Vacuolation: Origin and development of the lysosomal apparatus in root-tip cells

Summary The morphology of vacuolation has been investigated in root tip cells of corn using the freeze-etching technique. The genesis of vacuoles involves the following processes: a) Formation of small, endoplasmic-reticulum (ER)-derived vesicles (provacuoles); b) fusion of provacuoles resulting in the formation of small vacuoles, and followed by fusion and expansion of vacuoles; c) incorporation of large, dictyosome-derived vesicles into vacuoles by invagination of the tonoplast; d) invagination of the tonoplast resulting in the incorporation of cytoplasmic material into vacuoles. The morphological findings are correlated with biochemical data obtained from isolated vacuoles (lysosomes). Provacuoles (ER-derived vesicles) are shown to be primary lysosomes; their hydrolases arise from the ER. Vacuoles represent secondary lysosomes (digestive vacuoles) of the higher-plant cell. The metabolic role of lytic processes proceeding in the lysosomal apparatus is discussed.     

The Golgi apparatus in epidermal mucoid and ellipsoid-vacuolate cells ofAeolidia papillosa andCoryphella rufibranchialis (Nudibranchia)

Summary The epidermal cell layer of the apical end of the ceras was investigated in two species of aeolid nudibranchs. Based on cellular inclusions, mostly two cell types were found: mucoid and ellipsoid-vacuolate cells. Mucoid cells ofCoryphella rufibranchialis have large heterogeneous and fibrillar secretory granules whereas inAeolidia papillosa, the granules are homogeneous, but vary in electron density from one cell to another. Ellipsoid-vacuolate cells contained large quantities of small vacuoles with an included ellipsoidal structure. Both species contained very numerous ellipsoid-vacuolate cells. Secretory granules and ellipsoid-vacuoles appear to arise from the Golgi apparatus and these contents stain with PAS, suggesting a polysaccharide composition. Mucoid cells contained both secretory granules and ellipsoid-vacuoles which may arise from the same Golgi apparatus.     

VACUOLE FORMATION IN THE ACTIVELY GROWING ROOT MERISTEM OF BARLEY (HORDEUM SATIVUM)

The subapical meristem of actively growing barley roots produces series of undifferentiated cells, some of which are devoid of vacuoles. At the beginning of their differentiation, the Golgi apparatus gives rise to vesicles and tubules which concentrate hydrolases, acid phosphatase being the typical representative of these enzymes. Some of these structures organize themselves as sequestration vacuoles. Then, the imprisoned fraction is destroyed by the process of autophagy after an alteration of the vacuolar internal membrane. These structures are identical to the “provacuolar apparatus” described by Marty in Euphorbia characias roots. Lytic processes which develop in autophagic vacuoles give rise to the first true meristematic vacuoles. Relations between dictyosomes, provacuoles and vacuoles, and their degree of exclusivity are discussed.     

An electron microscopical study of absorbing cells in the posterior caput epididymidis of rabbits

Summary The columnar cells in regions 3 and 4 of the ductus epididymidis in rabbits display ultrastructural features characteristic of absorbing cells. The stereocilia show basal anastomoses and often a fibrillar core continuous with a fibrillar web in the apical cytoplasm. Numerous invaginations of the slightly downy apical cell membrane and many thick-walled apical vesicles and vacuoles contain an opaque substance similar to that seen in the lumen. The vacuoles often contain small vesicles or bodies, probably formed from the vacuolar wall by budding. Numerous bodies or vacuoles with moderately dense contents are seen in the Golgi area and in the supranuclear and intranuclear cytoplasm in region 3. In region 4 they are denser and mainly seen above the nucleus. A high acid phosphatase activity was demonstrated in most dense and some light bodies. India ink introduced by way of the rete testis was taken up from the lumen into apical invaginations, vesicles and vacuoles and slowly transferred to denser bodies below the Golgi apparatus.These observations are interpreted as evidence for a resorption of substances from the lumen by a pinocytotic process, and for their storage and perhaps digestion in the dense bodies, which appear to have a lysosomal character. The Golgi apparatus is large with many vesicles of two types and empty cisternae but few typical Golgi vacuoles. The partly granular endoplasmic reticulum is very well developed and has opaque contents. Microtubules run from the terminal bar region into the Golgi area. Thick-walled vesicles occur throughout the cytoplasm, sometimes in continuity with the cell membrane. The basal parts of the cell borders often interdigitate.Supported by a grant from the Swedish State Medical Research Council.     

