Growth of mammalian cells on substrates coated with cellular microexudates. I. Effect on cell growth at low population densities

Mammalian and avian cells cultured on glass or plastic substrates produce microexudates of cellular macromolecules which remain bound to the substrate when the cells are detached. The gross macromolecular composition of microexudates from a range of diploid, heteroploid, and virus-transformed cells was determined with cells labeled with radioisotopes. Significant differences in the amounts of cellular glycoproteins, proteins, and RNA present in microexudates were found between different cell types and between cells of the same type at different stages of growth. Inoculation of cells onto substrates "coated" with microexudates altered their growth behavior. Microexudates from exponentially growing subconfluent homotypic and heterotypic cell populations enhanced the growth of mouse and chick embryo cells seeded at very low densities, but similar microexudates had no effect on the proliferation of cells seeded at higher densities. The enhanced growth of low-density cell populations seeded on microexudates was compared with the growth enhancement produced by feeder cell layers and conditioned medium.     

The nature of substrate-attached materials in human fibroblast cultures: localization of cell and fetal calf serum components.

Human fibroblasts have been used as an in vitro model to examine the morphology and origin of substrate-attached materials. In cultures of subconfluent cells, no ‘tracks’ or ‘pools’ of material could be detected on substrata by anodic oxide interferometry or electron microscopy. However, a continuous layer of densely staining material was present on Falcon plastic tissue culture dishes never exposed to cells or culture medium. Exposure of substrata to culture medium caused the adsorption of fetal calf serum (FCS) components onto the substratum within a few minutes. Although antigenic FCS components remained on the substrata for several days, they were seldom adsorbed to the cells. The hypothesis was formulated that adhesion was mediated by FCS components on the substrata, but not by cellular materials deposited extracellularly. Support for this hypothesis was obtained by studying serum-dependent differences in cell adhesion. Fibroblasts subcultured in the presence of FCS components were usually separated from the substratum by a distance of at least 30 Å. In the absence of FCS components, the cells were more closely adherent, in the range at which the near van der Walls forces were effective. Fibroblasts subcultured in the absence of serum components could be removed readily from the substratum, leaving lsfootprints’ of cell surface material behind. Although this material has been prepared similarly to ‘microexudates’ from other types of cultured cells, its relationship to those microexudates has not been determined.     

Cellular “bauplans”: Evolving unicellular forms by means of Julia sets and Pickover biomorphs

The universe of cellular forms has received scarce attention by mainstream neo-Darwinian views. The possibility that a fundamental trait of biological order may consist upon, or be guided by, developmental processes not completely amenable to natural selection was more akin to previous epochs of biological thought, i.e. the “bauplan” discussion. Thirty years ago, however, Lynn and Tucker studied the biological mechanisms responsible for defining organelles position inside cells. The fact that differentiated structures performing a specific function within the eukaryotic cell (i.e. mitochondrion, vacuole, or chloroplast) were occupying specific positions in the protoplasm was the observational and experimental support of the ‘morphogenetic field’ notion at the cellular level. In the present paper we study the morphogenetic field evolution yielding from an initial population of undifferentiated cells to diversified unicellular organisms as well as specialized eukaryotic cell types. The cells are represented as Julia sets and Pickover biomorphs, simulating the effect of Darwinian natural selection with a simple genetic algorithm. The morphogenetic field “defines” the locations where cells are differentiated or sub-cellular components (or organelles) become organized. It may be realized by different possibilities, one of them by diffusing chemicals along the Turing model. We found that Pickover cells show a higher diversity of size and form than those populations evolved as Julia sets. Another novelty is the way that cellular organelles and cell nucleus fill in the cell, always in dependence on the previous cell definition as Julia set or Pickover biomorph. Our findings support the existence of specific attractors representing the functional and stable form of a differentiated cell—genuine cellular bauplans. The configuration of the morphogenetic field is “attracted” towards one or another attractor depending on the environmental influences as modeled by a particular fitness function. The model promotes the classical discussions of D’Arcy Thompson and the more recent views of Waddington, Goodwin and others that consider organisms as dynamical systems that evolve through a ‘master plan’ of transformations, amenable to natural selection. Intriguingly, the model also connects with current developments on mechanobiology, highlighting the informational–developmental role that cytoskeletons may play.     

