Frédéric Brau

Involvment of Cytosolic and Mitochondrial GSK-3β in Mitochondrial Dysfunction and Neuronal Cell Death of MPTP/MPP+-Treated Neurons

Aberrant mitochondrial function appears to play a central role in dopaminergic neuronal loss in Parkinsons disease (PD). 1-methyl-4-phenylpyridinium iodide (MPP+), the active metabolite of N-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), is a selective inhibitor of mitochondrial complex I and is widely used in rodent and cell models to elicit neurochemical alterations associated with PD. Recent findings suggest that Glycogen Synthase Kinase-3β (GSK-3β), a critical activator of neuronal apoptosis, is involved in the dopaminergic cell death. In this study, the role of GSK-3β in modulating MPP+-induced mitochondrial dysfunction and neuronal death was examined in vivo, and in two neuronal cell models namely primary cultured and immortalized neurons. In both cell models, MPTP/MPP+ treatment caused cell death associated with time- and concentration-dependent activation of GSK-3β, evidenced by the increased level of the active form of the kinase, i.e. GSK-3β phosphorylated at tyrosine 216 residue. Using immunocytochemistry and subcellular fractionation techniques, we showed that GSK-3β partially localized within mitochondria in both neuronal cell models. Moreover, MPP+ treatment induced a significant decrease of the specific phospho-Tyr216-GSK-3β labeling in mitochondria concomitantly with an increase into the cytosol. Using two distinct fluorescent probes, we showed that MPP+ induced cell death through the depolarization of mitochondrial membrane potential. Inhibition of GSK-3β activity using well-characterized inhibitors, LiCl and kenpaullone, and RNA interference, prevented MPP+-induced cell death by blocking mitochondrial membrane potential changes and subsequent caspase-9 and -3 activation. These results indicate that GSK-3β is a critical mediator of MPTP/MPP+-induced neurotoxicity through its ability to regulate mitochondrial functions. Inhibition of GSK-3β activity might provide protection against mitochondrial stress-induced cell death.

Altered acetylcholine, bradykinin and cutaneous pressure-induced vasodilation in mice lacking the TREK1 potassium channel: the endothelial link.

The TWIK related K+ channel TREK1 is an important member of the class of two‐pore‐domain K+ channels. It is a background K+ channel and is regulated by hormones, neurotransmitters, intracellular pH and mechanical stretch. This work shows that TREK1 is present both in mesenteric resistance arteries and in skin microvessels. It is particularly well expressed in endothelial cells. Deletion of TREK1 in mice leads to an important alteration in vasodilation of mesenteric arteries induced by acetylcholine and bradykinin. Iontophoretic delivery of acetylcholine and bradykinin in the skin of TREK1+/+ and TREK1−/− mice also shows the important role of TREK1 in cutaneous endothelium‐dependent vasodilation. The vasodilator response to local pressure application is also markedly decreased in TREK1−/− mice, mimicking the decreased response to pressure observed in diabetes. Deletion of TREK1 is associated with a marked alteration in the efficacy of the G‐protein‐coupled receptor‐associated cascade producing NO that leads to major endothelial dysfunction.

FATE1 antagonizes calcium‐ and drug‐induced apoptosis by uncoupling ER and mitochondria

Several stimuli induce programmed cell death by increasing Ca2+ transfer from the endoplasmic reticulum (ER) to mitochondria. Perturbation of this process has a special relevance in pathologies as cancer and neurodegenerative disorders. Mitochondrial Ca2+ uptake mainly takes place in correspondence of mitochondria‐associated ER membranes (MAM), specialized contact sites between the two organelles. Here, we show the important role of FATE1, a cancer‐testis antigen, in the regulation of ER–mitochondria distance and Ca2+ uptake by mitochondria. FATE1 is localized at the interface between ER and mitochondria, fractionating into MAM. FATE1 expression in adrenocortical carcinoma (ACC) cells under the control of the transcription factor SF‐1 decreases ER–mitochondria contact and mitochondrial Ca2+ uptake, while its knockdown has an opposite effect. FATE1 also decreases sensitivity to mitochondrial Ca2+‐dependent pro‐apoptotic stimuli and to the chemotherapeutic drug mitotane. In patients with ACC, FATE1 expression in their tumor is inversely correlated with their overall survival. These results show that the ER–mitochondria uncoupling activity of FATE1 is harnessed by cancer cells to escape apoptotic death and resist the action of chemotherapeutic drugs.

