水稻胚乳细胞质膜内陷的超微结构和磷酸酶的细胞化学定位

对生长分化期水稻胚乳细胞的质膜内陷进行了超微结构和磷酸酶的细胞化学研究。结果表明 ,胚乳细胞内的小泡、内质网常与胞间连丝相连 ;质膜形态多变 ,功能活跃 ,由局部起伏的波纹状发展成明显内陷 ,深浅不一 ,多呈袋状 ,袋中包含着大小不一的泡状物 ;有些内陷脱离质膜成为胞质中的囊泡 ,表现出活跃的内吞现象。除细胞间隙中含有圆球状的内含物外 ,在质膜内陷和囊泡中常含有大量的内含物。H ATP酶定位结果显示 ,质膜及其邻近的泡状物周围有酶的分布 ;而酸性磷酸酶定位在液泡、胞间隙和其中的泡状内含物周围 ;在质膜及其内陷形成的囊泡中有G6P酶的分布。这些结果表明胞间隙和质膜内陷在物质的运输中可能起着重要作用     

蚕豆叶片细胞中IAA的胶体金免疫电镜定位

利用胶体金免疫电镜技术对蚕豆(Vicia faba L.)叶片细胞中的IAA定位进行了研究。幼嫩叶片的叶肉细胞中金颗粒主要分布在细胞核和叶绿体中,细胞质及细胞壁也有金颗粒标记。成熟叶片的叶肉细胞中金颗粒主要分布在叶绿体和细胞质,细胞壁也有少量金颗粒标记,液泡中没有发现金颗粒标记。成熟叶片小叶脉的韧皮细胞发现有大量的金颗粒标记,金颗粒主要标记在传递细胞的细胞壁中。小叶脉的维管束鞘细胞中也有很多的金颗粒标记,金颗粒主要分布在叶绿体、细胞质及细胞壁中。幼嫩叶片组织不进行IAA的固定或用正常兔IgG代替IAA抗体染色的对照,很难发现金颗粒标记。对IAA在组织及亚细胞中的定位及其生理意义进行了讨论。     

杜仲次生木质部分化和脱分化过程中酸性磷酸酶的超微细胞化学定位

杜仲（EucommiaulmoidesOliv．）次生木质部分化过程中,在形成层刚衍生的木薄壁细胞中,酸性磷酸酶（APase）主要分布于核膜边缘和高尔基体;在分化程度较高的木薄壁细胞中,APase散布于整个核中,进而,在各种细胞器残体上聚集;在成熟的木薄壁细胞中,APase沿细胞壁内侧分布。在未成熟导管分子中,核、质膜及纹孔上明显存在APase聚集,进而,核解体;在即将分化成熟的导管分子中,APase主要集中于初生壁;在已分化成熟的导管分子中,APase集中于次生壁。脱分化过程中,只在细胞质中可见分散的APase活性,而细胞核和细胞壁上未见此酶的分布;更深层的即将分化成熟和已分化成熟的导管分子,未见有细胞分裂,其上APase的分布与剥皮前相同。通过比较分化和脱分化过程中APase的分布,推测不同的APase同工酶可能分别参与了次生木质部细胞程序性死亡过程中原生质体的解体和次生壁的建成。APase的聚集程度可能是决定细胞能否脱分化的一个重要特征。     

蚕豆籽粒内的~(14)C同化物的运转和卸出动态

通过向蚕豆叶片饲喂~(14)CO_2,应用液闪和显微放射性自显影技术表明标记同化物经叶脉和果荚韧皮部筛管快速运输至蚕豆种皮。种皮吸收营养、生长,后期逐步降解、供养子叶。种皮内的两类维管束系统同时输送营养并卸出到种皮内侧的质外体空间里。种皮里的反向维管束韧皮部卸出以共质体方式为主。并提供养分供种皮生长,而大部分的同化物由正向完整维管束韧皮部的筛分子一传递细胞进行质外体方式卸出。膨大中的子叶在早期即已成为生理上十分活跃的库。它对标记同化物的摄入随时间进程而急剧上升。     

一种特殊的长寿细胞:毛竹茎秆纤维细胞

利用显微和细胞化学方法,对毛竹(Phyllostachys edulis)茎秆纤维次生壁形成过程中超微结构变化以及ATP酶、Ca2 -ATPase和酸性磷酸酶的超微细胞化学定位进行了研究.研究发现,次生壁形成早期,细胞核具有双层核膜,染色质凝聚,可见大量的线粒体、粗面内质网和高尔基体等细胞器存在于纤维细胞中;随后,双层核膜消失,细胞器将逐渐解体,多泡体开始出现在纤维细胞的细胞质;随着年龄的增加,纤维细胞壁逐渐增厚,并出现多层结构现象,而运输小泡、细胞膜、胞间连丝和凝聚的染色质将持续存在.在次生壁形成的整个过程中,ATP酶、Ca2 -ATPase和酸性磷酸酶在运输小泡、细胞膜、质膜内陷、胞间连丝和凝聚的染色质中将持续存在.结果表明,毛竹茎秆纤维细胞是一种不同于木本双子叶植物的长寿细胞,纤维原生质体中ATP酶和酸性磷酸酶的持续存在与次生壁的持续增厚密切相关.     

