The sensor kinase KdpD of Escherichia coli senses external K+

The Kdp system of Escherichia coli is composed of the high‐affinity K⁺ transporter KdpFABC and the two regulatory proteins KdpD (sensor kinase) and KdpE (response regulator), which constitute a typical two‐component system. The kdpFABC operon is induced under K⁺‐limiting conditions and, to a lesser extent, under high osmolality in the medium. In search for the stimulus sensed by KdpD, we studied the inhibitory effect of extracellular K⁺ on the Kdp system at pH 6.0, which is masked by unspecific K⁺ transport at higher pH values. Based on KdpD derivatives carrying single aspartate replacements in the periplasmic loops which are part of the input domain, we concluded that the inhibition of the Kdp system at extracellular K⁺ concentrations above 5 mM is mediated via KdpD/KdpE and not due to inhibition of the K⁺‐transporting KdpFABC complex. Furthermore, time‐course analyses of kdpFABC expression revealed that a decline in the extracellular K⁺ concentration efficiently stimulates KdpD/KdpE‐mediated signal transduction. In this report we provide evidence that the extracellular K⁺ concentration serves as one of the stimuli sensed by KdpD.     

Domain swapping reveals that the N-terminal domain of the sensor kinase KdpD in Escherichia coli is important for signaling

Background  

The KdpD/KdpE two-component system of Escherichia coli regulates expression of the kdpFABC operon encoding the high affinity K⁺ transport system KdpFABC. The input domain of KdpD comprises a domain that belongs to the family of universal stress proteins (Usp). It has been previously demonstrated that UspC binds to this domain, resulting in KdpD/KdpE scaffolding under salt stress. However the mechanistic significance of this domain for signaling remains unclear. Here, we employed a "domain swapping" approach to replace the KdpD-Usp domain with four homologous domains or with the six soluble Usp proteins of E. coli.     

The Universal Stress Protein UspC Scaffolds the KdpD/KdpE Signaling Cascade of Escherichia coli under Salt Stress

The sensor kinase KdpD and the response regulator KdpE control induction of the kdpFABC operon encoding the high-affinity K⁺-transport system KdpFABC in response to K⁺ limitation or salt stress. Under K⁺ limiting conditions the Kdp system restores the intracellular K⁺ concentration, while in response to salt stress K⁺ is accumulated far above the normal content. The kinase activity of KdpD is inhibited at high concentrations of K⁺, so it has been puzzling how the sensor can be activated in response to salt stress. Here, we demonstrate that the universal stress protein UspC acts as a scaffolding protein of the KdpD/KdpE signaling cascade by interacting with a Usp domain in KdpD of the UspA subfamily under salt stress. Escherichia coli encodes three single domain proteins of this subfamily, UspA, UspC, and UspD, whose expression is up-regulated under various stress conditions. Among these proteins only UspC stimulated the in vitro reconstructed signaling cascade (KdpD→KdpE→DNA) resulting in phosphorylation of KdpE at a K⁺ concentration that would otherwise almost prevent phosphorylation. In agreement, in a ΔuspC mutant KdpFABC production was down-regulated significantly when cells were exposed to salt stress, but unchanged under K⁺ limitation. Biochemical studies revealed that UspC interacts specifically with the Usp domain in the stimulus perceiving N-terminal domain of KdpD. Furthermore, UspC stabilized the KdpD/KdpE∼P/DNA complex and is therefore believed to act as a scaffolding protein. This study describes the stimulation of a bacterial two-component system under distinct stress conditions by a scaffolding protein, and highlights a new role of the universal stress proteins.     

