模拟微重力条件下几种植物的过氧化物酶同工酶谱分析

对模拟微重力条件下的人参果、马铃薯和草莓处理后进行了过氧化物酶同工酶谱分析实验。结果表明 ,在模拟微重力条件下过氧化物同工酶的活性明显增强     

模拟微重力对拟南芥幼苗的影响

对正常条件和模拟微重力条件下拟南芥幼苗的生长状况进行了研究,发现拟南芥幼苗的生长发育、生理生化特性、酶活性等均发生一系列的变化.并利用qRT-PCR技术深入研究了经模拟微重力处理的幼苗过氧化物酶的基因表达量的变化.这些结果为植物在受控生态生保系统中的生长提供了试验支持.     

模拟微重力诱导PC12细胞衰老的初步探讨

目的：构建模拟微重力条件下PC12细胞的培养体系,探讨模拟微重力对PC12细胞衰老的影响。方法：用Cytodex-3型微载体作为PC12细胞的贴附载体,旋转细胞培养系统所提供10-2g的微重力环境进行模拟微重力条件下的细胞培养。在倒置显微镜下观察PC12细胞的生长情况;用扫描电镜观察PC12细胞超微结构的变化;衰老相关β半乳糖苷酶（SA-β-gal）特异性染色对衰老的PC12细胞进行评估。结果：光镜下模拟微重力培养的PC12细胞表现出类衰老细胞的形态,扫描电子显微镜下观察发现其微绒毛增多。SA-β-gal染色的结果显示在模拟微重力的作用下,PC12细胞SA-β-gal的活性升高。结论：模拟微重力可以引起PC12细胞衰老样的形态变化,以及SA-β-gal的活性升高。     

模拟微重力诱导PC12 细胞衰老的初步探讨

目的:构建模拟微重力条件下PC12细胞的培养体系,探讨模拟微重力对PC12细胞衰老的影响。方法:用Cytodex-3型微载体作为PC12细胞的贴附载体,旋转细胞培养系统所提供10-2g的微重力环境进行模拟微重力条件下的细胞培养。在倒置显微镜下观察PC12细胞的生长情况;用扫描电镜观察PC12细胞超微结构的变化;衰老相关β半乳糖苷酶(SA-β-gal)特异性染色对衰老的PC12细胞进行评估。结果:光镜下模拟微重力培养的PC12细胞表现出类衰老细胞的形态,扫描电子显微镜下观察发现其微绒毛增多。SA-β-gal染色的结果显示在模拟微重力的作用下,PC12细胞SA-β-gal的活性升高。结论:模拟微重力可以引起PC12细胞衰老样的形态变化,以及SA-β-gal的活性升高。     

二萜醌类成分与过氧化物酶同工酶关系的初步研究

本文以聚丙酰胺凝胶柱电泳,分析了唇形科18种植物的过氧化物酶同工酶。实验表明含二萜醌类成分的种,它们的过氧化物酶同工酶的酶谱在中部偏正极处明显。二萜醌类化合物的含量与其过氧化物酶同工酶的酶谱表现常一致。含挥发油成分的种在上述条件下,过氧化物酶同工酶几乎不出现谱带。     

谷子耐盐系的几种同工酶的变化及外源ABA对它们的影响

对谷子细胞变异系的过氧化物酶,细胞色素氧化酶和脂酶同工酶的分析表明：耐盐系在无盐胁迫条件下过氧化物酶同工酶的总酶活性高于对照系,其各同工酶带的强度也与对照有明显差异;在ＮａＣｌ迫条件焉耐盐系中个别原有的酶带消失。细胞色素氧化活性与过氧化物酶同工酶的活性变化情况类似,均与对照有明显差异。     

模拟微重力对拟南芥幼苗的生物学效应

对正常条件和模拟微重力条件下生长的拟南芥幼苗进行比较试验,结果表明模拟微重力会产生如下影响:(1)影响拟南芥幼苗的生长发育;(2)影响拟南芥光合特性;(3)影响拟南芥的生理特性;(4)影响拟南芥植株的钙离子分布。此外,运用基因芯片技术探讨模拟微重力对拟南芥基因表达的影响。     

