Contribution of Cyclic and Pseudo-cyclic Electron Transport to the Formation of Proton Motive Force in Chloroplasts

Photosynthetic electron transport is coupled to proton translocation across the thylakoid membrane, re- sulting in the formation of a trans-thylakoid proton gradient （△pH） and membrane potential （△ψ）. Ion trans-porters and channels localized to the thylakoid membrane regulate the contribution of each component to the proton motive force （pmf）. Although both △pH and △ψ contribute to ATP synthesis as pmf, only ~pH downregulates photosynthetic electron transport via the acidification of the thylakoid lumen by inducing thermal dissipation of excessive absorbed light energy from photosystem II antennae and slowing down of the electron transport through the cytochrome bsf complex. To optimize the tradeoff between efficient light energy utilization and protection of both photosystems against photodamage, plants have to regulate the pmf amplitude and its components, △pH and △ψ. Cyclic electron transport around photosystem I （PSI） is a major regulator of the pmf amplitude by generating pmf independently of the net production of NADPH by linear electron transport. Chloroplast ATP synthase relaxes pmf for ATP synthesis, and its activity should be finely tuned for maintaining the size of the pmf during steady-state photosynthesis. Pseudo-cyclic electron transport mediated by flavodiiron protein （FIv） forms a large electron sink, which is essential for PSI photoprotection in fluctuating light in cyanobacteria. FIv is conserved from cyanobacteria to gymno- sperms but not in angiosperms. The Arabidopsis proton gradient regulation 50（pgr5） mutant is defective in the main pathway of PSI cyclic electron transport. By introducing Physcomitrella patens genes encoding Flvs, the function of PSI cyclic electron transport was substituted by that of FIv-dependent pseudo-cyclic electron transport. In transgenic plants, the size of the pmf was complemented to the wild-type level but the contribution of △pH to the total pmf was lower than that in the wild type. In the pgr5 mutant, the size of the pmf was drastically lowered by the absence of PSI cyclic electron transport. In the mutant, △pH occupied the majority ofpmf, suggesting the presence of a mechanism for the homeostasis of luminal pH in the light. To avoid damage to photosynthetic electron transport by periods of excess solar energy, plants employ an intricate regulatory network involving alternative electron transport pathways, ion transporters/channels, and pH-dependent mechanisms for downregulating photosynthetic electron transport.

Relationship between components of proton motive force and photosynthesis

The proton motive force formed across the thylakoid membrane accompanying the photosynthetic electron transport can be used to synthesize ATP from ADP and inorganic phosphate for carbon assimilation. The mechanism of this important process has been intensively studied. However, there are still many aspects unsolved. For example: What is the ratio between the ATP and NADPH formed in noncyclic photophosphorylation and can it meet the requirement of carbon assimilation? Is there any localized proton within thylakoid membrane and is it related to the effi-

A bestrophin-like protein modulates the proton motive force across the thylakoid membrane in Arabidopsis

During photosynthesis, photosynthetic electron transport generates a proton motive force （pmf） across the thylakoid membrane, which is used for ATP biosynthesis via ATP synthase in the chloroplast. The pmf is composed of an electric potential （△φ） and an osmotic component （△pH）. Partitioning between these components in chloroplasts is strictly regulated in response to fluctuating environments. However, our knowledge of the molecular mechanisms that regulate pmf partitioning is limited. Here, we report a bestrophin-like protein （AtBest）, which is critical for pmf partitioning. While the △pH component was slightly reduced in atbest, the △φ component was much greater in this mutant than in the wild type, resulting in less efficient activation of nonphotochemical quenching （NPQ） upon both illumination and a shift from low light to high light. Although no visible phenotype was observed in the atbest mutant in the greenhouse, this mutant exhibited stronger photoinhibition than the wild type when grown in the field. AtBest belongs to the bestrophin family proteins, which are believed to function as chloride （Cl^-） channels. Thus, our findings reveal an important Cl^- channel required for ion transport and homeo- stasis across the thylakoid membrane in higher plants. These processes are essential for fine-tuning photosynthesis under fluctuating environmental conditions.

