region. Northern (RNA) blot analysis of tetA(L) RNA from wild-type and JC111 strains revealed the same patterns. That JC111 nevertheless exhibited some Na+ and alkali sensitivity may be accounted for by disruption of regulatory features that, in the wild type, allow increased tetA(L) expression under specific conditions of pH and monovalent cation concentration. Evidence for several different regulatory effects emerged from studies of lacZ expression from the transposon of JC111 and from a tetA(L)-lacZ translational fusion introduced into the amyE locus of wild-type and JC112 strains.     

Cloning, nucleotide sequencing, and genetic mapping of the gene for small, acid-soluble spore protein gamma of Bacillus subtilis.

The Bacillus subtilis gene (sspE) which codes for small acid-soluble spore protein gamma (SASP-gamma) was cloned, and its chromosomal location (65 degrees, linked to glpD) and nucleotide sequence were determined. The amino acid sequence of SASP-gamma is similar to that of SASP-B of Bacillus megaterium, but these sequences are not as highly conserved across species as are those of other SASPs. The SASP-gamma gene is transcribed only in sporulation in parallel with other SASP genes and gives a single mRNA that is approximately 340 nucleotides long. The results of hybridization of an sspE gene probe to Southern blots of B. subtilis DNA suggested that there is only a single gene coding for the SASP-gamma type of protein in B. subtilis. This was confirmed by introducing a deletion mutation into the cloned sspE gene and transferring the deletion into the B. subtilis chromosome, with concomitant loss of the wild-type gene. This sspE deletion strain sporulated well, but lacked the SASP-gamma type of protein.     

Bacillus subtilis generates a major specific deletion in pAM beta 1.

pAM beta 1, a 26.5-kilobase plasmid originally isolated from Streptococcus faecalis, was conjugally transferred from Streptococcus lactis to Bacillus subtilis. No conjugal transfer of pAM beta 1 from B. subtilis to S. lactis was observed. In addition, pAM beta 1 which had been reintroduced in S. lactis after cycling through B. subtilis had lost its conjugal transferability to Streptococcus cremoris, although under the same conditions noncycled pAM beta 1 was transferred at high efficiency. Restriction and Southern blot analyses showed that pAM beta 1 had suffered one major, specific 10.6-kilobase deletion and several minor but also specific deletions in B. subtilis. Comparing the major deletion derivative, delta pAM beta 1, with B. subtilis strains which have been reported to contain pAM beta 1 showed that these strains also contained delta pAM beta 1. Hybridization experiments showed that the deleted fragment was not transposed to the B. subtilis chromosome. Based on the size of the minor deletion derivatives from pAM beta 1, it is suggested that these use a different origin of replication in B. subtilis.