A Bioactive Olive Pomace Extract Prevents the Death of Murine Cortical Neurons Triggered by NMDAR Over-Activation.

We have recently demonstrated that bioactive molecules, extracted by high pressure and temperature from olive pomace, counteract calcium-induced cell damage to different cell lines. Here, our aim was to study the effect of the same extract on murine cortical neurons, since the preservation of the intracellular Ca2+-homeostasis is essential for neuronal function and survival. Accordingly, we treated neurons with different stimuli in order to evoke cytotoxic glutamatergic activation. In these conditions, the high-pressure and temperature extract from olive pomace (HPTOPE) only abolished the effects of N-methyl-d-aspartate (NMDA). Particularly, we observed that HPTOPE was able to promote the neuron rescue from NMDA-induced cell death. Moreover, we demonstrated that HPTOPE is endowed with the ability to maintain the intracellular Ca2+-homeostasis following NMDA receptor overactivation, protecting neurons from Ca2+-induced adverse effects, including aberrant calpain proteolytic activity. Moreover, we highlight the importance of the extraction conditions used that, without producing toxic molecules, allow us to obtain protecting molecules belonging to proanthocyanidin derivatives like procyanidin B2. In conclusion, we can hypothesize that HPTOPE, due to its functional and nontoxic properties on neuronal primary culture, can be utilized for future therapeutic interventions for neurodegeneration.

A new human calpastatin skipped of the inhibitory region protects calpain-1 from inactivation and degradation.

Several human acute and chronic diseases involve calpain over-activation. However, the mechanistic linkages between the etiology and the progression of cell damages are not yet completely understood. Here we show that different human cells and tissues, including brain tumor specimens, cell lines of nerve origin, breast tumor samples and peripheral blood mononuclear cells from healthy donors, express a calpastatin form that lacks all the exons coding for the domains responsible of calpain inhibition. The open reading frame of this new form of calpastatin, named hcast 3-25, starts inside the L-domain (exons 2 and 3) and continues with the exons from 25 to 29 that code for the conserved C-terminal tail shared by all the full-length calpastatins. We have here observed that unlike the other calpastatins forms, that are predominantly Δ3 splice variants, hcast 3-25 is endowed with exon 3. At a functional level, recombinant hcast 3-25 operates as a positive modulator of calpain-1 in vitro by preventing 1) calpain-1-mediated proteolytic degradation of the activated enzyme and 2) binding to calpain-1 of inhibitory calpastatins that contain the L-domain. Thus hcast 3-25 can be considered as a novel member and possible modulator of the calpain/calpastatin system acting by a mechanism alternative to inhibition.

Cell protection from Ca2+-overloading by bioactive molecules extracted from olive pomace.

We are reporting in the present study that molecules extracted from olive pomace prevent cell death induced by Ca2+-overloading in different cell types. Exposure of cells to these molecules counteracts the Ca2+-induced cell damages by reducing the activation of the Ca2+-dependent protease calpain, acting possibly through the modification of the permeability to Ca2+ of the plasma membrane. The purification step by RP-HPLC suggests that effective compound(s), differing from the main biophenols known to be present in the olive pomace extract, could be responsible for this effect. Our observations suggest that bioactive molecules present in the olive pomace could be potential candidates for therapeutic applications in pathologies characterised by alterations of intracellular Ca2+ homeostasis.

Unexpected role of the L-domain of calpastatin during the autoproteolytic activation of human erythrocyte calpain.

Autoproteolysis of human erythrocyte calpain-1 proceeds in vitro at high [Ca2+], through the conversion of the 80-kDa catalytic subunit into a 75-kDa activated enzyme that requires lower [Ca2+] for catalysis. Importantly, here we detect a similar 75 kDa calpain-1 form also in vivo, in human meningiomas. Although calpastatin is so far considered the specific inhibitor of calpains, we have previously identified in rat brain a calpastatin transcript truncated at the end of the L-domain (cast110, L-DOM), coding for a protein lacking the inhibitory units. Aim of the present study was to characterize the possible biochemical role of the L-DOM during calpain-1 autoproteolysis in vitro, at high (100 µM) and low (5 µM) [Ca2+]. Here we demonstrate that the L-DOM binds the 80 kDa proenzyme in the absence of Ca2+ Consequently, we have explored the ability of the 75 kDa activated protease to catalyze at 5 µM Ca2+ the intermolecular activation of native calpain-1 associated with the L-DOM. Notably, this [Ca2+] is too low to promote the autoproteolytic activation of calpain-1 but enough to support the catalysis of the 75 kDa calpain. We show for the first time that the L-DOM preserves native calpain-1 from the degradation mediated by the 75 kDa form. Taken together, our data suggest that the free L-domain of calpastatin is a novel member of the calpain/calpastatin system endowed with a function alternative to calpain inhibition. For this reason, it will be crucial to define the intracellular relevance of the L-domain in controlling calpain activation/activity in physiopathological conditions having altered Ca2+ homeostasis.