Change of proton motive force across thylakoid membrane in soybean leaf during state transitions

Change of proton gradient across thylakoid membrane in soybean leaves was studied with millisecond delayed light emission (ms-DLE) during the course of state transitions which were indicated by the chlorophyll fluores-cence at room temperature and 77 K. When dark-adapted leaves were induced to stateⅠ with far-red light, Fm/Fo, F685/F735 and the intensity of fast phase of ms-DLE were af-fected slightly. However, during the induction to stateⅡ with red light, both Fm/Fo and F685/F735 decreased immedi-ately and the former were quicker than the latter. In this interval, the intensity of fast phase of ms-DLE increased to a maximum and then decreased to a lower value during the transition to stateⅡ. Nigericin, an uncoupler which elimi-nates the proton gradient across thylakoid membrane, inhib-ited the increase in the intensity of fast phase of ms-DLE during the transition to stateⅡ. Another uncoupler, valino-mycin, which eliminates the membrane potential, did not affect the changes of the intensity of fast phase. These results suggest that the prompt increase in the intensity of fast phase of ms-DLE at the beginning of transitions to stateⅡ is cor-related mainly with the proton gradient released from water oxidation in photosystemⅡ.

D-海藻糖增强氨基糖苷类抗生素杀灭大肠杆菌的机制探究

寻找高效的抗生素佐剂并研究其增效杀菌机制是目前应对细菌耐药问题的有效策略之一。为探究D-海藻糖(D-trehalose)增强氨基糖苷类抗生素杀灭大肠杆菌的机制,以大肠杆菌BW25113为研究对象,测定D-trehalose联合氨基糖苷类抗生素作用前后的ATP、NADH含量以及质子动力势(PMF),分析菌体内能量代谢和膜电位水平的变化,并通过抑菌圈实验检测对抗生素摄取的影响。结果提示:D-trehalose联合妥布霉素或庆大霉素双处理后,D-trehalose能够通过升高大肠杆菌PMF水平增加ATP合成,提高NADH水平,促进抗生素摄取,由此显著增强抗生素的杀菌效果。研究结果为开发D-海藻糖作为新型氨基糖苷类抗生素佐剂提供依据。

秸秆覆盖与施磷显著提高丘陵旱地小麦花后根尖质子动力势

【目的】西南丘陵旱地气候冬干春旱,土壤速效磷缺乏,施磷可有效提高小麦的抗旱能力和产量。我们研究了秸秆覆盖与施磷量对旱地小麦花后根尖质子吸收能力(PMF)的影响,为小麦高产稳产提供理论和技术依据。【方法】试验于2020—2022年在四川仁寿进行,采用二因素裂区设计,以秸秆覆盖和不覆盖为主区;3个磷(P2O5)水平0(P0)、75(P75)和120(P120)kg/hm2为裂区,分析了小麦花后20天根尖质子动力势(质子吸收速率、净吸收速率),测定了小麦干物质积累量、产量及其构成因素。【结果】花后20天,P75和P120处理的质子净吸收速率秸秆覆盖下较P0分别提高了37.7%和32.4%,秸秆不覆盖下分别提高了20.3%和36.5%。与不覆盖相比,秸秆覆盖下小麦根尖质子净吸收速率平均提升了29.4%,氮、磷和钾积累量分别提高了23.2%、32.7%和31.9%,开花期和成熟期营养器官干物质积累量分别提高了30.9%和38.5%。秸秆覆盖显著提高了有效穗、穗粒数和产量,且增加幅度表现为P120>P75>P0。无论是否进行秸秆覆盖,P75、P120处理较P0显著提高了小麦氮、磷和钾吸收效率,P75与P0的氮、钾素籽粒生产效率无显著差异,而P120处理显著降低了氮、钾素籽粒生产效率。秸秆覆盖和磷肥配合的6个处理中,秸秆覆盖+P75处理所获得的小麦产量和磷素利用效率显著高于无秸秆覆盖+P120处理。【结论】秸秆覆盖与施用磷肥均可显著提高小麦花后根尖质子动力势,促进养分吸收和地上部干物质的积累,增加有效穗和穗粒数,进而实现增产。施磷75 kg/hm2可提高小麦的氮、钾吸收率,不影响氮、钾素籽粒生产效率,而施磷120 kg/hm2显著降低了氮、钾素籽粒生产效率,因此,采用秸秆覆盖配施75 kg/hm2的磷肥(P2O5)可实现小麦高产高效和绿色生产。

