条浒苔和缘管浒苔对镉胁迫的生理响应比较

为探讨大型海藻对重金属胁迫的生理响应及耐受机制,以条浒苔（Enteromorpha clathrata）和缘管浒苔（Enteromorpha linza）为试验材料,研究了不同浓度的镉（Cd2 ）处理7天对两个浒苔品种的生长、叶绿素（Chl）和类胡萝卜素（Car）含量、叶绿素荧光参数以及可溶性糖（SS）和可溶性蛋白含量（SP）的影响。结果表明：随着Cd2 浓度的增加,条浒苔和缘管浒苔鲜重和相对生长速率（RGR）与对照相比显著下降,且条浒苔的鲜重和RGR降低幅度大于缘管浒苔。镉胁迫下,叶绿素和类胡萝卜素含量、叶绿素a/叶绿素b（Chla/Chlb）、PSⅡ最大光能转化效率（Fv/Fm）、PSⅡ实际光能转化效率（Yield）、最大相对电子传递速率（rETRmax即Pm）和光能利用效率（α）、可溶性蛋白含量随着Cd2 浓度的升高均出现下降趋势,除了叶绿素外,条浒苔的其它指标的降幅要大于缘管浒苔。随着镉胁迫强度的增加,浒苔可溶性糖含量呈现逐渐显著上升。上述表明,条浒苔和缘管浒苔对Cd2 胁迫均具有一定的适应能力,且缘管浒苔耐镉性高于条浒苔。在镉胁迫下,维持较高的Car含量、Chla/Chlb、Fv/Fm、Yield、rETRmax、α、SS含量、SP含量是缘管浒苔耐镉性高于条浒苔的主要原因。     

蛋白核小球藻生长和无机碳利用对不同光照强度和CO2浓度的响应

为了探讨光照强度和CO₂浓度对蛋白核小球藻(Chlorella pyrenoidosa)生长、无机碳利用的复合效应, 丰富绿藻中无机碳浓缩机制的资料, 该文设置两种光照强度(40和120 µmol photons•m^-2•s^-1)和两种CO₂浓度(0.04%和0.16%)组合成4种条件, 比较了蛋白核小球藻生长、无机碳浓度、pH补偿点、光合放氧速率、碳酸酐酶(CA)活性和α-CA基因转录表达对这4种培养条件的响应。结果发现: 蛋白核小球藻在高光强高CO₂浓度组生长最快; 低光强高CO₂浓度组培养体系中总无机碳浓度为1163.3 µmol•L^-1, 显著高于其他3组; 高光强低CO₂浓度组藻的pH补偿点最高(9.8), 而低光强高CO₂浓度组藻的pH补偿点最低(8.6); 低光强高CO₂浓度组藻的最大光合速率(V_max)和最大光合速率一半时的无机碳浓度(K_0.5)最高, 分别是其他3组的1.28-1.91倍和1.61-2.00倍; 高光强低CO₂浓度组藻的胞外CA活性最高; 而低光强低CO₂浓度组藻的胞外α-CA基因表达量显著高于其他3组。以上结果表明低CO₂浓度可促进蛋白核小球藻的pH补偿点和无机碳亲和力的提高, 诱导胞外CA活性及α-CA基因的表达; 该藻主要以HCO₃^-为无机碳源, 其对无机碳的利用受光照的调节。     

光强对浒苔充气叶状体内氧气浓度的影响

以烟台海域定生浒苔为研究对象,采用光暗转换法,研究了不同光强条件下浒苔充气叶状体内部氧气浓度的变化。结果表明,浒苔充气叶状体内部气体成分中含有氧气,其浓度在360μmol/m2.s光强下达到最高值且保持稳定,光暗转换法显示其最高稳态到最低稳态的过渡仅需约10 s,此外,最低稳态的氧浓度仍高于水体饱和溶氧浓度。     

