荔枝胚蛋白质的提取方法

以不同体积的Tris-HCl(0.1mol／L,pH8．8)为提取液,结合不同含量(以胚鲜重计)的PVP40,对怀枝、黑叶和桂味等荔枝(Lithi chinensis)品种的胚蛋白质进行提取。结果表明,提取液体积为胚鲜重的5倍(ml g-1 FW),并加入15％的 PVP40时,提取蛋白质的效果最好,可用于荔枝胚可溶性蛋白质含量的测定;胚乳蛋白质的提取则以等体积的提取液(内含2％的PVP40)为佳。加入10% PVP40的胚蛋白提取液可直接进行SDS-PAGE电泳,用10倍于蛋白质提取液体积的乙醇沉淀胚和胚乳的蛋白提取液,可得到最佳的SDS-PAGE电泳效果。     

焦核与大核龙眼雌配子体发育、授粉受精及早期胚胎发育的比较研究

利用人工授粉,采用压片法对大核龙眼‘九月乌’和焦核龙眼‘闽焦64-1’、‘闽焦64-2’、‘白核’等的自交与杂交后花粉管的生长特性进行研究,同时应用常规石蜡切片技术对大核与焦核龙眼的雌配子体以及合子胚早期发育进行观察。结果表明,龙眼胚珠在单核胚囊形成前就开始败育,且焦核品种(系)的败育率显著高于大核品种。不同亲本组合的授粉率存在差异,所有授粉组合在授粉36～48 h后均能观察到1个花粉管生长并进入胚囊受精。焦核品种(系)的胚胎在谢花后10 d开始败育,且败育率明显高于大核品种。受精是龙眼子房发育的首要条件,胚珠败育的雌蕊在谢花后10 d不膨大,不能发育形成焦核果实。谢花后10～30 d的早期胚胎败育是形成焦核龙眼的主要原因。焦核品种‘白核’胚乳具有成胚能力。约有24%的‘闽焦64-1’胚珠在胚胎发育过程中,其助细胞、合点端细胞及胚乳发生异常,这可能与早期胚胎败育有关。     

荔枝花蜜分泌规律及可溶性糖组分和含量的分析

为了解荔枝(Litchi chinensis)花蜜的分泌规律和主要组分,对‘糯米糍’、‘桂味’和‘怀枝’3个主栽品种雄花和雌花的花蜜分泌模式进行研究,并测定花蜜中可溶性糖的组分和含量。结果表明,采样期间果园阴天和晴天气温差异不明显,但阴天的相对空气湿度显著高于晴天。总体上阴天的荔枝花蜜分泌量高于晴天,雌花的花蜜分泌量高于雄花,‘桂味’和‘糯米糍’的花蜜分泌量均高于‘怀枝’。晴天花蜜中的可溶性固形物含量高于阴天的,且在雌花中表现尤为明显。‘怀枝’花蜜中的可溶性固形物含量最高,可达37.7%,‘桂味’其次,‘糯米糍’最少(17.7%)。利用高效液相色谱检测,荔枝花蜜中主要可溶性糖组分为葡萄糖、果糖和蔗糖,以葡萄糖含量最高。晴天时‘怀枝’雌花花蜜中可溶性糖含量达450.36μg m L–1,显著高于另外两个品种。这为荔枝栽培和花蜜生产提供科学依据。     

不同荔枝品种采后果实衰老的比较

比较了5个荔枝(Litchi chinensis Sonn.)品种("怀枝"、"糯米糍"、"桂味"、"红蜜荔"和"水晶球")果实采后在常温下的衰老表现.其中,"糯米糍"果实衰老褐变快,而"桂味"衰老最为缓慢.果实褐变过程伴随失水,但品种间脱水速度与果实衰老的速度无显著相关性.果皮的褐变潜力、果皮细胞壁糖醛酸含量、果胶甲酯化程度、果皮和果肉总钙含量、果皮水溶性钙含量与果实衰老均无显著的相关性,但膜透性与坏果率呈显著的正相关,而果皮结构钙与之有显著的负相关性.     