A mitochondrion as the structural basis of the formation of a cell-type-specific organelle inDictyostelium development

Summary The mitochondrion has been mainly given attention as a self-reproductive and respiratory organelle. We report here that the mitochondrion may participate in the formation of a cell-type-specific organelle, coupling with the Golgi complex. During the development ofDictyostelium discoideum, the two types of cells, i.e., the anterior prestalk cells and the posterior prespore cells form a polarized cell mass. Prespore differentiation is characterized by the presence of unique vacuoles named PSVs (prespore-specific vacuoles) in the cytoplasm. Thus the PSV is the most essential organelle to understand the structural basis of cell differention in this organism. In differentiating prespore cells, the mitochondrion exerts a remarkable transformation to form a sort of vacuole (M-vacuole). Using a PSV specific antibody, it was immunocytochemically shown that a PSV antigen (C-10) is localized in the M-vacuole as well as in the lining membrane of PSV. Interestingly, the C-10 antigen was also noticed in the Golgi cisternae that had fused with M-vacuole. Based on these findings, we propose here a promising model which suggests how both mitochondria and Golgi cisternae may be coordinately involved in the PSV formation. This model will provide a new aspect of mitochondrial functions in cell differentiation.     

Observations on the Fine Structure of the "Cyst Stage" of Besnoitia jellisoni

SYNOPSIS. Light and electron microscope studies of the "cyst" of Besnoitia jellisoni indicate that it consists of an extracellular wall, a large, sometimes multinucleate, host cell, and an intracellular vacuole containing the parasites. The "cyst" wall has fine fibrils and small dense granules embedded in an election-lucid matrix. The wall may be formed from a secretion of the enclosed host cell. The plasma membrane of the host cell is very irregular, being modified into microvillar or pseudopodial extensions. Small vesicles and invaginations of the plasma membrane indicate mioropinocytosis. The one to several large lobular nuclei lie in a thick area of cytoplasm which is filled with rough endoplasmic reticulum and many mitochondria with lamellar cristae. The parasite-containing vacuole is limited by a vacuolar membrane which has many blebs suggesting a transfer of materials into the vacuole.
The "cyst" organisms are crescentic or piriform and are enclosed by a pellicle consisting of outer and inner membranes. Twenty-two subpellicular fibrils extend longitudinally adjacent to the inner membrane from the anterior polar ring to a posterior ring. A micropyle is situated laterally in the pelliole near the level of the nucleus. A conold and several associated paired organelles are present at the anterior end. Microuemes, more abundant in older organisms, are also present in the anterior portion of the parasite. A Golgi apparatus lies adjacent and anterior to the nucleus. One or more mitochondria with saccular cristae, ovoid glycogen bodies, free ribosomes and occasional vacuoles are also present. Organisms within the "cyst" multiply by endodyogeny.     

The feeding apparatus of a chitinivorous ciliate

The chitinivorous ciliate Ascophrys, an ectosymbiont of the shrimp Palaemon serratus, is enclosed by a thick cyst wall except for a ventral hiatus exposing a circular area of exoskeleton to the interior of the cyst. The exoskeleton underlying the cyst wall remains intact, but the circular area of exoskeleton is dissolved enzymatically and ingested. The feeding ciliate forms a cavity in the exoskeleton into which it sinks. Its complex oral apparatus resembles a pump encircled by cytoplasm containing Golgi and high concentrations of coated vesicles that join pellicular pores between cilia. The ingestive apparatus is formed of microtubular lamellae that originate in the midplane of the body, descend toward a coated membrane on the surface, and ascend again as a lamellar lining to a complex food tube that ends in the middle of the body surrounded by food vacuoles. The cytoplasm enclosed between the descending lamellae and the food tube is crowded with membrane organelles that recycle as food vacuole membranes at the coated membrane. We hypothesize that vacuoles containing dissolved exoskeleton are drawn up into the oral tube and are released into the cytoplasm at the terminus of the tube, where their contents are concentrated and excess vacuolar membrane collapsed into membrane organelles.     

