Sites of accumulation in excised Phloem and vascular tissues

Excised pieces of vascular bundle and phloem tissue were allowed to accumulate radioactive phosphate and sulfate, and were then sectioned and autoradiographed so as to detect the sites of accumulation. Special methods were needed to prevent any diffusion of the radioisotope. Some autoradiographs obtained are presented. In excised celery vascular bundles, the most radioactive area and hence the most actively accumulating tissue was the young secondary phloem at the sides of the bundle. In intact plants, the same tissue was the most active in translocating. In excised apple phloem there was some variation in behavior, but again the young secondary phloem was generally the most actively accumulating tissue. Accumulation activities of individual cells in the phloem and vascular tissue were compared. It appeared that all cell types, ray, phloem and xylem parenchyma, cambial cells and sieve tubes, accumulated at least 5 times more actively than did the cortical parenchyma cells. The sieve tubes were among the most actively accumulating cells present, accumulating 20 times more actively than the cortical parenchyma cells. It is concluded that accumulation processes have a primary role to play in the mechanism of phloem transport.     

Sul trasporto dei glucidi nelle piante superiori: I. — Aspetti biochimici

Abstract

CARBOHYDRATE TRANSLOCATION IN HIGHER PLANTS. I. - BIOCHEMICAL ASPECTS. — The concentration of soluble sugars and of hexose phosphates and the activity of several enzymes involved in hexose activation and polysaccaride synthesis have been investigated, separately, in the phloematic tissue and in the medullar parenchyma of Cucurbita Pepo internodes.

In the phloematic tissue (including sieve tubes, companion cells and phloematic parenchyma) the concentration of free hexoses appeared of about 50% lower, and that of glucose-6-P and of sucrose of about 100% higher then in the medullar parenchyma. Consistent amounts of raffinose were found only in the phloematic tissue. Paper chromatograms of the sieve tube exudate showed the presence of raffinose and sucrose in a ratio close to unity, and no appreciable amounts of free hexoses.

Determination of enzyme activity on preparations obtained from homogenates from the two types of tissue by repeated ammonium sulfate precipitation showed in the phloematic tissue a high activity of the enzymes hexokinase, UDP-kinase, UDPG-pyrophosphorylase and inorganic pyrophosphatase. The presence in the same tissue of galactosekinase, UDP-Gal-pyrophosphorylase and UDPG-epimerase was also ascertained.

On a protein basis, the activity of UDPG-pyrophosphorylase, inorganic pyrophosphatase and hexokinase appared about 3 times higher in the phloematic tissue than in the parenchyma; while this difference between the two tissues was not so marked for phosphofructokinase, and very small for other enzymes such as ATP-ase and phosphomono-esterase.

These results suggest that the very high activity, in the phloem cells neighbouring the sieve tubes, of the enzyme system catalyzing oligopolysaccaride synthesis could be an important component of the mechanism involved in the accumulation of oligopolysaccarides in the sieve tubes, and thus in sugar translocation. A scheme is proposed according to which the ATP and UTP energy would be utilized by the phloem cells to reach and to maintein a concentration of soluble sugars consistently higher than that prevailing in the contiguous tissues.     

Sucrose-metabolizing enzymes in transport tissues and adjacent sink structures in developing citrus fruit

