Potassium-dependant mutants of Escherichia coli K-12

Mutants of Escherichia coli K-12 that grow more slowly in media containing low concentrations of K have been isolated. All independent mutants of this type which have been studied carry a mutation in a small region of the bacterial chromosome between the supE and gal loci. The growth rate of the mutants is the same as that of the parental strains in medium containing more than 1 mm K, but is only 50% that of the parent when the K concentration is reduced to 0.1 mm. The mutants do not appear to have a primary alteration in K transport, and are therefore referred to as K-dependent. The abbreviation kdp is proposed for this class of mutant.     

Properties of Escherichia coli mutants altered in calcium/proton antiport activity.

Mutants sensitive to growth inhibition by CaCl2 were found to have alterations in calcium uptake in everted membrane vesicles. These mutations map at different loci on the Escherichia coli chromosomes. A mutation at the calA locus results in vesicles which have two- to threefold higher levels of uptake activity than vesicles from wild-type cells. The calA mutation is phenotypically expressed as increased sensitivity to CaCl2 in a strain also harboring a mutation in the corA locus, which is involved in Mg2+ transport. The calA locus maps very close to purA and cycA at about min 97. The calB mutation results both in sensitivity to CaCl2 at pH 5.6 and in vesicles with diminished calcium transport capability. The CalB phenotype is also expressed only in a corA genetic background; the calB locus appears to map very near, yet separately from, the calA locus. When the cor+ allele is present, calA and calB mutations still result in a defect in calcium transport in vesicles. In addition, both calC and calD mutations result in vesicles with impaired calcium transport activity. calC is cotransducible with kdp and nagA, whereas calD is cotransducible with proC.     

Trk1 and Trk2 define the major K(+) transport system in fission yeast

The trk1(+) gene has been proposed as a component of the K(+) influx system in the fission yeast Schizosaccharomyces pombe. Previous work from our laboratories revealed that trk1 mutants do not show significantly altered content or influx of K(+), although they are more sensitive to Na(+). Genome database searches revealed that S. pombe encodes a putative gene (designated here trk2(+)) that shows significant identity to trk1(+). We have analyzed the characteristics of potassium influx in S. pombe by using trk1 trk2 mutants. Unlike budding yeast, fission yeast displays a biphasic transport kinetics. trk2 mutants do not show altered K(+) transport and exhibit only a slightly reduced Na(+) tolerance. However, trk1 trk2 double mutants fail to grow at low K(+) concentrations and show a dramatic decrease in Rb(+) influx, as a result of loss of the high-affinity transport component. Furthermore, trk1 trk2 cells are very sensitive to Na(+), as would be expected for a strain showing defective potassium transport. When trk1 trk2 cells are maintained in K(+)-free medium, the potassium content remains higher than that of the wild type or trk single mutants. In addition, the trk1 trk2 strain displays increased sensitivity to hygromycin B. These results are consistent with a hyperpolarized state of the plasma membrane. An additional phenotype of cells lacking both Trk components is a failure to grow at acidic pH. In conclusion, the Trk1 and Trk2 proteins define the major K(+) transport system in fission yeast, and in contrast to what is known for budding yeast, the presence of any of these two proteins is sufficient to allow growth at normal potassium levels.     

Trk2 Is Required for Low Affinity K(+) Transport in Saccharomyces Cerevisiae

TRK1, the gene encoding the high affinity K+ transporter in Saccharomyces cerevisiae, is nonessential due to the existence of a functionally independent low affinity transporter. To identify the gene(s) encoding the low affinity K+ transporter, we screened trk1 delta cells for mutants (Kla-) that require higher concentrations of K+ in the medium to support growth. trk1 delta trk2 mutants require up to tenfold higher concentrations of K+ to exhibit normal growth compared to trk1 delta TRK2 cells. K+ and 86Rb+ transport assays demonstrate that the mutant phenotype is due to defective K+ transport (uptake). Each of 38 independent mutants contains a mutation in the same gene, TRK2. Cells deficient for both high and low affinity K+ transport (trk1 delta trk2) exhibit hypersensitivity to low extracellular pH that can be suppressed by high concentrations of K+ but not Na+. TRK1 completely suppresses both the K+ transport defect and low pH hypersensitivity of trk2 cells, suggesting that TRK1 and TRK2 are functionally independent.     

