细菌Enterobacter dissolvens的电解刺激效应研究

以葡萄糖为惟一碳源,研究了细菌Enterobacter dissolvens在直流电条件下的生长和代谢过程.结果,在直流电刺激过程中,反应体系中发生水解反应.当屏蔽阴极电极时,阳极产生的氧气使细胞生长曲线和葡萄糖代谢速率急剧下降,菌液葡萄糖的降解率和脱氢酶活性分别为对照参比的0.45倍和0.06倍,细胞浓度明显的下降;而屏蔽阳极电极时,阴极产生的氢气通过改变环境而使得细胞生长曲线和葡萄糖代谢急速上升,菌液葡萄糖的降解率和脱氢酶活性分别为对照参比的3倍和4.5倍,细胞浓度呈现明显的增长.分析原因可能是电极反应导致菌液的物化性质改变所致.     

溶解肠杆菌的交流电电解刺激过程

以葡萄糖为惟一碳源,研究了溶解肠杆菌(Enterobacter dissolvens)在外加电场交流电的刺激下细胞的生长和代谢的过程.研究表明,在低电流10 mA刺激下,交流电刺激下的细菌没有明显的刺激效应;当采用100 mA的电流通电24 h,交流电刺激下的细菌出现了明显的刺激效应,当通电12 h后,菌液葡萄糖的降解率和脱氢酶活性分别为对照参比的1.4倍和2.17倍,细胞浓度呈现明显的增长.分析原因可能是由于电极产物中没有过氧化氢的产生.     

中国仓鼠卵巢细胞的悬浮适应及代谢特征

目的：通过悬浮适应,使中国仓鼠卵巢细胞（CHO细胞）获得悬浮生长的特性,并可在悬浮培养条件下较快地生长。方法：将CHO细胞以3×10^5／mL接种于100mL的三角瓶内,培养时加入1％小牛血清、1g/LPIuronic F-68、25μg／mL硫酸葡聚糖,培养体积35mL,摇床转速90r／min,每24h离心换液,当细胞增殖为2×10^6／mL时传代。结果：经过悬浮适应,细胞的平均比生长速率由适应最初的0．27／d提高为适应后的0．48／d,最大总细胞密度由适应初期的2．5×10^6／mL提高为适应后的6．3×10^6／mL,目的蛋白活性也由适应前的2781U／mL提高为适应后的8878U／mL,适应后细胞的葡萄糖平均比消耗率为1．42μmol／（10^6细胞·d）,低于适应前的2．16μmol／（10^6细胞·d）。结论：贴壁生长的CHO细胞经过悬浮适应,不仅可以在悬浮培养条件下快速生长,而且细胞对葡萄糖的利用率也得到提高。     

大肠杆菌W 3110(pEC901)的αA干扰素生产

通过大肠杆菌Ｗ３１１０（ｐＥＣ９０１）和宿主菌Ｗ３１１０的连续培养,分别得到它们的最大比生长速率、饱和常数、维持系数和生长得率系数。两生长动力学参数的差异表明由于质粒ｐＥＣ９０１的存在,明显使大肠杆菌的生长速率降低及维持代谢的消耗增大,Ｗ３１１０（ｐＥＣ９０１）质粒稳定性和ａＡ干扰素的表达均随比生长速率的增大而增大。在补料分批培养中,通过葡萄糖的流加维持Ｗ３１１０（ｐＷＣ９０１）较高的比生长速率     

恒pH葡萄糖流加方法培养重组大肠杆菌生产人肿瘤坏死因子-α及其动力学研究

研究了一种新型的流加方法──恒pH流加葡萄糖法,用于培养重组大肠杆菌生产人肿瘤坏死因子-α。流加后培养液中菌体OD(600)达到9．0,是在LB培养基培养的15倍,而α-肿瘤坏死因子的比活保持（1．05±0．11）×105u/mg,并建立了菌体生长的动力学方程。     