Juice tissues of citrus lack phloem; therefore, photosynthates enroute to juice sacs exit the vascular system on the surface of each segment. Areas of extensive phloem unloading and transport (vascular bundles + segment epidermis) can thus be separated from those of assimilate storage (juice sacs) and adjacent tissues where both processes occur (peel). Sugar composition, dry weight accumulation, and activities of four sucrose-metabolizing enzymes (soluble and cell-wall-bound acid invertase, alkaline invertase, sucrose synthase, and sucrose phosphate synthase) were measured in these transport and sink tissues of grapefruit (Citrus paradisi Macf.) to determine more clearly whether a given enzyme appeared to be more directly associated with assimilate transport versus deposition or utilization. Results were compared at three developmental stages. Activity of sucrose (per gram fresh weight and per milligram protein) extracted from zones of extensive phloem unloading and transport was significantly greater than from adjacent sink tissues during the stages (II and III) when juice sacs grow most rapidly. In stage II fruit, activity of sucrose synthase also significantly surpassed that of all other sucrose-metabolizing enzymes in extracts from the transport tissues (vascular bundles + segment epidermis). In contrast, sucrose phosphate synthase and alkaline invertase at this stage of growth were the most active enzymes from adjacent, rapidly growing, phloem-free sink tissues (juice sacs). Activity of these two enzymes in extracts from juice sacs was significantly greater than that form the transport tissues (vascular bundles + segment epidermis). Soluble acid invertase was the most active enzyme in extracts from all tissues of very young fruit (stage I), including nonvascular regions, but nearly disappeared prior to the onset of juice sac sugar accumulation. The physiological function of high sucrose synthase activity in the transport tissues during rapid sucrose import remains to be determined.     

掌叶大黄根多糖的积累分布特征

采用组织化学方法和苯酚硫酸比色法研究了掌叶大黄（Rheum palmatum）根中大黄多糖的贮藏分布特征和含量变化规律。结果表明：大黄多糖在根内的贮藏是多位点的,在根周皮的栓内层、次生维管组织的薄壁细胞内不同程度地贮藏和积累了一定数量的大黄多糖,次生木质部的木薄壁细胞和次生韧皮部的韧皮薄壁细胞是主要贮藏和积累的部位;不同发育时期根中大黄多糖含量的变化规律为,随着植物的不断成熟,根及其各组织中大黄多糖的总含量表现为逐渐增高的趋势,但在发育的后期略有下降;韧皮薄壁细胞与木薄壁细胞相比,贮藏大黄多糖的含量相对较多,大黄多糖的贮藏积累方式为逐渐累积的方式。     

Effects of low light on phloem ultrastructure and subcellular localization of sucrose synthase in <Emphasis Type="Italic">Prunus persica</Emphasis> L. var. <Emphasis Type="Italic">nectarina</Emphasis> Ait. fruit

Using electron microscopy, the ultrastructure of phloem unloading zone was examined in the Prunus persica L. var. nectarina Ait. fruit. Our study showed that, in the SE/CC (sieve element/companion cell) complexes, CC developing under low light had a thin cytoplasm layer with few mitochondria and numerous small vacuoles, and not clearly seen nuclei. The cytoplasm vacuolation indicated that the cytoskeleton was destroyed at low light. The effects of low light on CC development suggest that unloading evidently linked to the low accumulation of soluble sugars by fruit. At the young fruit stage, flesh parenchyma around the phloem tissue had no starch grains in the plastids in fruit developing under low light. This is a further indication that less photoassimilates was translocated from source leaves to fruit sinks under low light during the young fruit developmental stage. The activity of sucrose synthase (SuSy), the key enzyme of sucrose metabolism in fruit, increased dramatically during fruit maturation. The highest SuSy activity during the rapid fruit growth phase suggests that sink strength could be correlated with the SuSy activity. The high SuSy activity under normal light possibly indicates that fruit had a capacity to utilize sucrose irrespective of their site of phloem unloading. Immunogold electron microscopy showed that SuSy was localized mainly in the vacuole of flesh parenchyma cells. The vacuole-localized SuSy can hydrolyze sucrose imported from the phloem, which may explain the apparent correlation between SuSy activity and phloem unloading. The double sieve element (SE/SE) complexes occurred in a greater number and had thicker cell walls under normal light intensity than under low light intensity. These data demonstrate clearly that low light decreased SuSy activity in the control of phloem unloading. Published in Russian in Fiziologiya Rastenii, 2009, Vol. 56, No. 4, pp. 509–517. This text was submitted by the authors in English.     

