Studies on Differentiation of Laticifers through Light and Electron Microscopy in Calotropis gigantea (Linn.) R.Br.

The distribution, cytological organization and differentiationof non-articulated laticifers in the primary and mature tissuesof Calotropis gigantea (Linn.) R.Br., were studied by the useof optical and electron microscopy. Laticifers occur in thecortex, vascular bundle and pith of the plant axis. At the earliestdetectable stage a laticifer is a cell which undergoes rapidelongation and nuclear division. This results in a multinucleateelongated cell which undergoes further increase in length withgradual degeneration of the cytoplasm. At the electron microscopiclevel the presumptive laticifer cell shows increasing vacuolationwhich forms a large central vacuole. Simultaneously the cytoplasmicorganelles undergo degeneration by autophagic processes. Laternumerous vesicles can be observed in the large central vacuole,the remaining cytoplasm being pushed to a thin layer. Maturelaticifers show three types of spherical structures of whichthe highly electron dense globules are the latex particles. Calotropis gigantea (Linn.), R.Br., laticifers, ultrastructure, differentiation     

Differentiation of Non-articulated Laticifers in Poinsettia (Euphorbia pulcherrima Willd.)

Differentiation of non-articulated laticifers in poinsettia(Euphorbia pulcherrima Willd.) was studied ultra-structurally.Growing laticifers show: (1) a multinucleate apical region containingabundant ribosomes but few other differentiated organelles and(2) a sub-apical zone where the cytoplasm is dominated by vacuolesof diverse morphology with latex particles. These particlesappear first within narrow tubular vacuoles developed especiallyin the peripheral cytoplasm. During vacuolation of the laticifer,portions of cytoplasm, including some of the nuclei, becomeisolated by the enlarging and fusing vacuoles; eventually thesebecome lysed, except the latex particles which remain in thecentral vacuole. During differentiation of a laticifer branch,the cytoplasm contains the usual organelles, including a fewmicrobodies and coated vesicles. The plastids that lie withinthe peripheral cytoplasm differentiate into amyloplasts witha single elongated starch grain. Towards the end of differentiationthe cytoplasm becomes restricted to a thin parietal layer, withthe remaining organelles reduced or degenerate, surroundinga central vacuole filled with latex particles. Euphorbia pulcherrima Willd, poinsettia, ultrastructure, differentiation, laticifers     

Ultrastructure of Non-Articulated Laticifers in Allamanda violacea

Ultrastructure studies on the differentiation of non-articulatedbranched laticifers in Allamanda violacea Gardn. were carriedout. Growing laticifers show sequential changes. In the earlystage, the laticifers possess electron dense cytoplasm, abundantmitochondria, ER, ribosomes, small vacuoles, nucleus and plastidwith starch-grains. The ER dilates to form small vacuoles whichcoalesce at the later stages. A large central vacuole is formedin the mature laticifers due to the cellular autophagy of cytoplasmincluding the cell organelles. At this stage, the mitochondriapossess a few cristae and plastids with plastoglobuli and smallstarch grains. Towards the end of differentiation the cytoplasmis restricted to a thin parietal layer along the cell wall,the remaining organelles being either reduced in number or degenerate.Plasmodesmata and primary pit fields are occasionally observedbetween the laticifer and the adjacent parenchyma cell. Allamanda violacea, laticifers, ultrastructure     

Distribution and Organization of Non-articulated Laticifers in Mature Tissues of Poinsettia (Euphorbia pulcherrima Willd.)

The distribution and cytological organization of non-articulatedbranched laticifers in the mature root, stem, and leaf tissuesof poinsettia. Euphorbia pulcherrima Willd., were studied bythe use of optical and electron microscopy. The laticifers occurin all parts of the plant body, being well represented in certainparenchymatous tissues and the phloem. The mature region ofthe laticifer has a living protoplast showing a thin parietalcytoplasm, bounded by plasmalemma and a tonoplast, which enclosesa large continuous central vacuole containing the milky latexfluid. The protoplast is multinucleate and possesses large amyloplasts,each enclosing a single elongated starch grain. Sparseness andpoor differentiation of the other components of the protoplast,mostly mitochondria, ribosomes and endoplasmic reticulum, suggestlow metabolism in the mature region of the laticifer. The latexof the central vacuole is dominated by spherical particles,0.3–1 µm in diameter, each with a dense matrix andan eccentric core of lighter staining material. In some laticifersthe latex particles fuse into coagulated masses. Euphorbia pulcherrima Willd, poinsettia, laticifers, ultrastructure, cytology     