大型绿藻浒苔转化表达系统选择标记的筛选

主要研究了条浒苔对抗生素氯霉素和除草剂Basta的敏感性,以确定适合的阳性选择标记基因。应用不同浓度氯霉素(0、25、50、75、100、125μg/ml)和Basta(0、5、12.5、25、37.5、50μg/ml)对不同发育时期条浒苔细胞存活率影响进行了测定。实验结果表明:不同发育时期条浒苔对氯霉素和Basta的敏感性不同。其中最大浓度125μg/ml浓度的氯霉素在15d内对条浒苔孢子和小苗两个不同发育时期的细胞均难以达到全部杀死效果,相对存活率仍分别为1%和20%;而Basta对条浒苔孢子和小苗均具有很强的杀生作用,其中5μg/ml浓度的Basta在3d内可将条浒苔孢子全部杀死,12.5μg/ml浓度下约一周时间可以将浒苔小苗全部致死。本实验结果提示bar基因有可能成为浒苔基因工程较理想的选择标记基因。     

一种简单快速测定Rubisco CO2／O2特异性因子的方法

提出了一种简单快速测定１,５－二磷酸核酮糖羧化／氧化酶ＣＯ２／Ｏ２特异性因子的方法。理论上改进了定量计算公式;操作上避免了使用放射性同位素标记以及层析分离３－磷酸甘油酸和２－磷酸乙醇酸的复杂程度,使测定过程一步完成,极大地减少了随机误差。讨论了实验数据（ｐＨ、温度、离子强度）的准确性对计算结果的影响。     

浒苔多糖的降血脂及其对SOD活力和LPO含量的影响

浒苔多糖剂量１５０ｍｇ／ｋｇ可使高胆固醇血症小鼠血清胆固醇下降２２％,剂量１６８ｍｇ／ｋｇ可使高脂血症大鼠ＴＣＨ和ＴＧ分别降低５８％和６１％,ＨＤＬ升高２７％,剂量２５０ｍｇ／ｋｇ可分别提高血清、脑和肝ＳＯＤ活力３３％、１１８％和２２４％,剂量１６８ｍｇ／ｋｇ对高血脂大鼠血清和心脏ＬＰＯ含量降低３５％和４６％。     

水杨酸对浒苔生长和生理特性的影响

为探讨水杨酸(SA)对不同增殖方式来源的浒苔生长和生理特性的影响,本文选取营养繁殖得到的浒苔(VU)和孢子/配子繁殖得到的浒苔(SU)作为供试材料,设置不同的水杨酸浓度,测定两种浒苔的生长、叶绿素荧光、超氧化物歧化酶(SOD)和可溶性蛋白含量等生理指标.结果表明: 低浓度水杨酸可以促进VU和SU的生长,对VU促进效果更为显著;在0.2 μg·mL^-1水杨酸浓度下,VU相对生长速率达到最大值21.0%,且与SU相比,VU最大光化学效率提高了9.8%.水杨酸对两种浒苔的SOD活性影响较大,在水杨酸浓度为0.2、0.5 μg·mL^-1下,VU的SOD活性增幅分别达52.0%、198.6%,SU的SOD活性增幅分别达54.1%、38.0%.水杨酸促进了浒苔的相对电子传递速率、光合作用和蛋白质含量.水杨酸对两种增殖方式来源的浒苔的生长均有促进作用,尤其是对VU的促进作用更为明显.     

低温弱光对黄瓜幼苗Rubisco与Rubisco活化酶的影响

以‘津优3号'黄瓜幼苗为试材,研究弱光(100 μmol·m-2·s-1)下适温(WL:25℃/18℃)、亚适温(ST+WL:18℃/12℃)和低温(LT+WL:10℃/5℃)对黄瓜幼苗光合速率(Pn)、核酮糖-1,5-二磷酸羧化/加氧酶(Rubisco)、Rubisco活化酶(RCA)活性及其基因表达量的影响.结果表明:与对照(25℃/18℃,400 μmol·m-2·s-1)相比,WL、ST+WL和LT+WL处理的单株叶面积和干物质量均明显减小.处理初期,Pn、Rubisco活性及其大亚基基因(rbcL)、小亚基基因(rbcS)表达、RCA活性与基因(CsRCA)表达量大幅度降低,5～7 d后,WL处理趋于平稳,ST+WL处理缓慢回升,而LT+WL处理持续下降,表明黄瓜光合机构对适温弱光和亚适温弱光环境有逐步适应机制.Rubisco和RCA活性及其基因表达对低温弱光的响应与Pn基本一致,表明低温弱光下RCA和Rubisco活性及其基因表达量下降是黄瓜幼苗Pn降低的重要原因.     

