The Glutathione Metabolite γ-Glutamyl-Glutamate Partially Activates Glutamate NMDA Receptors in Central Neurons With Higher Efficacy for GluN2B-Containing Receptors.

Gamma-L-glutamyl-L-glutamate (γ-Glu-Glu) was synthetized and further characterized for its activity on cultured neurons. We observed that γ-Glu-Glu elicited excitatory effects on neurons likely by activating mainly the N-methyl-D-aspartate (NMDA) receptors. These effects were dependent on the integrity of synaptic transmission as they were blocked by tetrodotoxin (TTX). We next evaluated its activity on NMDA receptors by testing it on cells expressing these receptors. We observed that γ-Glu-Glu partially activated NMDA receptors and exhibited better efficacy for NMDA receptors containing the GluN2B subunit. Moreover, at low concentration, γ-Glu-Glu potentiated the responses of glutamate on NMDA receptors. Finally, the endogenous production of γ-Glu-Glu was measured by LC-MS on the extracellular medium of C6 rat astroglioma cells. We found that extracellular γ-Glu-Glu concentration was, to some extent, directly linked to GSH metabolism as γ-Glu-Glu can be a by-product of glutathione (GSH) breakdown after γ-glutamyl transferase action. Therefore, γ-Glu-Glu could exert excitatory effects by activating neuronal NMDA receptors when GSH production is enhanced.

Manipulations of Glutathione Metabolism Modulate IP3-Mediated Store-Operated Ca2+ Entry on Astroglioma Cell Line.

The regulation of the redox status involves the activation of intracellular pathways as Nrf2 which provides hormetic adaptations against oxidative stress in response to environmental stimuli. In the brain, Nrf2 activation upregulates the formation of glutathione (GSH) which is the primary antioxidant system mainly produced by astrocytes. Astrocytes have also been shown to be themselves the target of oxidative stress. However, how changes in the redox status itself could impact the intracellular Ca2+ homeostasis in astrocytes is not known, although this could be of great help to understand the neuronal damage caused by oxidative stress. Indeed, intracellular Ca2+ changes in astrocytes are crucial for their regulatory actions on neuronal networks. We have manipulated GSH concentration in astroglioma cells with selective inhibitors and activators of the enzymes involved in the GSH cycle and analyzed how this could modify Ca2+ homeostasis. IP3-mediated store-operated calcium entry (SOCE), obtained after store depletion elicited by Gq-linked purinergic P2Y receptors activation, are either sensitized or desensitized, following GSH depletion or increase, respectively. The desensitization may involve decreased expression of the proteins STIM2, Orai1, and Orai3 which support SOCE mechanism. The sensitization process revealed by exposing cells to oxidative stress likely involves the increase in the activity of Calcium Release-Activated Channels (CRAC) and/or in their membrane expression. In addition, we observe that GSH depletion drastically impacts P2Y receptor-mediated changes in membrane currents, as evidenced by large increases in Ca2+-dependent K+ currents. We conclude that changes in the redox status of astrocytes could dramatically modify Ca2+ responses to Gq-linked GPCR activation in both directions, by impacting store-dependent Ca2+-channels, and thus modify cellular excitability under purinergic stimulation.

Proteotranscriptomic Insights into the Venom Composition of the Wolf Spider Lycosa tarantula.

Spider venoms represent an original source of novel compounds with therapeutic and agrochemical potential. Whereas most of the research efforts have focused on large mygalomorph spiders, araneomorph spiders are equally promising but require more sensitive and sophisticated approaches given their limited size and reduced venom yield. Belonging to the latter group, the genus Lycosa ("wolf spiders") contains many species widely distributed throughout the world. These spiders are ambush predators that do not build webs but instead rely strongly on their venom for prey capture. Lycosa tarantula is one of the largest species of wolf spider, but its venom composition is unknown. Using a combination of RNA sequencing of the venom glands and venom proteomics, we provide the first overview of the peptides and proteins produced by this iconic Mediterranean spider. Beside the typical small disulfide rich neurotoxins, several families of proteins were also identified, including cysteine-rich secretory proteins (CRISP) and Hyaluronidases. Proteomic analysis of the electrically stimulated venom validated 30 of these transcriptomic sequences, including nine putative neurotoxins and eight venom proteins. Interestingly, LC-MS venom profiles of manual versus electric stimulation, as well as female versus male, showed some marked differences in mass distribution. Finally, we also present some preliminary data on the biological activity of L. tarantula crude venom.

Targeting TMEM176B Enhances Antitumor Immunity and Augments the Efficacy of Immune Checkpoint Blockers by Unleashing Inflammasome Activation.

Although immune checkpoint blockers have yielded significant clinical benefits in patients with different malignancies, the efficacy of these therapies is still limited. Here, we show that disruption of transmembrane protein 176B (TMEM176B) contributes to CD8+ T cell-mediated tumor growth inhibition by unleashing inflammasome activation. Lack of Tmem176b enhances the antitumor activity of anti-CTLA-4 antibodies through mechanisms involving caspase-1/IL-1ß activation. Accordingly, patients responding to checkpoint blockade therapies display an activated inflammasome signature. Finally, we identify BayK8644 as a potent TMEM176B inhibitor that promotes CD8+ T cell-mediated tumor control and reinforces the antitumor activity of both anti-CTLA-4 and anti-PD-1 antibodies. Thus, pharmacologic de-repression of the inflammasome by targeting TMEM176B may enhance the therapeutic efficacy of immune checkpoint blockers.

