Metabolomics of astaxanthin hyperaccumulation in Haematococcus pluvialis under high light stress

Variation in metabolite profiles of Haematococcus pluvialis(a type of unicellular green algal)under light stress is a key issue of study at the present.To investigate the effect of light intensity on accumulation of astaxanthin in H.pluvialis,a 26-day batch culture experiment of H.pluvialis under the light intensity levels at 73,127,182,236,and 291μmol/(m^(2)·s)was conducted.Therefore,the optimal light intensity and the corresponding metabolic pathways of accumulation in H.pluvialis were determined.Results show that 236μmol/(m^(2)·s)was the optimum light intensity to induce astaxanthin accumulation,at which a maximum content of 9.01 mg/L was achieved on Day 24.A total of 132 metabolites were identified and quantified,of which 38 differential metabolites were highlighted and classified,including 3 fatty acids or intermediates,5 amino acids or derivatives,5 carbohydrates or intermediates,16nucleoside derivatives,and 9 other metabolites using LC-MS/MS technique.Subsequently,16 statistically significant differential metabolic pathways were enriched and annotated based on Kyoto Encyclopedia of Genes and Genomes(KEGG)pathway analysis between the control and the 236μmol/(m^(2)·s)treatment group(P<0.05).In addition,the bioprocesses included cellular basal metabolism and signaling systems,such as carbohydrate metabolism,amino acid metabolism,glycerol and derivatives metabolism,nucleotide and derivative metabolism,and inositol phosphate metabolism were activated and regulated under strong light stress conditions.Moreover,4 hub metabolites containing D-glucose-6-phosphate,L-tyrosine,glycerol-3-phosphate,and L-glutamine were identified,based on which the associated metabolic network was constructed.The study provided a metabolomic view of astaxanthin accumulation in H.pluvialis under strong light stress.

Effects of High Light Stress on Chlorophyll-protein Complexes of Two Subspecies of Rice

Influence of high light stress on the photosynthesis of flag leaves of indica subspecies (cv. “Shanyou 63', sensitive to photoinhibition) and japonica subspecies (cv. “Wuyujing', resistant to photoinhibition) of rice ( Oryza sativa L.) was comparatively investigated. In both cultivars of rice, the excitation energy distribution between two photosystems was altered and the excitation energy transfer from light harvesting chlorophyll protein complexes to PSⅡ was inhibited by high light stress. These decreases were more pronounced in indica rice cultivar as compared to japonica one. The analysis of mild SDS_PAGE showed that in indica rice, high light stress almost disaggregated the trimer of light harvesting chlorophyll protein complexes of PSⅡ (LHC Ⅱ 1). The stress reduced the contents of internal antennae chlorophyll protein complexes of PSⅡ (CPa), light harvesting chlorophyll protein of PSⅠ (CPⅠa) and Chl a protein complex of PSⅠ reaction center (CPⅠ) as well as dimer of LHCⅡ (LHCⅡ 2) in indica rice. In japonica subspecies, however, high light stress depressed the contents of LHCⅡ 1, CPa and CPⅠa, but slightly impacted on CPⅠ content. Moreover, the increase in the contents of monomer of LHCⅡ by high light stress was found in both subspecies. In consistent with above results, analysis of polypeptide indicated that the amounts of 27 kD and 25 kD polypeptide of LHCⅡ in particular, as well as that of 21 kD polypeptide of CPⅠa were reduced by high light stress in both subspecies. It was found that, comparing with japonica rice, the stress pronouncedly diminished 43 kD and 47 kD proteins of CPa and 23 kD extrisic protein in indica rice.

Effects of Light Stress on Oxygen Evolution and Photochemical Energy Stor age of Hybrid Poplar Clones Determined by Photoacoustic Technique

The oxygen evolution, thermal dissipation, and photochemical energy storage of three hybrid poplar clones, namely the triploid clone B342, the diploid clone B11 [(Populus alba×P. glandulosa)×(P.tomentosa×P.bolleana)], and the triploid clone B346 [(P.tomentosa×P. bolleana)×(P. alba×P.glandulosa)], under light stress were studied using photoacoustics. The oxygen evolution signal and photochemical energy storage varied negatively with the pretreatment_PFD (photon flux density), whereas the thermal signal varied positively with the pretreatment_PFD. Photochemical energy storage was reallocated to PSⅡ more than to PSⅠ, while the photochemical energy storage in PSⅠ was more stable than that in PSⅡ when subjected to light stress. The inhibitors streptomycin (SM), dithiothreitol (DTT) and sodium fluoride (NaF) could all affect the oxygen evolution signal. Clones B11 and B342 were more resistant to light stress than clone B346.

