顽拗性黄皮种子脱水过程中活性氧清除酶活性的变化

以正常性种子花生为对照,研究了顽拗性黄皮种子脱水过程中活性氧清除酶、膜脂过氧化作用以及电解质渗漏率的变化。随着含水量的下降,黄皮胚的电解质渗漏率和膜脂过氧化产物丙二醛(MDA)含量均显著增加;当黄皮胚含水量下降至40％后,SOD活性开始急剧下降,而POD和CAT活性在胚含水量下降过程中呈现出缓慢下降的趋势。花生胚在含水量从45％降至14％的过程中,电解质渗漏率没有明显增加,MDA含量只有少量增加;当含水量降至14％后,电解质渗漏率出现少量增加。花生胚脱水初期,活性氧清除酶活性明显增加,并在整个脱水过程中维持较高的水平。以上结果表明顽拗性种子黄皮的脱水敏感性与活性氧清除酶相对活性变化有关。脱水引起黄皮胚活性氧清除酶活性降低,活性氧清除能力下降,膜脂过氧化作用加强,膜透性增大。黄皮胚的膜系统可能是脱水伤害的靶位之一。     

顽拗性黄皮种子税水过程中活性氧清除酶活性的变化

以正常性种子花生为对照,研究了顽拗性黄皮种子脱水过程中活性氧清除酶、膜脂过氧化作用以及电解质渗漏率的变化。随着含水量的下降,黄皮胚的电解质渗漏率和膜脂过氧化产物丙二醛（MDA）含量均显著增加;当黄皮胚含水量下降致40％后,SOD活性开始急剧下降,而POD和CAT活性在胚含水量下降过程中呈现出缓慢下降的趋势。花生胚在含水量从45％降至145的过程中,电解质渗漏率没有明显增加,MDA含量只有少量增加;当含水量降至14％后,电解质渗漏率出现少量增加,花生胚脱水初期,活性氧清除酶活怀明显增加,并在整个脱水过程中维持较高的水平。以上结果表明：顽拗性处子黄皮的脱水敏感性与活性氧清除酶相对活性变化有关。脱水引起黄皮胚活性氧清除酶活性降低,活性氧清除能力下降,膜脂过氧化作用加强,膜透性增大。黄皮胚的膜系统可能是脱水伤害的靶位之一。     

体细胞胚发生的生化基础

在胚性细胞分化和分裂过程中ATP酶活性和分布的动态变化表明,这些胚性细胞进行着旺盛的主动物质吸收和活跃的新陈代谢过程。在多种植物的体细胞胚发生中过氧化物酶的活性与同工酶的种类都高于对照,而且在大麦中发现过氧化物酶、酯酶和酸性磷酸酶同工酶的结合应用可以作为体细胞胚发生的标志酶。胚性愈伤组织中可溶性蛋白质含量与组分远高于或多于非胚性愈伤组织。大多数材料中都存在45kD-55kD的胚胎发生特异性蛋白质组分。而且在体细胞胚发生中蛋白质和核酸代谢动态呈规律性变化,首先是RNA合成速率增加,继而是蛋白质的迅速合成,并在胚性细胞分化和发育过程中一直保持相对较高水平,其中mRNA种类丰富,不同发育时期mRNA种类不同,因此转译形成多种蛋白质。DNA的代谢相对较稳定,但在胚性细胞系中DNA合成量仍高于非胚性细胞系。加入蛋白质或核酸合成抑制剂,不仅抑制了蛋白质和核酸的合成,同时也抑制了体细胞胚的发生与发育,而且抑制剂加和时间愈早,影响愈严重。由此表明,蛋白质与核酸的合成为体细胞胚的分化和发育奠定了分子基础。     

成熟脱水对种子发育和萌发的作用

成熟脱水是正常性种子发育的末端事件。种子在成熟时胚的脱水耐性增加;当种子萌发时胚变得不耐脱水。当种子获得脱水耐性时,糖、蛋白质和抗氧化防御系统等保护性物质积累;当脱水耐性丧失时,这些物质被降解。成熟脱水是种子从发育过程向萌发过程转变的“开关”,它降低发育的蛋白质和mRNA的合成,终止发育事件和促进萌发事件。顽拗性种子不经历成熟脱水的发育阶段,对脱水高度敏感。     

