Application of real-time confocal microscopy for observation of living cells in tissue specimens.

Measurement of intracellular Ca2+ concentration ([Ca2+]i) has been a fundamental technique in cell biology. However, most investigations have used cultured or isolated cells as an experimental model, and consequently can provide only limited insight into the mechanisms that operate in tissue in situ. Useful information may be obtained by studying intact tissue specimens. High-speed confocal microscopes that can acquire digital images at video rate have recently been developed. These confocal microscopes which can acquire data in real-time enable [Ca2+]i dynamics of individual cells in intact tissue specimens to be observed. The present paper examines the use of fluorescent microscopy and confocal microscopy for [Ca2+]i imaging of living tissue. We analyzed the dynamics of the duodenal gland, lacrimal gland, intestinal smooth muscles, arterioles, myenteric plexus, and dorsal root ganglion. In these specimens, individual cells exhibited different [Ca2+]i dynamics, and the responses to transmitters/modulators were heterogeneous. In conclusion, real-time imaging provides a useful tool for observing dynamic changes in cells in situ, and it may lead to improve understanding tissue physiology.     

The effect of dehydration dynamics on the characteristics of the E. coli cells

It was shown that NMR and IR-spectroscopy may be employed to study the dynamics of cell dehydration on E. coli as an example. It was noted that the withdrawal of the cell binding water causes an increase of the relative protein quantity in beta-turn. Similar dependences on the relative humidity have been obtained both for chemical shift and the changes of the secondary protein structure and the number of viable cells. It was concluded that the processes associated with binding water removal should be considered as one of the main factors, causing the inactivation of the bacterial cells.     

Collective dynamics of cancer cells confined in a confluent monolayer of normal cells

Tumorigenesis often involves specific changes in cell motility and intercellular adhesion. Understanding the collective cancer cell behavior associated with these specific changes could facilitate the detection of malignant characteristics during tumor growth and invasion. In this study, a cellular vertex model is developed to investigate the collective dynamics of a disk-like aggregate of cancer cells confined in a confluent monolayer of normal cells. The effects of intercellular adhesion and cell motility on tumor progression are examined. It is found that the stresses in both the cancer cells and the normal cells increase with tumor growth, resulting in a crowded environment and enhanced cell apoptosis. The intercellular adhesion between cancer cells and normal cells is revealed to promote tumor growth and invasion. The tumor invasion dynamics hinges on the motility of cancer cells. The cancer cells could orchestrate into different collective migration modes, e.g., directional migration and rotational oscillations, dictated by the competition between cell persistence and local coordination. Phase diagrams are established to reveal the competitive mechanisms. This work highlights the role of mechanics in regulating tumor growth and invasion.     

Cytoskeletal dynamics in living plant cells

Microtubules and microfilaments have been imaged in living plant cells and their dynamic changes recorded during division, growth and development. Carboxyfluorescein labeled brain tubulin has been injected into cells that are maintained in an active state in a culture chamber on the microscope stage. Subsequent imaging with the confocal microscope reveals microtubules in the preprophase band, the mitotic apparatus, the phragmoplast, and the cortical array. The structural changes of these microtubules have been observed during transitional stages. In addition, their dynamic features are demonstrated by depolymerization in elevated calcium, low temperature, and in the drug oryzalin, and by repolymerization when returned to normal conditions. Examination of living Tradescantia stamen hair cells, which have been injected with fluorescent phalloidin to label the actin microfilaments, reveals hitherto undisclosed aspects of the preparation of the division site and dynamics of the phragmoplast cytoskeleton. During prophase microfilaments occur throughout the cell cortex, with those in the region of the preprophase band becoming transversely aligned. At nuclear envelope breakdown, these specifically disassemble, leaving a circumferential zone from which microfilaments remain absent throughout division. During cytokinesis microfilaments arise within the phragmoplast, oriented parallel to the microtubules, but excluded from the zone where the MTs overlap and where cell plate vesicles aggregate. The phragmoplast microfilaments, in a manner similar to microtubules, shorten in length, expand in girth, and eventually disassemble when the cell plate is complete.     

Dynamic proteomics in individual human cells uncovers widespread cell-cycle dependence of nuclear proteins

We examined cell cycle-dependent changes in the proteome of human cells by systematically measuring protein dynamics in individual living cells. We used time-lapse microscopy to measure the dynamics of a random subset of 20 nuclear proteins, each tagged with yellow fluorescent protein (YFP) at its endogenous chromosomal location. We synchronized the cells in silico by aligning protein dynamics in each cell between consecutive divisions. We observed widespread (40%) cell-cycle dependence of nuclear protein levels and detected previously unknown cell cycle-dependent localization changes. This approach to dynamic proteomics can aid in discovery and accurate quantification of the extensive regulation of protein concentration and localization in individual living cells.     

