Deletion of Aquaporin-4 Curtails Extracellular Glutamate Elevation in Cortical Spreading Depression in Awake Mice.

Cortical spreading depression (CSD) is a phenomenon that challenges the homeostatic mechanisms on which normal brain function so critically depends. Analyzing the sequence of events in CSD holds the potential of providing new insight in the physiological processes underlying normal brain function as well as the pathophysiology of neurological conditions characterized by ionic dyshomeostasis. Here, we have studied the sequential progression of CSD in awake wild-type mice and in mice lacking aquaporin-4 (AQP4) or inositol 1,4,5-triphosphate type 2 receptor (IP3R2). By the use of a novel combination of genetically encoded sensors that a novel combination - an unprecedented temporal and spatial resolution, we show that CSD leads to brisk Ca2+ signals in astrocytes and that the duration of these Ca2+ signals is shortened in the absence of AQP4 but not in the absence of IP3R2. The decrease of the astrocytic, AQP4-dependent Ca2+ signals, coincides in time and space with a decrease in the duration of extracellular glutamate overflow but not with the initial peak of the glutamate release suggesting that in CSD, extracellular glutamate accumulation is extended through AQP4-dependent glutamate release from astrocytes. The present data point to a salient glial contribution to CSD and identify AQP4 as a new target for therapy.

Stimulation-evoked Ca2+ signals in astrocytic processes at hippocampal CA3-CA1 synapses of adult mice are modulated by glutamate and ATP.

To date, it has been difficult to reveal physiological Ca(2+) events occurring within the fine astrocytic processes of mature animals. The objective of the study was to explore whether neuronal activity evokes astrocytic Ca(2+) signals at glutamatergic synapses of adult mice. We stimulated the Schaffer collateral/commissural fibers in acute hippocampal slices from adult mice transduced with the genetically encoded Ca(2+) indicator GCaMP5E driven by the glial fibrillary acidic protein promoter. Two-photon imaging revealed global stimulation-evoked astrocytic Ca(2+) signals with distinct latencies, rise rates, and amplitudes in fine processes and somata. Specifically, the Ca(2+) signals in the processes were faster and of higher amplitude than those in the somata. A combination of P2 purinergic and group I/II metabotropic glutamate receptor (mGluR) antagonists reduced the amplitude of the Ca(2+) transients by 30-40% in both astrocytic compartments. Blockage of the mGluRs alone only modestly reduced the magnitude of the stimulation-evoked Ca(2+) signals in processes and failed to affect the somatic Ca(2+) response. Local application of group I or I/II mGluR agonists or adenosine triphosphate (ATP) elicited global astrocytic Ca(2+) signals that mimicked the stimulation-evoked astrocytic Ca(2+) responses. We conclude that stimulation-evoked Ca(2+) signals in astrocytic processes at CA3-CA1 synapses of adult mice (1) differ from those in astrocytic somata and (2) are modulated by glutamate and ATP.

The use of femto-second lasers to trigger powerful explosions of gold nanorods to destroy cancer cells.

Gold nanorods (AuNRs) with an aspect ratio of 3-4 exhibit large cross sections for single and multi photon light absorption processes in the near infrared region due to surface plasmon resonances. 800 nm laser pulses with the 150 fsec pulse duration (fs laser) can trigger explosions of AuNRs. The fs laser pulses at 20 W/mm(2) equivalent continuous wave (cw) power density blasted AuNRs in QGY human carcinoma cells as confirmed using transmission electron microscopy, while a cw laser at the same power density and dose did not. Cell survival studies further demonstrated that the cw laser at a dose of 15 J/mm(2) resulted in the death of 15% of AuNRs-loaded cells, probably due to a photothermal effect, while the fs laser at only 1.5 J/mm(2) killed more than 90% of AuNRs-loaded cells, indicating that the fs laser-triggered explosions of intracellular AuNRs are powerful enough to instantaneously kill tumour cells.

