波罗的海希瓦氏菌AI-2/LuxS对生物被膜和致腐的调控

【目的】波罗的海希瓦氏菌(Shewanella baltica)是冷藏海产鱼类的特定腐败菌。研究群体感应信号AI-2/Lux S对鱼源S.baltica生物被膜和致腐的调控作用。【方法】扩增SB11分离株的lux S基因,用自杀性质粒构建lux S基因缺失株,通过结晶紫染色、珠涡流法、显微镜观察和HPLC,比较分析野生株与缺失株△lux S在4°C和28°C下生物被膜形成、粘附能力、泳动性和致腐产物的差异。【结果】S.baltica SB11中扩增获得lux S基因,生物信息学分析显示Lux S蛋白由169个氨基酸构成,含有保守的His-Thr-Leu-Glu-His(HTLEH)模体和关键氨基酸位点,蛋白三维空间结构与其他细菌相似。与野生株相比,△lux S缺失株上清荧光信号散失,但不影响生长,生物被膜形成期和成熟期的含量显著低于野生株,在4°C培养96 h和28°C培养24 h被膜分别减少20.1%和27.9%。缺失株在不锈钢片的粘附能力明显减弱,其中在4°C培养72 h和28°C培养24 h后的粘附量比野生株分别减少6.48%和6.57%。荧光显微镜观察发现,野生株能快速粘附于玻璃片,聚集形成大量生物被膜,而△lux S仅形成平坦稀疏的被膜,粘附细菌降低,CLSM证实野生株和△lux S的成熟被膜厚度分别为68.95μm和36.44μm。并且,△lux S株在4°C和28°C下泳动性均显著强于野生株。然而,野生株和△lux S株三甲胺和腐胺积累无差异。【结论】鱼源S.baltica中Lux S蛋白保守,AI-2/Lux S参与被膜、粘附能力及泳动性等多种生物被膜形成相关的调控作用,然而不是该菌致腐能力的功能性群体感应信号。     

海藻希瓦氏菌(Shewanella alga)发酵培养基条件优化的研究

目的:优化海藻希瓦氏菌生产河豚毒素的发酵培养基。方法:通过测定菌体密度(用OD600表示)和菌体收获量,研究了部分初始条件及添加不同营养物质对海藻希瓦氏菌生长的影响,采用单因素试验和正交试验对发酵条件进行了优化。结果:最适发酵初始pH为7.5,最适摇瓶装液量为150mL。通过正交试验找出最大影响因素为葡萄糖供应,优化后的培养基最佳配方为:在2216E培养基中添加1.0%葡萄糖、2.5%酵母粉、1.0%磷酸高铁。结论:优化后的培养基培养供试菌,菌体收获量比在2216E培养基中培养增加了2.012g.L-1。     

中国希瓦氏菌D14^T的厌氧腐殖质呼吸

实验证明,希瓦氏菌新种(ShewanellacinicaD14T)在厌氧条件下可以利用多种有机酸盐和甲苯等环境有毒污染物作为电子供体,以腐殖质作为唯一末端电子受体进行厌氧呼吸(即醌呼吸)。电子在细胞膜呼吸链的传递过程中,偶联能量的产生来支持菌体的生长,1mmol/LAQDS可支持细胞增殖约60倍。电子供体的氧化和唯一电子受体腐殖质还原之间存在着动态的偶联过程,随着电子供体量的增加腐殖质还原的量也随之增加。典型呼吸链抑制剂诸如:抑制Fe-S中心的Cu2 ,甲基萘醌类似物标桩菌素,抑制甲基萘醌氧化型向还原型转化的双香豆素和细胞色素P450的专一抑制物甲吡酮等对腐殖质的还原有着极为显著的抑制作用,为进一步证明希瓦氏菌(Shewanellacinica)D14T可利用腐殖质进行厌氧呼吸提供了有力的佐证。而D14T在进行腐殖质呼吸的同时,对于甲苯,苯胺等环境有毒物质的有效降解则具有着重要的环境学意义。     

Characterisitics and Gene Cloning of Phospholipase D of the Psychrophile,Shewanella sp.

Phospholipase D, with a molecular mass of 64 kDa, was purified from the psychrophile, Shewanella sp. The enzyme showed maximal activity at pH 7.8 and 40 °C in the presence of the Ca²⁺-ion, and its activity at 10 °C was 6.5% of maximum. The enzyme exhibited high activity to the non-micelle form of phosphatidylcholine in an aqueous solution containing water miscible alcohols such as methanol, ethanol, iso-propanol, and n-propanol. Nucleotide sequencing of the enzyme gene yielded a deduced amino acid sequence, which showed 36.2% identity to that of Streptomyces chromofuscus phopsholipase D alone. The low sequence similarity to other phopsholipase D enzymes suggests that the purified enzyme might be a novel phospholipase D.     

