Identification of osmo-dependent and osmo-independent betaine-choline-carnitine transporters in Acinetobacter baumannii: role in osmostress protection and metabolic adaptation

Acinetobacter baumannii is outstanding for its ability to cope with low water activities and therefore its adaptation mechanism to osmotic stress. Here we report on the identification and characterization of five different secondary active compatible solute transporters, belonging to the betaine-choline-carnitine transporter (BCCT) family. Our studies revealed two choline-specific and three glycine betaine-specific BCCTs. Activity of the BCCTs was differentially dependent to the osmolality: one choline and one betaine transporter were osmostress-independent. Addition of choline to resting cells of Acinetobacter grown in the presence of the co-substrate choline or with phosphatidylcholine as sole carbon source led to ATP synthesis in the wild type but not in the BCCT quadruple mutant. This indicates that the BCCTs are essential to transport the energy substrate choline. The role of the different BCCTs in osmostress resistance and in metabolic adaptation of A. baumannii to the human host is discussed.     

BetS is a major glycine betaine/proline betaine transporter required for early osmotic adjustment in Sinorhizobium meliloti

Hybridization to a PCR product derived from conserved betaine choline carnitine transporter (BCCT) sequences led to the identification of a 3.4-kb Sinorhizobium meliloti DNA segment encoding a protein (BetS) that displays significant sequence identities to the choline transporter BetT of Escherichia coli (34%) and to the glycine betaine transporter OpuD of Bacillus subtilis (30%). Although the BetS protein shows a common structure with BCCT systems, it possesses an unusually long hydrophilic C-terminal extension (169 amino acids). After heterologous expression of betS in E. coli mutant strain MKH13, which lacks choline, glycine betaine, and proline transport systems, both glycine betaine and proline betaine uptake were restored, but only in cells grown at high osmolarity or subjected to a sudden osmotic upshock. Competition experiments demonstrated that choline, ectoine, carnitine, and proline were not effective competitors for BetS-mediated betaine transport. Kinetic analysis revealed that BetS has a high affinity for betaines, with K(m)s of 16 +/- 2 microM and 56 +/- 6 microM for glycine betaine and proline betaine, respectively, in cells grown in minimal medium with 0.3 M NaCl. BetS activity appears to be Na(+) driven. In an S. meliloti betS mutant, glycine betaine and proline betaine uptake was reduced by about 60%, suggesting that BetS represents a major component of the overall betaine uptake activities in response to salt stress. beta-Galactosidase activities of a betS-lacZ strain grown in various conditions showed that betS is constitutively expressed. Osmotic upshock experiments performed with wild-type and betS mutant cells, treated or not with chloramphenicol, indicated that BetS-mediated betaine uptake is the consequence of immediate activation of existing proteins by high osmolarity, most likely through posttranslational activation. Growth experiments underscored the crucial role of BetS as an emerging system involved in the rapid acquisition of betaines by S. meliloti subjected to osmotic upshock.     

Isolation and characterization of ButA, a secondary glycine betaine transport system operating in Tetragenococcus halophila

Through functional complementation of an Escherichia coli mutant defective in glycine betaine uptake, we identified a single-component glycine betaine transporter from Tetragenococcus halophila, a moderate halophilic lactic acid bacterium. DNA sequence analysis characterized the ButA protein as a member of the betaine choline carnitine transporter (BCCT) family, that includes a variety of previously characterized compatible solute transporters such as OpuD from Bacillus subtilis, EctP and BetP from Corynebacterium glutamicum, and BetL from Listeria monocytogenes. When expressed in the heterologous host E. coli, the permease is specific for glycine betaine and does not transport the other osmoprotectants previously described for T. halophila (i.e. carnitine, choline, dimethylsulfonioacetate, dimethylsulfoniopropionate, and ectoine). In E. coli, statement of ButA is mainly constitutive and maximal uptake activity may result from a weak osmotic induction. This is the first study demonstrating a role for a permease in osmoregulation, and GB uptake, of a lactic acid bacterium.     