Expression patterns of vascular-specific promoters RolC and Sh in transgenic potatoes and their use in engineering PLRV-resistant plants

The expression patterns of GUS fusion constructs driven by the Agrobacterium rhizogenes RolC and the maize Sh (Shrunken; sucrose synthase-1) promoters were examined in transgenic potatoes (cv. Atlantic). RolC drove high-level gene expression in phloem tissue, bundle sheath cells and vascular parenchyma, but not in xylem or non-vascular tissues. Sh expression was exclusively confined to phloem tissue. Potato leafroll luteovirus (PLRV) replicates only in phloem tissues, and we show that when RolC is used to drive expression of the PLRV coat protein gene, virus-resistant lines can be obtained. In contrast, no significant resistance was observed when the Sh promoter was used.     

Companion-Cell Specific Localization of Sucrose Synthase in Zones of Phloem Loading and Unloading

An immunohistochemical approach was used in maize (Zea mays) and citrus (Citrus paradisi) to address the previously noted association between sucrose synthase and vascular bundles and to determine the localization of the low but detectable levels of sucrose synthase that remain in leaves after the import-export transition. Sucrose synthase protein was immunolocalized at the light microscope level using paraffin sections reacted with rabbit sucrose synthase polyclonal antisera and gold-conjugated goat anti-rabbit immunoglobulin G. Immunolabel was specifically observed in phloem companion cells of minor and intermediate veins in mature leaves of both species. Similar localization was apparent in the midrib of mature citrus leaves, with additional labeling in selected files of phloem parenchyma cells. A clear companion-cell specificity was evident in the phloem unloading zone of citrus fruit, where high activity of sucrose synthase has been demonstrated in vascular bundles during periods of rapid import. Sucrose synthase protein was not associated with adjacent cells surrounding the vascular strands in this tissue. The companion-cell specificity of sucrose synthase in phloem of both importing and exporting structures of these diverse species implies that this may be a widespread association and underscores its potential importance to the physiology of vascular bundles.     

Symplastic connection is required for bud outgrowth following dormancy in potato (Solanum tuberosum L.) tubers

To gain greater insight into the mechanism of dormancy release in the potato tuber, an investigation into physiological and biochemical changes in tuber and bud tissues during the transition from bud dormancy (immediately after harvest) to active bud growth was undertaken. Within the tuber, a rapid shift from storage metabolism (starch synthesis) to reserve mobilization within days of detachment from the mother plant suggested transition from sink to source. Over the same period, a shift in the pattern of [U-(14)C]sucrose uptake by tuber discs from diffuse to punctate accumulation was consistent with a transition from phloem unloading to phloem loading within the tuber parenchyma. There were no gross differences in metabolic capacity between resting and actively growing tuber buds as determined by [U-(14)C]glucose labelling. However, marked differences in metabolite pools were observed with large increases in starch and sucrose, and the accumulation of several organic acids in growing buds. Carboxyfluorescein labelling of tubers clearly demonstrated strong symplastic connection in actively growing buds and symplastic isolation in resting buds. It is proposed that potato tubers rapidly undergo metabolic transitions consistent with bud outgrowth; however, growth is initially prevented by substrate limitation mediated via symplastic isolation.     

掌叶大黄根茎大黄多糖的贮藏和分布特征

采用组织化学方法和苯酚硫酸比色法研究了大黄多糖在掌叶大黄(Rheum palmatum)根茎中的贮藏分布特征及其含量变化规律。结果表明: 大黄多糖在根茎中呈多位点贮藏, 在根茎的周皮、皮层、次生维管组织的薄壁细胞以及髓内不同程度地贮藏和积累了一定数量的大黄多糖, 次生木质部的木薄壁细胞以及次生韧皮部的韧皮薄壁细胞是大黄多糖的主要贮藏和积累部位; 不同发育时期根茎中大黄多糖含量的变化规律为: 随着植物的生长, 根茎及其各组织中大黄多糖的总含量表现为逐渐增高的趋势, 但在发育的后期略有下降; 与木薄壁细胞相比, 韧皮薄壁细胞贮藏大黄多糖量相对较多, 大黄多糖的贮藏和积累方式为逐渐累积。次生维管组织为大黄多糖贮藏和积累的主要组织。     

