Sieve-Element Ontogeny in the Aerial Shoot of Equisetum hyemale L.

The aerial shoots of Equisetum hyemale L. var. affine (Engelm.)A. A. Eat. were examined with the electron microscope as partof a continuing study of sieveelement development in the lowervascular plants. Young E. hyemale sieve elements are distinguishablefrom all other cell types within the vascular system by thepresence of refractive spherules, proteinaceous bodies whichdevelop within dilated portions of the endoplasmic reticulum(ER). Details of cell wall thickening differ between protophloemand metaphloem sieve elements. Following cell wall thickeningthe ER increases in quantity and aggregates into stacks. Shortlythereafter, nuclear degeneration is initiated. During the periodof nuclear degeneration some cytoplasmic components-dictyosomes,microtubules and ribosomes-degenerate and disappear, while organellessuch as mitochondria and plastids persist. The latter undergostructural modifications and become parietal in distribution.Eventually the massive quantities of ER are reduced, leavingthe lumen of the cell clear in appearance. At maturity the plasmalemma-linedsieve element contains a parietal network of tubular ER, aswell as mitochondria, plastids, and refractive sphemh At thistime many of the spherules are discharged into the region ofthe wall. Sieveelement pores occur in both lateral and end walls.At maturity many pores are traversed by large numbers of ERmembranes. The metaphloem sieve elements of the mid-internodalregions apparently are sieve-tube members. The connections betweenmature protophloem sieve elements and pericycle cells are associatedwith massive wall thickenings on the pericyclecell side.     

SIEVE-ELEMENT ONTOGENY IN THE ROOT OF EQUISETUM HYEMALE

Roots of Equisetum hyemale L. var. affine (Engelm.) A. A. Eat. were fixed in glutaraldehyde, postfixed in osmium tetroxide, and sieve elements of various ages were examined with the electron microscope. Young sieve elements are distinguished by their position within the vascular cylinder and by the presence of numerous refractive spherules, which originate within dilated portions of the endoplasmic reticulum (ER). Early in development, the sieve-element walls undergo a substantial increase in thickness. This is followed by the appearance of massive ER aggregates in the cytoplasm and then by a phase involving stacking and sequestering of the remaining ER. Nuclear degeneration is initiated shortly after the appearance of the ER aggregates. The chromatin condenses into masses of variable size along the inner surface of the nuclear envelope. The envelope then ruptures and chromatin is released into the cytoplasm. During the period of nuclear degeneration, mitochondria and plastids undergo structural modification, while components such as dictyosomes, microtubules, and ribosomes degenerate and disappear. The remaining cytoplasmic components assume a parietal position in the cell, leaving the lumen of the cell clear in appearance. At maturity, the plasmalemma-lined sieve element contains plastids, mitochondria, some ER, and refractive spherules. At this time many of the refractive spherules are discharged into the region of the wall. Pores between sieve elements occur largely on the end walls. During pore development, tubules of ER apparently traverse the pores, but because of the presence of massive callose deposits in the material examined, the true condition of mature pores could not be determined. The connections between mature sieve elements and pericycle cells are characterized by the presence of massive wall thickenings on the pericycle-cell side. Plasmodesmata in the wall thickening are matched by pores on the sieve-element side. Ontogenetic and cytoplasmic factors argue against use of the term “companion cell” for the vascular parenchyma cells associated with the sieve elements.     

Le phloème deSelaginella willdenowii: histophysiologie comparée

Metaphloem sieve elements ofSelaginella willdenowii are elongated cells with slightly oblique or transverse end walls. Pores are seen on both lateral and end walls, although they are more numerous on the latter. Parenchyma cells exhibiting strong enzyme activities (acid phosphatase, non specific esterase, succinate dehydrogenase, cytochrome oxidase, peroxidase) are present between sieve elements and tracheids in each vascular bundle. A functional association thus appears to exist between these parenchyma cells and the conducting elements.—The occurrence of transverse to slightly oblique end walls in sieve elements seems to characterize the ligulate Lycopsids (as opposed to the aligulateLycopodium where sieve elements possess slanting, very oblique, end walls).

     

Sieve Elements of Minor Veins in the Leaves of Beta vulgaris L.