在不同营养条件下铜绿微囊藻对模拟微重力胁迫的响应

通过测定在不同重力水平和营养条件下培养的铜绿微囊藻(Microcystis aeruginosa)的各项生理生化指标,研究了培养基的营养物质浓度对微囊藻细胞响应模拟微重力胁迫的影响。结果表明,在正常浓度的BG-11(富营养)和营养盐浓度减为1/10的BG-11(贫营养)培养基中培养的微囊藻对模拟微重力胁迫都很敏感,培养2d后多项生理生化指标显著改变;但是在富营养和贫营养条件下,模拟微重力的作用效果是截然不同的。对培养在BG-11中的微囊藻细胞来说,模拟微重力抑制其生长和光合活性,导致细胞内色素(叶绿素a和类胡萝卜素)、蛋白(藻蓝蛋白和可溶性蛋白)和毒素含量显著升高,向外分泌的毒素含量降低;而对培养在1/10BG-11中的藻细胞来说,模拟微重力促进其生长和光合活性,导致细胞内色素、蛋白和毒素含量降低,并使得毒素分泌增强。模拟微重力或营养限制单独作用所造成的影响相似,且后者的作用效果强于前者。当二者同时存在时,模拟微重力可以部分抵消营养限制对微囊藻生长和代谢的影响,这可能是由于模拟微重力下藻细胞的生长受到抑制而导致营养需求降低,也可能是由于模拟微重力提高了藻细胞利用营养物质的效率。总之,微囊藻对模拟微重力胁迫的响应与培养基的营养条件有关。     

槲皮素对模拟微重力条件下体外培养大鼠心肌细胞骨架的影响

采用细胞免疫双荧光染色观察离体培养的大鼠心肌细胞微丝和微管分布 ,探讨模拟微重力条件下槲皮素对心肌细胞骨架分布的影响。结果表明 :模拟微重力条件下心肌细胞微丝、微管在近胞核区的分布增多 ;模拟微重力处理的同时加入槲皮素 ,则使近胞核处微丝、微管分布明显减少 ,微丝束的粗细与对照组无异。提示模拟微重力可显著影响心肌细胞微丝、微管的分布 ,槲皮素可对抗该效应而发挥其心肌细胞保护作用 [动物学报49(1) :98～ 10 3 ,2 0 0 3]。     

模拟微重力效应对心肌细胞一氧化氮水平的影响及其相关机制的研究

空间微重力导致的心肌收缩功能下降是航天医学的重要问题, 其发生机制尚不清楚. 采用电子自旋共振(ESR)、免疫细胞化学和核酸原位杂交等技术研究了模拟微重力效应对心肌细胞一氧化氮(NO)水平、诱导型一氧化氮合成酶(iNOS)表达的影响及其调控的信号转导途径, 以探讨模拟微重力影响心肌细胞收缩功能的可能机制. 结果表明, 模拟微重力导致心肌细胞NO水平增高, iNOS蛋白及其mRNA表达上调; 非选择性的蛋白激酶抑制剂staurosporine和选择性的蛋白激酶C ( PKC )抑制剂calphostin C均可显著抑制模拟微重力下心肌细胞NO水平增高, 说明模拟微重力对iNOS表达的调节至少是部分地依赖于PKC途径. 结果提示, 心肌细胞NO途径对模拟微重力条件敏感, 该途径可能在模拟微重力影响心肌细胞收缩功能的机制中发挥重要作用.     

Suppression of Hydroxycinnamate Network Formation in Cell Walls of Rice Shoots Grown under Microgravity Conditions in Space

