Characterization of the ectoine biosynthesis genes of haloalkalotolerant obligate methanotroph “Methylomicrobium alcaliphilum 20Z”

The genes involved in biosynthesis of the major compatible solute ectoine (1,4,5,6-tetrahydro-2-methylpyrimidine carboxylic acid) in halotolerant obligate methanotroph “Methylomicrobium alcaliphilum 20Z” were studied. The complete nucleotide sequences of the structural genes encoding l-aspartokinase (Ask), l-2,4-diaminobutyric acid transaminase (EctB), l-2,4-diaminobutyric acid acetyltransferase (EctA), and l-ectoine synthase (EctC) were defined and shown to be transcribed as a single operon ectABCask. Phylogenetic analysis revealed high sequence identities (34–63%) of the Ect proteins to those from halophilic heterotrophs with the highest amino acid identities being to Vibrio cholerae enzymes. The chromosomal DNA fragment from “M. alcaliphilum 20Z” containing ectABC genes and putative promoter region was expressed in Escherichia coli. Recombinant cells could grow in the presence of 4% NaCl and synthesize ectoine. The data obtained suggested that despite the ectoine biosynthesis pathway being evolutionary well conserved with respect to the genes and enzymes involved, some differences in their organization and regulation could occur in various halophilic bacteria.Dedicated to the 70th birthday of Professor Gerhard Gottschalk who inspired our studies on methylotrophic haloalkaliphiles.     

Biochemistry and Crystal Structure of Ectoine Synthase: A Metal-Containing Member of the Cupin Superfamily

Ectoine is a compatible solute and chemical chaperone widely used by members of the Bacteria and a few Archaea to fend-off the detrimental effects of high external osmolarity on cellular physiology and growth. Ectoine synthase (EctC) catalyzes the last step in ectoine production and mediates the ring closure of the substrate N-gamma-acetyl-L-2,4-diaminobutyric acid through a water elimination reaction. However, the crystal structure of ectoine synthase is not known and a clear understanding of how its fold contributes to enzyme activity is thus lacking. Using the ectoine synthase from the cold-adapted marine bacterium Sphingopyxis alaskensis (Sa), we report here both a detailed biochemical characterization of the EctC enzyme and the high-resolution crystal structure of its apo-form. Structural analysis classified the (Sa)EctC protein as a member of the cupin superfamily. EctC forms a dimer with a head-to-tail arrangement, both in solution and in the crystal structure. The interface of the dimer assembly is shaped through backbone-contacts and weak hydrophobic interactions mediated by two beta-sheets within each monomer. We show for the first time that ectoine synthase harbors a catalytically important metal co-factor; metal depletion and reconstitution experiments suggest that EctC is probably an iron-dependent enzyme. We found that EctC not only effectively converts its natural substrate N-gamma-acetyl-L-2,4-diaminobutyric acid into ectoine through a cyclocondensation reaction, but that it can also use the isomer N-alpha-acetyl-L-2,4-diaminobutyric acid as its substrate, albeit with substantially reduced catalytic efficiency. Structure-guided site-directed mutagenesis experiments targeting amino acid residues that are evolutionarily highly conserved among the extended EctC protein family, including those forming the presumptive iron-binding site, were conducted to functionally analyze the properties of the resulting EctC variants. An assessment of enzyme activity and iron content of these mutants give important clues for understanding the architecture of the active site positioned within the core of the EctC cupin barrel.     

The biosynthesis of ectoine

Abstract The biosynthetic pathway of the novel compatible solute ectoine (1,4,5,6-tetrahydro-2-methyl-4-pyrimidine carboxylic acid) was studied in the two extremely halophilic eubacteria Ectothiorhodospira halochloris and Halomonas elongata . The pathway starts with the phosphorylation of l -aspartate and shares its first two enzymatic steps with the biosynthesis of amino acids of the aspartate family: aspartokinase and l -aspartate-β-semialdehyde dehydrogenase. Evidence is presented for the presence of the enzymes l -diaminobutyric acid transaminase and l -diaminobutyric acid acetyl transferase and for the new enzyme the ring-forming ectoine synthase.     