Fusion with enucleated fibroblasts corrects “I-cell” defect

Fusions have been carried out between fibroblasts from patients with “I-cell” disease and enucleated human fibroblasts with a single lysosomal enzyme deficiency derived from patients with G_M1-gangliosidosis, Sandhoff disease and mannosidosis. Pure cytoplasts were obtained using cytochalasin B treatment followed by fluorescence activated cell sorting. After fusion with whole “I-cells”, the cybrid populations showed a restoration of deficient lysosomal enzyme activity and also the abnormal electrophoretic pattern characteristic for the residual hexosaminidase activity in “I-cells” was found to be corrected. The results described in this paper indicate that the defective post-translational modification, which is responsible for the multiple lysosomal enzyme deficiency, can be corrected by a factor that is stable for at least three days in enucleated cells. During this period the cytoplasmic factor can act without the need of de novo synthesis but the absence of correction in in vitro experiments shows that cellular integrity is required.     

STRIP-LIKE COVERING REVEALED ON “WALL-LESS”ASTEROMONAS (CHLOROPHYCEAE)1

Asteromonas Artari previously described as a wall-less biflagellated unicell exhibits a strip-like cell covering on some cells. Both tannic acid fixation and freeze-etch reveal the covering of electron opaque strips outside the plasmalemma. Cross striations are apparent in the surface strips. Golgi vesicles contain material presumed to be precursor components of the covering strips. The crystalline pattern of the freeze-etched material is similar to that reported for other, walled volvocalean algae.     

Exosomes: Revisiting their role as “garbage bags”

In recent years, the term “extracellular vesicle” (EV) has been used to define different types of vesicles released by various cells. It includes plasma membrane‐derived vesicles (ectosomes/microvesicles) and endosome‐derived vesicles (exosomes). Although it remains difficult to evaluate the compartment of origin of the two kinds of vesicles once released, it is critical to discriminate these vesicles because their mode of biogenesis is probably directly related to their physiologic function and/or to the physio‐pathologic state of the producing cell. The purpose of this review is to specifically consider exosome secretion and its consequences in terms of a material loss for producing cells, rather than on the effects of exosomes once they are taken up by recipient cells. I especially describe one putative basic function of exosomes, that is, to convey material out of cells for off‐site degradation by recipient cells. As illustrated by some examples, these components could be evacuated from cells for various reasons, for example, to promote “differentiation” or enhance homeostatic responses. This basic function might explain why so many diseases have made use of the exosomal pathway during pathogenesis.     

Collective Cell Behavior in Mechanosensing of Substrate Thickness

Extracellular matrix stiffness has a profound effect on the behavior of many cell types. Adherent cells apply contractile forces to the material on which they adhere and sense the resistance of the material to deformation—its stiffness. This is dependent on both the elastic modulus and the thickness of the material, with the corollary that single cells are able to sense underlying stiff materials through soft hydrogel materials at low (<10 μm) thicknesses. Here, we hypothesized that cohesive colonies of cells exert more force and create more hydrogel deformation than single cells, therefore enabling them to mechanosense more deeply into underlying materials than single cells. To test this, we modulated the thickness of soft (1 kPa) elastic extracellular-matrix-functionalized polyacrylamide hydrogels adhered to glass substrates and allowed colonies of MG63 cells to form on their surfaces. Cell morphology and deformations of fluorescent fiducial-marker-labeled hydrogels were quantified by time-lapse fluorescence microscopy imaging. Single-cell spreading increased with respect to decreasing hydrogel thickness, with data fitting to an exponential model with half-maximal response at a thickness of 3.2 μm. By quantifying cell area within colonies of defined area, we similarly found that colony-cell spreading increased with decreasing hydrogel thickness but with a greater half-maximal response at 54 μm. Depth-sensing was dependent on Rho-associated protein kinase-mediated cellular contractility. Surface hydrogel deformations were significantly greater on thick hydrogels compared to thin hydrogels. In addition, deformations extended greater distances from the periphery of colonies on thick hydrogels compared to thin hydrogels. Our data suggest that by acting collectively, cells mechanosense rigid materials beneath elastic hydrogels at greater depths than individual cells. This raises the possibility that the collective action of cells in colonies or sheets may allow cells to sense structures of differing material properties at comparatively large distances.     