<Emphasis Type="Italic">Marinococcus halophilus</Emphasis> DSM 20408<Superscript>T </Superscript>encodes two transporters for compatible solutes belonging to the betaine-carnitine-choline transporter family: identification and characterization of ectoine transporter EctM and glycine betaine transporter BetM

In response to osmotic stress, the halophilic, Gram-positive bacterium Marinococcus halophilus accumulates compatible solutes either by de novo synthesis or by uptake from the medium. To characterize transport systems responsible for the uptake of compatible solutes, a plasmid-encoded gene bank of M. halophilus was transferred into the transport-deficient strain Escherichia coli MKH13, and two genes were cloned by functional complementation required for ectoine and glycine betaine transport. The ectoine transporter is encoded by an open reading frame of 1,578 bp named ectM. The gene ectM encodes a putative hydrophobic, 525-residue protein, which shares significant identity to betaine-carnetine-choline transporters (BCCTs). The transporter responsible for the uptake of glycine betaine in M. halophilus is encoded by an open reading frame of 1,482 bp called betM. The potential, hydrophobic BetM protein consists of 493 amino acid residues and belongs, like EctM, to the BCCT family. The affinity of whole cells of E. coli MKH13 for ectoine (K_s=1.6 M) and betaine (K_s=21.8 M) was determined, suggesting that EctM and BetM exhibit a high affinity for their substrates. An elevation of the salinity in the medium resulted in an increased uptake of ectoine via EctM and glycine betaine via BetM in E. coli MKH13 cells, demonstrating that both systems are osmoregulated.Communicated by W.D. Grant     

OusB, a Broad-Specificity ABC-Type Transporter from Erwinia chrysanthemi, Mediates Uptake of Glycine Betaine and Choline with a High Affinity

The ability of Erwinia chrysanthemi to cope with environments of elevated osmolality is due in part to the transport and accumulation of osmoprotectants. In this study we have identified a high-affinity glycine betaine and choline transport system in E. chrysanthemi. By using a pool of Tn5-B21 ousA mutants, we isolated a mutant that could grow in the presence of a toxic analogue of glycine betaine (benzyl-glycine betaine) at high osmolalities. This mutant was impaired in its ability to transport all effective osmoprotectants in E. chrysanthemi. The DNA sequence of the regions flanking the transposon insertion site revealed three chromosomal genes (ousVWX) that encode components of an ABC-type transporter (OusB): OusV (ATPase), OusW (permease), and OusX (periplasmic binding protein). The OusB components showed a significant degree of sequence identity to components of ProU from Salmonella enterica serovar Typhimurium and Escherichia coli. OusB was found to restore the uptake of glycine betaine and choline through functional complementation of an E. coli mutant defective in both ProU and ProP osmoprotectant uptake systems. Competition experiments demonstrated that choline, dimethylsulfoniacetate, dimethylsulfoniopropionate, and ectoine were effective competitors for OusB-mediated betaine transport but that carnitine, pipecolate, and proline were not effective. In addition, the analysis of single and double mutants showed that OusA and OusB were the only osmoprotectant transporters operating in E. chrysanthemi.     

VP2118 has major roles in Vibrio parahaemolyticus response to oxidative stress

Background

Reactive oxygen species (ROS), including superoxide anion radical, induce chronic risk of oxidative damage to many cellular macromolecules resulting in damage to cells. Superoxide dismutases (SODs) catalyze the dismutation of superoxide to oxygen and hydrogen peroxide and are a primary defense against ROS. Vibrio parahaemolyticus, a marine bacterium that causes acute gastroenteritis following consumption of raw or undercooked seafood, can survive ROS generated by intestinal inflammatory cells. However, there is little information concerning SODs in V. parahaemolyticus. This study aims to clarify the role of V. parahaemolyticus SODs against ROS.

Methods

V. parahaemolyticus SOD gene promoter activities were measured by a GFP reporter assay. Mutants of V. parahaemolyticus SOD genes were constructed and their SOD activity and resistance to oxidative stresses were measured.

Results

Bioinformatic analysis showed that V. parahaemolyticus SODs were distinguished by their metal cofactors, FeSOD (VP2118), MnSOD (VP2860), and CuZnSOD (VPA1514). VP2118 gene promoter activity was significantly higher than the other SOD genes. In a VP2118 gene deletion mutant, SOD activity was significantly decreased and could be recovered by VP2118 gene complementation. The absence of VP2118 resulted in significantly lowered resistance to ROS generated by hydrogen peroxide, hypoxanthine–xanthine oxidase, or Paraquat. Furthermore, both the N- and C-terminal SOD domains of VP2118 were necessary for ROS resistance.

