A cell-penetrating artificial metalloenzyme regulates a gene switch in a designer mammalian cell

Complementing enzymes in their native environment with either homogeneous or heterogeneous catalysts is challenging due to the sea of functionalities present within a cell. To supplement these efforts, artificial metalloenzymes are drawing attention as they combine attractive features of both homogeneous catalysts and enzymes. Herein we show that such hybrid catalysts consisting of a metal cofactor, a cell-penetrating module, and a protein scaffold are taken up into HEK-293T cells where they catalyze the uncaging of a hormone. This bioorthogonal reaction causes the upregulation of a gene circuit, which in turn leads to the expression of a nanoluc-luciferase. Relying on the biotin-streptavidin technology, variation of the biotinylated ruthenium complex: the biotinylated cell-penetrating poly(disulfide) ratio can be combined with point mutations on streptavidin to optimize the catalytic uncaging of an allyl-carbamate-protected thyroid hormone triiodothyronine. These results demonstrate that artificial metalloenzymes offer highly modular tools to perform bioorthogonal catalysis in live HEK cells

Compensatory ion transport buffers daily protein rhythms to regulate osmotic balance and cellular physiology

Abstract: Between 6–20% of the cellular proteome is under circadian control and tunes mammalian cell function with daily environmental cycles. For cell viability, and to maintain volume within narrow limits, the daily variation in osmotic potential exerted by changes in the soluble proteome must be counterbalanced. The mechanisms and consequences of this osmotic compensation have not been investigated before. In cultured cells and in tissue we find that compensation involves electroneutral active transport of Na+, K+, and Cl− through differential activity of SLC12A family cotransporters. In cardiomyocytes ex vivo and in vivo, compensatory ion fluxes confer daily variation in electrical activity. Perturbation of soluble protein abundance has commensurate effects on ion composition and cellular function across the circadian cycle. Thus, circadian regulation of the proteome impacts ion homeostasis with substantial consequences for the physiology of electrically active cells such as cardiomyocytes

