不同培养基中氧化亚铁硫杆菌生长及沉淀研究

为减缓氧化亚铁硫杆菌在9K培养基中培养时产生的沉淀,通过改变9K液体培养基的组成成分,研究了培养基成分的改变对细菌生长特性的影响及沉淀产生情况,并利用X射线衍射仪对沉淀进行了物相鉴定。结果表明,最佳培养基组成为(NH4)2HPO43.00g,KCl 0.10g,MgSO4.7H2O 0.50g,FeSO4.7H2O 44.3g,蒸馏水1 000ml,pH 2.0。在该培养基中,氧化亚铁硫杆菌不仅能保持其较高的氧化活性(其Fe2 氧化速率最高为0.3376 g/L.h-1),而且生长过程中沉淀出现的时间最迟,产生的沉淀量最少,且沉淀为非晶型物质。     

大规模茶叶细胞悬浮培养茶氨酸合成工艺优化研究

以婺源绿茶为材料进行茶叶愈伤组织悬浮培养,采用正交实验设计进行了大规模茶叶细胞悬浮培养合成茶氨酸工艺条件优化研究。结果显示,NH4+/NO-30.0/60.0mmol/L、K+100.0mmol/L、Mg++3.0mmol/L、H2PO-43.0mmol/L、蔗糖30.0g/L、水解酪蛋白2.0g/L条件下,茶叶细胞生长量(速率)和茶氨酸积累量均达到最高值;提高培养基中蔗糖和水解酪蛋白浓度可延长细胞对数生长期和稳定生长期,从而有利于茶氨酸积累;H2PO-4浓度主要影响细胞生长速率和茶氨酸积累速率的同步性,低H2PO4-浓度环境中茶氨酸积累速率峰值滞后于细胞增长速率峰值,高H2PO4-浓度环境中早于细胞生长速率峰值出现时间;K+和Mg++对细胞生长的影响不明显,但影响茶氨酸合成酶活性,维持适量的K+和Mg++有利于茶氨酸积累。先加入一定量盐酸乙胺再每天进行少量补充,茶氨酸合成量比一次性加入的效果要好。从生产效率考虑,培养周期以19～22d为宜。     

L-色氨酸基因工程菌发酵培养基配方优化研究

[目的]对L-色氨酸基因工程菌液态发酵的培养基进行优化。[方法]通过P-B试验,筛选出对基础发酵培养基的发酵液中L-色氨酸浓度影响显著的因素,进一步通过最陡爬坡试验、B-B试验对影响显著的因素进行优化。在此基础上,确定最佳的发酵培养基配方。[结果]酵母粉、Fe SO4·7H2O、KH2PO4对发酵液中L-色氨酸浓度的影响显著;最佳培养基配方为:Glucose 25.0 g/L,酵母粉4.5 g/L,(NH4)2SO49.0 g/L,Mg SO44.5 g/L,柠檬酸钠2.0 g/L,Fe SO4·7H2O 96.1 m g/L,KH2PO41.2 g/L。[结论]根据此配方进行验证实验,发酵液中L-色氨酸浓度可达2.25 g/L。     

环氧树脂固定化L-谷氨酸氧化酶

通过环氧树脂作为载体对经(NH4)2SO4盐析处理后的L-谷氨酸氧化酶(LGOX)进行固定化,优化固定化工艺条件,并利用固定化LGOX转化产α-酮戊二酸(α-KG)。结果表明:饱和度45%的(NH4)2SO4为最佳盐析浓度;当选用环氧树脂ES-105作为固定化载体、树脂加量为20 m L酶液(14 U/m L)加入3.5 g载体、固定化K3PO4缓冲液浓度为0.2 mol/L(p H 7.0)、固定化温度25℃、固定化时间24 h时,固定化LGOX酶活力最高,其酶活回收率为85.9%,比酶活55.7 U/g。利用该固定化酶转化L-谷氨酸产α-KG,当谷氨酸钠质量浓度为100 g/L,反应20 h,产物收率达98.2%。固定化酶重复使用14批次后,产物收率仍有90%以上;重复使用20批,收率有83.2%。因此,该固定化酶具有具良好的操作稳定性。     