Transcriptome Profiling of the Abdominal Skin of Larimichthys crocea in Light Stress

Large yellow croaker(Larimichthys crocea), one of the most important marine fish species in China, can change its abdominal skin color when it is shifted from light to dark or from dark to light, providing us an opportunity of investigating the molecular responding mechanism of teleost in light stress. The gene expression profile of fish under light stress is rarely documented. In this research, the transcriptome profiles of the abdominal skin of L. crocea exposed to light or dark for 0 h, 0.5 h and 2 h were produced by next-generation sequencing(NGS). The cluster results demonstrated that stress period, rather than light intensity(e.g., light or dark), is the major influencing factor. Differently expressed genes(DEGs) were identified between 0 h and 0.5 h groups, between 0 h and 2 h groups, between 0.5 h light and 0.5 h dark, and between 2 h light and 2 h dark, respectively. The gene ontology(GO) and Kyoto Encyclopedia of Genes and Genomes(KEGG) annotation revealed that the genes relating to immunity, energy metabolism, and cytoskeletal protein binding were significantly enriched. The detailed analysis of transcriptome profiles also revealed regular gene expression trends, indicating that the elaborate gene regulation networks underlined the molecular responses of the fish to light stress. This transcriptome analysis suggested that systematic and complicated regulatory cascades were functionally activated in response to external stress, and coloration change caused by light stress was mainly attributed to the change in the density of chromatophores for L. crocea. This study also provided valuable information for skin coloration or light stress research on other marine fish species.

Plants response to light stress

Plants require solar energy to grow through oxygenic photosynthesis;however,when light intensity exceeds the optimal range for photosynthesis,it causes abiotic stress and physiological damage in plants.In response to high light stress,plants initiate a series of signal transduction from chloroplasts to whole cells and from locally stressed tissues to the rest of the plant body.These signals trigger a variety of physiological and biochemical reactions intended to mitigate the deleterious effects of high light intensity,such as photodamage and photoinhibition.Light stress protection mechanisms include chloroplastic Reactive oxygen species(ROS)scavenging,chloroplast and stomatal movement,and anthocyanin production.Photosynthetic apparatuses,being the direct targets of photodamage,have also developed various acclimation processes such as thermal energy dissipation through nonphotochemical quenching(NPQ),photorepair of Photosystem II(PSII),and transcriptional regulation of photosynthetic proteins.Fluctuating light is another mild but persistent type of light stress in nature,which unfortunately has been poorly investigated.Current studies,however,suggest that state transitions and cyclic electron transport are the main adaptive mechanisms for mediating fiuctuating light stress in plants.Here,we review the current breadth of knowledge regarding physiological and biochemical responses to both high light stress and fiuctuating light stress.

Light Regulated Osa-miR169e Is Implicated during Priming under High Temperature Stress in Rice

Plants face biotic and abiotic stresses during their entire life cycle, which leads to the loss in crop productivity. It has been shown that a relatively shorter exposure to heat stress, called priming, results in better adaptation of plants under subsequent stresses, which plants may face. While rice plants in nature often encounter high temperature stress conditions, the strategies to cope with those are poorly understood. We identified the involvement of microRNA pathways in the adaptation to heat stress (HS) at the physiological and molecular levels. It was observed that osa-miR169 levels are altered after HS and in response to light conditions. Its expression was also regulated by heat priming during anthesis and effectively responds to the successive exposure to high temperature stress during grain filling in rice. Osa-miR169 targets nuclear factor Y (NF-Y). We propose that osa-miR169: NF-Y regulatory module may be important for HS memory induced during high temperature priming and thus may serve to integrate stress responses with light regulated development. The future study in this direction will be useful to understand how plants acclimatize to the changing environment and thus help in generating stress tolerant crops.