大核和焦核"桂味"荔枝果实发育及其发育期间果皮中内源激素含量的变化比较

同一株大核和焦核"桂味"荔枝的果实生长型均呈"单S型",其果实大小差异主要由种子大小不同引起.果实发育期间,两者果皮中内源激素变化的规律大体上一致,大核果皮中GA3、IAA含量和(IAA ZRs GA3)/ABA比值均高于焦核果皮,但ZRs含量和ZRs/ABA比值则比其低,ABA含量的差异无规律可循.     

寄主植物对荔枝蒂蛀虫产卵的引诱作用

试验观察荔枝蒂蛀虫Conopomorpha sinensisBradley对寄主植物品种、器官及器官部位的产卵选择性规律。结果表明,与老梢相比,荔枝蒂蛀虫明显倾向于选择嫩梢产卵;4个荔枝品种果枝中以妃子笑上落卵数最多,在淮枝、糯米糍荔枝果实上较少,桂味荔枝上最少;不同的荔枝品种果实气味引诱雌虫产卵的能力不同,其中妃子笑引诱力最强,淮枝、糯米糍引诱力较低,桂味最低;在同一荔枝果实不同部位的落卵量,以果皮上、下两部分较大,全果明显低于果皮上部,而荔枝肉和荔枝核上没有落卵。     

不同品种荔枝对荔枝蒂蛀虫引诱活性成分的研究

首次采用顶空单滴液相微萃取(HS-SDME)结合气质联用(GC-MS)法,对比分析对荔枝蒂蛀虫具有不同引诱力的4个品种荔枝(妃子笑＞黑叶＞糯米糍＞桂味)成熟果实的果皮、幼果的挥发性物质.结果表明:挥发物组成和含量在不同荔枝品种间、同一品种荔枝不同组织间差异显著.2-乙基-1-己醇、α-姜黄烯、姜烯、β-甜没药烯、β-倍半水芹烯及β-杜松烯等6个物质主要存在于易感虫荔枝品种中,(E)-β-金合欢烯与(Z)-β-金合欢烯只存在于妃子笑成熟果实的果皮中,故初步推测这8个化合物按照一定比例复配组合后的混合物,可能是荔枝吸引荔枝蒂蛀虫的活性物质.     

荔枝受荔枝蝽危害后对平腹小蜂趋性的影响

采用Y-型嗅觉仪测定了荔枝蝽Tessaratoma papillosa成虫危害后,糯米糍、桂味和三月红3个荔枝品种对平腹小蜂Anastatus japonicus行为的影响。结果发现：只有当超过3头荔枝蝽成虫危害时,糯米糍植株才对平腹小蜂具有较强的引诱效果;三月红健康植株本身对平腹小蜂的引诱效果就较强,对其进行机械损伤或者害虫取食后这种作用有一定程度的增强;而桂味健康植株与机械损伤植株、虫害植株对平腹小蜂行为的影响大致相同。随着荔枝蝽危害时间的延长,以上3个品种都在被害后第2天对平腹小蜂的引诱作用达到最强,此后这种效果逐渐降低。3个品种中三月红植株在虫害后做出反应的速度最快。平腹小蜂对桂味植株的趋性一直处于相对较低的水平。     

水稻胚与胚乳分化发育中的内源多胺

稻胚发育过程中,其内源多胺以腐胺、亚精胺为主。在幼胚分化期,腐胺和亚精胺的含量很高;幼胚分化完成时,其含量急剧下降;直至分化后期才趋稳定。在胚及胚乳发育时期,还出现一种未知多胺X_(22),其含量除在胚分化完成时较少外,在胚发育的其他各期中,含量则一直很高。DNA和蛋白质含量的变化,从分化期开始递增直至物质积累成熟期,其趋势均相同。多胺可能参与胚与胚乳中核酸和蛋白质合成的调节。     