掌叶大黄根茎大黄多糖的贮藏和分布特征

采用组织化学方法和苯酚硫酸比色法研究了大黄多糖在掌叶大黄（Rheum palmatum）根茎中的贮藏分布特征及其含量变化规律。结果表明：大黄多糖在根茎中呈多位点贮藏,在根茎的周皮、皮层、次生维管组织的薄壁细胞以及髓内不同程度地贮藏和积累了一定数量的大黄多糖,次生木质部的木薄壁细胞以及次生韧皮部的韧皮薄壁细胞是大黄多糖的主要贮藏和积累部位;不同发育时期根茎中大黄多糖含量的变化规律为：随着植物的生长,根茎及其各组织中大黄多糖的总含量表现为逐渐增高的趋势,但在发育的后期略有下降;与木薄壁细胞相比,韧皮薄壁细胞贮藏大黄多糖量相对较多,大黄多糖的贮藏和积累方式为逐渐累积。次生维管组织为大黄多糖贮藏和积累的主要组织。     

Modification of a Specific Class of Plasmodesmata and Loss of Sucrose Export Ability in the sucrose export defective1 Maize Mutant

We report on the export capability and structural and ultrastructural characteristics of leaves of the sucrose export defective1 (sed1; formerly called sut1) maize mutant. Whole-leaf autoradiography was combined with light and transmission electron microscopy to correlate leaf structure with differences in export capacity in both wild-type and sed1 plants. Tips of sed1 blades had abnormal accumulations of starch and anthocyanin and distorted vascular tissues in the minor veins, and they did not export sucrose. Bases of sed1 blades were structurally identical to those of the wild type and did export sucrose. Electron microscopy revealed that only the plasmodesmata at the bundle sheath-vascular parenchyma cell interface in sed1 minor veins were structurally modified. Aberrant plasmodesmal structure at this critical interface results in a symplastic interruption and a lack of phloem-loading capability. These results clarify the pathway followed by photosynthates, the pivotal role of the plasmodesmata at the bundle sheath-vascular parenchyma cell interface, and the role of the vascular parenchyma cells in phloem loading.     

Onset of Phloem Export from Senescent Petals of Daylily

During senescence, petals of attached daylily (Hemerocallis hybrid cv Cradle Song) flowers lost 95% sugar and 65% dry weight over the first 24 h, with 30% of dry weight loss coming from nonsugar components. Detaching flowers did not delay senescence, but halted loss of carbohydrate and amino acid, suggesting that loss in the intact state was due to phloem export. Petal autolysis occurred mainly in the interveinal parenchyma, causing vascular strands to begin separating from the petal mass. Such vascular strands still stained with tetrazolium and accumulated sucrose, indicating a retained viability. Their sucrose accumulation rates were high in comparison with those of other plant tissues, and the accumulated product was mainly sucrose. Sucrose synthesis took place in the senescent petal, and sucrose was the principal sugar in phloem exudate, whereas hydroxyproline and glutamine were the main transport amino acids. [14C]Sucrose applied to attached senescent flowers was rapidly translocated to other parts of the plant, particularly developing flower buds. Thus, onset of phloem export allowed most of the soluble carbohydrate and amino acid in the senescing flower to be retrieved by the plant. Additional salvaged material came from proteins and possibly from structural carbohydrate. Over a 12-h period, the flower switched from acting as a strong carbohydrate sink during expansion to become a strong source during senescence. This rapid reversal offers potential for phloem transport studies.     