大气CO2浓度升高对土壤微生物的影响

自人类进入工业化时代以来,由于化石燃料的燃烧和森林的大面积破坏,大气中ＣＯ２的浓度已由工业革命以前的２８０μｌ·Ｌ－１增加到现在的３５０μｌ·Ｌ－１,仅从１９５７年至今的几十年间,大气中ＣＯ２的浓度就增加了２０％,预计到下个世纪下半叶,大气中ＣＯ２的...     

Al_2O_3催化剂对海洋生物质热解特性的影响

以海洋生物质浒苔为研究对象,并以玉米秸秆(草类生物质)和锯末(木质类生物质)为对照,采用热重分析方法研究了3种生物质的热解特性,并比较了3种生物质之间的热解差异。结果表明,与玉米秸秆和锯末等典型陆生生物质相比,浒苔的热稳定性最低。此外,以不同浓度氧化铝作为催化剂,用热重分析法对其热解过程进行了研究,利用TG-DTG曲线分析了不同催化剂在不同浓度下对其基本热解特性的影响。结果表明,Al2O3对于3种生物质转化率和最大失重速率有显著的影响,其中Al2O3对锯末和浒苔的转化率降低程度比玉米秸秆较明显。考虑到Al2O3具有可调变的表面酸碱性以及多种不同的晶相结构等优点,Al2O3具有较大的的应用价值。     

Chemical characteristic of an anticoagulant-active sulfated polysaccharide from Enteromorpha clathrata

A sulfated polysaccharide FEP from marine green alga Enteromorpha clathrata was extracted with hot water and further purified by ion-exchange and size-exclusion chromatography. Results of chemical and spectroscopic analyses showed that FEP was a high arabinose-containing sulfated polysaccharide with sulfate ester of 31.0%, and its average molecular weight was about 511kDa. The backbone of FEP was mainly composed of (1→4)-linked β-l-arabinopyranose residues with partially sulfate groups at the C-3 position. In vitro anticoagulant assay indicated that FEP effectively prolonged the activated partial thromboplastin time and thrombin time. The investigation demonstrated that FEP was a novel sulfated polysaccharide with different chemical characteristics from other sulfated polysaccharides from marine algae, and could be a potential source of anticoagulant.     

大型海藻浒苔热解特性与动力学研究

以2005年10月采自江苏如东海区的条浒苔(Enteromorpha clathrata)为研究材料,用热重分析法对其热解过程及其动力学规律进行了研究。采用10、20、30℃/min等升温速率分别对0.18、0.28、0.45mm等粒径样品进行热解,结果表明样品非等温失重过程主要为脱水、保持、剧烈失重和缓慢失重4个阶段,且热解失重区为190～520℃之间范围;通过对最大失重率Dmax、失重率峰值温度θmax、挥发等参数分析,可以得出温度Ts和r值都随升温速率的增加而增加,升温速率越高,反应时间越短,热解特性指数增加;当样品粒径为0.28mm以上时,颗粒粒径越大对热解过程影响较大。用Coats-Redfern方法计算出样品的热解动力学参数,发现其热解反应机理函数不同于木质类生物质,求得的活化能E与频率因子A之间存在动力学补偿效应。     

Effect of Rubisco Activase Deficiency on the Temperature Response of CO2 Assimilation Rate and Rubisco Activation State: Insights from Transgenic Tobacco with Reduced Amounts of Rubisco Activase