Comparison of ectoine synthesis regulation in secreting and non-secreting strains of Halomonas

Ectoine is an osmotic pressure compatible solute. It is synthesized by Halomonas and other microorganisms in a hypertonic environment. As a stabilizing agent of cells proteins, nucleic acids and other biological products, ectoine has wide applications. Therefore, an efficient production method for ectoine is in great demand. Ectoine is overproduced by Halomonas salina DSM 5928, an ectoine-secreting strain, in which the synthesis of ectoine is not limited by its intracellular threshold concentration. In order to explain the mechanism of secretion of ectoine, the response to NaCl stress, and the release and uptake kinetics of ectoine were compared between H. salina DSM 5928 and Halomonas elongata DSM 2581, a non-ectoine-secreting strain. Moreover, the ectoine binding protein TeaA from each of these two strains was cloned and expressed, and binding abilities were examined in vitro. The results indicated that H. salina DSM 5928 and H. elongata DSM 2581 respond to NaCl in the medium in different ways. Compared with H. elongata DSM 2581, the amount of ectoine released was higher and the uptake of ectoine under NaCl stress was lower in H. salina DSM 5928. In addition, the binding ability of TeaA to ectoine in H. salina DSM 5928 was also lower. These results reveal the secretion mechanism of ectoine as well as critical regulation and control factors involved in ectoine synthesis.     

中度嗜盐菌四氢嘧啶合成基因的克隆与功能分析

中度嗜盐菌Bacillus alcalophilus DTY1分离自晋西北黄土高原盐碱土壤, 能够产生耐盐相关的相容性溶质四氢嘧啶。为了研究四氢嘧啶的功能, 克隆了DTY1菌株四氢嘧啶合成基因簇ectABC。ectA、ectB和ectC分别编码169、428和132个氨基酸的肽链, 分别与B. halodurans C-125中的二氨基丁酸乙酰基转移酶(EctA)、二氨基丁酸氨基转移酶(EctB)、四氢嘧啶合成酶(EctC)同源性达59%、81%和81%。将携带该基因簇的4.0 kb片段转入蜡质芽孢杆菌B. cereus Z后, 芽孢杆菌的耐盐度显著提高。HPLC检测发现, 在1.0% NaCl浓度下, 转化菌B. cereus Z-E菌株生成70.1 mg/g四氢嘧啶, 而在5.0%的NaCl浓度下四氢嘧啶的产量高达118.6 mg/g, 显著高于B. alcalophilus DTY1的四氢嘧啶产量。而且随着盐浓度的提高, 四氢嘧啶的合成量也随之提高。由此证明四氢嘧啶参与中度嗜盐菌重要的渗透调节, ectABC的表达受盐诱导。     

中度嗜盐菌四氢嘧啶合成基因的克隆与功能分析

中度嗜盐菌Bacillus alcalophilus DTY1分离自晋西北黄土高原盐碱土壤, 能够产生耐盐相关的相容性溶质四氢嘧啶。为了研究四氢嘧啶的功能, 克隆了DTY1菌株四氢嘧啶合成基因簇ectABC。ectA、ectB和ectC分别编码169、428和132个氨基酸的肽链, 分别与B. halodurans C-125中的二氨基丁酸乙酰基转移酶(EctA)、二氨基丁酸氨基转移酶(EctB)、四氢嘧啶合成酶(EctC)同源性达59%、81%和81%。将携带该基因簇的4.0 kb片段转入蜡质芽孢杆菌B. cereus Z后, 芽孢杆菌的耐盐度显著提高。HPLC检测发现, 在1.0% NaCl浓度下, 转化菌B. cereus Z-E菌株生成70.1 mg/g四氢嘧啶, 而在5.0%的NaCl浓度下四氢嘧啶的产量高达118.6 mg/g, 显著高于B. alcalophilus DTY1的四氢嘧啶产量。而且随着盐浓度的提高, 四氢嘧啶的合成量也随之提高。由此证明四氢嘧啶参与中度嗜盐菌重要的渗透调节, ectABC的表达受盐诱导。     

