Hydroxyectoine is superior to trehalose for anhydrobiotic engineering of Pseudomonas putida KT2440.

Anhydrobiotic engineering aims to increase the level of desiccation tolerance in sensitive organisms to that observed in true anhydrobiotes. In addition to a suitable extracellular drying excipient, a key factor for anhydrobiotic engineering of gram-negative enterobacteria seems to be the generation of high intracellular concentrations of the nonreducing disaccharide trehalose, which can be achieved by osmotic induction. In the soil bacterium Pseudomonas putida KT2440, however, only limited amounts of trehalose are naturally accumulated in defined high-osmolarity medium, correlating with relatively poor survival of desiccated cultures. Based on the enterobacterial model, it was proposed that increasing intracellular trehalose concentration in P. putida KT2440 should improve survival. Using genetic engineering techniques, intracellular trehalose concentrations were obtained which were similar to or greater than those in enterobacteria, but this did not translate into improved desiccation tolerance. Therefore, at least for some populations of microorganisms, trehalose does not appear to provide full protection against desiccation damage, even when present at high concentrations both inside and outside the cell. For P. putida KT2440, it was shown that this was not due to a natural limit in desiccation tolerance since successful anhydrobiotic engineering was achieved by use of a different drying excipient, hydroxyectoine, with osmotically preconditioned bacteria for which 40 to 60% viability was maintained over extended periods (up to 42 days) in the dry state. Hydroxyectoine therefore has considerable potential for the improvement of desiccation tolerance in sensitive microorganisms, particularly for those recalcitrant to trehalose.

Anhydrobiotic engineering of gram-negative bacteria.

Anhydrobiotic engineering aims to improve desiccation tolerance in living organisms by adopting the strategies of anhydrobiosis. This was achieved for Escherichia coli and Pseudomonas putida by osmotic induction of intracellular trehalose synthesis and by drying from trehalose solutions, resulting in long-term viability in the dried state.

Plasmid RK2 toxin protein ParE: purification and interaction with the ParD antitoxin protein.

The parDE operon, located within the 3.2-kb stabilization region of plasmid RK2, encodes antitoxin (ParD) and toxin (ParE) proteins that stabilize the maintenance of this broad-host-range plasmid via a postsegregational killing mechanism. A ParE protein derivative, designated ParE', was purified by construction of a fusion protein, GST-ParE, followed by glutathione-agarose binding and cleavage of the fusion protein. ParE' has three additional amino acids on the N terminus and a methionine residue in place of the native leucine residue. The results of glutathione-agarose affinity binding and glutaraldehyde cross-linking indicate that ParE' exists as a dimer in solution and that it binds to the dimeric form of ParD to form a tetrameric complex. The formation of this complex is presumably responsible for the ability of ParD to neutralize ParE toxin activity. Previous studies demonstrated that the parDE operon is autoregulated as a result of the binding of the ParD protein to the parDE promoter. ParE' also binds to the parDE promoter but only in the presence of the autoregulatory ParD protein. ParE', in the presence or absence of the ParD protein, does not bind to any other part of the 3.2-kb stabilization region. The binding of the ParE' protein to ParD did not alter the DNase I footprint pattern obtained as a result of ParD binding to the parDE promoter. The role of ParE in binding along with ParD to the promoter, if any, remains unclear.

The complex bet promoters of Escherichia coli: regulation by oxygen (ArcA), choline (BetI), and osmotic stress.

