Ex vivo imaging of active caspase 3 by a FRET-based molecular probe demonstrates the cellular dynamics and localization of the protease in cerebellar granule cells and its regulation by the apoptosis-inhibiting protein survivin.

BACKGROUND: Apoptosis takes place in naturally occurring neuronal death, but also in aging, neurodegenerative disorders, and traumatic brain injuries. Caspase 3 (Casp3) is the most important effector protease in apoptosis: being inactive inside the cell, it undergoes enzymatic cleavage and - hence - activation once the apoptotic cascade is triggered. Immunological techniques with antibodies against cleaved Casp3 (cCasp3) or assays with colorimetric/fluorogenic substrates are commonly in use, but they do not allow to directly follow the dynamics of activation in alive neurons that may be committed to die. RESULTS: By combined biolistic transfection, confocal microscopy, and fluorescence resonance energy transfer (FRET), we have implemented a methodology to dynamically monitor Casp3 activation in organotypic cerebellar slices from postnatal mice. After transfection with pSCAT3 FRET probes, we measured the ratio of the emissions of the donor/acceptor pair (ECFPem/Venusem) in fixed or alive cultures. In so doing, we i. discriminated the cellular compartment(s) of enzyme activation (nucleus, perikaryon, neurites); ii. demonstrated that Casp3 was constitutively active in the granule cells; iii. followed the fluctuations of ECFPem/Venusem, and its response to 25 mM KCl depolarization, or to increased intracellular Ca(++) after NMDA (1 mM), kainic acid (1 mM), or A23187 (100-200 µM). The specificity of the active pSCAT3-DEVD probe was confirmed with RNA interference and after inhibition of Casp3 with Ac-DEVD-CMK (100 µM), as both sets of experiments brought ECFPem/Venusem to the values recorded with the control probe pSCAT3-DEVG. After double-transfection with pSCAT3-DEVD + pHcRed1-C1-survivin, we also showed a 44-56% reduction of basal Casp3 activity in cells overexpressing survivin, a protein-member of the family of apoptosis inhibitors, with augmented survival (2.82 folds). Survivin-rescued cells were sensitive to 5 mM H2O2 oxidative stress but died without intervention of Casp3. CONCLUSIONS: This ex vivo FRET-based methodology provides quantitative information on the functional and histological dynamics of Casp3 activation in individual neurons at a cell level resolution. Not only it can be combined with experimental manipulation of the apoptotic machinery inside the cell, but offers several advantages over existing protocols for monitoring apoptosis in live mammalian neurons, and has potential to be transferred in vivo. Due to the pivotal role of Casp3 in apoptosis, our approach is relevant for a better comprehension of molecular neurodegeneration in the normal and pathological brain.

Real-time visualization of caspase-3 activation by fluorescence resonance energy transfer (FRET).

As apoptosis occurs via a complex signaling cascade that is tightly regulated at multiple cell points, different methods exist to evaluate the activity of the proteins involved in the intracellular apoptotic pathways and the phenotype of apoptotic neurons. Detention of the activity of the enzyme caspase-3, the key executioner caspase in programmed cell death, by laser scanning confocal fluorescence microscopy and the fluorescence resonance energy transfer technology is an alternative approach to classical standard techniques, such as Western blotting, activity assays, or histological techniques, and allows working with both fixed and living cells. This technique combined with the organotypic culture approach ex vivo represents a valid tool for the study of the mechanisms of neuronal survival /death and neuroprotection.

Post-natal development of the Reeler mouse cerebellum: An ultrastructural study.

Reelin, an extracellular protein promoting neuronal migration in brain areas with a laminar architecture, is missing in the Reeler mouse (reelin(-/-)). Several studies indicate that the protein is also necessary for correct dendritic outgrowth and synapse formation in the adult forebrain. By transmission electron microscopy, we characterize the development and synaptic organization of the cerebellar cortex in Reeler mice and wild type control littermates at birth, postnatal day (P) 5, 7, 10 and 15. Ultrastructural analysis shows deep alterations in cortical architecture and mispositioning of the Purkinje neurons (Pns), which remain deeply embedded in a central cellular mass within the white matter, with highly immature features. Quantitative examination shows that Reeler mice display: (i) a lower density of granule cells and a higher density of Pns, from P10; (ii) a lower density of synaptic contacts between Pn dendrites and parallel or climbing fibers, from P5; (iii) a lower density of synaptic contacts between basket cells and Pns, from P5; and (iv) a lower density of mossy fiber rosettes, from P10. Our results demonstrate that Reelin profoundly affects the structure and synaptic connectivity of post-natal mouse cerebellum.

