Effects of ethanol on rat schwann cell proliferation and myelination in culture

Summary It is possible to treat dissociated embryonic rat dorsal root ganglia in culture to inhibit proliferation of all nonneuronal cells except Schwann cells. Neurons have been shown to produce a mitogenic stimulus for Schwann cells under these conditions. Additionally, myelin-competent neurons induce Schwann cells to elaborate myelin sheaths. Groups of sibling cultures were exposed to various nonlethal concentrations of ethanol (0, 43, 86, or 172 mM) for 4 wk. Culture were assessed weekly by light microscopy in a blind fashion for evidence of Schwann cell proliferation and myelin formation. Ethanol adversely affected both Schwann cell proliferation and myelin formation in culture. No obvious differences in neuronal morphology were observed among the various groups of cultures by light or electron microscopy. These observations suggest that ethanol might interfere with Schwann cell proliferation and myelin formation in culture by one or both of the following means: a) inhibit neuronal production of signals for Schwann cell proliferation and myelination or b) impede Schwann cell responses to neuronal signals. Investigation of these possibilities in culture may provide insight into neuropathologic mechanisms operative in the fetal alcohol syndrome or alcohol-associated peripheral neuropathy in humans. This work was supported by the Department of Veterans Affairs, Washington, D.C.     

The in vitro antibiofilm activity of selected marine bacterial culture supernatants against Vibrio spp.

The aim of the work is to investigate the effect of marine bacterial culture supernatants on biofilm formation of Vibrio spp., a major menace in aquaculture industries. Vibrio spp. biofilm cause life-threatening infections in humans and animals. Forty-three marine bacterial culture supernatants were screened against the hydrophobicity index, initial attachment and biofilm formation in Vibrio spp. Twelve culture supernatants showed antibiofilm activity. The bacterial culture supernatants S8-07 (Bacillus pumilus) and S6-01 (B. indicus) inhibited the initial attachment, biofilm formation and dispersed the mature biofilm at 5% v/v concentration without inhibiting the growth. Analysis by light microscopy and confocal laser scanning microscopy showed that the architecture of the biofilm was destroyed by bacterial supernatants when compared to the control. The bacterial supernatants also reduce the surface hydrophobicity of Vibrio spp. which is one of the important requirements for biofilm formation. Further characterization of antibiofilm activity in S8-07 culture supernatant confirmed that it is an enzymatic activity and the size is more than 10 kDa and in S6-01, it is a heat-stable, non-protein compound. Furthermore, both the supernatants failed to show any biosurfactant activity. The culture supernatants of S8-07 and S6-01 with promising antibiofilm property have potential for application in medicine and marine aquaculture.     

Floral morphogenesis in thin-layer tissue cultures of Nicotiana tabacum

The morphological changes in thin-layer tissues of Nicotiana labacum L. cv. Samsun, cultured on Murashige and Skoog medium with 1 μ M each of naphthalene acetic acid (NAA) and benzyladenine (BA), were studied during the first 8 days of culture with light and scanning electron microscopy. The first three days of culture arc characterized by enlargement of all cells and cell divisions starling in the cortical parenchyma cells adjacent to the medium. Between days 3 and 6, epidermal and/or subepidermal cells start to divide, resulting in division centers, which lead to flower bud formation. The hormones NAA and BA in different concentrations affect the formation and distribution of flower buds, bud morphology and callus formation. BA influences particularly bud formation and bud morphology, while NAA affects callus formation in particular. In addition, polarity may occur in the formation of both callus and flower buds, the degree of which depends upon the hormone concentrations.     

Characterization of the Growth of Herpes Simplex Virus in Human Lymphoid Cells

Herpes simplex virus was grown in a 6-liter suspended culture of an atypical permanent human lymphoid cell line, Roswell Park Memorial Institute no. 8226. The kinetics of virus replication were determined by counting viruses by electron microscopy, plaque formation, and tissue culture infectivity. Deoxyribonucleic acid-dependent deoxyribonucleic acid polymerase activity was determined during the course of infection. Electron microscopy studies substantiated the kinetics of the virus infection in lymphoid cells.     

Electron microscopic study of several features of spore formation in type B Clostridium perfringens]

The authors carried out electron microscopy of the thin sections of Cl. perfringens, type B (strain No. 89). Material of middle electron density was revealed on the cell wall surface from the first hours of the culture growing; the cytoplasm displayed both rod-like incorporations with transverse striations, and phage particles. Different spore formation disturbances were revealed in the strain under study. In the majority of cells spore formation was blocked at the III--V stage. Besides, there were pseudospores, whereas mature spores were rarely encountered, and even those which did occur, were at the stage of growing.     