大麦胚和胚乳发育的相关性及贮藏营养物质的积累

大麦(Hordeum vulgare L.)开花后1d,见合子及退化助细胞,游离核胚乳尚未形成;开花后2～3d,胚为5及10个细胞,胚乳为游离核期;开花后4及5、6d,胚为梨形及长梨形,胚乳达细胞化期;开花后8d,胚为胚芽鞘期,糊粉层原始细胞产生;开花后10d,胚具1叶,糊粉层1～2层;开花后13d胚为2叶胚,亚糊粉层发生;开花后17d,3叶胚形成,糊粉层多为3层并停止分裂,菱柱形及不规则胚乳细胞分化;开花后21～29d,胚为4叶胚,胚乳进一步分化;开花后33d,胚为5叶成熟胚,胚乳亦成熟。淀粉、蛋白质在胚中积累始于开花后13d。在盾片中由基向顶发生,在胚芽鞘及叶原基中,首先在顶端出现。成熟盾片顶端的淀粉消失。开花后6d,胚乳开始积累淀粉;开花后10d,糊粉层及胚乳细胞积累蛋白质。开花17d后胚乳的蛋白质体多聚集,29d后蛋白质体显著减少。开花后17d,在盾片及糊粉层细胞中检测到油脂。果长或果长与稃片长之比和盾片长可作为不同发育期胚和胚乳的形态指标。     

Endosperm protein of wheat seed as a determinant of seedling growth

Seed of a Mexican semidwarf wheat (Triticum aestivum L. cv. Inia 66), was obtained from a nitrogen fertilizer field trial grown in Mexico. A high positive correlation was obtained between seed protein content and seedling dry weight after 3 weeks growth (r = +0.92^**). The seedling dry weight was positively related to the protein content of the aleurone layer and endosperm, but not to the embryo. Small, 35 milligrams, high protein seeds (4.7 milligrams protein per seed) produced larger seedlings than large, 45 milligrams, low protein seeds (4.3 milligram protein per seed). There was no difference in the weight or protein content of embryos from low and high protein seeds and their growth was similar. Composite seeds of the two protein levels were produced by transferring embryos from one endosperm type to the other. After 4 weeks, there was no difference between the different embryo types grown on the same endosperm type. High protein endosperm produced more vigorous seedlings regardless of the embryo type grown on it, indicating that the factor(s) responsible for the greater growth of high protein seed is in the endosperm.     

ADVENTIVE EMBRYOGENESIS IN CITRUS (RUTACEAE) II. POSTFERTILIZATION DEVELOPMENT

Cytological and histological studies on postfertilization development of ovules were carried out in six facultatively apomictic Citrus cultivars. At the time of anthesis, adventive embryo initial cells (AEICs) were detected mainly in the cell layers of the nucellus around the chalazal half of the embryo sac. During the approximately 40 days rest period of the AEICs after fertilization, rapid cell division and enlargement in the endosperm and the chalazal half of the nucellus resulted in the split of AEICs into several separated areas forming the micropylar, lateral and chalazal islands surrounding the enlarging embryo sac. Both in diploid seeds with triploid endosperm and triploid seeds with pentaploid endosperm, the AEICs located in the micropylar half successfully developed into adventive embryos. In diploid seeds, almost all AEICs located in the chalazal half did not develop beyond the initial-celled stage, while in the triploid seeds, those located in the chalazal half occasionally developed into cotyledonary embryos. In seeds with aborted endosperm, the AEICs located in the chalazal half often developed into cotyledonary embryos. The chalazal expiants from normal seeds produced a large number of embryos in vitro. Four results can be summarized from these studies on adventive embryogenesis as follows: 1) All AEICs are initiated prior to anthesis. 2) Whether or not the AEICs successfully developed into adventive embryos is dependent upon their position in the seed. 3) The farther the AEICs are located from the micropylar end, the more adventive embryogenesis is suppressed by endosperm. 4) The degree of adventive embryogenesis in the chalazal half is affected by time and extent of malfunction of the endosperm. Under natural conditions, these regulatory systems of adventive embryogenesis contribute to high production of zygotic seedlings in apomictic Citrus species and cultivars.     

