渗透压冲击下中度嗜盐菌Halomonas sp. Y四氢嘧啶类相容性溶质的合成与释放

【背景】四氢嘧啶类物质在高温、冷冻和干燥等逆境条件下,对酶、蛋白质、核酸及整个细胞具有良好的保护作用,已经应用于酶制剂、生物医药及护肤品等相关领域。目前此类物质只能依赖中度嗜盐菌采用细菌泌乳工艺进行商业化生产,因此四氢嘧啶类高产菌株及其发酵技术的研究日益受到国内外研究者关注。【目的】分离获得高产合成四氢嘧啶类相容性溶质的中度嗜盐细菌,研究渗透压冲击对其胞内四氢嘧啶合成与释放的影响,探索细菌泌乳法制备四氢嘧啶的可行性。【方法】采用涂布平板法分离中度嗜盐菌,对分离菌株进行形态、生理生化和16S rRNA基因序列分析,鉴定其种属;采用高效液相色谱法(HPLC)和质谱法(MS)分析四氢嘧啶类物质,细菌泌乳法制备四氢嘧啶类物质。【结果】从盐池土样中分离到一株以四氢嘧啶类物质为主要相容性溶质的中度嗜盐菌Y,鉴定为盐单胞菌(Halomonas sp.)Y。盐单胞菌Y能在NaCl质量浓度为10-250 g/L的培养基中生长,最适生长的NaCl浓度为100 g/L;HPLC-MS测试结果证明盐单胞菌Y可同时合成四氢嘧啶和羟基四氢嘧啶2种相容性溶质,在最适生长的盐浓度下其合成量分别达175.5 mg/g和47.9 mg/g;在NaCl质量浓度为0-30 g/L的低渗溶液中胞内四氢嘧啶类物质经5 min即可达到最大释放率,而细菌泌乳工艺中最适合诱导四氢嘧啶释放的低渗溶液为质量浓度为10 g/L的NaCl溶液;采用细菌泌乳工艺制备四氢嘧啶,经连续11轮的高渗/低渗冲击,四氢嘧啶总合成量为6.0 g/L,总释放量为5.7 g/L,平均释放率为64.5%,底物转化率为128.9 mg/g。【结论】盐单胞菌Y是一株较高产合成四氢嘧啶类的中度嗜盐菌,能够耐受反复的渗透压冲击,采用细菌泌乳工艺显著提高了四氢嘧啶的制备效率。     

极端耐盐放线菌白色普氏菌YIM 90005T四氢嘧啶及5-羟基四氢嘧啶合成相关基因的克隆

摘要：【目的】 为了研究耐盐放线菌对高盐环境的适应机理。【方法】 用HPLC定量检测了极端耐盐、丝状产孢放线菌——白色普氏菌（Prauserella alba） YIM 90005T在不同盐浓度下胞内相容性溶质的种类和含量。【结果】 结果发现,四氢嘧啶和5-羟基四氢嘧啶是其主要的相容性溶质。在培养基NaCl浓度为10%时,四氢嘧啶在胞内累积浓度最大,为18.77 μg/mg干菌体重。之后随NaCl浓度的升高,胞内的四氢嘧啶含量逐渐减少,而5-羟基四氢嘧啶的含量逐渐增加,在该菌耐受的最高NaCl浓度下（24% w/v）,胞内5-羟基四氢嘧啶含量达到最大值,为22.98 μg/mg干菌体重。设计兼并引物,利用染色体步移,克隆得到四氢嘧啶及5-羟基四氢嘧啶合成相关基因ectABCD。序列分析表明,ectABCD位于一个操纵子中。进一步对不同NaCl浓度培养条件下ectB,D的表达量进行定量分析,结果表明该基因簇表达量随着培养基中NaCl浓度的增加而增大。【结论】 研究结果证实5-羟基四氢嘧啶是P. alba YIM 90005T在极高盐浓度条件下起渗透调节及保护的相容性溶质。     

相容性溶质四氢嘧啶及其羟基化衍生物的研究进展

四氢嘧啶类化合物是嗜盐以及耐盐菌胞内合成的一类能够抵御外界高盐胁迫的相容性溶质,概述了四氢嘧啶及其衍生物的理化特征以及在嗜盐微生物中抵御外界高渗透压的作用机理,主要阐述了四氢嘧啶类相容性溶质的生物合成途径、膜运输机理、分泌释放机制、高密度发酵生产等方面在细胞、分子水平上的最新研究进展以及前景展望。并且综述了四氢嘧啶类在精细化工、生物医药及生物制造等行业的应用研究以及发展前景,探讨了未来的研究方向。     

