细菌细胞壁生长调控机制研究进展

在细菌生长过程中,细胞壁起到维持细胞形状和完整性,抵抗内部膨胀压的作用。细胞壁的合成、分裂、再生、循环再利用等与细菌自身生长繁殖和应对环境压力息息相关。目前,细胞壁生长机理,细菌如何调控细胞壁生长及如何与其他细胞过程相协调的机制尚未研究清楚。细胞壁调控机制的解析对了解细菌细胞壁功能、确定药物的作用方式和发展新一代的治疗方法至关重要。对细菌调控细胞壁生长机制的国外研究进展进行了概述,重点阐述了支架蛋白、转录因子、非编码小RNA及蛋白相互作用调控细胞壁的合成、细胞分裂、压力响应的机制,总结了细胞壁调控机制在抗菌药物研发中的应用,并对未来的研究方向进行了展望。     

烫伤创面绿脓杆菌定植动态的实验研究

本文从细菌以多细胞生理活动观点出发,以认识定植稳定过程为目的。进行了实验大白鼠烫伤创面绿脓杆菌定植与抗定植动态观察。通过用铁浸染色法对细菌群体结构定量化研究,用糖包被负染法对群体结构内部结构观察,对粘附在组织表面细菌数量的测定,反映结构与粘附力的关系。进一步结合电镜观察及细菌生长状态的分析,证明了烫伤创面上绿脓杆菌群体结构的形成是细菌分裂繁殖所致。通过群体结构,糖包被,粘附力及生长状态的动态观察,表现出与定植的稳定程度呈平行关系,显示其重要性。联系抗定植力研究,表明定植与抗定植的一致性。最后分析了定植三个主要条件,和稳定性定植的三要素。     

影响多粘菌素B对绿脓杆菌杀菌效力的主要环境因素的研究

本文通过改变温度,水活度,气体条件和营养含量等影响绿脓杆菌生长的主要环境因素,测定多粘菌素B对绿脓杆菌的最小杀菌浓度(MBC)。结果表明环境因素导致或显著影响绿脓杆菌对抗生素的生态耐受性。实验表明多粘菌素B对绿脓杆菌的杀菌效力,除药物对细菌特有的药理学作用外,还取决于细菌的生长环境。结合冷休克率试验表明,环境影响细菌群体处于分裂状态的菌数。若分裂状态菌数下降表明生长速度减慢。提示了多粘菌素B对绿脓杆菌的效力指数,定量分析可以作为其综合效力作用的表现。以同步培养法确定在单个细胞周期中的抗生素敏感阶段。同时以冷休克率试验资料证明细菌处于分裂状态和幼龄期是其敏感阶段。初步阐述了生长速度缓慢与药物的生态耐受性密切相关。     

突变率计算中细菌群体生长不同步系数的修正

遗传和变异是生物学最根本的问题之一, 而突变率估算有助于比较不同基因、不同生物个体、以及不同生长环境下突变率的差异。细菌因其生长繁殖快速和群体庞大而成为突变率估算的最方便的模式生物。突变率的定义为：每个细胞每一世代发生突变的概率。通常表示为。其中, 为突变数, 为细菌分裂的世代数。国内外的微生物学及遗传学教科书和专著中, 在计算细菌突变率时, 有些引入了ln2作为群体中细菌分裂不同步的校正系数, 有些则没有。那么, 在突变率估算中, 究竟是否应该对非同步生长群体进行校正？如果需要校正, 仅仅引入ln2作为     

用遗传算法进行重组大肠杆菌发酵动力学的分析

重组大肠杆菌在诱导表达人表皮生长因子的过程促使细菌的生长受到抑制,一部分重组菌丧失了分裂能力,但仍保持着一定的代谢活力,分离成为存活但不能培养的细菌,根据大肠杆菌在表达外源蛋白过程中细胞生理状态的不同将细菌分为三类,提出一个描述诱导表达过程中重组大肠杆菌分离、生长的动力学模型．应用遗传算法对不同底物浓度的细胞生长、分离和产物合成的动力学参数进行了有效地估计,避免了传统算法可能陷于局部最优的问题,模型计算结果与实验结果吻合良好．分离模型在初始糖浓为5-20g/L的范围内可以较好地描述发酵过程中细胞生长、分离和目标产物表达的过程并具有一定的预测能力．     

