光合细菌产氢因子的研究进展

光合细菌在固氮的同时释放氢气。产氢与固氮是同步进行的。固氮酶与氢酶共同影响光合细菌的产氢活性,而外源生理条件又影响着固氮酶与氢酶的活性,其中有机碳阻抑吸氢酶表达,促进产氢;氨则抑制固氮活性而降低产氢量;氧气的存在使固氮酶与氢酶都失活,从而抑制放氢反应的进行。     

光合细菌光合产氢的研究进展

光合细菌 (Photosyntheticbacteria ,PSB)光合产氢的研究是国内外普遍关注的热点问题。就PSB光合产氢的机理、条件及光合细菌生态应用等方面进行综述 ,并着重论述了光合细菌产氢过程中两种主要的酶—固氮酶和氢酶以及影响酶活性的因素。     

光合细菌产氢研究进展

光合细菌能利用有机废水(废弃物)转化太阳能产生氢能,故应作为环保产业新能源开发的一个重要研究方向。       

固定化光合细菌利用有机物产氢的研究

应用固定化细胞技术包埋荚膜红假单胞菌(Rhodopseudomonas capsulata)菌株386．研究在光照下利用有机物产氢的特性。实验观察到,光照培养120小时,悬浮培养物的产氢量为68．2ml·比产氢速率为104．1ml H2/g(生物量)·h;用琼脂包埋后．其产氢能力得到改善,产氢量和比产氢速率分别达到128．4ml和l 9s．8mlH2/g·h。该菌株除可利用苹果酸外,还可利用葡萄糖、乳酸、丙酸等基质高效地产氢。基质浓度只有控制在适当水平时,才具有较高的基质转化产氢效率。此外．菌体生物量、菌龄、培养液pH、光照强度、光照／黑暗时间比以及温度对产氢过程均有不同程度的影响。     

光合细菌产氢条件的研究

从被有机物污染的土壤及水域中分离得到13株属于红螺菌科的光合细菌,对其在苹果酸、乳酸、葡萄糖、乙酸、丙酸及丁酸中的光致产氢现象进行了研究。最高产氢量为39.8ml·20ml菌液~(-1)·48h~(-1),产氢活性为7.8ml·g生物量~(-1)·h~(-1)”。底物对不同菌株的产氢量与产氢活性均具有影响,pH对产氢过程也有明显的作用,大于6000lx的光强度对提高产氢活性已无明显作用。固定化细胞在静态培养条件下也能提高产氢能力,但延长产氢时间的作用不明显。     

正交实验优选光合细菌混合菌群产氢的最佳条件

对光合细菌混合菌群产氢影响因子进行了实验研究。通过单因素实验和正交实验, 系统考察了碳源、氮源、碳源浓度、氮源浓度、初始pH值、光照方式、接种量等因素对产氢量的影响, 实验得出最佳工艺条件为: 采用3号菌群, 碳源为葡萄糖, 碳源浓度为3 g/L, 氮源为尿素, 氮源浓度为9 g/L, 接种量为10%, pH值为8.5, 光照方式为12 h光照-12 h黑暗交替光照, 培养温度为30°C。菌种、碳源、碳源浓度、氮源是影响产氢量的重要因素。     

光合细菌与产气肠杆菌协同产氢特性分析

对光合细菌(Rhodopseudomonas sp. DT)与产气肠杆菌(Enterobacter aerogenes)进行了发酵产氢试验, 考察了不同起始接种比例、培养温度及碳源条件下混合菌协同产氢特性。结果表明: 光合细菌与产气肠杆菌初始接种比例对协同产氢影响较大, 初始接种比例为1:1最有利于协同产氢, 产氢效率和产氢周期达到了3.1 mol H2/mol葡萄糖及81 h。进一步培养液pH动力学变化研究发现初始接种比例为1:1的混合菌培养液pH变化较小, 为pH 6~7, 利于混合菌协同产氢。28°     

不产氧光合细菌Rhodobacter sphaeroides产氢影响因子研究

对不产氧光合细菌球形红细菌Rhodobacter sphaeroides产氢的影响因子进行了初步研究。结果表明,处于不同生长期的球形红细菌接种后的产氢速率略有差异,稳定期的菌株的产氢能力相对较低。苹果酸钠、乳酸钠、丙酮酸钠和葡萄糖都是球形红细菌产氢的良好碳源,这表明球形红细菌具有利用食品工业等高浓度废水为底物产氢的可能性。以葡萄糖和谷氨酸钠为C源和N源产氢时,适宜的葡萄糖浓度在25~50mmol/L之间,谷氨酸钠浓度在2~10mmol/L之间。球形红细菌产氢的适宜pH值在7.0~8.0范围内,酸性环境明显不利于该菌的催化放氢,适宜的温度在30~35℃范围内。光照强度在5000~7000lx之间适合于产氢。球形红细菌的固氮酶活性和放氢活性之间呈正相关性。吸氢酶虽然可在无固氮酶和无放氢活性的状态下独立表达,但多数情况下仍受氢气浓度的调节。以氮气为氮源时,固氮酶活性和放氢活性较低,铵的浓度高于0.5mmol/L时,固氮酶活性完全受到抑制,进而抑制产氢。     