How cells process information: quantification of spatiotemporal signaling dynamics

Arguably, one of the foremost distinctions between life and non-living matter is the ability to sense environmental changes and respond appropriately—an ability that is invested in every living cell. Within a single cell, this function is largely carried out by networks of signaling molecules. However, the details of how signaling networks help cells make complicated decisions are still not clear. For instance, how do cells read graded, analog stress signals but convert them into digital live-or-die responses? The answer to such questions may originate from the fact that signaling molecules are not static but dynamic entities, changing in numbers and activity over time and space. In the past two decades, researchers have been able to experimentally monitor signaling dynamics and use mathematical techniques to quantify and abstract general principles of how cells process information. In this review, the authors first introduce and discuss various experimental and computational methodologies that have been used to study signaling dynamics. The authors then discuss the different types of temporal dynamics such as oscillations and bistability that can be exhibited by signaling systems and highlight studies that have investigated such dynamics in physiological settings. Finally, the authors illustrate the role of spatial compartmentalization in regulating cellular responses with examples of second-messenger signaling in cardiac myocytes.     

Lateral feedback from monophasic horizontal cells to cones in carp retina. II. A quantitative model

About half of the monophasic horizontal cells in carp retina receive input from both red- and green-sensitive cones. Since the horizontal cells feed back to cones, the color and feedback pathways result in wavelength- and intensity-dependent changes of the dynamics and of the receptive field amplitude profile of the horizontal cell responses. In this paper we present a quantitative model that describes adequately the color and spatial coding and the dynamics of the responses from monophasic horizontal cells in carp. Lateral feedback plays a distinct role in this model.     

Small GTP-binding proteins in parietal cells: candidate modulators of parietal cell membrane dynamics.

The stimulated fusion of intracellular H/K-ATPase-containing tubulovesicles with a target canalicular membrane surface is central to the process of acid secretion. A super-family of small GTP-binding proteins (smGTPBPs) has been implicated in many aspects of intracellular dynamics and vesicle membrane trafficking. We have investigated the presence of smGTPBPs in isolated rabbit parietal cells. Parietal cells possess a number of smGTPBP species with molecular masses of 18-28 kDa. One 23 kDa smGTPBP has been localized to tubulovesicles and identified immunochemically as rab2. Rab2 redistributes during stimulation in concert with the movement of the H/K-ATPase. The results demonstrate that specific smGTPBPs are associated with the parietal cell secretory apparatus. Small GTP-binding proteins are important candidate regulators of parietal secretory membrane dynamics.     

Quantifying lamella dynamics of cultured cells by SACED, a new computer-assisted motion analysis.

Formation of lamellipodia and the retraction of ruffles are essential activities during motility and migration of eukaryotic cells. We have developed a computer-assisted stroboscopic method for the continuous observation of cell dynamics (stroboscopic analysis of cell dynamics, SACED) that allows one to analyze changes in lamellipodia protrusion and ruffle retraction with high resolution in space and time. To demonstrate the potential of this method we analyzed keratinocytes in culture, unstimulated or stimulated with epidermal growth factor (EGF), which is known to induce cell motility and migration. Keratinocytes stimulated with EGF exhibited a 2.6-fold increase in their migration velocity, which coincided with enhanced ruffle retraction velocity (144%) and increased ruffle frequency (135%) compared to control cells. We also recorded an enhanced frequency of lamellipodia (135%), whereas the velocity of lamellipodia protrusion remained unchanged. These results on ruffle and lamellipodia dynamics in epidermal cells show that SACED is at least equal to established methods in terms of accuracy. SACED is, however, advantageous concerning resolution in time and therefore allows one to analyze the activity of lamellipodia and ruffles in as yet unknown detail. Moreover, SACED offers two opportunities that render this technique superior to established methods: First, several parameters relevant to cell motility can be analyzed simultaneously. Second, a large number of cells can conveniently be examined, which facilitates the compilation of statistically significant data.     

Reorganization of molecular morphology of epitheliocytes and connective-tissue cells in morphogenesis and carcinogenesis

Complete and incomplete transitions of epitheliocytes into cells of mesenchymal type, so-called epithelial-mesenchymal transitions (EMT), take place in many types of normal morphogenesis and in epithelial carcinogenesis. Connective tissue cells (fibroblasts) also undergo considerable morphological changes during normal morphogenesis and carcinogenesis, but their dynamics are less known. It is suggested that EMT and fibroblast dynamics may have some common step that is some united precursor cell type. The program for normal EMT can be activated in the course of multistep progression of epithelial carcinogenesis; this activation can be supported by cell selection as it provides a basis for dissemination of neoplastic cells from original tumor.     