Laticifer Differentiation in Hevea brasiliensis: Induction by Exogenous Jasmonic Acid and Linolenic Acid

Laticifer differentiation of Hevea brasiliensis was investigatedby application of lanolin containing jasmonic acid (JA) or otherchemicals to the surface of young stems in epicormic shoots.The young stems had primary laticifers and no secondary laticifers.When applied to extending young stems, JA led to a significantincrease in primary laticifer number but did not induce secondarylaticifer differentiation. Secondary laticifer differentiationand a less significant increase in primary laticifer numberwere caused by JA application to the extended young stems. Theinduction of the secondary laticifers was dependent on the concentrationof JA applied. Cambium cell division leading to the formationof secondary phloem was not accelerated by JA treatment. Treatedbark tissues showed no visible changes except for the additionallaticifers, which were normal in ultrastructure. The secondarylaticifers were also induced by the application of linolenicacid, a precursor of JA biosynthesis. Abscisic acid, ethephonand salicylic acid had no detectable effect on laticifer differentiation.Copyright 2000 Annals of Botany Company Hevea brasiliensis, laticifer differentiation, jasmonic acid, linolenic acid, vascular cambium.     

THE STRUCTURE AND DEVELOPMENT OF AN UNUSUAL TYPE OF ARTICULATED LATICIFER IN MAMMILLARIA (CACTACEAE)

Although the laticifers of several species of Mammillaria can technically be classified as being of the articulated type, they differ significantly from all other reported articulated laticifers. They are derived from cells which differentiate only in older tissues, never in meristematic or young regions. The development involves the complete lysis of masses of cells, not just the perforation or resorption of the end walls in a single file of cells. At maturity, the laticifer lumen is lined with a one-to-several layered epithelium which may be quite thick. The laticifers increase in diameter with age, apparently by the lysis of the inner epithelial cells. Laticifers occur in the pith, cortex and tubercles of the vegetative body but were not observed in the roots, flower parts or in seedlings up to eight months old. Seven species were studied, all of which have “milky sap.” and the laticifers of each were virtually identical to the laticifers of the others.     

Observations on the Development and Fine Structure of the Articulated Laticifers of Papaver somniferum

The development and fine structure of articulated anastomosinglaticifers in Papaver somniferum were studied. Laticifers arenot present in the embryos but differentiate soon after germinationand are found in the phloem areas 18–30 h after the seedis sown. Laticifers and sieve elements are generally separatedby at least one cell layer in the roots, but in cotyledons,stems, and leaves they usually occur adjacent to each other. As the laticifers differentiate an abundance of vesicles formsin the cytoplasm. This process appears to involve the endoplasmicreticulum and it is suggested that the vesicles may be a specializedform of vacuole. Substances present in the vesicles react stronglywith iodine-potassium iodide. Laticifer-cytoplasm persists peripherallyand between the vesicles. It contains the usual cell organelles,the presence of which substantiates an active metabolic rolefor the laticifer contents.     

Laticifer Differentiation of Calotropis gigantea R. Br. ex Ait. in Cultures

The initiation and subsequent development of laticifers werestudied in callus tissues of Calotropis gigantea grown on MS(Murashige and Skoog) medium supplemented with 1 mg l^–1IAA. Laticifer development was related to the age of the cultureand could be preserved by repeated subculturing on similar mediumwith IAA. Our previous work had established that cardenolidebiosynthesis was related to rhizogenesis and here we reportthe culture system of laticifer, long term preservation anddifferentiation of this hydrocarbon producing energy plant. Calotropis gigantea, Asclepiadaceae, laticifer, differentiation, cardenolides, tissue culture     

STRUCTURE AND ONTOGENY OF LATICIFERS IN CICHORIUM INTYBUS (COMPOSITAE)

The branched anastomosed laticifer system in the primary body of Cichorium intybus L. originates in embryos from files of laticiferous members at the boundary between phloic procambium and ground meristem. Upon seed germination, laticiferous members develop perforations in the end walls which become entirely resorbed. Perforations also develop in the longitudinal walls of contiguous laticiferous members and from lateral connections between developing laticifer branches. Additional laticiferous members originate as procambium differentiation proceeds, and their differentiation follows a continuous acropetal sequence in leaf primordia of the plumule. In roots, laticifers closely associated with sieve tubes in the secondary phloem originate from derivatives of fusiform initials in the vascular cambium. These laticifers develop wall perforations and in a mature condition resemble laticifers in the primary body. As the girth of the root increases, laticifers toward the periphery, unlike associated sieve tubes, resist crushing and obliteration. Laticifers vary in width from about 4 to 22 μm; the widest ones occur in involucral bracts and the narrowest ones in florets. There was no evidence that intrusive growth occurs during development of the laticifer system, although such growth may occur during development of occasional branches which extend through ground tissue independent of phloem and terminate in contact with the epidermis. Presence of amorphous callose deposits is related to aging of laticifers and mechanical injury.     

