On-demand assembly of macromolecules used for the design and application of targeted secretion inhibitors

Neurological and endocrine pathologies such as acromegalie, Cushing’s disease, and neuropathic pain display disregulated exocytosis. Silencing specific cell populations would thus be invaluable to correct these debilitating disorders. To achieve this goal, we reengineered the Botulinum neurotoxin (BoT), a highly potent pharmaceutical compound capable of inhibiting exocytosis, and fused to it a protein “stapling” domain [1,2]. These peptide motifs, that form an irreversible tetrahelical coiled-coil, are able to link a variety of targeting domains onto the enzyme and thus redirect it towards normally unaffected cells. The conformational diversity of this assembly process greatly supersedes traditional protein expression since multiple targeting domains (homo- and hetero-) can be linked onto one scaffold, larger yields can be produced separately, it permits the combination of solid-phase peptide synthesis with recombinant protein expression, and it can avoid the necessity of an N- to C- translational fusion. With only a few dozen building “blocks” it is possible to construct thousands of different complexes specifically tailored for each purpose as every individual component can be linked onto any other cognate stapling moieties

SNARE based peptide linking as an efficient strategy to retarget botulinum neurotoxin’s enzymatic domain to specific neurons using diverse neuropeptides as targeting domains

Many disease states are caused by miss-regulated neurotransmission. A small fraction of these diseases can currently be treated with botulinum neurotoxin type A (BoNT/A). BoNT/A is composed of three functional domains – the light chain (Lc) is a zinc metalloprotease that cleaves intracellular SNAP25 which inhibits exocytosis, the translocation domain (Td) that enables the export of the light chain from the endosome to the cytosol, and the receptor binding domain (Rbd) that binds to extracellular gangliosides and synaptic vesicle glycoproteins while awaiting internalisation [1]. Current endeavours are directed towards retargeting Bont/A as well as finding safer methods of preparation and administration. Recently, our laboratory has developed a SNARE based linking strategy to recombine non-toxic BoNT/A fragments into a functional protein by simple mixing [2]. This SNARE based linking strategy permits the stepwise assembly of highly stable macromolecular complexes [2,3]. Onto these three SNARE peptides, diverse functional groups can be attached to the N- or C- terminus by direct synthesis and/or by genetic design. To enhance the therapeutic potential of BoNT/A, this method enables the rapid assembly of a large array of neuropeptide-SNAREs to their cognate LcTd-SNARE. A substitution of the Rbd with various neuropeptide sequences permits a large throughput combinatorial assay of LcTd to target new cell types. In this study, we have fused LcTd to 3 different Synaptobrevin sequences; we also use a small protein staple, and 26 different Syntaxin-neuropeptide fusions (permitting the assay of 78 new chimeric LcTd proteins with modified targeting domains). These neuropeptides such as, but not exclusively, somatostatin (SS), vasoactive intestinal peptide, substance P, opioid peptide analogues, Gonadotropin releasing hormone, and Arginine Vasopressin, which natively function through G protein coupled receptors (GPCR) can undergo agonist induced internalisation upon activation. The ability of our new constructs, once endocytosed, to inhibit neurotransmitter release was tested on different neuronal cell lines with immunoblotting of endogenous SNAP25. This cleavage by Lc reflects the ultimate readout of the enzyme’s efficacy, which incorporates the cell surface binding, internalisation kinetics, translocation of the Lc to the cytosol, and finally the enzymatic cleavage of SNAP25. Internalisation of the toxins can also be monitored with confocal microscopy and FACS by the substitution of the staple peptide for a fluorescent homologue. Figure 1 shows that whole boNT/A (upper left) can have its Rbd replaced with SNARE peptides, which will fuse together to form highly stable chimeric proteins with an altered targeting domain (right). Figure 1 also shows 4 different neuropeptide synthaxins in complex, resolved on SDS-PAGE gel (bottom left lanes 1-4, boiled 1’-4’). Fig. 1. SNARE-linked botulinum neurotoxins used for the retargeting of Bont/A. 29

Le photomarquage en fonction de la température du récepteur d'angiotensine II de type 1 mène à une meilleure compréhension du mécanisme d'activation