On the role of Trk1 and Trk2 in Schizosaccharomyces pombe under different ion stress conditions

Trk1 and Trk2 are the major K(+) transport systems in Schizosaccharomyces pombe. Both transporters individually seem to be able to cope with K(+) requirements of the cells under normal conditions, since only the double mutant shows defective K(+) transport and defective growth at limiting K(+) concentrations. We have studied in detail the role of SpTrk1 and SpTrk2 under different ion stress conditions. Results show that the strain with only Trk1 (trk1(+)) is less sensitive to Li(+) and to hygromycin B, it grows better at low K(+) and it survives longer in a medium without K(+) than the strain expressing only Trk2 (trk2(+)). We conclude that Trk1 contributes more efficiently than Trk2 to the performance of the fission yeast under ion stress conditions. In the wild type both trk1(+) and trk2(+) genes are expressed and probably collaborate for the performance of the cells.     

A potassium transporter of the yeast Schwanniomyces occidentalis homologous to the Kup system of Escherichia coli has a high concentrative capacity.

The yeast Schwanniomyces occidentalis has a high-affinity K+ uptake system with a high concentrative capacity, which is able to deplete the external K+ to < 0.03 microM. We have cloned the gene HAK1 of S.occidentalis which complements defective K+ uptake by trk1 and trk1 trk2 mutants of Saccharomyces cerevisiae. When HAK1 was expressed in a trk1 trk2 S.cerevisiae mutant, transport affinities for K+ and other alkali cations resembled those of S.occidentalis. The predicted amino acid sequence of the HAK1 protein shows significant homology with the hydrophobic region of the Kup transporter of Escherichia coli. In S.occidentalis HAK1 expresses in K(+)-limiting conditions. Our data indicate that in K(+)-starved cells the system encoded by HAK1 is the major K+ transporter of S.occidentalis.     

Identification of an iron uptake system specific for coprogen and rhodotorulic acid in Escherichia coli K12

With the lac operon fusion technique, mutants were isolated in two genes that specify two outer membrane proteins designated FhuE (76 K) and Fiu (83 K). The synthesis of both proteins was increased under low iron growth conditions. The FhuE-protein was shown to be necessary for iron uptake via coprogen, an iron chelator produced by certain fungi, e.g. Neurospora crassa. In addition to fhueE the genes fhuCDB, tonB and exbB were necessary for iron coprogen uptake. The gene fhuE was mapped between kdp and gltA near 16 min on the genetic map of E. coli K12, while gene fiu was mapped near 18 min between chlA and chlE. Nor iron transport system could be assigned as yet to the Fiu protein.     

Osmotic regulation of transcription: induction of the proU betaine transport gene is dependent on accumulation of intracellular potassium

The proU locus, which encodes a high-affinity betaine transport system, and the kdp operon, which encodes a potassium transport system, are the principal osmoresponsive genes in Escherichia coli and Salmonella typhimurium. The kdp operon is known to be induced in response to changes in cell turgor. We have investigated the control of proU expression and shown that it differs from that of kdp in a number of fundamental ways. Rather than responding to changes in turgor, proU expression is principally determined by the intracellular accumulation of potassium ions. Potassium and betaine were shown to play distinct osmoprotective roles. Potassium serves as the principal osmoprotectant and is accumulated in response to low-level osmotic stress to restore turgor. As external osmolarity is increased to a level at which the corresponding increase in internal potassium concentrations is potentially deleterious to enzyme function, betaine (when available) is accumulated in preference to potassium. The different mechanisms of proU and kdp regulation reflect the different physiological roles of these two osmoprotectants.     

A model for the regulation of expression of the potassium-transport operon,kdp, inEscherichia coli

The intracellular concentration of K+in Escherichia coli is known to be determined by osmolarity of the growth medium, and it is believed that the expression of the potassium-transport operon, kdp, is controlled by the turgor pressure differential between the cytoplasm and the extracellular environment. Several lines of evidence, however, argue against a strict turgor-regulation model for kdp expression. Instead, it is proposed here that kdp is controlled by one fraction of intracellular [K+], and that the size of this fraction is independent of the osmolarity of the culture medium.     