夹竹桃科2种引种植物分泌结构的解剖学研究

为了解夹竹桃科(Apocynaceae)植物乳汁管的发生发育,对爱之蔓(Ceropegia woodii)和百万心(Dischidia ruscifolia)营养器官中的分泌结构进行了显微观察。结果表明,爱之蔓和百万心营养器官中均有无节分枝乳汁管的分布,茎皮层中的乳汁管大部分具有明显的分枝,叶中乳汁管具明显分枝,分布与走向多与叶脉维管组织平行。另外,爱之蔓营养器官中的分泌结构除乳汁管外,还有分泌腔。这为夹竹桃科植物的系统分类研究提供了解剖学依据。     

ULTRASTRUCTURE OF DEVELOPING AND MATURE NONARTICULATED LATICIFERS IN THE MILKWEED ASCLEPIAS SYRIACA L. (ASCLEPIADACEAE)

The ultrastructure of developing and mature nonarticulated laticifers in Asclepias syriaca L. (the common milkweed) was studied by conventional fixation and staining techniques and by osmium impregnation techniques. The mature laticifer protoplast in A. syriaca possesses a large central vacuole with an intact vacuolar membrane. Formation of this vacuole apparently results from dilation and subsequent enlargement of endoplasmic reticulum and possibly in part by fusion of smaller vacuoles and limited cellular-lytic autophagy. Widespread digestion or autophagy of cytoplasm within vacuoles is not evident. Nuclei, mitochondria, dictyosomes, and small vesicles are the most prominent components distributed in the peripheral cytoplasm. Plastids appear to degenerate as the laticifer matures. The specialized cellular component, latex, which is the vacuolar content of the laticifer, is interpreted to be produced in the cytoplasm and subsequently incorporated into the large central vacuole. Rubber globules, the most prominent latex component, are surrounded by a membrane that does not have a trilaminate structure. Globules are associated with an electron-dense fibrillar component in the vacuole.     

Lysosome and proteasome pathways are distributed in laticifers of Euphorbia helioscopia L.

At present, the lysosome pathway (LP) and proteasome pathway (PP) are known as major clearance systems in eukaryotic cells. The laticifer, a secretory tissue, degrades some cytoplasm during development. In this study, we investigated the distribution of LP and PP in non‐articulated laticifers of Euphorbia helioscopia L. Electron microscopy revealed that, plastids, mitochondria and some cyotsol were degraded in the late development laticifers, where there were numerous vesicles originated from dicytosomes. Accordingly, some key proteins in LP and PP were detected in E. helioscopia latex using isobaric tags for relative and absolute quantitation (iTRAQ) proteomics. Further immunohistochemistry analysis revealed that the clathrin heavy chain (CHC) belonging to LP and the ubiquitin‐mediated proteasome degradation increases gradually as the laticifer develops. Immuno‐electron microscopy revealed that the cysteine protease, CHC and AP‐2 complex subunit beta‐1 belonging to LP were mainly distributed in vesicles deriving from dicytosomes, which we called lysosome‐like vesicles. Ubiquitin was widely distributed in the cytosol, and proteasome activity was significantly reduced when various concentrations of the inhibitor MG132 were added to the latex total protein. We hypothesize that LP and PP are distributed in E. helioscopia laticifers; and it was speculated that LP and PP might be involved in the degradation of organelles and some cytoplasmic matrix in E. helioscopia laticifers.     

Immunolocalization of beta-D-glucans,pectins, and arabinogalactan-proteins during intrusive growth and elongation of nonarticulated laticifers in Asclepias speciosa Torr

