A method for estimating the proportion of sieve tubes in the phloem of higher plants

Summary A statistical method has been developed for the estimation of the proportion of phloem area occupied by sieve tube lumen which is applicable to most higher plants. By simple probability, the number of sieve tubes in a given area of phloem is equal to the number of sieve plates present in a series of transverse sections whose total thickness equals the mean sieve element length. The case of oblique sieve plates, where the plate is divided and occurs in more than one section, has also been dealt with and a solution obtained. Estimates of the proportion of phloem area occupied by sieve tubes have been made by this method in willow (Salix viminalis L.), sugar beet (Beta vulgaris L.) and a cucurbit (Ecballium elaterium L.) and the values obtained discussed in relation to estimates made previously by other methods.     

THE CAMBIUM AND SEASONAL DEVELOPMENT OF THE PHLOEM IN ROBINIA PSEUDOACACIA

The cambium in black locust consists of several layers of cells at all times. Cambial reactivation (division) is preceded by a decrease in density of cambial cell protoplasts and cell wall thickening but not by cell enlargement. During the resumption of cambial activity, periclinal divisions occur throughout the cambial zone. Early divisions contribute largely to the phloem side. The period of greatest cambial activity coincides with early wood formation. Judged by numerous collections made during two seasons (October, 1960-October, 1962) the seasonal cycle of phloem development is as follows. Phloem differentiation begins in early April, ends in late September. The amount of phloem produced is quite variable (range: 1-10 bands of sieve elements per year). Cessation of function begins with the accumulation of definitive callose in the first-formed sieve elements and spreads to those more recently formed. By late November all but the last-formed sieve elements are collapsed. All sieve elements are collapsed by mid-winter and before the resumption of new phloem production in spring. Phloem differentiation precedes xylem differentiation by at least 1 week, and apparently functional sieve elements are present 3 weeks before new functional vessel elements. Xylem and phloem production ends simultaneously in most trees.     

SEASONAL DEVELOPMENT OF THE SECONDARY PHLOEM IN ACER NEGUNDO

Functional sieve elements are present year-round in the secondary phloem of the trunk of Acer negundo L., the box elder tree. Judging from numerous collections made between May, 1962, and May, 1964, the seasonal cycle of phloem development is as follows: cambial activity and new phloem differentiation begin in late March or early April; xylem differentiation begins about a month later and is completed in most trees in late August. At the time of cessation of cambial activity most of the relatively wide sieve elements of the current season's increment are mature. However, numerous groups of narrow, immature sieve elements and companion cells located on the outer margin of the cambial zone do not reach maturity until fall and winter. By the time of cambial reactivation in spring, most, if not all, of these narrow elements are mature. Some of the sieve elements which reach maturity either shortly after cessation of cambial activity or during dormancy become non-functional within 6 weeks after resumption of cambial activity in spring, while others remain functional until mid-August. For the phloem increment of a given year, cessation of function begins in September with the accumulation of definitive callose on the sieve plates of the first-formed sieve elements and spreads to all but the last-formed ones by the end of December.     

SOME ULTRASTRUCTURAL ASPECTS OF METAPHLOEM SIEVE ELEMENTS IN THE AERIAL STEM OF THE HOLOPARASITIC ANGIOSPERM EPIFAGUS VIRGINIANA (OROBANCHACEAE)

A light and electron microscope investigation was conducted on phloem in the aerial stem of Epifagus virginiana (L.) Bart. Tissue was processed at field collection sites in an effort to overcome problems resulting from manipulation. At variance with earlier accounts, Epifagus phloem consists of sieve elements, companion cells, phloem parenchyma cells, and primary phloem fibers. The sieve elements possess simple sieve plates and the phloem is arranged in a collateral type of vascular bundle. In addition, this constitutes the first study on phloem ultrastructure in the aerial stems of a holoparasitic dicotyledon, an entire plant which could be viewed as an “ideal sink.” Epifagus phloem possesses unoccluded sieve plate pores in mature sieve elements and a total lack of P-protein in sieve elements at all stages of development. Mature sieve elements lack nuclei. Plastids were rarely observed in mature sieve elements. Vacuoles with intact tonoplasts were encountered in some mature sieve elements. Otherwise, the ultrastructural features of sieve elements appear to differ little from those described by investigators of non-parasitic species.     

