Anti-phase calcium oscillations in astrocytes via inositol (1, 4, 5)-trisphosphate regeneration.

Observations in cultured mouse astrocytes suggest anti-phase synchronization of cytosolic calcium concentrations in nearest neighbor cells that are coupled through gap junctions. A mathematical model is used to investigate physiologic conditions under which diffusion of the second messenger inositol (1, 4, 5)-trisphosphate (IP(3)) through gap junctions can facilitate synchronized anti-phase Ca(2+) oscillations. Our model predicts anti-phase oscillations in both cytosolic calcium and IP(3) concentrations if (a) the gap junction permeability is within a window of values and (b) IP(3) is regenerated in the astrocytes via, e.g. phospholipase C(delta). This result sheds new light on the current dispute on the mechanism of intercellular calcium signaling. It provides indirect evidence for a partially regenerative mechanism as the model excludes anti-phase synchrony in the absence of IP(3) regeneration.

Growth factors but not gap junctions play a role in injury-induced Ca2+ waves in epithelial cells.

This paper characterizes the early responses of epithelial cells to injury. Ca2+ is an important early messenger that transiently increases in the cytoplasm of cells in response to external stimuli. Its elevation leads to the regulation of signaling pathways responsible for the downstream events important for wound repair, such as cell migration and proliferation. Live cell imaging in combination with confocal laser scanning microscopy of fluo-3 AM loaded cells was performed. We found that mechanical injury in a confluent region of cells creates an elevation in Ca2+ that is immediately initiated at the wound edge and travels as a wave to neighboring cells, with [Ca2+]i returning to background levels within two minutes. Addition of epidermal growth factor (EGF), but not platelet-derived growth factor-BB, resulted in increased [Ca2+]i, and EGF specifically enhanced the amplitude and duration of the injury-induced Ca2+ wave. Propagation of the Ca2+ wave was dependent on intracellular Ca2+ stores, as was demonstrated using both thapsigargin and Ca2+ chelators (EGTA and BAPTA/AM). Injury-induced Ca2+ waves were not mediated via gap junctions, as the gap-junction inhibitors 1-heptanol and 18alpha-glycyrrhetinic acid did not alter wave propagation, nor did the cells recover in photobleaching experiments. Additional studies also demonstrated that the wave could propagate across an acellular region. The propagation of the injury-induced Ca2+ wave occurs via diffusion of an extracellular mediator, most probably via a nucleotide such as ATP or UTP, that is released upon cell damage.

Synchronization of hyperexcitable systems with phase-repulsive coupling.

We study two-dimensional arrays of FitzHugh-Nagumo elements with nearest-neighbor coupling from the viewpoint of synchronization. The elements are diffusively coupled. By varying the diffusion coefficient from positive to negative values, interesting synchronization patterns are observed. The results of the simulations resemble the intracellular oscillation patterns observed in cultured human epileptic astrocytes. Three measures are proposed to determine the degree of synchronization (or coupling) in both the simulated and the experimental system.

Calcium signaling induced by adhesion mediates protein tyrosine phosphorylation and is independent of pHi.

Our goal was to evaluate early signaling events that occur as epithelial cells make initial contact with a substrate and to correlate them with phosphorylation. The corneal epithelium was chosen to study signaling events that occur with adhesion because it represents a simple system in which the tissue adheres to a basal lamina, is avascular, and is bathed by a tear film in which changes in the local environment are hypothesized to alter signaling. To perform these experiments we developed a novel adhesion assay to capture the changes in intracellular Ca(2+) and pH that occur as a cell makes its initial contact with a substrate. The first transient cytosolic Ca(2+) peak was detected only as the cell made contact with the substrate and was demonstrated using fluorimetric assays combined with live cell imaging. We demonstrated that this transient Ca(2+) peak always preceded a cytoplasmic alkalization. When the intracellular environment was modified, the initial response was altered. Pretreatment with 1,2-bis(o-aminophenoxy)ethane-N,N, N'N'-tetraacetic acid (BAPTA), an intracellular chelator, inhibited Ca(2+) mobilization, whereas benzamil altered the duration of the oscillations. Thapsigargin caused an initial Ca(2+) release followed by a long attenuated response. An inositol triphosphate analog induced a large initial response, whereas heparin inhibited Ca(2+) oscillations. Inhibitors of tyrosine phosphorylation did not alter the initial mobilization of cytosolic Ca(2) but clearance of cytosolic Ca(2+) was inhibited. Exposing corneal epithelial cells to BAPTA, benzamil, or thapsigargin also attenuated the phosphorylation of the focal adhesion protein paxillin. However, although heparin inhibited Ca(2+) oscillations, it did not alter phosphorylation of paxillin. These studies demonstrate that the initial contact that a cell makes with a substrate modulates the intracellular environment, and that changes in Ca(2+) mobilization can alter later signaling events such as the phosphorylation of specific adhesion proteins. These findings may have implications for wound repair and development.