古盐井中嗜盐菌的分离及四氢嘧啶的制备

[目的]分离鉴定古盐井中的嗜盐菌,确定相容性溶质,增加相容性溶质的合成。[方法]从盐井卤水中分离嗜盐菌,对菌株进行形态、生理生化和16S rRNA分析,用高效液相色谱法(HPLC)和质谱法(MS)确定相容性溶质,以谷氨酸钠为唯一碳氮源来制备四氢嘧啶。[结果]菌株S2为色盐杆菌属;相容性溶质为四氢嘧啶; 1. 5 mol/L Na Cl时四氢嘧啶达到最适合成浓度,为0. 168 3 mg/mL,单位质量合成量为238. 201 mg/g;以谷氨酸钠为唯一碳氮源时,相同体积发酵液中四氢嘧啶的总合成量与单位质量合成量均增加,四氢嘧啶合成量为0. 184 8 mg/mL,单位质量合成量为390. 389 mg/g。[结论]成功分离出了产四氢嘧啶的嗜盐菌,并且以谷氨酸钠为唯一碳氮源时四氢嘧啶合成量大大增加。     

中度嗜盐菌DTY1的鉴定及其耐盐机制的初步分析

菌株DTY1分离自山西省五寨县柠条种植区盐碱土壤,可在0~1·2mol/LNaCl的浓度培养基上生长,最适生长温度32℃,最适pH7~10。通过形态观察,生理生化测定与16SrDNA序列分析,将该菌株鉴定为嗜碱芽孢杆菌(Bacillusalcalophilus)。高压液相色谱分析,DTY1菌株在常规LB培养液中能够产生1·40mg/g四氢嘧啶,且在最适盐浓度条件下,盐浓度越高单位干重菌体所产生的四氢嘧啶含量越高。通过PCR介导的方法从DTY1的基因组文库中克隆到四氢嘧啶合成基因ectB。该基因长度为1284bp,编码427个氨基酸的肽链。此肽链与B.haloduransC-125(BAB04638)中二氨基丁酸氨基转移酶同源性达81%。ectB基因可能存在典型的σ70启动子,而且在启动子间有一段明显的23bp的回文序列。     

中度嗜盐菌相容性溶质机制的研究进展

生活在高盐环境中的中度嗜盐菌不仅能抗衡外界的高渗透压胁迫,而且还能迅速适应短时间内的渗透冲击。为适应该环境,中度嗜盐菌依赖于一种被称为相容性溶质的物质,以执行渗透保护功能。这类物质属于极性的、易溶的和低分子量的有机化合物,其中包括糖类、氨基酸类、甜菜碱类和四氢嘧啶类等。中度嗜盐菌主要采用相容性溶质机制来适应盐环境。在此,就中度嗜盐菌的盐适应机理、相容性溶质的种类和特点,以及其作用的分子机制进行了阐述和讨论。     

外界高渗环境对枯草芽孢杆菌胞内自由脯氨酸含量的影响

枯草芽孢杆菌(93151)在基本培养基中培养,可耐受高达8%NaCl浓度,而在10%NaCl条件下96h内未见生长。随胞外NaCl浓度的增加,其胞内自由脯氨酸的含量相应明显增加,在8%NaCl浓度下胞内脯氨酸含量可达2.944mg·g-1干细胞重,与无NaCl条件下相比,增加了1572%,而对照菌大肠杆菌仅可耐受4%NaCl浓度,并且在不同NaCl浓度下,胞内脯氨酸含量变化不明显。     