Impact of disinfectant and nutrient concentration on growth and biofilm formation for a Pseudomonas strain and the mixed cultures from a fine papermachine system

Biofilm formation in papermaking processes could inflict financial loss by interrupting paper machine operation and pose a potential health hazard. A mixed microbial culture obtained from paper machine slime and a Pseudomonas strain (identified as Pseudomonas putida HB45) which is tolerant to the alkyl dimethyl benzyl ammonium chloride (quaternary ammonium chloride, QAC) were used to investigate the interplay between disinfectants and glucose on bacterial growth and biofilm formation. QAC and 2,2-dibromo-3-nitrilopropionamide (DBNPA) were found to be effective at concentration lower than isothiazolone in both standardized Minimum Inhibitory Concentration (MIC) and Minimum Bactericidal Concentration (MBC) tests. Crystal violet staining technique demonstrated that biofilm formation of P. putida HB45 and the mixed culture could be controlled by modest dosage of DBNPA and QAC; however, they could be barely eliminated due to high MBC to MIC ratios. In simulated papermaking processing water, glucose was shown to increase the average biofilm formation rates during stationary phase for both P. putida HB45 and the mixed culture under the presence of biocides. Complexity and population diversity of biofilm of the paper machine slime was observed by in-situ cryo-scanning electron microscopy. Confocal laser scanning microscopy (CSLM) was employed to show qualitative and partial quantitative biofilm formation under various circumstances. The results of this study could assist improving strategy for controlling biofilm formation in papermaking processes.     

Plasmalemma fine structure in isolated tobacco mesophyll protoplasts

Summary Tobacco mesophyll protoplasts have been examined by electron microscopy during isolation procedures and after 24 hours culture in a medium known to support cell wall regeneration. During isolation the plasmalemma shows little structural differentiation apart from the formation of small vacuoles in the cytoplasm. After 24 hours of culture, several types of activity are seen at the plasmalemma surface. Microtubules, profiles of endoplasmic reticulum, electron dense granules and coated vesicles are associated with the inner surface of the membrane. External to the plasmalemma fibrillar structures occur, both as extensive networks and as individual fibrils apparently associated with the membrane itself. Techniques and criteria for electron microscopy are presented, and the results discussed in terms of plasmalemma function and the regeneration of the cell wall.     

Early development of parasympathetic nerves in the mouse submandibular gland.

The early development of the parasympathetic nerves of the mouse submandibular gland is described, both in vivo and in culture. Axon outgrowth has been visualized by electron microscopy, supravital staining with methylene blue, and histochemical localization of acetylcholinesterase activity. Axon outgrowth from the submandibular ganglion parallels in time and in space the morphogenesis of the epithelium of the salivary gland. The average rate of axon elongation during the first 2 days of culture is about 500 μm/day. The precision of pattern formation during that period and the high rate of growth indicate that axon outgrowth is not initially random but that its orientation is determined immediately during the process of outgrowth.     

Cell death and lumen formation in spheroids of MCF‐7 cells

3D (three‐dimensional) cell culture permits a more integrated analysis of the relationship between cells, inserting them into a structure more closely resembling the cellular microenvironment in vivo. The development of in vitro parameters to approximate in vivo 3D cellular environments makes a less reductionist interpretation of cell biology possible. For breast cells, in vitro 3D culture has proven to be an important tool for the analysis of luminal morphogenesis. A greater understanding of this process is necessary because alterations in the lumen arrangement are associated with carcinogenesis. Following lumen formation in 3D cell culture using laser scanning confocal microscopy, we observed alterations in the arrangement of cytoskeletal components (F‐actin and microtubules) and increasing levels of cell death associated with lumen formation. The formation of a polarized monolayer facing the lumen was characterized through 3D reconstructions and the use of TEM (transmission electron microscopy), and this process was found to occur through the gradual clearing of cells from the medullary region of the spheroids. This process was associated with different types of cell death, such as apoptosis, autophagy and entosis. The present study showed that changes in the extracellular matrix associated with long periods of time in 3D cell culture lead to the formation of a lumen in MCF‐7 cell spheroids and that features of differentiation such as lumen and budding formation occur after long periods in 3D culture, even in the absence of exogenous extracellular compounds.     