The bet regulon allows Escherichia coli to synthesize the osmoprotectant glycine betaine from choline. It comprises a regulatory gene, betI, and three structural genes: betT (choline porter), betA (choline dehydrogenase), and betB (betaine aldehyde dehydrogenase). The bet genes are regulated by oxygen, choline, and osmotic stress. Primer extension analysis identified two partially overlapping promoters which were responsible for the divergent expression of the betT and betIBA transcripts. The transcripts were initiated 61 bp apart. Regulation of the promoters was investigated by using cat (chloramphenicol acetyltransferase) and lacZ (beta-galactosidase) operon fusions. Mutation of betI on plasmid F'2 revealed that BetI is a repressor which regulates both promoters simultaneously in response to the inducer choline. Both promoters remained inducible by osmotic stress in a betI mutant background. On the basis of experiments with hns and hns rpoS mutants, we conclude that osmoregulation of the bet promoters was hns independent. The bet promoters were repressed by ArcA under anaerobic growth conditions. An 89-bp promoter fragment, as well as all larger fragments tested, which included both transcriptional start points, displayed osmotic induction and BetI-dependent choline regulation when linked with a cat reporter gene on plasmid pKK232-8. Flanking DNA, presumably on the betT side of the promoter region, appeared to be needed for ArcA-dependent regulation of both promoters.

DNA-binding properties of the BetI repressor protein of Escherichia coli: the inducer choline stimulates BetI-DNA complex formation.

The betT and betIBA genes govern glycine betaine synthesis from choline in Escherichia coli. In an accompanying paper we report that the betT and betI promoters are divergently organized and partially overlapping and that both are negatively regulated by BetI in response to choline. (T. Lamark, T.P. Rokenes, J. McDougall, and A.R. Strom, J. Bacteriol. 178:1655-1662, 1996). In this paper, we report that the in vivo synthesis rate of the BetI protein constituted only 10% of that of BetA and BetB dehydrogenase proteins, indicating the existence of a posttranscriptional control of the betIBA operon. A genetically modified BetI protein called BetI*, which carries 7 extra N-terminal amino acids, was purified as a glutathione S-transferase fusion protein. Gel mobility shift assays showed that BetI* formed a complex with a 41-bp DNA fragment containing the -10 and -35 regions of both promoters. Only one stable complex was detected with the 41-bp fragment and all larger promoter-containing fragments tested. In DNase I footprinting, BetI* protected a region of 21 nucleotides covering both the -35 boxes. Choline stimulated complex formation but did not change the binding site of BetI*. We conclude that in vivo BetI is bound to its operator in both repressed and induced cells and that BetI represents a new type of repressor.

Production of the Escherichia coli betaine-aldehyde dehydrogenase, an enzyme required for the synthesis of the osmoprotectant glycine betaine, in transgenic plants.

In several organisms osmotic stress tolerance is mediated by the accumulation of the osmoprotective compound glycine betaine. With the ambition to transfer the betaine biosynthetic pathway into plants not capable of synthesizing this osmoprotectant, the Escherichia coli gene betB encoding the second enzyme in the pathway, betaine-aldehyde dehydrogenase was introduced into Nicotiana tabacum. The betB structural gene was fused to the promoter of ats1a, a gene coding for the small subunit of Rubisco in Arabidopsis thaliana. Two types of constructs were made, either encoding the N-terminal transit peptide for chloroplast targeting or without the targeting signal for cytoplasmic localization of the BetB polypeptide. Analysis of transgenic N. tabacum plants harboring these constructs showed that in both cases the transgenes were expressed. Northern analysis of the plants demonstrated the accumulation of betB-related mRNA of the correct size. The production and processing of the corresponding polypeptides could be demonstrated by immunoblotting using polyclonal antisera raised against the BetB polypeptide. The transit peptide encoded by ats1a was able to direct BetB to the chloroplast, as suggested by the presence of the correctly processed BetB polypeptide in the chloroplast fraction. High betaine-aldehyde dehydrogenase activity was detected in transgenic plants, both in those where the chimeric gene product was targeted to the chloroplast and those where it remained in the cytoplasm. The transgenic tobacco acquired resistance to the toxic intermediate, betaine aldehyde, in the betaine biosynthetic pathway indicating that the bacterial enzyme is biologically active in its new host. Furthermore, these transgenic plants were able to convert exogenously supplied betaine aldehyde efficiently to glycine betaine.

Analysis of the otsBA operon for osmoregulatory trehalose synthesis in Escherichia coli and homology of the OtsA and OtsB proteins to the yeast trehalose-6-phosphate synthase/phosphatase complex.