近江牡蛎共附生耐热真菌C051的鉴定、生理学特性及抗菌活性研究

为进一步开发利用耐热海洋真菌,以1株近江牡蛎共附生耐热真菌C051为出发菌株,对其进行系统鉴定、生理学特性及抗菌活性研究。采用形态学鉴定并结合18S rRNA序列分析,确定菌株C051为烟曲霉(Aspergillus fumigatus)。3种培养基比较,适合基础培养基为PDA;生长温度范围为15～50℃,最适生长温度45℃,具有明显的耐热真菌特性;生长pH范围3～9,最适生长pH 6;生长盐浓度0%～16%,最适生长盐浓度3.5%,具兼性海洋真菌的特点。其发酵产物对铜绿假单胞菌(Pseudomons aeruginosa)、金黄色葡萄球菌(Staphylococcus aureus)、交替假单胞菌属SL-1(Pseudoalteromonas sp.)、金黄杆菌属SL-4(Chryseobacterium sp.)均有良好的抑菌效果,最大抑菌圈直径达22.15 mm,为耐热海洋真菌的开发与研究提供参考。     

尖顶羊肚菌液体培养基质与条件的研究

通过对尖顶羊肚菌液体培养基质与条件的研究,明确其菌丝生长的最适pH值、最适温度、适宜光照条件、适宜葡萄糖和蛋白胨浓度、适宜培养基,以便应用于尖顶羊肚菌液体菌种的生产和工业发酵。结果表明:菌丝的最适生长温度为2 5℃;最适生长pH值为6 ;葡萄糖和蛋白胨最适浓度分别为2 0 0g/L和10g/L ;菌丝在黑暗环境下生长良好,光照对菌丝生长具有抑制作用;用胡萝卜酵母膏培养基振荡培养形成的菌丝球多,菌丝生长量大;菌丝球在不同培养基中生长,可引起培养液pH值的上升或者下降;菌丝球可利用培养基内的氨基酸,使氨基酸降解,在胡萝卜酵母膏培养基中振荡培养8d的菌液总氨基酸含量较原液减少了36 71% ,亮氨酸、异亮氨酸和甲硫氨酸含量的下降幅度最大     

甲胺磷降解菌的筛选及降解特性研究

从长期受有机磷农药污染的土壤中分离到1株能降解甲胺磷的菌株B15,经生理生化鉴定为巨大芽孢杆菌(Bacillus megaterium)。在甲胺磷无机盐培养基(甲胺磷浓度为0.5%)生长时,最适生长温度为28℃,最适pH为7.0,摇床培养(28℃190 r/min)48 h降解率达到83%。菌株在甲胺磷浓度为1%的无机盐培养基上能生长,但是在甲胺磷浓度为0.5%的无机盐培养基上生长最好,降解率最高。外加碳氮源对菌株的降解率有所提高,但是超过某一浓度降解率随着浓度的增加反而下降。     

Isolation and characterization of salt-sensitive mutants of the moderately halophilic bacterium Salinivibrio costicola subsp. yaniae

Salinivibrio costicola subsp. yaniae is a moderately halophilic bacterium which can grow over a wide range of salinity. In response to external osmotic stress (1-3 M NaCl), S. costicola subsp. yaniae can accumulate ectoine, glycine betaine, and glutamate as compatible solutes. We used suicide plasmids pSUP101 to introduce transposon Tn1732 into S. costicola subsp. yaniae via Escherichia coli SM10 mediated by conjugation. One Tn1732-induced mutant, MU1, which was very sensitive to the external salt concentration, was isolated. Mutant MU1 did not grow above 1.5 M NaCl and did not synthesize ectoine, but accumulated Ngamma-acetyldiaminobutyrate, an ectoine precursor, as confirmed by (1)H-NMR analysis. From these data, we concluded that ectoine performs a key role in osmotic adaptation towards high salinity environments in strain S. costicola subsp. yaniae.     

Interrelation between synthesis and uptake of ectoine for the growth of the halotolerant Brevibacterium species JCM 6894 at high osmolarity

The growth of a halotolerant Brevibacterium sp. JCM 6894 was examined in the presence of compatible solutes such as glycine betaine, ectoine (2-methyl-4-carboxy-3,4,5,6-tetrahydropyrimidine) and ectoine derivatives. The effect of competition between their uptake and synthesis in the cells was subjected to osmotic shift towards the higher salinity. Among each solute examined the supplement of ectoine or hydroxyectoine exhibited a remarkable stimulation on the growth of strain JCM 6894, regardless of the range of osmotic shifts, where the largest was 0-->2 M NaCl, the intermediate was 1-->2 M NaCl, and no shift was 2-->2 M NaCl. The growth rates of this strain were dependent on the amount of ectoine taken up, which was conspicuous for the largest osmotic shift and during the first few hours of incubation after transfer. The cells subjected to 1-->2 M NaCl and 2-->2 M NaCl transfers took up less ectoine and this resulted in lower growth rates than those of cells with the largest osmotic shift (0-->2 M NaCl). The role of other compatible solutes which accumulated is discussed in relation to growth stimulation of strain JCM 6894.     

