A CYTOCHEMICAL INVESTIGATION OF A CHLOROPLAST INCLUSION

The chemical composition of a membrane-bound plastid inclusion observed in genetic tumor cells of the amphiploid Nicotiana suaveolens X N. langsdorffii was studied by means of electron microscope cytochemistry. Treatment with the following enzymes had no effect on the ultrastructure of the inclusion: α-amylase, DNase, lipase, papain, pronase, protease, RNase, and trypsin. The only enzyme to alter the fine structure of the inclusion was pepsin, which decreased the electron density of the granular component of the structure. These results indicate that protein is the major chemical constituent of this membrane-bound plastid inclusion. This finding is discussed in relation to the possible role of the inclusion in plastid ontogeny.     

Structure and Development of Plastids in Epidermal Cells of African Violet (Saintpaulia ionantha Wendl.) in Culture

The structure of plastids in epidermal cells of African violet(Saintpaulia ionantha Wendl.) ‘Marge Winters’ wasexamined using transmission electron microscopy before and afterplacement of leaf tissue in culture. The plastids from matureepidermal cells contained membrane-bound inclusion bodies andprolamellar bodies in various stages of development. Starchgrains and poorly developed granal stacks were observed in asmall number of plastids. After placement of the leaves on suitableculture medium, inclusion bodies decreased in size and the lamellarsystem became more organized. The plastids in the epidermaltissue are believed to be in an arrested state of developmentand are released from this state by placement on a medium inductiveto organogenesis. Saintpaulia ionantha Wendl., African violet, membrane-bound inclusion, tissue culture, plastid development     

THE FINE STRUCTURE OF GENETIC TUMOR CELLS

Tissue from genetic tumors at an early stage of development on young seedlings of Nicotiana suaveolens x N. langsdorffii was examined with the electron microscope. Such tumors, which first appear on the stem immediately below the petioles of the first and second leaves, are composed essentially of three cell types. They are covered by a single layer of epidermal cells of which two specializations, guard cells and trichomes, were observed. The majority of cells in the tumors are large, irregularly shaped, highly vacuolated, parenchymal cells. Meristematic cells, which are found in clusters close to the surface of the tumor, are the third cell type. A membrane-bound inclusion was observed within the plastids of all of the cell types within the tumor. It consists of granular material which accumulates within an intrathylakoid space. There are no major differences in ultrastructure between parenchymal cells of genetic tumors and their normal counterparts from stems without any signs of tumor formation.     

THE FINE STRUCTURE OF THE GUARD CELLS OF HELIANTHUS ANNUUS

The guard cells of Helianthus annuus contain elements of endoplasmic reticulum and large numbers of mitochondria and dictyosomes. Each guard cell possesses a complex system of small to large vacuoles which contain small, membrane-bound vesicles; the vacuole may actually be one highly invaginated and dissected vacuole extending throughout the cell. A highly developed grana fretwork within the plastids implies full photosynthetic capability and the capability of producing the osmoticulum required for turgor change. No plasmodesmata occur between the sister guard cells or between the guard and epidermal cells. It is postulated that there is a close relationship between plastid development and the presence or absence of plasmodesmata. No microbodies were positively identified in any of the guard cells. Microtubules appear to lie in two planes, thereby giving support to the “two system” observation for microtubules in the guard cells of Pisum sativum.     

PLASTIDS IN LATICIFERS OF PAPAVER. I. DEVELOPMENT AND CYTOCHEMISTRY OF LATICIFER PLASTIDS IN P. SOMNIFERUM L. (PAPAVERACEAE)

Plastids were observed in all stages of laticifer differentiation in Papaver somniferum L. Plastids in laticifer initials were present as proplastids that later developed electron-dense inclusions, but never possessed the thylakoids or starch grains that characterize chloroplasts in other cells. Electron-dense inclusions in laticifer plastids were membrane-bound and appeared to arise from the accumulation of material within an invagination of the inner plastid membrane. Cytochemical studies of these plastid inclusions indicated that their matrix was not composed of crystalline protein, α-amylose, amylopectin or polysaccharide. The results suggest that the electron-dense, membrane-bound inclusions in laticifer plastids may be composed of lipoprotein.     