滇产植物乌墨中胰岛素增敏活性成分

从乌墨（Syzygium cumini）根的甲醇提取物中分离鉴定8个已知化合物,并对其进行了经高糖、高胰岛素处理后胰岛素抵抗L6肌管细胞糖摄取活性的筛选。初步研究结果表明,其中7个化合物在有无胰岛素刺激下均能明显促进葡萄糖的利用。在无胰岛素刺激状态下,浓度为10μgml^-1时,无羁萜（1）的葡萄糖消耗量比抵抗细胞增加了17．35％;在有胰岛素刺激状态下,浓度为0．1μgml^-1,5,7,3’,4’,5＇-五羟基黄酮（8）葡萄糖消耗量比抵抗细胞增加了51．11％。     

伞形科两种植物幼苗生长对光照强度的可塑性响应

将明党参（Changium smyrnioides Wolff）和峨参（Anthriscus sylvestris Hoffm．）幼苗置于按全光照百分率为100％（S100）、65％（S65）和25％（S25）的人工控制光环境下处理。结果表明,光照强度显著影响明党参和峨参幼苗的生长：明党参在S6,生长最好,株高、冠幅、叶长、叶宽、地上地下生物量等均达到最大值,且S65的明党参生物量是S100的2倍、S25的3倍左右;而峨参地上部生长随着光照强度的减弱而增强,S25生长最好,但地下部生长则在S65生长最好,表现出与明党参同样的响应规律。明党参在不同光照强度下生长速率差异显著,S65显著高于其余两个处理;峨参虽然也在S65生长速率最大,但在不同光照强度间无差异。明党参生长速率明显小于峨参,总生物量约为峨参的1／3—1／8,相对于峨参而言明党参是一个在幼苗阶段生长缓慢的物种。     

碳源对粉核油球藻生长和脂肪酸组成特性的影响

研究了不同碳源类型（CO2、NaHCO3和葡萄糖）及其浓度对粉核油球藻（Pinguiococcus pyrenoidosus CCMP 2078）生长及脂肪酸组成的影响。结果表明：（1）培养液中适量添加碳源促进了粉核油球藻的生长,三种碳源的适宜添加浓度分别是0.5% CO2,5mmol/L NaHCO3和20g/L葡萄糖,对数生长末期的细胞密度分别是对照的3.10倍、1.47倍和2.78倍;（2）除了低浓度葡萄糖外,其他碳源类型和浓度均降低了TPUFA和EPA占总脂肪酸的比例,提高了TSFA的比例,胞内EPA和TSFA含量均下降;（3）低浓度碳源提高了TSFA和EPA产量。通入0.5% CO2培养的EPA和TSFA产量分别是对照的2.30倍和2.69倍,5mmol/L NaHCO3培养的TSFA产量是对照的1.85倍,5g/L和10g/L葡萄糖培养的EPA和TSFA产量最高分别可达对照的2.11倍和1.58倍。因此,通入低浓度CO2最有利于粉核油球藻的生长以及EPA和饱和脂肪酸的生产,EPA和饱和脂肪酸含量的提高主要是通过生物量的增大来实现的。     

真养产碱杆菌二级连续培养系统中稀释率对聚β—羟基丁酸合成的影响

在研究真养产碱杆菌ＷＳＨ３一级连续培养动力学的基础上,采用二级连续培养系统对不同稀释率下聚β羟基丁酸的生产进行了研究。结果表明：在一级连续培养系统中,当稀释率为０２１ｈ－１时,细胞干重最大值达２７１ｇ／Ｌ;二级培养系统中,稀释率为０１４ｈ－１时细胞干重最大值为４７６ｇ／Ｌ;在稀释率为０１２ｈ－１时,ＰＨＢ的生产强度达到最大值为２５０ｇ／（Ｌ·ｈ）,但胞内ＰＨＢ含量仅为４７６％;在稀释率为００７５ｈ－１时,产物对基质的转化率达到最大值为０３８ｇ／ｇ,此时ＰＨＢ的生产强度达２１４ｇ／（Ｌ·ｈ）和胞内ＰＨＢ含量±７２１％;随着细胞比生长速率的增长,细胞中ＰＨＢ含量和单位菌体合成ＰＨＢ的量不断下降。     