Organic Osmolytes in Aerobic Bacteria from Mono Lake, an Alkaline, Moderately Hypersaline Environment

The identity and concentrations of intracellular organic solutes were determined by nuclear magnetic resonance spectroscopy for two strains of aerobic, gram-negative bacteria isolated from Mono Lake, Calif., an alkaline, moderately hypersaline lake. Ectoine (1,4,5,6-tetrahydro-2-methyl-4-pyrimidinecarboxylic acid) was the major endogenous solute in both organisms. Concentrations of ectoine varied with external NaCl levels in strain ML-D but not in strain ML-G, where the level was high but invariant from 1.5 to 3.0 M NaCl. Hydroxyectoine also occurred in strain ML-D, especially at elevated NaCl concentrations (2.5 and 3.0 M), but at levels lower than those of ectoine. Exogenous organic solutes that might occur in Mono Lake were examined for their effects on the de novo synthesis of ectoine. Dimethylsulfoniopropionate (DMSP) (0.1 or 1 mM) did not significantly lower ectoine levels in either isolate, and only strain ML-G showed any capacity for DMSP accumulation. With nitrogen limitation, however, DMSP (0.1 mM) substituted for ectoine in strain ML-G and became the main organic solute. Glycine betaine (GB) was more effective than DMSP in affecting ectoine levels, principally in strain ML-D. Strain ML-D accumulated GB to 50 or 67% of its organic solute pool at 2.5 M NaCl, at an external level of 0.1 or 1 mM GB, respectively. Strain ML-D also accumulated arsenobetaine. The methylated zwitterionic compounds, probably metabolic products of phytoplankton (DMSP and GB) or brine shrimps (arsenobetaine) in Mono Lake, may function as osmolytes for indigenous bacteria when present at high concentrations or under conditions of nitrogen limitation or salt stress.     

Accumulation and role of compatible solutes in fast-growing Salinivibrio costicola subsp. yaniae

The moderately halophilic bacterium Salinivibrio costicola subsp. yaniae showed an extremely fast growth rate. Optimal growth was observed in artificial seawater containing 1.4 mol/L NaCl and in MM63 media containing 0.6 mol/L NaCl. We analyzed a variety of compatible solutes that had accumulated in this strain grown in the media. The supplementation effect of the compatible solutes glycine betaine, glutamate, and ectoine to the growth of S. costicola subsp. yaniae was examined. Glycine betaine and glutamate had no supplementation effect on the fast growth rate. Growth of salt-sensitive mutants MU1 and MU2, both of which were defective in the ability to synthesize ectoine, was not observed in MM63 medium in the presence of more than 1.0 mol/L NaCl. From these data, we conclude that ectoine was the predominant compatible solute synthesized in this bacterium that effected an extremely fast growth rate.     

Contribution of chemical changes in membrane lipids to the osmoadaptation of the halophilic bacterium Chromohalobacter salexigens