细菌生物膜研究技术

细菌生物膜是细菌生长过程中为适应生存环境而在固体表面上生长的一种与游走态细胞相对应的存在形式。只要条件允许,绝大多数细菌都可以形成生物膜。一旦形成了生物膜细菌就具有极强的耐药性,在医疗、食品、工业、军事等诸多领域给人类社会带来了严重的危害,造成巨大的经济损失。因此,细菌生物膜已成为全球关注的重大难题,也是目前科学界研究的前沿和热点。本文结合细菌生物膜研究技术的最新进展,重点介绍了几种常用生物膜发生装置及检测量化技术,并对其原理及优缺点进行了讨论。     

线粒体动力学在细菌感染性疾病中的研究进展

线粒体是一种高度动态的细胞器,其分裂与融合的协调循环被称为“线粒体动力学”。线粒体动力学对于细胞代谢调控、免疫调控、氧化还原稳态及钙稳态维持等生物反应至关重要。细菌侵袭细胞后,通过调控宿主线粒体动力学以促进感染和自身增殖。现对线粒体动力学在细菌感染性疾病中的机制、作用及功能的研究进展作一概述。     

二巯基乙醇对大鼠骨肉瘤细胞增殖的诱导作用

目的:观察二巯基乙醇(2-ME)对大鼠骨肉瘤细胞增殖的诱导作用.方法:将含10%小牛血清的RPMI1640完全培养基分装成六瓶,每瓶100ml,一瓶不加2-ME作为对照组Ⅰ,其余五瓶分别加入不同剂量2-ME作为实验组,再设一个含10%胎牛血清的完全培养基一瓶作对照组Ⅱ,分别在96孔板中培养大鼠骨肉瘤UMR106细胞,24h、48h和72h后,观察细胞生长状态,采用MTT法检测细胞增殖情况.结果:对照组Ⅰ生长缓慢,对照组Ⅱ生长状态良好,分裂增殖相较多.实验组随着2-ME浓度的增加,细胞生长的速度逐渐增快.其中0.3μl组生长速度适中,细胞生长状态与对照组Ⅱ相似.结论:二巯基乙醇有明显诱导大鼠骨肉瘤细胞增殖的作用.     

复苏延迟体(regrowth-delay body)作为一种标示休眠细菌的可逆亚细胞结构

大约在1895年前后,人们就注意到一个有趣的现象,那就是在实验室批量培养细菌(如伤寒杆菌)的时候,每当细胞进入快速生长分裂状态之前,总是存在一个无任何生长迹象的潜伏期(latent period)或延迟期(lag phase)。而且这种复苏过程的延迟时间的长短与细胞经历上一次培养过程的时间有关:培养时间越长(细胞越老),复苏的延迟期越长;培养时间越短(细胞越年轻),复苏的延迟期越短[1]。究其原因,当时的观点是经历了长时间培养的细菌细胞受到了损伤,所以再次生长时需恢复一段时间[1]。     

VicRK(YycFG)双组分调节系统

细菌双组分调节系统,或称之为双组分信号转导系统,是细菌感应外界多变环境,维持自身存活和生长繁衍的重要感应系统.在这些调节系统中,最早发现于枯草芽孢杆菌的VicRK(YycFG)系统因与细胞存活密切相关而倍受关注.该系统存在于少数低G+C含量的革兰氏阳性菌中,包括金黄色葡萄球菌和肺炎链球菌等致病菌,高度保守.许多证据显示,VicRK(YycFG)具有调控细胞壁合成与代谢、胞膜完整、细胞分裂、脂类代谢、多糖合成与被膜形成以及细菌毒力等多种功能,参与细胞的生长、分裂与感染.该系统异常可导致细菌生活力严重下降,甚至死亡,因而成为防治该类病原菌的重要靶标.     