超高压对单核细胞增生李斯特氏菌细胞膜损伤及其氧化磷酸化的影响

【目的】研究超高压作用对单核细胞增生李斯特氏菌(LM 54004)细胞膜、氧化磷酸化和F0F1-ATP酶的影响。【方法】用原子吸收法测定LM 54004经超高压作用后细胞内金属离子(K+、Mg2+)的泄漏;以亲脂性阳离子四苯基溴化膦([3H]-TPP+)作为放射性探针标记LM 54004细胞膜,测定经超高压作用后细胞膜电位的变化;用羧基荧光素琥珀酰亚胺酯(cFSE)为荧光探针测定经超高压作用后细胞内pH的变化;用比色法测定超高压对LM 54004 F0F1-ATP酶活性的影响。【结果】150—300 MPa作用10 min,随着压力的增大LM 54004菌落数显著降低,细胞内K+和Mg2+没有泄漏到细胞外,膜电势、跨膜H+浓度梯度和质子动力势大小基本保持不变,F1F0-ATP酶活性降低显著;300 MPa作用10 min,尽管LM 54004菌落数低于检测限,F0F1-ATP酶活性降到0,但细胞膜完整无损,其质子动力势仍然达到最大值。【结论】超高压作用下LM 54004的灭活与F0F1-ATP酶活性的降低之间相关性较好。LM 54004的细胞膜上参与呼吸链有关的酶和电子载体较F0F1-ATP酶耐压,F0F1-ATP酶对超高压敏感,超高压作用下F0F1-ATP酶的失活是超高压灭活的重要原因。

厌氧下的PHB和聚磷酸盐及其生化机理研究

用氧化还原电位仪严格监测反应过程 ,准确测定了在厌氧状况下PHB的合成量与聚磷酸盐的释放量 ;对活性污泥细胞内的PHB颗粒和聚磷颗粒进行了大量染色及显微镜检分析。通过试验证明 ,厌氧状况发生了PHB大量合成与聚磷酸盐大量释放 ,并得出二者关系曲线图 ,对其生化机理进行了深入研究。

细菌鞭毛马达——一种卓越的分子机器

鞭毛马达 (flagellarmotor)是一种分子旋转马达 ,它在细菌鞭毛的结构与功能中起着中心作用 .鞭毛马达的结构已基本清楚 ,主要由MotA、MotB、FliG、FliM和FliN 5种蛋白组成定子 (stator)和转子 (rotor) ,其驱动力来自于跨膜的H+或Na+流 .目前对鞭毛马达的旋转动力学及旋转力矩产生机制已有初步的了解 .鞭毛马达可作为研究分子旋转马达的理想模型 。

CO_2增施对四川弱光区设施黄瓜叶片光系统功能及其产量的影响

【目的】为探究CO_2增施对弱光区设施黄瓜叶片光系统II、光系统I、跨膜质子梯度及产量的影响。【方法】以‘川翠3号’黄瓜为材料,利用吊袋式CO_2气肥进行黄瓜的CO_2增施处理,采用分光光度计、LI-6400便携式光合测定仪和Dual-PAM-100双通道荧光测定仪分别测定处理和对照黄瓜叶片的光合色素含量、叶片气体交换参数、光系统II和光系统I荧光参数及跨膜质子梯度的550~515 nm差示信号等参数;此外,测定黄瓜叶片的叶面积、单果重、单株结果数、株高及产量等指标。【结果】CO_2增施使黄瓜叶片叶面积、叶绿素b、总叶绿素含量、表观量子效率(AQE)增高,而叶绿素a/b下降;PSII和PSI的最大电子传递速率和跨膜电位(Δψ)增高导致pmf增高。此外,CO_2增施使得黄瓜单果重、单株结果数及株高均有增加,小区产量比对照增加73.8%。由此可见,叶片接受的光能更多的用于CO_2同化作用,同时提高了黄瓜叶片的弱光利用率和抗光氧化的能力,最终通过增加单果重和单株结果数导致其产量的增加。【结论】本研究结果不仅进一步揭示了弱光区黄瓜光合系统对CO_2浓度升高的响应机制,还为四川弱光地区春季黄瓜促成栽培中应用吊袋式CO_2施肥方式提供了理论依据。