Invaginated apical vacuoles in the cells of the proximal convoluted tubule in the rat kidney

Summary Following perfusion fixation of the rat kidney with glutaraldehyde the proximal tubule cells display small apical vacuoles, large apical vacuoles, and apical vacuoles in which a part of the limiting membrane is invaginated into the vacuole. These invaginated apical vacuoles occur more frequently in proximal convoluted tubules than in proximal straight tubules. One tubular cell may contain apical vacuoles of different sizes and stages of invagination, ranging from larger vacuoles with a wide lumen and a small area of invaginated membrane to smaller elements with no apparent lumen and a large area of invaginated membrane. Invaginated apical vacuoles lie either singly in the cytoplasm or close to the membranes of other apical vacuoles, but never in contact with the cell membrane or the membranes of lysosomes, endoplasmic reticulum, Golgi apparatus, mitochondria and peroxisomes.These findings suggest that the invaginated apical vacuoles are not fixation artifacts, but rather develop in living state in cells of the proximal tubule from spherical endocytotic elements.Supported by the Deutsche Forschungsgemeinschaft (SFB 105)     

Encystment ofBodo caudatus

Summary Before formation of the cyst wall, the food vacuoles are lost, the cell rounds up and the flagella lie close against the body in a flagellar groove. At this early stage, the contractile vacuole is very active, the Golgi apparatus is prominent and the basophilic cytoplasm is composed of closely packed ribosomes. As the cyst wall is secreted, layer by layer, the large Golgi apparatus is replaced by several smaller membrane stacks and mitochondrial changes occur involving local loss and modification of the cristae. Some parts of the mitochondrion undergo degenerative changes and may become surrounded by bacilliform bodies. These same bodies are also associated with small particles of sequestered cytoplasm which are present throughout the encystment process and are believed to be autophagic vacuoles. As the cyst wall thickens, cell shrinkage is manifest as a number of membrane invaginations. The final cyst wall is of uneven thickness and possesses a single operculum which is visible only by electron microscopy. Probable cyst wall precursor is found in small vesicles scattered throughout the cytoplasm.     

Immunocytochemical Localization of Enzymes Involved in Lignification of the Cell Wall

O -methyltransferase, and cinnnamyl alcohol dehydrogenase were localized to differentiating xylem. These enzymes are particularly abundant during secondary wall formation. Immunolabeling was observed on polysomes and in the cytosol of the cells during secondary wall formation, indicating that these enzymes are synthesized in the polysomes and released in the cytosol. The synthesis of monolignols might occur in the cytosol. Immunolabeling of anionic peroxidase was also localized to the differentiating xylem, particularly during secondary wall formation. The labeling, however, was observed in the rough endoplasmic reticulum (r-ER), the Golgi apparatus, and the plasma membrane, indicating that peroxidase is synthesized in the r-ER, transported to the Golgi apparatus, and localized on the plasma membrane by fusion of the Golgi vesicles to the membrane. Received 3 September 2001/ Accepted in revised form 16 October 2001     

Tube formation by complex cellular processes in Ciona intestinalis notochord

In the course of embryogenesis multicellular structures and organs are assembled from constituent cells. One structural component common to many organs is the tube, which consists most simply of a luminal space surrounded by a single layer of epithelial cells. The notochord of ascidian Ciona forms a tube consisting of only 40 cells, and serves as a hydrostatic “skeleton” essential for swimming. While the early processes of convergent extension in ascidian notochord development have been extensively studied, the later phases of development, which include lumen formation, have not been well characterized. Here we used molecular markers and confocal imaging to describe tubulogenesis in the developing Ciona notochord. We found that during tubulogenesis each notochord cell established de novo apical domains, and underwent a mesenchymal–epithelial transition to become an unusual epithelial cell with two opposing apical domains. Concomitantly, extracellular luminal matrix was produced and deposited between notochord cells. Subsequently, each notochord cell simultaneously executed two types of crawling movements bi-directionally along the anterior/posterior axis on the inner surface of notochordal sheath. Lamellipodia-like protrusions resulted in cell lengthening along the anterior/posterior axis, while the retraction of trailing edges of the same cell led to the merging of the two apical domains. As a result, the notochord cells acquired endothelial-like shape and formed the wall of the central lumen. Inhibition of actin polymerization prevented the cell movement and tube formation. Ciona notochord tube formation utilized an assortment of common and fundamental cellular processes including cell shape change, apical membrane biogenesis, cell/cell adhesion remodeling, dynamic cell crawling, and lumen matrix secretion.     

