Ontogeny of B lymphocyte function. XV. A role for thymus cells in the maturation of the capacity of a subpopulation of B cells to re-express surface immunoglobulin after treatment with anti-immunoglobulin

The maturation of the C57BL/6 B cell population to be able to re-express surface immunoglobulin (sIg) after its removal by treatment with rabbit antimouse Ig (RAMIg) was studied in a cell transfer system. It was found that thymus cells were required for the maturation of a subset of the B cell population to be able to re-express sIg. The B cell population of irradiated, thymectomized mice reconstituted with spleen cells from donors under 2 wk of age remained deficient in their ability to re-express sIg even after 4 wk residence in the cell transfer recipient. In contrast, if adult thymus cells were transferred together with the immature B cells, the B cell population matured to be able to re-express sIg after treatment with RAMIg. Approximately one-third of the B cell population appears to require thymus cells for this maturation. The maturation of the thymus cell population to be capable of mediating this maturation of the B cell population occurs in two steps: between 2 and 3 and between 3 and 4 wk of age. This timing corresponds to the age at which the B cell population of C57BL/6 mice normally acquires the capacity to re-express sIg, which we have previously shown to also occur in two steps. Thymus cells from 3-wk-old donors can mediate the first step in B cell maturation to be able to re-express sIg, but cannot mediate the second step in this maturation of the B cell population. Thymus cells from 4-wk-old donors can mediate both steps in the maturation of the B cell population. The results suggest that thymus cells are involved in regulating some aspects of B cell differentiation.     

Heteromorphism of the corynebacteria. III. D- (dark) and C- (clear) cell types and multiseptate specimens]

A population of Corynebacterium diphtheriae may consist of cells with accented (osmiophilic) cytoplasm (cells of the "dark" type, or D type) and cells with cytoplasm having no pronounced osmiophilic properties (cells of the "clear" type, or C type). The divergence of the population into cells of the D and C types occurs at the stage of cell division, the original mother cell being able to divide into 2 or more individual cells belonging to different types (elongated multiseptate cells). At the same time no morphological disturbances in septation may be observed. The ability of each type of cells for division into the corresponding individual daughter cells indicates their being biologically valid. The mixed (D--C) population of Corynebacterium diphtheriae is considered to be a sign of the dissociation of bacterial culture.     

Cell motility measurements with an automated microscope system

The motility of 3T3 cells has been studied using a newly developed automated microscope system which is capable of recognizing live unstained cells growing in tissue culture. A large number of individual cells can be rapidly identified and characterized and their precise positions recorded. All cells can be revisited automatically every few minutes, and the new cell positions can be determined. Quantitative data from up to 1 000 cells can then be obtained, and cell movement parameters like cell speed, distance travelled, direction of movement, etc., can be measured for individual cells and for the whole cell population. In addition, for any number of chosen cells, high-resolution digitized images can be taken for further morphological studies, including acquisition of images of individual cells.     

In-situ microscopy: Online process monitoring of mammalian cell cultures

The in-situ microscope is a system developed to acquire images of mammalian cells directly inside a bioreactor (in-situ) duringa fermentation process. It requires only minimal operator intervention and it is well suited for either batch or long-termperfusion fermentation runs. The system fits into a 25 mm standard port and has a retractable housing, similar to the industry standard InTrac. Therefore, it can be cleaned and serviced without interruption of the process or risking contamination. A sampling zone inside the bioreactor encloses adefined volume of culture and an image sequence is taken. The height of the sampling zone is set by the control program and canbe adjusted during the cultivation to accommodate a wide range of change in cell density. The system has an infinity correctedoptical train and uses a progressive scan CCD camera to acquirehigh quality images. Process relevant information like cell density is extracted fromthe images by digital image processing software, currently in development for mammalian cells (CHO, BHK). The first version ofthe software will be able to estimate the cell density, cellsize distribution and to give information of the degree of aggregation (single and double cells, cell clusters).     