植物体内的传递细胞

早在1884年,Fischer在考虑叶肉组织细胞的光合产物是如何运输到小叶脉问题时,就曾猜想过叶子的小叶脉中,可能有某种特殊的细胞来起着它的传递作用。当时他称这种细胞为“中间细胞”。后来,有了一些这方面的报道,但并没引起人们的注意。一直到本世纪六十年代后期,由于运用了超薄切片技术和电子显微镜的观察,才又发现了这些运输代谢产物、细胞壁结构非常特殊的细胞,当时就称之为传递细胞(transfer cell)。起初人们认为传递细胞主要集中叶的木质部和韧皮部,特别是叶小脉的维管组织中。后来研究发现,这种细胞在植物体内分布却十分广泛。除了植物的叶以外,节、鳞片、苞片、小苞片、子叶、胚囊等都发现有这类细胞存在。近年来,国内学者又报道了蒜的花茎中也存在着这类细胞。     

菠萝蜜叶和花的解剖结构研究

运用石蜡切片和电镜扫描等方法对菠萝蜜叶和花进行解剖学的观察和研究,结果表明:菠萝蜜的叶是典型的异面叶;表皮细胞的角质层较厚,叶肉有2～4层栅栏组织,海绵组织细胞间隙发达,在叶肉和叶脉中还有较多含单宁的薄壁细胞,叶脉的木质部非常发达;说明了菠萝蜜的叶具有较强的耐旱和抗虫能力。花小,单性,花粉粒小而量多,风媒传粉;三孔花粉粒。     

一种特殊的长寿细胞: 毛竹茎秆纤维细胞

利用显微和细胞化学方法, 对毛竹( Phyllostachys edulis) 茎秆纤维次生壁形成过程中超微结构变化以及ATP 酶、Ca²⁺ -ATP_ase 和酸性磷酸酶的超微细胞化学定位进行了研究。研究发现, 次生壁形成早期,细胞核具有双层核膜, 染色质凝聚, 可见大量的线粒体、粗面内质网和高尔基体等细胞器存在于纤维细胞中; 随后, 双层核膜消失, 细胞器将逐渐解体, 多泡体开始出现在纤维细胞的细胞质; 随着年龄的增加,纤维细胞壁逐渐增厚, 并出现多层结构现象, 而运输小泡、细胞膜、胞间连丝和凝聚的染色质将持续存在。在次生壁形成的整个过程中, ATP 酶、Ca²⁺ -ATP_ase 和酸性磷酸酶在运输小泡、细胞膜、质膜内陷、胞间连丝和凝聚的染色质中将持续存在。结果表明, 毛竹茎秆纤维细胞是一种不同于木本双子叶植物的长寿细胞, 纤维原生质体中ATP 酶和酸性磷酸酶的持续存在与次生壁的持续增厚密切相关。     

磷胁迫诱导大豆叶片酸性磷酸酶同工酶的表达

通过田间试验对两种磷处理的274个大豆基因型叶片酸性磷酸酶活性进行筛选,并将其中8个进行营养液栽培试验以研究磷胁迫对其叶片酸性磷酸酶同工酶表达的影响.结果表明,大豆叶片酸性磷酸酶活性存在着明显的基因型差异,不施磷处理提高了大部分(约60%)供试基因型叶片酸性磷酸酶的活性.营养液栽培试验表明,低磷处理普遍提高了所有8个供试大豆基因型叶片酸性磷酸酶的活性.等电聚焦电泳结果表明,供试大豆基因型的老叶和新叶中均有6条酸性磷酸酶的同工酶带.低磷处理显著增加了叶片酸性磷酸酶酶带的活性,但是没有诱导新的酸性磷酸酶酶带产生.研究发现叶片酸性磷酸酶活性可作为反映大豆磷胁迫的酶学指标;磷胁迫诱导大豆叶片酸性磷酸酶活性的增加是由于已有同工酶活性的提高而不是由于特异性酶带的产生.     