End walls of sieve elements of minor veins of the leaves ofBeta vulgaris L. do not contain the multi-perforate sieve plateswhich typically occur on the end walls of sieve-tube membersof major veins. Instead, both end and side walls of the sieveelements of minor veins contain scattered pores which may occursingly or in small numbers. These pores are similar to thosewhich are grouped in sieve plates of major veins in size, possessionof callose and plugs of filaments. In addition to these pores,there are tubular connections 0.1 µ in diameter throughcharacteristically thickened parts of the cell wall betweensieve cells and companion cells. Sieve elements of minor veinsdiffer from those of major veins in structure as well as infunction.     

Microtubules do not control microfibril orientation in a helicoidal cell wall

Summary The secondary cell wall layer of the young root hair ofEquisetum hyemale (L) has a helicoidal texture. The cortical microtubules in these hairs maintain an axial alignment while microfibrils are being deposited with a different orientation in each subsequent layer. The role of cortical microtubules in microfibril orientation is disputed.I gratefully acknowledge the support of Professor Dr. M. M. A.Sassen and the technical assistance of M.Wolters-Arts.     

Studies onArtemisia afra Jacq.: The phloem in stem and leaf

Summary The structure of the phloem was studied in stem and leaf ofArtemisia afra Jacq., with particular attention being given to the sieve element walls. Both primary and secondary sieve elements of stem and midvein have nacreous walls, which persist in mature cells. Histochemical tests indicated that the sieve element wall layers contained some pectin. Sieve element wall layers lack lignin. Sieve elements of the minor veins (secondary and tertiary veins) lack nacreous thickening, although their walls may be relatively thick. These walls and those of contiguous transfer cells are rich in pectic substances. Transfer cell wall ingrowths are more highly developed in tertiary than in secondary veins.     

Über den Feinbau verdickter (nacré) Wände und der Plastiden in den Siebröhren vonAnnona undMyristica

Zusammenfassung Die verdickten (nacré) inneren Wände der Siebröhren von Annonaceen, vonMyristica, Illicium undKadsura geben mit spezifischen Farbstoffen eine positive Cellulosereaktion. Untersuchungen über ihre Feinstruktur zeigen, daß sie sich aus bevorzugt parallel verlaufenden Fibrillen (Durchmesser 100–200 Å) zusammensetzen. Die Paralleltextur ist wahrscheinlich für den Perlmutterglanz der Wände mitverantwortlich. Die Wandverdickungen entstehen bereits in sehr jungen plasmareichen Siebröhren und engen das Siebröhrenlumen im Laufe ihrer Differenzierung bis auf weniger als die Hälfte des Ausgangswertes ein. - Die Siebröhren-Plastiden von Annonaceen undMyristica enthalten einen Proteineinschluß, z. T. zusätzlich auch Stärkekörner.

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On the fine structure of nacreous walls and of plastids in the sieve tubes ofAnnona andMyristica

Summary Wall thickenings (nacreous walls) in sieve tubes ofAnnonaceae, ofMyristica, Illicium, andKadsura give positive reactions with dyes staining cellulose walls. In electron microscopic investigations their composition of 100–200 Å wide fibrils can be depicted. The predominant parallel arrangement of the fibrils is suggested to be one of the conditions for the pearly luster of the wall thickenings. The formation of nacreous walls is initiated in young sieve tubes; finally the wall thickenings may occlude more than half of their cross-sectional area.—Sieve-tube plastids fromAnnonaceae andMyristica contain protein inclusions and often supplementary starch grains.

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Meinem Lehrer, Herrn Prof. Dr.Walter Schumacher, in Dankbarkeit zum 70. Geburtstag.     

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.     

Development of P-protein in sieve elements ofMimosa pudica

Summary The P-protein in sieve elements of leaves ofMimosa pudica L. is first discernible as fine fibrous material which forms homogeneous aggregates. Ribosomes, rough endoplasmic reticulum, and dictyosomes with associated vesicles occur in the cytoplasm surrounding the aggregates. The plastids and mitochondria are in a parietal position in the parts of the cell where the nascent P-protein accumulates. In a later stage, the fibrillar material is organized into a three-dimensional system of five- and six-sided elongated compartments. The corners of the compartments appear solid at first, then they become electron lucent in the center and assume tubular form. Aggregates of mature P-protein tubules usually occur near the compartmentalized system. Tubules in pentagonal or hexagonal arrangements may be present in the aggregates and may be partly interconnected. The conclusion was drawn that the P-protein tubules are assembled at the corners of compartments within a continuous orderly system. The fully formed tubules occur first in aggregates, the P-protein bodies. Later the aggregates become loose and partly dispersed. Many of the dispersed tubules assume a loose, extended, helical form characteristic of P-protein in older sieve elements.This work was supported in part by National Science Foundation grant GB-5506. I am also grateful to MissHatsume Kosakai and Mr.Robert H.Gill for technical assistance.     