Intervertebral disc cells as competent phagocytes in vitro: implications for cell death in disc degeneration

Introduction

Apoptosis has been reported to occur in the intervertebral disc. Elsewhere in the body, apoptotic cells are cleared from the system via phagocytosis by committed phagocytes such as macrophages, reducing the chance of subsequent inflammation. These cells, however, are not normally present in the disc. We investigated whether disc cells themselves can be induced to become phagocytic and so have the ability to ingest and remove apoptotic disc cells, minimising the damage to their environment.

Method

Bovine nucleus pulposus cells from caudal intervertebral discs were grown in culture and exposed to both latex particles (which are ingested by committed phagocytes) and apoptotic cells. Their response was monitored via microscopy, including both fluorescent and video microscopy, and compared with that seen by cell lines of monocytes/macrophages (THP-1 and J774 cells), considered to be committed phagocytes, in addition to a nonmacrophage cell line (L929 fibroblasts). Immunostaining for the monocyte/macrophage marker, CD68, was also carried out.

Results

Disc cells were able to ingest latex beads at least as efficiently, if not more so, than phagocytic THP-1 and J774 cells. Disc cells ingested a greater number of beads per cell than the committed phagocytes in a similar time scale. In addition, disc cells were able to ingest apoptotic cells when cocultured in monolayer with a UV-treated population of HeLa cells. Apoptotic disc cells, in turn, were able to stimulate phagocytosis by the committed macrophages. CD68 immunostaining was strong for THP-1 cells but negligible for disc cells, even those that had ingested beads.

Conclusion

In this study, we have shown that intervertebral disc cells are capable of behaving as competent phagocytes (that is, ingesting latex beads) and apoptotic cells. In terms of number of particles, they ingest more than the monocyte/macrophage cells, possibly due to their greater size. The fact that disc cells clearly can undergo phagocytosis has implications for the intervertebral disc in vivo. Here, where cell death is reported to be common yet there is normally no easy access to a macrophage population, the endogenous disc cells may be encouraged to undergo phagocytosis (for example, of neighbouring cells within cell clusters).     

“Non-Toxic” Cyclic Peptides Induce Lysis of Cyanobacteria—An Effective Cell Population Density Control Mechanism in Cyanobacterial Blooms

The presence of planktopeptin BL1125, anabaenopeptin B and anabaenopeptin F, two types of "non-toxic" cyclic peptide produced in bloom forming cyanobacteria, can provoke lysis of different non-axenic Microcystis aeruginosa cell lines via the induction of virus-like particles. The resulting particles are also able to infect the axenic M. aeruginosa cell line without lytic effects. Nevertheless, the presence of "non-toxic" cyclic peptides of cyanobacterial origin can induce lysis of these previously infected cells. This effect implies that a possible role of these peptides in the natural environment is the control of cyanobacterial population density. Lysogenic cyanobacteria can consequently act as hot-spots that, in the presence of cyanobacterial cyclic peptides, release numerous infectious particles. The process can be self-augmented with the simultaneous release of additional cyclic peptides from the producing lysogens, starting a forest fire effect that ends in collapse of cyanobacterial blooms.     

The karyotypic structure of cell populations in vitro as an integral system

This review describes regularities of karyotypic variability maintaining karyotypic stabilization of continuous cell lines. Statistical analysis of individual karyotypes of "marker" and "markerless" cell lines show that survival of cell population in vitro is maintained by a certain ratio of cells with different structural variants of karyotype (SVK). Characteristic feature of karyotypic variability in the "markerless" cell lines during long-term cultivation under various conditions is dicentric formation due to telomeric associations. These dicentrics seem to form genetical structures providing adaptation to conditions in vitro of the cell population as an autonomous system. Correlations between the numerical variability reflecting in SVK, and structural variability (dicentric formation) are manifestations of an integral cell-populational function. Experimental data allow to suggest that integrity of the karyotypic structure of cell populations is maintained not only by selection of random variations, but also by programmed (adaptive) changes of karyotype. As a whole, in the cell population the state is realized that can be called karyotypic homeostasis; the observed phenomena characterize processes maintaining such homeostasis.     