Molecular changes in cell surface membranes resulting from trypsinization of sarcoma 180 tumor cells.

Sarcoma-180 tumor cells in culture or grown as an ascites form in the CD-1 mouse have been subjected to mild trypsinization procedures in order to study morphological and molecular changes resulting from proteolysis. The cells attached to a substratum become rounded within 20 min. and most undergo cell division, but they do not detach from the substratum. Removal of trypsin permits the cells to go back to their original spindle shape over an 8-20 h period. Surface membranes were isolated from trypsinized ascites and cultured cells and subjected to dodecyl sulfate-acrylamide gel electrophoresis. Both cell types showed the same two kinds of changes in electrophoretic patterns. First, there was a loss of glycoproteins from both cell types even though they show different complements of cell surface glycoproteins. Second, there is a loss of high molecular weight polypeptides, which have previously been suggested to play a role in membrane stabilization and cell shape. These results further implicate these polypeptides in the control of cell morphology and offer circumstanital evidence for transmembrane interactions of surface glycoproteins with the high molecular weight polypeptides as a factor in controlling cell morphology.     

Plasticity in the nervous system of adult hydra. II. Conversion of ganglion cells of the body column into epidermal sensory cells of the hypostome

Due to the tissue dynamics of hydra, every neuron is constantly changing its location within the animal. At the same time specific subsets of neurons defined by morphological or immunological criteria maintain their particular spatial distributions, suggesting that neurons switch their phenotype as they change their location. A position-dependent switch in neuropeptide expression has been demonstrated. The possibility that ganglion cells of the body column are converted into epidermal sensory cells of the head was examined using a monoclonal antibody, TS33, whose binding is restricted to a subset of epidermal sensory cells of the hypostome, the apical end of the head. When animals devoid of interstitial cells, which are the nerve cell precursors, were decapitated and allowed to regenerate, they formed TS33+ epidermal sensory cells. As this latter cell type is not found in the body column, and the interstitial cell-free animals contained only epithelial cells and ganglion cells in the part of the ectoderm that formed the head during regeneration, the TS33+ epidermal sensory cells most likely arose from the TS33- ganglion cells. The observation of epidermal sensory cells labeled with both TS33 and TS26, a monoclonal antibody that binds to ganglion cells, in regenerating and normal heads provides further support. The double-labeled cells are probably in transition from a ganglion cell to an epidermal sensory cell. These results provide a second example of position-dependent changes in neuron phenotype, and suggest that the differentiated state of a neuron in hydra is only metastable with regard to phenotype.     

NKT cells in HIV-1 infection

Natural killer T （NKT） cells are a unique T cell population that have important immunoregulatory functions and have been shown to be involved in host immunity against a range of microorganisms. It also emerges that they might play a role in HIV-1 infection, and therefore be selectively depleted during the early stages of infection. Recent studies are reviewed regarding the dynamics of NKT depletion during HIV-1 infection and their recovery under highly active antiretroviral treatment （HAART）. Possible mechanisms for these changes are proposed based on the recent developments in HIV pathogenesis. Further discussions are focused on HIV＇s disruption of NKT activation by downregulating CDld expression on antigen presentation cells （APC）. HIV-1 protein Nefis found to play the major role by interrupting the intracellular trafficking of nascent and recycling CDld molecules.     

Dynamics of the changes of electrophysical properties of <Emphasis Type="Italic">Azospirillum brasilense</Emphasis> Sp7 cells at their binding with wheat germ agglutinin

The electrooptical properties of Azospirillum brasilense Sp7 cell suspensions, have been studied at a specific interaction with wheat germ agglutinin (WGA), using the dependences between the changes of optical densities of cell suspensions at the electric orientation of cells and the orienting field frequencies of 740, 1000, 1450, 2000, and 2800 kHz. It was shown that the electrooptical (EO) properties of cell suspensions changed at the interaction of A. brasilense Sp7 cells with WGA and that the EO signal value changed irrespective of the cultivation conditions. At the same time, the dynamics of the changes of the EO properties of microbial suspensions was different for microbial cells grown under different conditions. It may be evidence of the differences in the cell surface properties of microbial cells, and of the dependence, between bacterial response to lectin and growth conditions. The possibility of using the EO analysis of bacterial suspensions for the study of the high-specific binding of polypeptide molecular signals with the bacterial target cells and for assessment of the dynamics of this process has been demonstrated.     

Alterations in chromatin of cells infected with RNA tumor viruses.