A study of the source of virus in the Pholem exudate appearing on leaves of Amscinckia infected with the beet curly top virus

Abstract Leaves of Amsinckia douglasiana discharging phloem exudate after infection with the beet curly top virus (BCTV) were studied with the electron microscope. Infected tissue differed from the noninfected in having much hyperplastic phloem characterized by abnormally high proportion of sieve elements, scarcity of companion cells, degenerating parenchyma cells, and some unusually large intercellular spaces. Many spaces contained amorphous debris. Particles resembling BCTV were discernible within the debris. Such particles were encountered also in the debris trapped between stomatal guard cells. Since the phloem exudate excreted from leaves of BCTV-infected plants contains virus particles, and since the virus is found extremely rarely in sieve elements, we suggest (1) that most of BCTV particles apparently released into intercellular spaces are derived from degenerating parenchyma cells in which the virus had multiplied; (2) that the exudate is derived from sieve elements of the hyper-plastic phloem in which the normal functional control by companion cells is lacking; (3) that the exudate leaks from the nontransporting sieve elements through cell walls into intercellular spaces and carries the virus to the outside. Initially, stomata may serve as exits for the infectious exudate, but subsequently ruptures in the epidermis are involved.     

Expression of the phloem lectin is developmentally linked to vascular differentiation in cucurbits

The conducting elements of phloem in angiosperms are a complex of two cell types, sieve elements and companion cells, that form a single developmental and functional unit. During ontogeny of the sieve element/companion cell complex, specific proteins accumulate forming unique structures within sieve elements. Synthesis of these proteins coincides with vascular development and was studied in Cucurbita seedlings by following accumulation of the phloem lectin (PP2) and its mRNA by RNA blot analysis, enzyme-linked immunosorbent assay, immunocytochemistry and in␣situ hybridization. Genes encoding PP2 were developmentally regulated during vascular differentiation in hypocotyls of Cucurbita maxima Duch. Accumulation of PP2 mRNA and protein paralleled one another during hypocotyl elongation, after which mRNA levels decreased, while the protein appeared to be stable. Both PP2 and its mRNA were initially detected during metaphloem differentiation. However, PP2 mRNA was detected in companion cells of both bundle and extrafascicular phloem, but never in differentiating sieve elements. At later stages of development, PP2 mRNA was most often observed in extrafascicular phloem. In developing stems of Cucurbita moschata L., PP2 was immunolocalized in companion cells but not to filamentous phloem protein (P-protein) bodies that characterize immature sieve elements of bundle phloem. In contrast, PP2 was immunolocalized to persistent ␣ P-protein bodies in sieve elements of the extrafascicular phloem. Immunolocalization of PP2 in mature wound sieve elements was similar to that in bundle phloem. It appears that PP2 is synthesized in companion cells, then transported into differentiated sieve elements where it is a component of P-protein filaments in bundle phloem and persistent P-protein bodies in extrafascicular phloem. This differential accumulation in bundle and extrafascicular elements may result from different functional roles of the two types of phloem. Received: 31 July 1996 / Accepted: 27 August 1996     

Penetration of faba bean sieve elements by pea aphid does not trigger forisome dispersal