Altered biochemical properties of mitochondria in mouse mammary epithelial cells during primary culture.

A liquid culture system is described whereby proliferation of haemopoietic stem cells (CFU-S), production of granulocyte precursor cells (CFU-C), and extensive granulopoiesis can be maintained in vetro for several months. Such cultures consist of adherent and non-adherent populations of cells. The adherent population contains phagocytic mononuclear cells, "epithelial" cells, and "giant fat" cells. The latter appear to be particularly important for stem cell maintenance and furthermore there is a strong tendency for maturing granulocytes to selectively cluster in and around areas of "giant fat" cell aggregations. By "feeding" the cultures at weekly intervals, between 10 to 15 "population doublings" of functionally normal CFU-S regularly occurs. Increased "population doublings" may be obtained by feeding twice weekly. The cultures show initially extensive granulopoiesis followed, in a majority of cases, by an accumulation of blast cells. Eventually both blast cells and granulocytes decline and the cultures contain predominantly phagocytic mononuclear cells. Culturing at 33 degrees C leads to the development of a more profuse growth of adherent cells and these cultures show better maintenance of stem cells and increased cell density. When tested for colony stimulating activity (CSA) the cultures were uniformly negative. Addition of exogenous CSA caused a rapid decline in stem cells, reduced granulopoiesis and an accumulation of phagocytic mononuclear cells.     

Natural killer cells: detectors of stress

Natural killer (NK) cells are a key component of the innate immune system, as they are able to detect microbe-infected cells, tumors as well as allogeneic cells, without specific sensitization. NK cell effector functions (cytotoxicity, cytokine secretion) are regulated by a wide array of inhibitory and activating receptors. MHC class I molecules are the ligands of most inhibitory receptors, while activating receptors recognize either pathogen-encoded molecules, or self-proteins whose expression is up-regulated upon microbial infection or tumor development. Upon integration of these negative and positive signals, Natural Killer cells can discriminate between healthy "self" (tolerance) and autologous cells undergoing different types of cellular stress or allogeneic cells (immunosurveillance). The knowledge of the different mechanisms of target cell recognition is thus crucial to dissect NK cell involvement in homeostatic and disease conditions as well as to develop novel alternative therapeutic approaches based on NK cell manipulation.     

Population dynamics of human activated natural killer cells in culture

The growth kinetics and population dynamics of recombinent interleukin-2 (rlL-2) stimulated human natural killer (NK) cell-enriched populations were studied in vitro. The NK-enriched populations was obtained from normal peripheral blood mononuclear cells (PBMNC) by immunomagnetic bead depletion of CD3(+) and CD5(+) T cells. The growth kinetics of NK cells, T cells, monocytes, and total cells are shown. In the absence of PBMNC accessory cells, the NK-enriched population showed limited expansion. In the presence of PBMNC accessory cells, the NK-enriched population expanded threefold more than in the absence of accessory cells due to increased NK cell growth rate and increased duration of exponential growth. Using a Transwell system, which separates two cell population by a polycarbonate membrane, the accessory cells were shown to act on the NK-enriched population via a diffusible factor. Accessory cell conditioned media was able to replace the accessory cell population to stimulate NK cell expansion. A monocyte-enriched population prepared by sheep red blood cell rosetting of T cells was extensively phenotyped and compared with the NK-enriched populations. Although the final cultured cells were phenotypically homogeneous for CD56(+)/CD3(-) NK cells, the initial NK precusor populations appear to be different. Namely, the NK cell precursors in the monocyte-enriched population were predominantly CD56(+)/CD2(-). Kinetic equations were formulated for this culture system and the effects of major culture variables are investigated.     

