The phloem necrosis virus disease of tea in Ceylon; further characterization of necrosis in the leaf

Phloem necrosis due to the virus disease of that name in tea is fully described as it affects the leaf, on which diagnosis is chiefly based. Originating in the protophloem, it may extend inwards to the metaphloem and outwards to the pericycle, causing the breakdown and discoloration of the cells and their eventual death and obliteration, cell enlargement, and the production of new thin-walled cells by hyperplasia. The condition is termed 'true necrosis' to distinguish it from the non-pathogenic 'false necrosis', of unknown cause, which originates typically in the metaphloem but may have the same histological effects except for the absence of hyperplasia. In the petiole, the visual distinction between 'true' and 'false' necrosis on the basis of their position as seen in a transverse section of the bundle is relatively easy, and the continued use of this method of diagnosis is recommended. No such distinction can reliably be made in the midrib, where 'false' necrosis often occurs in the same position as 'true' necrosis, i.e. immediately within the pericycle. This is interpreted ontogenetically in terms of the smaller total width of the phloem in the midrib as compared with the petiole bundle; it effectively prevents the use of the midrib for diagnosis. The observations are discussed in terms of the inherent properties of the phloem, as affected by viruses and other agencies reported to have caused necrosis, among plants in general.     

Tuberization in potato involves a switch from apoplastic to symplastic phloem unloading

Phloem unloading was studied in potato plants in real time during the early stages of tuberization using carboxyfluorescein (CF) as a phloem-mobile tracer, and the unloading pattern was compared with autoradiography of tubers that had transported (14)C assimilates. In stolons undergoing extension growth, apoplastic phloem unloading predominated. However, during the first visible signs of tuberization, a transition occurred from apoplastic to symplastic transport, and both CF and (14)C assimilates subsequently followed identical patterns of phloem unloading. It is suggested that the switch to symplastic sucrose unloading may be responsible for the upregulation of several genes involved in sucrose metabolism. A detailed analysis of sugar levels and (14)C sugar partitioning in tuberizing stolons revealed a distinct difference between the apical region of the tuber and the subapical region. Analysis of invertase activity in nontuberizing and tuberizing stolons revealed a marked decline in soluble invertase in the subapical region of swelling stolons, consistent with the switch from apoplastic to symplastic unloading. However, cell wall-bound invertase activity remained high in the apical 1 to 2 mm of tuberizing stolons. Histochemical analysis of potato lines transformed with the promoter of an apoplastic invertase gene (invGE) linked to a reporter gene also revealed discrete gene expression in the apical bud region. Evidence is presented that the apical and lateral tuber buds function as isolated domains with respect to sucrose unloading and metabolism.     

Cadmium loading into potato tubers: the roles of the periderm, xylem and phloem

The mobility of Cd in potato plants (Solanum tuberosum) was examined using both short‐term radioisotopic labelling with ¹⁰⁹Cd and long‐term growth experiments in soil supplemented with Cd, with an emphasis on the pathways through which Cd is taken up by tubers. Split‐pot experiments showed that tubers and their associated stolons and stolon roots contribute only a minor fraction to the overall Cd absorption by the plant. Most of the Cd was absorbed by the basal roots. ¹⁰⁹Cd absorbed from the soil was rapidly exported to other parts of the plant, especially the stem, with significant amounts appearing in the tubers within 30 h. Application of ¹⁰⁹Cd to leaves showed that Cd can be rapidly distributed via the phloem to all tissues. The results suggest that unlike Ca, Cd has high mobility in plants in both xylem and phloem, and that stems may have an important role in transfer between these two pathways.     