Morphological development of sclerotia by <Emphasis Type="Italic">Sclerotinia sclerotiorum</Emphasis>: a view from light and scanning electron microscopy

Sclerotinia sclerotiorum is a worldwide pathogen with a broad host spectrum pathogenic to around 400 plant species. Sclerotia formed by S. sclerotiorum serve as resting structures that secure fungal survival in soil for prolonged periods in the absence of a host plant or may help to overcoming periods of unsuitable growth conditions. In the present study, the morphological development of sclerotia was examined by light and scanning electron microscopy of fungal microcultures. Observations from microscopy indicated that, during the first 4 days of culture, the sclerotial primordial originate by dichotomous branching of apical hyphae and from the 5th day mycelial clusters were also observed, indicating the initiation stage of sclerotia formation. From the 6th to the 8th day, sclerotia turned from white to dark color, and water drops (exudates) were observed on their surface. The process of sclerotia formation ended at the 9th day when they were easy to detach from the culture medium and had a black coloration. All the morphological processes involved in the formation of sclerotia by S. sclerotiorum were observed with both light and scanning electron microscopy.     

Fine structure of human malaria in vitro.

The erythrocytic cycle of the human malaria parasite, Plasmodium, falciparum, was examined by electron microscopy. Three strains of parasites maintained in continuous culture in human erythrocytes were compared with in vivo infections in Aotus monkeys. The ultrastructure of P. falciparum is not altered by continuous cultivation in vitro. Mitochondria contain DNA-like filaments and some cristae at all stages of the erythrocytic life cycle. The Golgi apparatus is prominent at the schizont stage and may be involved in the formation of rhoptries. In culture, knob-like protrusions first appear on the surface of trophozoite-infected erythrocytes. The time of appearance of knobs on cells in vitro correlates with the life cycle stage of parasites which are sequestered from the peripheral circulation in vivo. Knob material of older parasites coalesces and forms extensions from the erythrocyte surface. Some of this material is sloughed from the host cell surface. The parasitophorous vacuole membrane breaks down in erythrocytes containing mature merozoites both in vitro and in vivo. Merozoite structure is similar to that of P. knowlesi. The immature gametocytes in culture have no knobs.     

Formation and barrier function of tight junctions in human ovarian surface epithelium

The normal ovarian surface epithelium (OSE) is a primitive epithelium made up by a single layer of mesothelial-type epithelial cells. When these cells get trapped in the ovarian stroma, expression of epithelial specific markers, such as E-cadherin, are induced. Most epithelial cells are also characterized by the ability to form tight junctions (TJ). Incomplete TJ have earlier been demonstrated in the OSE by electron microscopy studies. We have investigated expression and localization of the TJ proteins ZO-1, occludin, and claudin-1 in tissue biopsies from normal human ovaries and OSE in culture. The dynamics of TJ formation were studied in human OSE cultured on porous filters in culture inserts by measuring trans epithelial resistance (TER) including Ca(2+) switch experiments. Confluent OSE cells were also analyzed by electron microscopy. The results show that normal human OSE has expression of all three TJ proteins investigated. These proteins, ZO-1, occludin, and claudin-1, were localized to OSE cell borders both in ovarian biopsies and in cultured OSE. There was no difference in this regard between fertile and postmenopausal women. Cells in culture were polarized and presented junctional complexes seen by electron microscopy. In the Ca(2+) switch experiments, removing free Ca(2+) transiently, TER decreased significantly (P < 0.05) in the Ca(2+)-free group compared with nontreated OSE. TER was fully restored after 24 h. N-cadherin but not E-cadherin was expressed in the OSE and localized to the cell borders. We conclude that normal human OSE express and form functional TJ both in vivo and vitro. This report also describes a method to study the influence of ovarian-derived mediators on TJ in cultured OSE.     

Development of novel elongated fiber-structure in protoplast cultures of Betula platyphylia and Larix leptolepis

Summary Novel elongated fiber-structures were repeatedly found both in leaf protoplast culture of two clones of Betula platyphylla and in protoplast culture of embryogenic cells of Larix leptolepis. Suboptimum culture conditions for cell division appeared to lead to fiber formation when using multi-well plate culture with varying medium compositions The suboptimum conditions for cell divisions were brought about by (1) plant growth regulators: auxins and cytokinins; (2) pH: 3.5, 4.5, 5.8; (3) divalent cations: CaCl₂ and MgCl₂; and (4) sugars: sucrose and mannitol. Divalent cations had the most profound effect on fiber formation. Calcium ions were preferred by Betula and magnesium ions were preferred by Larix. Single fiberpurification and micro-staining methods using a micromanipulator were developed. The fibers fluoresced when stained with Calcofluor White and Aniline Blue, which suggested that they were composed of cell wall component(s), including callose (β-1,3-glucan). Electron microscopy showed that fiber bundles of Larix fibers had helical substructures.     