成熟脱水对种子发育和萌发的作用

成熟脱水是正常性种子发育的末端事件。种子在成熟时胚的脱水耐性增加;当种子萌发时胚变得不耐脱水。当种子获得脱水耐性时,糖、蛋白质和抗氧化防御系统等保护性物质积累;当脱水耐性丧失时,这些物质被降解。成熟脱水是种子从发育过程向萌发过程转变的“开关”,它降低发育的蛋白质和ｍＲＮＡ的合成,终止发育事件和促进萌发事件。顽拗性种子不经历成熟脱水的发育阶段,对脱水高度敏感。     

脱落酸对发育中花生胚萌发和贮藏蛋白质合成的影响

发育中的花生胚在无激素固体培养基上高体培养时提前萌发,其发芽力随胚的成熟增加而提高。果针入土后40d胚的发芽率达100％。禹体培养过程中,外源ABA能够阻止花生胚提前萌发和促进胚的发育。胚成熟前期,较低浓度的ABA(10~(-5)mol/L)便抑制胚的萌发;而在成熟中期以后,则要求较高浓度的ABA(10~(-4)mol/L)才能抑制胚的萌发。ABA对成熟前期胚的贮藏蛋白质合成无影响,而对成熟中期至后期胚的贮藏蛋白质合成起促进作用。ABA维持花生胚贮藏蛋白质合成和积累的作用表现在转录水平上。     

杉木雌配子体与后胚发育过程中核酸、蛋白质和类脂的消长

在杉木胚胎分化期至成熟期,每个雌配子体总核酸和DNA,RNA含量在初期增加,后期则随着胚的分化发育逐渐下降,而蛋白质和类脂则一直上升。每胚总核酸、DNA,RNA则相应增加,而蛋白质、类脂的含量和干重亦逐渐增加。在胚分化早期RNA的迅速合成与细胞的分化及器官形成有关。但以胚干重为单位的DNA、RNA含量却随着胚的发育而有所减少;蛋白质含量先增加,至成熟后才下降。授粉前的胚珠,以及雌配子体、胚中都发现有凝集素存在。     

玉米花粉胚状体发育过程中DNA,RNA蛋白质含量及合成动态变化

继代培养的玉米花粉胚状体的发育过程可划分为6个时期:胚性细胞团时期、球形胚时期、心形胚时期、梨形胚时期、子叶形胚时期以及分化期。我们应用微量生化分析技术以及放射性同位素液体闪烁计数技术研究了玉米花粉胚状体发育过程的DNA、RNA、蛋白质含量及合成动态,发现DNA、RNA和蛋白质含量在胚性细胞团期较高,然后下降,但到了分化期时又有所升高。DNA合成速度在胚性细胞团时期较高,在以后的各时期降低并保持平稳。RNA和蛋白质的合成动态呈相似的变化规律。这个结果说明DNA、RNA和蛋白质在胚状体发育早期的活跃代谢,可能与胚性细胞的快速分裂以及胚性结构的形成有关,而后期的活跃代谢可能与胚状体的分化有关。     

脱水敏感的黄皮种子在发育中的可溶性蛋白变化

黄皮种子的子叶与胚轴,在发育前期蛋白质合成速率均高于后期。在发育过程中子叶的可溶性蛋白含量无明显变化,但在后期能新合成少数低分子量的热不稳定蛋白,可能是引起种子萌发的水解酶类。胚轴中可溶性蛋白单位干重含量高于子叶,而其成分不随发育而变化。ABA可促进发育后期黄皮种子胚轴中20kD蛋白的合成,但不能改变种子的脱水敏感性。     

玉米种子萌发能力和耐脱水能力的形成

以玉米品种“粤单9117”为材料,研究了种子发育过程中萌发能力和耐脱水能力的获得。玉米种子的生理成熟期约为43DAP（授粉后天数）。胚萌发能力的获得是在14－21DAP、耐脱水能力的获得出现在25－28DAP。胚的耐脱水能力在28DAP后仍不断得到加强。耐脱水能力的获得与细胞膜的发育及受保护的程度密切相关。脱水有利于不同发育时期的胚和种子的萌发。     

