灵武长枣果实发育结构特征研究

采用石蜡切片法,研究不同发育时期灵武长枣果实的结构特征。结果表明:(1)缓慢生长期细胞增长缓慢,外果皮细胞5~6层,表皮细胞由1层薄壁细胞构成,呈长矩形或长椭圆形,表皮细胞以内的薄壁细胞不断增生,形成内表皮细胞。果实体积增大伴随着空腔的出现,中果皮维管束数量多;(2)第一次快速生长期细胞增长迅速,表皮细胞排列疏松,中果皮中的空腔增大速度最快,维管束主要分布在靠近外果皮和内果皮的中果皮部位;(3)减缓生长期表皮细胞变成圆形或椭圆形等不规则形状,细胞排列松散,内表皮细胞形状、大小不一,细胞排列疏松。中果皮中的空腔继续增大,维管束数目逐渐减少,但变化幅度较小;(4)第二次快速生长期外果皮细胞层数减少到3~4层,表皮细胞和内表皮细胞难以区分,空腔随着果实体积的增大达到最大,许多细胞单列排成网状结构,形成更大的腔,果皮中的维管束分布最少。在灵武长枣果实发育过程中,不同发育时期的不同部位其果实的形态解剖特征不同。     

山茱萸果皮的解剖学研究

本文报导了山茱萸果皮的解剖学研究结果.外果皮由一层表皮细胞构成.中果皮外方为3-4(5)层厚角组织细胞,这些细胞通常含有单宁;其内方包含薄壁细胞、单宁细胞和8束维管束.单宁细胞成团或零星分布于薄璧细胞中,前者的体积明显大于后者.单宁细胞的单宁与多糖结合在一起.维管束含有环纹、螺纹、梯纹、网纹及孔纹管胞,还有少数散生的纤维.内果皮高度木质化,主要由多种形状的石细胞组成,其间分布了肉眼可见、排列成环状的异细胞,偶见少数生活石细胞及薄壁细胞.内果皮有3束维管束.     

山茱萸果皮的解剖学研究

本文报导了山茱萸果皮的解剖学研究结果.外果皮由一层表皮细胞构成.中果皮外方为3-4(5)层厚角组织细胞,这些细胞通常含有单宁;其内方包含薄壁细胞、单宁细胞和8束维管束.单宁细胞成团或零星分布于薄璧细胞中,前者的体积明显大于后者.单宁细胞的单宁与多糖结合在一起.维管束含有环纹、螺纹、梯纹、网纹及孔纹管胞,还有少数散生的纤维.内果皮高度木质化,主要由多种形状的石细胞组成,其间分布了肉眼可见、排列成环状的异细胞,偶见少数生活石细胞及薄壁细胞.内果皮有3束维管束.     

矮樱桃果实发育的解剖学研究

利用石蜡制片法解剖研究魏樱桃果实的发育过程,将其发育过程分为３个时期：（１）果实细胞旺盛分裂和增大期：外果皮细胞垂周分裂,以增加果实表面积;中果皮和内果皮主要进行平周分裂３以增加细胞层数,同时３层果皮的细胞体积也增大。（２）内果皮细胞硬化期：外果皮和中果皮的细胞停止分裂,体积增大也不明显,内果皮细胞壁逐渐加厚、硬化。９３）中果皮细胞显著增大期：中果皮的细胞的体积弦向增大的同时,径向延长更明显。其成     

龙眼果皮形态结构比较观察及其与果实耐贮运的关系

比较了福建省 1 0个主栽龙眼品种果实的果皮形态和结构 ,结果表明 :不同品种在果皮厚度、外果皮表面颜色、龟状纹、放射线、瘤状突、刺毛、外果皮皮孔、周皮层厚度、栓质层厚度和连续性、中果皮薄壁组织细胞排列、石细胞大小、含量、排列和分布 ,维管束发达状况、排列和分布 ,内果皮表皮细胞排列和角蜡质层厚度等方面均存在着明显差异。风梨味、东壁、油潭本、乌龙岭、红核子、蕉眼龙眼果皮厚 ,外果皮表面瘤状突和剌毛多 ,外果皮周皮层、栓质层厚且连续性好 ,中果皮石细胞 (团 )含量多且排列紧密 ,分布在中果皮外侧且在中果皮中所占比例大 ,维管束发达且排列有序 ,内果皮角蜡质层厚 ;这些品种果实耐贮运、抗病性强。而水涨、赤壳、福眼、普明庵龙眼果皮薄 ,外果皮周皮层薄、栓质层不发达 ,中果皮石细胞 (团 )含量少、分布分散 ,维管束不发达 ,薄壁组织细胞胞间隙大 ,皮孔间隙大、皮孔通道与中果皮组织细胞间隙相通 ;这些品种的果实不耐贮运、抗病性弱。讨论了龙眼外果皮表面主色为褐色和内果皮比外果皮更容易褐变的解剖学原因及龙眼果皮形态结构与果实耐贮运的关系。     