Nonarticulated laticifers are latex-containing cells that elongate indefinitely and grow intrusively between the walls of meristematic cells. To identify biochemical mechanisms involved in the growth of nonarticulated laticifers, we have analyzed the distribution of various polysaccharides and proteoglycans in walls of meristematic cells in contact with laticifers, nonadjacent to laticifers, and in laticifer walls. In the shoot apex of Asclepias speciosa, the levels of callose and a (1-->4)-beta-galactan epitope are lower in meristematic walls in contact with laticifers than in nonadjacent walls. In contrast, we did not detect a decline in xyloglucan, homogalacturonan, and arabinogalactan-protein epitopes upon contact of meristematic cells with laticifers. Laticifer elongation is also associated with the development of a homogalacturonan-rich middle lamella between laticifers and their neighboring cells. Furthermore, laticifers lay down walls that differ from those of their surrounding cells. This is particularly evident for epitopes in rhamnogalacturonan I. A (1-->5)-alpha-arabinan epitope in this pectin is more abundant in laticifers than meristematic cells, while the opposite is observed for a (1-->4)-beta-galactan epitope. Also, different cell wall components exhibit distinct distribution patterns within laticifer walls. The (1-->5)-alpha-arabinan epitope is distributed throughout the laticifer walls while certain homogalacturonan and arabinogalactan-protein epitopes are preferentially located in particular regions of laticifer walls. Taken together, our results indicate that laticifer penetration causes changes in the walls of meristematic cells and that there are differences in wall composition within laticifer walls and between laticifers and their surrounding cells.     

Structure of the Bark and Clonal Variability in Hevea brasiliensis Muell. Arg. (Willd. ex A. Juss.)

Detailed studies have been made on the structure of the barkof ten Hevea clones and the clonal variabilities with regardto the density and size of ray groups, density of laticifersper row per unit circumference of the tree, diameter of laticifersand the extent of connection between laticifers. Clonal variabilitywas highly significant with regard to the density of ray groups,ray height, ray width in the laticifer layer and the laticifercharacters. The influence of ray characters on the orientationof laticifers and thereby its quantity is discussed. The scopeof using anatomical parameters for clone identification is examined. Hevea brasiliensis, Para rubber tree, laticifers, bark (structure), anatomy, clonal variability, rubber     

Histochemical study of detailed laticifer structure and rubber biosynthesis-related protein localization in <Emphasis Type="Italic">Hevea brasiliensis</Emphasis> using spectral confocal laser scanning microscopy

In Hevea brasiliensis, laticifers produce and accumulate rubber particles. Despite observation using histochemical methods, development stage structure and structures with ceasing functions have rarely been described. Spectral confocal laser scanning microscopy with Nile red staining simplifies laticifer structure observation in tangential sections while enhancing the resolution. Laticifer and ray images were extracted from unmixed images and used to monitor changes during growth. A laticifer network structure developed from increased anastomoses between adjoining laticifers outside of the conducting phloem, but because of increased radial division and growth of rays, the network structure ruptured and disintegrated. We also investigated immunohistochemical localization of two rubber particle-associated proteins in the laticifers: small rubber particle protein (SRPP) and rubber elongation factor (REF). Mature bark test results show that SRPP is localized only in the laticifer layers in the conducting phloem; REF is localized in all laticifer layers. Because SRPP plays a positive role in rubber biosynthesis, results show that the rubber biosynthesis capability of laticifers is concentrated where rays and the sieve tube actively transport metabolites.     

Investigations of Laticifer Differentiation in Tissue Cultures Derived from Asclepias syriaca L.

Callus cultures of Asclepias syriaca were established from stemexplants and grown in tissue culture. The culture medium onwhich the callus was grown was modified to produce either planfletsof superficial origin on the callus or embryoids which wereanalyzed to determine whether laticifers differentiated in thesestructures. Mature zygotic embryos and adult plants of A. syriacanormally possess a well-developed network of intrusively-growingnon-articulated branched laticifers that arise only once duringplant develop ment from initials differentiated in the youngheart stage embryo. Embryoids were derived from two differentculture media. These embryoids were observed to lack laticifers,although they were similar in their morphology in other respectsto zygotic embryos. Plantlets of superficial origin were formedon each of the media employed in this study. These plantletswere observed to possess laticifers that resemble those in normalshoots. Embryoids and induced shoots represent experimentalsystems in which it may be possible to control for the firsttime the differentiation of the laticifer as a cell type instructures similar to those present in the normal plant.     

Fine structure and development of laticifers inGnetum gnemon L.