线粒体和叶绿体中能量转化问题研究

该研究探讨了在线粒体和叶绿体中质子驱动力和三磷酸腺苷(ATP)生成的关系。质子驱动力是驱动ATP生成最直接的因素。结合线粒体内膜的电子传递链系统和叶绿体内囊体膜上的光合系统,分析了线粒体内膜电子传递链、ATP合成酶以及叶绿体内囊体光反应和暗反应的能量转化机制,并且对线粒体和叶绿体系统中的能量转化效率问题进行了定量计算。

红光和远红光处理引起的杜氏盐藻跨类囊体膜质子动力势变化

照射远红光后杜氏盐藻毫秒延迟发光快相强度明显增加,而红光处理结果则相反。低温条件明显抑制远红光引起的毫秒延迟发光快相强度的上升,而红光则仍能够有效地引起毫秒延迟发光快相强度的降低。加入消除跨类囊体膜质子梯度的尼日利亚菌素后,远红光不能引起延迟荧光强度的上升。与以前在高等植物中得到的结果相比,在杜氏盐藻中远红光处理后毫秒延迟发光快相强度增加的幅度更大,红光处理后没有出现毫秒延迟发光快相强度先增加后降低的现象。

呼吸链研究的最新进展

呼吸链的氧化磷酸化.系统由五种蛋白质—脂类的酶复合体组成:复合体Ⅰ——NADH:泛醌氧化还原酶;复合体Ⅱ——琥珀酸:泛醌氧化还原酶;复合体Ⅲ——泛醌醇:高铁细胞色素 C 氧化还原酶;复合体Ⅳ——亚铁细胞色素 C 氧化还原酶;复合体Ⅴ——ATP 合成酶。本文介绍了上述五个复合体的结构和功能研究进展,并用形象的图来表达它们的概念,如图1所示,从功能上来看,线粒体的氧化—磷酸化系统的五种酶复合体是相互作用着的.呼吸链的电子载体都是醌式结构(FMN、FAD、COQ)和过渡金属的复合物(铁硫蛋白等)。

盐碱胁迫对枸杞幼苗生长与叶绿素荧光特性的影响

为深入了解盐碱胁迫下植物的生长发育情况,以宁夏1号枸杞为研究对象,采用盆栽控盐试验,设置完全营养土组(CK)、半营养土半盐碱土组(BK)和完全盐碱土组(AK)3个处理,测定枸杞幼苗的生长指标、叶片叶绿素荧光参数以及质子动力势参数,分析其变化规律。结果表明:低浓度盐碱胁迫(BK组)对枸杞幼苗的生长和叶片叶绿素含量并无显著影响,反而可能促进叶绿素的合成,而高浓度盐碱胁迫(AK组)则会抑制其生长,并使叶绿素含量显著降低;BK组和AK组枸杞叶片光系统Ⅱ(PSⅡ)光反应中心开放数目(q_(L))呈现先增加后减少的趋势,PSⅡ最大光化学量子产量(F_(v)/F_(m))在盐碱胁迫中后期显著下降(P<0.05),而非光化学猝灭系数(q_(N))显著升高(P<0.05);调节性能量耗散的量子产额(Y_(NPQ))随着胁迫时间的延长保持在一个较高的水平,而非调节性能量耗散的量子产额(Y_(NO))则在胁迫后期显著增加(P<0.05);类囊体质子传导率(g_(H^(+)))保持总体下降的趋势,电致变色带移衰退总幅度(ECS_(t))在略微降低后又显著升高(P<0.05);随着盐碱胁迫程度的加强,AK组各项生理指标较BK组波动更为剧烈,变化幅度更大,且与CK组的差异也更为显著。枸杞幼苗具有一定的耐盐碱能力,但较高浓度、长时间的盐碱胁迫仍会降低其光合作用效率,从而影响其正常生长。

细胞线粒体状态的热力学分析

近年来,线粒体在一些重大的代谢性疾病如糖尿病和神经退行性病变中的作用备受关注。由于线粒体是细胞生产能量的“工厂”,线粒体的能量代谢理论研究带动了线粒体热力学研究的进展,也向化学热力学研究提出新的问题。本文在总结了化学渗透理论和近年来与线粒体有关的生物化学研究新结果的基础上,对线粒体的工作及其调节机制进行了分析,提出了线粒体工作状态受化学热力学机制控制的新观点。

线粒体F_1-ATP酶高效运行机制分析

线粒体内膜上F1-ATP合酶只有十几个纳米,但能量转化效率却高得惊人,几乎达到100%!文章对Kinosita实验系统中F1-ATP酶所携带的微丝进行了力学分析,得到马达的平均力矩约为44pNnm,结果与实验相吻合;并且根据已知实验数据得到了平均力矩与ATP浓度的关系.