产葡萄糖异构酶工程菌工业发酵条件模拟研究*

高效表达葡萄糖异构酶的大肠杆菌工程菌Ｋ３８／ｐＧＰＩ－２,ｐＴＫＤ－ＧＩ菌株,在玉米浆培养基中能高效合成葡萄糖异构酶,观察了细菌生长的细胞浓度（ＯＤ）、ｐＨ和酶产生的动态变化。玉米浆培养基成本低、制备工艺简单,在５０Ｌ发酵罐中酶活力为１４３ｕ／ｍＬ,比在ＬＢ培养基中高约１０倍。用超声波破碎细胞液作酶源吸附于大孔阴离子交换树脂制成固定化葡萄糖异构酶、其酶活力达到１０２００ｕ／ｇ（干）。     

外加电场刺激对菲降解菌的影响

以菲为主要C源,吐温80作为增溶剂,研究细菌Enterobacter dissolvens在直流电和交流电条件下的生长和代谢过程。实验结果表明:当施加10 mA直流电时,通电8 h后,菌液中细胞的菲降解率较对照增长1.6倍,细胞生长亦有所加快;而施加交流电时,细菌生长和菲降解率均低于直流电刺激。     

Glucose transport by a mutant of Streptococcus mutans unable to accumulate sugars via the phosphoenolpyruvate phosphotransferase system.

Streptococcus mutans transports glucose via the phosphoenolpyruvate (PEP)-dependent sugar phosphotransferase system (PTS). Earlier studies indicated that an alternate glucose transport system functions in this organism under conditions of high growth rates, low pH, or excess glucose. To identify this system, S. mutans BM71 was transformed with integration vector pDC-5 to generate a mutant, DC10, defective in the general PTS protein enzyme I (EI). This mutant expressed a defective EI that had been truncated by approximately 150 amino acids at the carboxyl terminus as revealed by Western blot (immunoblot) analysis with anti-EI antibody and Southern hybridizations with a fragment of the wild-type EI gene as a probe. Phosphotransfer assays utilizing 32P-PEP indicated that DC10 was incapable of phosphorylating HPr and EIIAMan, indicating a nonfunctional PTS. This was confirmed by the fact that DC10 was able to ferment glucose but not a variety of other PTS substrates and phosphorylated glucose with ATP and not PEP. Kinetic assays indicated that the non-PTS system exhibited an apparent Ks of 125 microM for glucose and a Vmax of 0.87 nmol mg (dry weight) of cells-1 min-1. Sugar competition experiments with DC10 indicated that the non-PTS transport system had high specificity for glucose since glucose transport was not significantly by a 100-fold molar excess of several competing sugar substrates, including 2-deoxyglucose and alpha-methylglucoside. These results demonstrate that S. mutans possesses a glucose transport system that can function independently of the PEP PTS.     

Regulation of sugar transport via the multiple sugar metabolism operon of Streptococcus mutans by the phosphoenolpyruvate phosphotransferase system.

In this report, we provide evidence that the transport of sugars in Streptococcus mutans via the multiple sugar metabolism system is regulated by the phosphoenolpyruvate phosphotransferase system. A ptsI-defective mutant (DC10), when grown on the multiple sugar metabolism system substrate raffinose, exhibited reduced growth, transport, and glycolytic activity with raffinose relative to the parent strain BM71. Inhibition of [3H]raffinose uptake was also observed in both BM71 and DC10 with increasing concentrations of glucose and the glucose analogs alpha-methyl glucoside and 2-deoxyglucose.     

Degradation of 1,2-dichloroethane by Ancylobacter aquaticus and other facultative methylotrophs.