Intranuclear Inclusions in the Ameboid Cells of Protostelium zonatum*

SYNOPSIS. Two morphologically distinct types of intranuclear inclusions are found in ameboid cells of the protostelid mycetozoan Protostelium zonatum. One type of inclusion is a coiled tubular structure which in cross section appears as cisternae and oval to elliptical vesicles 40–60 nm in diameter. These tubular and vesicular structures are formed by a unit membrane that is connected directly with the inner nuclear membrane. The other type of inclusion is a membrane-bound structure that contains amorphous and/or fibrous material. These inclusions usually are present at several locations in a nucleus. No similar structures occur in the cytoplasm.     

Preprophasic establishment of division polarity in monoplastidic mitosis of hornworts

Summary Preprophase in the monoplastidic mitotic cells ofPhaeoceros andNotothylas is characterized by the establishment of a division site in the absence of a typical preprophase band. The future cytokinetic plane is predicted by plastid orientation and development of an elaborate preprophasic microtubule system perpendicular to the division plane. Division of the single plastid is initiated early in preprophase and the constricting plastid migrates to a position perpendicular to the future plane of division. Plastid orientation assures that division of the plastid by mid-constriction will result in distribution of a plastid to each daughter cell. Microtubules parallel the long axis of the plastid and are most numerous adjacent to the nucleus which becomes elongated in the future spindle axis. We conclude that the division site is a fundamental component of the cytokinetic apparatus involved in the determination of cleavage plane prior to nuclear division.     

Acidophilic granular cells in the epidermis of the brown trout,Salmo trutta L.

Summary Acidophilic cells occur in the epidermis of several species of salmonid fish, although their abundance fluctuates considerably between individuals within the same population and at different times during the life cycle. The histology, histochemistry and ultrastructure of an acidophilic, granular celltype in the epidermis of the brown trout, Salmo trutta L., is described. At the light microscope level this cell type is easily distinguished from the large, mucus-secreting, epidermal goblet cells by its acidophilic, proteinaceous secretion. At the ultrastructural level this secretion consists of membrane-bound granules formed by the very active Golgi region. It is argued that the acidophilic, granular cell is not a transformed blood cell but constitutes a normal epidermal component of the brown trout. Possible roles of this cell in the function(s) of the epidermis are discussed.     

Membrane-bound Plastid Inclusions and Chloroplast Thylakoid Formation in Sunflower (Helianthus annuus L.)

The ultrastructure, distribution and frequency of membrane-boundplastid inclusions present in the epidermal cells of leavesof intact sunflower plants (Helianthus annuus L.) and in theepidermal and mesophyll cells of sunflower leaf discs culturedin darkness have been studied. These inclusions appear to bedilated thylakoids containing a granular material which, undernormal conditions, is probably involved in chloroplast membraneformation. It is suggested that this material accumulates, andinclusions form, in the chloroplasts of sunflower leaves intwo specific situations. Firstly, in the completely differentiatedcells of the epidermis where the chloroplasts, although at arelatively immature stage, have nevertheless reached a terminalstage of development. Secondly, in the mesophyll cells of youngleaves when chloroplast development has been arrested at animmature stage by a 5-day dark period. In the latter situationthe material can be remobilized if plastid development is restimulated.The plastids of sunflower leaf discs cultured in darkness containboth membrane-bound inclusions and prolamellar bodies, indicatingthat they are separate and distinct structures possibly containingdifferent membrane components. Helianthus annuus L., sunflower, chloroplast, ultrastructure, plastid inclusions, thylakoid formation     

Die Siebröhren-Plastiden der Monocotyledonen

Zusammenfassung In vergleichenden feinstrukturellen Beobachtungen an 24 Monocotyledonen aus 21 Familien wird ein für Monocotylen-Siebröhren charakteristischer Plastidentyp näher beschrieben. Neben gelegentlichen Ablagerungen von Siebröhrenstärke enthalten ausdifferenzierte Siebröhren-Plastiden zahlreiche keilförmige, kontrastreiche und proteinhaltige Kristalloide. Sie entstehen in der Matrix der noch amöboiden Formveränderungen unterworfenen Proplastiden; in reifem Zustand werden sie aus gekreuzten Reihen paralleler, gerader und kontrastreicher Filamente (50–60 Å) aufgebaut.Die Siebröhren-Plastiden von Nymphaea alba und Nuphar luteum bilden keine Kristalloide aus, dagegen läßt sich Siebröhrenstärke wie in den übrigen bisher untersuchten Dicotylen nachweisen.

