Two proline porters in Escherichia coli K-12

Escherichia coli mutants defective at putP and putA lack proline transport via proline porter I and proline dehydrogenase activity, respectively. They retain a proline uptake system (proline porter II) that is induced during tryptophan-limited growth and are sensitive to the toxic L-proline analog, 3,4-dehydroproline. 3,4-Dehydroproline-resistant mutants derived from a putP putA mutant lack proline porter II. Auxotrophic derivatives derived from putP+ or putP bacteria can grow if provided with proline at low concentration (25 microM); those derived from the 3,4-dehydroproline-resistant mutants require high proline for growth (2.5 mM). We conclude that E. coli, like Salmonella typhimurium, possesses a second proline porter that is inactivated by mutations at the proP locus.     

Proline porter II is activated by a hyperosmotic shift in both whole cells and membrane vesicles of Escherichia coli K12

Proline porter II is rapidly activated when nongrowing bacteria are subjected to a hyperosmotic shift (Grothe, S., Krogsrud, R. L., McClellan, D. J., Milner, J. L., and Wood, J. M. (1986) J. Bacteriol. 166, 253-259). Proline porter II was active in membrane vesicles prepared from bacteria grown under optimal conditions, nutritional stress, or osmotic stress. That activity was: (i) dependent on the presence of the energy sources phenazine methosulphate plus ascorbate or D-lactate; (ii) observed only when a hyperosmotic shift accompanied the transport measurement; (iii) inhibited by glycine betaine in a manner analogous to that observed in whole cells; and (iv) eliminated by lesions in proP. Membrane vesicles were able to transport serine but not glutamine and serine transport was reduced by the hyperosmotic shift. In whole cells, proline porter II activity was supported by glucose and by D-lactate in a strain defective for proline porters I and III and the F1F0-ATPase. Glucose energized proline uptake was eliminated by carbonyl cyanide m-chlorophenylhydrazone and KCN as was serine uptake. These results suggested that proline porter II was respiration-dependent and probably ion-linked. Activation of proline porter II in whole cells by sucrose or NaCl was sustained over 30 min, whereas activation by glycerol was transient. Proline porter II was activated by NaCl and sucrose with a half-time of approximately 1 min in both whole cells and membrane vesicles. Thus, activation of proline porter II was reversible. It occurred at a rate comparable to that of K+ influx and much more rapid than the genetic regulatory responses that follow a hyperosmotic shift.     

Factors reducing and promoting the effectiveness of proline as an osmoprotectant in Escherichia coli K12

Proline accumulation in Escherichia coli is mediated by three proline porters. Proline catabolism is effected by proline porter I (PPI) and proline/delta 1-pyrroline carboxylate dehydrogenase. Proline did not accumulate cytoplasmically when E. coli was subjected to osmotic stress in minimal salts medium. Although PPI is induced when proline is provided as carbon or nitrogen source, its activity decreased following growth of the bacteria in minimal salts medium of high osmotic strength. Proline dehydrogenase was induced by proline in low or high osmotic strength media. Proline porter II (PPII) was both activated and induced in osmotically stressed bacteria, though the dependencies of the two responses on medium osmolarity differed. Osmotic downshift during the transport measurement decreased the uptake of proline, serine and glutamine by bacteria cultured in media of high osmotic strength. Thus, while osmotic upshift caused specific activation of PPII, osmotic downshift caused a non-specific reduction in amino acid uptake. Glycine betaine inhibited the uptake of [14C]proline via PPII and PPIII but not via PPI. The dependence of that inhibition on glycine betaine concentration was similar when PPII was uninduced, induced or activated by osmotic stress, or induced by amino acid limited growth. Thus PPII and PPIII, not PPI, contribute to the mechanism of osmoprotection by proline and glycine betaine. The tendency for exogenous proline to accumulate in the cytoplasm of bacteria exposed to osmotic stress would, however, be countered by increased proline catabolism.     

A third L-proline permease in Salmonella typhimurium which functions in media of elevated osmotic strength.