Characterization of Biosynthetic Enzymes for Ectoine as a Compatible Solute in a Moderately Halophilic Eubacterium,Halomonas elongata

1,4,5,6-Tetrahydro-2-methyl-4-pyrimidinecarboxylic acid (ectoine) is an excellent osmoprotectant. The biosynthetic pathway of ectoine from aspartic β-semialdehyde (ASA), in Halomonas elongata, was elucidated by purification and characterization of each enzyme involved. 2,4-Diaminobutyrate (DABA) aminotransferase catalyzed reversively the first step of the pathway, conversion of ASA to DABA by transamination with l-glutamate. This enzyme required pyridoxal 5′-phosphate and potassium ions for its activity and stability. The gel filtration estimated an apparent molecular mass of 260 kDa, whereas molecular mass measured by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) was 44 kDa. This enzyme exhibited an optimum pH of 8.6 and an optimum temperature of 25°C and had K_ms of 9.1 mM for l-glutamate and 4.5 mM for dl-ASA. DABA acetyltransferase catalyzed acetylation of DABA to γ-N-acetyl-α,γ-diaminobutyric acid (ADABA) with acetyl coenzyme A and exhibited an optimum pH of 8.2 and an optimum temperature of 20°C in the presence of 0.4 M NaCl. The molecular mass was 45 kDa by gel filtration. Ectoine synthase catalyzed circularization of ADABA to ectoine and exhibited an optimum pH of 8.5 to 9.0 and an optimum temperature of 15°C in the presence of 0.5 M NaCl. This enzyme had an apparent molecular mass of 19 kDa by SDS-PAGE and a K_m of 8.4 mM in the presence of 0.77 M NaCl. DABA acetyltransferase and ectoine synthase were stabilized in the presence of NaCl (>2 M) and DABA (100 mM) at temperatures below 30°C.Halotolerance is of considerable interest scientifically and from the perspective of wide application in fermentation industries and in agriculture. When eubacteria are exposed to hyperosmotic stress, they accumulate various low-molecular-weight organic compounds, the so-called “compatible solutes” such as polyols, amino acids, sugars, and betaines (7–9, 13, 19, 48), because maintenance of turgor pressure is a prerequisite for growth under the conditions of elevated external osmotic pressure. Since Galinski et al. (14) discovered 1,4,5,6-tetrahydro-2-methyl-4-pyrimidinecarboxylic acid (ectoine) as a compatible solute in Ectothiorhodospira halochloris, an extremely halophilic phototrophic eubacterium, ectoine has been found to be distributed widely in nature, largely in moderately halophilic eubacteria (3, 11, 12, 26, 38, 50). In addition, ectoine has been investigated as a new excellent universal osmoprotectant in this decade, since incorporation of external ectoine under hyperosmotic stress has been observed to confer protection on various nonhalotolerant eubacteria (16, 21, 44).We previously isolated a moderately halophilic eubacterium, Halomonas elongata (31), from dry salty land in Thailand. We identified ectoine and γ-N-acetyl-α,γ-diaminobutyric acid (ADABA), which is one of the cleavage structures of ectoine, as osmotically responding compounds in the cells grown in a glucose-mineral medium containing NaCl in a concentration range of 3 to 15% (31). To understand the accumulation mechanism of the intracellular ectoine, characterization of enzymes involved in the biosynthesis of ectoine is indispensable. Therefore, we have focused on the biosynthetic enzyme of ectoine in this organism. We observed that radioactivity from [1-¹⁴C]aspartate was most efficiently incorporated into ectoine and that the signal intensity was enriched preferentially from [1-¹³C]acetate into the methyl carbon at position 2′ and from [2-¹³C]acetate into the methine carbon at position 2 of the ectoine skeleton, respectively, in ¹³C nuclear magnetic resonance (NMR) spectroscopy (22). From these findings, we also hypothesized the following pathway essentially similar to that described by Peters et al. (34): aspartic β-semialdehyde (ASA) is converted to 2,4-diaminobutyric acid (DABA) by transamination, and DABA is converted to ADABA by acetylation with acetyl coenzyme A (CoA), which in turn yields ectoine by circularization (Fig. ​(Fig.1).1). The three enzymes involved in this pathway are DABA aminotransferase, DABA acetyltransferase, and ectoine synthase in order of the reactions to ectoine. Peters et al. (34) detected the activity of the first and the second of the three steps by using crude extracts of E. halochloris and H. elongata. However, the characterization of these enzymes was limited; in particular, their responses to various salt concentrations remained unknown. Open in a separate windowFIG. 1Proposed biosynthetic pathway of ectoine in H. elongata {"type":"entrez-protein","attrs":{"text":"OUT30018","term_id":"1200192464","term_text":"OUT30018"}}OUT30018.In this study, we confirmed the biosynthetic pathway of ectoine by using purified enzymes in H. elongata {"type":"entrez-protein","attrs":{"text":"OUT30018","term_id":"1200192464","term_text":"OUT30018"}}OUT30018 and characterized the three enzymes involved in the conversion of ASA to ectoine for the first time.     