黄皮种子线粒体呼吸速率和活性氧清除酶活性对脱水的响应及其生态学意义

顽拗性种子脱落时具有较高的含水量和代谢活性, 对脱水高度敏感; 但顽拗性种子脱水敏感性的机理至今仍然不清楚。该文以顽拗性黄皮(Clausena lansium)种子为材料, 研究了种子和胚轴对水分丧失的响应, 在脱水过程中胚轴和子叶的呼吸速率, 胚轴和子叶线粒体的细胞色素c氧化酶(CCO)活性、外膜完整性、CCO和交替氧化酶(AOX)途径以及线粒体活性氧清除酶活性的变化。结果表明, 随着水分的丧失, 种子和胚轴的存活率逐渐下降, 种子的脱水敏感性大于胚轴; 胚轴和子叶的呼吸速率以及线粒体外膜的完整性降低。胚轴和子叶线粒体的CCO途径以及胚轴AOX途径的呼吸速率在脱水初期增加, 随着继续脱水下降, 胚轴线粒体AOX途径的呼吸速率则随着脱水显著下降。胚轴线粒体的超氧化物歧化酶(SOD)、抗坏血酸过氧化物酶(APX)和谷胱甘肽还原酶(GR)活性和子叶线粒体的APX活性随着脱水迅速下降; 胚轴线粒体的脱氢抗坏血酸还原酶(DHAR)活性和子叶线粒体的SOD、DHAR和GR活性在脱水初期增加, 然后下降。这些数据表明黄皮种子的脱水敏感性与线粒体的呼吸速率和活性氧清除酶的活性降低密切相关, 也与长期适应热带/亚热带的生境有关。     

Response of Chinese Wampee Axes and Maize Embryos to Dehydration at Different Rates

Survival of wampee (Clausena lansium Sksels) axes and maize (Zea mays L.) embryos decreased with rapid and slow dehydration. Damage of wampee axes by rapid dehydration was much less than by slow dehydration, and that was contrary to maize embryos. The malondialdehyde contents of wampee axes and maize embryos rapidly increased with dehydration, those of wampee axes were lower during rapid dehydration than during slow dehydration, and those of maize embryos were higher during rapid dehydration than during slow dehydration. Activities of superoxide dismutsse (SOD), ascorbate peroxidase (APX) and catalase (CAT) of wampee axes markedly increased during the sady phase of dehydration, and then rapidly decreased, and those of rapidly dehydrated axes were higher than those of slow dehydrated axes when they were dehydrated to low water contents. Activities of SOD and APX of maize embryos notable decreased with dehydration. There were higher SOD activities and lower APX activities of slowly dehydrated maize embryos compared with rapidly dehydrated maize embryos. CAT activities of maize embryos markedly increased during the eady phase of dehydration, and then decreased, and those of slowly dehydrated embryos were higher than those of rapidly dehydrated embryos during the late phase of dehydration.     

花生种子老化相关蛋白质的初步研究

本文以粤油 116花生(Arachis hypogaea L.)为材料,对不同处理种子的除子叶“种胚”(以下简称“种胚”)的蛋白质进行了研究.实验结果表明,当花生种子活力下降到一定程度时,其“种胚”内出现一种新蛋白质( pI6.2、MW 10 KD),随种子老化程度加深,含量逐渐增多.我们认为该蛋白质与花生种子老化存在着一定的相关关系,可作为该种子老化的标志.     

提高黄皮种子活力的途径

黄皮种子经脱水至40％左右或持续贮藏（一年以上）后种子活力迅速下降,PEG对劣变种子直接引发不但不能提高其活力,反而使其活力更为下降,甚至丧失萌发能力而引发加速了代谢物质的消耗和渗漏。在黄皮种子脱水前用ABA、Ca2 、茶多酚（抗氧化剂）预处理,明显降低了黄皮种子的脱水敏感性。结合用PEG引发技术,则能较大幅度提高黄皮种子脱水后的活力,Ca2 短时高温引发也能提高黄皮种子贮藏一年后的活力,说明预处理是提高脱水和贮藏后黄皮种子活力的必要措施。     

Cytological and physiological changes related to cryotolerance in recalcitrant <Emphasis Type="Italic">Livistona chinensis</Emphasis> embryos during seed development

Cytological and biochemical changes in recalcitrant Livistona chinensis embryos following the acquisition and loss of cryotolerance to liquid nitrogen during seed development were studied. The embryonic cells were always hydrated and contained fully functional organelles throughout seed development. However, the central cells in the root-epicotyl end of the embryo exhibited partial dedifferentiation during the middle developmental stages, although extensive reduction of mitochondria and vacuolation and intensive accumulation of starch grains, lipid, and protein bodies were not observed. Total soluble sugar content rose then decreased on a fresh weight and water weight basis, while soluble and heat-stable proteins increased in number and content then decreased, as seeds matured. These cytological and biochemical features differ from those of orthodox seeds, providing a physiological basis for the recalcitrant behavior of L. chinensis seeds. The changes were closely correlated with acquisition and loss of cryotolerance in L. chinensis embryos and are presumed to contribute to cryotolerance, which would account for the cryotolerance variation in L. chinensis embryos. Cryotolerance is suggested to be a complex, multifaceted process, and accumulation of soluble sugars and soluble and heat-stable proteins alone is not enough to increase cryotolerance per se without acting in combination with a decrease of cellular metabolic activity.     