Seeds of tomato (Lycopersicon esculentum Mill.) which develop in a fully hydrated environment in the fruit switch from a developmental to a germinative mode without a requirement for desiccation

Seed water content is high during early development of tomato seeds (10–30 d after pollination (DAP)), declines at 35 DAP, then increases slightly during fruit ripening (following 50 DAP). The seed does not undergo maturation drying. Protein content during seed development peaks at 35 DAP in the embryo, while in the endosperm it exhibits a triphasic accumulation pattern. Peaks in endosperm protein deposition correspond to changes in endosperm morphology (i.e. formation of the hard endosperm) and are largely the consequence of increases in storage proteins. Storage-protein deposition commences at 20 DAP in the embryo and endosperm; both tissues accumulate identical proteins. Embryo maturation is complete by 40 DAP, when maximum embryo protein content, size and seed dry weight are attained. Seeds are tolerant of premature drying (fast and slow drying) from 40 DAP.Thirty-and 35-DAP seeds when removed from the fruit tissue and imbibed on water, complete germination by 120 h after isolation. Only seeds which have developed to 35 DAP produce viable seedlings. The inability of isolated 30-DAP seed to form viable seedlings appears to be related to a lack of stored nutrients, since the germinability of excised embryos (20 DAP and onwards) placed on Murashige and Skoog (1962, Physiol. Plant. 15, 473–497) medium is high. The switch from a developmental to germinative mode in the excised 30- and 35-DAP imbibed seeds is reflected in the pattern of in-vivo protein synthesis. Developmental and germinative proteins are present in the embryo and endosperm of the 30- and 35-DAP seeds 12 h after their isolation from the fruit. The mature seed (60 DAP) exhibits germinative protein synthesis from the earliest time of imbibition. The fruit environment prevents precocious germination of developing seeds, since the switch from development to germination requires only their removal from the fruit tissue.Abbreviations DAP days after pollination - kDa kilodaltons - SP1-4 storage proteins 1–4 - SDS-PAGE sodium dodecyl sulphate-polyacrylamide gel electrophoresis - HASI hours after seed isolation - MS medium Murashige and Skoog (1962) medium This work is supported by National Science and Engineering Research Council of Canada grant A2210 to J.D.B.     

Endosperm and Embryo Development in Daucus carota L.

Maximum carrot seed dry weight and maximum endosperm volumewere reached about 35 d after anthesis, although at this timethe endosperm was still soft, the pericarp green and less than50% of the seeds were viable. Fully viable, ripe seeds werenot produced until 44 d later. Seventy per cent of the increasein endosperm volume was due to an increase in cell number, whichceased 35 d after anthesis. The increase in embryo volume wasslower and was due to an increase in both cell number and cellvolume which continued until 49 d after anthesis. At maturitythe embryo was the equivalent of between 2% and 3% of the endospermvolume. The relationship between embryo length and cell number per embryowas unaffected by seed crop plant density, seed crop harvestdate and position of the seed on the mother plant but it wasaffected by the year of seed production, possibly due to differencesin temperature during the period of seed growth. Key words: Endosperm, Embryo, Carrot, Development     

玉米籽粒贮藏蛋白组成及特性的研究

利用等电聚焦（ＩＥＦ）电泳和不连续醋酸尿素聚丙烯酰胺凝胶电泳（ＮＡＵ－ＰＡＧＥ）对玉米籽粒贮藏蛋白的等电点（ｐＩ）和在Ｆ１中的遗传表现以及贮藏蛋白在胚和胚乳中的分布进行研究,结果表明：（１）玉米籽粒贮藏蛋白的ｐＩ在３．５￣８．４５范围内,可分离的有３９条左右,６０％左右的蛋白质属酸性,ｐＩ分布在３．５０－６．８５范围内,４０％左右属中性偏碱,ｐＩ在６．８５－８．４５范围内。（２）籽粒贮藏蛋白在Ｆ１     

Studies on the Structure,Afterripening and Cytochemistry of Seeds in Eleutherococcus brachypus Harms