Context-dependent toxicity of amyloid-ß peptides on mouse cerebellar cells.

Alzheimer's disease (AD) is the major cause of dementia in old people. AD pathology is characterized by amyloid-ß (Aß) deposits in several regions of the brain, and links have been hypothesized between Aß toxicity and apoptosis. Cerebellar granule cells (CGCs) have been widely used as in vitro tools for molecular studies correlating apoptosis with AD, although the cerebellum is a relatively spared area of the brain in vivo. We have used mixed neuronal-glial cerebellar cultures (NGCCs) and organotypic cerebellar cultures (OCCs) obtained from postnatal mice to assess the toxic effect of the Aß oligomer 1-40 (Aß1-40) after propidium iodide uptake in vitro. Our results demonstrate that NGCCs, which are primarily composed of CGCs, are resistant to Aß1-40 challenge (5-10 µM) when cultured in physiological (5 mM) extracellular KCl ([K+]e) concentrations, i.e., in a condition in which CGCs undergo full maturation. Conversely, when 10 µM Aß1-40 is given to NGCCs cultured in elevated (25 mM) [K+]e (and thus maintained in an immature state), there is a statistically significant increase in cell death. Cell death is by apoptosis, as demonstrated by ultrastructural examination. OCCs are resistant to Aß challenge in any of the conditions tested (variation of [K+]e, presence or absence of serum, or addition of the neprilysin blocker phosphoramidon). Altogether these observations lead us to conclude that cerebellar cells in an organotypic context may be less susceptible to damage by Aß, raising the question whether isolated CGCs are a reliable assay in drug discovery studies of AD.

Posttranslational regulation of BCL2 levels in cerebellar granule cells: A mechanism of neuronal survival.

Apoptosis can be modulated by K(+) and Ca(2+) inside the cell and/or in the extracellular milieu. In murine organotypic cultures, membrane potential-regulated Ca(2+) signaling through calcineurin phosphatase has a pivotal role in development and maturation of cerebellar granule cells (CGCs). P8 cultures were used to analyze the levels of expression of B cell lymphoma 2 (BCL2) protein, and, after particle-mediated gene transfer in CGCs, to study the posttranslational modifications of BCL2 fused to a fluorescent tag in response to a perturbation of K(+)/Ca(2+) homeostasis. There are no changes in Bcl2 mRNA after real time PCR, whereas the levels of the fusion protein (monitored by calculating the density of transfected CGCs under the fluorescence microscope) and of BCL2 (inWestern blotting) are increased. After using a series of agonists/antagonists for ion channels at the cell membrane or the endoplasmic reticulum (ER), and drugs affecting protein synthesis/degradation, accumulation of BCL2 was related to a reduction in posttranslational cleavage by macroautophagy. The ER functionally links the [K(+)](e) and [Ca(2+)](i) to the BCL2 content in CGCs along two different pathways. The first, triggered by elevated [K(+)](e) under conditions of immaturity, is independent of extracellular Ca(2+) and operates via IP3 channels. The second leads to influx of extracellular Ca(2+) following activation of ryanodine channels in the presence of physiological [K(+)](e), when CGCs are maintained in mature status. This study identifies novel mechanisms of neuroprotection in immature and mature CGCs involving the posttranslational regulation of BCL2.

Cell death and proliferation in acute slices and organotypic cultures of mammalian CNS.

Analysis of the interplay between cell proliferation and death has been greatly advantaged by the development of CNS slice preparations. In slices, interactions between neurons and neurons and the glial cells are fundamentally preserved in a fashion close to the in vivo situation. In parallel, these preparations offer the possibility of an easy experimental manipulation. Two main types of slices are currently in use: the acute slices, which are short living preparations where the major functions of the intact brain (including neurogenesis) are maintained, and the organotypic cultures, where the maturation and plasticity of neuronal circuitries in relation to naturally occurring neuronal death and/or experimental insults can be followed over several weeks in vitro. We will discuss here the main advantages/disadvantages linked to the use of CNS slices for histological analysis of neuronal proliferation and death, as well as the main findings obtained in the most popular types of preparations, i.e. the cortical, hippocampal, cerebellar and retinal slices.