Developmental Changes in Amounts of Thylakoid Components in Plastids of Barley Leaves

Changes in the amounts of several components of the photosyntheticelectron-transport system during greening of etiolated barleyleaves were studied on a "per plastid" basis. P700 and Q_A, whichwere initially absent from etioplasts, appeared 2 h after thestart of illumination in complete complexes of PS I and PS II,respectively. From 6 h, they increased rapidly in amount witha constant stoichiometric ratio of 1:1. Amounts of Cyt f, Cytb₆, Cyt b-559 and FeS, initially present in etioplasts at levelsthat were one-third to half of those in mature chloroplasts,also increased rapidly after 6 h of illumination. The molarratio of Cyt f, Cyt b₆ and Cyt b-559 was the same in etioplastsand in mature chloroplasts, namely 1:2:2. After 4 h of illumination,levels of FeS increased at nearly the same rate as those ofthe PS I complex. The increase in levels of all components wasmarked after 6 h of illumination, probably due to the energysupplied by developing plastids that had just become photosyntheticallycompetent. The results are discussed in relation to the timeof appearance of chlorophyll-protein complexes and photochemicalactivities. ¹ Present address: Department of Botany, Faculty of Science,Kyoto University, Kyoto, 606-01 Japan.     

杜仲次生木质部分化过程中的细胞编程死亡

通过电子显微镜观察、DNA断裂检测及类似半胱氨酸蛋白酶(caspase-like proteases,CLPs)降解检测等技术,对杜仲(Eucommia ulmoides Oliv.)次生木质部分化过程的细胞编程死亡进行了研究.分化中的次生木质部细胞总DNA凝胶电泳检测到DNA ladder,并通过TUNEL检测进一步确定了DNA被降解.Western blot结果表明;caspase-8和caspase-3状蛋白酶(caspase-8-和caspase-3-like proteases,CLPs)及多聚ADP-核糖聚合酶(poly(ADP-ribose)polymerase,PARP)在次生木质部分化过程中被降解.这些研究结果表明,杜仲次生木质部的细胞分化是一个典型的编程性死亡(Programmed cell death,PCD)过程,CLPs可能参与了此过程.     

杜仲次生木质部分化过程中的细胞编程死亡

通过电子显微镜观察、DNA断裂检测及类似半胱氨酸蛋白酶（caspase-like proteases,CLPs)降解检测等技术,对杜仲（Eucommia ulmoides Oliv.）次生木质部分化过程的细胞编程死亡进行了研究。分化中的次生木质部细胞总DNA凝胶电泳检测到DNA ladder,并通过TUNEL检测进一步确定了DNA被降解。Western blot结果表明：caspase-8和caspase-3状蛋白酶（caspase-8-和caspase-3-like proteases,CLPs)及多聚ADP-核糖聚合酶（poly(ADP-ribose) polymerase,PARP)在次生木质部分化过程中被降解。这些研究结果表明,杜仲次生木质部的细胞分化是一个典型的编程性死亡（Programmed cell death,PCD)过程,CLPs可能参与了此过程。     

The Role of the Root in the Induction of Xylem Differentiation in Peas

It is known that growing parts of the shoot induce the differentiationof vascular tissues below them and that this induction is dueto the production of auxin. The problem dealt with here is whythe formation of xylem proceeds in the growing roots. The redifferentiationof parenchyma to tracheary elements in grafts of pea plantswas used in this study. It is proved that this is not due tostimuli coming from the root tip but rather to the movementof a stimulus coming from the shoot into the root. The polarityof movement is maintained even in thin sections, but it canbe reversed by a strong shoot influence.     