Anaerobic respiration of Shewanella putrefaciens requires both chromosomal and plasmid-borne genes

Abstract Pleiotropic respiratory mutants, incapable of growth on any electron acceptor other than oxygen, were isolated from two strains of Shewanella putrefaciens (MR-1 and sp200). All anaerobic respiratory functions were restored by complementation of the mutants with specific cloned DNA fragments. Southern hybridization experiments revealed that the fragment that complements the MR-1 mutant was localized on the megaplasmids of both strains, while the fragment that complements the sp200 mutant was chromosomal. Neither of these fragments hybridized with the anaerobic regulatory genes of S. putrefaciens ( etrA ) or E. coli ( fnr ).     

The influence of chelating agents upon the dissimilatory reduction of Fe(III) by Shewanella putrefaciens

The ability of S. putrefaciens to reduce Fe(III) complexed by a variety of ligands has been investigated. All of the ligands tested caused the cation to be more susceptible to reduction by harvested whole cells than when uncomplexed, although some complexes were more readily reduced than others. Monitoring rates of reduction by a ferrozine assay for Fe(II) formation proved inadequate using Fe(III) ligands giving Fe(II) complexes of low kinetic lability (e.g. EDTA). A more suitable assay for Fe(III) reduction in the presence of such ligands proved to be the observation of associated cytochrome oxidation and re-reduction. Where possible, an assay for Fe(III) reduction based upon the disappearance of Fe(III) complex was also employed. Reduction of all Fe(III) complexes tested was totally inhibited by the presence of O₂, partially inhibited by HQNO and slower in the absence of a physiological electron donor. Upon cell fractionation, Fe(III) reductase activity was detected exclusively in the membranes. Using different physiological electron donors in assays on membranes, relative reduction rates of Fe(III) complexes complemented the data from whole cells. The differences in susceptibility to reduction of the various complexes are discussed, as is evidence for the respiratory nature of the reduction.     

Impedance spectroscopy as a tool for non‐intrusive detection of extracellular mediators in microbial fuel cells

Endogenously produced, diffusible redox mediators can act as electron shuttles for bacterial respiration. Accordingly, the mediators also serve a critical role in microbial fuel cells (MFCs), as they assist extracellular electron transfer from the bacteria to the anode serving as the intermediate electron sink. Electrochemical impedance spectroscopy (EIS) may be a valuable tool for evaluating the role of mediators in an operating MFC. EIS offers distinct advantages over some conventional analytical methods for the investigation of MFC systems because EIS can elucidate the electrochemical properties of various charge transfer processes in the bio‐energetic pathway. Preliminary investigations of Shewanella oneidensis DSP10‐based MFCs revealved that even low quantities of extracellular mediators significantly influence the impedance behavior of MFCs. EIS results also suggested that for the model MFC studied, electron transfer from the mediator to the anode may be up to 15 times faster than the electron transfer from bacteria to the mediator. When a simple carbonate membrane separated the anode and cathode chambers, the extracellular mediators were also detected at the cathode, indicating diffusion from the anode under open circuit conditions. The findings demonstrated that EIS can be used as a tool to indicate presence of extracellular redox mediators produced by microorganisms and their participation in extracellular electron shuttling. Biotechnol. Bioeng. 2009; 104: 882–891. © 2009 Wiley Periodicals, Inc.     

New violet 3,3′-bipyridyl pigment purified from deep-sea microorganism <Emphasis Type="Italic">Shewanella violacea</Emphasis> DSS12

We have purified a new violet pigment derived from Shewanella violacea DSS12 to determine its chemical structure. The pigment colored blue in tetrahydrofuran (THF) or chloroform and showed a broad absorption spectrum from 500 to 700 nm. X-ray diffraction analysis of single crystals showed that the chemical structure of this pigment was 5,5′-didodecylamino-4,4′-dihydroxy-3,3′-diazodiphenoquinone-(2,2′), containing the same chromophore as an indigoidine known as microbial blue pigment. The violet color of this pigment was due to hypsochromic shift (blue shift) caused by the side-by-side orientation of this pigment molecule, revealed by X-ray structural analyses of a single crystal. Electronic supplementary material Supplementary material is available in the online version of this article at and is accessible for authorized users.