Magnesium transport in Salmonella typhimurium: genetic characterization and cloning of three magnesium transport loci

Salmonella typhimurium strains lacking the CorA Mg2+ transport system retain Mg2+ transport and the ability to grow in medium containing a low concentration of Mg2+. Mutagenesis of a corA strain followed by ampicillin selection allowed isolation of a strain that required Mg2+-supplemented media for growth. This strain contained mutations in at least two loci in addition to corA, designated mgtA and mgtB (for magnesium transport). Strains with mutations at all three loci (corA, mgtA, and mgtB) exhibited no detectable Mg2+ uptake and required 10 mM Mg2+ in the medium for growth at the wild-type rate. A wild-type allele at any one of the three loci was sufficient to restore both Mg2+ transport and growth on 50 microM Mg2+. P22 transduction was used to map the mgt loci. The mgtA mutation was located to approximately 98 map units (cotransducible with pyrB), and mgtB mapped at about 80.5 map units (near gltC). A chromosomal library from S. typhimurium was screened for clones that complemented the Mg2+ requirement of a corA mgtA mgtB mutant. The three classes of plasmids obtained could each independently restore Mg2+ transport to this strain and corresponded to the corA, mgtA, and mgtB loci. Whereas the corA locus of S. typhimurium is analogous to the corA locus previously described for Escherichia coli, neither of the mgt loci described in this report appears analogous to the single mgt locus described in E. coli. Our data in this and the accompanying papers (M. D. Snavely, J. B. Florer, C. G. Miller, and M. E. Maguire, J. Bacteriol. 171:4752-4760, 4761-4766, 1989) indicate that the corA, mgtA, and mgtB loci of S. typhimurium represent three distinct systems that transport Mg2+.     

Transport and utilization of the biosynthetic intermediate shikimic acid in Escherichia coli.

Auxotrophic mutants of Escherichia coli W or K12 blocked before shikimic acid in the aromatic biosynthetic pathway grew poorly on shikimic acid as sole aromatic supplement. This poor growth response was correlated with a relatively poor ability to transport shikimic acid. If citrate was present in the growth medium (as it is in some commonly used basal media) the growth of some of the E. coli K12 mutants on shikimate was further reduced. Mutants were derived from pre-shikimate auxotrophs which grew rapidly on media containing shikimic acid. These derivatives all had an increased ability to transport shikimic acid. Thus, it is proposed that the growth on shikimate observed in the parent cells is restricted by their relatively poor uptake of shikimate from the medium and that this restriction may be removed by a mutation which enhances shikimate transport. Transduction analysis of the mutations which enhanced utilization and transport of shikimic acid by E. coli K12 strains indicated at least two classes. Class 1 was about 20% cotransduced with the histidine region of the E. coli K12 chromosome and appeared to be coincident with a known shikimate transport locus, shiA. Class 2 was not cotransduced with his. The locus (or loci) of this class is unknown. Kinetic measurements suggested that both classes had shikimate uptake systems derived from the wild-type system. Two class 1 mutants had increased levels of otherwise unaltered wild-type transport while one class 2 mutant had an altered Michaelis constant (Km) for shikimate transport.     

Wide distribution of homologs of Escherichia coli Kdp K+-ATPase among gram-negative bacteria.

We used Southern blotting to screen a variety of bacterial genes for homology to the kdp genes of Escherichia coli, genes that encode an ATP-driven K+ transport system. We found that most enterobacteria have sequences homologous to those of the three kdp structural genes and the kdpD regulatory gene. A number of distantly related species, including some cyanobacteria, have sequences homologous to those of the structural genes but not the regulatory gene. In all cases only a single region of homology was found. These results suggest that ATP-driven transport systems similar to the Kdp system in structure and regulation are found in many enteric organisms. In other gram-negative organisms, the ATPase is more divergent, retaining good homology at the DNA level only to the highly conserved phosphorylated subunit of the ATPase.     

Functional expression of the voltage-gated neuronal mammalian potassium channel rat ether à go-go1 in yeast.

It has been shown previously that heterologous expression of inwardly rectifying potassium channels (K+-channels) from plants and mammals in K+-transport defective yeast mutants can restore the ability of growth in media with low [K+]. In this study, the functional expression of an outward rectifying mammalian K+-channel in yeast is presented for the first time. The outward-rectifying mammalian neuronal K+-channel rat ether à go-go channel 1 (rEAG1, Kv 10.1) was expressed in yeast (Saccharomyces cerevisiae) strains lacking the endogenous K+-uptake systems and/or alkali-metal-cation efflux systems. It was found that a truncated channel version, lacking almost the complete intracellular N-terminus (rEAG1 Delta 190) but not the full-length rEAG1, partially complemented the growth defect of K+-uptake mutant cells (trk1,2 Delta tok1 Delta) in media containing low K+ concentrations. The expression of rEAG1 Delta 190 in a strain lacking the cation efflux systems (nha1 Delta ena1-4 Delta) increased the sensitivity to high monovalent cation concentrations. Both phenotypes were observed, when rEAG1 Delta 190 was expressed in a trk1,2 Delta and nha1, ena1-4 Delta mutant strain. In the presence of K+-channel blockers (Cs+, Ba2+ and quinidine), the growth advantage of rEAG1 Delta 190 expressing trk1,2 tok1 Delta cells disappeared, indicating its dependence on functional rEAG1 channels. The results demonstrate that S. cerevisiae is a suitable expression system even for voltage-gated outward-rectifying mammalian K+-channels.     