Summary Articulated laticifers are a regular component of stem cortex and pith ofGnetum gnemon L. Differentiation of laticifers starts very early and is completed within the very first centimeters adjacent to the apical meristem.Ultrastructurally, young laticifers ofGnetum can be distinguished from surrounding cells by the presence of characteristic cytoplasmic inclusions, called spherule complexes and composed of 40–70 nm light spherules and up to 0.5 by 1.0 m large particles. While there is no record on their first beginnings, a connection between rER and the large particles can be demonstrated during many steps of laticifer differentiation which includes an increase in spherule complex areas. On account of positive Sudan staining and responses to EM fixations and in comparison to other laticifers it is concluded that the spherule complexes are terpenoid-containing. A transition from spherules to larger particles (orvice versa) is discussed, but could not be documented.Relative to the formation of the spherule complexes the other changes during laticifer maturation are inferior. The vacuolar system, in close connection to an extensive ER system, does largely expand and finally takes over the almost entire cell lumina. Nuclei do persist for an extended period, even after breakdown of the end walls and during disorganization of the cytoplasm. Plastids in all stages of laticifer ontogeny are very rarely encountered.Supplemented part of an investigation presented in 1976 by S. H. to the Fakultät für Biologie der Universität Heidelberg in partial fulfilment of the requirements for the degree of a Diplom-Biologe.     

Accumulation of non-utilizable starch in laticifers of Euphorbia heterophylla and E. myrsinites

Starch biosynthesis and degradation was studied in seedlings and mature plants of Euphorbia heterophylla L. and E. myrsinites L. Mature embryos, which lack starch grains in the non-articulated laticifers, develop into seedlings that accumulate starch rapidly when grown either in the light or the dark. Starch accumulation in laticifers of dark-grown seedlings was ca. 47 and 43% of total starch in light-grown controls in E. heterophylla and E. myrsinites, respectively. In light-grown seedlings, starch was present in laticifers as well as parenchyma of stems and leaves, whereas in dark-grown seedlings starch synthesis was almost exclusively limited to laticifers. In 7-month-old plants placed into total darkness, the starch in chyma was depleted within 6 d, whereas starch in laticifers was not mobilized. The starch content of latex in plants during development of floral primordia, flowering, and subsequent fruit formation remained rather constant. The results indicate that laticifers in seedlings divert embryonal storage reserves to synthesize starch even under stress conditions (darkness) in contrast to other cells, and that starch accumulated in laticifers does not serve as a metabolic reserve. The laticifer in Euphorbia functions in the accumulation and storage of secondary metabolites yet retains the capacity to produce, but not utilize starch, a primary metabolite.     

Laticifers: An historical perspective

This review describes the development of the laticifer concept, with emphasis upon the nonarticulated type, from early observations of plant exudates and “juices” to the presentation of laticifers by Esau (1953). Classical writers and herbalists described practical applications of these substances. With the advent of the microscope early investigators believed that these substances occurred in structures present in most, if not all, plants and, wrongly, equated these structures to the circulatory system in animals. Introduction of the term, latex, into botany derived from its early use as a term for a blood component by physicians, and not for analogy to milk. However, the origin of the terms, laticifer and laticiferous, remains uncertain. Initial studies of laticifers were marked by the controversy of whether they represented intercellular spaces or elongated cells. Confirmation of their cellular character led to the designation of nonarticulated and articulated laticifers. Nonarticulated laticifers were shown to arise during early embryogeny in some plants. The ontogenetic origin of the articulated laticifer was unclear to early workers, but new laticifers were detected to be formed by cambium activity. Nonarticulated laticifers were described to develop by intrusive growth whereby tips of the cell penetrated between adjacent cells. The coenocytic condition of the nonarticulated laticifer resulted from nuclear divisions along the cell positioned in the growth region of the shoot and the subsequent distribution of the daughter nuclei along the length of the cell.     

Laticifers in Camptotheca acuminata Decne: distribution and structure

Summary. In this paper, a system of laticifers in Camptotheca acuminata Decne (Nyssaceae) is described. Laticifers were already present in the leaf primordia of the shoot apex. In the mature leaves, laticifers were found in the midrib and in the larger veins, both in the parenchymatic region delimited by vascular bundles and in the cortex just external to the phloem. In the stem, laticifers were present in both the primary and secondary body, running parallel to the longitudinal axis. They were located in the pith and in the cortex proximal to the phloem. No laticifers were found in the roots. The histochemical analyses indicated that the main compounds accumulated in laticifers were phenols. Neutral lipids and fatty acids were also present. Ultrastructural observations showed osmiophilic globules both in the vacuoles and in the peripheral regions of the cytoplasm of the laticifer cells. Plastids were present, although altered, with some parallel membranes and lacking starch grains. The discovery in C. acuminata of a laticifer system, which had never been described for the order Cornales, could be of taxonomic value, also considering that this order has traditionally represented one of the most problematic groups of flowering plants. Correspondence and reprints: Dipartimento di Biologia Vegetale, Università “La Sapienza”, Piazzale Aldo Moro 5, 00185 Rome, Italy.