杜仲次生木质部分化过程中木质素与半纤维素组分在细胞壁中分布的动态变化

利用紫外光显微镜、透射电子显微镜结合免疫胶体金标记,研究了杜仲（Eucommia ulmoides Oliv.)次生木质部分化过程中木质素与半纤维素组分（木葡聚糖和木聚糖）在细胞壁分布的动态变化。在形成层及细胞伸展区域,细胞壁具有木葡聚糖的分布,而没有木聚糖和木质素沉积,随着次生壁S1层的形成,木质素出现在细胞角隅和胞间层,木聚糖开始出现在S1层中,此时木葡聚糖则分布在初生壁和胞间层;随着次生,壁S2层及S3层的形成和加厚,木质逐逐步由细胞角隅和胞间层扩展到S1、S2和S3层,其沉积呈现出不均匀的块状或片状沉积模式,在次生壁各层形成与其木质化的同时,木聚糖逐渐分布于整个次生壁中,而木糖聚糖仍局限分布于初生壁和胞间层。结果表明,随着细胞次生壁的形成与木质化,细胞壁结构发生较大变化。细胞壁的不同区域,如细胞角隅、胞间层、初生壁和次生壁各层,具有不同的半纤维素组成,其与木质等细胞壁组分结构构成不同的细胞壁分子结构。     

Ultrastructural Changes in Cambial Cell Derivatives during Xylem Differentiation in Poplar

Abstract: The changes in cellular structures that occur in cambial cell derivatives during xylogenesis were examined in Populus trichocarpa Torr et Gray. During dormancy, the cells of the vascular cambium are characterised by dense cytoplasm, many small vacuoles and lipid bodies. During cambial activation, cambial cells are highly vacuolated, the cytoplasm is rich in organelles and the nucleus contains distinctly enlarged nucleoli. The plasma membrane forms vesicle-filled invaginations which mediate uptake of vesicular material into the vacuole. The mitotic patterns in dividing fusiform cells are fragmentary due to their strong vacuolisation. During cell enlargement, cambial cell derivatives remain strongly vacuolated and cytoplasmic structures are similar to active fusiform cells. From the beginning of secondary cell wall formation many changes in cytoplasmic structures occur in newly-formed fibres and vessels. In fibres, the cytoplasm is characterised by components of secondary cell wall synthesis, as indicated by increased amounts of endoplasmic reticulum, vesicle-producing dictyosomes and microtubules. In contrast, vessels show a more or less distinct occurrence of these components and remain more strongly vacuolated than fibres. Similar to cambial cells, a distinct flow of vesicular material into the vacuole through invaginations of the plasma membrane is apparent in fibres, as well as in vessels. After completion of the secondary cell walls, the loss of tonoplast integrity causes the collapse of the vacuole and initiates cell death in vessels and fibres. In vessels the tonoplast exhibits unusually strong staining prior to the collapse of the vacuole, indicating subsequent cell death. Overall, our results indicate an important role for the vacuole in the xylogen differentiation of cambial derivatives.     

木质部细胞分化的程序

本文主要对近十几年来有关木质部细胞分化研究中使用的实验系统及用这些系统所取得的重要进展作了评述.并以作者实验室的研究成果为基础,结合国内外研究进展,提出木质部细胞分化程序由参与细胞编程死亡(PCD)和次生壁构建的全部基因综合编制而成.以PCD过程各阶段的划分标准来看,木质部细胞分化中从IAA诱导形成层细胞平周分裂到细胞扩大前为PCD的起始阶段,其间包括死亡信号的发生、接受和传导,以及启始caspase(半胱氨酰基天门冬氨酸蛋白酶)类似物(例如caspase-8类似物)的活化;木质部母细胞的径向扩大为PCD的效应阶段,而效应caspase类似物(例如caspase-3类似物)活化DNase、DNA的片段化及次生细胞壁的构建和各种细胞器的解体则为PCD的清除降解阶段.至今还无法将DNase活化及其引起的DNA断裂过程与次生细胞壁构建过程分开.     