The effects of L-2,4-diaminobutyric acid on the uptake of gamma-aminobutyric acid by a synaptosomal fraction from rat brain

l-2,4-diaminobutyric acid was studied as an inhibitor of gamma-aminobutyric acid uptake by a synaptosomal fraction isolated from rat brain. Competitive inhibition was observed during short-term exposure of the synaptosomal fraction to the inhibitor but noncompetitive inhibition was observed following prolonged exposure. Studies on the mode of action of l-2,4-diaminobutyric acid showed that the synaptosomal fraction was capable of accumulating this compound and that both the uptake and the effectiveness of the inhibitor were sodium-dependent and temperature-sensitive. In addition, the degree of inhibition of gamma-aminobutyric acid uptake was related to the amount of l-2,4-diaminobutyric acid accumulated. It is suggested that the observed noncompetitive inhibition of gamma-aminobutyric acid uptake by l-2,4-diaminobutyric acid is a result of the accumulation of the inhibitor which exerts its effect from within the synaptosomes. Raising the external concentration of gamma-aminobutyric acid to saturating levels did not completely inhibit the accumulation of l-2,4-diaminobutyric acid. Thus, the transport of l-2,4-diaminobutyric acid appears to be mediated, at least in part, by a carrier which is not involved in the transport of gamma-amiuobutyric acid.     

The `neurotoxicity'' of l-2,4-diaminobutyric acid

The neurolathyrogen l-2,4-diaminobutyric acid is concentrated by liver, and liver damage can yield neurotoxicity; thus the neurotoxicity caused by this compound may be due to liver damage followed by secondary brain damage. 1. The intraperitoneal administration of toxic doses of l-2,4-diaminobutyric acid to rats resulted in hyperirritability, tremors and convulsions in 12-20hr. and increased the concentration of ammonia of blood and brain slightly and the concentration of glutamine of brain two- to three-fold. By contrast, toxic doses of l-homoarginine, l-lysine, l-leucine and ammonium acetate caused dyspnoea, extreme prostration, and in some cases coma in 15-30min., and increased the concentration of ammonia of blood significantly and the concentration of glutamine of brain slightly. These results indicate that l-2,4-diaminobutyric acid caused a chronic ammonia toxicity, whereas the other amino acids and ammonium acetate resulted in an acute ammonia toxicity. 2. Liver slices from l-2,4-diaminobutyric acid-treated animals and normal liver slices preincubated with l-2,4-diaminobutyric acid utilized ammonia and formed urea at a lower rate than control slices from normal rats. 3. l-2,4-Diaminobutyric acid inhibited competitively ornithine carbamoyltransferase of rat liver homogenates, thus demonstrating that this reaction is a primary site of toxicity for this neurolathyrogen. Although we were unable to show marked elevations of blood ammonia concentration after treatment with l-2,4-diaminobutyric acid, these results are interpreted to mean that ammonia utilization (urea synthesis) in liver is inhibited by l-2,4-diaminobutyric acid and that at least part of the neurotoxicity is due to a prolonged slight increase in body ammonia concentration.     