Les récepteurs couplés aux protéines G (RCPG) sont réfractaires à l'application efficace des méthodes structurales pour étudier la structure 3D du complexe récepteur-ligands. Nous présentons une nouvelle méthode basée sur l'analyse de l'interaction ligand-RCPG à différentes températures avec le photomarquage par affinité exploitant des ligands contenant le photomarqueur pBenzoyl-L-phénylalanine (Bpa). Cette approche nous a permis de générer un modèle du complexe du récepteur d'angiotensine H de type 1 (hAT [indice inférieur 1] ) avec le [Sar [indice supérieur 1] , Bpa [indice supérieur 8] AngII à plus haute résolution et aussi d'identifier des différences conformationnelles entre la forme active et la forme inactive du récepteur. Notre laboratoire a démontré que la position 8 du [indice supérieur 125] I-[Sar [indice supérieur 1] , Bpa [indice supérieur 8] AngII formait un lien covalent avec le domaine transmembranaire 7 (DTM7) dans hAT [indice inférieur 1] . Le Bpa, qui a une sélectivité réactionnelle pour les méthionines (Met), était ambigue dans son rayon d'action variable. Néanmoins, cette sélectivité a permis d'élaborer l'essai de proximité aux Met (MPA). La température de photomarquage a été subséquemment identifiée comme un facteur important à contrôler dans les études de photomarquage. En étudiant ainsi les mutants Met positifs en MPA du récepteur hAT 1 , nous avons observé des changements importants lors de l'interaction ligand-récepteur en fonction de la température. A basse température, les fluctuations conformationnelles du complexe ligand-récepteur sont minimisées. Inversement, à 37 [degrés Celsius], le complexe démontre une flexibilité structurale très importante.Les analyses de ces résidus photomarqués suivis d'une digestion au CNBr'démontrent que l'accessibilité aux Met augmente proportionnellement avec la température. Ensuite, en photomarquant le mutant constitutivement actif, le N111G-hAT [indice inférieur 1] , nous pouvons comparer les différences entre une forme basale et une forme plus active du récepteur.Les résultats sont quantifiés en un ratio du marquage Met/DTMVII et ceci nous donne un indice d'accessibilité entre le ligand et le résidu muté dans hAT [indice inférieur 1] . Nous avons observé des différences thermodépendantes entre ces ratios d'accessibilités des mutants X[arrow right]Met et N111G/X[arrow right]Met. Ces ratios d'accessibilités ont été transformés en distance et insérés comme contraintes dans la modélisation moléculaire par refondu simulée. Nous voyons dans le récepteur un éloignement du haut du DTMVI, un rapprochement du DTMII et V et un petit déplacement du DTMIII lors de l'activation.Les différences dans les structures sont à la base des mécanismes d'activations d'hAT [indice inférieur 1] et des RCPGs en général

Cleaved intracellular SNARE peptides are implicated in a novel cytotoxicity mechanism of botulinum serotype C

Recent advances in intracellular protein delivery have enabled more in-depth analyses of cellular functions. A specialized family of SNARE proteases, known as Botulinum Neurotoxins, blocks neurotransmitter exocytosis, which leads to systemic toxicity caused by flaccid paralysis. These pharmaceutically valuable enzymes have also been helpful in the study of SNARE functions. As can be seen in Figure 1A, SNARE bundle formation causes vesicle docking at the presynapse. Although these toxins are systemically toxic, no known cytotoxic effects have been reported with the curious exception of the Botulinum serotype C [1]. This enzyme cleaves intracellular SNAP25, as does serotype A and E, but also, exceptionally, cleaves Syntaxin 1. Using an array of lipid and polymer transfection reagents we were able to deliver different combinations of Botulinum holoenzymes into the normally unaffected, Neuro2A, SH-SY5Y, PC12, and Min6 cells to analyze the individual contribution of each SNARE protein and their cleaved peptide products

Selective neuronal silencing using synthetic botulinum molecules alleviates chronic pain in mice