The cytology and ultrastructure of zoospores of Hydrurus foetidus (Chrysophyceae)

The unusual tetrahedral shape of Hydrurus foetidus (Vill.) Trev. zoospores is associated with a complex skeletal system of microtubules extending from a broad flagellar root (up to 19 microtubules) into each of three, pointed anterior processes. The posterior end, also pointed and supported by a separate set of microtubules, contains a single large chloroplast with a prominent posterior furrow containing mitochondrial elements. A large immersed pyrenoid is penetrated by paired thylakoids. There is no eyespot. Numerous large Golgi bodies occur immediately anterior to the nucleus and up to 5–6 contractile vacuoles lie near the cell surface at the anterior end. Two terminally inserted flagella extend from the cell surface, a long one serving for cell locomotion, and the other vestigial with an axonemal pattern of 9+0. The flagellar root system consists of: (1) a thin, striated rhizoplast extending from the basal body of the long flagellum and ramifying over the surface of a conspicuous, anteriorly directed, conical projection of the nucleus; (2) a broad microtubular root which emanates from near the basal body of the long flagellum and appears to function as a MTOC; (3) a compound root, consisting of a striated fiber and two associated microtubules, which runs alongside the basal body of the stubby flagellum before terminating at the cell surface; and (4) a short two-membered microtubular root, also associated with the basal body of the stubby flagellum. Other components of the flagellar apparatus include a large dense body near the proximal end of the basal body of the short flagellum, and a small, dense, core-like structure closely associated with one of its triplet fibers. The flagellar apparatus of H. foetidus is remarkably similar in ultrastructure to that of Chrysonebula holmesii Lund.     

Fine structure of the gastric epithelium of the ascidian botryllus schlosseri vacuolated and zymogenic cells

Summary Vacuolated and zymogenic cells, which are two of five cell types identified by electron microscopy in gastric epithelium of B. schlosseri, are described in detail. The vacuolated cells are characterized by one, or a few, supranuclear vacuoles containing myelin figures. A peculiar Golgi apparatus is consistently found at the base of the vacuoles; it consists of cisternae frequently containing small vesicles and tubules of constant diameter and/or a strong electron-opaque material. A variety of vesicles and multivesicular bodies are visible in the apical cytoplasm below long ribbon-like microvilli. The se findings suggest that the vacuolated cells are involved in absorptive and perhaps secretory activity. The zymogenic cells are characterized by a highly developed RER, numerous apical secretory granules and a well developed supranuclear Golgi apparatus. At the apical end, autophagosomes are frequently encountered, some of which contain also zymogen granules. Both cell types contain numerous lipid droplets, which are interpreted as an energy reserve available for the cells and for the entire colony during the change of generation. Correlation between structure and function in both cell types is discussed by taking into account the peculiar life cycle of B. schlosseri, as well as previously reported data on similar cells in other ascidians.We would like to dedicate this work to Prof. Giuseppe Reverberi on the occasion of his 70th birthday.The authors are indebted to Profs. A. Sabbadin and G. Mazzocchi for their most helpful suggestions and advice. We would also like to thank Mr. G. Tognon for technical assistance and the staff of the Stazione Idrobiologica di Chioggia for their assistance in collecting material. — This research was supported by a grant of C.N.R., contract from the Istituto di Biologia del Mare, Venezia, No. 7100396/04115542 and with the E.M. facilities of C. N. R. contract No. 70.01798.04.115.876.     