Dynamic Changes in Distribution of Lignin and Hemicelluloses in Cell Walls During Differentiation of Secondary Xylem in Eucommia ulmoides (in English)

The dynamic changes in the distribution of lignin and hemicelluloses (xylans and xyloglucans) in cell walls during the differentiation of secondary xylem in Eucommia ulmoides Oliv. were studied by means of ultraviolet light microscopy and transmission electron microscopy combined with immunogold labelling. In the cambial zone and cell expansion zone, xyloglucans were localized both in the tangential and radial walls, but no xylans or lignin were found in these regions. With the formation of secondary wall S1 layer, lignin occurred in the cell corners and middle lamella, while xylans appeared in S1 layer, and xyloglucans were localized in the primary walls and middle lamella. In pace with the formation of secondary wall S2 and S3 layer, lignification extended to S1, S2 and S3 layer in sequence, showing a patchy style of lignin deposition. Concurrently, xylans distributed in the whole secondary walls and xyloglucans, on the other hand, still localized in the primary walls and middle lamella. The results indicated that along with the formation and lignification of the secondary wall, great changes had taken place in the cell walls. Different parts of cell walls, such as cell corners, middle lamella, primary walls and various layers of secondary walls, had different kinds of hemicelluloses, which formed various cell wall architecture combined with lignin and other cell wall components.     

杜仲次生木质部细胞分化和脱分化过程中ATPase的超微细胞化学定位

The ultracytochemical localization of ATPase in the secondary xylem cells during their differentiation and dedifferentiation in the girdled Eucommia ulmoides Oliv. was carried out using a lead phosphate precipitation technique. Throughout the differentiation, which is a typical programmed cell death (PCD) process, ATPase deposits increased in the nucleus but decreased and progressively disappeared in the cell organelles. At the same time, the distribution of ATPase increased in the inner face of the cell wall and pits with cytoplasmic degeneration. The results demonstrated that the PCD was an energy dependent active process and was controlled by nuclear genes. On the other hand, the distribution of ATPase in the intercellular spaces increased with the formation of the new cambium resulted from the dedifferentiation of the secondary xylem cells after girdling. However, ATPase was not found in the nucleus of the dividing cells, suggesting that nutrients were transported through protoplast during differentiation, and through both protoplast and apoplast during dedifferentiation. Thus, the energy required in cell division was provided mainly by intercellular spaces. These findings indicate that the dynamic distribution of ATPase reflected which cell component was actively taking part in the cell metabolism at various stages of the plant development, and its distribution was associated with the physiological state of the cell. Based on the characteristic distributions of ATPase, the critical stage of cell differentiation and the relationship between the critical stage and dedifferentiation were discussed.     

Changes in Root Hydraulic Conductivity During Wheat Evolution

A better understanding of the mechanisms of water uptake by plant roots should be vital for improving drought resistance and water use efficiency (WUE). In the present study, we have demonstrated correlations between root system hydraulic conductivity and root characteristics during evolution using six wheat evolution genotypes (solution culture) with different ploidy chromosome sets (Triticum boeoticum Bioss., T. monococcum L.: 2n = 2x = 14; T. dicoccides Koern., T. dicoccon (Schrank) Schuebl.: 2n = 4x = 28;T. vulgare Vill., T. aestivum L. cv. Xiaoyan No. 6: 2n = 6x = 42). The experimental results showed that significant correlations were found between root system hydraulic conductivity and root characteristics of the materials with the increase in ploidy chromosomes (2x→6x) during wheat evolution. Hydraulic conductivity of the wheat root system at the whole-plant level was increased with chromosome ploidy during evolution, which was positively correlated with hydraulic conductivity of single roots, whole plant biomass,root average diameter, and root growth (length, area), whereas the root/shoot ratio had an inverse correlation with the hydraulic conductivity of root system with increasing chromosome ploidy during wheat evolution. Therefore, it is concluded that that the water uptake ability of wheat roots was strengthened from wild to modern cultivated species during evolution, which will provide scientific evidence for genetic breeding to improve the WUE of wheat by genetic engineering.     