Chromatins were isolated from murine leukemia or sarcoma virus infected lymphocyte-like TB cells and compared by immunological and biochemical methods. Chromatin from virus infected cells did not fix complement as well as uninfected cell chromatin suggesting that conformational changes had occurred in chromatin from virus infected cells. This alteration was detected within 24 hours after infection. Infected cell chromatins, examined by electrophoretic methods after radiolabeling displayed alterations in nonhistone proteins, whereas the histones appeared unaltered. The non-histones were synthesized in greater amounts in infected compared to normal cells, particularly a 60,000 D protein, while the amount of histone did not vary. The above changes should not have been due to cell growth or cycle variations, for the cells had similar growth rates and were harvested from the same stage of cell confluency during exponential growth to ensure uniformity of culture conditions.     

Mechanotransduction in blood cells

Blood cells are subjected to various mechanical forces; including pressure, flow, shear force, gravity, and forces acting against them with varying stiffness (eg. blood vessel wall). Scientists have discovered that these forces have profound effects on cellular growth, differentiation, secretion of cytokines, cell death, and migration. These processes are called mechanotransduction, a conversion of mechanical forces to biochemical signals. In this article the author reviews biophysical forces that affect biological functions of blood cells and their responses in normal physiology and pathophysiology. Although input (forces) and output (cellular responses) have been well studied by utilizing recently developed various force-generating devices, the molecular mechanism of mechanotransudction is still a mystery. This is because reconstructing molecular interaction in the presence of mechanical forces in vitro is highly challenging and until now the molecular dynamics involved in structural changes caused by these forces are largely unknown. Nevertheless, the author has reviewed a few examples of potential structural effects on the molecular mechanism of mechanotransduction.     

Dynamics of surface neurotransmitter receptors and transporters in glial cells: Single molecule insights

The surface dynamics of neurotransmitter receptors and transporters, as well as ion channels, has been well-documented in neurons, revealing complex molecular behaviour and key physiological functions. However, our understanding of the membrane trafficking and dynamics of the signalling molecules located at the plasma membrane of glial cells is still in its infancy. Yet, recent breakthroughs in the field of glial cells have been obtained using combination of superresolution microscopy, single molecule imaging, and electrophysiological recordings. Here, we review our current knowledge on the surface dynamics of neurotransmitter receptors, transporters and ion channels, in glial cells. It has emerged that the brain cell network activity, synaptic activity, and calcium signalling, regulate the surface distribution and dynamics of these molecules. Remarkably, the dynamics of a given neurotransmitter receptor/transporter at the plasma membrane of a glial cell or neuron is unique, revealing the existence of cell-type specific regulatory pathways. Thus, investigating the dynamics of signalling proteins at the surface of glial cells will likely shed new light on our understanding of glial cell physiology and pathology.     

Germ cells in Hydra oligactis males. II. Evidence for a subpopulation of interstitial stem cells whose differentiation is limited to sperm production

Animals containing germline-restricted interstitial cells were obtained by treating males from a clone of Hydra oligactis with hydroxyurea (HU) to lower the interstitial population to 1 or 2 cells per animal. A 3-day HU treatment produced animals whose interstitial cells did not form somatic cells, but did produce sperm. The isolation of these cells in HU-treated animals has lead us to propose that the interstitial cell population may contain subpopulations which possess different growth dynamics and developmental potentials. Through asexual propagation, we have cloned several animals containing only sperm precursor interstitial cells and have examined the growth and differentiation behavior of these cells in offspring propagated over a 2-year period. Evidence has been obtained which demonstrates (1) the extensive self-renewal capacity of the sperm precursor interstitial cells, and (2) the restricted differentiation capacity of these interstitial stem cells. Factors which affect cells entering and traversing the spermatogenic pathway are also presented.     

Observation of living cells using the atomic force microscope.

We used an atomic force microscope (AFM) to image samples immersed in a fluid in order to study the dynamic behavior of the membranes of living cells. AFM images of cultured cells immersed in a buffer were obtained without any preliminary preparation. We observed surface changes and displacements which suggest that the cells were still alive during the measurements. Some membrane details imaged with the AFM have also been observed using a scanning electron microscope and their dynamic behavior has been confirmed by microcinematography. We believe that the AFM will offer new insights into the exploration of dynamic changes affecting cell membranes.     

Lactic dehydrogenase activity in degenerative neoplastic glial cells after actinomycin application in vitro.

Glial tumors of glioblastoma type, cultured in vitro, have been exposed between the 7th and 14th day of growth to actinomycin C and K in a concentration of 5 x 10(-6) M. The developing degenerative changes in the neoplastic cells were observed after 6, 8, 12 and 24 hours after the addition of actinomycin to the culture of the tumor. It has been found, that the developing degenerative changes in the tumor cells are paralleled by a growing activity of the enzyme tested. The degenerative changes were described in the neoplastic cells, beginning from the accumulation of the enzyme activity in small granules of the cell processes up to very high activity of the enzyme in fragments of the breaking down cells. It is suggested that LDH activity is a good marker of cell form degenerative changes.