Fine structure of the intestine development in cultured sea bream larvae

At hatching, the gut cells of Sparus aurata are quite undifferentiated; however, slight ultrastructural differences can already be distinguished between the presumptive intestinal regions. The hindgut cells are more differentiated than midgut cells and the rectal cells show rather particular ultrastructural features. During days 1 (D1) and 2 (D2) after hatching, major changes occur that lead to full differentiation of the epithelial cells. Shortly before the onset of exogenous feeding (D3), the anterior intestine enterocytes can synthesize lipoprotein particles (LP) from endogenous lipids. The posterior intestine enterocytes show morphological features indicating a role in absorption and intracellular digestion of nutrients, whereas the rectal cells do not. Transient ciliated cells occur at hatching (D0) in the presumptive intestine, except in the caudal rectum, and disappear at the start of the late endotrophic phase about 3 days after hatching (D3). At hatching, very scarce enteroendocrine and leucocyte-like cells are found at the base of the gut epithelium. Their number increases throughout development. At D3 (late endotrophic phase), LP synthesized mainly in the periblast invade the circulatory system, interstitial spaces of the subepithelial tissue and intercellular spaces of the gut epithelium. When the endo-exotrophic phase begins (D4), the enterocytes can absorb exogenous food. Acid phosphatase activity was detected in microvilli, pical vacuoles and Golgi complex in both anterior and posterior enterocytes, as well as in supranuclear vacuoles (SNV) of posterior enterocytes, but not in the apical tubulovesicular system (TVS). During the exotrophic phase, large lipid droplets (LD) are found in anterior enterocytes, and the SNV occupy a large cell volume in posterior enterocytes. LP accumulate first in extracellular spaces and then are transferred to the circulatory system. Mucous and rodlet cells appear in the intestinal epithelium during the exotrophic phase, from D15.     

Osmium Zinc Iodide staining of Golgi elements in oocytes of Triturus cristatus

Summary Developing oocytes of the newt Triturus cristatus were studied in order to clarify the role played by the Golgi apparatus in the formation of yolk. The cytochemical method used for this purpose was that of Maillet (1968) which employs an Osmium Zinc Iodide (OZI) complex.Previtellogenic oocytes reveal a pattern of OZI staining only after hormonal (HCG) stimulation, following which both the Golgi apparatus and the multivesicular bodies are stained.Vitellogenic oocytes taken from non-hormonally stimulated females reveal OZI deposits in a number of vesicles peripheral to the Golgi apparatus as well as within the superficial layer of the forming yolk platelets. Following hormone stimulation, many of the Golgi apparatus located in the central ooplasm of vitellogenic oocytes have all their cisternae blackened by the OZI deposits; other apparatuses, more peripherally located, remain essentially unchanged in their staining pattern. Further, a large number of OZI stained vesicles becomes visible in the vicinity of the Golgi apparatus and within the superficial layer of the forming yolk platelets.The present findings are interpreted as indicating the occurrence of fusion between Golgi derived vesicles and forming yolk platelets. It is also suggested that the vesicles in question function as carriers of Golgi produced enzymes which are presumably required to accomplish the final elaboration of the yolk material.Supported by a grant from the Consiglio Nazionale delle RicercheWe acknowledge the valuable help received from Prof. G. Mancino throughout this investigation     

Uptake of Lucifer Yellow CH into intact barley roots: Evidence for fluid-phase endocytosis

Intact barley (Hordeum vulgare L.) roots have been shown to take up the highly fluorescent dye Lucifer Yellow CH (LYCH) into their cell vacuoles. In the apical 1 cm of root tip, differentiating and dividing cells showed a prolific uptake of LYCH into their provacuoles. The LYCH was retained during fixation, apparently becoming bound to electron-dense material in the vacuoles. The dye freely entered the apoplast of roots in which the Casparian band was not developed, being taken up into the vacuoles of cells in both the cortex and stele. However, when LYCH was applied to a 1-cm zone approx. 6 cm behind the root tip the Casparian band on the radial walls of the endodermis completely prevented the dye from entering the cells of the stele, only the cell walls and vacuoles of the cortical cells taking up the dye. The inability of LYCH to cross the plasmalemma of the endodermal cells and enter the stele via the symplast substantiates previous claims that the dye is unable to cross the plasmalemma of plant cells. The results are discussed in the light of recent demonstrations that LYCH is a particularly effective marker for fluid-phase endocytosis in animal and yeast cells. A calculation of the energetic requirements for LYCH uptake into barley roots supports the contention that LYCH is taken up into the vacuoles of plant cells by fluid-phase endocytosis.Abbreviation LYCH Lucifer Yellow CH     