Conclusion

VP2118 is the primary V. parahaemolyticus SOD and is vital for anti-oxidative stress responses.

General significance

The V. parahaemolyticus FeSOD VP2118 may enhance ROS resistance and could promote its survival in the intestinal tract to facilitate host tissue infection.     

Ectoine functions as an osmoprotectant in Bacillus subtilis and is accumulated via the ABC-transport system OpuC

We report here that the cyclic amino acid ectoine functions as an osmoprotectant for the soil bacterium Bacillus subtilis. Growth experiments with a set of B. subtilis strains that carry defined mutations in the glycine betaine transport systems OpuA, OpuC and OpuD and the choline transport system OpuB revealed that ectoine was specifically accumulated via the ABC-transport system OpuC. Competition experiments employing unlabeled ectoine and radiolabeled glycine betaine showed that the OpuC transport system has a low affinity for ectoine with a K_i value of approximately 1.5 mM. Ectoine was identified by ¹H NMR spectroscopy in the solute pool of cells grown in the presence of ectoine. Ectoine could not be used by B. subtilis as sole carbon or nitrogen source. Our data thus characterise ectoine as a metabolically inert stress compound for B. subtilis and establish a crucial role for the ABC-transport system OpuC for the acquisition of the osmoprotectant ectoine from the environment.     

Isolation and Characterization of ButA,a Secondary Glycine Betaine Transport System Operating in <Emphasis Type="Italic">Tetragenococcus halophila</Emphasis>

Through functional complementation of an Escherichia coli mutant defective in glycine betaine uptake, we identified a single-component glycine betaine transporter from Tetragenococcus halophila, a moderate halophilic lactic acid bacterium. DNA sequence analysis characterized the ButA protein as a member of the betaine choline carnitine transporter (BCCT) family, that includes a variety of previously characterized compatible solute transporters such as OpuD from Bacillus subtilis, EctP and BetP from Corynebacterium glutamicum, and BetL from Listeria monocytogenes. When expressed in the heterologous host E. coli, the permease is specific for glycine betaine and does not transport the other osmoprotectants previously described for T. halophila (i.e. carnitine, choline, dimethylsulfonioacetate, dimethylsulfoniopropionate, and ectoine). In E. coli, statement of ButA is mainly constitutive and maximal uptake activity may result from a weak osmotic induction. This is the first study demonstrating a role for a permease in osmoregulation, and GB uptake, of a lactic acid bacterium.Received: 19 November 2002/Accepted: 19 December 2002     

Pseudomonas syringae BetT is a low-affinity choline transporter that is responsible for superior osmoprotection by choline over glycine betaine

The plant pathogen Pseudomonas syringae derives better osmoprotection from choline than from glycine betaine, unlike most bacteria that have been characterized. In this report, we identified a betaine/carnitine/choline family transporter (BCCT) in P. syringae pv. tomato strain DC3000 that mediates the transport of choline and acetylcholine. This transporter has a particularly low affinity (K(m) of 876 microM) and high capacity (V(max) of 80 nmol/min/mg of protein) for choline transport relative to other known BCCTs. Although BetT activity increased in response to hyperosmolarity, BetT mediated significant uptake under low-osmolarity conditions, suggesting a role in transport for both osmoprotection and catabolism. Growth studies with mutants deficient in BetT and other choline transporters demonstrated that BetT was responsible for the superior osmoprotection conferred to P. syringae by choline over glycine betaine when these compounds were provided at high concentrations (>100 microM). These results suggest that P. syringae has evolved to survive in relatively choline-rich habitats, a prediction that is supported by the common association of P. syringae with plants and the widespread production of choline, but genus- and species-specific production of glycine betaine, by plants. Among the three putative BCCT family transporters in Pseudomonas aeruginosa and six in Pseudomonas putida, different transporters were predicted to function based on similarity to Escherichia coli BetT than to P. syringae BetT. Functional P. putida and P. aeruginosa transporters were identified, and their possession of a long C-terminal tail suggested an osmoregulatory function for this tail; this function was confirmed for P. syringae BetT using deletion derivatives.     