谷氨酸棒状杆菌发酵生产L-瓜氨酸及发酵条件优化

以代谢控制发酵理论为指导,重点对C.glutamicum 366菌株进行摇瓶发酵条件的优化。应用响应面法优化发酵培养基的配比,优化后的发酵培养基:葡萄糖63.33 g/L、精氨酸196.96 mg/L、(NH4)2SO445.79 g/L、生物素35.72μg/L、K2HPO4·3H2O 1.0 g/L、KH2PO41.0 g/L、Mg SO4·7H2O、0.25 g/L、Mn SO4·H2O 0.02 g/L、Fe SO4·7H2O 0.02g/L、Zn Cl21 mg/L、Cu SO40.2 mg/L、VB1200μg/L、Ca CO330 g/L。摇瓶发酵培养条件:温度30℃、摇床转速200r/min、初始p H 7.0。在此发酵条件下,菌株进行摇瓶发酵72 h,产L-瓜氨酸14.96 g/L,相比优化之前提高了75.8%。     

基因工程菌Pichia pastoris高密度培养条件研究

基因工程菌pichiapastoris最佳种子培养基为添加4mL/LPTMl的BMGY培养基;全合成高密度摇瓶培养基是甘油4%,(NH4)2SO410g/L,CaSO40.93g/L,K2SO418.2g/L,MgSO4@7H2O14.9g/L,0.1mol/L磷酸缓冲液(pH=6.0)配制,培养26h后细胞密度OD600可达到65。经SDS-PAGE电泳图谱分析,甲醇诱导培养72h结果12h有重组人血清白蛋白表达,24h达到最大。此全合成摇瓶培养基与批补料发酵培养基相类似,有利于指导发酵罐上发酵培养。     

氧化亚铁硫杆菌固定化技术研究

在生物脱硫过程中 ,以H - 2软性填料作为氧化亚铁硫杆菌 (Thiobacillusferrooxidans)的固定化载体 ,构建了固定床生化反应器。考察了不同稀释率固定下床生化反应器氧化Fe2 + 的情况 ,在通气量为 330L/h ,稀释率为 0 6h-1条件下 ,Fe2 + 最大氧化速率达 7 6 7g[Fe2 + ]/L·h。该反应器连续运行 10 0d,固定化细胞稳定性良好     

金属离子对粪产碱杆菌C16的脱氮和亚硝酸盐积累的影响

【目的】研究不同金属离子对异养氨氧化细菌C16的生长和脱氮性能影响,探讨适于C16生长和脱氮的金属离子及其浓度。【方法】实验选用Mg2+、Mn2+、Fe2+、Cu2+、Zn2+5种金属离子,对C16的生长﹑脱氮性能﹑亚硝酸盐氮积累以及相关酶活性进行研究。【结果】Mg2+明显促进C16的生长和NH4+-N氧化速率;较高浓度Mn2+使得C16无法生长;原培养基中缺少Fe2+会抑制C16的生长和NH4+-N氧化速率;在原培养基中加入0.1 mmol/L的Cu2+对C16的生长和脱氮具有一定的促进作用,Cu2+使得培养基中基本无NO2--N和NH2OH的积累;不同浓度的Zn2+对C16的生长和氨氮去除有抑制作用。酶活实验结果显示,0.1 mmol/L Mg2+促进了羟胺氧化还原酶(HAO)的活性;0.1 mmol/L Cu2+促进了硝酸盐还原酶(Nar)和亚硝酸盐还原酶(Nir)的活性。【结论】Mg2+是C16生长和脱氮过程中的一种重要金属离子;加入Cu2+可避免过量亚硝酸盐积累。     

