Microbeam laser-injured neurons increase in vitro astrocytic gap junctional communication as measured by fluorescence recovery after laser photobleaching

Connexin-Dependent Neuroglial Networking as a New Therapeutic Target

Astrocytes and neurons dynamically interact during physiological processes, and it is now widely accepted that they are both organized in plastic and tightly regulated networks. Astrocytes are connected through connexin-based gap junction channels, with brain region specificities, and those networks modulate neuronal activities, such as those involved in sleep-wake cycle, cognitive, or sensory functions. Additionally, astrocyte domains have been involved in neurogenesis and neuronal differentiation during development; they participate in the “tripartite synapse” with both pre-synaptic and post-synaptic neurons by tuning down or up neuronal activities through the control of neuronal synaptic strength. Connexin-based hemichannels are also involved in those regulations of neuronal activities, however, this feature will not be considered in the present review. Furthermore, neuronal processes, transmitting electrical signals to chemical synapses, stringently control astroglial connexin expression, and channel functions. Long-range energy trafficking toward neurons through connexin-coupled astrocytes and plasticity of those networks are hence largely dependent on neuronal activity. Such reciprocal interactions between neurons and astrocyte networks involve neurotransmitters, cytokines, endogenous lipids, and peptides released by neurons but also other brain cell types, including microglial and endothelial cells. Over the past 10 years, knowledge about neuroglial interactions has widened and now includes effects of CNS-targeting drugs such as antidepressants, antipsychotics, psychostimulants, or sedatives drugs as potential modulators of connexin function and thus astrocyte networking activity. In physiological situations, neuroglial networking is consequently resulting from a two-way interaction between astrocyte gap junction-mediated networks and those made by neurons. As both cell types are modulated by CNS drugs we postulate that neuroglial networking may emerge as new therapeutic targets in neurological and psychiatric disorders.

Overview of laser microbeam applications as related to antibody targeting

This chapter reviews several techniques which combine the use of laser microbeams with antibodies to study molecular and cellular biology. An overview of the basic properties of lasers and their integration with microscopes and computers is provided. Biophysical applications, such as fluorescence recovery after photobleaching to measure molecular mobility and fluorescence resonance energy transfer to measure molecular distances, as well as ablative applications for the selective inactivation of proteins or the selective killing of cells are described. Other techniques, such as optical trapping, that do not rely on the interaction of the laser with the targeting antibody, are also discussed.

Neurons set the tone of gap junctional communication in astrocytic networks

A number of studies have contributed to demonstrate that neurons and astrocytes tightly and actively interact. Indeed, the presence of astrocytes in neuronal cultures increases the number of synapses and their efficiency, and thanks to enzymatic and uptake processes, astrocytes play a role in neuroprotection. A typical feature of astrocytes is that they establish cell-cell communication in vitro, as well as in situ, through intercellular channels forming specialized membrane areas defined as gap junctions. These channels are composed of junctional proteins termed connexins (Cxs): in astrocytes connexin 43 (Cx43) and 30 (Cx30) have been shown to prevail. Several recent works indicate that gap junctional communication (GJC) and/or connexin expression in astrocytes are controlled by neurons. Altogether, these observations lead to the concept that neuronal and astrocytic networks interact through mutual setting of their respective mode of communication and that astrocyte gap junctions represent a target in neuroglial interaction.

Connexin43 null mutation increases infarct size after stroke

Glial-neuronal interactions have been implicated in both normal information processing and neuroprotection. One pathway of cellular interactions involves gap junctional intercellular communication (GJIC). In astrocytes, gap junctions are composed primarily of the channel protein connexin43 (Cx43) and provide a substrate for formation of a functional syncytium implicated in the spatial buffering capacity of astrocytes. To study the function of gap junctions in the brain, we used heterozygous Cx43 null mice, which exhibit reduced Cx43 expression. Western blot analysis showed a reduction in the level of Cx43 protein and GJIC in astrocytes cultured from heterozygote mice. The level of Cx43 is reduced in the adult heterozygote cerebrum to 40% of that present in the wild-type. To assess the effect of reduced Cx43 and GJIC on neuroprotection, we examined brain infarct volume in wild-type and heterozygote mice after focal ischemia. In our model of focal stroke, the middle cerebral artery was occluded at two points, above and below the rhinal fissure. Four days after surgery, mice were killed, the brains were sectioned and analyzed. Cx43 heterozygous null mice exhibited a significantly larger infarct volume compared with wild-type (14.4 +/- 1.4 mm(3) vs. 7.7 +/- 0.82 mm(3), P < 0.002). These results suggest that augmentation of GJIC in astrocytes may contribute to neuroprotection after ischemic injury.