Immediately after their stylets penetrate a phloem sieve element, aphids inject saliva into the sieve element for approximately 30–60 s before they begin to ingest phloem sap. This salivation period is recorded as waveform E1 in electrical penetration graph (EPG) monitoring of aphid feeding behavior. It has been hypothesized that the function of this initial period of phloem salivation is to reverse or prevent plugging of the sieve element by one of the plant's phloem defenses: formation of P‐protein plugs or callose synthesis in the sieve pores that connect adjacent sieve elements. This hypothesis was tested using the pea aphid, Acyrthosiphon pisum (Harris) (Hemiptera: Aphididae), and faba bean, Vicia faba L. (Fabaceae), as a model system, and the results do not support the hypothesis. In legumes, such as faba bean, P‐protein plugs in sieve elements are formed by dispersal of proteinaceous bodies called forisomes. Contrary to the hypothesis, the great majority of sieve element penetrations by pea aphid stylets do not trigger forisome dispersal. Thirteen sieve elements were cryofixed early in phloem phase before the aphids could complete their salivation period and the forisomes were not dispersed in any of the 13 samples. However, in these samples, the aphids completed on average a little over half of their normal E1 salivation period before they were cryofixed. Thus, it is possible that sieve element penetration triggered forisome dispersal in these samples but the abbreviated period of salivation was still sufficient to reverse dispersal. To rule out this possibility, 17 sieve elements were cryofixed during R‐pds, which are an EPG waveform associated with sieve element penetration but without the characteristic E1 salivation that occurs during phloem phase. In 16 of the 17 samples, the forisomes were not dispersed. Thus, faba bean sieve elements usually do not form P‐protein plugs in response to penetration by pea aphid stylets. Consequently, the characteristic E1 salivation that occurs at the start of each phloem phase does not seem to be necessary to prevent a plugging response because penetration of sieve elements during R‐pds does not trigger forisome dispersal despite the absence of E1 salivation. Furthermore, as P‐protein plugs do not normally form in response to sieve element penetration, E1 salivation that occurs at the start of each phloem phase is not a response to development of a P‐protein plug. Thus, the E1 salivation period at the beginning of the phloem phase appears to have function(s) unrelated to phloem sealing.     

Seasonal Changes in the Structure of the Secondary Phloem of Grewia tiliaefolia, a Deciduous Tree from India

Structure of the secondary phloem of Grewia tillaefolia Roxb.was studied in samples of bark collected at monthly intervalsfrom forest populations of Gujarat in western India. The secondaryphloem in this species is vertically storied and the axial elementsoccur as alternate tangential bands of fibres and sieve elementsproduced in succession. On average, two to four bands of fibresand corresponding bands of sieve elements are produced in ayear. The sieve elements function for more than one season anddifferent phloem increments are separated by terminal zonesmade up of very narrow sieve elements which mature just beforeand immediately after the period of dormancy. The tree becomesleafless about eight to ten weeks preceding the spring equinox.Cambial activity, phloem differentiation and phloem functionare suspended during this period. Differentiation of phloembegins after bud break which occurs in April, and continuesuntil January, but most of the phloem is produced between Julyand September when the rainy season is well advanced. The widthof the conducting zone is maximal at the end of the period ofgrowth when the tree is in full leaf. Inactivation of sieveelements, apparently by callose plugging the sieve plates, beginswith leaf abscission. The sieve elements produced in the precedingseason, just before dormancy is imposed resume function in thefollowing growing season and the older elements die. Companioncells and axial parenchyma cells surrounding sieve elementsappear to have s significant role during senescence of the conductingelements. The development and activity of the secondary phloemseem to be related to other developmental phenomena occurringwithin the tree.     