Enriched environment reduces glioma growth through immune and non-immune mechanisms in mice

Mice exposed to standard (SE) or enriched environment (EE) were transplanted with murine or human glioma cells and differences in tumour development were evaluated. We report that EE exposure affects: (i) tumour size, increasing mice survival; (ii) glioma establishment, proliferation and invasion; (iii) microglia/macrophage (M/Mφ) activation; (iv) natural killer (NK) cell infiltration and activation; and (v) cerebral levels of IL-15 and BDNF. Direct infusion of IL-15 or BDNF in the brain of mice transplanted with glioma significantly reduces tumour growth. We demonstrate that brain infusion of IL-15 increases the frequency of NK cell infiltrating the tumour and that NK cell depletion reduces the efficacy of EE and IL-15 on tumour size and of EE on mice survival. BDNF infusion reduces M/Mφ infiltration and CD68 immunoreactivity in tumour mass and reduces glioma migration inhibiting the small G protein RhoA through the truncated TrkB.T1 receptor. These results suggest alternative approaches for glioma treatment.

Melanin-concentrating hormone regulates beat frequency of ependymal cilia and ventricular volume

Ependymal cell cilia help move cerebrospinal fluid through the cerebral ventricles, but the regulation of their beat frequency remains unclear. Using in vitro, high-speed video microscopy and in vivo magnetic resonance imaging in mice, we found that the metabolic peptide melanin-concentrating hormone (MCH) positively controlled cilia beat frequency, specifically in the ventral third ventricle, whereas a lack of MCH receptor provoked a ventricular size increase.

Visualizing early splenic memory CD8+ T cells reactivation against intracellular bacteria in the mouse.

Memory CD8+ T cells represent an important effector arm of the immune response in maintaining long-lived protective immunity against viruses and some intracellular bacteria such as Listeria monocytogenes (L.m). Memory CD8+ T cells are endowed with enhanced antimicrobial effector functions that perfectly tail them to rapidly eradicate invading pathogens. It is largely accepted that these functions are sufficient to explain how memory CD8+ T cells can mediate rapid protection. However, it is important to point out that such improved functional features would be useless if memory cells were unable to rapidly find the pathogen loaded/infected cells within the infected organ. Growing evidences suggest that the anatomy of secondary lymphoid organs (SLOs) fosters the cellular interactions required to initiate naive adaptive immune responses. However, very little is known on how the SLOs structures regulate memory immune responses. Using Listeria monocytogenes (L.m) as a murine infection model and imaging techniques, we have investigated if and how the architecture of the spleen plays a role in the reactivation of memory CD8+ T cells and the subsequent control of L.m growth. We observed that in the mouse, memory CD8+ T cells start to control L.m burden 6 hours after the challenge infection. At this very early time point, L.m-specific and non-specific memory CD8+ T cells localize in the splenic red pulp and form clusters around L.m infected cells while naïve CD8+ T cells remain in the white pulp. Within these clusters that only last few hours, memory CD8+ T produce inflammatory cytokines such as IFN-γ and CCL3 nearby infected myeloid cells known to be crucial for L.m killing. Altogether, we describe how memory CD8+ T cells trafficking properties and the splenic micro-anatomy conjugate to create a spatio-temporal window during which memory CD8+ T cells provide a local response by secreting effector molecules around infected cells.

Splenic CD8α+ dendritic cells undergo rapid programming by cytosolic bacteria and inflammation to induce protective CD8+ T-cell memory

Memory CD8+ T lymphocytes are critical effector cells of the adaptive immune system mediating long‐lived pathogen‐specific protective immunity. Three signals – antigen, costimulation and inflammation – orchestrate optimal CD8+ T‐cell priming and differentiation into effector and memory cells and shape T‐cell functional fate and ability to protect against challenge infections. While among the conventional spleen DCs (cDCs), the CD8α+ but not the CD8α− cDCs most efficiently mediate CD8+ T‐cell priming, it is unclear which subset, irrespective of their capacity to process MHC class I‐associated antigens, is most efficient at inducing naïve CD8+ T‐cell differentiation into pathogen‐specific protective memory cells in vivo. Moreover, the origin of the required signals is still unclear. Using mice infected with the intracellular bacterium Listeria monocytogenes, we show that splenic CD8α+ cDCs become endowed with all functional features to optimally prime protective memory CD8+ T cells in vivo within only a few hours post‐immunization. Such programming requires both cytosolic signals resulting from bacterial invasion of the host cells and extracellular inflammatory mediators. Thus, these data designate these cells as the best candidates to facilitate the development of cell‐based vaccine therapy.