Exogenous proline specifically stimulates the growth rate of enteric bacteria in media of inhibitory osmotic strength (J. H. B. Christian, Aust. J. Biol. Sci. 8:490-497, 1955). I observed that Salmonella typhimurium mutants which lack both of the previously known proline permeases (putP proP) are stimulated by proline in media of inhibitory osmolarity. I propose that there is a third proline permease which functions only in media of elevated osmolarity. This conclusion is based on the observations that, in media of elevated osmolarity, (i) the sensitivity of putP proP mutants to toxic proline analogs increases, (ii) proline requirements for maximal growth of proline auxotrophic putP proP mutants decreases, and (iii) the specific rate of incorporation of radioactive proline into protein of growing cells increases. I obtained a Tn10-induced mutation in a gene (proU) required for the functioning of the third proline permease and determined the map location to be at 59 map units of the chromosome, between srlA and tct, 66% linked to nalB in P22 transduction. My results suggest that the function of the third, osmotically stimulated permease might be to accumulate high intracellular proline levels during osmotic stress. Possible mechanisms by which proline might cause growth stimulation are discussed.     

Characterization of the Erwinia chrysanthemi osmoprotectant transporter gene ousA.

Growth of Erwinia chrysanthemi in media of elevated osmolarity can be achieved by the uptake and accumulation of various osmoprotectants. This study deals with the cloning and sequencing of the ousA gene-encoded osmoprotectant uptake system A from E. chrysanthemi 3937. OusA belongs to the superfamily of solute ion cotransporters. This osmotically inducible system allows the uptake of glycine betaine, proline, ectoine, and pipecolic acid and presents strong similarities in nucleotide sequence and protein function with the proline/betaine porter of Escherichia coli encoded by proP. The control of ousA expression is clearly different from that of proP. It is induced by osmotic strength and repressed by osmoprotectants. Its expression in E. coli is controlled by H-NS and is rpoS dependent in the exponential phase but unaffected by the stationary phase.     

Proline transport and osmotic stress response in Escherichia coli K-12.

Proline is accumulated in Escherichia coli via two active transport systems, proline porter I (PPI) and PPII. In our experiments, PPI was insensitive to catabolite repression and was reduced in activity twofold when bacteria were subjected to amino acid-limited growth. PPII, which has a lower affinity for proline than PPI, was induced by tryptophan-limited growth. PPII activity was elevated in bacteria that were subjected to osmotic stress during growth or the transport measurement. Neither PPI nor uptake of serine or glutamine was affected by osmotic stress. Mutation proU205, which was similar in genetic map location and phenotype to other proU mutations isolated in E. coli and Salmonella typhimurium, influenced the sensitivity of the bacteria to the toxic proline analogs azetidine-2-carboxylate and 3,4-dehydroproline, the proline requirements of auxotrophs, and the osmoprotective effect of proline. This mutation did not influence proline uptake via PPI or PPII. A very low uptake activity (6% of the PPII activity) observed in osmotically stressed bacteria lacking PPI and PPII was not observed when the proU205 lesion was introduced.     

Sensitivity of Escherichia coli to proline analogues during osmotic stress and anaerobiosis

L.M. REESE, K.O. CUTLER AND C.E. DEUTCH. 1996. The sensitivity of wild-type Escherichia coli K-12 to a series of proline analogues was determined in cultures containing increasing concentrations of NaCl under both aerobic and anaerobic conditions. The bacteria were most sensitive to L-azetidine-2–carboxylate and L-thiazolidine-4–carboxylate. The minimum inhibitory concentrations for these compounds decreased progressively during osmotic stress, but the bacteria were much more sensitive to these proline analogues under aerobic conditions than during anaerobiosis. The reduced sensitivity under anaerobic conditions did not reflect degradation of the compounds in the culture medium. Since both urine and medullary renal tissue contain relatively low oxygen concentrations, these results raise doubts about the potential use of proline or glycine betaine analogues in treating urinary tract infections.     