核桃果皮的发育解剖学研究

核桃果皮的发育过程可分为３个阶段,发育时期：中、内三层果皮的界线不清,维管束处于发育初期;发育中期：随着中果皮最外侧两层石细胞的出现和薄壁组织细胞体积的迅速扩大以及维管束轮数的增加,使三层果皮具较明显的界面,发育后期：中果皮的维管束递增到４－５轮,     

白扁豆荚果形态发育过程的研究

本文叙述了白扁豆荚果的形态发育和组织分化规律。果实的生长曲线略呈单顶型,前期快,中期缓慢,以后干缩变小。在此过程中,果皮的颜色、表面特征和质地也产生有规律的变化。在上述生长发育过程中,果皮的外表皮与下皮形成外果皮,内表皮与其内的4—5层纤维状细胞形成内果皮,两者之间的薄壁组织与维管束组成中果皮。在荚果迅速生长期末,种子各部分结构已基本形成。成熟的种子由外珠被形成的种皮和发育完全的胚组成。由于其果皮内缺乏交叉的厚壁组织,且两缝线处具有两排木质化细胞的封闭层,故成熟时荚果不开裂。根据其荚果的形态发育规律和结构特征对白扁豆的栽培管理提出了一些建议。     

莲果皮发育及其结构的扫描电镜观察

莲（Nelumbo nucifera Gaertn)的果皮由子房壁单独发育形成,可清晰地分出外果皮,中果皮和内果皮,在果皮基本组织中散生有维管束,分泌器和通气系统,通气系统由气孔、气道和气室组成,气孔在内、外表皮上都有,深陷于表皮下,形状特殊,气道为裂生型,气室裂浴生型,气室内壁有孔与周围组织相通;气道,气室又与内、外表皮上的气孔相通,形成贯通果皮的通气网络。表皮上有多种分泌器,其分泌物的形不同,乳汁管有节,分枝或不分枝,维管束木质部内有环纹和螺纹管胞和导管;韧皮部内有筛管,伴胞及内含物,在柱头下方的果皮上长一突起,果皮突起是莲的独特结构,是种子发育中起作用的呼吸器官。     

莲果皮发育及其结构的扫描电镜观察

莲（Nelumbo nucifera Gaertn)的果皮由子房壁单独发育形成,可清晰地分出外果皮,中果皮和内果皮,在果皮基本组织中散生有维管束,分泌器和通气系统,通气系统由气孔、气道和气室组成,气孔在内、外表皮上都有,深陷于表皮下,形状特殊,气道为裂生型,气室裂浴生型,气室内壁有孔与周围组织相通;气道,气室又与内、外表皮上的气孔相通,形成贯通果皮的通气网络。表皮上有多种分泌器,其分泌物的形不同,乳汁管有节,分枝或不分枝,维管束木质部内有环纹和螺纹管胞和导管;韧皮部内有筛管,伴胞及内含物,在柱头下方的果皮上长一突起,果皮突起是莲的独特结构,是种子发育中起作用的呼吸器官。     

山茱萸果实发育过程中单宁物质的分布与积累特征

选取不同发育时期的山茱萸果实作为研究对象,采用果实形态观察法、显微及超微技术、组织化学定位法以及紫外分光光度计法对山茱萸果实发育过程中单宁物质分布及积累特征进行观察分析,并以单因素ANOVA检验不同发育时期单宁含量的差异,以揭示单宁物质在山茱萸果实发育中的变化规律,为山茱萸果实涩味调控机制研究提供理论依据。结果表明:(1)山茱萸果实发育过程中果皮颜色和果实体积变化明显,可将其发育过程划分为幼果期、中果期、成熟期3个时期;单宁物质主要分布在山茱萸果实中果皮的单宁细胞中。(2)在山茱萸果实发育过程中单宁细胞数目呈先增后减的变化趋势,幼果期单宁细胞从无到有,随着果实发育单宁细胞数目不断增多,至中果期单宁细胞数目开始减少。(3)单宁含量的变化规律与单宁细胞数目的变化一致,单宁含量在花后120 d时达到最多,随后逐渐减少。(4)单宁物质首先在细胞质的小液泡中积累,中央大液泡形成后则为单宁物质积累的主要场所,其积累形态主要有颗粒状、不规则状和板块状3种;单宁细胞中线粒体数目较多,中果期后期及成熟期在中央大液泡液泡膜附近有电子致密物质积累。研究认为,山茱萸果实中中果皮薄壁细胞为单宁物质积累的专属细胞,即单宁细胞,单宁物质的合成运输与液泡、囊泡以及线粒体的作用密切相关;成熟期山茱萸果实总单宁含量降低,涩味降低,表明单宁物质积累的动态变化与植物对环境的适应性和果实涩味息息相关,可结合代谢组和转录组的方法对山茱萸果实中单宁物质的合成机制进行进一步研究。     

Flower fertilization and fruit development prompt changes in free polyamines and ethylene in damson plum (Prunus insititia L.)