受体介导内吞过程中巨噬细胞线粒体质子动力势的变化

ＳＮＡＦＬ－ｃａｌｃｅｉｎ－ＡＭ、ｒｈｏｄａｍｉｎｅ１２３分别标记培养的小鼠腹腔巨噬细胞胞浆ｐＨ、线粒体ｐＨ和线粒体跨膜电位；用激光共聚焦显微镜，观察了巨噬细胞内线粒体的分布，ＣｏｎＡ刺激后胞浆ｐＨ、线粒体ｐＨ及线粒体跨膜电位随时间变化曲线。结果显示ＣｏｎＡ刺激可引起线粒体内外ｐＨ差增加，线粒体跨膜电位在刺激开始时上升，而后逐渐下降；线粒体质子动力势绝对值在刺激开始一段时间增加，随后逐渐降低到比刺激前更低的水平。

谷氨酸逆转副溶血弧菌氧氟沙星耐药性的研究

细菌耐药已经成为国际社会面临的重大公共卫生挑战,不仅严重危害人类健康,而且制约水产养殖业的可持续发展,迫切需要解决抗生素耐药性问题.尽管对细菌耐药机制的认识不断完善,但仍缺乏有效的控制策略.本文以严重危害我国水产养殖业的副溶血弧菌为研究对象,开展代谢逆转氧氟沙星耐药性的研究.选择副溶血弧菌(Vibrio parahaemolyticus ATCC17802)为实验对象,通过人工传代筛选氧氟沙星耐药菌.采用GC-MS代谢组学的方法比较了副溶血弧菌敏感菌和耐药菌的代谢特征;进一步分析敏感菌与耐药菌的差异代谢特征,筛选出11条差异代谢通路,并鉴定到谷氨酸为关键生物标志物.外源谷氨酸能够有效逆转副溶血弧菌对氧氟沙星的耐药性,提高抗生素的体外杀菌率30倍,并且这种逆转效力不仅对副溶血弧菌有效,对其他临床分离的耐药弧菌菌株也具有很好的效果.进一步对谷氨酸促进氧氟沙星杀菌作用机制的研究发现,谷氨酸是通过代谢调节质子动力势(proton motive force,PMF)介导的胞内抗生素浓度增加来发挥作用的.本研究拓展了代谢调节细菌耐药性的认识,为建立利用现有抗生素对抗水产耐药菌感染奠定了研究基础.

Nisin抗菌作用机制及抑菌效力

Nisin是一种由乳酸乳球菌核糖体上合成的并经过一系列酶学修饰的以含有羊毛硫氨酸和β-甲基羊毛硫氨酸等稀有氨基酸为特征的抗菌肽,Nisin作用目标为细胞膜,Nisin与细胞膜通过结合,插入和孔道形成等多步过程形成孔道复合物,从而引起细胞液渗漏。孔道的形成有“桶板”和“楔入”两种孔道模型。Nisin能够抑杀许多引起食品腐败的革兰阳性菌,Nisin的抑菌效率取决于其分子结构,受目标控制菌及其系统性质的影响,如Nisin抗性、膜干扰剂、亚致死伤害、阳离子、温度、pH、蛋白水解酶和其它防腐剂。

P515的测量原理、方法和应用

光谱技术已广泛应用于光合研究领域,如光吸收信号P515和P700氧化还原动力学以及叶绿素荧光等,可快速、准确地检测植物的光合活性。P515信号广泛存在于高等植物和藻类中,是类囊体膜上的色素分子吸收光能后,其吸收光谱发生位移造成。利用光诱导的P515快速和慢速动力学,可检测PSI和PSII反应中心的比值、ATP合酶的质子传导性、围绕PSI的环式电子传递速率、质子动力势及其组分,还可通过同步检测叶绿素荧光和P515信号研究光保护机制。该文总结了P515的主要测量原理、方法及其应用,旨在为深入研究光合作用机理提供技术支持。