Nonspecific inhibition of proline dehydrogenase synthesis in Escherichia coli during osmotic stress

L-Proline, which is accumulated by Escherichia coli during growth in media of high osmolality, also induces the synthesis of the enzyme degrading it to glutamate. To determine if proline catabolism is inhibited during osmotic stress, proline utilization and the formation of proline dehydrogenase were examined in varying concentrations of NaCl and sucrose. Although the specific growth rate of E. coli with proline as the sole nitrogen source diminished as the solute osmolality increased, a comparable reduction in growth rate occurred with ammonium as the primary nitrogen source. Proline catabolism, as measured in whole cells by the conversion of [14C]proline to [14C]glutamate, was only slightly inhibited by solute osmolalities up to 1.0 osmol/kg; more than 50% of the initial activity was still found at 2.0 osmol/kg. By contrast, the specific activity of proline dehydrogenase in bacteria grown in the presence of added solutes decreased to less than 20% of the control level. This reduction was related to a lower rate of synthesis, but was independent of genes currently known to be involved in osmoregulation or proline metabolism. The specific activities of tryptophanase, beta-galactosidase, and histidinol dehydrogenase were also reduced under similar growth conditions. These results indicate that while proline catabolism is not directly inhibited by high solute concentrations, prolonged exposure to osmotic stress leads to its reduction as part of a more general metabolic response.     

Nitrogen fixation in Klebsiella pneumoniae during osmotic stress. Effect of exogenous proline or a proline overproducing plasmid

Osmotic stress, imposed by 0.5 M NaCl or other electrolytes and non-electrolytes, caused over a 100-fold reduction in the whole-cell nitrogen fixation activity of Klebsiella pneumoniae, wild-type strain M5A1. This reduction of nitrogen fixation activity could be reversed by the addition of proline to the culture medium at 0.5 mM concentration. With 0.5 M NaCl, in the presence of proline, nitrogenase activity was 47-fold greater than in the absence of proline. A mutation, originally isolated in Salmonella typhimurium, which resulted in proline over-production and enhanced osmotolerance, was transferred into K. pneumoniae by F' conjugation. Intracellular proline, synthesized at high levels because of the mutation, had similar stimulatory effects on nitrogen fixation under osmotic stress as proline provided exogenously. In the overproducing strain, the cellular level of proline is elevated as much as 125-fold during stress over that seen in the control strain. To determine the mechanism of stimulation of nitrogen fixation by proline during stress, the biosynthesis of nitrogenase polypeptides was studied. Net nitrogenase biosynthesis and the biosynthesis of other unidentified peptides, is strongly inhibited during osmotic stress; proline reverses the inhibition. The role of proline in enhancing nitrogen fixation during osmotic stress is discussed.     

Effect of cadmium on proline accumulation and ribonuclease activity in rice seedlings: role of proline as a possible enzyme protectant

When seedlings of two rice (Oryza sativa L.) cultivars Ratna and Jaya were raised under 100 and 500 μM cadmium nitrate in the medium, a high proline content was noted in Cd²⁺ stressed seedlings compared to controls. Seedlings grown under 500 μM Cd(NO₃)₂ maintained increased proline level compared to non-stressed seedlings. Kinetic properties of RNase extracted from control grown and Cd²⁺ stressed seedlings showed a marked alteration in Km due to Cd²⁺ treatment. The RNase isoforms were purified from 15-d-old rice seedlings with a total purification of 22.25 fold and 74.75 % yield using conventional biochemical techniques. Three RNase isoforms, namely I, II and III were eluted from DEAE-Sephacel column. The isoform RNase II had Km value of 3.2 mg(RNA) cm^-3. The in vitro osmotic stress created by incorporation of PEG in the enzyme assay medium led to decreased affinity of enzyme towards its substrate with increase in Km. This loss in affinity was partially restored by the addition of 1 M proline in the assay medium, suggesting the possible protective role of proline on RNase under osmotic stress. This revised version was published online in July 2006 with corrections to the Cover Date.     

Transgenic Medicago truncatula plants that accumulate proline display nitrogen-fixing activity with enhanced tolerance to osmotic stress