Ectoine, the compatible solute of Halomonas elongata, confers hyperosmotic tolerance in cultured tobacco cells

1,4,5,6-Tetrahydro-2-methyl-4-pyrimidinecarboxylic acid (ectoine) functions as a compatible osmolyte in the moderate halophile Halomonas elongata OUT30018. Ectoine is biosynthesized by three successive enzyme reactions from aspartic beta-semialdehyde. The genes encoding the enzymes involved in the biosynthesis, ectA, ectB, and ectC, encoding L-2,4-diaminobutyric acid acetyltransferase, L-2, 4-diaminobutyric acid transaminase, and L-ectoine synthase, respectively, have been previously cloned. To investigate the function of ectoine as a compatible solute in plant cells, the three genes were individually placed under the control of the cauliflower mosaic virus 35S promoter and introduced together into cultured tobacco (Nicotiana tabacum L.) cv Bright Yellow 2 (BY2) cells. The transgenic BY2 cells accumulated a small quantity of ectoine (14-79 nmol g(-1) fresh weight) and showed increased tolerance to hyperosmotic shock (900 mOsm). Furthermore, the transgenic BY2 cells exhibited a normal growth pattern even under hyperosmotic conditions (up to 530 mOsm), in which the growth of the untransformed BY2 (wild type) cells was obviously delayed. These results suggest that genetically engineered synthesis of ectoine results in the increased hyperosmotic tolerance of cultured tobacco BY2 cells despite the low level of accumulation of the solute.     

Role of Nγ-Acetyldiaminobutyrate as an Enzyme Stabilizer and an Intermediate in the Biosynthesis of Hydroxyectoine

Strain CHR63 is a salt-sensitive mutant of the moderately halophilic wild-type strain Halomonas elongata DSM 3043 that is affected in the ectoine synthase gene (ectC). This strain accumulates large amounts of Nγ-acetyldiaminobutyrate (NADA), the precursor of ectoine (D. Cánovas, C. Vargas, F. Iglesias-Guerra, L. N. Csonka, D. Rhodes, A. Ventosa, and J. J. Nieto, J. Biol. Chem. 272:25794–25801, 1997). Hydroxyectoine, ectoine, and glucosylglycerate were also identified by nuclear magnetic resonance (NMR) as cytoplasmic organic solutes in this mutant. Accumulation of NADA, hydroxyectoine, and ectoine was osmoregulated, whereas the levels of glucosylglycerate decreased at higher salinities. The effect of the growth stage on the accumulation of solutes was also investigated. NADA was purified from strain CHR63 and was shown to protect the thermolabile enzyme rabbit muscle lactate dehydrogenase against thermal inactivation. The stabilizing effect of NADA was greater than the stabilizing effect of ectoine or potassium diaminobutyrate. A ¹H NMR analysis of the solutes accumulated by the wild-type strain and mutants CHR62 (ectA::Tn1732) and CHR63 (ectC::Tn1732) indicated that H. elongata can synthesize hydroxyectoine by two different pathways—directly from ectoine or via an alternative pathway that converts NADA into hydroxyectoine without the involvement of ectoine.     