固定化光合细菌产氢过程的基质利用动力学

研究了固定化荚膜红假单胞菌386、红假单胞菌D两菌株产氢过程基质利用的动力学特性。基质利用与产氢过程以不同的速率进行．琼脂包埋固定化细胞的产氢能力高于海藻酸钙固定化细胞,但最大产氢活性的进程迟于后者。固定化D菌株利用葡萄糖的动力学遵循一级反应,其反应常数K值为1．2×10　2h-1。宏观动力学分析表明,利用基质的产氢过程属于反应控制,扩散传质过程不构成控速步骤。386和D两个菌株固定化细胞生物反应器连续产氢系统,在以乳酸作基质时．平均产氢量分别可达到0．659L／d和0．457L／d,容积(液相)产氢率接近1．OL／L·d。     

初始底物浓度对序批式培养光合细菌产氢动力学影响

实验研究了初始底物浓度对序批式培养光合细菌生长、降解及产氢过程的影响,根据最大比生长速率实验数据拟合得到其关于初始底物浓度影响的关联式,并在建立的修正Monod模型基础上建立了光合细菌比生长速率、基质比消耗速率和比产氢速率关于底物初始浓度影响的数学模型,模型预测值与实验结果在光合细菌生长期和稳定期内得到较好吻合,反映了光合细菌生长、降解和产氢过程中受底物初始浓度限制性和抑制性影响的基本规律。分析发现光合细菌生长、降解基质和产氢过程中最适底物浓度为50 mmol/L,初始底物浓度低于或高于该浓度时,光合细菌生长、降解及产氢过程都受到限制性或抑制性影响,且抑制性影响较限制性影响效果更明显;底物比消耗速率受初始底物浓度影响较小。     

光合菌生物制氢技术

简要分析了光合细菌产氢的主要影响因素,介绍了国内外光合细菌生物制氢技术的研究和应用现状,并对光合制氢技术的发展趋势和应用前景进行了评述。     

Enhanced hydrogen production by Rhodopseudomonas palustris CQK 01 with ultra-sonication pretreatment in batch culture

In the present study, the photo-hydrogen production performances by Rhodopseudomonas palustris CQK 01 growing from the inoculated cells with ultra-sonication pretreatment (R. palustris CQK 01-USP) were experimentally investigated in batch culture and compared with that without pretreatment (R. palustris CQK 01-NP). It was found that the ultra-sonication pretreatment modified membrane morphology and broke up part of the cells, resulting in improvement of membrane permeability and bacterial activities and hence, helping the improvement of hydrogen production. The hydrogen production rate, hydrogen yield and energy conversion efficiency with R. palustris CQK 01-USP were increased to be nearly 2 times higher than that with R. palustris CQK 01-NP. The parametric study showed that under the conditions of initial glucose concentration 50 mmol/l, inoculum size 12%, illumination wavelength 590 nm, the photobioreactor with R. palustris CQK 01-USP obtained the optimal hydrogen production rate 0.54 mmol/l/h, hydrogen yield 1.2 mol-H₂/mol-glucose and energy conversion efficiency 9.03%.     

光合菌群发酵玉米秸秆水解液产氢

以玉米秸秆水解液作为产氢底物,研究光合菌群产氢性能。考察了硫酸浓度、固液比、水解时间、水解温度等秸秆水解条件对产氢的影响,确定了最佳水解条件,并对不同脱毒方法进行了对比研究。结果表明,最佳的水解条件为硫酸浓度1%,固液比1:12,水解时间0.5 h,水解温度为110°C。采用Ca(OH)2脱毒方法的产氢效果要优于其他2种脱毒方法;NH4+在一定浓度范围内对该光合菌群产氢有促进作用。     

Photoproduction of hydrogen by photosynthetic bacteria from sewage and waste water