The activation of Rubisco in vivo requires the presence of the regulatory protein Rubisco activase. To elucidate its role in maintaining CO₂ assimilation rate at high temperature, we examined the temperature response of CO₂ assimilation rate at 380 μL L⁻¹ CO₂ concentration (A₃₈₀) and Rubisco activation state in wild-type and transgenic tobacco (Nicotiana tabacum) with reduced Rubisco activase content grown at either 20°C or 30°C. Analyses of gas exchange and chlorophyll fluorescence showed that in the wild type, A₃₈₀ was limited by ribulose 1,5-bisphosphate regeneration at lower temperatures, whereas at higher temperatures, A₃₈₀ was limited by ribulose 1,5-bisphosphate carboxylation irrespective of growth temperatures. Growth temperature induced modest differences in Rubisco activation state that declined with measuring temperature, from mean values of 76% at 15°C to 63% at 40°C in wild-type plants. At measuring temperatures of 25°C and below, an 80% reduction in Rubisco activase content was required before Rubisco activation state was decreased. Above 35°C, Rubisco activation state decreased slightly with more modest decreases in Rubisco activase content, but the extent of the reductions in Rubisco activation state were small, such that a 55% reduction in Rubisco activase content did not alter the temperature sensitivity of Rubisco activation and had no effect on in vivo catalytic turnover rates of Rubisco. There was a strong correlation between Rubisco activase content and Rubisco activation state once Rubisco activase content was less that 20% of wild type at all measuring temperatures. We conclude that reduction in Rubisco activase content does not lead to an increase in the temperature sensitivity of Rubisco activation state in tobacco.The catalytic sites of Rubisco must be activated for CO₂ fixation to take place. This requires the carbamylation of a Lys residue at the catalytic sites to allow the binding of Mg²⁺ and ribulose 1,5-bisphosphate (RuBP; Andrews and Lorimer, 1987). Rubisco activase facilitates carbamylation and the maintenance of Rubisco activity by removing inhibitors such as tight-binding sugar phosphates from Rubisco catalytic sites in an ATP-dependent manner (Andrews, 1996; Spreitzer and Salvucci, 2002; Portis, 2003; Parry et al., 2008). The activity of Rubisco activase is regulated by the ATP/ADP ratio and redox state in the chloroplast (Zhang and Portis, 1999; Zhang et al., 2002; Portis, 2003).In many plant species, Rubisco activation state decreases at high temperature in vivo (Crafts-Brandner and Salvucci, 2000; Salvucci and Crafts-Brandner, 2004b; Cen and Sage, 2005; Yamori et al., 2006b; Makino and Sage, 2007). However, it is unclear what the primary mechanisms underlying the inhibition of Rubisco activation are and whether Rubisco deactivation limits CO₂ assimilation rate at high temperature. It has been proposed that Rubisco activation state decreases at high temperature, because the activity of Rubisco activase is insufficient to keep pace with the faster rates of Rubisco inactivation at high temperatures (Crafts-Brandner and Salvucci, 2000; Salvucci and Crafts-Brandner, 2004a, 2004c; Kim and Portis, 2006). In in vitro assays using purified Rubisco and Rubisco activase, the activity of Rubisco activase was sufficient for the activation of Rubisco at the optimum temperature but not at high temperatures (Crafts-Brandner and Salvucci, 2000; Salvucci and Crafts-Brandner, 2004a, 2004c). ATP hydrolysis activity of Rubisco activase in vitro has varying temperature optima among species (e.g. 25°C in Antarctic hairgrass [Deschampsia antarctica] and spinach [Spinacia oleracea] but 35°C in tobacco [Nicotiana tabacum] and cotton [Gossypium hirsutum]), and Rubisco activase more readily dissociates into inactive forms at high temperature, causing a loss of Rubisco activase capacity (Crafts-Brandner and Law, 2000; Salvucci and Crafts-Brandner, 2004b). Moreover, the rates of inhibitor formation by misprotonation of RuBP during catalysis increased at higher temperatures (Salvucci and Crafts-Brandner, 2004c; Kim and Portis, 2006). CO₂ assimilation rates and plant growth were improved under heat stress in transgenic Arabidopsis expressing thermotolerant Rubisco activase isoforms generated by either gene-shuffling technology (Kurek et al., 2007) or chimeric Rubisco activase constructs (Kumar et al., 2009). These results support the view that the reduction of Rubisco activase activity limits the Rubisco activation and, therefore, the CO₂ assimilation rates at high temperatures.It has also been suggested that the decrease in CO₂ assimilation rate at high temperatures is caused by a limitation of RuBP regeneration capacity (e.g. electron transport capacity) rather than by Rubisco deactivation per se (Schrader et al., 2004; Wise et al., 2004; Cen and Sage, 2005; Makino and Sage, 2007; Kubien and Sage, 2008). These groups suggest that Rubisco deactivation at high temperature may be a regulatory response to the limitation of one of the processes contributing to electron transport capacities. For example, at high temperature, protons can leak through the thylakoid membrane, impairing the coupling of ATP synthesis to electron transport (Pastenes and Horton, 1996; Bukhov et al., 1999, 2000). As the electron transport capacity becomes limiting, ATP/ADP ratios and the redox potential of the chloroplast decline, causing a loss of Rubisco activase activity and, in turn, a reduction in the Rubisco activation state (Zhang and Portis, 1999; Zhang et al., 2002; Sage and Kubien, 2007). Based on this understanding, the decline in the Rubisco activation state at high temperature may be a regulated response to a limitation in electron transport capacity rather than a consequence of a direct effect of heat on the integrity of Rubisco activase.Temperature dependence of CO₂ assimilation rate shows a considerable variation with growth temperature (Berry and Björkman, 1980; Hikosaka et al., 2006; Sage and Kubien, 2007). Plants grown at low temperature generally exhibit higher CO₂ assimilation rates at low temperatures compared with plants grown at high temperature, but they exhibit lower rates at high temperature. Furthermore, both the temperature response of Rubisco activation state and the limiting step of CO₂ assimilation rate (a Rubisco versus RuBP regeneration limitation) have been shown to differ depending on growth temperature (Hikosaka et al., 1999; Onoda et al., 2005; Yamori et al., 2005, 2006a, 2006b, 2008). This suggests that the regulation of Rubisco activation state could also differ in plants grown at different growth temperatures. Here, we analyzed the effects of Rubisco activase content on Rubisco activation state and CO₂ assimilation rate at leaf temperatures ranging from 15°C to 40°C in tobacco grown under two different temperature regimes (day/night temperatures of 20°C/15°C or 30°C/25°C). We used wild-type and transgenic tobacco with a range of reductions in Rubisco activase content to examine the dependence of Rubisco activation on Rubisco activase content over the range of leaf temperatures (Mate et al., 1993, 1996).     