The long-term response of the broad-salt growing halophile Chromohalobacter salexigens DSM 3043T to salt stress has been investigated with respect to adaptive changes in membrane lipid composition. This study included the wild-type and three salt-sensitive, ectoine-deficient strains: CHR62 (ectA::Tn1732, unable to grow above 0.75 M NaCl), CHR63 (ectC::Tn1732, unable to grow above 1.5 M NaCl), and CHR64, which was able to grow in minimal medium M63 up to 2.5 M NaCl, but its growth was slower than the wild-type strain at salinities above 1.5 M NaCl. This mutant accumulated ectoine and hydroxyectoine as major compatible solutes, but also the ectoine precursor, N-gamma-acetyldiaminobutyric acid, and was found to be affected in the ectoine synthase gene ectC. The main phospholipids of the wild-type strain were phosphatidylethanolamine, phosphatidylglycerol (PG), and cardiolipin (CL). Major fatty acids were detected as 16:0, 18:1, and 16:1, including significant amounts of cyc-19:0, and cyc-17:0. CL and cyclopropane fatty acids (CFA) levels were elevated when the wild-type strain was grown at high salinity (2.5 M NaCl). Membranes of the most salt-sensitive trains CHR62 and CHR63, but not of the less salt-sensitive strain CHR64, contained lower levels of CL. The proportion of cyc-19:0 in CHR64 was three-fold (at 2.0M NaCl) and 2.5-fold (at 2.5 M NaCl) lower than that of the wild type, suggesting that this mutant has a limited capacity to incorporate CFA into phospholipids at high salt. The addition of 1 mM ectoine to cultures of the wild-type strain increased the ratio PG/CL from 1.8 to 3.3 at 0.75 M NaCl, and from 1 to 6.5 at 2.5 M NaCl, and led to a slight decrease in CFA content. Addition of 1 mM ectoine to the mutants restored the steady-state levels of CL and CFA found in the wild-type strain supplemented with ectoine. These findings suggest that exogenous ectoine might attenuate the osmostress response involving changes in membrane lipids.     

Accumulation of the compatible solutes, glycine-betaine and ectoine, in osmotic stress adaptation and heat shock cross-protection in the biocontrol agent Pantoea agglomerans CPA-2

AIMS: The effect of modifying the water activity (a(w)) of Pantoea agglomerans growth medium with the ionic solute NaCl on water stress resistance, heat-shock survival and intracellular accumulation of the compatible solutes glycine-betaine and ectoine were determined. METHODS AND RESULTS: The bacterium was cultured in an unmodified liquid medium or that modified with NaCl to 0.98 and 0.97 a(w), and viability of cells evaluated on a 0.96 a(w)-modified solid media to check water stress tolerance. Cells grown under ionic stress had better water stress tolerance than control cells. These cells also had cross-protection to heat stress (30 min, 45 degrees C). The modified cells accumulated substantial amounts of the compatible solutes glycine-betaine and ectoine in contrast to the control cells, which contained little or none of these two compounds. CONCLUSIONS: Improvement in osmotic and thermal tolerance of cells of the biocontrol agent P. agglomerans by modifying growth media with the ionic solute NaCl was achieved. The compatible solutes glycine-betaine and ectoine play a critical role in environmental stress tolerance improvement. SIGNIFICANCE AND IMPACT OF THE STUDY: This approach provides a method for improving the physiological quality of inocula and could have implications for formulation and shelf-life of biocontrol agents.     

Whole genome sequencing of the halophilic Halomonas qaidamensis XH36, a novel species strain with high ectoine production

Here, we report the whole genome of a novel halophilic Halomonas species strain XH36 with high ectoine production potential. The genome was 3,818,310 bp in size with a GC content of 51.97%, and contained 3533 genes, 61 tRNAs and 18 rRNAs. The phylogenetic analysis using the 16s rRNA genes, the UBCGs and the TYGS database indicated that XH36 belongs to a novel Halomonas species, which we named as Halomonas qaidamensis. Osmoadaptation related genes including Na(+) and K(+) transport and compatible solute accumulation were both present in the XH36 genome, the latter of which mainly contained ectoine, 5-hydroxyectoine and betaine. HPLC validation studies showed that H. qaidamensis XH36 accumulated ectoine to cope with salt stress, and the content of ectoine could be as high as 315 mg/g CDW under 3 mol/l NaCl. Our results show that XH36 is a new promising industrial strain for ectoine production, and the genomic analysis will guide us to better understand its salt-induced osmoadaptation mechanisms, and provide theoretical references for future application research of ectoine.

     

Ectoine accumulation in Brevibacterium epidermis

As a halotolerant bacterial species, Brevibacterium epidermis DSM 20659 can grow at relatively high salinity, tolerating up to 2 M NaCl. It synthesizes ectoine and the intracellular content increases with the medium salinity, with a maximum of 0.14 g ectoine/g CDW at 1 M NaCl. Sugar-stressed cells do not synthesize ectoine. Ectoine synthesis is also affected by the presence of external osmolytes. Added betaine is taken up and completely replaced ectoine, while L-proline is only temporarily accumulated after which ectoine is synthesized. The strain can metabolize ectoine; L-glutamate is a better carbon source for ectoine synthesis than L-aspartate.