The Escherichia coli otsBA operon, located at min 42, was sequenced and shown to encode a 29.1-kDa trehalose-6-phosphate phosphatase (OtsB) and a 53.6-kDa trehalose-6-phosphate synthase (OtsA). Both proteins display sequence homology with subunits of the Saccharomyces cerevisiae trehalose-6-phosphate synthase/phosphatase complex, which is made up of the subunits TPS1, TPS2 and TPS3 (TSL1). OtsA has homology to the full-length TPS1, the N-terminal part of TPS2 and an internal region of TPS3 (TSL1). OtsB has homology to the C-terminal part of TPS2, but no homology to the other subunits. Primer extension analysis showed only one transcription start point upstream from otsB and one upstream from otsA, regardless of the growth conditions tested. The start codons of the otsB and otsA genes were established by N-terminal sequence determination of the proteins. The 3' end of the otsB coding region overlaps the 5' end of the otsA coding region by 23 nucleotides. The araH gene is located directly upstream from otsBA, and otsB may be identical to pexA.

The parDE operon of the broad-host-range plasmid RK2 specifies growth inhibition associated with plasmid loss.

Recently, a 0.8 kb region of the broad-host-range plasmid RK2 has been shown to be sufficient to stabilize plasmids in a vector-independent, broad-host-range manner under some but not all growth conditions (Roberts, R. C. & Helinski, D. R. (1992). J. Bacteriol. 174, 8119-8132). This region encompasses the parDE operon, which encodes the small proteins ParD and ParE, both of which are required for the plasmid stabilization. This paper demonstrates that the 0.8 kb region encodes the capacity to inhibit cell growth of Escherichia coli, presumably of those bacteria that have lost plasmids carrying this stabilization region, and this inhibition appears to be associated with cell killing and bacterial cell filamentation. A good correlation was observed between the capacity of wild-type and mutated 0.8 kb regions to promote stable maintenance of a temperature-sensitive RK2 replicon plasmid and to inhibit bacterial cell division under specified medium conditions. The properties of the wild-type and mutant 0.8 kb regions further indicate that the ParE protein is responsible for the growth inhibition and the ParD protein neutralizes the toxic activity of the ParE protein. This is consistent with the finding that the presence of the parD gene in trans destabilizes a temperature-sensitive RK2 replicon carrying a copy of the functional 0.8 kb region. This destabilization appears to be the result of ParD protein-mediated suppression of growth inhibition, thus allowing survival of cells that have lost the temperature-sensitive plasmid. These observations indicate that the 0.8 kb sequence of RK2 encodes a growth inhibition function that is likely to play a role in the plasmid stabilization.

Trehalose metabolism in Escherichia coli: stress protection and stress regulation of gene expression.

Endogenously synthesized trehalose is a stress protectant in Escherichia coli. Externally supplied trehalose does not serve as a stress protectant, but it can be utilized as the sole source of carbon and energy. Mutants defective in trehalose synthesis display an impaired osmotic tolerance in minimal growth media without glycine betaine, and an impaired stationary-phase-induced heat tolerance. Mechanisms for stress protection by trehalose are discussed. The genes for trehalose-6-phosphate synthase (otsA) and anabolic trehalose-6-phosphate phosphatase (otsB) constitute an operon. Their expression is induced both by osmotic stress and by growth into the stationary phase and depend on the sigma factor encoded by rpoS (katF). rpoS is amber-mutated in E. coli K-12 and its DNA sequence varies among K-12 strains. For trehalose catabolism under osmotic stress E. coli depends on the osmotically inducible periplasmic trehalase (TreA). In the absence of osmotic stress, trehalose induces the formation of an enzyme IITre (TreB) of the group translocation system, a catabolic trehalose-6-phosphate phosphatase (TreE), and an amylotrehalase (TreC) which converts trehalose to free glucose and a glucose polymer.

A yeast gene for trehalose-6-phosphate synthase and its complementation of an Escherichia coli otsA mutant.