Changes in Root Hydraulic Conductivity During Wheat Evolution

A better understanding of the mechanisms of water uptake by plant roots should be vital for improving drought resistance and water use efficiency (WUE). In the present study, we have demonstrated correlations between root system hydraulic conductivity and root characteristics during evolution using six wheat evolution genotypes (solution culture) with different ploidy chromosome sets (Triticum boeoticum Bioss., T. monococcum L.: 2n=2x=14;T. dicoccides Koern., T. dicoccon (Schrank) Schuebl.:2n=4x=28;T. vulgare Vill., T. aestivum L. cv. Xiaoyan No. 6:2n=6x=42). The experimental results showed that significant correlations were found between root system hydraulic conductivity and root characteristics of the materials with the increase in ploidy chromosomes (2x→6x) during wheat evolution. Hydraulic conductivity of the wheat root system at the whole-plant level was increased with chromosome ploidy during evolution, which was positively correlated with hydraulic conductivity of single roots, whole plant biomass,root average diameter, and root growth (length, area), whereas the root/shoot ratio had an inverse correlation with the hydraulic conductivity of root system with increasing chromosome ploidy during wheat evolution. Therefore, it is concluded that that the water uptake ability of wheat roots was strengthened from wild to modern cultivated species during evolution, which will provide scientific evidence for genetic breeding to improve the WUE of wheat by genetic engineering.     

杜仲次生木质部细胞分化和脱分化过程中ATPase的超微细胞化学定位

采用磷酸铅沉淀技术,对杜仲（Ｅｕｃｏｍｍｉａ ｕｌｍｏｉｄｅｓ Ｏｌｉｖ．）次生木质部细胞分和脱化过程进行了ＡＴＰａｓｅ的超微细胞化学定位。随着分化过程中细胞程序性死亡（ｐｒｏｇｒａｍｍｅｄ ｃｅｌｌ ｄｅａｔｈ,ＰＣＤ）程度的加深,ＡＴＰａｓｅ在细胞核上的分布由少变多,而在各种细胞器上的分布由有到无,并且随着细胞质的解体,ＡＴＰａｓｅ在细胞壁内侧和纹孔处的分布也由少到多,说明它们的变化是由核基因     

Programmed Cell Death During the Vessel Element Differentiation of the Secondary Xylem in Eucommia ulmoides Shoots

The result from in situ end-labelling of fragmented DNA indicated that the vessel element differentiation of the secondary xylem in Eucommia ulmoides Oliv. was a typical programmed cell death (PCD) which involved a series of events, viz. synthesis of components essential for the secondary wall formation and a well organized succession of protoplast degeneration and autolysis in the tracheary cells. The nuclei gradually became irregular with highly condensed chromatin. In some nuclei, the cistema of the nuclear envelope became unevenly dilated within which some inner membrane protrusion enclosed with nuclear materials were present. The nuclear envelope underwent disruption and the nucleus eventually degenerated. However, as the nucleus was one of the most stable components in the cell, it was among the last organelles disappeared during the autolytic process. In the process, there were two forms of degeneration in the mitochondria (Mit). In one form the Mit shrank and became disorganized; in the other, part of the matrix in the Mit became electron-lucent with breakage of the membrane nearby. The cytoplasmic component residues were phagocitized and sequestered by the dilated rough endoplasmic reticulum (RER) cisternae. The RER and vacuoles did play a vital role in the further degeneration of other organelles just similar to the lysosomes acting in the animal cells. The autolyzed debri might be utilized in situ by taking part in the formation of secondary wall or be transported to the adjacent cells through the pits.     

盐胁迫下大麦根系木质部压力的自调节现象

用植物木质部压力探针测定的结果表明,水培大麦幼苗根的木质部压力在环境条件恒定不变时始终保持波动,并且在受到轻度的盐胁迫和当盐胁迫解除时表现出高度的自调节现象.这种波动和自调节现象将对植物水势的测定和根的径向反射系数的测定产生很大的影响,并可能与植物的抗盐性有关.小麦根在同样条件下未表现出上述现象.     