Ingénierie et auto-assemblage de systèmes biomoléculaires multivalents

Natural systems are inspiring in showing that the combination of multiple interactions enables improvement in binding affinity and selectivity for a target. Thus, the design of synthetic and biocompatible multivalent systems is of great importance for biological applications. The work described in this PhD thesis aims at developing novel methodologies for generating functional multivalent systems.In order to engineer multivalent systems for the recognition of oligonucleotides, we elaborated a multi-step synthesis of functionalized α-PNA scaffolds bearing side-groups. This new scaffold can potentially serve for the multi-point sequence-selective recognition of DNA.Multivalent nanoconstructs are emerging tools for enzyme inhibition. In this context, we prepared multivalent clusters of iminosugars – by metal-free click ligations on peptide scaffolds – as candidates for glycosidases inhibition. Although such enzyme inhibitors based on iminosugar clusters were recently reported, their synthesis relies almost exclusively on copper-catalyzed azide-alkyne cycloaddition, which notorious toxicity represents a serious limitation for biological applications. Our approach demonstrates that iminosugar clusters can be prepared in a metal-free fashion and exhibit strong multivalent effects for the inhibition of α-mannosidases.Multivalent biomolecular systems are also candidates for gene delivery application. In this context, the design of dynamic systems is of interest for achieving controlled release. We implemented a self-assembly strategy, using the acylhydrazone click ligation, for the in situ generation of biomolecular clusters starting from peptide scaffolds and modified amino acids building blocks. We showed that, whereas both compounds are ineffective for DNA complexation, the mixed system spontaneously expresses cationic clusters that effectively complex DNA. We further demonstrated that, given the dynamic character of the acylhydrazone ligation, the system is able to a) adapt to the presence of the DNA target by selecting the optimal building blocks for the cluster self-assembly, and b) trigger DNA release by component exchange. This modular and versatile self-assembly approach was further exploited to perform a fragments screening varying molecular structure and valency. Thereby, we identified new and effective vectors for the transfection of siRNA in living cells.The last project described in this manuscript deals with the generation of cage-type peptide nanoconstructs by using a set of orthogonal and chemoselective click ligations. Two cages, based on acylhydrazone ligation on one side and thiol-maleimide on the other, were obtained successfully in one-pot.In summary, this work has led to the development of novel methodologies for the engineering and self-assembly of multivalent biomolecular nanoconstructs for diverse biological applications such as oligonucleotide recognition, delivery and enzyme inhibition.Les systèmes naturels ont montré l'intérêt de la multiplication des interactions pour une cible, permettant d'améliorer l'affinité et de moduler la spécificité de reconnaissance. Il est ainsi important pour des applications biologiques de concevoir des systèmes multivalents et biocompatibles. Le travail entreprit au cours de ce doctorat porte sur le développement de nouvelles méthodologies pour accéder à des systèmes multivalents originaux.Ainsi, nous avons conçu, par synthèse multi-étapes, une nouvelle plate-forme fonctionnalisée, basée sur un châssis α-PNA pour la reconnaissance multivalente d'oligonucléotides. Ce nouveau système peut potentiellement être impliqué dans la reconnaissance sélective multipoint d'ADN.En parallèle, nous avons préparé des clusters multivalents d'iminosucres sur des châssis peptidiques, construits à partir de ligations click sans métaux, pour l'inhibition enzymatique de glycosidase. En effet, des systèmes multivalents ont été récemment développés en tant qu'inhibiteurs de glycosidase. Cependant, leur méthodologie de synthèse repose quasiment exclusivement sur la ligation azoture-alcyne catalysée au cuivre, ce qui limite son application biologique en raison de sa toxicité. Nos travaux ont ainsi conduit à l'identification d'inhibiteurs efficaces d’α-mannosidases par une approche synthétique sans métaux.Dans le contexte de la vectorisation d'oligonucléotides, il existe un besoin de concevoir des systèmes dynamiques qui permettent un relargage contrôlé. Nous avons appliqué une stratégie d'auto-assemblage, par ligation click de type acylhydrazone, pour la génération in situ de clusters biomoléculaires à partir de châssis peptidiques et de ligands d'acides aminés modifiés. Etant donné le caractère dynamique de la ligation qui confère une adaptabilité au système, nous avons démontré que a) la présence d'une cible permet d'assister la formation des clusters par sélection de certains composants et b) l'ADN peut être relargué par échange de ligands. Cette technique efficace et rapide d’auto-assemblage de fragments a ensuite permis de réaliser un criblage pour sonder l’effet de l’architecture et de la valence sur la complexation. Ce projet a finalement conduit à l'identification de vecteurs efficaces pour la transfection de siARN sur cellules.Enfin, dans un dernier projet, nous avons exploité diverses techniques orthogonales et chimiosélectives de ligations click dans le but de générer des nanostructures peptidiques. Deux cages ont ainsi été obtenues par la formation de ligations acylhydrazones et thiol-maléimides selon une approche one-pot.En résumé, ces travaux d'ingénierie et d'auto-assemblage de systèmes biomoléculaires multivalents ont permis le développement de méthodes innovantes pour répondre à des besoins d’actualité et permettre la construction de systèmes multivalents destinés à la reconnaissance d’oligonucléotides, la vectorisation et l’inhibition enzymatique