Electron Cryotomography of Bacterial Cells

While much is already known about the basic metabolism of bacterial cells, many fundamental questions are still surprisingly unanswered, including for instance how they generate and maintain specific cell shapes, establish polarity, segregate their genomes, and divide. In order to understand these phenomena, imaging technologies are needed that bridge the resolution gap between fluorescence light microscopy and higher-resolution methods such as X-ray crystallography and NMR spectroscopy.Electron cryotomography (ECT) is an emerging technology that does just this, allowing the ultrastructure of cells to be visualized in a near-native state, in three dimensions (3D), with "macromolecular" resolution (~4nm).^{1, 2} In ECT, cells are imaged in a vitreous, "frozen-hydrated" state in a cryo transmission electron microscope (cryoTEM) at low temperature (< -180°C). For slender cells (up to ~500 nm in thickness³), intact cells are plunge-frozen within media across EM grids in cryogens such as ethane or ethane/propane mixtures. Thicker cells and biofilms can also be imaged in a vitreous state by first "high-pressure freezing" and then, "cryo-sectioning" them. A series of two-dimensional projection images are then collected through the sample as it is incrementally tilted along one or two axes. A three-dimensional reconstruction, or "tomogram" can then be calculated from the images. While ECT requires expensive instrumentation, in recent years, it has been used in a few labs to reveal the structures of various external appendages, the structures of different cell envelopes, the positions and structures of cytoskeletal filaments, and the locations and architectures of large macromolecular assemblies such as flagellar motors, internal compartments and chemoreceptor arrays.^{1, 2}In this video article we illustrate how to image cells with ECT, including the processes of sample preparation, data collection, tomogram reconstruction, and interpretation of the results through segmentation and in some cases correlation with light microscopy.     

New technologies for automated cell counting based on optical image analysis `The Cellscreen'

A prototype of a newly developed apparatus for measuring cell growth characteristics of suspension cells in micro titre plates over a period of time was examined. Fully automated non-invasive cell counts in small volume cultivation vessels, e.g. 96 well plates, were performed with the Cellscreen system by Innovatis AG, Germany. The system automatically generates microscopic images of suspension cells which had sedimented on the base of the well plate. The total cell number and cell geometry was analysed without staining or sampling using the Cedex image recognition technology. Thus, time course studies of cell growth with the identical culture became possible. Basic parameters like the measurement range, the minimum number of images which were required for statistically reliable results, as well as the influence of the measurement itself and the effect of evaporation in 96 well plates on cell proliferation were determined. A comparison with standard methods including the influence of the cultured volume per well (25 l to 200 l) on cell growth was performed. Furthermore, the toxic substances ammonia, lactate and butyrate were used to show that the Cellscreen system is able to detect even the slightest changes in the specific growth rate.     

Effect of retinoic acid on the differentiation and growth of murine mastocyte precursors

In cultures of normal mouse hematopoietic cells containing Interleukin-3 develop cells with many features of mast cells. These cells seem heterogeneous with respect to morphological and biochemical examination. Nevertheless, most of the cells show many granules and a low ability to self-renew. In the present report we describe the development of a blastic cell population, termed mastoblasts, when normal mouse hematopoietic cells are exposed continuously to retinoic acid (RA: 10(-6) to 10(-5) M/l). Using H*3-thymidine incorporation, cell cycle measurement and protein content by flow cytometry, transmission and scanning electron microscopy, we show that these cells seem to be of mast cell lineage but with a high self-renewing capability. So, RA is able to inhibit mast cell differentiation and to provide us a "mastoblastic" population which could be used as a model to study mast cell differentiation.     

Live Cell Imaging of Primary Rat Neonatal Cardiomyocytes Following Adenoviral and Lentiviral Transduction Using Confocal Spinning Disk Microscopy

Primary rat neonatal cardiomyocytes are useful in basic in vitro cardiovascular research because they can be easily isolated in large numbers in a single procedure. Due to advances in microscope technology it is relatively easy to capture live cell images for the purpose of investigating cellular events in real time with minimal concern regarding phototoxicity to the cells. This protocol describes how to take live cell timelapse images of primary rat neonatal cardiomyocytes using a confocal spinning disk microscope following lentiviral and adenoviral transduction to modulate properties of the cell. The application of two different types of viruses makes it easier to achieve an appropriate transduction rate and expression levels for two different genes. Well focused live cell images can be obtained using the microscope’s autofocus system, which maintains stable focus for long time periods. Applying this method, the functions of exogenously engineered proteins expressed in cultured primary cells can be analyzed. Additionally, this system can be used to examine the functions of genes through the use of siRNAs as well as of chemical modulators.     