Noise-induced spiral waves in astrocyte syncytia show evidence of self-organized criticality.

Long range (a few centimeters), long lived (many seconds), spiral chemical waves of calcium ions (Ca2+) are observed in cultured networks of glial cells for normal concentrations of the neurotransmitter kainate. A new method for quantitatively measuring the spatiotemporal size of the waves is described. This measure results in a power law distribution of wave sizes, meaning that the process that creates the waves has no preferred spatial or temporal (size or lifetime) scale. This power law is one signature of self-organized critical phenomena, a class of behaviors found in many areas of science. The physiological results for glial networks are fully supported by numerical simulations of a simple network of noisy, communicating threshold elements. By contrast, waves observed in astrocytes cultured from human epileptic foci exhibited radically different behavior. The background random activity, or "noise", of the network is controlled by the kainate concentration. The mean rate of wave nucleation is mediated by the network noise. However, the power law distribution is invariant, within our experimental precision, over the range of noise intensities tested. These observations indicate that spatially and temporally coherent Ca2+ waves, mediated by network noise may play and important role in generating correlated neural activity (waves) over long distances and times in the healthy vertebrate central nervous system.

Noise sustained waves in subexcitable media: From chemical waves to brain waves.

We discuss a novel type of spatiotemporal pattern that can be observed in subexcitable media when coupled to a thermal environment. These patterns have been recently observed in several different types of systems: a subexcitable photosensitive Belousov-Zhabotinsky reaction, hippocampal slices of rat brains, and astrocyte syncytium. In this paper, we introduce the basic concepts of subexcitable media, describe recent experimental observations in chemistry and neurophysiology, and put these observation into context with computer simulations. (c) 1998 American Institute of Physics.

Human epileptic astrocytes exhibit increased gap junction coupling.

Fluorescence Recovery After Photobleach (FRAP) was used to quantify astrocyte gap junction coupling from tissues surgically resected from medically intractable epilepsy patients. Mesial temporal lobe cases provided hippocampus, surrounding hyperexcitable parahippocampus and normal cortex for culture. Cortical tumor cases yielded astrocytoma proper, cortex margins with normal EEG activity, and hyperexcitable cortex. Cells isolated from cortex surrounding astrocytomas and the parahippocampus surrounding the hippocampus showed an increase in glutamate-induced Ca2+ oscillations and intercellular Ca2+ waves. Gap-junction coupling was more pronounced in cells isolated from hyperexcitable tissue than from normal tissues as judged by their faster and more complete fluorescence recovery from laser bleach [FRAP]. This data suggests that intractable epilepsy may be associated with alterations in glial gap junction coupling.

Astrocytes exhibit regional specificity in gap-junction coupling.

Astrocytes are coupled to each other via gap-junctions both in vivo and in vitro. Gap-junction coupling is essential to a number of astrocyte functions including the spatial buffering of extracellular K+ and the propagation of Ca2+ waves. Using fluorescence recovery after photo-bleach, we quantitatively assayed and compared the coupling of astrocytes cultured from six different central nervous system (CNS) regions in the rat: spinal cord, cortex, hypothalamus, hippocampus, optic nerve, and cerebellum. The degree of fluorescence recovery (% recovery) and time constant of recovery (tau) served as quantitative indicators of coupling strength. Gap-junction coupling differed markedly between CNS regions. Coupling was weakest in astrocytes derived from spinal cord (43% recovery, tau approximately 400 s) and strongest in astrocytes from optic nerve (91% recovery, tau approximately 226 s) and cerebellum (95% recovery, tau approximately 100 s). As indicated by the degree of recovery, coupling strength among CNS regions could be ranked as follows: spinal cord < cortex < hypothalamus < hippocampus = optic nerve = cerebellum. Gap-junction coupling also differed between CNS regions with respect to its sensitivity to inhibition by the uncoupling agent octanol. Kd values for 50% inhibition by octanol ranged from 188 microM in spinal cord astrocytes to 654 microM in hippocampal astrocytes. Sensitivity of gap-junctions to octanol could be ranked as follows: spinal cord = cortex = hypothalamus > cerebellum > optic nerve > hippocampus. The observed differences in coupling indicate differences in the number of gap-junction connections in astrocytes cultured from the six CNS regions. These differences may reflect the adaptation of astrocytes to varying functional requirements in different CNS regions.