Cloning and Characterization of the Genes for Biosynthesis of the Compatible Solute Ectoine in the Moderately Halophilic Bacterium Halobacillus dabanensis D-8T

A 11.2-kb fragment containing the ectABC genes of the biosynthetic pathway of ectoine from the Gram-positive, moderately halophilic bacterium Halobacillus dabanensis D-8^T was obtained by inverse polymerase chain reaction. Subsequently, the entire ectABC cluster was cloned and analyzed. It revealed that the intergenic regions of the ectABC genes from H. dabanensis D-8^T are more tightly spaced than those of Chromohalobacter salexigens, Halomonas elongata, Marinococcus halophilus, and Salibacillus pasteurii. The amino-acid sequence deduced from ectABC was highly homologous that from Virgibacillus pantethenticus (EctA 52%, EctB 60%, EctC 67%, respectively). The ectABC genes were cloned in the expression plasmid pMXB10 resulting in pMXB10ectABC. The ectoine was detected from cell extract in Escherishia coli ER2566 containing pMXB10ectABC using ¹³C nuclear magnetic resonance spectroscopy.     

Optimization of the extraction and purification of the compatible solute ectoine from <Emphasis Type="Italic">Halomonas elongate</Emphasis> in the laboratory experiment of a commercial production project

Optimization of compatible solutes (ectoine) extraction and purification from Halomonas elongata cell fermentation had been investigated in the laboratory tests of a large scale commercial production project. After culturing H. elongata cells in developed medium at 28?°C for 23–30 h, we obtained an average yield and biomass of ectoine for 15.9 g/L and 92.9 (OD₆₀₀), respectively. Cell lysis was performed with acid treatment at moderate high temperature (60–70?°C). The downstream processing operations were designed to be as follows: filtration, desalination, cation exchange, extraction of crude product and three times of refining. Among which the cation exchange and extraction of crude product acquired a high average recovery rate of 95 and 96%; whereas a great loss rate of 19 and 15% was observed during the filtration and desalination, respectively. Combined with the recovering of ectoine from the mother liquor of the three times refining, the average of overall yield (referring to the amount of ectoine synthesized in cells) and purity of final product obtained were 43% and over 98%, respectively. However, key factors that affected the production efficiency were not yields but the time used in the extraction of crude product, involving the crystallization step from water, which spended 24–72 h according to the production scale. Although regarding to the productivity and simplicity on laboratory scale, the method described here can not compete with other investigations, in this study we acquired higher purity of ectoine and provided downstream processes that are capable of operating on industrial scale.     

Unexpected property of ectoine synthase and its application for synthesis of the engineered compatible solute ADPC

A new cyclic amino acid was detected in a deletion mutant of the moderately halophilic bacterium Halomonas elongata deficient in ectoine synthesis. Using mass spectroscopy (MS) and nuclear magnetic resonance (NMR) techniques, the substance was identified as 5-amino-3,4-dihydro-2H-pyrrole-2-carboxylate (ADPC). We were able to demonstrate that ADPC is the product of a side reaction of lone ectoine synthase (EC 4.2.1.108), which forms ADPC by cyclic condensation of glutamine. This reaction was shown to be reversible. Subsequently, a number of ectoine derivatives, in particular 4,5-dihydro-2-methylimidazole-4-carboxylate (DHMICA) and homoectoine, were also shown to be cleaved by ectoine synthase, which is classified as a hydro-lyase. This study thus reports for the first time that ectoine synthase accepts more than one substrate and is a reversible enzyme able to catalyze both the intramolecular condensation into and the hydrolytic cleavage of cyclic amino acid derivatives. As ADPC supports growth of bacteria under salt stress conditions and stabilizes enzymes against freeze-thaw denaturation, it displays typical properties of compatible solutes. As ADPC has not yet been described as a natural compound, it is presented here as the first man-made compatible solute created through genetic engineering.     