Strukturelle Grundlagen des Parasitismus beiOrobanche

Zusammenfassung Innerhalb des Haustoriums vonOrobanche werden zur Assimilatleitung besondere Zellen ausgebildet. Diese zeigen viele Merkmale der typischen Siebelement-Differenzierung: Tonoplastenverlust, Kernverlust, Veränderung der Plastiden und Mitochondrien. Während der Entwicklung der haustorialen Siebröhren bleiben die Ribosomen jedoch in großer Dichte vorübergehend erhalten. Dieses Zwischenstadium der Siebelemententwicklung wird von uns als Übergangssiebelement bezeichnet. Erst mit der Desintegration der Ribosomen treten die typischen Plasmafilamente angiospermer Siebröhren auf, die Plasmodesmen werden zu Siebporen erweitert. Charakteristisch für die haustorialen Siebelemente ist ein glattes zisternales, wandständiges ER, das um so stärker ausgebildet ist, je näher die Parasitenzelle an der Wirtssiebröhre liegt.Ein direkter Anschluß dieser umdifferenzierten Zellen an die Wirtssiebröhren wird jedoch nicht beobachtet. Stets ist zwischen den Leitelementen beider Organismen mindestens eine Kontaktzelle ausgebildet, die einen normalen, wenngleich besonders dicht strukturierten Protoplasten zeigt. Es werden keine plasmatischen Verbindungen zwischenOrobanche und ihrem Wirt gefunden.Die Befunde anOrobanche werden mit denjenigen an anderen parasitischen Pflanzen verglichen.

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Structural features of parasitism ofOrobanche II. The differentiation of assimilate conducting elements within the haustorium

Summary Within the haustorium ofOrobanche special assimilate conducting cells are developed. These cells show many typical features of sieve element differentiation: disintegration of tonoplast and nucleus, structural changes of plastids and mitochondria. The ribosomes however persist in high quantity in the developing sieve element. We call this intermediate stage of sieve element differentiation transition-sieve element. Only after disappearance of ribosomes the typical plasmatic filaments of angiosperm sieve tubes appear and plasmodesmata dilate to sieve pores. A smooth surfaced ER adjacent to the wall, is specific for haustorial sieve elements. The closer the parasitic cell lies to the host sieve tube, the better ER is developed. However a direct contact of this specialized cell to the host sieve tube was not observed. There is always a particular contact cell, showing a normal protoplast of high density. No plasmatic connections betweenOrobanche and its host are detected. These findings onOrobanche are compared with those on other parasitic plants.

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Wir danken FrauChristl Glockmann für ihre verantwortungsvolle Mitarbeit. Die Untersuchungen wurden durch Mittel der Deutschen Forschungsgemeinschaft gefördert.     

Some aspects of sieve-element structure and development inSelaginella kraussiana

Summary The vacuoles of the sieve elements ofSelaginella kraussiana contain a crystalline protein which appears to degenerate in mature cells. Although it occurs in sieve elements we have elected not to call it P-protein because of ontogenetic and possibly functional differences between the two. The nucleus undergoes unique structural changes during development of the sieve element, ultimately being converted to a mass of tubules. The structures referred to by earlier workers as refractive spherules inSelaginella are probably plastids. As the size of the sieve pores in lateral and end walls falls into the same size range, the sieve elements ofSelaginella kraussiana can be considered to be sieve cells.This work was supported by the U.S. National Science Foundation (GB 31417).     

Sieve elements rapidly develop ‘nacreous walls’ following injury − a common wounding response?

Thick glistening cell walls occur in sieve tubes of all major land plant taxa. Historically, these ‘nacreous walls’ have been considered a diagnostic feature of sieve elements; they represent a conundrum, though, in the context of the widely accepted pressure–flow theory as they severely constrict sieve tubes. We employed the cucurbit Gerrardanthus macrorhizus as a model to study nacreous walls in sieve elements by standard and in situ confocal microscopy and electron microscopy, focusing on changes in functional sieve tubes that occur when prepared for microscopic observation. Over 90% of sieve elements in tissue sections processed for microscopy by standard methods exhibit nacreous walls. Sieve elements in whole, live plants that were actively transporting as shown by phloem‐mobile tracers, lacked nacreous walls and exhibited open lumina of circular cross‐sections instead, an appropriate structure for Münch‐type mass flow of the cell contents. Puncturing of transporting sieve elements with micropipettes triggered the rapid (<1 min) development of nacreous walls that occluded the cell lumen almost completely. We conclude that nacreous walls are preparation artefacts rather than structural features of transporting sieve elements. Nacreous walls in land plants resemble the reversibly swellable walls found in various algae, suggesting that they may function in turgor buffering, the amelioration of osmotic stress, wounding‐induced sieve tube occlusion, and possibly local defence responses of the phloem.     