Effects of High Temperature and Strong Light Combine Stress on Yield and Quality of Early Indica Rice with Different Amylose Content during Grout Filling

High temperature(HT)accompanied with strong light(SL)often occurs in early indica rice production during grout filling stage in Southern China,which accelerates grain ripening.Two indica rice cultivars with different amylose content(Zhongjiazao17,ZJZ17,high amylose content;Xiangzaoxian45,XZX45,low amylose content)were grown under control(CK),HT,and HT+SL conditions during grout filling to determine the effects on grain yield and quality of rice.The results showed that compared with CK,HT and HT+SL significantly reduced the 1000-grain weight and filled grain rate whether in high or low amylose content early indica rice cultivars during grout filling,resulting in a significantly lower grain yield.Meanwhile,HT and HT+SL significantly decreased the milled rice rate,brown rice rate and head rice rate,whereas significantly increased chalky rate and chalky degree;and breakdown decreased and setback,pasting temperature increased in the cultivars,leading to the poor processing,appearance and cooking and eating quality of early indica rice cultivars.Compared with HT,the yield of ZJZ17 was significantly decreased under HT+SL,due to the lower 1000-grain weight.However,the effect of HT+SL on rice quality varied in the cultivars.In general,the yield and rice quality of ZJZ17 were relatively poor under HT+SL.Our results suggested that HT and HT+SL during grout filling had significant damage to the yield and quality of early indica rice cultivars,especially HT+SL,while the high amylose cultivar ZJZ17 showed a higher negative effect under HT+SL.

Blue light induced retinal oxidative stress:Implications for macular degeneration

A number of studies have shown that oxidative stress can be harmful for the retina. The real causal circumstances that lead to degenerative diseases like age related macular degeneration remain obscure. Whether light induced radical stress is a direct interaction of light with photoreceptors or a secondary mechanism within the pigment epithelium or choroid is in discussion. Among the molecular mechanisms involved are production of reactive oxygen species(ROS), secondary lipid peroxidation, protein oxidation and DNA-damage. The initial trigger to write this review was first a recent finding of our group that the photoreceptor outer segments produce great amounts of ROS and second the detection of ectopic enzymes of the respiratory chainlocalized there- in addition to the hitherto known ROS sources like the visual pigments with their intermediates and the photoreceptor mitochondria harbouring the respiratory chain.

弱光胁迫对不同甜瓜品种果实生理特性的影响

【目的】为揭示弱光胁迫对不同品种甜瓜果实主要品质特征的影响。【方法】研究‘西洲蜜1号’、‘早皇后’、‘伽师’3个甜瓜品种在不同光照条件(100%、42%、23%透光率)下,其果实不同部位(果梗、果基、果肉)碳水化合物、类胡萝卜素和叶绿素含量在不同发育时期(花后0、3、7、14、21、35、40、60 d)的变化。【结果】甜瓜果实淀粉、蔗糖、还原糖含量在果实发育过程中不断增加,且在成熟期(花后35 d)含量最高,其中‘西洲蜜1号’淀粉含量最高(10.835%),‘伽师’淀粉含量最低(8.342%)。3个甜瓜品种果肉和果基部分的蔗糖含量比果梗高,但还原糖含量无差异;类胡萝卜素和叶绿素含量在果实发育过程中增加,但在完熟期(花后60 d)下降。弱光胁迫显著降低甜瓜果实碳水化合物含量,增加类胡萝卜素和叶绿素含量,其中透光率23%处理影响最为显著,‘西洲蜜1号’甜瓜淀粉、蔗糖、还原糖含量最高降低了32.3、29.87、28.02,胡萝卜素、叶绿素含量增加了19.47、13.98%;‘早皇后’甜瓜淀粉、蔗糖、还原糖含量最高降低了32.63、25.09、20.24%,胡萝卜素、叶绿素含量增加了54.74、21.06%;‘伽师’甜瓜淀粉、蔗糖、还原糖含量最高降低了41.08、32.39、39.1%,胡萝卜素、叶绿素含量增加了55.20、31.79%。与‘西州蜜1号’和‘早皇后’甜瓜相比,‘伽师’甜瓜的淀粉、叶绿素含量最低,蔗糖、还原糖含量最高,弱光胁迫下其淀粉、蔗糖、还原糖量下降最为显著,类胡萝卜素和叶绿素含量增加最为显著,表明‘伽师’甜瓜受弱光胁迫影响最大,耐弱光性最差。【结论】弱光胁迫会降低甜瓜果实的商业品质,透光率越低品质降低越严重,而‘伽师’甜瓜对弱光胁迫最敏感。