Osmotic adaptation in Brevibacterium linens: differential effect of proline and glycine betaine on cytoplasmic osmolyte pool

In the coryneform Brevibacterium linens, ectoine constitutes the major intracellular solute accumulated under elevated medium osmolarity. Here we report that exogenously supplied proline, choline, glycine betaine, and even ectoine, protected bacterial cells against deleterious effects of a hyperosmotic constraint (i.e. 1.5 M NaCl). In all cases, a significant improvement of growth was observed; in parallel, intracellular osmolyte pools composed mainly of glutamate and ectoine substantially increased, either with added glycine betaine (under limiting supply) or with proline. However, these two osmoprotectants behaved differently: glycine betaine acted as a genuine osmoprotectant, whereas proline was accumulated only transiently and participated actively in the biosynthesis of glutamate, ectoine, and trehalose. The strategy developed by B. linens cells allows the proposal of a novel role for proline in the osmoprotection process through its conversion to the apparently preferred endogenous osmolyte ectoine.     

Expression and substrate specificity of betaine/proline transporters suggest a novel choline transport mechanism in sugar beet

Proline transporters (ProTs) originally described as highly selective transporters for proline, have been shown to also transport glycinebetaine (betaine). Here we examined and compared the transport properties of Bet/ProTs from betaine accumulating (sugar beet, Amaranthus, and Atriplex,) and non-accumulating (Arabidopsis) plants. Using a yeast mutant deficient for uptake of proline and betaine, it was shown that all these transporters exhibited higher affinity for betaine than proline. The uptake of betaine and proline was pH-dependent and inhibited by the proton uncoupler carbonylcyanide m-chlorophenylhydrazone (CCCP). We also investigated choline transport by using a choline transport-deficient yeast mutant. Results revealed that these transporters exhibited a higher affinity for choline uptake rather than betaine. Uptake of choline by sugar beet BvBet/ProT1 was independent of the proton gradient and the inhibition by CCCP was reduced compared with that for uptake of betaine, suggesting different proton binding properties between the transport of choline and betaine. Additionally, in situ hybridization experiments revealed the localization of sugar beet BvBet/ProT1 in phloem and xylem parenchyma cells.     

Corynebacterium glutamicum Is Equipped with Four Secondary Carriers for Compatible Solutes: Identification, Sequencing, and Characterization of the Proline/Ectoine Uptake System, ProP, and the Ectoine/Proline/Glycine Betaine Carrier, EctP

Gram-positive soil bacterium Corynebacterium glutamicum uses the compatible solutes glycine betaine, proline, and ectoine for protection against hyperosmotic shock. Osmoregulated glycine betaine carrier BetP and proline permease PutP have been previously characterized; we have identified and characterized two additional osmoregulated secondary transporters for compatible solutes in C. glutamicum, namely, the proline/ectoine carrier, ProP, and the ectoine/glycine betaine/proline carrier, EctP. A ΔbetP ΔputP ΔproP ΔectP mutant was unable to respond to hyperosmotic stress, indicating that no additional uptake system for these compatible solutes is present. Osmoregulated ProP consists of 504 residues and preferred proline (K_m, 48 μM) to ectoine (K_m, 132 μM). The proP gene could not be expressed from its own promoter in C. glutamicum; however, expression was observed in Escherichia coli. ProP belongs to the major facilitator superfamily, whereas EctP, together with the betaine carrier, BetP, is a member of a newly established subfamily of the sodium/solute symporter superfamily. The constitutively expressed ectP codes for a 615-residue transporter. EctP preferred ectoine (K_m, 63 μM) to betaine (K_m, 333 μM) and proline (K_m, 1,200 μM). Its activity was regulated by the external osmolality. The related betaine transporter, BetP, could be activated directly by altering the membrane state with local anesthetics, but this was not the case for EctP. Furthermore, the onset of osmotic activation was virtually instantaneous for BetP, whereas it took about 10 s for EctP.     