Changes in the lanthanum distribution following decapitation of the sporophytes of an aquatic fern,Marsilea drummondii A. Br.

Summary The active terminal bud and the quiescent lateral buds and corresponding nodes inserted at different levels on the main rhizome ofMarsilea drummondii were examined with the EM afterin vivo feeding with lanthanum nitrate. These tracer experiments demonstrate that all the buds are fed by their phloem cells. In the lateral bud axis the labelling of the sieve elements apoplast indicates that a solute transfer took place in the node between xylem and phloem via xylem transfer cells. La³⁺ deposits are completely absent from the apical dome of inhibited buds indicating that the walls of the quiescent meristematic cells are not permeated by the tracer. The removal of the terminal bud has two effects. It rapidly (in 2 hours) allows the lanthanum to penetrate the lateral bud tip walls at a stage when no fine structural changes are discernable and to bind to the outer surface of the plasmalemma as it does in the active terminal bud. This study including inhibited buds and buds released from apical dominance support the view that changes in the state of the cell surface (cell wall and plasma membrane) may be a prerequisite for the resumption growth activity.This study was supported in part by a grant from the Centre National de la Recherche Scientifique to L.Sossountzov (AI 031275).     

OBSERVATIONS ON SIEVE ELEMENTS IN THREE PERENNIAL MONOCOTYLEDONS

Seasonal collections were made of rhizomes of Polygonatum canaliculatum and Typha latifolia and of aerial stems of Smilax hispida. Many metaphloem sieve elements in all three species remain functional for 2 or more years, or for the life of the plant parts in which they occur. Although the protoplasts of mature sieve elements remain similar in appearance from one time of year to the next, the amount of callose associated with the sieve plates and lateral sieve areas of such cells apparently varies with the seasons, being heavier in late fall and winter and lighter in late spring and summer. At maturity the metaphloem sieve elements contain strands derived from the slime bodies of immature cells. It is suggested that in mature sieve elements the slime strands normally occur as a network along the wall. Many mature sieve elements of S. hispida contained normal-appearing nuclei.     

Ultrastructural features of well-preserved and injured sieve elements: Minute clamps keep the phloem transport conduits free for mass flow

Summary After chemical fixation following two different preparation procedures, the ultrastructure of mature sieve elements (SEs) was systematically compared in the transport phloem ofVicia faba leaves andLycopersicon esculentum internodes. The SEs in samples obtained by gentle preparation were well preserved, while those in conventionally prepared samples were generally injured. (1) In well-preserved SEs, parietal P-proteins were associated with cisternae of the SE endoplasmic reticulum (ER). Additionally, theV. faba SEs had crystalline P-proteins, and a homogeneous network of filamentous P-proteins occurred in the lumen of theL. esculentum SEs. In injured SEs, all P-proteins were dispersed. (2) In well-preserved SEs, stacked ER cisternae associated with P-proteins lay also on the sieve-plate walls, but passages were kept free in front of the sieve pores. Injured SEs lacked these orderly arranged deposits. Instead, irregular filamentous and membranous materials occluded the sieve pores. (3) In well-preserved SEs, the sieve-pore lumen was free of obstructions, apart from small, lateral coatings of P-proteins. Sieve pores in injured SEs were always occluded. (4) The SE organelles and, in tomato SEs, also the parietal ER located at the longitudinal walls were firmly attached in the SE periphery and stayed in place after injury. The stable parietal attachment is likely exerted by minute, clamplike structures which link the outer membranes of the SE components with one another or to the SE plasma membrane. Single, straight clamps with a length of about 7 nm anchored the SE components directly to the SE plasma membrane. The connections between adjacent SE organelles and/or parietal ER cisternae were mostly twice as long (about 15 nm) and often were branched. Presumably, the long, branched clamps were constituted by the interaction of opposite short clamps. The ultrastructural results are discussed with respect to SE functioning.     

Leaf structure in relation to solute transport and phloem loading in Zea mays L.

