Disease suppressive soils typically develop after a disease outbreak due to the subsequent assembly of protective microbiota in the rhizosphere. The role of the plant immune system in the assemblage of a protective rhizosphere microbiome is largely unknown. In this study, we demonstrate that Arabidopsis thaliana specifically promotes three bacterial species in the rhizosphere upon foliar defense activation by the downy mildew pathogen Hyaloperonospora arabidopsidis. The promoted bacteria were isolated and found to interact synergistically in biofilm formation in vitro. Although separately these bacteria did not affect the plant significantly, together they induced systemic resistance against downy mildew and promoted growth of the plant. Moreover, we show that the soil-mediated legacy of a primary population of downy mildew infected plants confers enhanced protection against this pathogen in a second population of plants growing in the same soil. Together our results indicate that plants can adjust their root microbiome upon pathogen infection and specifically recruit a group of disease resistance-inducing and growth-promoting beneficial microbes, therewith potentially maximizing the chance of survival of their offspring that will grow in the same soil.
This study investigated the presence of specific drug-excipient interactions in amorphous solid dispersions of lapatinib (LB) and four commonly used pharmaceutical polymers, including Soluplus, polyvinylpyrrolidone vinyl acetate (PVPVA), hydroxypropylmethylcellulose acetate succinate (HPMCAS), and hydroxypropylmethylcellulose phthalate (HPMCP). Based on predicted pKa differences, LB was hypothesized to exhibit a specific ionic interaction with HPMCP, and possibly with HPMCAS, while Soluplus and PVPVA were studied as controls without ionizable functionality. Thermal studies showed a single glass transition (Tg) for each dispersion, in close agreement with predicted values for Soluplus, PVPVA, and HPMCAS systems. However, the Tg values of LB-HPMCP solid dispersions were markedly higher than predicted values, indicating a strong intermolecular interaction between LB and HPMCP. (15)N solid-state NMR provided direct spectroscopic evidence for protonation of LB (i.e., salt formation) within the HPMCP solid dispersions. (1)H T1 and (1)H T1ρ relaxation studies of the dispersions supported the ionic interaction hypothesis, and indicated multiple phases in the cases of excess drug or polymer. In addition, the dissolution and stability behavior of each system was examined. Both acidic polymers, HPMCAS and HPMCP, effectively inhibited the crystallization of LB on accelerated stability, likely owing to beneficial strong intermolecular hydrogen and/or specific ionic bonds with the acidic polymers. Soluplus and PVPVA showed poor physical properties on stability and subsequently poor crystallization inhibition.
It has been technically challenging to specify the detailed molecular interactions and binding motif between drugs and polymeric inhibitors in the solid state. To further investigate drug-polymer interactions from a molecular perspective, a solid dispersion of clofazimine (CLF) and hypromellose phthalate (HPMCP), with reported superior amorphous drug loading capacity and physical stability, was selected as a model system. The CLF-HPMCP interactions in solid dispersions were investigated by various solid state spectroscopic methods including ultraviolet-visible (UV-vis), infrared (IR), and solid-state NMR (ssNMR) spectroscopy. Significant spectral changes suggest that protonated CLF is ionically bonded to the carboxylate from the phthalyl substituents of HPMCP. In addition, multivariate analysis of spectra was applied to optimize the concentration of polymeric inhibitor used to formulate the amorphous solid dispersions. Most interestingly, proton transfer between CLF and carboxylic acid was experimentally investigated from 2D H-H homonuclear double quantum NMR spectra by utilizing the ultrafast magic-angle spinning (MAS) technique. The molecular interaction pattern and the critical bonding structure in CLF-HPMCP dispersions were further delineated by successfully correlating ssNMR findings with quantum chemistry calculations. These high-resolution investigations provide critical structural information on active pharmaceutical ingredient-polymer interaction, which can be useful for rational selection of appropriate polymeric carriers, which are effective crystallization inhibitors for amorphous drugs.
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