QTL mapping of internal heat necrosis in tetraploid potato

Internal heat necrosis (IHN) is a physiological disorder of potato tubers. We developed a linkage map of tetraploid potato using AFLP and SSR markers, and mapped QTL for mean severity and percent incidence of IHN. Phenotypic data indicated that the distribution of IHN is skewed toward resistance. Late foliage maturity was slightly but significantly correlated with increased IHN symptoms. The linkage map for ‘Atlantic’, the IHN-susceptible parent, covered 1034.4 cM and included 13 linkage groups, and the map for B1829-5, the IHN-resistant parent, covered 940.2 cM and contained 14 linkage groups. QTL for increased resistance to IHN were located on chromosomes IV, V, and groups VII and X of ‘Atlantic’, and on group VII of B1829-5 in at least 2 of 3 years. The QTL explained between 4.5 and 29.4% of the variation for mean severity, and from 3.7 to 14.5% of the variation for percent incidence. Most QTL detected were dominant, and associated with decreased IHN symptoms. One SSR and 13 AFLP markers that were linked to IHN were tested in a second population. One AFLP marker was associated with decreased symptoms in both populations. The SSR marker was not associated with IHN in the second population, but was closely linked in repulsion to another marker that was associated with IHN, and had the same (negative) effect on the trait as the SSR marker did in the first population. The correlation between maturity and IHN may be partially explained by the presence of markers on chromosome V that are linked to both traits. This research represents the first molecular genetic research of IHN in potato.     

Ultrastructural effects in potato leaves due to antisense-inhibition of the sucrose transporter indicate an apoplasmic mode of phloem loading

To study the export of sugars from leaves and their long-distance transport, sucrose-proton/co-transporter activity of potato was inhibited by antisense repression of StSUT1 under control of either a ubiquitously active (CaMV 35S ) or a companion-cell-specific (rolC) promotor in transgenic plants. Transformants exhibiting reduced levels of the sucrose-transporter mRNA and showing a dramatic reduction in root and tuber growth, were chosen to investigate the ultrastructure of their source leaves. The transformants had a regular leaf anatomy with a single-layered palisade parenchyma, and bicollateral minor veins within the spongy parenchyma. Regardless of the promoter used, source leaves from transformants showed an altered leaf phenotype and a permanent accumulation of assimilates as indicated by the number and size of starch grains, and by the occurrence of lipid-storing oleosomes. Starch accumulated throughout the leaf: in epidermis, mesophyll and, to a smaller degree, in phloem parenchyma cells of minor veins. Oleosomes were observed equally in mesophyll and phloem parenchyma cells. Companion cells were not involved in lipid accmulation and their chloroplasts developed only small starch grains. The similarity of ultrastructural symptoms under both promotors corresponds to, rather than contradicts, the hypothesis that assimilates can move symplasmically from mesophyll, via the bundle sheath, up to the phloem. The microscopical symptoms of a constitutively high sugar level in the transformant leaves were compared with those in wild-type plants after cold-girdling of the petiole. Inhibition of sugar export, both by a reduction of sucrose carriers in the sieve element/companion cell complex (se/cc complex), or further downstream by cold-girdling, equally evokes the accumulation of assimilates in all leaf tissues up to the se/cc complex border. However, microscopy revealed that antisense inhibition of loading produces a persistently high sugar level throughout the leaf, while cold-girdling leads only to local patches containing high levels of sugar. Received: 4 March 1998 / Accepted: 7 April 1998     

Diversity of the superfamily of phloem lectins (phloem protein 2) in angiosperms

Phloem protein 2 (PP2) is one of the most abundant and enigmatic proteins in the phloem sap. Although thought to be associated with structural P-protein, PP2 is translocated in the assimilate stream where its lectin activity or RNA-binding properties can exert effects over long distances. Analyzing the diversity of these proteins in vascular plants led to the identification of PP2-like genes in species from 17 angiosperm and gymnosperm genera. This wide distribution of PP2 genes in the plant kingdom indicates that they are ancient and common in vascular plants. Their presence in cereals and gymnosperms, both of which lack structural P-protein, also supports a wider role for these proteins. Within this superfamily, PP2 proteins have considerable size polymorphism. This is attributable to variability in the length of the amino terminus that extends from a highly conserved domain. The conserved PP2 domain was identified in the proteins encoded by six genes from several cucurbits, celery (Apium graveolens), and Arabidopsis that are specifically expressed in the sieve element-companion cell complex. The acquisition of additional modular domains in the amino-terminal extensions of other PP2-like proteins could reflect divergence from its phloem function.     