基于光合突变池的雨生红球藻优异性状藻株挖掘

雨生红球藻(Haematococcus pluvialis Flotow)是天然虾青素的主要来源,其高成本、低效率的规模化生产难以满足市场需求。建立快速获得优质突变株的筛选策略有助于提高雨生红球藻的种质资源开发效率,获得虾青素高富集的优质藻株。以雨生红球藻NIES-144为出发藻株,通过甲基磺酸乙酯(ethyl methylsufone,EMS)诱变和高光处理获得光合突变池。以叶绿素荧光参数为检测指标能够快速筛选出生长速率和虾青素积累能力发生变化的突变藻株。结果显示,从该光合突变池中随机选取11株藻株的增殖能力和虾青素积累能力均与原始对照株存在不同程度的差异,45%的突变株在增殖能力和虾青素积累能力方面显著优于对照株。该结果表明雨生红球藻的光化学活性与增殖和其虾青素积累能力之间存在着紧密的联系,证实基于光合突变池挖掘优异性状雨生红球藻的策略具有可行性,为微藻优良藻株的获取提供新思路。

用于应力双折射分布测量的多构型扫描系统设计

为了实现对不同构型光学样品进行应力双折射分布测量,在使用双弹光调制方法的基础上,设计了一种应用于双折射分布测量的多构型扫描系统。该系统在保证测量的高分辨率的同时,通过保持激光器静止,同时使样品进行快速移动,提高了测量精度与广度。在样品测量方面,采用633 nm(1/4)玻片测试,测试相对误差的范围为0.79%~0.95%,波动范围为0.12 nm,标准差为0.0352;采用BK7玻璃样品测试,波动范围为0.25 nm,标准差为0.0389。在扫描精度方面,连续扫描精度误差不超过0.05 mm,连续寸动扫描精度误差不超过0.009 mm。对比实验结果可得出,该多构型扫描系统可有效解决对样品任一区域实现高精度应力双折射测量的问题。

生肌玉红膏联合威伐光治疗3期压力性损伤的疗效观察

目的观察生肌玉红膏联合威伐光治疗3期压力性损伤的疗效。方法选取2019年8月至2022年12月期间我院3期压力性损伤患者90例(共计患处105处),按随机数字表法分为生-威组(生肌玉红膏+威伐光照射)30例(35处),生-紫组(生肌玉红膏外敷+紫外线照射)30例(37处)和生肌玉红膏组(生肌玉红膏外敷)30例(33处)。对比观察3组患者压力性损伤伤口面积、24 h渗液量及伤口床组织类型评分。结果治疗前3组患者压力性损伤伤口面积、24 h渗液量及伤口床组织类型评分均无统计学意义(P>0.05),治疗后3组患者伤口面积评分、24 h渗液量评分、伤口床组织类型评分均低于治疗前,且生-威组低于其他两组,生-紫组低于生肌玉红膏组(P<0.05)。结论生肌玉红膏联合威伐光治疗对3期压力性损伤的改善幅度最大,可有效促进压力性损伤创面的愈合。

镉胁迫对黄秋英生理及富集特性的影响

为给土壤镉(Cd)污染地区提供具有景观修复性的植物修复材料,本试验采用盆栽方法,研究不同质量浓度镉(0、0.3、3、30、60、120、180 mg/kg)对黄秋英(Cosmos sulphureus)植株生理及富集特性的影响。结果表明:胁迫15 d时,随着镉浓度增加,黄秋英叶片可溶性蛋白、叶绿素a、叶绿素b、类胡萝卜素含量和SOD活性均呈先升后降趋势,MDA含量逐渐下降,POD活性先降后升;ETR、qP、Tr在镉浓度0.3 mg/kg时达到最高,Pn与Gs在镉浓度3 mg/kg时达到最高,NPQ在镉浓度30 mg/kg时降到最低,Fv/Fm在镉浓度60 mg/kg时达到最高,Fo在镉浓度180 mg/kg时降到最低。胁迫30 d时,其可溶性蛋白含量、SOD活性先升后降,MDA含量先升后降再升高,POD活性先降后升再下降,叶绿素a、叶绿素b、类胡萝卜素含量先降后升;镉浓度0.3 mg/kg时Fv/Fm达到最高,镉浓度3 mg/kg时NPQ达到最高,而Tr、Pn、Gs降到最低,镉浓度30 mg/kg时qP达到最高、Fv/Fm降到最低,镉浓度60 mg/kg时Pn、Gs达到最高,而Fo、NPQ降到最低,镉浓度120 mg/kg时Ci降到最低,镉浓度180 mg/kg时Tr、ETR达到最高。镉浓度<180 mg/kg时,黄秋英各器官镉含量表现为茎>根>叶;镉浓度≥180 mg/kg时为根>茎>叶。镉浓度≥120 mg/kg时黄秋英根、茎及地上部镉含量均超过镉超富集植物的临界值。综上看出,黄秋英在高浓度镉胁迫下具有较高的耐受力,同时具备较强的镉富集能力,可作为具有景观修复性的植物修复材料。