Signal-sensing mechanisms of the putative osmosensor KdpD in Escherichia coli

The KdpD protein is a membrane-located sensory kinase (or signal transducer) critically involved in the regulation of the kdpABC operon that is responsible for a high-affinity transport system in Escherichia coli. In this study, a set of KdpD mutants, each resulting in a single amino acid substitution around the membrane-spanning regions of KdpD, was isolated. Amino acid substitutions in these KdpD mutants were located non-randomly, particularly within the C-terminal half of the membrane-spanning regions. This set of KdpD mutants exhibited altered transmembrane-signalling properties in response to external K⁺ and other stimuli. In particular, these mutants were found to be insensitive, if not completely, to the K⁺ signal. However, they were able to respond to other stimuli such as high-salt stress, as in the wild type. Therefore, in contrast to the wild type, the cells carrying these mutations exhibited high levels of the steady-state expression of kdp, regardless of external K⁺, provided that high concentrations of ionic solutes were supplemented to the cultures. More interestingly, the set of KdpD mutants could also respond to high concentrations of external non-ionic solutes such as sucrose and D-arabinose, thereby increasing substantially the steady-state expression of kdp in response to the medium osmolarity. Furthermore, it was found that certain chemicals, ethanol, chlorpromazine and procaine, could function as effectors for the KdpD mutants at relatively low concentrations in the media. Based on these findings, we have examined the primary signal(s) that regulates the function of KdpD. We propose here that KdpD can be considered to be an environmental sensor that exhibits sensing mechanisms in response to both the level of K⁺ and the physico-chemical state of the cytoplasmic membrane.     

The phosphotransferase protein EIIA(Ntr) modulates the phosphate starvation response through interaction with histidine kinase PhoR in Escherichia coli

Many Proteobacteria possess the paralogous PTS^Ntr, in addition to the sugar transport phosphotransferase system (PTS). In the PTS^Ntr phosphoryl‐groups are transferred from phosphoenolpyruvate to protein EIIA^Ntr via the phosphotransferases EI^Ntr and NPr. The PTS^Ntr has been implicated in regulation of diverse physiological processes. In Escherichia coli, the PTS^Ntr plays a role in potassium homeostasis. In particular, EIIA^Ntr binds to and stimulates activity of a two‐component histidine kinase (KdpD) resulting in increased expression of the genes encoding the high‐affinity K⁺ transporter KdpFABC. Here, we show that the phosphate (pho) regulon is likewise modulated by PTS^Ntr. The pho regulon, which comprises more than 30 genes, is activated by the two‐component system PhoR/PhoB under conditions of phosphate starvation. Mutants lacking EIIA^Ntr are unable to fully activate the pho genes and exhibit a growth delay upon adaptation to phosphate limitation. In contrast, pho expression is increased above the wild‐type level in mutants deficient for EIIA^Ntr phosphorylation suggesting that non‐phosphorylated EIIA^Ntr modulates pho. Protein interaction analyses reveal binding of EIIA^Ntr to histidine kinase PhoR. This interaction increases the amount of phosphorylated response regulator PhoB. Thus, EIIA^Ntr is an accessory protein that modulates the activities of two distinct sensor kinases, KdpD and PhoR, in E. coli.     

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.     

Effect of the essential oil fromAchillea fragrantissima onEscherichia coli cells

Escherichia coli cells treated with the essential oil from the plantAchillea fragrantissima released five polypeptides as well as K⁺ ions into the incubation medium. The oil also inhibited the respiration ofE. coli cells and reduced their ATP content. Electron micrographs showed that oil-treated cells were permeable to uranyl acetate. The effect of the essential oil on the cell membrane is discussed.     

Solubilization of a functionally active proline carrier from membranes of Escherichia coli with an organic solvent.

A proline transport carrier was extracted from the membranes of Escherichia coli with acidic n-butanol. Vesicles reconstituted from the butanol extract and E. coli phospholipids and preloaded with K⁺ showed rapid uphill uptake of proline when energy was supplied as a membrane potential introduced by K⁺-diffusion via valinomycin. Proline uptake by the reconstituted vesicles, like that of intact cells and isolated membrane vesicles, was inhibited by 3,4-dehydroproline, SH reagents, and a proton conducting uncoupler. Reconstituted vesicles of mutants defective in proline transport showed little or no proline uptake. The proline carrier was partially purified from the extract and separated from the bulk of phospholipids on Sephadex LH-20.     

Role of K+ in leaf growth: K+ uptake is required for light-stimulated H+ efflux but not solute accumulation