Carbon concentrating mechanisms: in rescue of Rubisco inefficiency

Agricultural yields have kept pace with the rising demands in the recent past as a result of the breeding and improved farming practices, but these practices alone will not be able to meet the demands of the future. The focus is now on the enhancement of the photosynthetic machinery. In photosynthesis, the rate limiting step is the one catalyzed by RuBisCO- Ribulose-1,5-bisphosphate carboxylase/oxygenase (4.1.1.39), which, because of its loose specificity and low turnover rate, is the primary target of most research programs directed towards improved photosynthesis. The other avenues of photosynthetic machinery that are under investigation to enhance it include—improved stomatal regulation and membrane permeability, RuBisCO with high specificity for CO₂ and higher catalytic turnover; bypass of photorespiration and introduction of carbon concentrating mechanism (CCM) into the C₃ plants. Carbon concentrating mechanisms cause accumulation of carbon dioxide in vicinity of RuBisCO producing a high CO₂/O₂ ratio and hence an environment more suitable for carboxylation reactions than oxygenation reactions. This article includes the basic details of the major naturally occurring CCMs in various photosynthetic organisms to identify the knowledge gaps in each which could help study the prospects of its possible introduction into a non-native system as C₃ plants which are devoid of any CCM.     

Rubisco activity in Mediterranean species is regulated by the chloroplastic CO2 concentration under water stress

Water stress decreases the availability of the gaseous substrate for ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) by decreasing leaf conductance to CO(2). In spite of limiting photosynthetic carbon assimilation, especially in those environments where drought is the predominant factor affecting plant growth and yield, the effects of water deprivation on the mechanisms that control Rubisco activity are unclear. In the present study, 11 Mediterranean species, representing different growth forms, were subject to increasing levels of drought stress, the most severe one followed by rewatering. The results confirmed species-specific patterns in the decrease in the initial activity and activation state of Rubisco as drought stress and leaf dehydration intensified. Nevertheless, all species followed roughly the same trend when Rubisco activity was related to stomatal conductance (g(s)) and chloroplastic CO(2) concentration (C(c)), suggesting that deactivation of Rubisco sites could be induced by low C(c), as a result of water stress. The threshold level of C(c) that triggered Rubisco deactivation was dependent on leaf characteristics and was related to the maximum attained for each species under non-stressing conditions. Those species adapted to low C(c) were more capable of maintaining active Rubisco as drought stress intensified.     