Biochemical characterization of recombinant methionine aminopeptidases (MAPs) from Mycobacterium tuberculosis H37Rv

The aim of this study was to investigate the effect of dihydrotanshinone I (DI) in inhibiting the growth of human cervical cancer cells both in vitro and in vivo, and molecular targets in HeLa cells when treated by DI or irradiation with or without being combined. In this study, MTT, clonogenic assay, flow cytometry, and Western blotting were performed to assess the effect of treatment on cells. After treatment with IR, DI, and DI + IR, the apoptosis was 5.8, 13.3 and 22.5% (P < 0.05 vs. control), respectively. Clonogenic assay revealed that the survival of irradiated HeLa cell was significantly reduced by DI treatment. Combination treatment with IR and DI could down-regulate HPV E6 gene expression. Effect of DI on up-regulation of p21 expression and down-regulation of cyclin B1, p34(cdc2) expression in irradiated HeLa cell was concomitant with cell cycle arrest in G(2) phase. The significant increase in caspase-3 activity was also observed in the combination treatment. When HeLa cells were grown as xenografts in nude mice, combination treatment with DI and IR induced a significant decrease in tumor growth, and without signs of general or organ toxicity. These data suggest DI should be tested as the radiosensitizer in vitro and in vivo, which has potential in the treatment of human cervical cancer.     

Cell cycle,cell size and mitochondrial activity of hybridoma cells during batch cultivation

Cell cycle, cell size and rhodamine 123 fluorescence in cell populations of two batch cultures were analysed and quantified with a fluorescence-activated cell sorter (FACS). Two cultures derived from either exponential or stationary phase innocula were investigated in order to demonstrate the dependency of the subsequent cell growth on innoculum condition. The results demonstrated that the level of activity of cells in the innoculum culture could have a significant effect on cellular activity during the initial phase of the inoculated culture, as it advances through its growth cycle. Positive correlation was found between the cell size and mitochondrial activity (as measured by rhodamine 123 uptake) with S and G₂ fractions as the cell progressed through the cell cycle. The enumeration of the fractions of cell cycle phases has helped in prediction of the changes in cell numbers following perturbation of the culture condition.     

Regulation of breakdown and synthesis of L-glutamate decarboxylase in Clostridium perfringens.

L-Glutamate decarboxylase (GAD) activity of Clostridium perfringens (ATCC 8009) cells grown in various culture conditions was investigated. Remarkable variations of GAD level occur during the growth cycle in thioglycollate broth. These changes are affected by the pH of the culture medium. Addition of alkali to the culture media results in decrease of cell GAD activity, whereas increase of enzyme level occurs only in cells growing in unbuffered media. The results indicate that the mechanism regulating the GAD levels is sensitive to the changes of pH (or buffering substances) rather than to the steady pH values. Neither repression by glucose nor induction by L-glutamate was observed. Moreover, high concentrations of the free amino acid substrate in the culture media considerably decrease cell GAD activity, owing to the buffering effect of the amino acid. The molecular mechanism supporting the variations of GAD activity during the growth cycle of the cells were investigated and tentatively related to the structural and functional properties of the pure enzyme. It is shown that the drop of GAD activity during the lag phase is due to protein breakdown. Evidence is presented suggesting a control of protein degradation by its quaternary structure. Data are also reported supporting de novo synthesis of GAD during the late logarithmic phase of cell growth. Finally, the possible role of GAD as part of the pH regulation system of C. perfringens cells is discussed in relation both to physiologic conditions of the bacterial cell and to the molecular mechanisms regulating the GAD activity in vivo.     