Small and intermediate (longitudinal) vascular bundles of the Zea mays leaf are surrounded by chlorenchymatous bundle sheaths and consist of one or two vessels, variable numbers of vascular parenchyma cells, and two or more sieve tubes some of which are associated with companion cells. Sieve tubes not associated with companion cells have relatively thick walls and commonly are in direct contact with the vessels. The thick-walled sieve tubes have abundant cytoplasmic connections with contiguous vascular parenchyma cells; in contrast, connections between vascular parenchyma cells and thin-walled sieve tubes are rare. Connections are abundant, however, between the thin-walled sieve tubes and their companion cells; the latter have few connections with the vascular parenchyma cells. Plasmolytic studies on leaves of plants taken directly from lighted growth chambers gave osmotic potential values of about-18 bars for the companion cells and thin-walled sieve tubes (the companion cell-sieve tube complexes) and about-11 bars for the vascular parenchyma cells. Judging from the distribution of connections between various cell types of the vascular bundles and from the osmotic potential values of those cell types, it appears that sugar is actively accumulated from the apoplast by the companion cell-sieve tube complex, probably across the plasmalemma of the companion cell. The thick-walled sieve tubes, with their close spatial association with the vessels and possession of plasmalemma tubules, may play a role in retrieval of solutes entering the leaf apoplast in the transpiration stream. The transverse veins have chlorenchymatous bundle sheaths and commonly contain a single vessel and sieve tube. Parenchymatic elements may or may not be present. Like the thick-walled sieve tubes of the longitudinal bundles, the sieve tubes of the transverse veins have plasmalemma tubules, indicating that they too may play a role in retrieval of solutes entering the leaf apoplast in the transpiration stream.     

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.     

ULTRASTRUCTURE OF THE NACREOUS LEPTOIDS (SIEVE ELEMENTS) IN THE POLYTRICHACEOUS MOSS ATRICHUM UNDULATUM

The physiological phloem equivalents, leptoids, of the polytrichaceous moss Atrichum undulatum appear to be similar to the nacreous sieve elements that occur in many higher plants. These leptoids are elongated cells with nacreous thickenings on their radial and tangential walls. Their oblique end walls, which lack such thickenings, are traversed by numerous pores through which the plasmalemma, endoplasmic reticulum, and cytoplasm are continuous between adjacent leptoids of a longitudinal file. These end walls closely resemble the simple sieve areas of the sieve elements found in Polypodium vulgare. The leptoid sieve pores have a median expanded area and frequently are occluded by small amorphous protein plugs at each end. Also, callose was observed as electron-luscent areas both on the faces of the end walls and as a thin cylinder surrounding the lateral area of each pore. Amorphous and granular cytoplasmic contents of the leptoids appear to be morphologically similar to the slime (P-protein) found in the sieve-tube elements of many angiosperms. Differentiating leptoids are characterized by the formation of numerous membrane-bound protein bodies in close association with polysomes and endoplasmic reticulum. As the leptoid matures, the contents of the protein bodies become dispersed in the cytoplasm. Ultrastructurally and ontogenetically the leptoids in the gametophores of A. undulatum appear almost identical to the sieve elements of P. vulgare and therefore should be considered sieve elements rather than phloem-like equivalents.     

Plastids of sieve tube members in the stamen vascular bundle ofSorghum bicolor (Gramineae)

Summary The plastids in sieve tube members of the stamen vascular bundles ofSorghum bicolor, fixed in glutaraldehyde with postfixation in osmium tetroxide, are of the P-type containing cuneate crystalloids of a proteinaceous nature surrounded by a double envelope. Secondary inclusions are present in these P-type plastids. P-type plastids inSorghum often remain intact in the mature sieve tube members.This work was supported by a grant from the Iowa Agricultural and Home Economics Experiment Station, Ames, U.S.A. Project No. 1740 toHarry T.Horner, Jr., andNels R.Lersten and Project No. 1914 toHarry T.Horner, Jr. of the Department of Botany and Plant Pathology, Iowa State University, Ames, U.S.A. This work was completed by the author as part of the Ph. D. dissertation research.     

Plastids in sieve elements and their companion cells

Summary Plastids have been identified in the sieve elements and/or companion cells of 14 monocotyledon species. In contrast to earlier reports, plastids are present in the sieve elements of Smilax and the companion cells of Tradescantia. The development and fine structure of the sieve-element plastids in Smilax do not differ from the type found in all of the 230 angiosperm species we have studied so far contain prominent plastids. The companion cells are easily identified by their specialized plasmatic connections with the sieve elements. The leucoplasts in the companion cells of Tradescantia are identical with those reported for many angiosperms.