Cultures of the newly isolated bacterial strains AD20, AD25, and AD27, identified as strains of Ancylobacter aquaticus, were capable of growth on 1,2-dichloroethane (DCE) as the sole carbon and energy source. These strains, as well as two other new DCE utilizers, were facultative methylotrophs and were also able to grow on 2-chloroethanol, chloroacetate, and 2-chloropropionate. In all strains tested, DCE was degraded by initial hydrolytic dehalogenation to 2-chloroethanol, followed by oxidation by a phenazine methosulfate-dependent alcohol dehydrogenase and an NAD-dependent aldehyde dehydrogenase. The resulting chloroacetic acid was converted to glycolate by chloroacetate dehalogenase. The alcohol dehydrogenase was induced during growth on methanol or DCE in strain AD20, but no activity was found during growth on glucose. However, in strain AD25 the enzyme was synthesized to a higher level during growth on glucose than on methanol, and it reached levels of around 2 U/mg of protein in late-exponential-phase cultures growing on glucose. The haloalkane dehalogenase was constitutively produced in all strains tested, but strain AD25 synthesized the enzyme at a level of 30 to 40% of the total cellular protein, which is much higher than that found in other DCE degraders. The nucleotide sequences of the haloalkane dehalogenase (dhlA) genes of strains AD20 and AD25 were the same as the sequence of dhlA from Xanthobacter autotrophicus GJ10 and GJ11. Hybridization experiments showed that the dhlA genes of six different DCE utilizers were all located on an 8.3-kb EcoRI restriction fragment, indicating that the organisms may have obtained the dhlA gene by horizontal gene transmission.     

Degradation of 1,2-dichloroethane by Ancylobacter aquaticus and other facultative methylotrophs.

Cultures of the newly isolated bacterial strains AD20, AD25, and AD27, identified as strains of Ancylobacter aquaticus, were capable of growth on 1,2-dichloroethane (DCE) as the sole carbon and energy source. These strains, as well as two other new DCE utilizers, were facultative methylotrophs and were also able to grow on 2-chloroethanol, chloroacetate, and 2-chloropropionate. In all strains tested, DCE was degraded by initial hydrolytic dehalogenation to 2-chloroethanol, followed by oxidation by a phenazine methosulfate-dependent alcohol dehydrogenase and an NAD-dependent aldehyde dehydrogenase. The resulting chloroacetic acid was converted to glycolate by chloroacetate dehalogenase. The alcohol dehydrogenase was induced during growth on methanol or DCE in strain AD20, but no activity was found during growth on glucose. However, in strain AD25 the enzyme was synthesized to a higher level during growth on glucose than on methanol, and it reached levels of around 2 U/mg of protein in late-exponential-phase cultures growing on glucose. The haloalkane dehalogenase was constitutively produced in all strains tested, but strain AD25 synthesized the enzyme at a level of 30 to 40% of the total cellular protein, which is much higher than that found in other DCE degraders. The nucleotide sequences of the haloalkane dehalogenase (dhlA) genes of strains AD20 and AD25 were the same as the sequence of dhlA from Xanthobacter autotrophicus GJ10 and GJ11. Hybridization experiments showed that the dhlA genes of six different DCE utilizers were all located on an 8.3-kb EcoRI restriction fragment, indicating that the organisms may have obtained the dhlA gene by horizontal gene transmission.     

Transplantation of insulin-secreting cells differentiated from human adipose tissue-derived stem cells into type 2 diabetes mice

Currently, there are limited ways to preserve or recover insulin secretory capacity in human pancreas. We evaluated the efficacy of cell therapy using insulin-secreting cells differentiated from human eyelid adipose tissue-derived stem cells (hEAs) into type 2 diabetes mice. After differentiating hEAs into insulin-secreting cells (hEA-ISCs) in vitro, cells were transplanted into a type 2 diabetes mouse model. Serum levels of glucose, insulin and c-peptide were measured, and changes of metabolism and inflammation were assessed in mice that received undifferentiated hEAs (UDC group), differentiated hEA-ISCs (DC group), or sham operation (sham group). Human gene expression and immunohistochemical analysis were done. DC group mice showed improved glucose level, and survival up to 60 days compared to those of UDC and sham group. Significantly increased levels of human insulin and c-peptide were detected in sera of DC mice. RT-PCR and immunohistochemical analysis showed human gene expression and the presence of human cells in kidneys of DC mice. When compared to sham mice, DC mice exhibited lower levels of IL-6, triglyceride and free fatty acids as the control mice. Transplantation of hEA-ISCs lowered blood glucose level in type 2 diabetes mice by increasing circulating insulin level, and ameliorating metabolic parameters including IL-6.     