Biochemical Properties of Ectoine Hydroxylases from Extremophiles and Their Wider Taxonomic Distribution among Microorganisms

Ectoine and hydroxyectoine are well-recognized members of the compatible solutes and are widely employed by microorganisms as osmostress protectants. The EctABC enzymes catalyze the synthesis of ectoine from the precursor L-aspartate-β-semialdehyde. A subgroup of the ectoine producers can convert ectoine into 5-hydroxyectoine through a region-selective and stereospecific hydroxylation reaction. This compatible solute possesses stress-protective and function-preserving properties different from those of ectoine. Hydroxylation of ectoine is carried out by the EctD protein, a member of the non-heme-containing iron (II) and 2-oxoglutarate-dependent dioxygenase superfamily. We used the signature enzymes for ectoine (EctC) and hydroxyectoine (EctD) synthesis in database searches to assess the taxonomic distribution of potential ectoine and hydroxyectoine producers. Among 6428 microbial genomes inspected, 440 species are predicted to produce ectoine and of these, 272 are predicted to synthesize hydroxyectoine as well. Ectoine and hydroxyectoine genes are found almost exclusively in Bacteria. The genome context of the ect genes was explored to identify proteins that are functionally associated with the synthesis of ectoines; the specialized aspartokinase Ask_Ect and the regulatory protein EctR. This comprehensive in silico analysis was coupled with the biochemical characterization of ectoine hydroxylases from microorganisms that can colonize habitats with extremes in salinity (Halomonas elongata), pH (Alkalilimnicola ehrlichii, Acidiphilium cryptum), or temperature (Sphingopyxis alaskensis, Paenibacillus lautus) or that produce hydroxyectoine very efficiently over ectoine (Pseudomonas stutzeri). These six ectoine hydroxylases all possess similar kinetic parameters for their substrates but exhibit different temperature stabilities and differ in their tolerance to salts. We also report the crystal structure of the Virgibacillus salexigens EctD protein in its apo-form, thereby revealing that the iron-free structure exists already in a pre-set configuration to incorporate the iron catalyst. Collectively, our work defines the taxonomic distribution and salient biochemical properties of the ectoine hydroxylase protein family and contributes to the understanding of its structure.     

Functional Expression of the Ectoine Hydroxylase Gene (thpD) from Streptomyces chrysomallus in Halomonas elongata

The formation of hydroxyectoine in the industrial ectoine producer Halomonas elongata was improved by the heterologous expression of the ectoine hydroxylase gene, thpD, from Streptomyces chrysomallus. The efficient conversion of ectoine to hydroxyectoine was achieved by the concerted regulation of thpD by the H. elongata ectA promoter.     

<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     

Potentiation of l-canavanine-induced developmental anomalies in the tobacco hornworm, Manduca sexta, by some amino acids

The growth and development of final-stadium tabacco hornworm Manduca sexta (Sphingidae) larvae fed a 2.5 mM l-canavanine-containing diet is disrupted markedly. Such canavanine-mediated disruption of larval growth is intensified greatly when these organisms are fed a canavanine-containing diet supplemented with a 1 : 10 molar ratio of l-arginine, l-citrulline, l-ornithine or l-2,4-diaminobutyric acid, the larvae possess enhanced haemolymph volume (oedema) and a significant mortality results from incomplete larval-pupal ecdysis. Two other compounds, 3-aminobutyric acid and l-2,3-diaminopropionic acid, do not produce larvae showing oedema but most larvae fail to complete larval-pupal ecdysis. 4-Aminobutyric acid, l-threonine and l-glutamic acid are much less potent but they still manifest appreciable developmental aberrations. Eighteen other tested compounds have no discernible effect. In general, compounds accentuating the biological activity of canavanine have: an α-carboxyl and α-amino group; a carbon skeleton of no less than 2 nor more than 4 carbon atoms; and and ω-amino group.