Potassium Translocation into the Root Xylem

Abstract: Potassium is the most abundant cation in cells of higher plants and plays vital roles in plant growth and develop ment. Since the soil is the only source of potassium, plant roots are well adapted to exploit the soil for potassium and supply it to the leaves. Transport across the root can be divided into three stages: uptake into the root symplast, transport across the symplast and release into the xylem. Uptake kinetics of potassium have been studied extensively in the past and sug gested the presence of high and low affinity systems. Molecular and electrophysiological techniques have now confirmed the existence of discrete transporters encoded by a number of genes. Surprisingly, detailed characterisation of the transpor ters using reverse genetics and heterologous expression shows that a number of the transporters (AKT and AtKUP family) func tion both in the low (μM) and high (mM) K⁺ range. Electrophy siological studies indicate that K⁺ uptake by roots is coupled to H⁺, to drive uptake from micromolar K⁺. However, thus far only Na⁺ coupled K⁺ transport has been demonstrated (HKT1). Ion channels play a major role in the exchange of potassium be tween the symplast and the xylem. An outward rectifying chan nel (KORC) mediates potassium release. Cloning of the gene en coding this channel (SKOR) shows that it belongs to the Shaker super-family. Both electrophysiological and genetic studies demonstrate that K⁺ release through this channel is controlled by the stress hormone abscisic acid. Interestingly, xylem par enchyma cells of young barley roots also contain a number of in ward rectifying K⁺ channels that are controlled by G-proteins. The involvement of G-proteins emphasises once more that po tassium transport at the symplast/xylem boundary is under hor monal control. The role of the electrical potential difference across the symplastxylem boundary in controlling potassium release is discussed.     

Mechanism of Xylem Differentiation in Pinus silvestrisL.

The duration and daily rate of radial growth and secondary-wallformation of all consecutive, radially-formed tracheids throughoutthe season were investigated in stems of adult trees of Pinussilvestris L. It was found that (1) the variation in radial diameter of tracheidswas probably dependent on seasonal changes in the rate of growthduring the phase of radial enlargement, (2) the daily rate ofcell-wall formation determined the final cell-wall thicknessof tracheids only at the beginning and the end of the season,(3) both rates were affected by temperature, (4) seasonal changesin cell-wall thickness were dependent mostly upon seasonal changesin the duration of the maturation period, (5) the changes inthe duration of the maturation period which brought about transitionfrom early to late wood were determined mostly by the delayin onset of autolysis of cytoplasm which terminates the phaseof tracheid maturation. This process, unlike the xylem productionfrom cambium and the termination of radial enlargemnt, was foundnot to be affected by the seasonal variation of temperature. An attempt to correlate these processes with the activity ofnatural auxin extracted from the cambial region gave negativeresults. On the basis of the results obtained, auxin and environmentalfactors such as precipitation and temperature seem not to bespecific for xylem differentiation. They may seriously affectwood differentiation if they become limiting or exceed the limitof tolerance, but probably they do not determine differentiationof the annual ring of conifers into early and late wood.     

Some Constituents of Xylem Sap and their Possible Relationship to Xylem Differentiation

Bleeding sap of Actinidia chinensis and Betula populifolia andguttation fluidof Avena sativa were analysed for sugars, amino-acids,auxin, and certain enzymes. A wide range of amino-acids wasfound in all three. Auxin was not detected in the bleeding sap,but was present in Avena guttation fluid (5.1 µg IAA equivalent/l).‘IAA oxidase’, acid phosphatase, ribonuclease, deoxyribonuclease,and protease were detected in the bleeding sap and guttationfluid. The possibility that some of the substances found insap and guttation fluid are products of autolysing, differentiatingxylem cells in the roots is discussed.