Legume root nodule nitrogen-fixing activity is severely affected by osmotic stress. Proline accumulation has been shown to induce tolerance to salt stress, and transgenic plants over-expressing Delta(1)-pyrroline-5-carboxylate synthetase (P5CS), which accumulates high levels of proline, display enhanced osmotolerance. Here, we transformed the model legume Medicago truncatula with the P5CS gene from Vigna aconitifolia, and nodule activity was evaluated under osmotic stress in transgenic plants that showed high proline accumulation levels. Nitrogen fixation was significantly less affected by salt treatment compared to wild-type (WT) plants. To our knowledge, this is the first time that transgenic legumes have been produced that display nitrogen-fixing activity with enhanced tolerance to osmotic stress. We studied the expression of M. truncatula proline-related endogenous genes M. truncatulaDelta(1)-pyrroline-5-carboxylate synthetase 1 (MtP5CS1), M. truncatulaDelta(1)-pyrroline-5-carboxylate synthetase 2 (MtP5CS2), M. truncatula ornithine delta-aminotransferase (MtOAT), M. truncatula proline dehydrogenase (MtProDH) and a proline transporter gene in both WT and transgenic plants. Our results indicate that proline metabolism is finely regulated in response to osmotic stress in an organ-specific manner. The transgenic model allowed us to analyse some of the biochemical and molecular mechanisms that are activated in the nodule in response to high salt conditions, and to ascertain the essential role of proline in the maintenance of nitrogen-fixing activity under osmotic stress.     

Nitrogen fixaton in Klebsiella pneumoniae during osmotic stress effect of exogenous proline or a proline overproducing plasmid

Osmotic stress, imposed by 0.5 M NaCl or other electrolytes and non-electrolytes, caused over a 100-fold reduction in the whole-cell nitrogen fixation activity in Klebsiella pneumoniae, wild-type strain M₅A₁. This reduction of nitrogen fixation activity could be reversed by the addition of proline to the culture medium at 0.5 mM concentration. With 0.5 M NaCl, in the presence of proline, nitrogenase activity was 47-fold greater than in the absence of proline. A mutation, originally isolated in Salmonella typhimurium, which resulted in proline over-production and enhanced osmotolerance, was transferred into K. pneumoniae by F′ conjugation. Intracellular proline, synthesized at high levels because of the mutation, had similar stimulatory effects on nitrogen fixation under osmotic stress as proline provided exogenously. In the overproducing strain, the cellular level of proline is elevated as much as 125-fold during stress over that seen in the control strain. To determine the mechanism of stimulation of nitrogen fixaton by proline during stress, the biosynthesis of nitrogenase polypeptides was studied. Net nitrogenase biosynthesis and the biosynthesis of other unidentified peptides, is strongly inhibited during osmotic stress; proline reverses the inhibition. The role of proline in enhancing nitrogen fixation during osmotic stress is discussed.     

Identification and mapping of a second proline permease Salmonella typhimurium

In this paper we demonstrate the existence of a second proline permease, gene proP, in Salmonella typhimurium. Uptake assays demonstrate that this second proline permease has 5 to 10% the uptake rate of the putP permease, the cell's major proline permease, when assayed at 20 microM proline. Genetic mapping by Hfr and P22-mediated genetic crosses placed the second proline permease gene at 92 min on the S. typhimurium genetic map, near the genes for melibiose utilization. F'-mediated complementation tests indicated that Escherichia coli also has the proP gene.     

Osmoprotection of Escherichia coli by peptone is mediated by the uptake and accumulation of free proline but not of proline-containing peptides

The effect of meat peptone type I (Sigma) on the growth of Escherichia coli cells under hyperosmotic stress has been investigated. Peptone is a complex mixture of peptides with a small content of free amino acids, which resembles nutrients found in natural environments. Our data showed that peptone enhances the growth of E. coli cells in high-osmolarity medium to levels higher than those achieved with the main compatible solute in bacteria, glycine betaine. The mechanism of osmoprotection by peptone comprises the uptake and accumulation of the compatible solute, proline. The main role of the peptides contained in peptone is the provision of nutrients rather than the intracellular accumulation of osmolytes. In contrast to Listeria monocytogenes (M. R. Amezaga, I. Davidson, D. McLaggan, A. Verheul, T. Abee, and I. R. Booth, Microbiology 141:41-49, 1995), E. coli does not accumulate exogenous peptides for osmoprotection and peptides containing proline do not lead to the accumulation of proline as a compatible solute. In late-logarithmic-phase cultures of E. coli growing at high osmolarity plus peptone, proline becomes the limiting factor for growth, and the intracellular pools of proline are not maintained. This is a consequence of the low concentration of free proline in peptone, the catabolism of proline by E. coli, and the inability of E. coli to utilize proline-containing peptides as a source of compatible solutes. Our data highlight the role that natural components in food such as peptides play in undermining food preservation regimes, such as high osmolarity, and also that the specific mechanisms of osmoprotection by these compounds differ according to the organism.