Structural and ultrastructural analysis of Solanum lycopersicoides protoplasts during diploid plant regeneration

Light, fluorescence and electron microscopy were used to analyse the structural properties of protoplasts obtained from established suspension culture of Solanum lycopersicoides Dun, composed of meristematic cell aggregates. Four types of protoplasts were distinguished immediately after isolation: (1) mononuclear; (2) polynuclear, (3) anuclear and (4) homogeneous protoplasts. Only mononuclear protoplasts were capable of complete cell wall regeneration and mitotic division. Other types of protoplasts were eliminated during culture. Three phases were distinguished in the developing protoplast culture: (1) the elimination phase during which protoplasts damaged during isolation underwent complete degradation; (2) a phase of intense division during which both mitotic cell division and amitotic nuclear division took place; and (3) a stabilization phase leading to the formation of suspension culture. The cell suspension culture obtained from protoplasts was capable of regenerating diploid plants.     

The method of mouse embryoid body establishment affects structure and developmental gene expression

To investigate formation of the three primary germ layers in mouse embryoid bodies (EBs), we observed changes in structure and gene expression over a 7-day culture period. We compared these changes using two methods for EB formation: hanging drop (HD) and static suspension culture (SSC). Light microscopy showed that a stratified columnar epithelial layer developed on the surface of EBs formed using the HD method. From Day 3 in culture, ultrastructural changes occurred in the aligned cellular membranes. Condensation of actin filaments was followed by formation of complicated adherent junctions and dilatation of intercellular canaliculi containing well-developed microvilli. These changes were more marked in EBs formed by the HD method than the SSC method. On Day 5 of culture, Brachyury gene expression, a marker for mesoderm formation, was detected only with the HD method. Nestin, an ectoderm marker, and Foxa2, an endoderm marker, were expressed with both methods. These results suggest that in EBs formed with the HD method, actin formation and Brachyury gene expression mark the transition from two to three primary germ layers. Additionally, the HD method promotes more rapid and complete development of mouse EBs than does the SSC method. While the SSC method is simple and easy to use, it needs improvement to form more complete EBs.     

Spreading of normal and transformed fibroblasts in dense cultures

Cell spreading in dense cultures of normal mouse embryo fibroblasts and of the two lines of mouse transformed fibroblasts was examined by electron microscopy. The mean number of cell layers in culture and cell population density per unit area of the substrate were detetmined; the mean area of the cell projection on the substratum was found from these data.Normal fibroblasts formed multilayefed sheet in dense culture. The cells in this sheet were well-spread. These cells formed thin lamellae (lamellar cytoplasm) over the surface of other cells and over the intercellular substance. The mean cell area in dense culture was not smaller than that of the cell spread on the substratum in sparse culture.Dense cultures of two transformed lines (M 22 and L) had differing morphologies: cultures of one line (M 22) were multilayered, those of the other line (L) were monolayered. Decreased spreading and almost complete (M 22) or complete (L) absence of lamellar cytoplasm were characteristic of both transformed lines. The mean area of the cell in dense cultures of both lines was several times smaller than that of their normal progenitors.It is concluded that similar reactions leading to the spreading accompanied by the formation of lamellar cytoplasm can be induced by the contact of fibroblast with various surfaces: that of the substratum in sparse culture, that of other cells and of intercellular structures in dense culture. Deficiency of these reactions characteristic for transformed fibroblasts may be responsible for abnormal morphology of their cultures.     

Calcium regulation of cell-cell contact and differentiation of epidermal cells in culture. An ultrastructural study

Calcium modulation of keratinocyte growth in culture was studied by both transmission (TEM) and scanning electron microscopy (SEM). Under standard culture conditions (1.2-1.8 mM calcium), cells were connected by desmosomes and stratified to 4-6 cell layers. Many aspects of in vitro epidermal maturation were analogous to the in vivo process, with formation of keratohyalin granules, loss of nuclei, formation of cornified envelopes and shedding of cornified cells containing keratin filaments. When the medium calcium concentration was lowered to 0.02-0.1 mM, the pattern of keratinocyte growth was strikingly changed. Cells grew as a monolayer with no desmosomal connections and proliferated rapidly, shedding largely non-cornified cells into the medium. Large bundles of keratin filaments were concentrated in the perinuclear cytoplasm. The elevation of extracellular calcium to 1.2 mM induced low calcium keratinocytes to stratify, keratinize and cornify in a manner analogous to that seen when plated in standard calcium medium. The earliest calcium-induced ultrastructural change was the asymmetric formation of desmosomes between adjacent cells. Desmosomal plaques with associated tonofilaments were observed 5 min after calcium addition; symmetric desmosomes were formed within 1-2 h. This system is presented as a useful model for the study of the regulation of desmosome assembly and disassembly.     