Glutamate-induced calcium signaling in astrocytes.

Astrocytes respond to the excitatory neurotransmitter glutamate with dynamic spatio-temporal changes in intracellular calcium [Ca2+]i. Although they share a common wave-like appearance, the different [Ca2+]i changes--an initial spike, sustained elevation, oscillatory intracellular waves, and regenerative intercellular waves--are actually separate and distinct phenomena. These separate components of the astrocytic Ca2+ response appear to be generated by two different signal transduction pathways. The metabotropic response evokes an initial spatial Ca2+ spike that can propagate rapidly from cell to cell and appears to involve IP3. The metabotropic response can also produce oscillatory intracellular waves of various amplitudes and frequencies that propagate within cells and are sustained only in the presence of external Ca2+. The ionotropic response, however, evokes a sustained elevation in [Ca2+]i associated with receptor-mediated Na+ and Ca2+ influx, depolarization, and voltage-dependent Ca2+ influx. In addition, the ionotropic response can lead to regenerative intercellular waves that propagate smoothly and nondecrementally from cell to cell, possibly involving Na+/Ca2+ exchange. All these astrocytic [Ca2+]i changes tend to appear wave-like, traveling from region to region as a transient rise in [Ca2+]i. Nevertheless, as our understanding of the cellular events that underlie these [Ca2+]i changes grows, it becomes increasingly clear that glutamate-induced Ca2+ signaling is a composite of separate and distinct phenomena, which may be distinguished not based on appearance alone, but rather on their underlying mechanisms.

Selective antimitotic effects of estramustine correlate with its antimicrotubule properties on glioblastoma and astrocytes.

Estramustine is an estradiol-based agent that accumulates in cells containing estramustine binding protein. Previous studies have shown that this binding site is expressed in human glioblastoma cells and that estramustine accumulates in glioma cells, resulting in a concentration-dependent inhibition of proliferation. We have shown that estramustine treatment results in a rapid inhibition of deoxyribonucleic acid synthesis (within 4 h) in human glioblastoma cells associated with an alteration of cell size and shape, consistent with its known antimicrotubule activity. To extend these findings, we performed an immunohistochemical analysis of microtubules with a monoclonal antibody to beta-tubulin, using a colorimetric assay with 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide to measure the antimitotic effects of estramustine on both human glioblastoma and astrocyte cultures. Within 4 hours, estramustine (10 mumol/L) caused a dramatic alteration in the tubulin staining in glioma cells, characterized by a disorganization in microtubules. Cell shape and microtubule staining in astrocytes were relatively preserved. Estramustine had a concentration-dependent cytotoxic effect in tumor cultures, whereas it had no effect on astrocyte viability at any concentration. Differences in the antimitotic effects do not appear to be related to variations in proliferation rates among these different types of cells. These data suggest that although estramustine is a potent inhibitor of proliferation in glioblastoma cells, it has modest antiproliferative effects on astrocytes and its selective activity is closely correlated with its antimicrotubule properties.

Expression of integrin and organization of F-actin in epithelial cells depends on the underlying surface.

PURPOSE: To evaluate the role of ionic interactions in the cell surface expression of integrins and the organization of F-actin. Understanding these interactions will allow the development of surfaces for prosthetic purposes that will promote the normal expression of adhesion proteins. METHODS: Hema (hydroxyethylmethacrylate) hydrogels were used to mimic the charges present on extracellular matrix proteins. The surfaces were modified by the addition of amines (N,N-dimethylaminoethylmethacrylate; NDAM) or carboxyl moieties (methacrylic acid). The effects of ionic interactions on cellular spreading and on the expression of proteins were examined by modification of the stoichiometrically defined amounts of positive and negative charges on the Hemas. Changes in intracellular pH and the distribution and localization of protein were monitored using fluorescent markers, spectrofluorometry, and confocal laser scanning microscopy, respectively. The immunohistochemical studies were confirmed by flow cytometric analysis. RESULTS: The data indicate that although cells adhered to all the surfaces, the number of cells possessing adhesion receptors is significantly greater on surfaces with amine functionalities. Cell seeding and plating efficiency after 2 hours were identical on all surfaces. The intracellular pH of epithelial cells grown on surfaces containing NDAM, a tertiary amine, was higher than that of cells grown on Hemas containing only methacrylic acid. Lamellipodial extensions and an extensive actin network were present on surfaces containing 5% NDAM. The alpha 6 subunit was localized along the lateral cell membranes. The alpha 2 and 3 subunits were present along cell membranes and at lamellipodial extensions. Cells cultured on surfaces containing only methacrylic acid did not spread. Actin filaments were not detected, and alpha 6 was negligible on these surfaces. CONCLUSIONS: This is a novel approach to understanding cell-substrate interactions, and one that allows quantitative evaluation of the response of cells to defined surfaces. The organization of F-actin is altered by the substrates containing only carboxyl moieties. The distribution of integrin subunits is also altered by the substrate. These results indicate that epithelial cell spreading and protein expression may be regulated by ionic interactions.