Melanin-concentrating hormone induces neurite outgrowth in human neuroblastoma SH-SY5Y cells through p53 and MAPKinase signaling pathways

Melanin-concentrating hormone (MCH) peptide plays a major role in energy homeostasis regulation. Little is known about cellular functions engaged by endogenous MCH receptor (MCH-R1). Here, MCH-R1 mRNA and cognate protein were found expressed in human neuroblastoma SH-SY5Y cells. Electrophysiological experiments demonstrated that MCH modulated K(+) currents, an effect depending upon the time of cellular growth. MCH treatments induced a transient phosphorylation of MAPKinases, abolished by PD98059, and partially blocked by PTX, suggesting a Galphai/Galphao protein contribution. MCH stimulated expression and likely nuclear localization of phosphorylated p53 proteins, an effect fully dependent upon MAPKinase activities. MCH treatment also increased phosphorylation of Elk-1 and up-regulated Egr-1, two transcriptional factors targeted by the MAPKinase pathway. Finally, MCH provoked neurite outgrowth after 24h-treatment of neuroblastoma cells. This effect and transcriptional factors activation were partly prevented by PD98059. Collectively, our results provide the first evidence for a role of MCH in neuronal differentiation of endogenously MCH-R1-expressing cells via non-exclusive MAPKinase and p53 signaling pathways.

Mixing and matching TREK/TRAAK subunits generate heterodimeric K2P channels with unique properties

Significance Nearly 350 human genes encode ion channels. Posttranscriptional (alternative splicing, editing, and alternative translation initiation) and posttranslational mechanisms (glycosylation, phosphorylation) further increase diversity. For multimeric channels, various heteromeric combinations may raise the number of ion channels to thousands. Here, we show that mixing and matching TWIK1-related K+ (TREK)/Twik-related acid-arachidonic activated K+ channel (TRAAK) subunits generate tens of different channels. Heterodimeric combinations have properties different from those of the corresponding homodimers, including single-channel behavior, regulation by kinases, and sensitivity to pharmacological agents. These results imply that any excitable cell can adjust its response to neurotransmitters by simply modulating the ratio of expressed TREK/TRAAK subunits. These results also imply that heteromerization has to be considered when analyzing in vivo functions of these channels but also when screening new potential therapeutic drugs. The tandem of pore domain in a weak inwardly rectifying K+ channel (Twik)-related acid-arachidonic activated K+ channel (TRAAK) and Twik-related K+ channels (TREK) 1 and TREK2 are active as homodimers gated by stretch, fatty acids, pH, and G protein-coupled receptors. These two-pore domain potassium (K2P) channels are broadly expressed in the nervous system where they control excitability. TREK/TRAAK KO mice display altered phenotypes related to nociception, neuroprotection afforded by polyunsaturated fatty acids, learning and memory, mood control, and sensitivity to general anesthetics. These channels have emerged as promising targets for the development of new classes of anesthetics, analgesics, antidepressants, neuroprotective agents, and drugs against addiction. Here, we show that the TREK1, TREK2, and TRAAK subunits assemble and form active heterodimeric channels with electrophysiological, regulatory, and pharmacological properties different from those of homodimeric channels. Heteromerization occurs between all TREK variants produced by alternative splicing and alternative translation initiation. These results unveil a previously unexpected diversity of K2P channels that will be challenging to analyze in vivo, but which opens new perspectives for the development of clinically relevant drugs.

Peribacteroid space acidification: a marker of mature bacteroid functioning in Medicago truncatula nodules.

Legumes form a symbiotic interaction with Rhizobiaceae bacteria, which differentiate into nitrogen-fixing bacteroids within nodules. Here, we investigated in vivo the pH of the peribacteroid space (PBS) surrounding the bacteroid and pH variation throughout symbiosis. In vivo confocal microscopy investigations, using acidotropic probes, demonstrated the acidic state of the PBS. In planta analysis of nodule senescence induced by distinct biological processes drastically increased PBS pH in the N2 -fixing zone (zone III). Therefore, the PBS acidification observed in mature bacteroids can be considered as a marker of bacteroid N2 fixation. Using a pH-sensitive ratiometric probe, PBS pH was measured in vivo during the whole symbiotic process. We showed a progressive acidification of the PBS from the bacteroid release up to the onset of N2 fixation. Genetic and pharmacological approaches were conducted and led to disruption of the PBS acidification. Altogether, our findings shed light on the role of PBS pH of mature bacteroids in nodule functioning, providing new tools to monitor in vivo bacteroid physiology.