Osmoadaptation among Vibrio Species and Unique Genomic Features and Physiological Responses of Vibrio parahaemolyticus

Vibrio parahaemolyticus is a moderately halophilic bacterium found in estuarine and marine coastal ecosystems worldwide. Although the ability of V. parahaemolyticus to grow and proliferate in fluctuating saline environments is well known, the underlying molecular mechanisms of osmoadaptation are unknown. We performed an in silico analysis of V. parahaemolyticus strain RIMD2210633 for genes homologous to osmotic stress response genes in other bacteria. We uncovered two putative compatible solute synthesis systems (encoded by ectABC and betABI) and six putative compatible solute transporters (encoded by four bcct loci and two proVWX loci). An ectoine synthesis system clustered with a betaine/carnitine/choline transporter and a ProU transporter (encoded by homologues of proVWX from Escherichia coli), and a betaine synthesis system clustered with a ProU transporter (encoded by homologues of proVXW from Pseudomonas syringae). This is at least double the number present in V. cholerae, V. fischeri, or V. vulnificus. Six additional Vibrio species contain both ectABC and betABI, i.e., V. alginolyticus 12G01, V. angustum, V. harveyi BAA-1116, V. splendidus LGP32, Vibrio sp. strain MED222, and Vibrio sp. strain Ex25. V. harveyi HY01 and V. splendidus 12B01 only encoded the betaine system. In addition, V. alginolyticus had a compendium of systems identical to that found in V. parahaemolyticus. Comparative physiological analysis of RIMD2210633 with V. vulnificus YJ016, V. cholerae N16961, and V. fischeri ES114 grown at different salinities and temperatures demonstrated that V. parahaemolyticus had a growth advantage under all of the conditions examined. We demonstrate, by one-dimensional nuclear magnetic resonance analysis, that V. parahaemolyticus is capable of de novo synthesis of ectoine at high salinity whereas a ΔectB knockout strain is not. We constructed a single-knockout mutation in proU1, but no growth defect was noted, indicating transporter system redundancy. We complemented E. coli MKH13, a compatible solute transporter-negative strain, with bcct2 and demonstrated uptake of betaine at high salt concentrations.Vibrio parahaemolyticus is a moderate halophile prevalent in all of the coastal waters around the world, particularly in the warmer summer months (17). V. parahaemolyticus is found associated with zooplankton and phytoplankton and is present in sea sediment (18-20). V. parahaemolyticus is a pathogen of fish and humans and is the leading cause of seafood-associated bacterial gastroenteritis worldwide. Fish and shellfish, particularly oysters, are implicated as the major vectors for infection (5, 7, 27). Numerous outbreaks of V. parahaemolyticus infection in the Pacific Northwest have resulted in severe economic losses and closures in the seafood industry (27). A number of environmental factors affect the occurrence and distribution of V. parahaemolyticus, such as temperature, salinity, oxygen availability, plankton, and tidal flushing (8-10, 18-20) Because all of the V. parahaemolyticus strains inhabit marine, brackish, and estuarine waters, fluctuations in temporal and persistent salinity pose a constant challenge to the adaptive response of the organism.In most bacteria, the response to osmotic upshock has two phases (3, 11, 31, 32, 40, 43). The immediate and short-term response to hyperosmotic and high-salinity changes is the accumulation of K⁺. This is the primary strategy for many extremophiles living in high-salinity environments (37). Because high K⁺ concentrations are detrimental to most cells, a more long-term strategy to deal with osmotic upshock is required (3, 11, 31, 32, 40, 43). The second strategy, and the one more widely used among halophiles and for salt adaptation in general among bacteria, actinomycetes, algae, fungi, and yeasts, is the synthesis and/or accumulation of organic osmotic solutes (Fig. ​(Fig.1)1) (3, 11, 31, 32). These are known as compatible solutes or osmolytes since they are amassed in high concentrations without disturbing vital cellular functions (6). Osmolytes include sugars such as trehalose, free amino acids such as proline and glutamate, and their derivatives betaine, glycine betaine, and ectoine, as well as a number of esters and amines (6, 11, 34-36, 40).Open in a separate windowFIG. 1.PCR confirmation of truncated alleles and double-crossover events in deletion mutagenesis of the ectB and proU1 genes of V. parahaemolyticus RIMD2210633. ectB: lane 1, 1-kb DNA ladder; lane 2, 533-bp ectAD product generated via SOE PCR; lane 3, 1.04-kb truncated ectB (double crossover); lane 4, 2.73-kb wild type. proU1: lane 1, 1-kb DNA ladder; lane 2, 428 bp; lane 3, 1.64 kb (double crossover); lane 4, 3.18-kb wild type.The majority of bacteria utilize the trimethylammonium compound glycine betaine (N,N,N-trimethylglycine) as their preferred compatible solute (23, 24, 26, 29, 40, 43). Escherichia coli, which can grow at a maximum NaCl concentration of 0.5 M, can convert choline to betaine by using enzymes encoded by betABI, and choline is transported into the cell by the high-affinity BetT system, as well as by a low-affinity ProU transporter encoded by proVWX (11). One of the most widespread compatible solutes is ectoine (1,4,5,6-tetrahydro-2-methyl-4-pyrimidinecarboxylic acid) (23, 24, 26, 29, 40, 43, 44). The pathway for ectoine synthesis has been determined for several moderate halophiles, and in all cases the products of the ectABC genes are required (15, 41, 42). Ectoine was shown to play a role in osmotolerance in V. cholerae; when Pflughoeft et al. exposed a ΔectA mutant strain to high osmolarity, they observed a pronounced growth delay compared to the wild-type strain (33). In E. coli, which lacks an ectoine synthesis system, the ProP (encoded by proP) and ProU transporters were shown to take up a wide variety of osmoprotectants, including ectoine (22). ProU shows a preference for glycine betaine and proline betaine in E. coli and is highly upregulated in high-osmolarity medium (12).In this study, we first examined the genome of V. parahaemolyticus RIMD2210633 and identified homologues of ectABC and betABI, as well as homologues of four betaine/carnitine/choline transporters (BCCTs) and two ProU compatible solute transporters, triple the number of systems identified in V. cholerae and double the number present in V. vulnificus and V. fischeri. Six additional Vibrio species encode both ectABC and betABI, i.e., V. alginolyticus 12G01, V. angustum, V. harveyi BAA-1116, V. splendidus LGP32, Vibrio sp. strain MED222, and Vibrio sp. strain Ex25. V. alginolyticus 12G01 had the same number and arrangement of compatible solute systems as V. parahaemolyticus. Comparative growth analysis experiments demonstrated that at high salinity and at high or low temperatures, V. parahaemolyticus had a growth advantage over V. cholerae, V. vulnificus, and V. fischeri. We show that the ectABC gene cluster in V. parahaemolyticus is required for de novo ectoine synthesis but that there is functional redundancy due to the large number of compatible solute transporters available.     