绿藻CO2浓缩机制的研究进展

单细胞绿藻是淡水水体中浮游植物的重要组成部分,也是淡水生态系统中主要的初级生产者,其在适应外界CO2浓度变化的过程中,细胞内形成了一种主动转移无机碳的机制－CO2浓缩机制（CO2 concentrating mechanism,CCM）。该机制能使细胞在核酮糖－2－磷酸羧化氧化酶（rubiscol)固碳位点提高CO2浓度,以增加光合作用和减少光吸收。本文综述了这种机制中的无机碳转移模型和不同环境因子（光,温度,CO2浓度和营养水平）对它的调控作用,以期促进深入开展浮游植物对大气CO2浓度升高响应的研究。     

Effects of growth-light quantity,growth-light quality and CO2 concentration on Rubisco deactivation during low PFD or darkness

The effects of CO₂ concentration and the effects of growth-light conditions on Ribulose 1,5-bisphosphate carboxylase/oxygenase (Rubisco) deactivation were examined for Spinacea oleracea (spinach). Rubisco deactivation kinetics and the degree that Rubisco activation limited the rise in photosynthesis following an increase in photon flux density (PFD) were determined from gas-exchange time courses. There were no significant differences in the apparent relaxation time for Rubisco deactivation among leaves exposed to high or low CO₂ (50 or 1000 mol mol^-1) and low PFD (170 mol m^-2 s^-1) or darkness. However, when PFD was increased to 1700 mol m^-2 s^-1 following a period of low PFD or darkness, leaves exposed to low CO₂ × low PFD showed a lower contribution to the photosynthetic induction process by the activation of Rubisco than leaves exposed to the other treatments. For the growth-light experiments, spinach was grown under high PFD × high red:far-red ratio (R:FR), low PFD × high R:FR, or low PFD × low R:FR light environments. Leaves that matured under the low PFD × low R:FR treatment showed a lower percent change in photosynthesis due to Rubisco activation than leaves exposed to the other growth-light treatments. However, there were no significant differences among the growth-light treatments in the maximum contribution of Rubisco activation to the induction response or in the apparent relaxation time for Rubisco deactivation during shade events.     

Role of carboxysomes in cyanobacterial CO2 assimilation: CO2 concentrating mechanisms and metabolon implications

Many carbon-fixing organisms have evolved CO₂ concentrating mechanisms (CCMs) to enhance the delivery of CO₂ to RuBisCO, while minimizing reactions with the competitive inhibitor, molecular O₂. These distinct types of CCMs have been extensively studied using genetics, biochemistry, cell imaging, mass spectrometry, and metabolic flux analysis. Highlighted in this paper, the cyanobacterial CCM features a bacterial microcompartment (BMC) called ‘carboxysome’ in which RuBisCO is co-encapsulated with the enzyme carbonic anhydrase (CA) within a semi-permeable protein shell. The cyanobacterial CCM is capable of increasing CO₂ around RuBisCO, leading to one of the most efficient processes known for fixing ambient CO₂. The carboxysome life cycle is dynamic and creates a unique subcellular environment that promotes activity of the Calvin–Benson (CB) cycle. The carboxysome may function within a larger cellular metabolon, physical association of functionally coupled proteins, to enhance metabolite channelling and carbon flux. In light of CCMs, synthetic biology approaches have been used to improve enzyme complex for CO₂ fixations. Research on CCM-associated metabolons has also inspired biologists to engineer multi-step pathways by providing anchoring points for enzyme cascades to channel intermediate metabolites towards valuable products.     

The roles of carbonic anhydrases in photosynthetic CO2 concentrating mechanisms

Cyanobacteria, algae, aquatic angiosperms and higher plants have all developed their own unique versions of photosynthetic CO₂ concentrating mechanisms (CCMs) to aid Rubisco in efficient CO₂ capture. An important aspect of all CCMs is the critical roles that the specialised location and function that various carbonic anhydrase enzymes play in the overall process, participating the interconversion of CO₂ and HCO₃ ⁻ species both inside and outside the cell. This review examines what we currently understand about the nature of the carbonic anhydrase enzymes, their localisation and roles in the various CCMs that have been studied in detail. This revised version was published online in August 2006 with corrections to the Cover Date.