Cellular details of the midgut of Cryptocellus boneti (Arachnida: Ricinulei)

The midgut of Cryptocellus boneti was studied by light and electron microscopy. The epithelia of the diverticula and of the anterior part of the midgut tube are composed of two cell types: digestive and secretory. In contrast, the epithelia of posterior part of the midgut tube and of the stercoral pocket consist of one type of cells only. In some places, parts of the midgut system are connected by an intermediate tissue. Digestive cells are characterized by an apical system of tubules, nutritional vacuoles, and spherites; characteristic features of secretory cells are secretory granules and a prominent rough endoplasmic reticulum. Cells of the midgut tube appear not to be involved in the absorption of food. © 1994 Wiley-Liss, Inc.     

FINE STRUCTURE OF THE MUCOCYSTS OF COLACIUM CALVUM (EUGLENOPHYCEAE)1

The characteristic stalk of Colacium calvum Stein is formed from carbohydrate extruded by granules in the anterior portion of the cell. These granules exhibit the characteristics of mucocysts and their contents have two electron densities. A narrow extension of each granule extends past neighboring muciferous bodies to attachment sites in the posterior notch of the pellicle strip. The granule contains neutral polysaccharide which resembles that in the peripheral cisternae of the Golgi apparatus. The attachment site is structurally complex.     

First report of Alexandrium taylori and Alexandrium peruvianum (Dinophyceae) in Malaysia waters

The occurrence of Alexandrium taylori and Alexandrium peruvianum is reported for the first time in Malaysia waters. The Malaysian A. taylori isolates were pyriform in shape with a transdiameter range of 36–40 μm and a cell length range of 33–37 μm. The first apical plate (1′) was pentagonal with two distinctive anterior margins. No direct connection between 1′ and the apical pore complex was observed. The posterior sulcal plate (S.p.) was large, elongated and oblique to the right with anterior projections. The ventral pore (vp) was relatively large and situated at a confluence point of 1′, the second apical (2′) and the fourth apical (4′) plates. Cells of A. peruvianum were slightly anteriorly and posteriorly compressed. S.p. had an irregular pentagonal shape, with the anterior margin divided into 2 portions. 1′ was boomerang-shaped with a large and truncated ventral pore in the middle right margin. The anterior right margin of 1′ was straight. The sixth precingular plate (6″) was wider than long. The anterior sulcal plate (S.a.) was triangular and lacked a left portion extension. In laboratory cultures, both A. taylori and A. peruvianum produced paralytic shellfish toxins, with GTX4 and GTX6 as the predominant toxin, respectively. This is the first report of PSP toxins production for both species as well as the occurrences in Malaysia waters.     

Immunolocalization of phenylalanine ammonia-lyase and cinnamate-4-hydroxylase in differentiating xylem of poplar

Phenylalanine ammonia-lyase (PAL; EC 4.3.1.5) and cinnamate-4-hydroxylase (C4H; EC 1.14.13.11) are pivotal enzymes involved in lignification. We synthesized peptides as the epitopes according to the amino acid sequences of these enzymes, coupled them with hemocyanin, and injected them into mice. The antiserums against peptides of PAL and C4H specifically detected PAL and C4H in the crude enzymes extracted from differentiating xylem of poplar, respectively. PAL and C4H were localized in differentiating xylem of poplar. PAL labeling was mainly localized in the cytosol, and somewhat localized on the rough-endoplasmic reticulum (r-ER) and the Golgi apparatus. In contrast, C4H was mainly observed on r-ER and the Golgi apparatus. These findings suggest that conversion of phenylalanine to cinnamic acid occurs in the cytosol and the following reaction occurs near the membrane of r-ER and the Golgi apparatus. The possibility of coordinated localization of PAL and C4H is discussed.