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Sieve-tube plastids of monocotyledonsComparative investigations of the fine structure and distribution of specific plastids

Summary Fine-structural investigations of 24 monocotyledons from 21 families and all but one order succeeded in revealing a plastid with cuneate proteinaceous inclusion bodies as being typical of monocot sieve-tubes. Inclusion bodies originate in large numbers during plastid differentiation; they concentrate in the matrix and aggregate around an invisible centre, that mostly lies at one end of the elongated ameboid proplastid. The inclusion-free part of the young plastid contains countless vesicles and short membranes, presumably invaginations of the inner plastid envelope. Proteinaceous inclusion bodies show a crystal-like structure composed of 50–60 Å subunits in straight and parallel order. Besides these crystal-like inclusion bodies sieve-tube plastids of many monocotyledons also contain starch. — Sieve-tube plastids of Nuphar luteum and Nymphaea alba look like plastids in dicotyledon sieve-tubes, starch being their only inclusion.

     

Nutlets micromorphology of some <Emphasis Type="Italic">Onosoma</Emphasis> L. (Boraginaceae) species from Turkey

Morphological and micromorphological characters of the nutlets of ten Onosma species in Turkey were reported. Studied fruit surfaces show some variations. Based on the structure and patterns of epidermis cells of the nutlets, two principal types can be distinguished. In Type 1, the epidermal cells of the nutlet surface are formed in a reticulate pattern with varied sizes and shapes of the meshes. This type is the most common type in the studied species. Seven of the species observed belong to the reticulate type, i.e. O. bracteosum, O. mutabile, O. aleppicum, O. bornmuelleri, O. aucheranum, O. araraticum and O. tauricum. In Type 2, the epidermal cells of the nutlet surface are formed in an elongated type with varied sizes and shapes. Three of the observed species belong to this type, i.e. O. roussaei, O. isauricum and O. stenolobum. Significant taxonomic differences between species were determined on the surface of the nutlets.     

Incomplete epidermal differentiation of A431 epidermoid carcinoma cells

Summary A431 malignant keratinocytes, although derived from a muco-cutaneous carcinoma of the vulva, fail to achieve terminal epidermal differentiation in culture as shown by their inability to form cornified envelopes. Even after culture in a serum-free medium (MCDB 153) containing no retinoic acid and a high (10⁻³ M) calcium concentration (conditions known to facilitate epidermal differentiation), the cells do not become competent as shown by the fact that subsequent treatment with a calcium ionophore is unable to provoke the formation of cornified envelopes. Nevertheless, A431 cells are able to synthesize the envelope precursor involucrin. The block in formation of cornified envelopes is thus not due to a lack in involucrin. The results described here suggest that the absence of cross-linking of this molecule is due to a lowered epidermal membrane-bound transglutaminase activity in A431 cells, enhances involucrin accumulation in these cells, although in normal human keratinocytes it stimulates growth and reduces involucrin synthesis. These results suggest that involucrin synthesis is triggered by the arrest of growth. EDITOR'S STATEMENT The A431 cell line has been used extensively in the study of EGF receptors and effects, and recently has been employed in studies of surface membrane receptors for other factors, as well as studies of extracellular matrix synthesis and deposition and tumor promoter activities. The expanding use of A431 cells calls for a more thorough understanding of the cell type it represents and the degree to which it represents a general in vitro model of normal or neoplastic epidermal cells. This article addresses some of these questions.     

Etude ultrastructurale de l'évolution du tégument de la Sangsue Hirudo medicinalis L. (Annélide,Hirudinée) au cours d'un cycle de mue / Developmental changes in the integument of the leech Hirudo medicinalis L. (Annelida,Hirudinea) during a molting cycle. An ultrastructural study

Summary

The integument of the leech Hirudo medicinalis is mainly composed of a single layer of cuticle-secreting epidermal cells. The cuticle is made up of collagen fibers which support a layer of membrane-bound epicuticular projections.

Shedding of the old cuticle is preceded by the formation of a new cuticle. The epicuticular projections are the first to develop: they originate from the tips of numerous microvilli of the epidermal cells. As soon as it appears, the newly-formed collagen layer is firmly attached to the epidermal cells by numerous hemidesmo-somes, whereas the old cuticle is no longer connected with the epidermal surface. The epidermal cells exhibit marked characteristics of secretory activity during the laying down of the new cuticle.

The observations are discussed in connexion with recent findings of high ecdysteroid levels in leeches at the beginning of the molting cycle.     

