New glucosamine-based TLR4 agonists: design, synthesis, mechanism of action, and in vivo activity as vaccine adjuvants

20 p.-15 fig.-1 graph. abst.We disclose here a panel of small-molecule TLR4 agonists (the FP20 series) whose structure is derived from previously developed TLR4 ligands (FP18 series). The new molecules have increased chemical stability and a shorter, more efficient, and scalable synthesis. The FP20 series showed selective activity as TLR4 agonists with a potency similar to FP18. Interestingly, despite the chemical similarity with the FP18 series, FP20 showed a different mechanism of action and immunofluorescence microscopy showed no NF-κB nor p-IRF-3 nuclear translocation but rather MAPK and NLRP3-dependent inflammasome activation. The computational studies related a 3D shape of FP20 series with agonist binding properties inside the MD-2 pocket. FP20 displayed a CMC value lower than 5 μM in water, and small unilamellar vesicle (SUV) formation was observed in the biological activity concentration range. FP20 showed no toxicity in mouse vaccination experiments with OVA antigen and induced IgG production, thus indicating a promising adjuvant activity.The authors acknowledge the European Union’s Horizon 2020 research and innovation program under the Marie Skłodowska-Curie, project BactiVax (www.bactivax.eu) grant agreement no. 860325; the consortium CINMPIS; the project of excellence CHRONOS, CHRonical multifactorial disorders explored by NOvel integrated Strategies of the Department of Biotechnology and Biosciences; the Agencia Estatal de Investigacion (Spain) for project PID2021-126130OB-I00 (N.G.A.A.), PID2020-113588RB-I00 (S.M.-S.), PRE2018-086249 (A.M.-R), PRE2021-097247 (M.M.-T.); and project FEDER MINECO, the EM-platform at the CIC bioGUNE for support in cryo-EM imaging. J.J.-B. also thanks funding by CIBERES, an initiative of Instituto de Salud Carlos III (ISCIII), Madrid, Spain. Perkin-Elmer Italia is also acknowledged for providing the cell imaging reagents.Peer reviewe

Determination of energy level alignment at metal/molecule interfaces by in-device electrical spectroscopy

The energetics of metal/molecular semiconductor interfaces plays a fundamental role in organic electronics, determining the performance of very diverse devices. So far, information about the energy level alignment has been most commonly gained by spectroscopy techniques that typically require experimental conditions far from the real device operation. Here we demonstrate that a simple three-terminal device allows the acquisition of spectroscopic information about the metal/molecule energy alignment in real operative condition. As a proof of principle, we employ the proposed device to measure the energy barrier height between different clean metals and C60 molecules and we recover typical results from photoemission spectroscopy. The device is designed to inject a hot electron current directly into the molecular level devoted to charge transport, disentangling the contributions of both the interface and the bulk to the device total resistance, with important implications for spintronics and low-temperature physics.Fil: Gobbi, M.. CIC nanoGUNE; España. Université de Strasbourg; FranciaFil: Pietrobon, L.. CIC nanoGUNE; EspañaFil: Atxabal, A.. CIC nanoGUNE; EspañaFil: Bedoya Pinto, A.. CIC nanoGUNE; EspañaFil: Sun, X.. CIC nanoGUNE; EspañaFil: Golmar, Federico. CIC nanoGUNE; España. Instituto Nacional de Tecnología Industrial; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas; ArgentinaFil: Llopis, R.. CIC nanoGUNE; EspañaFil: Casanova, F.. CIC nanoGUNE; España. Fundación Vasca para la Ciencia; EspañaFil: Hueso, L. E.. CIC nanoGUNE; España. Fundación Vasca para la Ciencia; Españ

Tuning the charge flow between Marcus regimes in an organic thin-film device

AbstractMarcus’s theory of electron transfer, initially formulated six decades ago for redox reactions in solution, is now of great importance for very diverse scientific communities. The molecular scale tunability of electronic properties renders organic semiconductor materials in principle an ideal platform to test this theory. However, the demonstration of charge transfer in different Marcus regions requires a precise control over the driving force acting on the charge carriers. Here, we make use of a three-terminal hot-electron molecular transistor, which lets us access unconventional transport regimes. Thanks to the control of the injection energy of hot carriers in the molecular thin film we induce an effective negative differential resistance state that is a direct consequence of the Marcus Inverted Region.</jats:p

Bis(triisopropylsilylethynyl)-substituted pyrene-fused tetraazaheptacene: synthesis and properties

The synthesis and characterisation of pyrene-fused tetraazaheptacene that is constituted of two terminal pyrene units and a central tetraazaanthracene core are reported.</p