Embryogeny of gymnosperms: advances in synthetic seed technology of conifers

Synthetic seed technology requires the inexpensive production of large numbers of high-quality somatic embryos. Proliferating embryogenic cultures from conifers consist of immature embryos, which undergo synchronous maturation in the presence of abscisic acid and elevated osmoticum. Improvements in conifer somatic embryo quality have been achieved by identifying the conditions in vitro that resemble the conditions during in ovulo development of zygotic embryos. One normal aspect of zygotic embryo development for conifers is maturation drying, which allows seeds to be stored and promotes normal germination. Conditions of culture are described that yield mature conifer somatic embryos that possess normal storage proteins and fatty acids and which survive either partial drying, or full drying to moisture contents similar to those achieved by mature dehydrated zygotic embryos. Large numbers of quiescent somatic embryos can be produced throughout the year and stored for germination in the spring, which simplifies production and provides plants of uniform size. This review focuses on recent advances in conifer somatic embryogenesis and synthetic seed technology, particularly in areas of embryo development, maturation drying, encapsulation and germination. Comparisons of conifer embryogeny are made with other gymnosperms and angiosperms.Abbreviations ABA abscisic acid - LEA late embryogenesis abundant - PEG polyethylene glycol - PGR plant growth regulator - RH relative humidity - TAG triacylglycerol     

Developmental Changes in Relation to Desiccation Tolerance of Archontophoenix alexandrae (Palmae) Seeds

Germination of Archontophoenix alexandrae seeds and embryos were studied under gradient water content treatments throughout the seed development phases of maturation in 2005 to investigate seed desiccation tolerance and storage characteristics. During the maturation process, seed water content decreased gradually from55 DAF (days after flowering) to 70 DAF, and seeds reached the maximum dry-weight at 90 DAF. Seed germinability appeared after 60 DAF. Seeds germinated with a temperature range from15℃- 40℃ under alternating photoperiod (14 h light, 10 h dark, 12μmol m^{- 2}s ^{- 1} ), while the best germination percentage was obtained between 30℃- 35℃. A maximum germination capacity reached at 70 DAF. However, seed germination was greatly inhibited by light. Desiccation tolerance of seeds and embryos increasedgradually from 55 DAF to 90 DAF and reached the maximum at 90 DAF with a semilethal water content of 0.18 g/g ( seed) and 0.3 g/g ( embryo) respectively. Rapid dehydration maintained higher seed germination percentage than thatof slow dehydration when drying to the same water content. Seeds with without water content treatments failed to germinate after 1 month storage under - 18℃, whereas appropriate desiccation treatment prolonged seed longevity under 4℃, 10℃ and 15℃ storage temperatures. It revealed obviously the recalcitrant characteristics of Archontophoenix alexandrae seeds torage behaviour which are tolerant toward neither deep desiccation nor low temperatures.     

用DSC法分析黄皮种子的贮藏特性和脱水敏感性

72 DAA是黄皮种子发育过程中的特征时期 .此时期种子的贮藏特性与在此时期前后采收时相比较均有明显差异 ,且其不可冻结水的比例最低 .旺盛的生理代谢和过高的不可冻结水含量维持细胞或生物大分子结构使黄皮种子的生活力依赖于高含量水分 ,可能是黄皮种子脱水敏感性的主要原因 .用 DSC法可以检测黄皮种子在贮藏和脱水过程中种子活力的变化趋势     

脱水速率对黄皮胚轴脱水敏感性及膜脂过氧化的影响

以黄皮种子离体胚轴为材料,研究了不同干燥速率对胚轴脱水反应和膜脂过氧化的影响.在脱水过程中,胚轴的萌发率、活力指数、电解质渗漏速率,超氧化物歧化酶(SOD)、过氧化物酶(POD)和过氧化氢酶(CAT)活性逐渐降低,膜脂过氧化产物MDA的含量不断增加.脱水速率愈快,胚轴的半致死含水量就愈低.快速干燥的胚轴能在较低的含水量下存活是因为缩短了在中间含水量下发生的膜脂过氧化作用的时间,以及保持较高的SOD、POD和CAT活性;缓慢干燥的胚轴当与周围环境达到水分平衡后,生活力的丧失将与保持在水分平衡后的时间有关.因此,脱水速率是一种影响顽拗性种子或者胚轴脱水敏感性的重要因子.