Differential expression of invertase genes in internal and external phloem tissues of potato (Solanum tuberosum L.)

The cloning of promoter sequences of two invertase genes from potato (Solanum tuberosum L.) is described. Histochemical analysis of series of reporter transgenic lines reveals phloem-specific expression from both promoters, with one expressed preferentially in internal phloem and the other in external phloem of stem vascular bundles.     

桉树树干维管形成层和次生韧皮部热致细胞坏死的定量试验

桉树树干维管形成层和次生韧皮部热致细胞坏死的定量试验 桉树(Eucalyptus)树干暴露在森林火灾辐射热中会杀死形成层细胞及其内嵌的再生分生组织,阻止树木萌枝和恢复。目前尚无组织水平的方法来量化热处理对桉树形成层细胞活力的影响。本研究的目 标包括：(1)采用并验证四氮唑还原法检测桉树细胞活力;(2)应用该方法确定斜叶桉(Eucalyptus oblique)形成层细胞活力的阈值水平,进而确定临界温度。采用四氮唑还原法量化该桉树韧皮部-形成层细胞活力。 从斜叶桉成树上切下带有形成层和韧皮部的圆形树皮切片,将质量为1-30 mg不等的样品在20–85°C 的温 度处理中放置1分钟,并在室温条件下在0.8%的2,3,5-氯化三苯基四氮唑(TTC)中保存20–22小时以检测 细胞活力。用乙醇冷萃取得到1,3,5-三苯基四唑甲臜(TPF),在485 nm处测定吸光度。结果表明,TTC还原 法准确地量化了组织切片(包括维管形成层)中细胞活力随温度升高而下降的情况,并确定60°C 为桉树物种形成层-韧皮部细胞的临界温度。细胞活力按[TPF 处理温度]/[TPF 20°C]计算,在20-85°C之间下降90%。细胞活力结果证实,在50-70°C的温度区间,经过1分钟体外组织加热,桉树的组织坏死显著 增加。TTC 方法显示细胞活力随温度升高而下降,这与温度处理和中性红染色处理后独立获得的活细胞计 数一致。     

Adenosine triphosphatase in the phloem of Cucurbita

Summary The distribution of adenosine triphosphatase (ATPase) activity in the phloem of petioles and minor veins of Cucurbita maxima has been studied using a lead phosphate precipitation procedure. ATPase activity was localized in sieve elements, companion cells and parenchyma cells. Activity was found at the cell surfaces, associated with the dispersed P-protein of mature sieve elements, in mitochondria, sieve-element reticulum, and at specific regions of the cell walls. It is suggested that the ATPase at the phloem cell surfaces may function in intercellular transport of assimilates or ions, and that the ATPase activity associated with the P-protein may function in the translocation process or in callose deposition.     

Source-to-sink gradient of potassium in the phloem

The potassium contents of bark strips of cassava (Manihot esculenta Crantz) and of phloem exudate of castor bean (Ricinus communis L.) were analyzed at different regions of the stem. In cassava, a peak in potassium content was observed near the first mature leaf, leveling off both above and below this point. In castor bean, only a downward decreasing gradient was observed. In both plants, the direction of the potassium gradient coincided with the presumed direction of assimilate flow.     

The evolution of minor vein phloem and phloem loading

Phylogenetic analysis provides a rational basis for comparative studies of phloem structure and phloem loading. Although several types of minor vein companion cell have been identified, and progress has been made in correlating structural features of these cells with loading mechanisms, little is known about the phylogenetic relationships of the different types. To add to the available data on companion cells, we analyzed the ultrastructure of minor veins in Euonymus fortunei and Celastrus orbiculatis (Celastraceae) leaves and determined that in these species they are specialized as intermediary cells. This cell type has been implicated in symplastic phloem loading. The data were added to published data sets on minor vein phloem characteristics, which were then mapped to a well-supported molecular tree. The analysis indicates that extensive plasmodesmatal continuity between minor vein phloem and surrounding cells is ancestral in the angiosperms. Reduction in plasmodesmatal frequency at this interface is a general evolutionary trend, punctuated by instances of the reverse. This is especially true in the case of intermediary cells that have many plasmodesmata, but other distinguishing characteristics as well, and have arisen independently at least four, and probably six, times in derived lineages. The character of highly reduced plasmodesmatal frequency in minor vein phloem, common in crop plants, has several points of origin in the tree. Thus, caution should be exercised in generalizing results on apoplastic phloem loading obtained from model species. Transfer cells have many independent points of origin, not always from lineages with reduced plasmodesmatal frequency.     