Osmoprotectants in Halomonas elongata: high-affinity betaine transport system and choline-betaine pathway.

The osmoregulatory pathways of the moderately halophilic bacterium Halomonas elongata DSM 3043 have been investigated. This strain grew optimally at 1.5 to 2 M NaCl in M63 glucose-defined medium. It required at least 0.5 M NaCl for growth, which is a higher concentration than that exhibited by the H. elongata type strain ATCC 33173. Externally provided betaine, choline, or choline-O-sulfate (but not proline, ectoine, or proline betaine) enhanced the growth of H. elongata on 3 M NaCl-glucose-M63 plates, demonstrating the utilization of these compounds as osmoprotectants. Moreover, betaine and choline stimulated the growth of H. elongata DSM 3043 over the entire range of salinity, although betaine was more effective than choline at salinities below and above the optimum. We found that H. elongata DSM 3043 has at least one high-affinity transport system for betaine (K(m) = 3.06 microM and Vmax = 9.96 nmol of betaine min(-1) mg of protein(-1)). Competition assays demonstrated that proline betaine and ectoine, but not proline, choline, or choline-O-sulfate, are also transported by the betaine permease. Finally, thin-layer chromatography and 13C-nuclear magnetic resonance analysis showed that exogenous choline was taken up and transformed to betaine by H. elongata, demonstrating the existence of a choline-glycine betaine pathway in this moderately halophilic bacterium.     