The flower opening of damson plum (Prunus insititia L.) was accompanied by an increase in the content of free-polyamines (PA) in the sepals, petals and sex organs, the ovary being most active in accumulating spermine (Spm). The fertilization process and senescence brought on a decline in ovarian Spm, but stimulated putrescine (Put) and spermidine (Spd) content in the sepals. The endocarp of this climacteric fruit produced only ethylene at the end of the S1 phase and throughout S2, in which there was a great richness in ACC and MACC. The greatest amounts of ACC and MACC were observed in the ripening mesocarp and epicarp. The contribution of the endocarp and epicarp to the total ACC in the developing fruit was very similar. During flowering and S1 and S2 phases, Spd was the most abundant PA; in contrast, during S3 and S4 Put was most abundant. The mesocarp contributed the most to the total content in PA throughout the fruit development. The control of SAM distribution towards ethylene and/or PA appears to differ during the development of the endocarp, as the only peak of free-Put (detected in S2) coincided with the highest ACC accumulation and ethylene production. On the contrary, in S3 it is probable that SAM was transformed preferentially into PA, given that free-Spd and Spm, hardly detectable in S1 and S2, peaked in this phase in which there was no gas production.     

Characterization of peroxidases in lignifying peach fruit endocarp

Developing peach (Prunus persica L. Batsch `Redskin') fruit were used to characterize the role of peroxidases in lignification. During development, the endocarp of these drupes becomes lignified while the mesocarp remains parenchymatous. Acidic peroxidase from lignifying endocarp were similar to those of the fleshy mesocarp. The endocarp had a larger amount and number of basic peroxidases than the mesocarp. Cultured peach leaf cells are thought to be lignified because their walls give a positive reaction with phloroglucinol-HCI. These cells also secreted a basic peroxidase. Peroxidases were difficult to extract from endocarp tissue as they lignified. This was also demonstrated by tissue printing on nitrocellulose. Flesh, but not endocarp peroxidase was evident in tissue prints. This suggests that tissue printing may fail to reveal the presence of enzymes which are firmly attached to the cell.     

无距虾脊兰果实发育及其解剖学特征

以授粉后无距虾脊兰不同发育阶段的蒴果为材料,对果实生长动态进行研究,并用石蜡切片法进行果实结构研究。观察结果表明：无距虾脊兰果实授粉至授粉后40 d生长速度最快。果实由3心皮组成,横切面为6瓣,3瓣有胎座,3瓣无胎座,开裂后6瓣于顶端连接。发育的过程中,果皮细胞层数及果实内外表皮细胞体积不变,果实直径的增加主要来自于细胞平周分裂和中果皮细胞体积的增大。果实成熟时只有少数细胞有细胞壁增厚现象,开裂线的前体细胞细胞壁发生木质化并向不同方向收缩导致果实的开裂。     

Carbohydrate Changes during Maturation of Cucumber Fruit : Implications for Sugar Metabolism and Transport

Changes in the carbohydrate profiles in the mesocarp, endocarp, and seeds of maturing cucumber (Cucumis sativus, L.) fruit were analyzed. Fruit maturity was measured by a decrease in endocarp pH, which was found to correlate with a loss in peel chlorophyll and an increase in citric acid content. Concentrations of glucose and fructose (8.6-10.3 milligrams per gram fresh weight, respectively) were found to be higher than the concentration of sucrose (0.3 milligrams per gram fresh weight) in both mesocarp and endocarp tissue. Neither raffinose nor stachyose were found in these tissues. The levels of glucose and fructose in seeds decreased during development, but sucrose, raffinose, and stachyose accumulated during the late stages of maturation. Both raffinose and stachyose were found in the seeds of six lines of Cucumis sativus L. This accumulation of raffinose saccharides coincided with an increase in galactinol synthase activity in the seeds. Funiculi from maturing fruit were found to be high in sucrose concentration (4.8 milligrams per gram fresh weight) but devoid of both raffinose and stachyose. The results indicated that sucrose is the transport sugar from the peduncle to seed, and that raffinose saccharide accumulation in the seed is the result of in situ biosynthesis and not from direct vascular transport of these oligosaccharides into the seeds.