Long-distance trafficking of macromolecules in the phloem

The fact that macromolecules such as proteins and mRNAs overcome the symplastic barriers between various tissue domains was first evidenced by the movement of plant viruses. We have recently demonstrated that viral infection disengages the symplastic restriction present between the sieve element-companion cell complex and neighboring cells in tobacco plants. As a result, green fluorescent protein, which was produced in mesophyll and bundle sheath cells, could traffic into the sieve tube and travel long distances within the vascular system. In this addendum we discuss the likely existence of a novel plant communication network in which macromolecules also act as long-distance trafficking signals. Plasmodesmata interconnecting sieve elements and companion cells as well as plasmodesmata connecting the sieve tube with neighboring cells may play a central role in establishing this communication network.Key words: companion cells, cucumber mosaic virus, Cucumis melo, plasmodesmata, movement protein, sieve-elementsTranslocation of photoassimilates from the source (site of synthesis) to various sink organs is governed, in part, by short-distance intercellular transfer of assimilates to the loading region of the phloem and long-distance transport within the plant vascular system. Sucrose, which is synthesized in the leaf mesophyll, moves cell-to-cell symplastically through plasmodesmata until it reaches the boundary of the sieve element (SE)-companion cell (CC) complex. In many plant species, the connection between phloem parenchyma (PP)/bundle sheath (BS) cells and CCs is characterized by a sparseness of plasmodesmata (e.g., Solanaceae), and sucrose is exported out of the cells to the apoplast. This type of plants (apoplastic loaders) uses sucrose proton symporters to load the sucrose into the vasculature.¹ Cucurbits are considered one of the model plants for symplastic phloem loading.² This type of plant is characterized by abundant plasmodesmata interconnecting the intermediary cells, which are specialized CCs, with the neighboring BS cells. It is generally accepted that in these plants, phloem loading includes intercellular movement of sucrose through the plasmodesmata, along the entire pathway from the mesophyll cell to the SE-CC complex.Interestingly, the existence of plasmodesmata interconnecting the SE-CC complex and neighboring cells is evident in all plant species that are characterized by an apoplastic phloem-loading mechanism. Moreover, microinjection experiments have indicated that plasmodesmata interconnecting the PP-CC are functional, in that they allow the exchange of small membrane-impermeable fluorescent probes.³ Virus movement through plasmodesmata from the mesophyll into the SEs further supports the notion that the symplastic communication between the CC-SE complex and the neighboring cells is functional.⁴One can assume that in apoplastic-loading plants, it would be an advantage to maintain the SE-CC complex as an isolated domain, with no functional plasmodesmata interconnecting it to the neighboring tissue. Symplastic continuity between the two domains could result in leakage of sucrose out of the vasculature and a significant reduction in the efficacy of sucrose loading. The fact that the two domains are interconnected suggests that any back-leakage of sucrose that might occur is insignificant relative to the likely efficacy of this communication route.What might the advantage be for symplastic communication between the SE-CC complex and the neighboring tissue? Accumulated evidence suggests that at the tissue/organ level, cell-to-cell trafficking of information molecules allows for noncell-autonomous control over a range of processes, whereas at the organismal level, the phloem serves as an information superhighway, delivering a wide range of macromolecules to enable the plant to function as a whole organism.^5–8 We advanced the hypothesis that plasmodesmata interconnecting the CCs and PP/BS cells play a pivotal role in controlling the long-distance trafficking of putative signaling molecules.