Ion selectivity of pore-forming peptides and ion channels measured in Xenopus oocytes.

The Xenopus laevis oocyte is a widely used system for heterologous expression of exogenous ion channel proteins. They are easy to obtain, mechanically and electrically stable, have a large size, enabling multiple types of electrophysiological recordings: two-electrode voltage clamp, single cell-attached or cell-free patch-clamp and macropatch recordings. The size of an oocyte (1 mm in diameter) also allows for the use of additional electrodes (from 1 to 3) for injection of diverse materials (Ca(2+) chelators, peptides, chemicals, antibodies, proteic-partners, etc.) before or during the course of the electrophysiological experiment.We have successfully used this system to analyze the biophysical properties of pore-forming peptides. Simple extracellular perfusion of these peptides induced the formation of channels in the oocyte plasma membrane; these channels can then be studied and characterized in diverse ionic conditions. The ease of the perfusion and the stability of the voltage-clamped oocyte make it a powerful tool for such analyses. Compared to artificial bilayers, oocytes offer a real animal plasma membrane where biophysical properties and toxicity can be studied in the stable environment.

Inorganic phosphate export by the retrovirus receptor XPR1 in metazoans.

Inorganic phosphate uptake is a universal function accomplished by transporters that are present across the living world. In contrast, no phosphate exporter has ever been identified in metazoans. Here, we show that depletion of XPR1, a multipass membrane molecule initially identified as the cell-surface receptor for xenotropic and polytropic murine leukemia retroviruses (X- and P-MLV), induced a decrease in phosphate export and that reintroduction of various XPR1 proteins, from fruit fly to human, rescued this defect. Inhibition of phosphate export was also obtained with a soluble ligand generated from the envelope-receptor-binding domain of X-MLV in all human cell lines tested, as well as in diverse stem cells and epithelial cells derived from renal proximal tubules, the main site of phosphate homeostasis regulation. These results provide new insights on phosphate export in metazoans and the role of Xpr1 in this function.

Use of Xenopus oocytes to measure ionic selectivity of pore-forming peptides and ion channels.

The Xenopus laevis oocyte is a widely used system for heterologous expression of exogenous ion channel proteins (1, 2). Among other advantages, these easy to obtain, mechanically and electrically stable, large-sized cells enable multiple types of electrophysiological recordings: two-electrode voltage-clamp, single-cell attached or cell-free patch-clamp, and macropatch recordings. The size of an oocyte (1 mm in diameter) also allows the use of additional electrodes (1-3) for injection of diverse materials (Ca2+ chelators, peptides, chemicals, antibodies, proteic-partners, and so on) before or during the course of the electrophysiological experiment. We have successfully used this system to analyze the biophysical properties of pore-forming peptides. Simple perfusion of these peptides induced the formation of channels in the oocyte plasma membrane; these channels can then be studied and characterized in diverse ionic conditions. The ease of the perfusion and the stability of the voltage-clamped oocyte make it a powerful tool for such analyses. Compared with artificial bilayers, oocytes offer a real animal plasma membrane where biophysical properties and toxicity can be studied in the same environment.

Formation of transmembrane ionic channels of primary amphipathic cell-penetrating peptides. Consequences on the mechanism of cell penetration.

The ability of three primary amphipathic Cell-Penetrating Peptides (CPPs) CH3-CO-GALFLGFLGAAGSTMGAWSQPKKKRKV-NH-CH2-CH2-SH, CH3-CO-GALFLAFLAAALS LMGLWSQPKKKRKV-NH-CH2-CH2-SH, and CH3-CO-KETWWETWWTEWSQPKKKRKV-NH-CH2-CH2-SH called Pbeta, Palpha and Pep-1, respectively, to promote pore formation is examined both in Xenopus oocytes and artificial planar lipid bilayers. A good correlation between pore formation and their structural properties, especially their conformational versatility, was established. This work shows that the cell-penetrating peptides Pbeta and Pep-1 are able to induce formation of transmembrane pores in artificial bilayers and that these pores are most likely at the basis of their ability to facilitate intracellular delivery of therapeutics. In addition, their behaviour provides some information concerning the positioning of the peptides with respect to the membrane and confirms the role of the membrane potential in the translocation process.

[Structure of the calcium channel beta subunit: the place of the beta-interaction domain]. / Structure de la sous-unité bêta du canal calcique: la place du beta-interaction domain.