NH4+浓度对黄色短杆菌XV0505发酵生产L-缬氨酸的影响

以L-缬氨酸(L-Val)生产菌黄色短杆菌XV0505为供试菌株,以(NH4)2SO4为唯一添加N源,考察不同NH 4+浓度对发酵过程中菌体干质量、L-Val产量和葡萄糖消耗速率以及菌体内代谢流量的影响。研究表明:NH 4+浓度过高或不足都会影响发酵水平,降低L-Val的产量。合适的初始NH4+浓度为225 mmol/L,产酸期NH4+维持浓度为35 mmol/L时,有利菌体产酸。在此NH4+浓度下,在30 L发酵罐发酵60 h,发酵液中菌体生物量和L-Val质量浓度分别可达22.35和59.12 g/L。     

组成型表达粪产碱杆菌青霉素G酰化酶重组大肠杆菌发酵条件研究

目的:对重组大肠杆菌组成型表达粪产碱杆菌青霉素G酰化酶(AfPGA)进行了发酵条件研究。方法:在摇瓶和5L发酵罐中研究了(NH4)2SO4和葡萄糖浓度对质粒的分离稳定性及青霉素G酰化酶表达的影响。结果:该工程菌质粒具有分离不稳定性,培养基中无(NH4)2SO4时发酵过程中pH和糊精水解生成葡萄糖的浓度变化较小,细胞前期(0h-12h)的生长速率降低,质粒分离稳定性和青霉素G酰化酶的表达水平提高。发酵过程中维持低葡萄糖水平可以限制细胞的生长速率,提高质粒稳定性和促进青霉素G酰化酶的合成。采用混合碳源发酵,发酵培养基含糊精2g/L,12h后以1g/L.h恒速流加葡萄糖至35h,控制流加过程葡萄糖浓度0.1g/L左右,平均比生长速率为0.06h-1,发酵结束时质粒稳定性为86%,青霉素G酰化酶的表达水平达23 000U/L。结论:重组大肠杆菌组成型表达青霉素G酰化酶的研究对工业生产有一定指导意义。     

铜蓝精矿的生物浸出

采用两种嗜酸硫杆菌(嗜酸氧化亚铁硫杆菌和喜温硫杆菌)对铜蓝进行生物浸出,实验在有或没有4 g/L硫酸亚铁pH 2．0、150转/分、35℃的三角瓶中进行。实验结果表明:用两种菌混合浸出的铜几乎等于嗜酸氧化亚铁硫杆菌单独浸出的铜;另外,亚铁的加入能提高铜的浸出。     

PVA-Ca(NO3)2法包埋固定氧化亚铁硫杆菌研究

首次报道了把聚乙烯醇(PVA)、海藻酸钠混合水溶胶和氧化亚铁硫杆菌混合后滴入1%~5%(W/V)的Ca(NO3)2溶液中凝固成型,并把成型后的颗粒置-20℃条件下冷冻1d,从而形成固定化颗粒,把该颗粒在摇瓶中进行分批培养,对Fe2 最大氧化速率可达2.45g/(L.h)。而且整个固定化操作简单,颗粒不粘连、强度高、稳定性好,可以同时消除PVA-H3BO3法中PVA颗粒的粘连膨胀和H3BO3对微生物的毒性,具有很好的应用价值。     

Numerical modeling of ferrous-ion oxidation rate in Acidithiobacillus ferrooxidans ATCC 23270: optimization of culture conditions through statistically designed experiments

Statistically designed experimental strategy has been performed in order to evaluate and optimize nutritional and environmental parameters that affect ferrous ion oxidation rate in Acidithiobacillus ferrooxidans ATCC 23270. Plackett-Burman design was carried out to evaluate efficiently the biological significance of 10 culture conditions influencing ferrous-ion oxidation rate of A. ferrooxidans grown for 5 days in shake-flask batch mode on the newly modified 9-K media. Among ten fermentation factors examined, the most significant variables influencing ferrous-ion oxidation rate were statistically elucidated to be pH and calcium nitrate as positive contributors, whereas trace metals solution and potassium chloride were the most significant negative contributors. The optimal levels of the most significant three nutritional factors were further predicted from a polynomial model created from the data obtained from three level factorial design, a Box-Behnken design. Predicted optimal ferrous-ion oxidation rate Q(Fe2+) was recorded to be 0.148 (g Fe2+/l/hr). On verifying the predicted value, an experiment was performed under optimal predicted conditions and showed an actual experimental Q(Fe2+) of 0.152 g/l/hr, which was 2.7% over the predicted value. Our optimized medium formula gave overall five folds increase in ferrous-ion oxidation rates over the previously published data of standard 9-K medium on batch culture of A. ferrooxidans ATCC 23270 with higher mu(max) (hr(-1)) of 0.177 which was achieved within 75 h incubation in shake-flask culture.     