Network structures created by hydroxycinnamate cross-links within the cell wall architecture of gramineous plants make the cell wall resistant to the gravitational force of the earth. In this study, the effects of microgravity on the formation of cell wall-bound hydroxycinnamates were examined using etiolated rice shoots simultaneously grown under artificial 1 g and microgravity conditions in the Cell Biology Experiment Facility on the International Space Station. Measurement of the mechanical properties of cell walls showed that shoot cell walls became stiff during the growth period and that microgravity suppressed this stiffening. Amounts of cell wall polysaccharides, cell wall-bound phenolic acids, and lignin in rice shoots increased as the shoot grew. Microgravity did not influence changes in the amounts of cell wall polysaccharides or phenolic acid monomers such as ferulic acid (FA) and p-coumaric acid, but it suppressed increases in diferulic acid (DFA) isomers and lignin. Activities of the enzymes phenylalanine ammonia-lyase (PAL) and cell wall-bound peroxidase (CW-PRX) in shoots also increased as the shoot grew. PAL activity in microgravity-grown shoots was almost comparable to that in artificial 1 g-grown shoots, while CW-PRX activity increased less in microgravity-grown shoots than in artificial 1 g-grown shoots. Furthermore, the increases in expression levels of some class III peroxidase genes were reduced under microgravity conditions. These results suggest that a microgravity environment modifies the expression levels of certain class III peroxidase genes in rice shoots, that the resultant reduction of CW-PRX activity may be involved in suppressing DFA formation and lignin polymerization, and that this suppression may cause a decrease in cross-linkages within the cell wall architecture. The reduction in intra-network structures may contribute to keeping the cell wall loose under microgravity conditions.     

The effect of 8 days of microgravity on regeneration of intact plants from protoplasts

The growth and development of protoplasts of rapeseed (Brassica napus L. cv Line) and carrot (Daucus carota L. cv. Navona) were studied onboard the Space Shuttle‘Discovery’during an 8-day International Microgravity Laboratory [IML-l) mission in January 1992. The Flight experiments were carried out in‘Biorack'. a fully controlled cell biological experimental facility. under microgravity conditions and in a l-g centrifuge. Parallel experiments were performed in a‘Biorack’module on the ground. After retrieval, some samples were subcultured on appropriate media and analysed for callus growth and regeneration to intact plants. The remainder were used for biochemical analysis. Samples fixed on board the Space Shuttle were kept in l% glutaraldehyde fixative at 4°C for 3–7 days for microscopy analysis after retrieval. Protoplasts exposed to microgravity conditions showed a delay in cell wall synthesis. Cells were swollen in appearance and formed cell aggregates with only few cells. Callus were obtained from protoplasts cultured under microgravity (Fogl). on the l-g centrifuge on board the shuttle (Flg), under normal l-g conditions on the ground (G1g) and on a centrifuge on the ground giving 1.4 g (Gl.4g). Regeneration of intact rapeseed plants was obtained from Flg. Glg and G1.4g. However, no plants were regenerated from protoplasts exposed to microgravity (Fog). Biochemical analysis indicated that the microgravity samples (Fog displayed a reduced packed cell volume, an increased concentration of soluble proteins per cell, and a reduced specific activity of peroxidase in the cytoplasm. Morphometric analysis of fixed samples demonstrated that 3-day old protoplasts under microgravity conditions were significantly larger than protoplasts kept on the l-g centrifuge in space. UItrastructural analysis by transmission electron microscopy showed that protoplasts exposed to microgravity conditions for 3 days had larger vacuoles and a slightly reduced starch content compared to Flg cells. Cell aggregates formed under microgravity conditions (Fog) had an average of 2–I cells per aggregate while aggregates formed under Flg had 8–12 cells.     

植物向重性地基研究

植物向重性的机理研究与植物在微重力环境下的生长发育有关。本文在地基1×g重力场上进行了幼苗重力反应实验,结果表明：重力引起水平放置的幼苗过氧化物酶在根尖组织上、下侧的差异分布;在重力场上水平放置的幼苗其根尖向高钙(Ca2+)—侧弯曲生长;当给倒置幼苗的顶端照光时其负向地性消失。     

Expression of stress-related genes in zebrawood (Astronium fraxinifolium,Anacardiaceae) seedlings following germination in microgravity

Seeds of a tropical tree species from Brazil, Astronium fraxinifolium, or zebrawood, were germinated, for the first time in microgravity, aboard the International Space Station for nine days. Following three days of subsequent growth under normal terrestrial gravitational conditions, greater root length and numbers of secondary roots was observed in the microgravity-treated seedlings compared to terrestrially germinated controls. Suppression subtractive hybridization of cDNA and EST analysis were used to detect differential gene expression in the microgravity-treated seedlings in comparison to those initially grown in normal gravity (forward subtraction). Despite their return to, and growth in normal gravity, the subtracted library derived from microgravity-treated seedlings was enriched in known microgravity stress-related ESTs, corresponding to large and small heat shock proteins, 14-3-3-like protein, polyubiquitin, and proteins involved in glutathione metabolism. In contrast, the reverse-subtracted library contained a comparatively greater variety of general metabolism-related ESTs, but was also enriched for peroxidase, possibly indicating the suppression of this protein in the microgravity-treated seedlings. Following continued growth for 30 days, higher concentrations of total chlorophyll were detected in the microgravity-exposed seedlings.     