Isolation of the putP gene of Corynebacterium glutamicum and characterization of a low-affinity uptake system for compatible solutes

Corynebacterium glutamicum accumulates the compatible solutes proline, glycine betaine, and ectoine under conditions of high osmolality. Uptake of proline is mediated by both a high-affinity and a low-affinity secondary transport system. The low-affinity uptake system also accepts glycine betaine and ectoine as substrates. In the present study, the gene encoding the high-affinity proline uptake system PutP was isolated by heterologous complementation of Escherichia coli mutant strain WG389, which lacks the transport systems BetT, PutP, ProP, and ProU and is unable to synthesize proline and glycine betaine. This gene (putP) encodes a protein of 524 amino acids that shares identity with the proline transport systems PutP of E. coli, Staphylococcus aureus, Salmonella typhimurium, Haemophilus influenzae, and Klebsiella pneumoniae. Functional studies of PutP synthesized in E. coli mutant strain MKH13, which also lacks the transport systems for compatible solutes and is unable to synthesize glycine betaine, revealed that this carrier system is not regulated by the external osmolality on the level of activity. K _m values of 7.6 mM for proline and 1.3 mM for sodium as cotransported ion were determined. Deletion of the putP gene allowed the functional characterization of another proline uptake system with low affinity. Received: 27 February 1997 / Accepted: 24 April 1997     

Choline Transport Activity Regulates Phosphatidylcholine Synthesis through Choline Transporter Hnm1 Stability

Choline is a precursor for the synthesis of phosphatidylcholine through the CDP-choline pathway. Saccharomyces cerevisiae expresses a single high affinity choline transporter at the plasma membrane, encoded by the HNM1 gene. We show that exposing cells to increasing levels of choline results in two different regulatory mechanisms impacting Hnm1 activity. Initial exposure to choline results in a rapid decrease in Hnm1-mediated transport at the level of transporter activity, whereas chronic exposure results in Hnm1 degradation through an endocytic mechanism that depends on the ubiquitin ligase Rsp5 and the casein kinase 1 redundant pair Yck1/Yck2. We present details of how the choline transporter is a major regulator of phosphatidylcholine synthesis.     

Transport kinetics of ectoine, an osmolyte produced by Brevibacterium epidermis

Brevibacterium epidermis DSM 20659 is a halotolerant Gram-positive bacterium which can synthesize the osmolyte, ectoine, but prefers to take it up from its environment. The present study revealed that B. epidermis is equipped with at least one transport system for ectoine, with a maximal transport velocity of 15.7 ± 4.3 nmol/g CDW·min. The transport requires energy (ATP) and is completely inhibited by the proton uncoupler, CCCP. The ectoine uptake system is constitutively expressed at a basal level of activity and its activity is immediately 10-fold increased by hyper-osmotic stress. Initial uptake rates are not influenced by the intensity of the hyper-osmotic shock but the duration of the increased activity of the uptake system could be directly related to the osmotic strength of the assay solution. Competition assays indicate that betaine, but not proline, is also transported by the ectoine uptake system.     

OusB, a broad-specificity ABC-type transporter from Erwinia chrysanthemi, mediates uptake of glycine betaine and choline with a high affinity

The ability of Erwinia chrysanthemi to cope with environments of elevated osmolality is due in part to the transport and accumulation of osmoprotectants. In this study we have identified a high-affinity glycine betaine and choline transport system in E. chrysanthemi. By using a pool of Tn5-B21 ousA mutants, we isolated a mutant that could grow in the presence of a toxic analogue of glycine betaine (benzyl-glycine betaine) at high osmolalities. This mutant was impaired in its ability to transport all effective osmoprotectants in E. chrysanthemi. The DNA sequence of the regions flanking the transposon insertion site revealed three chromosomal genes (ousVWX) that encode components of an ABC-type transporter (OusB): OusV (ATPase), OusW (permease), and OusX (periplasmic binding protein). The OusB components showed a significant degree of sequence identity to components of ProU from Salmonella enterica serovar Typhimurium and Escherichia coli. OusB was found to restore the uptake of glycine betaine and choline through functional complementation of an E. coli mutant defective in both ProU and ProP osmoprotectant uptake systems. Competition experiments demonstrated that choline, dimethylsulfoniacetate, dimethylsulfoniopropionate, and ectoine were effective competitors for OusB-mediated betaine transport but that carnitine, pipecolate, and proline were not effective. In addition, the analysis of single and double mutants showed that OusA and OusB were the only osmoprotectant transporters operating in E. chrysanthemi.