The optimal density of cellular solids in axial tension

For cellular bodies with uniform cell size, wall thickness, and shape, an important question is whether the same volume of material has the same effect when arranged as many small cells or as fewer large cells. To answer this question, for finite element models of periodic structures of Mooney-type material with different structural geometry and subject to large strain deformations, we identify a nonlinear elastic modulus as the ratio between the mean effective stress and the mean effective strain in the solid cell walls, and show that this modulus increases when the thickness of the walls increases, as well as when the number of cells increases while the volume of solid material remains fixed. Since, under the specified conditions, this nonlinear elastic modulus increases also as the corresponding mean stress increases, either the mean modulus or the mean stress can be employed as indicator when the optimum wall thickness or number of cells is sought.     

The synthesis of surface coat materials in normal and transformed cells

The rate of synthesis and thickness of the surface coat material in a range of virus-transformed and chemically-transformed cell lines were measured by ellipsometry. Cell lines transformed by polyoma virus, SV 40 virus, Rous sarcoma virus and murine sarcoma virus had a significantly thicker coat than the normal parent cells. An increase in the thickness of the cell coat was not a consistent feature of the transformed cell state since this change was not detected in cell lines transformed by methylcholanthrene. The rate of synthesis of the surface coat was significantly faster in transformed cells than in normal cells. Coat synthesis in normal and transformed cells was inhibited rapidly by treatment with cycloheximide. Inhibition of cellular RNA synthesis by actinomycin D produced rapid inhibition of coat synthesis in normal and chemically-transformed cell, but in certain virus-transformed cell lines coat synthesis continued for up to h. The significance of these changes in the pattern of coat synthesis in transformed cells in relation to their altered surface properties is discussed.     

FUNCTIONAL ASPECTS OF SECONDARY CAROTENOIDS IN HAEMATOCOCCUS LACUSTRIS (VOLVOCALES). III. ACTION AS A “SUNSHADE”1

We investigated the protection from photoinhibition by different developmental stages of Haematococcus lacustris [Girod] Rostafinski using chlorophyll fluorescence measurements of single cells and suspensions. An overall correlation between higher cellular content of secondary carotenoids and the capacity to withstand excessive irradiation was observed in flagellated cells and aplanospores of H. lacustris. Low-light-reversible spreading of extra-chloroplastic secondary carotenoids occurred in the periphery of the cell during strong irradiation. This process resulted in increased shading of the cup-shaped chloroplast as demonstrated by a decrease in chlorophyll fluorescence. Extrachloroplastic accumulation of secondary carotenoids in H. lacustris can be interpreted as a specific adaptation to habitats that exhibit strong insolation.     

A stable, “near-haploid” mammalian cell line (Dipodomys ordii)

An established SV40-transformed cell line of Dipodomys ordii was cloned for selective loss of chromosomal material. A clone is described which has a modal chromosome number of 50 (in the normal diploid 2n=72), and has about 66% of the DNA content of normal diploid cells. Karyotype analysis shows that, although some chromosome rearrangement has taken place, 23 chromosomes are completely unpaired and 7 chromosomes are partially unpaired. Buoyant density analysis in neutral CsCl and Cs₂SO₄+Ag gradients of the DNA of this clone shows that there has been no selective retention or loss of any of the satellite DNA components present in D. ordii during the elimination of 34% of the genetic material.     