Quantitative evaluation of intact peripheral nerve structures after utilization of CO2 laser, electrocautery, and scalpel

OBJECTIVE

This study aimed to evaluate quantitatively the integrity of nerve structures near CO2 laser incisions.

BACKGROUND DATA

There are some hypotheses that try to explain the analgesia reported after CO2 laser surgery. One of them is based upon the observation of the destruction of nerve endings after use of this technique.

METHODS

A comparative study was carried out using 25 animals (Rattus norvegicus) divided into five groups of 5 animals each. Standard incisions were carried on the dorsum of the tongue of each animal using the cautery (group 2), scalpel (group 3), CW CO2 laser (group 4), and SPS CO2 (group 5); group I served as control. The animals were killed immediately after the experiment, and specimens were taken and routinely processed to wax. Three-micrometer sections were cut and stained using S-100 protein antibody. The stained sections were analyzed under light microscopy using a calibrated graticule, and the number of intact nerves was counted in five standard areas around the incision.

RESULTS

The results of this study showed that there were no statistically significant differences in the numbers of intact peripheral nerve structures in both laser groups and other groups. No statistically significant difference was found between nonoperated and scalpel groups. The number of intact peripheral structures in cautery wounds was significantly smaller than in non-operated and scalpel wounds.

CONCLUSIONS

Therefore, it is unlikely that immediate destruction of peripheral nerve structures is the cause of post-operative analgesia following CO2 laser surgery.

Glioanatomy assessed by cell-cell interactions and phagocytotic labelling

In the last three decades of research in neuroscience, fluorescent probes have gone from technical tools in the studies of physicochemical reactions, to being versatile tools in developmental neurobiology, neuroanatomy, angiography, neuromorphology, connectivity, cell death and even photodynamic therapy. Fluorescent dyes belong to heterogeneous groups of substances, but the feature to emit light of a certain wavelength depends on the energy status of the corresponding chemical bond. Therefore, light emission can range from the blue to the infrared spectrum, thus allowing multiple stains of the same cell, or event. The heterogeneity in their structure allows application of some fluorescent dyes for anterograde long-tract labelling, whereas others can be used for retrograde tracing. Lipophilic dyes are suitable for intramembraneous diffusion along cell membranes post-mortem, whereas hydrophilic stains seem more suitable for genealogic cell studies over several cell divisions. In the same time, less attention has been paid by most researchers to the use of fluorescent dyes to monitor neuroglial interactions and glioanatomy in the healthy and diseased brain. Studies of cell-cell-interactions during apoptosis can now be carried out with sequestration and subsequent phagocytosis of intracellular dyes. The present review focuses on recent developments that include the use of fluorescent probes. These probes make it possible to transneuronally assess functions of glial cells during programmed cell death, or induced degeneration. The high variety of available dyes, and their particular accumulation within subcellular compartments, is promising to shed light on some glial cell geometry and functions. The lessons obtained from the vast number of studies in neurons are of increasing importance for cells too, as their functions are not directly accessible. In short, some glial-glial and neuroglial negotiations will be analysed in near future by developing new, or by modifying existing fluorescent probes.

Astrocytic gap junction removal, connexin43 redistribution, and epitope masking at excitatory amino acid lesion sites in rat brain

We previously reported that kainic acid (KA) lesion sites in rat brain exhibit an absence of astrocytic gap junctions at 1 week post-lesion. Loss of immunocytochemical reactivity with a sequence-specific antibody against the astrocytic gap junctional protein connexin43 (Cx43) suggested epitope masking since persistence of Cx43 was observed on Western blots. Here, we determined the fate of Cx43 at various times after thalamic KA and striatal NMDA lesions. In normal tissue and at 6 hr post-KA lesion, Cx43 immunoreactivity predominated at typical astrocytic gap junctions. Immunolabelled junctions were still seen at 3 days, with epitope masking already present, and were virtually absent by 6 days post-lesion. Gap junction remodeling was indicated by the appearance of intracellular immunostained annular profiles and uncharacteristically extensive gap junctions between symmetrically immunolabelled membranes and between labelled astrocytic and unlabelled oligodendrocytic membranes. Labelled multivesicular clusters emerged at 2 days, were numerous at 3 days and constituted the sole Cx43 sequestration site by post-lesion day 6. Ultrastructural disruption and gap junction disassembly progressed more slowly in NMDA-injected tissue where immunoreactivity persisted, albeit at markedly decreasing levels until the final survival time examined (16 days). Intense Cx43 immunolabelling was seen in filopodia of putative reactive astrocytes at the lesion periphery at 6-8 days and was associated at 16 days with an increased number of gap junctions primarily between fine astrocytic processes. These results demonstrate that massive neuronal loss alone or in conjunction with direct actions of excitotoxins on astrocytes precipitates an astrocytic reaction accompanied initially by removal of their gap junctions followed by redistribution of Cx43, and suggest that the astrocytic syncytium may undergo reorganization in a manner leading to isolation of the lesion site.