外源生长调节物质对低温弱光胁迫下辣椒幼苗生长的影响

为研究外源生长调节物质对低温弱光胁迫下辣椒幼苗形态和生理指标的影响,以兴蔬301为试材,采用0.1μmol·L^(-1)的油菜素内酯(BRs)、100μmol·L^(-1)的褪黑素(MT)、500μmol·L^(-1)的水杨酸(SA)、100μmol·L^(-1)的脱落酸(ABA)、300 mg·L^(-1)的6-苄基腺嘌呤(6-BA)、100μmol·L^(-1)的茉莉酸甲酯(MeJA)、20μmol·L^(-1)的独角金内酯(GR24)7种外源生长调节物质处理辣椒幼苗。结果表明:与常温对照相比,低温弱光胁迫下辣椒幼苗的壮苗指数显著降低,叶片中可溶性糖、脯氨酸和丙二醛含量显著增加;叶绿素含量和过氧化氢酶活性显著下降。与低温弱光对照相比,各外源生长调节物质处理的幼苗壮苗指数和叶片可溶性糖、脯氨酸、叶绿素含量及过氧化氢酶活性明显增加,丙二醛含量降低,叶绿素荧光参数F_(v)/F_(m)和光化学猝灭系数(qP)升高,非光化学猝灭系数(NPQ)降低。但不同外源生长调节物质缓解低温弱光胁迫效果有差异,ABA、MT、GR24效果更好。外源生长调节物质处理在低温弱光胁迫前期(5 d)效果明显,恢复生长5 d后差异不显著。表明低温弱光胁迫会影响辣椒幼苗生长,外源生长调节物质处理在早期能有效缓解逆境胁迫对辣椒幼苗的伤害;不同外源生长调节物质处理效果有差异,ABA、MT和GR24能显著增强辣椒幼苗的耐低温弱光能力,其中100μmol·L^(-1)的ABA效果最佳。

绿光辐照度对红鳍东方鲀视网膜、视蛋白基因及氧化应激的影响

为探讨红鳍东方鲀(Takifugu rubripes)在室内养殖中的适宜光照条件,将其分别置于5种绿光辐照度(G1∶300 mW/m^(2)、G2∶500 mW/m^(2)、G3∶750 mW/m^(2)、G4∶1000 mW/m^(2)和G5∶1500 mW/m^(2))及白光(W)和黑暗(D)环境下,进行为期60 d的养殖试验,观察其视网膜结构,并测定视网膜厚度、视蛋白基因的表达及抗氧化酶活性的变化。结果显示:不同绿光辐照度未对幼鱼的视网膜结构产生明显影响。视网膜厚度变化在不同区域之间呈现不同趋势,其中G3组幼鱼的感光层占比(PRos/is/TT)最高(P<0.05),外网层占比(OPL/TT)显著高于除G1组外的其他各组(P<0.05);G2和G3组幼鱼的外核层占比(ONL/TT)显著高于G1和G4组(P<0.05)。视蛋白基因表达方面,W组和D组的视杆视蛋白(Rod opsin)基因表达量最高(P<0.05);G3组的短波蓝色敏感视蛋白(SWS2)基因表达量最高(P<0.05);视蛋白3(Opsin3)在W组和G5组的基因表达量最高(P<0.05)。对于抗氧化酶活性,绿光处理组的超氧化物酶(SOD)、过氧化氢酶(CAT)和谷胱甘肽过氧化物酶(GPX)活性随辐照度增加而升高。研究表明,在室内养殖环境中建议选用表面白色的养殖载体,并采用绿光光照条件养殖红鳍东方鲀幼鱼,控制辐照度在500~750 mW/m^(2)范围内。