Confocal imaging of the alpha 6 and beta 4 integrin subunits in the human cornea with aging.

PURPOSE: The purpose of this study was to examine changes in the distribution of integrin subunits, alpha 6 and alpha 4, in the normal human cornea with age. METHODS: Thirty normal corneas were examined and divided into three groups; corneas from children younger than 2 years, corneas from adults 29 to 70 years, and corneas from adults older than 70 years. The corneas were frozen and the sections were cut, double-stained with monoclonal antibodies to the integrin subunits, and visualized with Texas Red or fluorescein using confocal laser scanning microscopy. Computer imaging was conducted to determine differences. RESULTS: The alpha 6 subunit was generally localized along the basal and lateral surfaces of basal epithelial cells and projected into Bowman's membrane. The beta 4 subunit was only present along the basal surface. Overall, the major age-related difference was the loss of continuous alpha 6 and beta 4 subunits along the basal surface of basal epithelial cells. When reconstructed images from corneas of individuals older than 70 years were optically sectioned en face, the alpha 6 subunit appeared discontinuous. If the same optical images were viewed from corneas of younger individuals, the staining was continuous. The number and distribution of hemidesmosomes along the basal lamina did not change with age in the corneas examined. CONCLUSIONS: Using computer imaging associated with confocal laser scanning microscopy, we have demonstrated that there is an age-related change in the localization of the alpha 6 and beta 4 subunits.

Calcium excitability and oscillations in suprachiasmatic nucleus neurons and glia in vitro.

Converging lines of evidence suggest that the hypothalamic suprachiasmatic nucleus (SCN) is the site of the endogenous biological clock controlling mammalian circadian rhythms. To study the calcium responses of the cellular components that make up the clock, computer-controlled digital video and confocal scanning laser microscopy were used with the Ca2+ indicator dye fluo-3 to examine dispersed SCN cells and SCN explants with repeated sampling over time. Ca2+ plays an important second messenger role in a wide variety of cellular mechanisms from gene regulation to electrical activity and neurotransmitter release, and may play a role in clock function and entrainment. SCN neurons and astrocytes showed an intracellular Ca2+ increase in response to glutamate and 5-HT, two major neurotransmitters in afferents to the SCN. Astrocytes showed a marked heterogeneity in their response to the serial perfusion of different transmitters; some responded to both 5-HT and glutamate, some to neither, and others to only one or the other. Under constant conditions, most neurons showed irregular temporal patterns of Ca2+ transients. Expression of regular neuronal oscillations could be blocked by the inhibitory transmitter GABA. Astrocytes, on the other hand, showed very regular rhythms of cytoplasmic Ca2+ concentrations with periods ranging from 7 to 20 sec. This periodic oscillation could be initiated by in vitro application of glutamate, the putative neurotransmitter conveying visual input to the SCN critical for clock entrainment. Long-distance communication between glial cells, seen as waves of fluorescence moving from cell to cell, probably through gap junctions, was induced by glutamate, 5-HT, and ATP. These waves increased the period length of cellular Ca2+ rises to 45-70 sec. Spontaneously oscillating cells were common in culture medium, serum, or rat cerebrospinal fluid, but rare in HEPES buffer. One source for cytoplasmic Ca2+ increases was an influx of extracellular Ca2+, as seen under depolarizing conditions in about 75% of the astroglia studied. All neurotransmitter-induced Ca2+ fluxes were not dependent on voltage changes, as Ca2+ oscillations could be initiated under both normal and depolarizing conditions. Since neurotransmitters could induce a Ca2+ rise in the absence of extracellular Ca2+, the mechanisms of ultradian oscillations appear to depend on cycles of intracellular Ca2+ fluxes from Ca(2+)-sequestering organelles into the cytoplasm, followed by a subsequent Ca2+ reduction. In the adult SCN, fewer astrocytes are found than neurons, yet astrocytes frequently surround glutamate-immunoreactive axons in synaptic contact with SCN dendrites, isolating neurons from each other while maintaining contact with other astrocytes by gap junctions.(ABSTRACT TRUNCATED AT 400 WORDS)

Ca2+ and filopodial responses to glutamate in cultured astrocytes and neurons.