A Saccharomyces cerevisiae gene for trehalose-6-phosphate synthase (TPS1) was sequenced. The gene appeared to code for a protein of 495 amino acid residues, giving the protein a molecular mass of 56 kDa. The TPS1 gene was able to restore both osmotolerance and trehalose accumulation during salt stress in an Escherichia coli strain mutated in the otsA gene encoding trehalose-6-phosphate synthase. Complementation studies with E. coli galU mutants showed that the TPS1-encoded trehalose-6-phosphate synthase is UDP-glucose-dependent. Sequence analysis and data base searches showed that TPS1 is allelic to GGS1, byp1, cif1 and fdp1. A possible gene for trehalose-6-phosphate synthase in Methanobacterium thermoautotrophicum was identified.

Efflux of choline and glycine betaine from osmoregulating cells of Escherichia coli.

We present evidence that glycine betaine (betaine) which was synthesized from choline was excreted and reaccumulated in osmoregulating cells of Escherichia coli. Choline which was accumulated in bet mutants defective in betaine synthesis was shown to be excreted in response to betaine uptake. Our data suggest that E. coli has efflux systems for betaine and choline which are independent of the uptake systems for these metabolites. The ProU system of E. coli, but not that of Salmonella typhimurium, can mediate low-affinity choline uptake.

Molecular cloning and physical mapping of the otsBA genes, which encode the osmoregulatory trehalose pathway of Escherichia coli: evidence that transcription is activated by katF (AppR)

It has been shown previously that the otsA and otsB mutations block osmoregulatory trehalose synthesis in Escherichia coli. We report that the transcription of these osmoregulated ots genes is dependent on KatF (AppR), a putative sigma factor for certain stationary phase- and starvation-induced genes. The transcription of the osmoregulated bet and proU genes was not katF dependent. Our genetic analysis showed that katF carries an amber mutation in E. coli K-12 and many of its derivatives but that katF has reverted to an active form in the much-used strain MC4100. This amber mutation in katF leads to strain variations in trehalose synthesis and other katF-dependent functions of E. coli. We have performed a molecular cloning of the otsBA genes, and we present evidence that they constitute an operon encoding trehalose-6-phosphate phosphatase and trehalose-6-phosphate synthase. A cloning and restriction site analysis, performed by comparing the cloned fragments with the known physical map of the E. coli chromosome, revealed that the otsBA genes are situated on a 2.9-kb HindIII fragment located 8 to 11 kb clockwise of tar (41.6 min).

DNA sequence and analysis of the bet genes encoding the osmoregulatory choline-glycine betaine pathway of Escherichia coli.

The sequence was determined of 6493 nucleotides encompassing the bet genes of Escherichia coli which encode the osmoregulatory choline-glycine betaine pathway. Four open reading frames were identified: betA encoding choline dehydrogenase, a flavoprotein of 61.9kDa; betB encoding betaine aldehyde dehydrogenase (52.8kDa); betT encoding a proton-motive-force-driven, high-affinity transport system for choline (75.8kDa); and betl, capable of encoding a protein of 21.8kDa, implicated as a repressor involved in choline regulation of the bet genes. Identification of the genes was supported by subcloning, physical mapping of lambda placMu53 insertions, amino acid sequence similarity, or N-terminal amino acid sequencing. The bet genes are tightly spaced, with betT located upstream of, and transcribed divergently to, the tandemly linked betIBA genes.

Synthesis, accumulation, and excretion of trehalose in osmotically stressed Escherichia coli K-12 strains: influence of amber suppressors and function of the periplasmic trehalase.