The chromoplasts of Or mutants of cauliflower (Brassica oleracea L. var. botrytis)

Summary. The Or mutation in cauliflower (Brassica oleracea L. var. botrytis) leads to abnormal accumulations of -carotene in orange chromoplasts, in tissues in which leucoplasts are characteristic of wild-type plants. Or chromoplasts were investigated by light microscopy of fresh materials and electron microscopy of glutaraldehyde- and potassium permanganate-fixed materials. Carotenoid inclusions in Or chromoplasts resemble those found in carrot root chromoplasts in their optical activity and angular shape. Electron microscopy revealed that the inclusions are made up of parallel, membrane-bound compartments. These stacks of membranes are variously rolled and folded into three-dimensional objects. We classify Or chromoplasts as membranous chromoplasts. The Or mutation also limits plastid replication so that a single chromoplast constitutes the plastidome in most of the affected cells. There are one to two chromoplasts in each cell of a shoot apex. The ability of differentiated chromoplasts to divide in the apical meristems of Or mutant plants resembles the ability of proplastids to maintain plastid continuity from cell to cell in meristems of Arabidopsis thaliana mutants in which plastid replication is drastically limited. The findings are used to discuss the number of levels of regulation involved in plastid replication.     

Complex epidermal organs of Phascolion (Sipuncula): insights into the evolution of bimodal secretory cells in annelids

The epidermal organs of an undescribed Phascolion species from the Balearic Islands were investigated using SEM, TEM, LM, CLSM and μCT methods. We found axial receptor cells confirming the previously assumed sensory function of epidermal organs. Our analyses also revealed six types of secretory cells. Some secretory cells types are capable of secreting filamentous and amorphous secretion in two different ways simultaneously (bimodal secretion). The high diversity of cell types, the complex pattern of acinar units, and the absence of a common gland pore make epidermal organs of Phascolion unique amongst sipunculans (Phascolion type). Our reconstruction of the evolution of the epidermal organs of Sipuncula revealed that Phascolion‐type epidermal organs may have derived from either Golfingia‐, Sipunculus‐ or Phascolosoma‐type epidermal organs. The oldest known sipunculans were Golfingia‐like and had epidermal organs, which might resemble the architecture of the Golfingia‐type epidermal organs in extant taxa. Thus, it can be hypothesized that bimodal secretory cells (e.g. basophilic secretory cells) were part of the sipunculan ground pattern. Moreover, bimodal secretory cells of Phascolion look strikingly similar to those found in various annelid glands and thus might even be part of the ground pattern of stem species of Sipuncula + Pleistoannelida.     

The isolation of apparently homoplastidic mutants induced by a nuclear recessive gene in Arabidopsis thaliana

Summary The nuclear recessive gene, chm1, of Arabidopsis thaliana is a imitator that induces a variety of plastid alterations giving rise to mixed cells and variegated leaves. The variegation is maternally transmitted but chm1 is transmitted in a Mendelian fashion (Rédei 1973; Rédei and Plurad 1973). In order to characterize the different types of plastid alterations induced by chm1, isolating homoplastidic lines, each apparently containing one type of mutant plastid in its cells, was essential since such characterization cannot be carried out on mixed cells. We have used two genetic approaches to isolate several apparently homoplastidic mutant lines by the removal of the mutator from the genetic background, and the maternal transmission of the mutant plastids. The rapidity of obtaining homoplastidic lines in the absence of chm1 indicated a non-stochastic sorting-out of plastids in mixed cells. That each of the chm1-free homoplastidic mutant lines was apparently homoplastidic for one type of mutant plastids was confirmed by electron microscopic observations. Here we report, for the first time, the production of different homoplastidic lines in the absence of the nuclear-mutator gene. Such genetically-stable homogeneous material should be a useful tool for studying the molecular mechanism(s) by which chm1 induces a variety of heritable plastid alterations.     

Expression of the HB9 homeobox gene concomitant with proliferation accompanying epidermal stratification during development of chick embryonic tarsometatarsal skin

A homeobox gene, HB9, has been isolated from the tarsometatarsal skin of 13-day-old chick embryos using a degenerate RT-PCR-based screening method. In situ hybridization analysis revealed that, during development of chick embryonic skin, the HB9 gene was expressed in epidermal basal cells of the placodes, but not in those of interplacodes, and in the dermal cells under the placodes at 9 days before addition of an intermediate layer by proliferation of the basal cells in the placodes. With the onset of epidermal stratification, the direction of the basal cell mitosis changed, with the axis becoming vertical to the epidermal surface. Placodes and interplacodes form outer and inner scales, respectively, after they have elongated distally (Tanaka S, Kato Y (1983b) J Exp Zool 225: 271–283). During scale ridge elongation at 12–15 days, HB9 was strongly expressed in the epidermis of the outer scale face, where the cell proliferation is more active than in the epidermis of the inner scale face; hence, stratification of the outer scale face is more prominent than that of the inner scale face. After 16 days, when mitotic activity in the epidermal basal cells decreases and the thickness of the epidermis is maintained at a constant level, the HB9 expression decreases with the onset of epidermal keratinization. These results suggest that HB9 may be involved in the proliferation of the epidermal basal cells that accompanies epidermal stratification.     