Engineering and self-assembly of multivalent biomolecular nanoconstructs

Les systèmes naturels ont montré l'intérêt de la multiplication des interactions pour une cible, permettant d'améliorer l'affinité et de moduler la spécificité de reconnaissance. Il est ainsi important pour des applications biologiques de concevoir des systèmes multivalents et biocompatibles. Le travail entreprit au cours de ce doctorat porte sur le développement de nouvelles méthodologies pour accéder à des systèmes multivalents originaux.Ainsi, nous avons conçu, par synthèse multi-étapes, une nouvelle plate-forme fonctionnalisée, basée sur un châssis α-PNA pour la reconnaissance multivalente d'oligonucléotides. Ce nouveau système peut potentiellement être impliqué dans la reconnaissance sélective multipoint d'ADN.En parallèle, nous avons préparé des clusters multivalents d'iminosucres sur des châssis peptidiques, construits à partir de ligations click sans métaux, pour l'inhibition enzymatique de glycosidases. En effet, des systèmes multivalents ont été récemment développés en tant qu'inhibiteurs de glycosidases. Cependant, leur méthodologie de synthèse repose quasiment exclusivement sur la ligation azoture-alcyne catalysée au cuivre, ce qui limite son application biologique en raison de sa toxicité. Nos travaux ont ainsi conduit à l'identification d'inhibiteurs efficaces d'α-mannosidases par une approche synthétique sans métaux.Dans le contexte de la vectorisation d'oligonucléotides, il existe un besoin de concevoir des systèmes dynamiques qui permettent un relargage contrôlé. Nous avons appliqué une stratégie d'auto-assemblage, par ligation click de type acylhydrazone, pour la génération in situ de clusters biomoléculaires à partir de châssis peptidiques et de ligands d'acides aminés modifiés. Etant donné le caractère dynamique de la ligation qui confère une adaptabilité au système, nous avons démontré que a) la présence d'une cible permet d'assister la formation des clusters par sélection de certains composants et b) l'ADN peut être relargué par échange de ligands. Cette technique efficace et rapide d'auto-assemblage de fragments a ensuite permis de réaliser un criblage pour sonder l'effet de l'architecture et de la valence sur la complexation. Ce projet a finalement conduit à l'identification de vecteurs efficace pour la transfection de siARN sur cellules.Enfin, dans un dernier projet, nous avons exploité diverses techniques orthogonales et chimiosélectives de ligations click dans le but de générer des nanostructures peptidiques. Deux cages ont ainsi été obtenues par la formation de ligations acylhydrazones et thiol-maléimides selon une approche one-pot.En résumé, ces travaux d'ingénierie et d'auto-assemblage de systèmes biomoléculaires multivalent ont permis le développement de méthodes innovantes pour répondre à des besoins d'actualité et permettre la construction de systèmes multivalents destinés à la reconnaissance d'oligonucléotides, la vectorisation et l'inhibition enzymatique.Natural systems are inspiring in showing that the combination of multiple interactions enables improvement in binding affinity and selectivity for a target. Thus, the design of synthetic and biocompatible multivalent systems is of great importance for biological applications. The work described in this PhD thesis aims at developing novel methodologies for generating functional multivalent systems.In order to engineer multivalent systems for the recognition of oligonucleotides, we elaborated a multi-step synthesis of functionalized α-PNA scaffolds bearing side-groups. This new scaffold can potentially serve for the multi-point sequence-selective recognition of DNA.Multivalent nanoconstructs are emerging tools for enzyme inhibition. In this context, we prepared multivalent clusters of iminosugars – by metal-free click ligations on peptide scaffolds – as candidates for glycosidases inhibition. Although such enzyme inhibitors based on iminosugar clusters were recently reported, their synthesis relies almost exclusively on copper-catalyzed azide-alkyne cycloaddition, which notorious toxicity represents a serious limitation for biological applications. Our approach demonstrates that iminosugar clusters can be prepared in a metal-free fashion and exhibit strong multivalent effects for the inhibition of α-mannosidases. Multivalent biomolecular systems are also candidates for gene delivery application. In this context, the design of dynamic systems is of interest for achieving controlled release. We implemented a self-assembly strategy, using the acylhydrazone click ligation, for the in situ generation of biomolecular clusters starting from peptide scaffolds and modified amino acids building blocks. We showed that, whereas both compounds are ineffective for DNA complexation, the mixed system spontaneously expresses cationic clusters that effectively complex DNA. We further demonstrated that, given the dynamic character of the acylhydrazone ligation, the system is able to a) adapt to the presence of the DNA target by selecting the optimal building blocks for the cluster self-assembly, and b) trigger DNA release by component exchange. This modular and versatile self-assembly approach was further exploited to perform a fragments screening varying molecular structure and valency. Thereby, we identified new and effective vectors for the transfection of siRNA in living cells.The last project described in this manuscript deals with the generation of cage-type peptide nanoconstructs by using a set of orthogonal and chemoselective click ligations. Two cages, based on acylhydrazone ligation on one side and thiol-maleimide on the other, were obtained successfully in one-pot.In summary, this work has led to the development of novel methodologies for the engineering and self-assembly of multivalent biomolecular nanoconstructs for diverse biological applications such as oligonucleotide recognition, delivery and enzyme inhibition

Glycosylated Cell-Penetrating Poly(disulfide)s: Multifunctional Cellular Uptake at High Solubility