Neurons and glia exhibit complex homeostatic interactions via shared extracellular space which can involve metabolites, inorganic ions, and neurotransmitters. Focal application of glutamate to both human and rat central nervous system astrocytes in primary culture produced a rapid, transient increase in both cytoplasmic and nuclear Ca2+. These Ca2+ waves can propagate at up to 15-20 micron/s for long distances (millimetres) through the astrocyte syncitium. Oscillatory Ca2+ signals were frequently observed under control conditions and were enhanced by glutamate application. These Ca2+ signals were paralleled by rapid extensions of filopodia from the astrocyte cell margin and apical surface near the point of glutamate application. Focal application of glutamate to rat hippocampal neurons also elicited rapid, transient increases in intracellular Ca2+. Levels of Ca2+ signals were consistently two- to three-fold greater in pyramidal neurons cultured from CA1 than in those from CA3. Filopodial extension was extensive in CA1 neurons, but rare in CA3 neurons, and in either case observable only during the first few days of primary culture. Diversity of glial and neuronal responses to binding the glutamate receptors may reflect their roles in homeostatic interactions.

Ca2+ waves in astrocytes.

The glial cell is the most numerous cell type in the central nervous system and is believed to play an important role in guiding brain development and in supporting adult brain function. One type of glial cell, the astrocyte also may be an integral computational element in the brain since it undergoes neurotransmitter-triggered signalling. Here we review the role of the astrocyte in the central nervous system, emphasizing receptor-mediated Ca2+ physiology. One focus is the recent discovery that the neurotransmitter glutamate induces a variety of intracellular Ca2+ changes in astrocytes. Simple Ca2+ spikes or intracellular Ca2+ oscillations often appear spatially uniform. However, in many instances, the Ca2+ rise has a significant spatial dimension, beginning in one part of the cell it spreads through the rest of the cell in the form of a wave. With high enough agonist concentration an astrocyte syncitium supports intercellular waves which propagate from cell to cell over relatively long distances. We present results of experiments using more specific pharmacological glutamate receptor agonists. In addition to describing the intercellular Ca2+ wave we present evidence for another form of intercellular signalling. Some possible functions of a long-range glial signalling system are also discussed.

Na(+)-current expression in rat hippocampal astrocytes in vitro: alterations during development.

1. With the use of whole-cell patch-clamp recording. Na(+)-current expression was studied in hippocampal astrocytes in vitro, individually identified by filling with Lucifer yellow (LY) and staining for glial fibrillary acidic protein (GFAP) and vimentin. 2. The proportion of astrocytes that express Na+ currents in rat hippocampal cultures changes during development in vitro and decreases from approximately 75% at day 1 to approximately 30% after 10 days in culture. 3. The sodium currents expressed in astrocytes can be differentiated into two types on the basis of kinetics. At early times in culture the time course of Na+ currents is fast in both onset and decay with an average decay time constant of 1.27 ms, whereas after 6 days Na+ currents become comparatively slow and decayed with an average time constant of 1.86 ms. 4. As with the time-course of Na+ currents, the two age groups of astrocytes (i.e., days 1-5 and day 6 and older) differ with respect to their steady-state inactivation characteristics. Early after plating and up to day 5, the midpoint of the steady-state inactivation curve is close to -60 mV, as also observed in hippocampal neurons of various ages; in contrast, after 6 days in culture the curve is shifted by approximately 25 mV toward more hyperpolarized potentials with a midpoint close to -85 mV. 5. In contrast to h infinity-curves, current-voltage (I-V) curves of Na(+)-current activation were identical in all astrocytes studied and did not change with time in culture. 6. In astrocytes expressing Na+ currents, current densities (average of 35 pA/pF on day 1) decreased throughout the first 5 days and were almost abolished around days 4 and 5 in culture. Beginning on day 6, however, current densities increased again and maintained a steady level (average of 14 pA/pF) for the duration of the time period in culture (20 days). This biphasic time course closely correlates with the time course of changes in Na(+)-current kinetics and steady-state inactivation. 7. These data suggest that Na+ currents in cultured hippocampal astrocytes show characteristic changes with increasing time in culture. During the first 4-5 days in culture, hippocampal astrocytes display Na+ currents with properties similar to those of hippocampal neurons. Our data further suggest that Na+ currents with distinctive, "glial-type" characteristics are only expressed in hippocampal astrocytes after 6 days in culture.