Analysis of optical properties of the mouse cranium--implications for in vivo multi photon laser scanning microscopy.

Trans-cranial imaging is the least invasive method for optical in vivo studies of structures in the mouse brain and has found wide application over the last few years. An important issue is how and to what extent the cranium and the tissue between the cranium and the focal point detract from the quality of the recorded images. Here we address this issue by recording transmission images in wild type mice at five wavelengths in the visible and near-infrared spectrum. The recorded laser scanning microscopic images were analyzed pixel by pixel in order to quantify the light attenuation and shading as function of the location of the focal point relative to the cranium. Additional images demonstrate the effects of the mouse crania on the images of fluorescent microspheres in the low micrometer range. The results of this study demonstrate that light attenuation by the cranium, though with typical losses of less than 20% of the incident light, induces shading effects during the imaging process. Geometrical shapes and sizes in the images of the recorded objects may differ substantially depending on whether they have been recorded trans-cranially or not. This is true even for comparatively large structures such as cell somata. Our results call for a more realistic appraisal of the potential of the trans-cranial imaging approach, particularly when it comes to absolute measurements of sizes and shapes of small objects. As trans-cranial imaging has found wide use in contemporary research it is important that the results be interpreted with due caution.

Water entry into astrocytes during brain edema formation.

The process of brain edema formation has been studied extensively at the macroscopic level. In contrast, little is known about water fluxes and volume changes at the cellular level in the initial phase of brain edema. Insight in these "microscopic" events could pave the way for more efficient prevention and therapy. Here, we report measurements of brain cell volume responses recorded in vivo in a model of systemic hyponatremia. Transgenic mice expressing fluorescent proteins in astrocytes were subjected to hypo-osmotic stress and two photon laser scanning microscopy. Volume measurements of glial cells in the cerebellum and the visual cortex indicate that individual astrocytes undergo a position-dependent increase in cell volume by a factor of two or more during edema formation. Our data are the first to show that volume changes can be monitored at the cellular level in vivo and demonstrate that astrocytes are sites of water entry in the initial phase of brain edema formation. The uptake of water in astrocytes is likely to reflect the strong expression of aquaporin-4 in these cells.

Localization and function of the Na+/Ca2+-exchanger in normal and detubulated rat cardiomyocytes.

It is controversial whether the Na+/Ca2+-exchanger (NCX) can induce cardiomyocyte contraction through reverse-mode exchange and Ca2+-induced Ca2+ release (CICR). Information about the spatial distribution and functional activity within different sarcolemmal (SL) regions could shed light on this potential role. We raised a new antibody to the NCX and showed by confocal laser scanning microscopy (CLSM) that immunoreactivity is strongly expressed throughout the surface SL and intercalated disk regions with punctate labeling of the vertical transverse (T)-tubules but not the longitudinal T-tubules. Immuno-electron microscopy confirmed CLSM observations. Gold particles associated with the exchanger were within nanometer range of particles signaling ryanodine receptors. A similar close association was found between the L-type Ca2+ channel (known to be concentrated in the dyad) and ryanodine receptors. In whole-cell patch-clamped cardiomyocytes, peak I(NCX) (measured at 90 mV) decreased by approximately 40% (497 +/- 32 vs. 304 +/- 12 pA, P < 0.001) after detubulation, while membrane capacitance decreased by 27% (204 +/- 11 vs. 150 +/- 7 pF, P < 0.01) thus giving a small but significant 16% reduction in current density. Thus, the density and/or functional activity of the NCX is greater in the vertical T-tubules than in the longitudinal T-tubules, surface SL or disk regions, pointing to important functional differences between these plasma membrane domains. Our combined co-immunolocalization and physiological data suggest that the NCX has multiple functions depending upon membrane location. We suggest the possibility that NCX modulates CICR, sarcoplasmic reticulum Ca2+ load, and that it also serves to regulate Ca2+ handling in neighboring cells.