Quantitative junctional permeability measurements using the confocal microscope

This paper describes the use of a photobleach method and confocal microscopy to compare the cell-to-cell transfer rate of 5,6 carboxyfluorescein in dissociated embryonic chick lens cells with those in the anterior epithelium of the whole embryonic chick lens. The average cell-to-cell transfer rates obtained were 7.9 x 10(-3) sec-1 in the dissociated cells and 2.6 x 10(-3) sec-1 in the anterior epithelium in an intact lens.

Ischemia-induced cellular redistribution of the astrocytic gap junctional protein connexin43 in rat brain

The distribution and levels of the astrocytic gap junction protein, connexin43 (Cx43) was analyzed in various regions of brain as a function of time after neuronal loss and consequent reactive gliosis induced by bilateral carotid occlusion in rats. In the striatum 2 days after induction of ischemia, immunostaining intensity for Cx43 increased in animals exhibiting mild to moderate striatal damage, whereas areas of reduced staining surrounded by elevated levels of Cx43 immunoreactivity were observed in animals with severe ischemic damage. Immunolabelling of glial cell bodies was evident in ischemic, but not normal, striatum. Similar, though less dramatic, changes were seen at 7 days post-ischemia. Compared with the fine punctate pattern of Cx43 staining seen in normal striatum, ischemic striatal areas contained large aggregates of punctate profiles. In the hippocampus, increased immunostaining was seen at 2 and 7 days post-ischemia and, unlike normal hippocampus, neurons in the CA3 pyramidal cell layer were surrounded by a network of Cx43-immunoreactive puncta at the latter survival time. Immuno-EM analysis of ischemic tissue revealed numerous immunolabelled gap junctions among astrocytic processes in the vicinity of degenerating neurons and elevated levels of intracellular Cx43 immunoreactivity in astrocytic processes and cell bodies. No differences in protein levels or phosphorylation states of Cx43 were detected in either hippocampus or striatum by Western blot analyses of ischemic and control tissue. These results suggest that astrocytes respond to an ischemic insult by reorganizing their gap junctions, that the qualitative nature of their response is dependent on the severity of neuronal damage or loss, and that a pool of Cx43 normally undetectable by immunohistochemistry may contribute to the ischemia-induced elevations of immunolabelling for this protein.

Kainic acid induced alterations in antibody recognition of connexin43 and loss of astrocytic gap junctions in rat brain

Intracerebral administration of kainic acid (KA) in rats was previously shown to abolish immunohistochemical labelling for the astrocytic gap junction protein connexin43 (Cx43) at sites depleted of neurons (Vukelic et al: Neurosci Lett 130:120-124, 1991). This response of Cx43 has now been further investigated with a number of different sequence-specific anti-Cx43 antibodies. At lesion sites in the thalamus, striatum, and hippocampus examined immunohistochemically with an antibody against amino acids (aa's) 346-363 in the Cx43 sequence, the antibody used in the earlier study, Cx43-immunoreactivity was increased 5 h after KA injections, absent by 24 h and for up to 2 weeks post-injection, and began to return to less than normal levels by 2 to 3 weeks post-injection. Analyses of KA lesion sites with antibodies against other sequences of Cx43 (amino acids 283-298, 253-270, 241-260, 113-123, and 49-61) revealed not only the presence but in some cases an increased density of Cx43 immunoreactivity after a survival time of 1 week. Immunolabelling patterns at these sites consisted of relatively large, coarse profiles rather the fine punctate labelling typically seen in sections of normal brain. In homogenates of KA-injected striatum analyzed by Western blots, Cx43 was detected at near normal or slightly increased levels at various survival times examined. The 43 kDa phosphorylated form of Cx43 and its faster migrating 41 kDa dephosphorylated form which is generated post-mortem by a brain phosphatase were both present after standard methods of tissue preparation for Western blot analysis, while only the 43 kDa form was present in normal and KA-injected striatum after inactivation of brain metabolism by focused cranial microwave irradiation. Ultrastructural investigations of lesions sites within the thalamus revealed a virtual absence of astrocytic gap junctions. These results demonstrate that Cx43 levels initially increase after intracerebral KA treatment, that its molecular organization in resident astrocytes is altered such that epitopes that are normally accessible to antibody are hidden while those that may be hidden or relatively inaccessible are exposed, and that this molecular alteration in Cx43 is associated with loss of astrocytic gap junctions.