Protein synthesis requirements during resumption of meiosis in the hamster oocyte: early nuclear and microtubule configurations.

The organization of chromatin and cytoplasmic microtubules changes abruptly at M-phase entry in both mitotic and meiotic cell cycles. To determine whether the early nuclear and cytoplasmic events associated with meiotic resumption are dependent on protein synthesis, cumulus-enclosed hamster oocytes were cultured in the presence of 100 micrograms/ml puromycin or cycloheximide for 5 hr. Both control (untreated) and treated oocytes were analyzed by fluorescence microscopy after staining with Hoechst 33258 and tubulin antibodies. Freshly isolated oocytes exhibit prominent nucleoli and diffuse chromatin within the germinal vesicle as well as an interphase network of cytoplasmic microtubules. After 4-4.5 hr in culture, most oocytes were in prometaphase I of meiosis as characterized by a prominent spindle with fully condensed chromosomes and numerous cytoplasmic asters. After 5-5.5 hr in culture, microtubule asters are no longer detected in most cells, and the spindle is the only tubulin-positive structure. Incubation for 5 hr in the presence of inhibitors does not impair germinal vesicle breakdown, chromatin condensation, kinetochore microtubule assembly, or cytoplasmic aster formation in the majority of oocytes examined; however, under these conditions, a population of oocytes retains a germinal vesicle, exhibiting variable degrees of chromatin condensation and cytoplasmic aster formation. Meiotic spindle formation is inhibited in all oocytes. These effects are fully reversible upon culture of treated oocytes in drug-free medium for 5 hr. The data indicate that meiotic spindle assembly is dependent on ongoing protein synthesis in the cumulus-enclosed hamster oocyte; in contrast, chromatin condensation and aster formation are not as sensitive to protein synthesis inhibitors during meiotic resumption.     

Role of pericellular matrix in development of a mechanically functional neocartilage

The role of the chondrocyte pericellular matrix (PCM) was examined in a three-dimensional chondrocyte culture system to determine whether retention of the native pericellular matrix could stimulate collagen and proteoglycan accumulation and also promote the formation of a mechanically functional hyaline-like neocartilage. Porcine chondrocytes and chondrons, consisting of the chondrocyte with its intact pericellular matrix, were maintained in pellet culture for up to 12 weeks. Sulfated glycosaminoclycans and type II collagen were measured biochemically. Immunocytochemistry was used to examine collagen localization as well as cell distribution within the pellets. In addition, the equilibrium compressive moduli of developing pellets were measured to determine whether matrix deposition contributed to the mechanical stiffness of the cartilage constructs. Pellets increased in size and weight over a 6-week period without apparent cell proliferation. Although chondrocytes quickly rebuilt a PCM rich in type VI collagen, chondron pellets accumulated significantly more proteoglycan and type II collagen than did chondrocyte pellets, indicating a greater positive effect of the native PCM. After 5 weeks in chondron pellets, matrix remodeling was evident by microscopy. Cells that had been uniformly distributed throughout the pellets began to cluster between large areas of interterritorial matrix rich in type II collagen. After 12 weeks, clusters were stacked in columns. A rapid increase in compressive strength was observed between 1 and 3 weeks in culture for both chondron and chondrocyte pellets and, by 6 weeks, both had achieved 25% of the equilibrium compressive stiffness of cartilage explants. Retention of the in vivo PCM during chondrocyte isolation promotes the formation of a mechanically functional neocartilage construct, suitable for modeling the responses of articular cartilage to chemical stimuli or mechanical compression.     

Electron tomography reveals the endoplasmic reticulum as a membrane source for autophagosome formation

The origin and source of autophagosomal membranes are long-standing questions. By electron microscopy, we show that the endoplasmic reticulum (ER) associates with early autophagic structures called isolation membranes (IM) or phagophores in mammalian culture cells. Overexpression of a mutant of Atg4B, which causes defects in autophagosome formation, caused accumulation of ER-IM complexes. Electron tomography revealed the ER-IM complex as a subdomain of the ER forming a cradle encircling the IM, and showed that both ER and isolation membranes are interconnected.