RVG-mediated calpain2 gene silencing in the brain impairs learning and memory.

In the central nervous system, two calpain isoforms are highly expressed: calpain1 and calpain2. Here, we show for the first time that activation of the calpain isoform, calpain2, is a necessary event in hippocampal synaptic plasticity and in learning and memory. We developed a fluorescence resonance energy transfer-based animal model to monitor in vivo calpain activation in single cells and in real time. Additionally, utilizing a novel rabies virus glycoprotein-chimeric peptide, which enabled the transvascular delivery of small interfering RNA to the brain against calpain2, we down-regulated the calpain2 isoform in vivo. Calpain2 gene silencing eliminated long-term potentiation and impaired learning and memory. Our results not only identify the calpain2 isoform as a critical mediator in learning and memory but also highlight an innovative, highly efficient calpain2-targeting peptide capable of isoform-specific gene silencing in the brain. We anticipate these innovative technologies and our better understanding of the calpain machinery, particularly of the calpain2 isoform, will have substantial influence on future translational studies, attracting considerable interest in the use of calpain models and calpain-specific inhibitors in the development of therapeutics.

Enhanced-acceptor fluorescence-based single cell ATP biosensor monitors ATP in heterogeneous cancer populations in real time.

Current methods to monitor cellular ATP do not provide spatial or temporal localization of ATP in single cells in real time or they display imperfect specificity to ATP. Here, we have developed a single cell, Enhanced Acceptor Fluorescence (EAF)-based ATP biosensor to visualize ATP in real time. This biosensor utilizes a modified mimic of the ε-subunits of the Bacillus subtilis F(0)F(1) synthase and is coupled to the EAF fluorophores pairs, GFP and YFP. The sensor was then used to monitor ATP in a heterogeneous glioblastoma multiform cancer cell population. We anticipate that this innovative technology and our better understanding of the ATP machinery will have substantial influence on future translational studies.

ENTPD5-mediated modulation of ATP results in altered metabolism and decreased survival in gliomablastoma multiforme.

Gliomablastoma multiforme (GBM) is the most aggressive of brain cancers in humans. Response to current therapies remains extremely poor, with dismal survival statistics. Recently, the endoplasmic reticulum UDPase, ectonucleoside triphosphate diphosphohydrolase 5 (ENTPD5), was identified as a key component in the Akt/phosphatidylinositol 3-kinase/phosphatase and tensin homolog regulatory loop, capable of synergizing aerobic glycolysis and cancer cell proliferation in vitro. Utilizing a novel enhanced acceptor fluorescence-based single-cell adenosine 5'-triphosphate (ATP) biosensor, we analyzed ENTPD5-mediated modulation of cytosolic ATP. Here, ENTPD5-dependent modulation of cellular ATP in GBM results in altered metabolic kinetics in vitro, increasing the catabolic efficiencies of aerobic glycolysis and fatty acid oxidation. Additionally, an upregulation of ENTPD5 in both GBM mouse xenografts and in GBM patient tumors was identified, resulting in dramatically reduced survival. Therefore, these results not only provide new tools to monitor ATP flux and cellular metabolism kinetics but also identified a novel therapeutic target for GBM.

Ampakines promote spine actin polymerization, long-term potentiation, and learning in a mouse model of Angelman syndrome.

Angelman syndrome (AS) is a neurodevelopmental disorder largely due to abnormal maternal expression of the UBE3A gene leading to the deletion of E6-associated protein. AS subjects have severe cognitive impairments for which there are no therapeutic interventions. Mouse models (knockouts of the maternal Ube3a gene: 'AS mice') of the disorder have substantial deficits in long-term potentiation (LTP) and learning. Here we report a clinically plausible pharmacological treatment that ameliorates both deficits. AS mice were injected ip twice daily for 5 days with vehicle or the ampakine CX929; drugs of this type enhance fast EPSCs by positively modulating AMPA receptors. Theta burst stimulation (TBS) produced a normal enhancement of field EPSPs in hippocampal slices prepared from vehicle-treated AS mice but LTP decreased steadily to baseline; however, LTP in slices from ampakine-treated AS mice stabilized at levels found in wild-type controls. TBS-induced actin polymerization within dendritic spines, an essential event for stabilizing LTP, was severely impaired in slices from vehicle-treated AS mice but not in those from ampakine-treated AS mice. Long-term memory scores in a fear conditioning paradigm were reduced by 50% in vehicle-treated AS mice but were comparable to values for littermate controls in the ampakine-treated AS mice. We propose that AS is associated with a profound defect in activity-driven spine cytoskeletal reorganization, resulting in a loss of the synaptic plasticity required for the encoding of long-term memory. Notably, the spine abnormality along with the LTP and learning impairments can be reduced by a minimally invasive drug treatment.

17-Beta-estradiol increases neuronal excitability through MAP kinase-induced calpain activation.

17-Beta-estradiol (E2) is a steroid hormone involved in numerous brain functions. E2 regulates synaptic plasticity in part by enhancing NMDA receptor function and spine density in the hippocampus, resulting in increased long-term potentiation and facilitation of learning and memory. As the calcium-dependent neutral protease, calpain, is also involved in these processes, we tested whether E2 could activate calpain and examined the functional consequences of E2-mediated calpain activation in hippocampus. Calpain activity was analyzed by a fluorescence resonance energy transfer (FRET)-based assay that allows both quantitative determination and spatial resolution. E2 rapidly activated calpain in cultured cortical and hippocampal neurons, prominently in dendrites and dendritic spines. E2-induced calpain activation was mediated through mitogen-activated protein kinase (MAPK), as it was completely blocked by MEK inhibitors. It was also calcium-independent, as it was still evident in presence of the calcium chelator, BAPTA-AM. Activation of ERalpha and ERbeta receptors by specific agonists stimulated calpain activity. Finally, the rapid E2-mediated increase in excitability in acute hippocampal slices was prevented by a membrane-permeable calpain inhibitor. Furthermore, E2 treatment of acute hippocampal slices resulted in increased actin polymerization and membrane levels of GluR1 but not GluR2/3 subunits of AMPA receptors; both effects were also blocked by a calpain inhibitor. Our results indicate that E2 rapidly stimulates calpain activity through MAP kinase-mediated phosphorylation, resulting in increased membrane levels of AMPA receptors. These effects could be responsible for E2-mediated increase in neuronal excitability and facilitation of cognitive processes.