R∶FR值对盐胁迫下银杏幼苗生长及光合生理的影响

【目的】设置不同比例红光与远红光环境,研究其对盐胁迫下银杏幼苗生长及光合特性的影响,为深入探究通过光质调节提高银杏抗盐性的机制提供理论依据。【方法】以当年生银杏实生苗为研究对象,设置4个处理,分别为对照CK(0 NaCl,红光与远红光之比为7,即R∶FR=7)、T1(0.3%NaCl,R∶FR=7)、T2(0.3%NaCl,R∶FR=1.2)、T3(0.3%NaCl,R∶FR=0.8),测定处理14、28、42 d的光合色素含量及相对电导率,于42 d试验结束时测定生长指标、叶片形态和光合指标,分析R∶FR值对盐胁迫下银杏幼苗生长发育及光合能力的影响。【结果】与CK相比,T1、T2处理下银杏幼苗各生长指标均显著下降,T3处理下银杏幼苗叶片鲜、干质量相较T1处理有显著提升。叶片形态参数中,各盐处理相较CK叶面积、叶片周长、叶宽及叶长均出现下降,T1处理下降幅度最大;随着R∶FR值的降低,盐胁迫对银杏幼苗叶片生长抑制减轻。随着胁迫时间的延长,各盐处理的叶片相对电导率均呈上升趋势,T3处理上升幅度最小。不同处理下银杏幼苗叶片叶绿素a(Chla)、类胡萝卜素(Car)和叶绿素a/b(Chla/b)随时间变化总体呈现先降后升的趋势,而叶绿素b(Chlb)和总叶绿素(Chla+b)则呈现相反的变化趋势;各处理组Chla+b含量整体表现为CK>T3>T2>T1,处理42 d后,不同处理间Chla/b表现为CK>T3>T1>T2。光合气体交换参数及光响应曲线特征参数中,T3处理下叶片净光合速率(Pn)、最大净光合速率(P_(n,max))及内禀量子效率(φ_(0))相较CK无显著差异,相较T1处理显著升高;随着光环境中R∶FR值的降低,盐胁迫下银杏幼苗暗呼吸速率(R_(d))、光补偿点(I_(c))显著提升。【结论】随着光环境中R∶FR值的降低,盐胁迫对银杏幼苗的生长、膜系统的损伤、呼吸及光合特性的抑制作用得到了有效缓解;且当R∶FR为0.8时,光合性能得到显著提升,缓解效果最佳。

不同胶结剂和骨料类型混凝土受压疲劳性能试验及寿命预测模型

为研究不同胶结剂和骨料类型对混凝土受压疲劳性能的影响,采用3种胶凝材料:普通硅酸盐水泥(ordinary portland cement,OPC);由30%OPC,20%粉煤灰(fly ash,FA)和50%磨细矿渣(ground granulated blast-furnace slag,GGBS)组成的高掺量辅助胶凝材料(supplementary cementitious material,SCM);由50%FA和50%GGBS组成,并掺入Na_(2)SiO_(3)和Ca(OH)_(2)的碱激发剂胶凝材料(alkali-activator,AA),试验制作了天然骨料混凝土(normal-weight concrete,NWC)和轻质骨料混凝土(light-weight concrete,LWC),开展恒应力循环压缩试验。最大应力水平设置3个等级,分别为混凝土静态单轴抗压强度的75%,80%和90%,而最小应力水平固定为静态抗压强度的10%。基于对试验结果的回归分析,建立了疲劳寿命和疲劳应力-应变曲线模型。结果表明,LWC的疲劳寿命略低于NWC,LWC的疲劳应变高于NWC,且与OPC混凝土相比,对于SCM或AA混凝土以上规律更加凸显。本文提出的不同胶结剂和骨料类型混凝土的改进疲劳应力-应变模型,具有计算精度高、计算过程简单、不需要繁琐迭代计算的优势。研究成果可为预测轻骨料混凝土疲劳应力-应变曲线及疲劳寿命提供一套新的方法。