六盘山鸡爪大黄根蒽醌类化合物组织化学定位的研究

采用组织化学方法研究了六盘山鸡爪大黄根蒽醌类化合物的组织化学定位特征及贮藏和积累的规律。结果表明：蒽醌类化合物在根内的贮藏是多位点的,在根周皮的木栓层和栓内层、次生维管组织的维管射线和根中央的部分木薄壁细胞内不同程度地贮藏和积累了一定数量的蒽醌类化合物,次生木质部的木射线和次生韧皮部的韧皮射线是主要贮藏和积累的部位,早期形成的维管射线中蒽醌类化合物的含量较晚期形成的射线含量高。     

Study of sucrose and mannitol transport in plasma-membrane vesicles from phloem and non-phloem tissues of celery (Apium graveolens L.) petioles

The mature petiole of celery is an organ with versatile sink/source capacities where sucrose and mannitol are unloaded from and reloaded into the phloem cells. Plasma-membrane vesicles were purified by twophase partitioning either from phloem strands isolated from mature petioles of celery (Apium graveolens L.) or from mature petioles devoid of vascular bundles. Both types of vesicle were comparable in purity (more than 86% of plasma-membrane origin), size (135 nm diameter) and orientation (72% right-side-out). Plasma-membrane vesicles from phloem tissues had a higher vanadate-sensitive ATPase activity than plasma-membrane vesicles from petioles. Plasma-membrane vesicles from phloem tissues accumulated mannitol and sucrose in response to an artificial proton-motive force, in agreement with the existence of proton/substrate carriers. Plasma-membrane vesicles from petioles devoid of vascular bundles accumulated only mannitol following application of an artificial proton-motive force. The data suggest the volvement of apoplasmic transport events. The pathway for sucrose uptake in storage parenchyma cells is discussed in the light of the available physiological data.     

In vitro and in vivo modification of sugar transport and translocation in celery by phytohormones

In an attempt to address the controversy in the literature as to whether phytohormones have any direct effect on phloem loading of sucrose, we investigated the effect of gibberellic acid (GA₃) and indoleacetic acid (IAA) on sugar transport and translocation in celery (Apium graveolens L. cv. Utah 5270). Both hormones enhanced sucrose uptake into isolated vascular bundles and phloem tissue of celery and enhanced the export of ¹⁴C assimilates from leaves of intact plants in vivo. The hormone-induced increase of uptake into isolated vascular bundles or phloem was specific for sucrose and mannitol which are translocated in phloem. Furthermore, the hormone-induced increase in translocation was not due to an increase in sink demand, since neither glucose nor sucrose uptake rates were affected in the storage parenchyma tissue discs (sink region) in the presence of GA₃ or IAA. The evidence suggests that phytohormones may have a direct effect on phloem loading of sucrose. The possibility of short-term GA₃ and IAA effects on processes resulting in membrane transport of sugars in celery is discussed.     

VARIATIONS IN ANATOMY,ASSOCIATIONS, AND ORIGINS OF KRANZ TISSUE

Although the unique tissue required for C₄ photosynthesis in nonsucculent plants is often described as being modified leaf parenchyma sheath, which is positioned meaningfully between the mesophyll externally and the vascular tissues internally, the actual range of locations and known associations make that concept untenable. In origin the Kranz tissue develops from procambium as well as ground parenchyma. It is found in stems as well as leaves. In position Kranz tissue can lie in the parenchyma sheath, in the mestome sheath, isolated in the mesophyll, peripherally in some thick leaves, or within the veins. It can be associated with mesophyll only, mesophyll and colorless parenchyma, mesophyll and sclerenchyma, other Kranz tissue and vascular tissues, mesophyll and mestome sheath, mesophyll and phloem, mesophyll and xylem, epidermis, and, finally, mestome sheath and xylem and phloem. The use of the term Kranz is expounded.     