It has been reported previously that Escherichia coli K-12 carries an amber mutation that prevents osmotic stress-dependent accumulation of trehalose (M. L. Rod, K. Y. Alam, P. R. Cunningham, and D. P. Clark, J. Bacteriol. 170:3601-3610, 1988). We report that E. coli K-12 and W1485 (sup0) accumulated trehalose but that they required a higher osmotic strength in the growth medium than that required by their sup+ derivatives. Furthermore, the sup+ derivatives displayed both strongly increased trehalose-6-phosphate synthase activity and expression of otsA-lacZ and otsB-lacZ operon fusions compared with their parental strains. It is suggested that the amber mutation in question may be in a gene system encoding a transcriptional activator of the ots genes which govern the synthase. The much-used sup0 strain MC4100 behaved like the sup+ derivatives of W1485 with respect to trehalose synthesis. treA mutants with a defective periplasmic trehalase accumulated trehalose extracellularly under osmotic stress. The amount of trehalose excreted correlated with their synthase activity. Strains with an intact trehalase did not display extracellular trehalose accumulation. Thus, stressed E. coli cells regulate the cytoplasmic level of trehalose by a futile cycle involving overproduction, excretion, and degradation to glucose, which is reutilized.

Purification and characterization of osmoregulatory betaine aldehyde dehydrogenase of Escherichia coli.

The osmoregulatory NAD-dependent betaine aldehyde dehydrogenase (betaine aldehyde:NAD oxidoreductase, EC 1.2.1.8), of Escherichia coli, was purified to apparent homogeneity from an over-producing strain carrying the structural gene for the enzyme (betB) on the plasmid vector pBR322. Purification was achieved by ammonium sulfate fractionation of disrupted cells, followed by affinity chromatography on 5'-AMP Sepharose, gel-filtration and ion-exchange chromatography. The amino acid composition was determined. The dehydrogenase was found to be a tetramer with identical 55 kDa subunits. Both NAD and NADP could be used as cofactor for the dehydrogenase, but NAD was preferred. The dehydrogenase was highly specific for betaine aldehyde. None of the analogs tested functioned as a substrate, but several inhibited the enzyme competitively. The enzyme was not activated by salts at concentrations encountered during osmotic upshock, but it was salt tolerant, retaining 50% of maximal activity at 1.2 M K+. It is inferred that salt tolerance is an essential property for an enzyme participating in the cellular synthesis of an osmoprotectant.

Biochemical and genetic characterization of osmoregulatory trehalose synthesis in Escherichia coli.

It has been shown previously that Escherichia coli accumulates endogenously synthesized trehalose under osmotic stress. We report here that E. coli contained an osmotically regulated trehalose-phosphate synthase which utilized UDP-glucose and glucose 6-phosphate as substrates. In the wild type, the synthase was induced by growth in glucose-mineral medium of elevated osmotic strength and the synthase itself was strongly stimulated by K+ and other monovalent cations. A laboratory strain which expressed the synthase at a high constitutive level was found. GalU mutants, defective in synthesis of UDP-glucose, did not accumulate trehalose. Two genes governing the synthase were identified and named otsA and otsB (osmoregulatory trehalose synthesis). They mapped near 42 min in the flbB-uvrC region. Mutants with an otsA-lacZ or otsB-lacZ operon fusion displayed osmotically inducible beta-galactosidase activity; i.e., the activity was increased fivefold by growth in medium of elevated osmotic strength. Mutants unable to synthesize trehalose (galU, otsA, and otsB) were osmotically sensitive in glucose-mineral medium. But an osmotically tolerant phenotype was restored in the presence of glycine betaine, which also partially repressed the synthesis of synthase in the wild type and of beta-galactosidase in ots-lacZ fusion mutants.

Molecular cloning, physical mapping and expression of the bet genes governing the osmoregulatory choline-glycine betaine pathway of Escherichia coli.

An analysis of the bet genes governing the osmoregulatory choline-glycine betaine pathway of Escherichia coli was performed. A 9 kb BamHI fragment, located 30 to 39 kb counterclockwise of the EcoRI site of lacZ, coded for all known Bet activities. The following genes were identified: the betA gene for the choline dehydrogenase, the betB gene for the betaine aldehyde dehydrogenase, and the betT gene or operon for the high-affinity choline transport. The betB and the betT genes were named in this paper, and the clockwise gene order was shown to be betA,B,T. Subcloning gave plasmids which expressed each of the three Bet activities separately. The cloned bet genes remained osmotically regulated, indicating the existence of several osmotically regulated promoters in the bet region. Salmonella typhimurium, which carried the bet region of E. coli in the broad-host-range vector pRK293 expressed the three Bet activities and displayed increased osmotic tolerance in the presence of choline.