The stimulation of dicotyledonous leaf growth by light depends on increased H⁺ efflux, to acidify and loosen the cell walls, and is enhanced by K⁺ uptake. The role of K⁺ is generally considered to be osmotic for turgor maintenance. In coleoptiles, auxin‐induced cell elongation and wall acidification depend on K⁺ uptake through tetraethylammonium (TEA)‐sensitive channels (Claussen et al., Planta 201, 227–234, 1997), and auxin stimulates the expression of inward‐rectifying K⁺ channels ( Philippar et al. 1999) . The role of K⁺ in growing, leaf mesophyll cells has been investigated in the present study by measuring the consequences of blocking K⁺ uptake on several growth‐related processes, including solute accumulation, apoplast acidification, and membrane polarization. The results show that light‐stimulated growth and wall acidification of young tobacco leaves is dependent on K⁺ uptake. Light‐stimulated growth is enhanced three‐fold over dark levels with increasing external K⁺, and this effect is blocked by the K⁺ channel blockers, TEA, Ba⁺⁺ and Cs⁺. Incubation in 10 mm TEA reduced light‐stimulated growth and K⁺ uptake by 85%, and completely inhibited light‐stimulated wall acidification and membrane polarization. Although K⁺ uptake is significantly reduced in the presence of TEA, solute accumulation is increased. We suggest that the primary role of K⁺ in light‐stimulated leaf growth is to provide electrical counterbalance to H⁺ efflux, rather than to contribute to solute accumulation and turgor maintenance.     

The KdpD/KdpE Two-Component System: Integrating K+ Homeostasis and Virulence

The two-component system (TCS) KdpD/KdpE, extensively studied for its regulatory role in potassium (K⁺) transport, has more recently been identified as an adaptive regulator involved in the virulence and intracellular survival of pathogenic bacteria, including Staphylococcus aureus, entero-haemorrhagic Escherichia coli, Salmonella typhimurium, Yersinia pestis, Francisella species, Photorhabdus asymbiotica, and mycobacteria. Key homeostasis requirements monitored by KdpD/KdpE and other TCSs such as PhoP/PhoQ are critical to survival in the stressful conditions encountered by pathogens during host interactions. It follows these TCSs may therefore acquire adaptive roles in response to selective pressures associated with adopting a pathogenic lifestyle. Given the central role of K⁺ in virulence, we propose that KdpD/KdpE, as a regulator of a high-affinity K⁺ pump, has evolved virulence-related regulatory functions. In support of this hypothesis, we review the role of KdpD/KdpE in bacterial infection and summarize evidence that (i) KdpD/KdpE production is correlated with enhanced virulence and survival, (ii) KdpE regulates a range of virulence loci through direct promoter binding, and (iii) KdpD/KdpE regulation responds to virulence-related conditions including phagocytosis, exposure to microbicides, quorum sensing signals, and host hormones. Furthermore, antimicrobial stress, osmotic stress, and oxidative stress are associated with KdpD/KdpE activity, and the system''s accessory components (which allow TCS fine-tuning or crosstalk) provide links to stress response pathways. KdpD/KdpE therefore appears to be an important adaptive TCS employed during host infection, promoting bacterial virulence and survival through mechanisms both related to and distinct from its conserved role in K⁺ regulation.     

Structural and physiological changes during sporangial development inAchlya intricata beneke

Summary Sporangial development in the zoosporic fungusAchlya intricata has been studied using light microscopy, a plasmolytic technique, KCl-filled microelectrodes and ion-selective microelectrodes. The completion of cleavage (spore delimitation) is accompanied by a change in appearance of the sporangium, loss of turgor and membrane potential, decrease in volume and release of K⁺. The measured loss of K⁺ is in agreement with previous measurements of extracellular ionic currents around developing sporangia ofAchlya using a vibrating probe. The relationship between these changes and the mechanism of spore liberation is discussed.     

Molecular cloning and functional expression in bacteria of the potassium transporters CnHAK1 and CnHAK2 of the seagrass Cymodocea nodosa

The cDNAs CnHAK1 and CnHAK2, encoding K⁺ transporters, were amplified from the leaves of the seagrass Cymodocea nodosa. None of these transporters suppressed the K⁺ deficiency of a Saccharomyces cerevisiae mutant, but both suppressed the equivalent defect of an Escherichia coli mutant. Overexpression of the transporter CnHAK1, but not CnHAK2, mediated very rapid K⁺ or Rb⁺ influxes in the E. coli mutant. The concentration dependence of these influxes demonstrated that CnHAK1 is a low-affinity K⁺ transporter, which does not discriminate between K⁺ and Rb⁺. CnHAK1 expressed in E. coli worked in reverse when the external K⁺ concentrations were low, and we established the condition of a simple functional test of K⁺ loss for transporters of the Kup-HAK family. In comparison with its homologue barley transporter HvHAK2, CnHAK1 was insensitive to Na⁺.     