甜菊愈伤组织中的质膜内陷:超微结构和酸性磷酸酶细胞化学定位

对在分化条件下的甜菊 (Stevia rebaudiana)愈伤组织分生区域细胞的质膜内陷进行了超微结构和酸性磷酸酶细胞化学研究。结果表明 ,在不同液泡化状态的细胞中均有质膜内陷存在。在原生质浓密的细胞中 ,质膜呈起伏的波纹状 ,某些部位发生明显内陷 ,大小不等 ,多呈圆球状。在部分液泡化细胞中 ,质膜内陷体积增大 ,内含物增多且结构复杂。在液泡化细胞中 ,质膜内陷嵌入中央液泡 ,但彼此间以一膜间隙隔开。质膜内陷中的内含物以小泡和卷绕的膜结构形式存在。酸性磷酸酶活性定位结果显示 ,质膜及其内陷含高的酶活性。推测质膜内陷在功能上与液泡相似 ,构成了这些细胞水解空间的一部分。     

Structural and functional vein maturation in developing tobacco leaves in relation to AtSUC2 promoter activity

Transgenic tobacco (Nicotiana tabacum) plants expressing green fluorescent protein (GFP) from the AtSUC2 promoter were used to study the function of different vein classes in developing leaves. In sink leaves, unloading capacity occurred acropetally, with the class I (midrib) and class II veins becoming functional in phloem unloading before the maturation of the class III veinal network. In contrast, in developing cotyledons and source leaves, loading capacity occurred in a basipetal direction. There was a strong correlation between loading capacity, as assessed by (14)C Suc uptake and companion cell expression of AtSUC2-GFP. Developing cotyledons were shown to utilize all available vein classes for loading. A second line of transgenic plants was produced in which GFP, expressed from the AtSUC2 promoter, was targeted to the endoplasmic reticulum instead of the cytoplasm. In these AtSUC2-GFP-ER plants, GFP was unable to traffic into the sieve element and was restricted solely to the companion cells of source leaf tissues. Partial shading of leaves undergoing the sink-source transition demonstrated that the activation of the AtSUC2 promoter in tobacco was influenced by light. Functional and structural maturation of the minor veins required light or a product of light. The activation of the AtSUC2 promoter within major veins appears to be regulated differently from that in the minor veins. The relationship between AtSUC2 activation and the activity of endogenous tobacco Suc transporters is discussed.     

Histochemical localization of nucleoside triphosphatase activity in assimilate conducting plant tissue

Summary For the histochemical localization of nucleoside triphosphatases at the electron microscopic level, prefixed tissues were incubated with lead nitrate in addition to substrate (GOMORI reaction). While ATP and UTP as substrates gave electron-dense reaction products at the plasmalemma of sieve tubes, companion cells and phloem parenchyma cells, and at plasmodesmata in primary pitfields, AMP gave reaction products only at the tonoplast of parenchyma cells. Since electron-dense deposits also occur in cell walls and vacuoles, energy dispersive X-ray microanalysis was used to distinguish between lead deposits and lead-phosphate deposits. The latter were restricted to the symplast. Among the three plant species used, the leaf bundle phloem ofHordeum distichon showed ATPase activity largely restricted to the phloem cells, except for the thickwalled sieve tubes. Some activity also bordered the chloroplasts of the bundle sheath cells. In the C₄ plantGomphrena globosa, ATPase and UTPase activities appeared to be the greater in phloem parenchyma cells than in sieve tubes. In the phloem of youngMonstera deliciosa roots, ATPase occurred not only at the plasmalemma of sieve tubes, but also around sieve-tube plastids. When compared with AMP as substrate, it appears that nucleoside triphosphates are the natural substrates of the enzyme(s) in the plasmalemma of sieve tubes and phloem parenchyma cells.     