Seeds of Eleutherococcus brachypus Harms were flat-kidney-shaped and their seed coats were only composed of one layer of cells. Embryos with abundant protein in their cells were just at the heart-shaped stage and were capped by sacs formed from degenerating endosperm cells when seeds shed from their maternal plants. A large amount of stored protein grains and lipids existed in endosperm cells but no polysaccharide grains were present either in endosperm cells or in embryo cells. Viable seeds were only 9.27% of the total. The plump seeds germinated in the cultivated field after 18～19 months and their germinating rate was 1.67%. Besides, the content of protein decreased gradually and a few polysaccharide grains were stored in embryo cells during the process. The afterripening process of seeds stratified at different temperatures ended after 6 months and the cytochemistry features of the seeds were that the content of protein decreased gradually and numerous polysaccharide grains had been stored in embryo cells at the late heart-shaped embryo stage and retained till the mature embryo stage. The structure, afterripening and cytochemistry of seeds were compared between Eleutherococcus brachypus and Eleutherococcus senticosus. The poor quality of the seeds, longer time of afterripening in a natural state and much lower germination rate of E. brachypus are considered to be important reasons for the endangerment of this species. Somemeasures are suggested for its conservation based on the above facts.     

AAP1 regulates import of amino acids into developing Arabidopsis embryos

The embryo of Arabidopsis seeds is symplasmically isolated from the surrounding seed coat and endosperm, and uptake of nutrients from the seed apoplast is required for embryo growth and storage reserve accumulation. With the aim of understanding the importance of nitrogen (N) uptake into developing embryos, we analysed two mutants of AAP1 (At1g58360), an amino acid transporter that was localized to Arabidopsis embryos. In mature and desiccated aap1 seeds the total N and carbon content was reduced while the total free amino acid levels were strongly increased. Separately analysed embryos and seed coats/endosperm of mature seeds showed that the elevated amounts in amino acids were caused by an accumulation in the seed coat/endosperm, demonstrating that a decrease in uptake of amino acids by the aap1 embryo affects the N pool in the seed coat/endosperm. Also, the number of protein bodies was increased in the aap1 endosperm, suggesting that the accumulation of free amino acids triggered protein synthesis. Analysis of seed storage compounds revealed that the total fatty acid content was unchanged in aap1 seeds, but storage protein levels were decreased. Expression analysis of genes of seed N transport, metabolism and storage was in agreement with the biochemical data. In addition, seed weight, as well as total silique and seed number, was reduced in the mutants. Together, these results demonstrate that seed protein synthesis and seed weight is dependent on N availability and that AAP1-mediated uptake of amino acids by the embryo is important for storage protein synthesis and seed yield.     

Cytokinin Activity in Lupinus albus L: IV. Distribution in Seeds

Endogenous levels of cytokinin activity were examined in Lupinus albus L. seed at intervals of 2 weeks after anthesis using the soybean callus bioassay. High levels of cytokinin activity per gram seed material were present in the seeds at 2, 4, and 6 weeks after anthesis. The cytokinin activity per gram seed material was low at 8 and 10 weeks after anthesis. Cytokinin activity associated with each seed was greatest at 6 weeks after anthesis. The majority of the activity in the seeds at 4, 6, and 8 weeks after anthesis was in the endosperm. Cytokinin activity was also detected in the testas and embryos at 4, 6, 8, and 10 weeks, and the suspensors at 4 weeks. Column chromatography of extracts of the different seed fractions on Sephadex LH-20 indicated that the cytokinins present coeluted with zeatin, zeatin riboside, and the glucoside cytokinins. It is suggested that cytokinins are accumulated in the seeds and are stored in the endosperm mainly in the form of ribosides and glucosides of zeatin. The reduction in cytokinin activity in the seed coincides with the reduction in endosperm volume and embryo growth and suggests that these compounds are utilized during the course of seed maturation.     

无核荔枝胚胎发育时期蛋白质图谱分析

通过二维聚丙烯酰胺凝胶电泳(2DE)以及计算机辅助的图像分析技术,对荔枝开花后20d的正常与败育胚蛋白质图谱进行了初步分析。结果表明,正常胚总蛋白质斑点数为129,败育胚总蛋白质斑点数为130,其中24个蛋白质点在两种胚中的表达丰度没有明显变化,35个蛋白质点在表达丰度上有明显差异,55%的蛋白则发生了蛋白质缺失、增加以及位置改变等变化。这两种蛋白质组的表达差异说明了胚内蛋白质成分在其败育过程中发生了变化,这些蛋白可能参与了胚败育的调节和控制。