氧化亚铁硫杆菌分离复壮及固定化的研究

用稀释涂布平板法从已退化的氧化亚铁硫杆菌（Thiobacillus ferrooxidans）菌液中分离出氧化活性较高、生命力强的氧化亚铁硫杆菌T1。以H2软性填料作为氧化亚铁硫杆菌的固定化载体,构建了固定床生物反应器。考察了固定床生物反应器氧化Fe2+的情况：Fe2+最大氧化速率达7.67g/(L·h)。并对固定床生物反应器运行过程中在载体表面形成的沉淀物进行了研究,通过X衍射证明此沉淀物为黄钾铁矾［Kfe3(SO4)2(OH)6］。     

An investigation of biooxidation ability of Acidithiobacillus ferrooxidans using NMR relaxation measurement

NMR relaxation measurements can provide a simple means for understanding biological activity of cells in solution with known composition. It has the advantage that it is an in situ, non-intrusive technique, and the acquisition is fast. The iron oxidation ability of Acidithiobacillus ferrooxidans was investigated using NMR relaxation measurements. The transversal relaxation is characterized by a time constant, T?, which is sensitive to the chemical environment. Fe3? ion has more significant T? shortening than Fe2? ion. In the presence of A. ferrooxidans in solutions containing Fe2? ion, T? shortening was found with increasing time as the bacteria oxidize Fe2? to Fe3? ions. In the optimal growth medium, the bacteria concentration increased 80 times and high iron oxidation rate was found. In 10 mM K?SO? medium, however, bacteria concentration remained almost unchanged and the iron oxidation rate was significantly lower.     

Development of an optimal medium for continuous ferrous iron oxidation by immobilized Acidothiobacillus ferrooxidans cells

This study was aimed at developing an immobilized bioreactor system in which long-term continuous ferrous iron oxidation can be realized with no formation of jarosite, which causes clogging of support pores and reactor lines. For this purpose, a medium with no jarosite formation was developed first by selecting optimal nitrogen and phosphate sources and their concentrations. Then with the developed medium containing ammonium phosphate instead of ammonium sulfate and potassium phosphate, repeated batch and continuous operations of ferrous iron oxidation by Acidothiobacillus ferrooxidans cells immobilized in a depth filter were successfully performed for an extended period of time. For about 510 h of operation including 450 h of continuous operation at dilution rates of 0.1, 0.2, and 0.3 h(-)(1), no formation of jarosite and thus no clogging of the reactor system were observed. The maximum ferrous iron oxidation rate was as high as 2.6 g/(L.h) at a dilution rate of 0.3 h(-)(1).     

Bacterial oxidation of ferrous iron at low temperatures

This study comprises the first report of ferrous iron oxidation by psychrotolerant, acidophilic iron-oxidizing bacteria capable of growing at 5 degrees C. Samples of mine drainage-impacted surface soils and sediments from the Norilsk mining region (Taimyr, Siberia) and Kristineberg (Skellefte district, Sweden) were inoculated into acidic ferrous sulfate media and incubated at 5 degrees C. Iron oxidation was preceded by an approximately 3-month lag period that was reduced in subsequent cultures. Three enrichment cultures were chosen for further work and one culture designated as isolate SS3 was purified by colony isolation from a Norilsk enrichment culture for determining the kinetics of iron oxidation. The 16S rRNA based phylogeny of SS3 and two other psychrotolerant cultures, SS5 from Norilsk and SK5 from Northern Sweden, was determined. Comparative analysis of amplified 16S rRNA gene sequences showed that the psychrotolerant cultures aligned within Acidithiobacillus ferrooxidans. The rate constant of iron oxidation by growing cultures of SS3 was in the range of 0.0162-0.0104 h(-1) depending on the initial pH. The oxidation kinetics followed an exponential pattern, consistent with a first order rate expression. Parallel iron oxidation by a mesophilic reference culture of Acidithiobacillus ferrooxidans was extremely slow and linear. Precipitates harvested from the 5 degrees C culture were identified by X-ray diffraction as mixtures of schwertmannite (ideal formula Fe(8)O(8)(OH)(6)SO(4)) and jarosite (KFe(3)(SO(4))(2)(OH)(6)). Jarosite was much more dominant in precipitates produced at 30 degrees C.     

