Lamina propria of IBD patients in the context of a cellular-based therapy. Importantly, weconfirm for the first time that this protocol could be used for the production of tol-DCs from Crohn’s disease patients, in line with studies in other immune-based diseases like rheumatoid arthritis [47] or multiple sclerosis [48]. This is a key aspect for considering this form of cell therapy in Crohn’s disease, because it might have occurred that genetic variants conferring susceptibility for Crohn’s disease might alter the biology of DCs. In conclusion, we herein report that DCs generated by 25033180 the addition of dexamethasone in combination with a cocktail of proinflammatory cytokines yield clinical-grade DCs with tolerogenic properties. Tol-DCs remain stable after Gram-negative bacteria interaction. These properties may serve as the basis for modulating abnormal immune responses and for developing effective strategies for the treatment of immune-mediated diseases.AcknowledgmentsWe would like to thank Dr. Xavier Romero Ros and Dr. Elisabeth Calderon-Gomez for discussion and critical reading of the manuscript and ??the DC.CAT group (the Catalan group for DCs studies) for suggestions. We would like to thank Dr. Jordi Vila and Elisabet Guiral for providing the microorganisms Tunicamycin site included in this study.Author ContributionsConceived and designed the experiments: RC JP DB-R. Performed the experiments: RC CE DB-R. Analyzed the data: RC ER JP DB-R. Wrote the paper: RC JP DB-R.
Computational protein design has advanced rapidly in recent years. A particularly exciting and dynamic area is the design of interactions between proteins and small molecule ligands. This includes the design of receptors that bind ligands of choice, which for example can be used as biosensors [1], as well as the design of enzymes that do not only bind a substrate, but also contain the catalytic machinery to process it [2?]. In all these designs, an existing protein is used as a scaffold, and its 47931-85-1 binding pocket is altered or a new one is introduced that should interact with the target ligand. With this approach, enzymes have been designed that catalyze chemical reactions for which no natural catalysts exist, such as a kemp eliminase [4?], a diels-alderase [6], and a retro-aldolase [7]. It has also been used to design a metalloenzyme by repurposing parts of the already existing catalytic machinery in the scaffold protein, namely the reactivity of a zinc metal center to hydrolyze organophosphates [8]. Furthermore, similar methods have been applied to change substrate specificities as well asaffinities. For example human guanine deaminase was changed to bind ammelide through the remodeling of a loop that now provides a key interaction to the new target substrate [9], the substrate specificity of gramicidin S synthetase was changed from phenylalanine to leucine [10], and mutations in dihydrofolate reductase from Staphylococcus aureus were predicted that decrease binding to an inhibitor molecule while stabilizing native protein function [11]. While these are impressive results, there is still much room for improvement in the computational methods. Specifically, it seems to be difficult to accurately design a protein for high affinity binding to a ligand or transition state [12]. The majority of the enzyme designs mentioned have low affinities for their substrates when compared to naturally occurring enzymes [13?4]. In a rare report of a failed attempt, the unsuccessful design of a high-affinity l.Lamina propria of IBD patients in the context of a cellular-based therapy. Importantly, weconfirm for the first time that this protocol could be used for the production of tol-DCs from Crohn’s disease patients, in line with studies in other immune-based diseases like rheumatoid arthritis [47] or multiple sclerosis [48]. This is a key aspect for considering this form of cell therapy in Crohn’s disease, because it might have occurred that genetic variants conferring susceptibility for Crohn’s disease might alter the biology of DCs. In conclusion, we herein report that DCs generated by 25033180 the addition of dexamethasone in combination with a cocktail of proinflammatory cytokines yield clinical-grade DCs with tolerogenic properties. Tol-DCs remain stable after Gram-negative bacteria interaction. These properties may serve as the basis for modulating abnormal immune responses and for developing effective strategies for the treatment of immune-mediated diseases.AcknowledgmentsWe would like to thank Dr. Xavier Romero Ros and Dr. Elisabeth Calderon-Gomez for discussion and critical reading of the manuscript and ??the DC.CAT group (the Catalan group for DCs studies) for suggestions. We would like to thank Dr. Jordi Vila and Elisabet Guiral for providing the microorganisms included in this study.Author ContributionsConceived and designed the experiments: RC JP DB-R. Performed the experiments: RC CE DB-R. Analyzed the data: RC ER JP DB-R. Wrote the paper: RC JP DB-R.
Computational protein design has advanced rapidly in recent years. A particularly exciting and dynamic area is the design of interactions between proteins and small molecule ligands. This includes the design of receptors that bind ligands of choice, which for example can be used as biosensors [1], as well as the design of enzymes that do not only bind a substrate, but also contain the catalytic machinery to process it [2?]. In all these designs, an existing protein is used as a scaffold, and its binding pocket is altered or a new one is introduced that should interact with the target ligand. With this approach, enzymes have been designed that catalyze chemical reactions for which no natural catalysts exist, such as a kemp eliminase [4?], a diels-alderase [6], and a retro-aldolase [7]. It has also been used to design a metalloenzyme by repurposing parts of the already existing catalytic machinery in the scaffold protein, namely the reactivity of a zinc metal center to hydrolyze organophosphates [8]. Furthermore, similar methods have been applied to change substrate specificities as well asaffinities. For example human guanine deaminase was changed to bind ammelide through the remodeling of a loop that now provides a key interaction to the new target substrate [9], the substrate specificity of gramicidin S synthetase was changed from phenylalanine to leucine [10], and mutations in dihydrofolate reductase from Staphylococcus aureus were predicted that decrease binding to an inhibitor molecule while stabilizing native protein function [11]. While these are impressive results, there is still much room for improvement in the computational methods. Specifically, it seems to be difficult to accurately design a protein for high affinity binding to a ligand or transition state [12]. The majority of the enzyme designs mentioned have low affinities for their substrates when compared to naturally occurring enzymes [13?4]. In a rare report of a failed attempt, the unsuccessful design of a high-affinity l.
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