Osmoregulation in Escherichia coli by accumulation of organic osmolytes: betaines, glutamic acid, and trehalose.

It has been shown previously that externally added glycine betaine is accumulated in Escherichia coli in response to the external osmotic strength. Here we have shown, by using nuclear magnetic resonance spectroscopy and radiochemical methods, that E. coli growing in a glucose-mineral medium of elevated osmotic strength generated with NaCl, had the same capacity to accumulate proline betaine and glycine betaine. Its capacity to accumulate gamma-butyrobetaine was, however, 40 to 50% lower. Accordingly, externally added proline betaine and glycine betaine stimulated aerobic growth of osmotically stressed cells equally well, and they were more osmoprotective than gamma-butyrobetaine. In cells grown at an osmotic strength of 0.64, 1.01, or 1.47 osmolal, respectively, the molal cytoplasmic concentration of the two former betaines corresponded to 29, 38, or 58% of the external osmotic strength. Nuclear magnetic resonance spectroscopy revealed that trehalose and glutamic acid were the only species of organic osmolytes accumulated in significant amounts in cells grown under osmotic stress in glucose-mineral medium without betaines. Their combined molal concentration in the cytoplasm of cells grown at 1.01 osmolal corresponded to 27% of the external osmotic strength.

Choline-glycine betaine pathway confers a high level of osmotic tolerance in Escherichia coli.

Glycine betaine and its precursors choline and glycine betaine aldehyde have been found to confer a high level of osmotic tolerance when added exogenously to cultures of Escherichia coli at an inhibitory osmotic strength. In this paper, the following findings are described. Choline works as an osmoprotectant only under aerobic conditions, whereas glycine betaine aldehyde and glycine betaine function both aerobically and anaerobically. No endogenous glycine betaine accumulation was detectable in osmotically stressed cells grown in the absence of the osmoprotectant itself or the precursors. A membrane-bound, O2-dependent, and electron transfer-linked dehydrogenase was found which oxidized choline to glycine betaine aldehyde and aldehyde to glycine betaine at nearly the same rate. It displayed Michaelis-Menten kinetics; the apparent Km values for choline and glycine betaine aldehyde were 1.5 and 1.6 mM, respectively. Also, a soluble, NAD-dependent dehydrogenase oxidized glycine betaine aldehyde. It displayed Michaelis-Menten kinetics; the apparent Km values for the aldehyde, NAD, and NADP were 0.13, 0.06, and 0.5 mM, respectively. The choline-glycine betaine pathway was osmotically regulated, i.e., full enzymic activities were found only in cells grown aerobically in choline-containing medium at an elevated osmotic strength. Chloramphenicol inhibited the formation of the pathway in osmotically stressed cells.

Selection, mapping, and characterization of osmoregulatory mutants of Escherichia coli blocked in the choline-glycine betaine pathway.

Osmotically stressed Escherichia coli cells synthesize the osmoprotectant glycine betaine by oxidation of choline through glycine betaine aldehyde (choline----glycine betaine aldehyde----glycine betaine; B. Landfald and A.R. Strøm, J. Bacteriol. 165:849-855, 1986. Mutants blocked at the level of choline dehydrogenase were isolated by selection of strains which did not grow at elevated osmotic strength in the presence of choline but grew when supplemented with glycine betaine. A gene governing the choline dehydrogenase activity was named betA. Mapping by P1 transduction, F' complementation, and deletion mutagenesis showed the betA gene to be located at 7.5 min in the argF-codAB region of the chromosome. Mutants carrying deletions of this region also lacked glycine betaine aldehyde dehydrogenase activity and high-affinity uptake activity for choline; these deletions did not influence the activities of glycine betaine uptake or low-affinity choline uptake, both of which were osmotically regulated.