Numerous prokaryotes, belonging to physiologically and taxonomically different groups, are able to produce hydrogen. Some photosynthetic bacteria have the property of light-dependent production of hydrogen from organic substrates. We isolated several photosynthetic purple and green bacteria from enrichment cultures made from the water of a waste-water pond of a cool-drink refilling station. After testing them for their ability to use various organic compounds as carbon source, and sulphide, thiosulphate and organic compounds as electron donor, we selected the fastest-growing isolate, aRhodopseudomonas, for a study of its ability to produce molecular hydrogen in presence of light. Immobilized cells of this isolate produced significant amounts of hydrogen from both sewage and waste water     

Perspectives on cultivation strategies and photobioreactor designs for photo-fermentative hydrogen production

Photosynthetic bacteria have considerable biotechnological potential for biological hydrogen production due to higher substrate conversion efficiency and hydrogen yield. Phototrophic fermentation using photosynthetic bacteria has a major advantage of being able to further convert the byproducts originating from dark fermentation (e.g., volatile fatty acids) to hydrogen. Through the combination of dark and photo-fermentation processes, organic feedstock is fully converted into gaseous product (H₂) at the highest possible H₂ yield, with significant reduction of chemical oxygen demand (COD). The performance of photo-fermentation is highly dependent on the medium composition, culture conditions, and photobioreactor design. Therefore, this article provides a critical review of the effects of key factors affecting the photo-hydrogen production efficiency of photosynthetic bacteria, and also summarizes the strategies being applied in promoting the performance of photo-fermentation.     

光合细菌对小麦生长和光合功能的影响

【目的】探明光合细菌对小麦生长、产量及光合功能的影响。【方法】以尧麦16为材料,在不同生长时期施用光合细菌,研究光合细菌对小麦生长、产量及光合功能的影响。【结果】光合细菌培养液的不同成分可提高小麦旗叶SPAD值、光合速率及干物质积累。拔节期施用后,混合菌液对叶片SPAD含量促进作用最大,较不施用对照提高33.6%,小麦干物质积累较对照增加25.7%,单株籽粒重量增效为14.3%。单菌株实验处理中沼泽红假单胞菌促进作用最强,干物质积累和单株籽粒重量较培养基稀释液对照增效均为13.1%。不同施用时期的结果表明沼泽红假单胞菌对灌浆期和拔节期小麦促进效应最强,其中静息细胞可延长叶片功能期,使光合产物持续增加;无细胞培养液通过促进小麦营养生长,进而提高小麦产量。【结论】光合细菌可促进小麦生长,有效提高小麦生育过程中相关光合功能;施用时期应为小麦拔节期和灌浆期;光合细菌对小麦生长和产量促进作用是静息细胞和代谢活性物质综合作用的结果。     

Bacteriophytochromes in anoxygenic photosynthetic bacteria

Since the first discovery of a bacteriophytochrome in Rhodospirillum centenum, numerous bacteriophytochromes have been identified and characterized in other anoxygenic photosynthetic bacteria. This review is focused on the biochemical and biophysical properties of bacteriophytochromes with a special emphasis on their roles in the synthesis of the photosynthetic apparatus.     

The Rhodopseudomonas viridis photosynthetic membrane: arrangement in situ

The organization of photosynthetic membranes in the cytoplasm of the photosynthetic bacterium Rh. viridis has been examined by several techniques for electron microscopy. Thin sections of membrane stacks show that the regular lattice of membrane subunits reported in other studies can be observed in thin section. Tilting of sections in the electron microscope shows that the regular lattices of several membranes overlap in a way that suggests they are in register with each other. This observation can be confirmed by freeze-fracture images in which a regular arrangement of membrane lattices can be observed, each perfectly aligned.Analysis of the spacings of membrane pairs shows that the photosynthetic membranes of Rh. viridis are very closely apposed. The mean diameter of two membranes is 160A, and the average space between two such membranes is only 42A. When a recently developed atomic level model of Rh. viridis reaction center is superimposed against these spacings, each reaction center extends from the surface of its respective membrane far enough to make contact with an apposing membrane. The limited free space between membranes and regular alignment of lattices has a number of implications for how this membrane is organized to carry out the process of energy transfer.     

Variable planar particle arrangements in the photosynthetic membrane of Rhodopseudomonas viridis

The thylakoids of Rhodopseudomonas viridis have been studied by freeze-fracturing whole cells. Depending on growth conditions and treatment before freezing, three different types of particle arrangements in the photosynthetic membrane are reported: a random arrangement, an isometric (quadratic) lattice arrangement with a lattice constant of 12.5 ± 0.8 nm, and a hexagonal lattice arrangement with a lattice constant of 12.5 ± 0.8 nm.