Variation in the growth medium during the culture cycle of Tetrahymena: with special reference to ammonia (NH3), ammonium (NH4+), and pH1

The ciliate Tetrahymena pyriformis was grown in a peptone medium without added glucose. The interrelationship between increasing cell density and pH of the growth medium was studied from mid-log to the stationary phase, i.e. from 50,000 to 1,000,000 cells/ml, by continuous registration of the pH of the growth medium. The present findings correlate with the known physiological, biochemical, and structural changes occurring in Tetrahymena as it passes through the culture cycle. The ammonia production of the cells and the buffer capacity of the growth medium were determined throughout the growth cycle. The results revealed that the ammonia excreted by the cells can explain the increase in pH of the medium from 6.8 to about 8.3 normally seen during the culture cycle. Moreover, neither the increased pH nor the raised level of ammonia were found to be the responsible factor for cessation of cell proliferation in the stationary growth phase although these factors may affect cell proliferation in concentrations well beyond the range found in normal cultures.     

Comparative responses of ‘Gala’ and ‘Fuji’ apple trees to deficit irrigation: Placement versus volume effects

Aims

Climate, soil water potential (SWP), leaf relative water content (RWC), stomatal conductance (g_s), fruit and shoot growth, and carbohydrate levels were monitored during the 2008 and 2009 growing seasons to study the responses of ‘Gala’ and ‘Fuji’ apple trees to irrigation placement or volume.

Methods

Three irrigation treatments were imposed, conventional irrigation (CI), partial root-zone drying (PRD, 50% of CI water on one side of the root-zone, which was alternated periodically), and continuous deficit irrigation (DI, 50% of CI water on both sides of the root-zone).

Results

After each irrigation season, DI generated twice the soil water deficit (SWD_int) than PRD (average of dry and wet sides) and a greater integrated leaf water deficit (LWD_int) than PRD and CI. Both PRD and DI reduced g_s by 9 and 15% over the irrigation period. RWC of both PRD and DI was directly related to SWP and inversely related (non-linear) to vapor pressure deficit (VPD), whereas it was unrelated to g_s. Considering individual sampling days, g_s of ‘Gala’ leaves was inversely related to VPD mainly until early August (fruit at cell expansion phase and high VPD), while it was directly related to VPD in September (no fruit and low VPD). On the contrary, g_s of ‘Fuji’ leaves was inversely related to VPD from late August until mid October (low VPD and fruit at cell expansion phase). Fruit growth was not affected by irrigation, whereas shoot and trunk growth was reduced by DI. Irrigation induced sporadic and inconsistent changes in carbohydrate contents or partitioning, with a general tendency of DI leaves to degrade and PRD to accumulate sorbitol and sucrose in dry periods.

Conclusions

‘Gala’ trees exhibited a more conservative water use than ‘Fuji’ trees due primarily to different timing of fruit growth and crop loads. Different levels of SWD_int, rather than changes in stomatal control and carbohydrate partitioning, seem to play a major role in determining a better water status in PRD than in DI trees.     

Global transcriptional responses of Pseudomonas aeruginosa to phage PRR1 infection

The infectious cycles of viruses are known to cause dramatic changes to host cell function. The development of microarray technology has provided means to monitor host cell responses to viral infection at the level of global changes in mRNA levels. We have applied this methodology to investigate gene expression changes caused by a small, icosahedral, single-stranded-RNA phage, PRR1 (a member of the Leviviridae family), on its host, Pseudomonas aeruginosa, at different times during its growth cycle. Viral infection in this system resulted in changes in expression levels of <4% of P. aeruginosa genes. Interestingly, the number of genes affected by viral infection was significantly lower than the number of genes affected by changes in growth conditions during the experiment. Compared with a similar study that focused on the complex, double-stranded-DNA bacterial virus PRD1, it was evident that there were no universal responses to viral infection. However, in both cases, translation was affected in infected cells.     