In situ plastid and mitochondrial DNA determination: Implication of the observed MINIMAL PLASTID GENOME NUMBER

The total loss of plastid DNA has never been reported for any alga or plant cell line, with the sole exception of the protozoan Euglena, yet plastid distribution at mitosis is apparently stochastric (Birky and Skavaril, Journal of Theoretical Biology, vol. 106, pp. 441–447, 1984) and accidental loss might be expected. It is not obvious how stem cells of photosynthetic eukaryotes avoid this problem. The chrysophyte alga Ochromonas danica, described as having but one or two plastids, can proliferate indefinitely without the benefit of photosynthesis. Under such conditions its plastid genome copy number per cell might drop to the absolute minimum compatible with maintaining its inheritance. In situ quantitation of Ochromonas plastid DNA in both photosynthetic and enriched mixotrophic growth, and in heterotrophic growth in prolonged darkness, suggests that plastids are capable of very wide variation (7 to >;200 genomes/plastid) in their DNA content, and likewise, cells can vary from one to >;8 plastids per cell, with total genomes numbers from 7 to >;1,000 per cell. Among many growth conditions tested, the smallest plastids were found in rapidly dividing cells grown in the dark, many of which contained but one plastid. The inability to find plastids with fewer than seven plastid genome equivalents of DNA, even in these rapidly multiplying cells grown in total darkness for months, suggests that multiple copies of the plastid genome may be very carefully maintained, even in the prolonged absence of photosynthesis. This implies that multiple copies are important for reasons other than photosynthetic capability; two possibilities are the biosynthetic steps necessary for eukaryote cell survival known to occur solely within a plastid, and/or the potential that multiple plastid genome copies provide to escape the effects of Muller's ratchet.     

Cryptic hybrids between Pinus uncinata and P. sylvestris

We tested the performance of molecular markers and biometric traits in the identification of hybrids between closely related mountain pine (Pinus uncinata) and Scots pine (Pinus sylvestris). A plastid DNA marker and a set of morphological and anatomical needle traits were applied in analyses of individuals from several sympatric stands of the species and a single‐species' population from southern Europe, used as a reference. A polymerase chain reaction‐restriction fragment length polymorphism (PCR‐RFLP) marker from the plastid trnL–trnF region and morphological and anatomical traits clearly discriminated between the pure species. Significant differences were found between P. uncinata and P. sylvestris, mostly in the shape of epidermal cells and the number of stomata. Four putative hybrids with P. sylvestris morphology, but with P. uncinata plastid DNA haplotypes, were found in a population from Sierra de Gúdar near Valdelinares, the southernmost locality of the latter species in eastern Spain. Discrimination analyses between and within populations placed these individuals on the edge of an agglomeration of P. sylvestris individuals. The results suggest that hybridization between the species is rare, but can result in cryptic hybrids morphologically similar to the maternal species. © 2010 The Linnean Society of London, Botanical Journal of the Linnean Society, 2010, 163 , 473–485.     

Plastid division and morphology in the genus Peperomia

We have investigated several factors determining plastid size and number in Peperomia, a genus in the Piperaceae family whose species naturally display great interspecific variation in chloroplast size and number per cell. Using microscopic techniques, we show that chloroplast size and number are differently regulated in the palisade parenchyma and the spongy parenchyma, suggesting that chloroplast division in these cell types is controlled in different ways. Microscopic studies of iodine-stained root cells revealed a correlation between amyloplast size in root cells and chloroplast size in palisade parenchyma cells. However, despite substantial variation in chloroplast number in leaf mesophyll cells, amyloplast number in root cells was very similar in all species. The results suggest that organelle size and number are regulated in a tissue-specific manner rather than in dependency on the plastid type. We also demonstrate that plastid size determines the size but not the number of starch grains in root amyloplasts.