微重力条件下细胞培养和组织工程研究进展

随着空间生命科学研究的发展,人们将细胞、组织培养技术与微重力环境相结合产生了组织工程研究的一个新领域——微重力组织工程。模拟微重力条件下细胞培养和组织构建研究表明,微重力环境有利于细胞的三维生长,形成具有功能的组织样结构,培养后的三维组织无论从形态上还是基因表达上都更接近于正常的机体组织。这种微重力对细胞的作用效应,将可能为未来组织工程和再生医学研究提供一条新途径。该文概述了近十年来国内外微重力组织工程相关研究的最新进展。     

Simulated Microgravity Compromises Mouse Oocyte Maturation by Disrupting Meiotic Spindle Organization and Inducing Cytoplasmic Blebbing

In the present study, we discovered that mouse oocyte maturation was inhibited by simulated microgravity via disturbing spindle organization. We cultured mouse oocytes under microgravity condition simulated by NASA''s rotary cell culture system, examined the maturation rate and observed the spindle morphology (organization of cytoskeleton) during the mouse oocytes meiotic maturation. While the rate of germinal vesicle breakdown did not differ between 1 g gravity and simulated microgravity, rate of oocyte maturation decreased significantly in simulated microgravity. The rate of maturation was 8.94% in simulated microgravity and was 73.0% in 1 g gravity. The results show that the maturation of mouse oocytes in vitro was inhibited by the simulated microgravity. The spindle morphology observation shows that the microtubules and chromosomes can not form a complete spindle during oocyte meiotic maturation under simulated microgravity. And the disorder of γ-tubulin may partially result in disorganization of microtubules under simulated microgravity. These observations suggest that the meiotic spindle organization is gravity dependent. Although the spindle organization was disrupted by simulated microgravity, the function and organization of microfilaments were not pronouncedly affected by simulated microgravity. And we found that simulated microgravity induced oocytes cytoplasmic blebbing via an unknown mechanism. Transmission electron microscope detection showed that the components of the blebs were identified with the cytoplasm. Collectively, these results indicated that the simulated microgravity inhibits mouse oocyte maturation via disturbing spindle organization and inducing cytoplasmic blebbing.     

Effects of simulated microgravity on nitric oxide level in cardiac myocytes and its mechanism

The depression of cardiac contractility induced by space microgravity is an important issue of aerospace medicine research, while its precise mechanism is still unknown. In the present study, we explored effects of simulated microgravity on nitric oxide (NO) level, inducible nitric oxide synthase (iNOS) expression and related regulative mechanism using electron spin resonance (ESR) spectroscopy, immunocytochemistry and in situ hybridization. We found a remarkable increase of NO level and up-regulation of iNOS and iNOS mRNA expression in rat cardiac myocytes under simulated microgravity. Staurosporine (a nonselective protein kinase inhibitor), calphostin C (a selective protein kinase C inhibitor), partially inhibited the effect of simulated microgravity. Thus regulative effect of simulated microgravity on iNOS expression is mediated at least partially via activation of protein kinase C. These results indicate that NO system in cardiac myocytes is sensitive to simulated microgravity and may play an important role in the depression of cardiac contractility induced by simulated microgravity.     

Secondary metabolism in simulated microgravity and space flight

Space flight experiments have suggested that microgravity can affect cellular processes in microorganisms. To simulate the microgravity environment on earth, several models have been developed and applied to examine the effect of microgravity on secondary metabolism. In this paper, studies of effects of space flight on secondary metabolism are exemplified and reviewed along with the advantages and disadvantages of the current models used for simulating microgravity. This discussion is both signi?cant and timely to researchers considering the use of simulated microgravity or space flight to explore effects of weightlessness on secondary metabolism.