Inhibiting the cGAS-STING Pathway in Ulcerative Colitis with Programmable Micelles.

Ulcerative colitis is a chronic condition in which a dysregulated immune response contributes to the acute intestinal inflammation of the colon. Current clinical therapies often exhibit limited efficacy and undesirable side effects. Here, programmable nanomicelles were designed for colitis treatment and loaded with RU.521, an inhibitor of the cyclic GMP-AMP synthase-stimulator of interferon genes (cGAS-STING) pathway. STING-inhibiting micelles (SIMs) comprise hyaluronic acid-stearic acid conjugates and include a reactive oxygen species (ROS)-responsive thioketal linker. SIMs were designed to selectively accumulate at the site of inflammation and trigger drug release in the presence of ROS. Our in vitro studies in macrophages and in vivo studies in a murine model of colitis demonstrated that SIMs leverage HA-CD44 binding to target sites of inflammation. Oral delivery of SIMs to mice in both preventive and delayed therapeutic models ameliorated colitis's severity by reducing STING expression, suppressing the secretion of proinflammatory cytokines, enabling bodyweight recovery, protecting mice from colon shortening, and restoring colonic epithelium. In vivo end points combined with metabolomics identified key metabolites with a therapeutic role in reducing intestinal and mucosal inflammation. Our findings highlight the significance of programmable delivery platforms that downregulate inflammatory pathways at the intestinal mucosa for managing inflammatory bowel diseases.

A multi-organ maize metabolic model connects temperature stress with energy production and reducing power generation.

Climate change has adversely affected maize productivity. Thereby, a holistic understanding of metabolic crosstalk among its organs is important to address this issue. Thus, we reconstructed the first multi-organ maize metabolic model, iZMA6517, and contextualized it with heat and cold stress transcriptomics data using expression distributed reaction flux measurement (EXTREAM) algorithm. Furthermore, implementing metabolic bottleneck analysis on contextualized models revealed differences between these stresses. While both stresses had reducing power bottlenecks, heat stress had additional energy generation bottlenecks. We also performed thermodynamic driving force analysis, revealing thermodynamics-reducing power-energy generation axis dictating the nature of temperature stress responses. Thus, a temperature-tolerant maize ideotype can be engineered by leveraging the proposed thermodynamics-reducing power-energy generation axis. We experimentally inoculated maize root with a beneficial mycorrhizal fungus, Rhizophagus irregularis, and as a proof-of-concept demonstrated its efficacy in alleviating temperature stress. Overall, this study will guide the engineering effort of temperature stress-tolerant maize ideotypes.

Relation between glycosidic linkage, structure and dynamics of α- and ß-glucans in water.

In a molecular dynamics simulation study of several oligosaccharides comprising of the very basic building block of carbohydrate, the α- or ß-d glucopyranose units, linked by any one of the 1-3/1-4 or 1-6 glycosidic linkages, we compare and contrast their structural and dynamical properties. Results indicate that the litheness of the oligosaccharide chain is noticeably controlled by the composition, anomeric nature and glycosidic linkage type of the units. In mixed ß 1-4/1-3 d-glucopyranosides, as those found in oats and barley, the ratio of the ß 1-4 and ß 1-3 linked residues is crucial in determining the structural and dynamical attributes. Principal component analysis (PCA) using the internal coordinates of torsion angles subtended by glycosidic oxygen atoms and subsequent K-means clustering of the dynamical space spanned by PC1 to PC2 point to the dynamical and structural disparity in the various types of oligosaccharides studied. The properties simulated in this work are meant to provide a systematic yet comparative understanding of the importance of linkage and anomericity on the oligosaccharide chain properties and are in line with some experimental structural attributes.

Principal Component Analysis of a Conotoxin Delineates the Link among Peptide Sequence, Dynamics, and Disulfide Bond Isoforms.

Replica exchange molecular dynamics (REMD) and subsequent principal component analysis (PCA) of the dynamical modes of α-conotoxins, GI and its two mutants, in water and an aqueous biocompatible ionic liquid, 1-ethyl-3-methyl-imidazolium acetate (50%, v/v), provide perceptions into how the mutations affect the global correlated motions in the peptide backbone, eventually ending up influencing the combination of disulfide links in such multiple cysteine-containing venom toxins. Region-wise breakup of the contribution of the three peptides to the first two principal components (PCs) reveals disparate dynamical patterns in water and a water-ionic liquid mixture. Additionally, K-means clustering within the conformation space spanned by PC1 and PC2 compares and contrasts the different peptide-solvent systems, sorting further the disulfide bond isoforms into specific clusters. In each cluster, and also in a particular disulfide bond isoform, an estimation of the amino acid block loadings toward PC1 and PC2 helps relate the mutations in the GI sequence to targeted synthesis of a given isoform in a given solvent system.