Seasonal Variation in Radial Growth and Phloem Activity of Terminalia ivorensis A. Chev

Radial growth in five Terminalia ivorensis trees has been recordedfrom dendrometer reading for a period of 12 months. The durationof the growing season was 7–9 months. Variation in annualradial increment between individual trees was observed to bedue both to differences in the length of the growing seasonand the rate of growth during that period. Seasonal changesin the diameter of sieve elements, and the extent of callosedeposition on the sieve plates have also been investigated.Sieve element diameters were smallest in the dry season, possiblybecause of shrinkage. The width of phloem tissue showing definitivecallose was fairly constant throughout the year, but the zonewith open pores on the sieve plates changed, being widest inSeptember, and narrowest in March when the trees were almostbare. There were two peaks of cambial activity, indicated byan increase in width of the ‘open pore zone’, onein April at the time of bud break, and a second in September. The sugar concentration of the phloem exudate obtained fromsmall cuts into the bark of the trees varied throughout theyear. Concentrations were highest in March, during the dry season,and lowest in May, when the young leaves were expanding. Terminalia ivorensis A. Chev., tropical timber tree, radial growth, callose, phloem exudate, phloem activity     

Comparative Anatomy of Secondary Phloem in Celastraceae

A comparative anatomical study on the secondary phloem of 5-genera, 10 species in Celastraceae was carried out. Based on the phloem structure characters, 3 phloem types were observed. In type Ⅰ , as seen in 5 species of Euonymus, the sieve-tube elements have more inclined end walls and numerous sieve areas (compound sieve plates), phloem rays are almost uniseriate. Type Ⅱ is seen in Celastrus and Tripterygium. It has relatively short sievetube elements, slight inclined end wall and sparse number of sieve areas: the phloem fiber is not lignified and ray is multiseriate. Type Ⅲ is observed in Dipentodon and Perrottetia, the sieve-tube elements are with simple sieve plate, the end wall is almost transverse, there are sclereid and fiber groups in the nonfounctional phloem, and phloem rays are uniseriate or biseriate.     

The phloem, a miracle of ingenuity

This review deals with aspects of the cellular and molecular biology of the sieve element/companion cell complex, the functional unit of sieve tubes in angiosperms. It includes the following issues: (a) evolution of the sieve elements; (b) the specific structural outfit of sieve elements and its functional significance; (c) modes of cellular and molecular interaction between sieve element and companion cell; (d) plasmodesmal trafficking between sieve element and companion cell as the basis for macromolecular long‐distance signalling in the phloem; (e) diversity of sieve element/companion cell complexes in the respective phloem zones (collection phloem, transport phloem, release phloem); (f) deployment of carriers, pumps and channels on the plasma membrane of sieve element/companion cell complexes in various phloem zones; and (g) implications of the molecular‐cellular equipment of sieve element/companion cells complexes for mass flow of water and solutes in a whole‐plant frame.     

Periodicity of Cambium Activity and Seasonal Changes of the Secondary Phloem in Two Species of Dalbergia

Periodicity of cambium activity, seasonal changes of the secondary phloem and longevity of sieve tube in main trunk of Dalbergia balansae Prain and in the twig of D. szemaoensis Prain were observed. The results are as follows: 1. All cambia fall under the category of storied type. 2. In D. balansae cambial activity begins in late April and ends in early November. Phloem differentiation is completed by early November. Xylem differentiation ceases in December. In D. szemaoensis cambial activity continues from mid-April to late October. Phloem and xylem differentiation ceases by late November. 3. The width of functional phloem zone is maximal (400—600 μm) in autumn and minimal (200—370 μm) in February to April. In overwintering, functional sieve tube elements contain P-protein, and the pores of sieve plate are open. It could be one of the reasons that these two species are promising host trees of Kerria yunnanensis during winter. 4. The longevity of sieve tubes in D. balansae and D. szemaoensis last 8—12 months and 9—11 months respectively. 5. During dormancy of cambium, the parenchyma cells of the secondary phloem contain large quantities of starch grains and calcium oxalate crystals, which decrease as cambium becomes active and remain little or even non visualized in summer.     

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.     