Measurement of monomer-oligomer distributions via fluorescence moment image analysis

We present higher-order moment analysis of fluorescence intensity fluctuations from individual laser scanning microscopy images applied to study monomer-oligomer distributions. We demonstrate that the number densities and brightness ratios of a mixed population of monomers and oligomers can be determined by analyzing higher-order moments of the fluorescence intensity fluctuations from individual images for specific ranges of densities and particle brightness ratios. Computer simulations and experiments with fluorescent microspheres and cells were performed to illustrate the detection limits and accuracy of this statistical approach. The simulation results show that the concentration of the dimer or oligomer population should be less than or equal to the monomeric concentration for the method to provide accurate results, and that the upper density detection limit of the population of monomers is one order-of-magnitude higher than the concentration of the oligomers. We implemented this technique to resolve two populations of fluorescent microspheres with different brightness ratios and we also applied the moment-analysis method to examine the distribution of aggregation states of PDGF-beta receptors in human fibroblast cells. The method was able to resolve a tetrameric population of the PDGF-beta receptors relative to the background distribution of nonspecifically bound fluorophore.     

Soluble suppressor factor produced by pokeweek mitogen-stimulated human peripheral blood leukocytes

Human peripheral blood leukocytes were exposed to either PWM or Con A mitogens. Cells activated by both these mitogens were able to depress proliferation in an MLC, and to inhibit the generation of spontaneous killer cell (SK) and induced T-cell cytotoxic activity. PWM-activated cells incubated in media for 48 hr were able to elaborate a soluble factor in vitro. This factor suppressed cytotoxicity, and was active only when present at the initiation of MLC cultures. In contrast, cells exposed to Con A were able to suppress immune responsiveness, but this population did not release a soluble factor which could inhibit cytotoxicity. PWM induction appears to be dependent on phagocytic cells, while Con A activation is less dependent on this adherent population. An enriched adherent cell population, stimulated with PWM, was able to suppress cytotoxicity. Thus, the PWM-stimulated system of suppression is mediated through a soluble factor and is dependent on adherent cells.     

Luminance,Colour, Viewpoint and Border Enhanced Disparity Energy Model

The visual cortex is able to extract disparity information through the use of binocular cells. This process is reflected by the Disparity Energy Model, which describes the role and functioning of simple and complex binocular neuron populations, and how they are able to extract disparity. This model uses explicit cell parameters to mathematically determine preferred cell disparities, like spatial frequencies, orientations, binocular phases and receptive field positions. However, the brain cannot access such explicit cell parameters; it must rely on cell responses. In this article, we implemented a trained binocular neuronal population, which encodes disparity information implicitly. This allows the population to learn how to decode disparities, in a similar way to how our visual system could have developed this ability during evolution. At the same time, responses of monocular simple and complex cells can also encode line and edge information, which is useful for refining disparities at object borders. The brain should then be able, starting from a low-level disparity draft, to integrate all information, including colour and viewpoint perspective, in order to propagate better estimates to higher cortical areas.     

Neural stem cell separation from the embryonic avian olfactory epithelium by sedimentation field-flow fractionation

The aim of the present study was to isolate neural stem cells from a complex tissue: the avian olfactory epithelium; by using sedimentation field flow fractionation (SdFFF). By using "Hyperlayer" elution mode, fraction collection and cell characterization methods, results shows that SdFFF could be a useful cell sorter to isolate an enriched, viable and sterile immature neural cell fraction from which the reconstitution of a complete epithelium was possible. In culture, SdFFF eluted cells first led to a "pseudoplacodal" epithelioid cell type from which derived "floating cells". These cells were then able to generate neurosphere-like structures which were composed of cell having many features of immature cells: undifferentiated, self-renewable and multipotentiality. Such a population might be used as a model to improve our understanding of the mechanisms of olfactory neoneurogenesis.