盘基网柄菌(Dictyostelium discoideum)突变型细胞allC细胞周期异常的研究

细胞计数和细胞倍增时间计算的结果表明allC细胞的倍增时间为2.36h,仅为KAx-3细胞倍增时间的1/3。为了探究allC细胞倍增时间大幅度缩短、细胞周期异常的原因我们采用流式细胞术测定两种细胞的细胞周期,并结合实时荧光定量PCR技术测定cycB1和cdk1基因的相对表达量的比值。结果表明,16h突变型allC细胞处于G2期的数目(1.51%)显著少于KAx-3细胞(16.61%)。allC细胞和KAx-3细胞的细胞周期素B1(cyclinB1)cycB1基因相对表达量分别是2.5和0.25,两者相差10倍。这些数据表明,两种类型细胞中G2期的差异十分明显,cyclinB1的相对表达量也存在显著差异。提示cyclinB1的过表达可能在一定程度上影响allC细胞的细胞周期正常的调控机制,与突变细胞的G2期异常有一定关系。     

Cell cycle control during the contact mediated growth inhibition of rat C6 glioma cells

Two separate control processes govern the cell cycle of rat C6 glioma cells. In subconfluent cultures growth inhibition is caused by cell contact interactions and the cell cycle is regulated primarily by changes in the duration of S phase. During advanced multilayering, medium depletion becomes the primary mechanism of growth inhibition and causes a pronounced G1 accumulation. Contact modulation acts by altering the velocity with which cells progress through the cell cycle, while depletion causes cycle arrest.     

Foreign gene expression (beta-galactosidase) during the cell cycle phases in recombinant CHO cells

Recombinant mammalian cultures for heterologous gene expression typically involve cells traversing the cell cycle. Studies were conducted to characterize rates of accumulation of intracellular foreign protein in single cells during the cell cycle of Chinese hamster ovary (CHO) cells transfected with an expression vector containing the gene for dihydrofolate reductase (dhfr) and the lacZ gene for bacterial beta-galactosidase (a nonsecreated protein). The lacZ gene was under the control of the constitutive cytomegalovirus promoter. These normally attachment-grown cells were adapted to suspension culture in 10(-7) M methotrexate, and a dual-laser flow cytometer was used to simultaneously determine the DNA and foreign protein (beta-galactosidase) content of single living cells. Expression of beta-galactosidase as a function of cell cycle phase was evaluated for cells in the exponential growth phase, early plateau phase, and inhibited traverse of the cell cycle during exponential growth. The results showed that the beta-galactosidase production rate is higher in the S phase than that in the G1 or G2/M phases. Also, when cell cycle progression was stopped at the S phase by addition of aphidicolin, beta-galactosidase content in single cells was higher than that in exponential phase or plateau phase cells and increased with increasing culture time. Although the cells did not continue to divide after aphidicolin addition, the production of beta-galactosidase per unit volume of culture was very similar to that in normal exponential growth. (c) 1993 John Wiley & Sons, Inc.     

Division Cycle of Myxococcus xanthus III. Kinetics of Cell Growth and Protein Synthesis

The kinetics of cell growth and protein synthesis during the division cycle of Myxococcus xanthus was determined. The distribution of cell size for both septated and nonseptated bacteria was obtained by direct measurement of the lengths of 8,000 cells. The Collins-Richmond equation was modified to consider bacterial growth in two phases: growth and division. From the derived equation, the growth rate of individual cells was computed as a function of size. Nondividing cells (growth phase) comprised 91% of the population and took up 87% of the time of the division cycle. The absolute and specific growth rates of nondividing cells were observed to increase continually throughout the growth phase; the growth rate of dividing cells could not be determined accurately by this technique because of changes in the geometry of cells between the time of septation and physical separation. The rate of protein synthesis during the division cycle was measured by pulselabeling an exponential-phase culture with radio-active valine or arginine and then preparing the cells for quantitative autoradiography. By measuring the size of individual cells as well as the number of grains, the rate of protein synthesis as a function of cell size was obtained. Nondividing cells showed an increase in both the absolute and specific rates of protein synthesis throughout the growth phase; the specific rate of protein synthesis for dividing cells was low when compared to growthphase cells. Cell growth and protein synthesis are compared to the previously reported kinetics of deoxyribonucleic acid and ribonucleic acid synthesis during the division cycle.