CALLOSE SUBSTANCE IN SIEVE ELEMENTS

The secondary phloem of 6 species of woody dicotyledons was examined for the occurrence of callose on the sieve plates of active sieve elements. Fluorescence and bright-field staining methods were used to detect callose. Tissue from the 6 species was killed and fixed in each of 5 solutions. Some tissue of each species was submerged in the killing solutions as quickly as possible, the remainder within 15 min after removal from the tree. In each species, some active sieve elements of the quick-killed tissue gave negative callose reactions. All active sieve elements of the delay-killed tissue gave positive callose reactions. These and other results suggest that the active sieve elements in the secondary phloem of the species studied normally lack callose and that the extent of callose deposition in these cells depended primarily upon the rapidity with which the sieve-element protoplasts were killed after wounding of the phloem. In addition, bright-field observations of sieve plates of large numbers of sieve elements from a seasonal collection of Tilia americana secondary phloem suggest that the active sieve elements normally lack callose during the growing season and that the inactive sieve elements normally possess it (dormancy callose).     

Callose deposition in the phloem plasmodesmata and inhibition of phloem transport in citrus leaves infected with “Candidatus Liberibacter asiaticus”

Huanglongbing (HLB) is a destructive disease of citrus trees caused by phloem-limited bacteria, Candidatus Liberibacter spp. One of the early microscopic manifestations of HLB is excessive starch accumulation in leaf chloroplasts. We hypothesize that the causative bacteria in the phloem may intervene photoassimilate export, causing the starch to over-accumulate. We examined citrus leaf phloem cells by microscopy methods to characterize plant responses to Liberibacter infection and the contribution of these responses to the pathogenicity of HLB. Plasmodesmata pore units (PPUs) connecting companion cells and sieve elements were stained with a callose-specific dye in the Liberibacter-infected leaf phloem cells; callose accumulated around PPUs before starch began to accumulate in the chloroplasts. When examined by transmission electron microscopy, PPUs with abnormally large callose deposits were more abundant in the Liberibacter-infected samples than in the uninfected samples. We demonstrated an impairment of symplastic dye movement into the vascular tissue and delayed photoassimilate export in the Liberibacter-infected leaves. Liberibacter infection was also linked to callose deposition in the sieve plates, which effectively reduced the sizes of sieve pores. Our results indicate that Liberibacter infection is accompanied by callose deposition in PPUs and sieve pores of the sieve tubes and suggest that the phloem plugging by callose inhibits phloem transport, contributing to the development of HLB symptoms.     

Seasonal Variations of Secondary Phloem Development in Pterocarya Stenoptera and Its Relation to Feeding of Kerria yunnanensis

Early in April of 1987, cells in an undifferentiated state which overwintered on the phloem side of the cambial zone in the branch of Pterocarya stenoptera began to differentiate into merebets of phloem. Cambium divided actively in mid-April and ceased to decide by early-Novembet. Five to eleven bands of fibers alternating with the bands of sieve tubes, companion cells and phloem parenchyma cells produced every year. By mid to late April, new xylem differentiation began. Phloem and xylem differentiation ceased almost simultaneously. Functional sieve tube elements were present all the year round in the phloem. During winter, most sieve tubes produced in the current year ceased functioning, leaving only the zone of functional sieve tube of several rows of cells in width with open pores in the sieve plates. These sieve tubes did not collapse until mid-May. In October, several rows of partially differentiated sieve elements appeared near the cambial zone. They still possessed nuclei. The companion cells had produced but no P-protein. They matured during April of the following year and collapsed by July to September. The life span of sieve elements extended for 8 months at the most. In winter, there were less functional sieve tubes in the branch. This may be one of the reasons that only few Kerria yunnanensis survive on the branch of Pterocarya stenoptera.     