The Fine Structure of Four “Species” of Amoeba*

The fine structure of Amoeba discoides, Amoeba dubia, and Amoeba amazonas was studied and compared with that of Amoeba proteus. The different kinds of amebas showed general similarities but differed in the ultrastructural details of their organelles. With respect to fine structure, A. discoides was indistinguishable from A. proteus, while both A. dubia and A. amazonas had distinctive features. The nuclei of all had a prominent honeycomb-like fibrous lamina, but A. dubia differed from the others in the distribution of nucleoli within the nucleus. The mitochondria of A. amazonas were unusual in having a variable pattern of cristae, some being plate-like and others tubular. Golgi bodies in A. amazonas had a greater proportion of vesicles and a smaller number of cisternae than those of the others, while Golgi bodies in A. dubia had highly flattened cisternae without a lining of filamentous material such as is found in the other types. The plasma membrane of A. dubia also lacked the prominent filamentous cell coat common to A. proteus and other amebas. The relation between the Golgi apparatus and the cell coat and the significance of the degree of development of the cell coat for pinocytosis and other phenomena is considered. The experimental use of these cells, including the formation of hybrids by nuclear transplantation is discussed.     

Purification of “colony-forming” cells from immature rat testis

Follicle stimulating hormone (FSH) enhances colony formation (as a result of reaggregation) by dissociated 10-day-old rat testis cells in primary culture. The purpose of this study was to examine various cytological characteristics of the FSH-responsive cells and develop techniques for their purification. The ability of testis cells to form colonies in response to FSH (5 μg/ml) was tested at various ages and was found to be maximal at 15 days of age. No colony formation occurred at ages greater than 20 days. Using colony formation as an assay for the FSH-responsive cells, techniques were developed for their purification. Colony cells were purified on a continuous bovine serum albumin (BSA) step gradient (1 ml/step). In fractions purified in this manner and subsequently cultured 24 h with FSH (5 μg/ml) 99.4% of attached cells were colony cells. Light and electron microscopy indicated that the colony cells (1) were one cell type; (2) were not germinal cells; (3) ultrastructurally resembled in situ Sertoli cell of the immature rat testis; and (4) contained a nucleolus with satellite karyosomes, structures which are characteristic of rat Sertoli cells. The mitotic index of the purified cells was 0.014% following 24 h in 10⁻⁵ M colchicine. Based on these data, it was concluded that the FSH responsive cells in culture are Sertoli cells.     

A new sensor,the “filtration probe,” for quantitative characterization of the penicillin fermentation. I. Mycelial morphology and culture activity

In this article the filtration resistance of fungal (Penicillium) mycelia is shown to be quantitatively related to the morphology of the cells. On this basis, it was possible to determine the intracellular volume by simple filtration measurements. Since the dry weight of the cells can also be measured, a morphological variable-the “hyphae density” (dry weight hyphae/volume hyphae)-can be quantified. This variable typically is measured to have values in the range of 0.35–0.20 g/cm³; the lower values represent the final stages of the fermentation. It can be shown that this loss of cell material during fermentation is limited to cytoplasmic components, and that most (70%) of the components which disappear are proteins. Concurrent with and linearly related to this loss of proteins, the culture activity in terms of both cell maintenance energy (respiration activity) and penicillin synthesis also decreased. The hyphae density measured by filtration is therefore a direct measure of the metabolic potential of the organism.     

Autophagy and ionizing radiation in tumors: The “survive or not survive” dilemma

Autophagy is a so‐called “self‐eating” system responsible for degrading long‐lived proteins and cytoplasmic organelles, whose products are recycled to maintain cellular homeostasis. This ability makes autophagy a good candidate for a survival mechanism in response to several stresses, including the tumor cell transformation. In particular, recent studies suggested that autophagy functions as a pro‐death mechanism within different tumor contexts. It is, however, widely reported that autophagy represents both a survival mechanism or contributes directly to cell death fate. This interplay of the autophagy functions has been observed in many types of cancers and, in some cases, autophagy has been demonstrated to both promote and inhibit antitumor drug resistance. From a therapeutical point of view, the effects of the modulation of the tumor cell autophagic status, in response to ionizing radiations, are presently of particular relevance in oncology. Accordingly, this review also provides a perspective view on future works for exploring the modulation of autophagic indices in tumor cells as a novel molecular‐based adjuvant strategy, in order to improve radiotherapy and chemotherapy effects in cancer patients. J. Cell. Physiol. 228: 1–8, 2013. © 2012 Wiley Periodicals, Inc.     