Chronic pain is a widespread debilitating condition affecting millions of people worldwide. Although several pharmacological treatments for relieving chronic pain have been developed, they require frequent chronic administration and are often associated with severe adverse events, including overdose and addiction. Persistent increased sensitization of neuronal subpopulations of the peripheral and central nervous system has been recognized as a central mechanism mediating chronic pain, suggesting that inhibition of specific neuronal subpopulations might produce antinociceptive effects. We leveraged the neurotoxic properties of the botulinum toxin to specifically silence key pain-processing neurons in the spinal cords of mice. We show that a single intrathecal injection of botulinum toxin conjugates produced long-lasting pain relief in mouse models of inflammatory and neuropathic pain without toxic side effects. Our results suggest that this strategy might be a safe and effective approach for relieving chronic pain while avoiding the adverse events associated with repeated chronic drug administration

Data Assimilation Enhancements to Air Force Weathers Land Information System

The United States Air Force (USAF) has a proud and storied tradition of enabling significant advancements in the area of characterizing and modeling land state information. 557th Weather Wing (557 WW; DoDs Executive Agent for Land Information) provides routine geospatial intelligence information to warfighters, planners, and decision makers at all echelons and services of the U.S. military, government and intelligence community. 557 WW and its predecessors have been home to the DoDs only operational regional and global land data analysis systems since January 1958. As a trusted partner since 2005, Air Force Weather (AFW) has relied on the Hydrological Sciences Laboratory at NASA/GSFC to lead the interagency scientific collaboration known as the Land Information System (LIS). LIS is an advanced software framework for high performance land surface modeling and data assimilation of geospatial intelligence (GEOINT) information

Assembly of Protein Building Blocks Using a Short Synthetic Peptide

Combining proteins or their defined domains offers new enhanced functions. Conventionally, two proteins are either fused into a single polypeptide chain by recombinant means or chemically cross-linked. However, these strategies can have drawbacks such as poor expression (recombinant fusions) or aggregation and inactivation (chemical cross-linking), especially in the case of large multifunctional proteins. We developed a new linking method which allows site-oriented, noncovalent, yet irreversible stapling of modified proteins at neutral pH and ambient temperature. This method is based on two distinct polypeptide linkers which self-assemble in the presence of a specific peptide staple allowing on-demand and irreversible combination of protein domains. Here we show that linkers can either be expressed or be chemically conjugated to proteins of interest, depending on the source of the proteins. We also show that the peptide staple can be shortened to 24 amino acids still permitting an irreversible combination of functional proteins. The versatility of this modular technique is demonstrated by stapling a variety of proteins either in solution or to surfaces

The SPARC Toroidal Field Model Coil Program

The SPARC Toroidal Field Model Coil (TFMC) Program was a three-year effort between 2018 and 2021 that developed novel Rare Earth Yttrium Barium Copper Oxide (REBCO) superconductor technologies and then successfully utilized these technologies to design, build, and test a first-in-class, high-field (~20 T), representative-scale (~3 m) superconducting toroidal field coil. With the principal objective of demonstrating mature, large-scale, REBCO magnets, the project was executed jointly by the MIT Plasma Science and Fusion Center (PSFC) and Commonwealth Fusion Systems (CFS). The TFMC achieved its programmatic goal of experimentally demonstrating a large-scale high-field REBCO magnet, achieving 20.1 T peak field-on-conductor with 40.5 kA of terminal current, 815 kN/m of Lorentz loading on the REBCO stacks, and almost 1 GPa of mechanical stress accommodated by the structural case. Fifteen internal demountable pancake-to-pancake joints operated in the 0.5 to 2.0 nOhm range at 20 K and in magnetic fields up to 12 T. The DC and AC electromagnetic performance of the magnet, predicted by new advances in high-fidelity computational models, was confirmed in two test campaigns while the massively parallel, single-pass, pressure-vessel style coolant scheme capable of large heat removal was validated. The REBCO current lead and feeder system was experimentally qualified up to 50 kA, and the crycooler based cryogenic system provided 600 W of cooling power at 20 K with mass flow rates up to 70 g/s at a maximum design pressure of 20 bar-a for the test campaigns. Finally, the feasibility of using passive, self-protection against a quench in a fusion-scale NI TF coil was experimentally assessed with an intentional open-circuit quench at 31.5 kA terminal current.Comment: 17 pages 9 figures, overview paper and the first of a six-part series of papers covering the TFMC Progra