Voltage-gated calcium channels are key players in a number of fundamental physiological functions including contraction, secretion, transmitter release or gene activation. They allow a flux of calcium into the cell that constitutes a switch-on signal for most of these functions. The structures responsible for the shaping of these fluxes by the membrane voltage belong to the channel itself, but a number of associated proteins are known to more precisely tune this calcium entry and adapt it to the cellular demand. The calcium channel regulatory beta subunit is undoubtedly the most important one, being influent on the expression, the kinetics, the voltage-dependence of channel opening and closing and on the pharmacology of the channel. Heterologous expression, combined to mutagenesis and electrophysiological and biochemical experiments have revealed the roles of short sequences of the beta subunit, including the BID (beta-interaction domain), in the physical and functional interactions with the channel pore. The resolved crystal structure of the beta subunit now sheds new light on these sequences and their interactions with the rest of the protein. The presence of a type 3 src-homology (SH3) domain and a guanylate kinase (GK) domain confirms that the subunit belongs to the MAGUK protein family. Consistently, the polyproline binding site and the kinase function of the SH3 and the GK domains, respectively, are non functional, and the BID appears to be buried in the structure, preserving the SH3-GK interaction but not directly available for interactions with the channel pore subunit. Anchoring of the beta subunit to the channel occurs via a hydrophobic grove in the GK domain, leaving a large surface of the subunit open to other protein-protein interactions. To what extent the intramolecular SH3-GK interaction is necessary for the stabilisation of this grove in a functional unit remains to be understood. The beta subunit may thus play a key role in scaffolding multiple proteins around the channel and organizing diverse calcium-dependent signalling pathways directly linked to voltage-gated calcium entry. These findings will undoubtedly vitalize the search for new beta-specific partners and functions.

On the mechanism of non-endosomial peptide-mediated cellular delivery of nucleic acids.

Recently, we described a new strategy for the delivery of nucleic acids into mammalian cells, based on an amphipathic peptide of 27 residues called MPG, which was designed on the basis of a hydrophobic domain derived from a fusion sequence associated with a nuclear localization sequence and separated by a linker. This peptide carrier constitutes a powerful tool for the delivery of nucleic acids in cultured cells, without requiring any covalent coupling. We have examined the conformational states of MPG in its free form and complexed with a cargo, as well as its ability to interact with phospholipids, and have investigated the structural consequences of these interactions. In spite of its similarity to the similarly designed cell-penetrating peptide Pep-1, MPG behaves significantly differently from the conformational point of view. Circular dichroism (CD) analysis reveals a transition from a nonstructured to a beta-sheet conformation upon interaction with phospholipids. We propose that the membrane crossing process involves formation of a transient transmembrane pore-like structure. Partial conformational change of MPG is associated with formation of a complex with its cargo, and an increase in sheet content occurs upon association with the cell membrane.

Insight into the mechanism of internalization of the cell-penetrating carrier peptide Pep-1 through conformational analysis.

Recently, we described a new strategy for the delivery of proteins and peptides into mammalian cells, based on an amphipathic peptide of 21 residues, Pep-1, which was designed on the basis of a protein-interacting domain associated with a nuclear localization sequence and separated by a linker. This peptide carrier constitutes a powerful tool for the delivery of active proteins or peptides both in cultured cells and in vivo, without requiring any covalent coupling. We have examined the conformational states of Pep-1 in its free form and complexed with a cargo peptide and have investigated their ability to interact with phospholipids and the structural consequences of these interactions. From the conformational point of view, Pep-1 behaves significantly differently from other similarly designed cell-penetrating peptides. CD analysis revealed a transition from a nonstructured to a helical conformation upon increase of the concentration. Determination of the structure by NMR showed that in water, its alpha-helical domain extends from residues 4-13. CD and FTIR indicate that Pep-1 adopts a helical conformation in the presence of phospholipids. Adsorption measurements performed at the air-water interface are consistent with the helical form. Pep-1 does not undergo conformational changes upon formation of a particle with a cargo peptide. In contrast, we observe a partial conformational transition when the complex encounters phospholipids. We propose that the membrane crossing process involves formation of a transient transmembrane pore-like structure. Conformational change of Pep-1 is not associated with complexation with its cargo but is induced upon association with the cell membrane.

Puroindolines form ion channels in biological membranes.

Wheat seeds contain different lipid binding proteins that are low molecular mass, basic and cystine-rich proteins. Among them, the recently characterized puroindolines have been shown to inhibit the growth of fungi in vitro and to enhance the fungal resistance of plants. Experimental data, using lipid vesicles, suggest that this antimicrobial activity is related to interactions with cellular membranes, but the underlying mechanisms are still unknown. This paper shows that extracellular application of puroindolines on voltage-clamped Xenopus laevis oocytes induced membrane permeabilization. Electrophysiological experiments, on oocytes and artificial planar lipid bilayers, suggest the formation, modulated by voltage, of cation channels with the following selectivity: Cs(+) > K(+) > Na(+) > Li(+) > choline = TEA. Furthermore, this channel activity was prevented by addition of Ca(2+) ions in the medium. Puroindolines were also able to decrease the long-term oocyte viability in a voltage-dependent manner. Taken together, these results indicate that channel formation is one of the mechanisms by which puroindolines exert their antimicrobial activity. Modulation of channel formation by voltage, Ca(2+), and lipids could introduce some selectivity in the action of puroindolines on natural membranes.