Thermal Stability of the Plasma Membrane Calcium Pump. Quantitative Analysis of Its Dependence on Lipid-Protein Interactions

Thermal stability of plasma membrane Ca²⁺ pump was systematically studied in three micellar systems of different composition, and related with the interactions amphiphile-protein measured by fluorescence resonance energy transfer. Thermal denaturation was characterized as an irreversible process that is well described by a first order kinetic with an activation energy of 222 ± 12 kJ/mol in the range 33–45°C. Upon increasing the mole fraction of phospholipid in the mixed micelles where the Ca²⁺ pump was reconstituted, the kinetic coefficient for the inactivation process diminished until it reached a constant value, different for each phospholipid species. We propose a model in which thermal stability of the pump depends on the composition of the amphiphile monolayer directly in contact with the transmembrane protein surface. Application of this model shows that the maximal pump stability is attained when 80% of this surface is covered by phospholipids. This analysis provides an indirect measure of the relative affinity phospholipid/detergent for the hydrophobic transmembrane surface of the protein (K _LD ) showing that those phospholipids with higher affinity provide greater stability to the Ca²⁺ pump. We developed a method for directly measure K _LD by using fluorescence resonance energy transfer from the membrane protein tryptophan residues to a pyrene-labeled phospholipid. K _LD values obtained by this procedure agree with those obtained from the model, providing a strong evidence to support its validity. Received: 5 August 1999/Revised: 20 October 1999     

Reversible envelope effects during and after killing of Escherichia coli W by a highly-purified rabbit polymorphonuclear leukocyte fraction

The effects of a highly-purified, potently bactericidal fraction from rabbit polymorphonuclear leukocytes on the envelope of Escherichia coli (W) have been examined. This leukocyte fraction has equally enriched bactericidal, permeability-increasing and phospholipase A₂ activities, and is essentially devoid of lysozyme, myeloperoxidase and protease activities (Weiss, J., Franson, R.C., Beckerdite, S., Schmeidler, K. and Elsbach, P. (1975) J. Clin. Invest. 55, 33–42). Rapid killing of E. coli by this fraction is accompanied by two almost immediate alterations in the bacterial envelope: (1) a discrete increase in envelope permeability (measured by inhibition of bacterial leucine incorporation by normally impermeant actinomycin D), and, (2) hydrolysis of ¹⁴C-labeled fatty acid-prelabeled E. coli phospholipids. Both envelope effects are promptly reversed during further incubation at 37 °C, but not at 0 °C, with 40 mM Mg²⁺. Reversal is also produced by Ca²⁺ (40 mM) and trypsin (200 μg/ml), but 200 mM K⁺ causes only partial recovery and Na⁺ and hyperosmolar sucrose are ineffective. Upon addition of Mg²⁺, phospholipid degradation ceases abruptly and the labeled products of hydrolysis (free fatty acids and lysocompounds) disappear with a corresponding reaccumulation of radioactive diacylphosphatides. The time course of resynthesis of phospholipids coincides with that of restoration of the permeability barrier. Higher concentrations of the leukocyte fraction and prolonged incubation increase both the extent of phospholipid degradation and the time required for reversal of both envelope effects. These findings suggest that both the initiation of the increased permeability and its reversal are linked to respectively the breakdown and resynthesis of major E. coli membrane phospholipids, and thus depend on the fact that the biochemical apparatus of E. coli remains capable of biosynthesis despite loss of viability.Treatment of E. coli, exposed to the leukocyte fraction, with albumin results in extracellular sequestration of the products of hydrolysis and also restores the permeability barrier to actinomycin D, suggesting that the accumulation of lytic products of lipid hydrolysis within the bacterial envelope, rather than the loss of phospholipids per se, causes increased permeability.     

Genes,enzymes and membrane proteins of the nitrate respiration system ofEscherichia coli

Summary A method was devised to isolate mutants carrying deletions through several genetic loci (chlD ⁺ andchlA ⁺) which are involved in the membrane-bound nitrate respiratory complex ofEscherichia coli. Specific transducing phages were used to reintroduce these genes. Comparisons of membrane fractions from these transduced strains showed five membrane proteins that are necessary for the formation of an active nitrate respiration system. Two particular bacterial genes (chlD ⁺ andchlA ⁺) were shown to control these five membrane proteins.Three of the proteins specified bychlA ⁺, appear to be constitutively controlled and always present in the membrane ofE. coli irrespective of growth conditions, while the other two proteins, specified bychlD ⁺, appear to be induced byanaerobic growth in the presence of nitrate.