Developmental Changes in the Anatomy of the Sugarcane Stem in Relation to Phloem Unloading and Sucrose Storage

Transverse sections of immature and mature sugarcane internodes were investigated anatomically with white and fluorescence light microscopy. The pattern of lignification and suberization was tested histo-chemically. Lignification began in the xylem of vascular bundles and progressed through the sclerenchymatic bundle sheath into the storage parenchyma. Suberization began in parenchyma cells adjacent to vascular bundle sheaths and spread to the storage parenchyma and outer sheath cells. In mature internodes most of the storage parenchyma was lignified and suberized to a significant degree, except in portions of walls of isolated cells. The pattern of increasing lignification and suberization in maturing internodes more or less paralleled an increase of sucrose in stem tissue. In mature internodes having a high sucrose concentration, the vascular tissue was surrounded by thick-walled, lignified and suberized sclerenchyma cells. The apoplastic tracer dyes triso-dium 3-hydroxy-5,8,10-pyrenetrisulfonate (PTS) and amido black 10 B, fed into cut ends of the stalk, wereconfined to the vascular bundles in all internodes above the one that was cut — with no dye apparently in storage parenchyma tissue. Thus both structural and experimental evidence is consistent with vascular tissue being increasingly isolated from the storage parenchyma as maturation of the tissue proceeds. We conclude that in mature internodes the pathway for sugars from the phloem to the storage parenchyma is symplastic. The data suggest that an increasingly greater role for a symplastic pathway of sugar transfer occurs as the tissue undergoes lignification/suberization.     

The small subunit ADP-glucose pyrophosphorylase (<Emphasis Type="Italic">ApS</Emphasis>) promoter mediates okadaic acid-sensitive<Emphasis Type="Italic"> uidA</Emphasis> expression in starch-synthesizing tissues and cells in<Emphasis Type="Italic"> Arabidopsis</Emphasis>

Transgenic plants of Arabidopsis thaliana Heynh., transformed with a bacterial beta-glucuronidase (GUS) gene under the control of the promoter of the small subunit (ApS) of ADP-glucose pyrophosphorylase (AGPase), exhibited GUS staining in leaves (including stomata), stems, roots and flowers. Cross-sections of stems revealed GUS staining in protoxylem parenchyma, primary phloem and cortex. In young roots, the staining was found in the root tips, including the root cap, and in vascular tissue, while the older root-hypocotyl axis showed prominent staining in the secondary phloem and paratracheary parenchyma of secondary xylem. The GUS staining co-localized with ApS protein, as found by tissue printing using antibodies against ApS. Starch was found only in cell and tissue types exhibiting GUS staining and ApS labelling, but not in all of them. For example, starch was lacking in the xylem parenchyma and secondary phloem of the root-hypocotyl axis. Sucrose potently activated ApS gene expression in leaves of wild-type (wt) plants, and in transgenic seedlings grown on sucrose medium where GUS activity was quantified with 4-methylumbelliferyl-beta-glucuronide as substrate. Okadaic acid, an inhibitor of protein phosphatases 1 and 2A, completely blocked expression of ApS in mature leaves of wt plants and prevented GUS staining in root tips and flowers of the transgenic plants, suggesting a similar signal transduction mechanism for ApS expression in various tissues. The data support the key role of AGPase in starch synthesis, but they also underlie the ubiquitous importance of the ApS gene for AGPase function in all organs/tissues of Arabidopsis.     

Anomalous secondary vascular tissue inHelminthostachys zeylanica (Ophioglossaceae)

The vascular anatomy ofHelminthostachys zeylanica was examined with special reference to anomalous secondary tissue. Primary xylem development gradually takes place centrifugally. In branched rhizomes with destroyed apices, the vascular cylinder apical to the insertion of branch traces is generally composed of primary xylem, accessory xylem, inner parenchyma of radially arranged cells, outer parenchyma of irregularly arranged cells, and partly crushed phloem, listed in order going outwards. The accessory xylem as well as the inner parenchyma ofHelminthostachys zeylanica is probably secondarily produced, partly to contribute to the branch traces, in a position corresponding to that of secondary vascular tissue developed from a normal cambium inBotrychium sensu lato. It is suggested that although a cambium is lacking inHelminthostachys zeylanica, the secondary vascular tissues are comparable between the genera. The phylogenetic implication of this tissue is discussed.