Ultrastructure of minor veins inCucurbita pepo leaves

Summary The minor veins ofCucurbita pepo leaves were examined as part of a continuing study of leaf development and phloem transport in this species. The minor veins are bicollateral along their entire length. Mature sieve elements are enucleate and lack ribosomes. There is no tonoplast. The sieve elements, which are joined to each other by sieve plates, contain mitochondria, plastids and endoplasmic reticulum as well as fibrillar and tubular (190–195 diameter) P-protein. Fibrillar P-protein is dispersed in mature abaxial sieve elements but remains aggregated as discrete bodies in mature adaxial sieve elements. In both abaxial and adaxial mature sieve elements tubular P-protein remains undispersed. Sieve pores in abaxial sieve elements are narrow, lined with callose and are filled with P-protein. In adaxial sieve elements they are wide, contain little callose and are unobstructed. The intermediary cells (companion cells) of the abaxial phloem are large and dwarf the diminutive sieve elements. Intermediary cells are densely filled with ribosomes and contain numerous small vacuoles and many mitochondria which lie close to the plasmalemma. An unusually large number of plasmodesmata traverse the common wall between intermediary cells and bundle sheath cells suggesting that the pathway for the transport of photosynthate from the mesophyll to the sieve elements is at least partially symplastic. Adaxial companion cells are of approximately the same diameter as the adaxial sieve elements. They are densely packed with ribosomes and have a large central vacuole. They are not conspicuously connected by plasmodesmata to the bundle sheath.     

Plasmatubules in transfer cells of pea (Pisum sativum L.)

Plasmatubules are tubular evaginations of the plasmalemma. They have previously been found at sites where high solute flux between apoplast and symplast occurs for a short period and where wall proliferations of the transfer cell type have not been developed (Harris et al. 1982, Planta 156, 461–465). In this paper we describe the distribution of plasmatubules in transfer cells of the leaf minor veins of Pisum sativum L. Transfer cells are found in these veins associated both with phloem sieve elements and with xylem vessels. Plasmatubules were found, in both types of transfer cell and it is suggested that the specific distribution of the plasmatubules may reflect further membrane amplification within the transfer cell for uptake of solute from apoplast into symplast.     

甘蔗叶不同部位ATP酶活性细胞化学定位

甘蔗叶片,叶鞘和肥厚带韧皮部 ATP 酶活性定位于筛管、伴胞的质膜、内质网和某些伴胞细胞基质、小囊泡和发育成熟的液泡上;叶片韧皮部薄壁细胞、厚壁细胞和厚壁通道细胞质膜及小囊泡中亦显示有 ATP 水解产物;维管束鞘细咆与厚壁细胞或厚壁通道细胞所构成的细胞间隙上也存在有 ATP 酶活性反应产物沉淀。甘蔗叶片大、中、小三种维管束,从小维管束到大维管束,面向细胞间隙的细胞表面上的 ATP 酶活性逐渐增强,而维管束鞘细胞质膜上的 ATP 酶活性则趋于减弱;同一维管束内则以韧皮部细胞的 ATP 酶活性最强。维管束鞘细胞与叶肉细胞之间存在很多的胞间连丝,并表现出高的 ATP 酶活性。讨论了 ATP 酶活性的分布状态与叶肉细胞的光合产物向韧皮部运输的关系。     

<Emphasis Type="Italic">Amborella trichopoda</Emphasis>, plasmodesmata,and the evolution of phloem loading

Phloem loading is the process by which photoassimilates synthesized in the mesophyll cells of leaves enter the sieve elements and companion cells of minor veins in preparation for long distance transport to sink organs. Three loading strategies have been described: active loading from the apoplast, passive loading via the symplast, and passive symplastic transfer followed by polymer trapping of raffinose and stachyose. We studied phloem loading in Amborella trichopoda, a premontane shrub that may be sister to all other flowering plants. The minor veins of A. trichopoda contain intermediary cells, indicative of the polymer trap mechanism, forming an arc on the abaxial side and subtending a cluster of ordinary companion cells in the interior of the veins. Intermediary cells are linked to bundle sheath cells by highly abundant plasmodesmata whereas ordinary companion cells have few plasmodesmata, characteristic of phloem that loads from the apoplast. Intermediary cells, ordinary companion cells, and sieve elements form symplastically connected complexes. Leaves provided with ¹⁴CO₂ translocate radiolabeled sucrose, raffinose, and stachyose. Therefore, structural and physiological evidence suggests that both apoplastic and polymer trapping mechanisms of phloem loading operate in A. trichopoda. The evolution of phloem loading strategies is complex and may be difficult to resolve.     

Sink Effect of Cytokinin in Detached Leaves Is Not Caused by Structural Rearrangements of Phloem