Deletions of SKY1 or PTK2 in the Saccharomyces cerevisiae trk1Deltatrk2Delta mutant cells exert dual effect on ion homeostasis

Sky1p and Ptk2p are protein kinases that regulate ion transport across the plasma membrane of Saccharomyces cerevisiae. We show here that deletion of SKY1 or PTK2 in trk1,2Delta cells increase spermine tolerance, implying Trk1,2p independent activity. Unexpectedly, trk1,2Deltasky1Delta and trk1,2Deltaptk2Delta cells display hypersensitivity to LiCl. These cells also show increased tolerance to low pH and improved growth in low K(+), as demonstrated for deletion of PMP3 in trk1,2Delta cells. We show that Sky1p and Pmp3p act in different pathways. Hypersensitivity to LiCl and improved growth in low K(+) are partly dependent on the Nha1p and Kha1p antiporters and on the Tok1p channel. Finally, Dhh1p, a RNA helicase was demonstrated to improve growth of trk1,2Deltasky1Delta cells in low K(+). Overexpression of Dhh1p improves the ability of trk1,2Delta cells to grow in low K(+) while dhh1Delta cells are sensitive to spermine and salt ions. A model that integrates these results to explain the mechanism of ion transport across the plasma membrane is proposed.     

TRH1 encodes a potassium transporter required for tip growth in Arabidopsis root hairs

Root hair initiation involves the formation of a bulge at the basal end of the trichoblast by localized diffuse growth. Tip growth occurs subsequently at this initiation site and is accompanied by the establishment of a polarized cytoplasmic organization. Arabidopsis plants homozygous for a complete loss-of-function tiny root hair 1 (trh1) mutation were generated by means of the T-DNA-tagging method. Trichoblasts of trh1 plants form initiation sites but fail to undergo tip growth. A predicted primary structure of TRH1 indicates that it belongs to the AtKT/AtKUP/HAK K(+) transporter family. The proposed function of TRH1 as a K(+) transporter was confirmed in (86)Rb uptake experiments, which demonstrated that trh1 plants are partially impaired in K(+) transport. In line with these results, TRH1 was able to complement the trk1 potassium transporter mutant of Saccharomyces, which is defective in high-affinity K(+) uptake. Surprisingly, the trh1 phenotype was not restored when mutant seedlings were grown at high external potassium concentrations. These data demonstrate that TRH1 mediates K(+) transport in Arabidopsis roots and is responsible for specific K(+) translocation, which is essential for root hair elongation.     

Oxidative phosphorylation in Escherichia coli K 12. Mutations affecting magnesium ion- or calcium ion-stimulated adenosine triphosphatase

1. Two mutants of Escherichia coli K 12 were isolated which, although able to grow on glucose, are unable to grow with succinate or d-lactate as the sole source of carbon. 2. Genetic mapping of these mutants showed that they both contain a mutation in a gene (designated uncA) mapping at about minute 73.5 on the E. coli chromosome. 3. The uncA(-) alleles were transferred by bacteriophage-mediated transduction into another strain of E. coli and the transductants compared with the parent strain to determine the nature of the biochemical lesion in the mutants. 4. The mutants gave low aerobic growth yields when grown on limiting concentrations of glucose, but oxidase activities in membranes from both the mutants and the normal strain were similar. 5. Measurement of P/O ratios with d-lactate as substrate indicated that a mutation in the uncA gene causes uncoupling of phosphorylation associated with electron transport. 6. Determination of the Mg(2+),Ca(2+)-stimulated adenosine triphosphatase activities in the mutant and normal strains indicated that the uncA gene is probably the structural gene for Mg(2+),Ca(2+)-stimulated adenosine triphosphatase. 7. Mg(2+),Ca(2+)-stimulated adenosine triphosphatase therefore appears to be essential for oxidative phosphorylation in E. coli.