Ultrastructure analysis of cadmium-tolerant and -sensitive cell lines of cucumber (<Emphasis Type="Italic">Cucumis sativus</Emphasis> L.)

Previously, a stable cell suspension culture of cucumber tolerant to cadmium (Cd) was established (Gzyl and Gwóźdź, Plant Cell Tissue Organ Cult 80:59–67, 2005). In this study, ultrastructures of Cd-tolerant and -sensitive cells were analyzed by transmission electron microscopy (TEM). Ultrastructural differences between cell lines exposed to 100 μM CdCl₂ were observed both at cellular and organelle levels. Tolerant cells exposed to Cd exhibited well-preserved cellular structures in comparison with sensitive cells. Increased numbers of osmiophilic globules in the cytoplasm and nucleolus-associated bodies as well as electron dense material in vacuoles were observed in cadmium tolerant cells. In contrast, ultrastructure of sensitive cells following exposure to Cd exhibited distinct disturbances including vacuolation, disintegration of cytoplasm, and structural changes in both mitochondria and endoplasmic reticulum. TEM observations confirmed the adaptation of tolerant cells to Cd.     

Creating a completely “cell‐free” system for protein synthesis

Cell‐free protein synthesis is a promising tool to take biotechnology outside of the cell. A cell‐free approach provides distinct advantages over in vivo systems including open access to the reaction environment and direct control over all chemical components for facile optimization and synthetic biology integration. Promising applications of cell‐free systems include portable diagnostics, biotherapeutics expression, rational protein engineering, and biocatalyst production. The highest yielding and most economical cell‐free systems use an extract composed of the soluble component of lysed Escherichia coli. Although E. coli lysis can be highly efficient (>99.999%), one persistent challenge is that the extract remains contaminated with up to millions of cells per mL. In this work, we examine the potential of multiple decontamination strategies to further reduce or eliminate bacteria in cell‐free systems. Two strategies, sterile filtration and lyophilization, effectively eliminate contaminating cells while maintaining the systems’ protein synthesis capabilities. Lyophilization provides the additional benefit of long‐term stability at storage above freezing. Technologies for personalized, portable medicine and diagnostics can be expanded based on these foundational sterilized and completely “cell‐free” systems. © 2015 American Institute of Chemical Engineers Biotechnol. Prog., 31:1716–1719, 2015     

Authigenic anatase within 1 billion‐year‐old cells

The siliciclastic ~1 Ga‐old strata of the Torridon Group, Scotland, contain some of the most exquisitely preserved three‐dimensional organic‐walled microfossils (OWMs) of the Precambrian. A very diverse microfossil assemblage is hosted in a dominantly phosphatic and clay mineral matrix, within the Diabaig and the Cailleach Head (CH) Formations. In this study, we report on several microfossil taxa within the CH Formation (Leiosphaeridia minutissima, Leiosphaeridia crassa, Synsphaeridium spp. and Myxococcoides spp.) that include populations of cells containing an optically transparent and highly refringent mineral, here identified using electron microscopy as anatase (TiO₂). Most anatase crystals occur entirely within individual cells, surrounded by unbroken carbonaceous walls. Rarely, an anatase crystal may protrude outside a cell, interpreted to correspond to zones where the cell wall had broken down prior to anatase precipitation. Where an anatase crystal entombs an organic intracellular inclusion (ICI), the ICI is large and well preserved. These combined observations indicate that the intracellular anatase is an authigenic sedimentary phase, making this the first report of in situ precipitated anatase intimately associated with microfossils. The ability of anatase to preserve relatively large volumes of intracellular and cell wall organic material in these cells suggests that the crystallisation of anatase entombed cellular contents particularly quickly, soon after the death of the cell. This is consistent with the strong affinity of Ti for organic material, the low solubility of TiO₂, and reports of Ti occurring in living organisms. With the data currently available, we propose a mineralisation pathway for anatase involving Ti complexation with organic ligands within specific cells, leading to localised post‐mortem anatase nucleation inside these cells as the complexes broke down. Further overgrowth of the anatase crystals was likely fuelled by very early diagenetic mobilisation of Ti that had been bound to more labile organic material nearby in the sediments.