The sink effect of cytokinin is manifested as a decrease in source capacity and the induction of sink activity in the phytohormone-treated region of a mature excised leaf. In order to find out whether this effect was due to the direct action of cytokinin on the phloem structure, two types of phloem terminals were examined. In pumpkin (Cucurbita pepo L.) leaves, the phloem terminals are open; i.e., they are linked to mesophyll by numerous symplastic connections, which are located in narrow areas called plasmodesmal pit fields. In broad bean (Vicia faba L.) leaves, the phloem terminals belong to the closed type and have no symplastic links with mesophyll. The electron microscopic study of terminal phloem did not reveal any structural changes in the companion cells, which could account for the suppression of assimilate export. The treatment of leaves with cytokinin neither disturbed the structure of plasmodesmal pit fields in pumpkin leaves nor eliminated the wall protuberances (the ingrowths promoting phloem loading) in bean leaves. No evidence was obtained that the cytokinin-induced import of assimilates in mature leaves is caused by the recovery of meristematic activity, i.e., by either formation of new phloem terminals having immature sieve elements capable of unloading or by the development of new sieve elements within the existing veins. Cytokinin did not induce de novo formation of phloem elements. Structural characteristics of the leaf phloem, such as the number of branching orders in the venation pattern, the number of vein endings per areole, the number of areoles per leaf, the area of one areole, and the number of sieve elements per bundle remained unaltered. It is concluded that the sink effect of cytokinin in excised leaves cannot be determined by alteration of the phloem structure.     

Cytochemical localization of adenosine triphosphatase in the phloem of Pisum sativum and its relation to the function of transfer cells

The cytochemical localization of ATPase in differentiating and mature phloem cells of Pisum sativum L. has been studied using a lead precipitation technique. Phloem transfer cells at early stages of differentiation exhibit strong enzyme activity in the endoplasmic reticulum (ER) and some reaction product is deposited on the vacuolar and plasma membranes. As the phloem transfer cells mature and develop their characteristic wall structures, strong enzyme activity can be observed in association with the plasma membranes and nuclear envelopes. Mature phloem transfer cells with elaborate cell-wall ingrowths show ATPase activity evenly distributed on plasma-membrane surfaces. Differentiating sieve elements show little or no enzyme activity. When sieve elements are fully mature they have reaction product in the parietal and stacked cisternae of the ER. There is no ATPase activity associated with P-protein at any stage of sieve-element differentiation or with the sieve-element plasma membranes. It is suggested that the intensive ATPase activity on the plasma membranes of the transfer cells is evidence for a transport system involved in the active movement of photosynthetic products through these cells.Key to labeling in the figures ER endoplasmic reticulum - P parenchyma cell - PP P-protein - SE sieve element - SPP sieve-plate pore - TC transfer cell     

Secondary plasmodesmata formation in the minor-vein phloem of Cucumis melo L. and Cucurbita pepo L.

Numerous branched plasmodesmata (pd) are present between bundle-sheath cells (BSCs) and specialized companion cells known as intermediary cells (ICs) in the minor-vein phloem of melon (Cucumis melo L.) and squash (Cucurbita pepo L.). These pd were found to be secondary, i.e., they form across existing walls. Sink, sink-source transition, and source tissues were sampled from developing and mature leaves. In sink tissue, IC precursors divide to produce the two to four ICs and associated sieve elements which are present by the time of the sink-source transition. Plasmodesmata along the interface between the IC precursor and adjacent BSCs in sink tissue are unbranched and few in number. Before the leaf tissue undergoes the sink-source transition, the number of pd channels (individual branches of pd) becomes more numerous. This increase in number of pd channels occurs at least in part and perhaps entirely by branching, resulting in more channels on the IC-side than on the BSC-side. In melon there is a 12-fold increase in the number of pd channels within the IC-side of the interface and a corresponding 9-fold increase in pd channels within the BSC-side. Thus, secondary pd form by the time of the sink-source transition and may be involved in phloem loading and photoassimilate export. The system described is well-defined and amenable to experimental manipulation: secondary pd form in large numbers, at a particular interface, over a short period of time, and in a highly predictable manner.Abbreviations BSC bundle-sheath cell - DAP days after planting - IC intermediary cell - LPI leaf plastochron index - pd plasmodesmata - PI plastochron interval We thank Edith Haritatos, Rich Medville, Esther Gowan, and Nancy Dussault for expert technical assistance. This research was supported by an NSF/DOE/USDA Cornell Plant Science Center fellowship (G.M.V.), Natural Sciences and Engineering Research Council Grant GP0138401 and Université de Montréal, Fonds internes de recherche (D.U.B.), and NSF grant IBN-9419703 (R.T.).     

Tubular extensions of the plasmalemma in leaf cells of Zea mays L.

Leaf tissues of Zea mays were examined with a transmission electron microscope and a high-voltage electron microscope. Tubular extensions (invaginations) of the plasmalemma were found in vascular parenchyma cells and thick-walled, lateformed sieve elements of intermediate and small veins, and in epidermal, mesophyll, and sheath cells of all leaves examined. No continuity seems to exist between the tubules and other cellular membranes.