强光胁迫对转玉米C_(4)型ZmPEPC+ZmPPDK基因小麦光合和生理特性的影响

为研究转玉米C_(4)型PEPC(磷酸烯醇式丙酮酸羧化酶基因)和PPDK(丙酮酸磷酸双激酶基因)双基因小麦对强光胁迫的光合和生理响应,以转ZmPEPC+ZmPPDK基因小麦株系PCK30和PCK60及其野生型对照材料(WT)为试验材料,鉴定了外源基因在转基因小麦中的表达量,在抽穗期和灌浆期测定正常光强(NL)和强光胁迫(HL)处理下转基因小麦的光合酶活性、叶绿素含量、气体交换参数、叶绿素荧光参数、活性氧物质含量和抗氧化酶活性。结果表明,2个转基因株系在转录水平上高效表达了PEPC和PPDK基因。在不同时期NL和HL处理下,转基因小麦的PEPC、PPDK、NADP-ME和Rubisco的酶活均显著高于WT,且HL处理下高出WT的幅度更明显。与NL处理相比,转基因小麦和WT的叶绿素含量在HL处理下显著降低,但转基因株系的下降幅度更小,且HL处理下转基因株系的叶绿素含量显著高于WT。两种水平处理下,转基因小麦PCK30、PCK60的净光合速率(P_(n))均显著高于WT,且HL处理下高出幅度更明显,抽穗期增幅分别为15.26%和17.57%,灌浆期为13.41%和15.82%。气孔导度、F_(v)/F_(m)、q_(p)的变化趋势与P_(n)一致,胞间二氧化碳浓度的变化趋势与P_(n)相反。转基因株系在HL处理下产生的活性氧物质和丙二醛含量显著低于WT,而抗氧化酶变化趋势与之相反。连续2年田间小区产量试验,转基因小麦PCK30和PCK60平均比WT高8.37%和10.16%。PEPC和PPDK在小麦中的过表达增强了小麦内源的光合酶、光化学效率和抗氧化酶活性,增强了强光下的叶片细胞膜的稳定性,保护了光合机构,维持了较高的光合效率,从而提高了转基因小麦的耐强光胁迫能力。

玉米黄质对低温弱光下辣椒光合能力和叶黄素循环的影响

为进一步探究玉米黄质对辣椒低温弱光耐受性的影响,以低温敏感性辣椒‘航椒2号’为试验材料,通过叶面喷施玉米黄质,研究其对低温弱光(15℃/5℃,100μmol·m^(-2)·s-1)胁迫下辣椒光合作用关键酶活性、叶绿素荧光参数、内源激素含量、叶黄素循环及相关基因表达量的影响,探究玉米黄质缓解辣椒幼苗低温弱光胁迫的生理机制。结果表明:喷施玉米黄质显著提高辣椒幼苗低温弱光下的光合能力,PSⅡ最大光化学量子产量(F_(v)/F_(m))、实际光化学量子产量Y(Ⅱ)分别显著提高5.90%和54.33%,处理后168 h茉莉酸(JA)和生长素(IAA)含量分别显著增加16.70%和62.30%;辣椒幼苗花药黄质、紫黄质、叶黄素和玉米黄质含量分别增加了1.06、0.48、0.19倍和1.57倍,同时在胁迫处理24、48、168 h时CaZEP基因表达量分别显著增加了3.44、1.64倍和5.50倍,而CaVDE基因表达量与对照相比未达到显著性差异。综上所述,喷施玉米黄质可能通过增强低温弱光下辣椒幼苗光合能力、调控激素代谢以及促进辣椒幼苗启动叶黄素循环来提高辣椒幼苗对低温弱光胁迫的耐受性。

PEG-6000胁迫对五裂茶藨子生长和光合荧光特性的影响

研究干旱胁迫对五裂茶藨子生长和光合荧光特性的影响,以五裂茶藨子幼苗为材料,通过不同浓度(10%、20%和30%)PEG-6000模拟干旱胁迫试验,检测五裂茶藨子生长指标、光和参数和叶绿素荧光参数的动态变化。结果表明:随着PEG-6000浓度和胁迫天数的增加,五裂茶藨子幼苗的株高、地径、相对叶绿素和叶片数量均呈下降趋势;光和参数Pn、Sn、Gs呈下降趋势,而胞间Ci则呈上升趋势;叶绿素荧光参数、Fv、qP、Fv/Fm、Fv/F0和Y(Ⅱ)五个指标均呈下降趋势,qNP和F0则呈逐渐上升的趋势。所以,在干旱持续增加的环境中,五裂茶藨子主要通过改变生长状况及光合和荧光特性的变化来应对干旱胁迫。