Calculation of Translocation Coefficients from Phloem Anatomy for use in Crop Models

Translocation coefficients, computed for unit ground area, arerequired in crop models as part of the simulation of the partitioningof assimilates. An equation for translocation is derived byconsidering pressure-driven flow and the physical dimensionsof the pathway in the phloem. Numerical estimates of the translocationcoefficients for grasses and trees are calculated using anatomicaldata. The values found are compatible with published rates oftranslocation in the phloem.Copyright 1995, 1999 Academic Press Model, Münch, phloem, sieve tube, translocation     

Faba bean forisomes can function in defence against generalist aphids

Phloem sieve elements have shut‐off mechanisms that prevent loss of nutrient‐rich phloem sap when the phloem is damaged. Some phloem proteins such as the proteins that form forisomes in legume sieve elements are one such mechanism and in response to damage, they instantly form occlusions that stop the flow of sap. It has long been hypothesized that one function of phloem proteins is defence against phloem sap‐feeding insects such as aphids. This study provides the first experimental evidence that aphid feeding can induce phloem protein occlusion and that the aphid‐induced occlusions inhibit phloem sap ingestion. The great majority of phloem penetrations in Vicia faba by the generalist aphids Myzus persicae and Macrosiphum euphorbiae triggered forisome occlusion and the aphids eventually withdrew their stylets without ingesting phloem sap. This contrasts starkly with a previous study on the legume‐specialist aphid, Acyrthosiphon pisum, where penetration of faba bean sieve elements did not trigger forisome occlusion and the aphids readily ingested phloem sap. Next, forisome occlusion was demonstrated to be the cause of failed phloem ingestion attempts by M. persicae: when occlusion was inhibited by the calcium channel blocker lanthanum, M. persicae readily ingested faba bean phloem sap.     

Role of auxin and sucrose in the differentiation of sieve and tracheary elements in plant tissue cultures

The differentiation of sieve and tracheary elements was studied in callus culture of Daucus carota L., Syringa vulgaris L., Glycine max (L.) Merr., Helianthus annuus L., Hibiscus cannabinus L. and Pisum sativum L. By the lacmoid clearing technique it was found that development of the phloem commenced before that of the xylem. In not one of the calluses was differentiation of tracheary elements observed in the absence of sieve elements. The influence of indole-3-acetic acid (IAA) and sucrose was evaluated quantitatively in callus of Syringa, Daucus and Glycine. Low IAA levels resulted in the differentiation of sieve elements with no tracheary cells. High levels resulted in that of both phloem and xylem. IAA thus controlled the number of sieve and tracheary elements, increase in auxin concentration boosting the number of both cell types. Changes in sucrose concentration, while the IAA concentration was kept constant, did not have a specific effect on either sieve element differentiation, or on the ratio between phloem and xylem. Sucrose did, however, affect the quantity of callose deposited on the sieve plates, because increase in the sucrose concentration resulted in an increase in the amount of callose. It is proposed that phloem is formed in response to auxin, while xylem is formed in response to auxin together with some added factor which reaches it from the phloem.     

STRUCTURE AND DEVELOPMENT OF THE SIEVE ELEMENT IN THE STEM OF LYCOPODIUM LUCIDULUM

Stem tissue of Lycopodium lucidulum Michx. was fixed in glutaraldehyde and postfixed in osmium tetroxide for electron microscopy. Although their protoplasts contain similar components, immature sieve elements can be distinguished from parenchymatous elements of the phloem at an early stage by their thick walls and correspondingly high population of dictyosomes and dictyosome vesicles. Late in maturation the sieve-element walls undergo a reduction in thickness, apparently due to an “erosion” or hydrolysis of wall material. At maturity, the plasmalemma-lined sieve elements contain plastids with a system of much convoluted inner membranes, mitochondria, and remnants of nuclei. Although the endoplasmic reticulum (ER) in most mature sieve elements was vesiculate, in the better preserved ones the ER formed a tubular network closely appressed to the plasmalemma. The sieve elements lack refractive spherules and P-protein. The protoplasts of contiguous sieve elements are connected with one another by pores of variable diameter, aggregated in sieve areas. As there is no consistent difference between pore size in end and lateral walls these elements are considered as sieve cells.