Biological oxidation of metallic copper by Acidithiobacillus ferrooxidans

This is a report on the kinetic aspects and the analytical study of the bioproducts of the oxidation of zero-valence copper by immobilized Acidithiobacillus ferrooxidans. Two different mechanisms of oxidation were considered: direct and indirect. A custom-built bioreactor was used to grow A. ferrooxidans in an iron-free media, which was required for the study of the direct mechanism. X-ray microdiffraction analysis of the copper after biooxidation in the sulfate-free medium revealed the presence of the copper sulfate, piypite, K(2)Cu(2)O(SO(4))(2), which indicates biooxidation of Cu metal has occurred. It was shown that the direct oxidation exists, but it is relatively slow, as compared to the indirect mechanism.     

紫外线和60Co辐照诱变选育高效嗜酸氧化亚铁硫杆菌

依次利用紫外线和60Co-γ射线辐照诱变的方法对嗜酸氧化亚铁硫杆菌进行诱变,选育高效嗜酸氧化亚铁硫杆菌菌株.结果表明,紫外诱变可以有效提高嗜酸氧化亚铁硫杆菌的Fe2+氧化速率,最佳紫外线诱变时间为240 s.诱变后菌株的Fe2+氧化速率从0.273 g/L/h提高到了0.312 g/L/h.继续利用60Co-γ射线进行...     

High-rate ferric sulfate generation by a Leptospirillum ferriphilum-dominated biofilm and the role of jarosite in biomass retention in a fluidized-bed reactor

The aims of this work were to develop a high-rate fluidized-bed bioprocess for ferric sulfate production, to characterize biomass retention, and to determine the phylogeny of the enrichment culture. After 7 months of continuous enrichment and air aeration at 37 degrees C, the iron oxidation rate of 8.2 g Fe(2+) L(-1)h(-1) (4.5.10(-12) g Fe(2+) cell(-1) h(-1)) was obtained at a hydraulic retention time (HRT) of 0.6 h. However, oxygen supply became the rate-limiting factor. With gas mixture (99.5% O(2)/0.5% CO(2) (vol/vol)) aeration and HRT of 0.2 h, the iron oxidation rate was 26.4 g Fe(2+) L(-1)h(-1) (1.0.10(-11) g Fe(2+) cell(-1) h(-1)). Leptospirillum sp. was predominant in the mesophilic fluidized-bed reactor (FBR) enrichment culture as determined by fluorescent in situ hybridization, while Acidithiobacillus ferrooxidans was not detected. Denaturing gradient gel electrophoresis (DGGE) of the amplified partial 16S rDNA showed only three bands, indicating a simple microbial community. DGGE fragment excision and sequencing showed that the populations were related to L. ferriphilum (100% similarity in sequence) and possibly to the genus Ferroplasma (96% similarity to F. acidiphilum). Jarosite precipitates accumulated on the top of the activated carbon biomass carrier material, increasing the rate of iron oxidation. The activated carbon carrier material, jarosite precipitates, and reactor liquid contained 59% (or 3.71.10(9) cells g(-1)), 31% (or 3.12.10(10) cells g(-1)) and 10% (or 1.24.10(8) cells mL(-1)) of the total FBR microbes, respectively, demonstrating that the jarosite precipitates played an important role in the FBR biomass retention.