Peptide Sequence and Solvent as Levers to Control Disulfide Connectivity in Multiple Cysteine Containing Venom Toxins.

Judicious choice of solvent, temperature, and strategic mutations along a peptide backbone can minimize formation of non-native disulfide bond isoforms in chemical synthesis of multiple cysteine containing venom toxins. By exploiting these controls, one can drive the population distribution in favor of a particular isoform. Some chosen ionic liquids (ILs), like 1-ethyl-3-methyl-imidazolium acetate, [Im21][OAc], have proven efficient in favoring the native globular isoform in some conotoxins. To comprehend such a preference, we report an explicit solvent replica exchange molecular dynamics (REMD) study of two conotoxins, AuIB and GI, solvated in either neat water or ∼50% (v/v) mixture of water-[Im21][OAc]. Our simulations indicate that compared to neat water, the probability of obtaining native globular isoform of AuIB significantly increases in a water-IL mixture at 305 K. Strikingly, and aligned with experimental observations, peptide GI does not favor the native connectivity in the water-IL mixture. In presence of IL, strong solvent mediated fluctuations of the GI backbone are observed in our simulations. Uneven ion accumulation along the backbone owing to strong H-bonding interactions of some GI residues with IL ions, especially the anion OAc-, restricts conformational freedom of the peptide. Estimation of backbone entropy and Helmholtz free energy corroborates the lack of conformational freedom in GI as compared to AuIB, especially in the presence of IL. In line with prior experiments, simulations of GI mutants indicate that one could possibly force a given pair of Cys residues to come closer by strategically mutating GI residues with glycine and/or alanine, resulting in the breakage/formation of helix-like motifs.

Aqueous ionic liquids influence the disulfide bond isoform equilibrium in conotoxin AuIB: a consequence of the Hofmeister effect?

The appearance of several disulfide bond isoforms in multiple cysteine containing venom peptides poses a significant challenge in their synthesis and purification under laboratory conditions. Recent experiments suggest that careful tuning of solvent and temperature conditions can propel the disulfide bond isoform equilibrium in favor of the most potent, native form. Certain aqueous ionic liquids (ILs) have proven significantly useful as solvents for this purpose, while exceptions have also been noted. To elucidate the molecular level origin behind such a preference, we report a detailed explicit solvent replica exchange molecular dynamics study of a conotoxin, AuIB, in pure water and four different aqueous IL solutions (~45-60% v/v). The ILs studied here are comprised of cations like 1-ethyl-3-methyl-imidazolium (Im21+) or 1-butyl-3-methyl-imidazolium (Im41+) coupled with either acetate (OAc-) or chloride (Cl-) as the counter anion. Our simulations unfold interesting features of the conformational spaces sampled by the peptide and its solvation in pure water and aqueous IL solutions. Detailed investigation into populations of the globular disulfide bond isoform of AuIB in aqueous IL solutions reveal distinct trends which might be related to the Hofmeister effect of the cation and anion of the IL and of specific interactions of the aqueous IL solutions with the peptide. In accordance with experimental observations, the aqueous [Im21][OAc] solution is found to promote the highest globular isoform population in AuIB.

Temperature-dependent molecular dynamics study reveals an ionic liquid induced 310 - to α-helical switch in a neurotoxin.

Thermal melting and recooling of AuIB, a neurotoxic conopeptide and a highly potent nonaddictive pain reliever is investigated thoroughly in water and an ionic liquid (IL) 1-butyl-3-methylimidazolium Chloride, [Im41 ][Cl] by classical molecular dynamics simulations. Structural evolution of AuIB in water and the IL is observed at different temperatures between 305 and 400 K, to explore how highly viscous ionic solvents affect the peptide structure as compared to conventional solvent water. At 305 K, unlike water, the coercive effect of IL frustrates AuIB secondary structural motifs significantly. As the temperature is raised, a very interesting IL induced conformational transition from 310 - to α-helix is noticed in the peptide, presumably triggered by a significant restructuring of the peptide H-bond network. The backbone length distributions of the peptide indicate that the IL induced conformational switching is accompanied by a reduction of the axial rise of the helical region, encompassing the residues Pro-6 to Ala-10. Further, we estimated the void space available to the peptide for its structural relaxation within the first solvation shell of ∼5 Å in water as well as in IL. A temperature increase by 100 K, opens up an estimated void volume of ∼70 Å3 , equivalent to the volume of approximately six water molecules, around the peptide in IL. Cooling simulations of AuIB point to the crucial interplay between thermodynamically favored AuIB conformers and their kinetic control. This study provides a comprehensive understanding of the ionic solvation of biomolecules reinforcing previous experimental findings.