The sourdough microflora. Interactions between lactic acid bacteria and yeasts: metabolism of carbohydrates

Interactions betweenLactobacillus brevis subsp.lindneri CB1,L. plantarum DC400,Saccharomyces cerevisiae 141 andS.exiguus M14 from sourdoughs were studied in a co-culture model system using a synthetic medium. The lack of competition for maltose whenS.exiguus M14 was present in co-culture with each of the lactic acid bacteria (LAB) enhanced the bacterial cell yield and lactic and acetic acid production.L.brevis subsp.lindneri CB1 resting cells hydrolysed maltose and accumulated glucose in the medium, allowing the growth of maltose negative yeast.S.cerevisiae 141 competed greatly with each of the LAB for glucose and only withL.plantarum DC400 for fructose, causing a decrease in the bacterial cell number and in acid production. As a result of the glucose and fructose availability after the invertase activity of both yeasts,L.plantarum DC400 grew optimally in the presence of sucrose as a carbon source. All of the interactions indicated were confirmed by studying the behaviour of the co-cultures in wheat flour hydrolysate.     

Glucose dehydrogenase of a rhizobacterial strain of <Emphasis Type="Italic">Enterobacter asburiae</Emphasis> involved in mineral phosphate solubilization shares properties and sequence homology with other members of enterobacteriaceae

Glucose dehydrogenase (GDH) of Gram-negative bacteria is a membrane bound enzyme catalyzing the oxidation of glucose to gluconic acid and is involved in the solubilization of insoluble mineral phosphate complexes. A 2.4 kb glucose dehydrogenase gene (gcd) of Enterobacter asburiae sharing extensive homology to the gcd of other enterobacteriaceae members was cloned in a PCR-based directional genome walking approach and the expression confirmed in Escherichia coli YU423 on both MacConkey glucose agar and hydroxyapatite (HAP) containing media. Mineral phosphate solubilization by the cloned E. asburiae gcd was confirmed by the release of significant amount of phosphate in HAP containing liquid medium. gcd was over expressed in E. coli AT15 (gcd::cm) and the purified recombinant protein had a high affinity to glucose, and oxidized galactose and maltose with lower affinities. The enzyme was highly sensitive to heat and EDTA, and belonged to Type I, similar to GDH of E. coli.     

Effects of chronic coffee consumption on glucose kinetics in the conscious rat

Epidemiological studies indicate that regular coffee consumption reduces the risk of developing type 2 diabetes. Despite these findings, the biological mechanisms by which coffee consumption exerts these effects are unknown. The aim of this study was twofold: to develop a rat model that would further delineate the effects of regular coffee consumption on glucose kinetics, and to determine whether coffee, with or without caffeine, alters the actions of insulin on glucose kinetics in vivo. Male Sprague-Dawley rats were fed a high-fat diet for 4 weeks in combination with one of the following: (i) drinking water as placebo (PL), (ii) decaffeinated coffee (2 g/100 mL) (DC), or (iii) alkaloid caffeine (20 mg/100 mL) added to decaffeinated coffee (2 g/100 mL) (CAF). Catheters were chronically implanted in a carotid artery and jugular vein for sampling and infusions, respectively. Recovered animals (5 days postoperative) were fasted for 5 h before hyperinsulinemic-euglycemic clamps (2 mU x kg(-1) x min(-1)). Glucose was clamped at 6 mmol/L and isotopes (2-deoxy-[(14)C]glucose and [3-(3)H]glucose) were administered to obtain indices of whole-body and tissue-specific glucose kinetics. Glucose infusion rates and measures of whole-body metabolic clearance were greater in DC than in PL or CAF, indicating increased whole-body insulin sensitivity. As the only difference between DC and CAF was the addition of alkaloid caffeine, it can be concluded that caffeine antagonizes the beneficial effects of DC. Given these findings, decaffeinated coffee may represent a nutritional means of combating insulin resistance.