The glycosylation of cell-penetrating poly(disulfide)s (CPDs) is introduced to increase the solubility of classical CPDs and to achieve multifunctional cellular uptake. With the recently developed sidechain engineering, CPDs decorated with α-d-glucose (Glu), β-d-galactose (Gal), d-trehalose (Tre), and triethyleneglycol (TEG) were readily accessible. Confocal laser scanning microscopy images of HeLa Kyoto cells incubated with the new CPDs at 2.5 μm revealed efficient uptake into cytosol and nucleoli of all glycosylated CPDs, whereas the original CPDs and TEGylated CPDs showed much precipitation into fluorescent aggregates at these high concentrations. Flow cytometry analysis identified Glu-CPDs as most active, closely followed by Gal-CPDs and Tre-CPDs, and all clearly more active than non-glycosylated CPDs. In the MTT assay, all glyco-CPDs were non-toxic at concentrations as high as 2.5 μm. Consistent with thiol-mediated uptake, glycosylated CPDs remained dependent on thiols on the cell surface for dynamic covalent exchange, their removal with Ellman's reagent DTNB efficiently inhibited uptake. Multifunctionality was demonstrated by inhibition of Glu-CPDs with d-glucose (IC50 ca. 20 mm). Insensitivity toward l-glucose and d-galactose and insensitivity of conventional CPDs toward d-glucose supported that glucose-mediated uptake of the multifunctional Glu-CPDs involves selective recognition by glucose receptors at the cell surface. Weaker but significant sensitivity of Gal-CPDs toward d-galactose but not d-glucose was noted (IC50 ca. 110 mm). Biotinylation of Glu-CPDs resulted in the efficient delivery of streptavidin together with a fluorescent model substrate. Protein delivery with Glu-CPDs was more efficient than with conventional CPDs and remained sensitive to DTNB and d-glucose, i.e., multifunctional

Epidithiodiketopiperazines : strain-promoted thiol-mediated cellular uptake at the highest tension

The disulfide dihedral angle in epidithiodiketopiperazines (ETPs) is near 0°. Application of this highest possible ring tension to strain-promoted thiol-mediated uptake results in efficient delivery to the cytosol and nucleus. Compared to the previous best asparagusic acid (AspA), ring-opening disulfide exchange with ETPs occurs more efficiently even with nonactivated thiols, and the resulting thiols exchange rapidly with nonactivated disulfides. ETP-mediated cellular uptake is more than 20 times more efficient compared to AspA, occurs without endosomal capture, depends on temperature, and is “unstoppable” by inhibitors of endocytosis and conventional thiol-mediated uptake, including siRNA against the transferrin receptor. These results suggest that ETP-mediated uptake not only maximizes delivery to the cytosol and nucleus but also opens the door to a new multitarget hopping mode of action

Efficient Delivery of Quantum Dots into the Cytosol of Cells Using Cell-Penetrating Poly(disulfide)s

Quantum dots (QDs) are extremely bright, photostable, nanometer particles broadly used to investigate single molecule dynamics <i>in vitro</i>. However, the use of QDs <i>in vivo</i> to investigate single molecule dynamics is impaired by the absence of an efficient way to chemically deliver them into the cytosol of cells. Indeed, current methods (using cell-penetrating peptides for instance) provide very low yields: QDs stay at the plasma membrane or are trapped in endosomes. Here, we introduce a technology based on cell-penetrating poly­(disulfide)­s that solves this problem: we deliver about 70 QDs per cell, and 90% appear to freely diffuse in the cytosol. Furthermore, these QDs can be functionalized, carrying GFP or anti-GFP nanobodies for instance. Our technology thus paves the way toward single molecule imaging in cells and living animals, allowing to probe biophysical properties of the cytosol

Efficient Delivery of Quantum Dots into the Cytosol of Cells Using Cell-Penetrating Poly(disulfide)s

Quantum dots (QDs) are extremely bright, photostable, nanometer particles broadly used to investigate single molecule dynamics <i>in vitro</i>. However, the use of QDs <i>in vivo</i> to investigate single molecule dynamics is impaired by the absence of an efficient way to chemically deliver them into the cytosol of cells. Indeed, current methods (using cell-penetrating peptides for instance) provide very low yields: QDs stay at the plasma membrane or are trapped in endosomes. Here, we introduce a technology based on cell-penetrating poly­(disulfide)­s that solves this problem: we deliver about 70 QDs per cell, and 90% appear to freely diffuse in the cytosol. Furthermore, these QDs can be functionalized, carrying GFP or anti-GFP nanobodies for instance. Our technology thus paves the way toward single molecule imaging in cells and living animals, allowing to probe biophysical properties of the cytosol