RESUMEN
The macrophage mannose receptor (RMM) is a crucial component of the immune system involved in immune responses, inflammation resolution, and tissue remodeling. When RMM is activated by a specific ligand, it undergoes internalization, forming an endosome that matures into a lysosome. Within the lysosome, structural changes in RMM facilitate the dissociation of ligands for further processing. However, the precise details of these structural changes are not well understood. In this study, we used molecular dynamics simulations to investigate the conformational dynamics of a specific region called CRD4 in RMM. Our simulations explored different conditions, including pH variations and the presence of Ca2+ ions. By analyzing the simulation data, we found that conformational changes primarily occur in loop regions, while the secondary structure remains stable. The binding site of CRD4, essential for ligand interaction, is located on the protein surface between two specific loop regions. Ligand binding is stabilized by three important amino acids. Interestingly, the interaction patterns differ between monosaccharide and disaccharide ligands. These findings improve our understanding of CRD4's dynamics and how it recognizes ligands. They provide insights into the structure of CRD4 and its role in ligand dissociation within lysosomes. The study also highlights the significance of loop regions in functional dynamics and interactions. Further research is needed to fully uncover the complete structure of CRD4, understand ligand binding modes, and explore the influence of environmental factors. This study lays the foundation for future investigations targeting carbohydrate-protein interactions and the development of therapeutics based on RMM's unique properties.Communicated by Ramaswamy H. Sarma.
RESUMEN
Background: Acetone is present in the earth´s atmosphere and extra-terrestrially. The knowledge of its chemical history in these environments represents a challenge with important implications for global tropospheric chemistry and astrochemistry. The results of a search for efficient barrierless pathways producing acetone from radicals in the gas phase are described in this paper. The spectroscopic properties of radicals needed for their experimental detection are provided. Methods: The reactants were acetone fragments of low stability and small species containing C, O and H atoms. Two exergonic bimolecular addition reactions involving the radicals CH 3, CH 3CO, and CH 3COCH 2, were found to be competitive according to the kinetic rates calculated at different temperatures. An extensive spectroscopic study of the radicals CH 3COCH 2 and CH 3CO, as well as the CH 2CHO isomer, was performed. Rovibrational parameters, anharmonic vibrational transitions, and excitations to the low-lying excited states are provided. For this purpose, RCCSD(T)-F12 and MRCI/CASSCF calculations were performed. In addition, since all the species presented non-rigid properties, a variational procedure of reduced dimensionality was employed to explore the far infrared region. Results: The internal rotation barriers were determined to be V 3=143.7 cm -1 (CH 3CO), V 2=3838.7 cm -1 (CH 2CHO) and V 3=161.4 cm -1 and V 2=2727.5 cm -1 (CH 3COCH 2).The splitting of the ground vibrational state due to the torsional barrier have been computed to be 2.997 cm -1, 0.0 cm -1, and 0.320 cm -1, for CH 3CO, CH 2CHO, and CH 3COCH 2, respectively. Conclusions: Two addition reactions, H+CH 3COCH 2 and CH 3+CH 3CO, could be considered barrierless formation processes of acetone after considering all the possible formation routes, starting from 58 selected reactants, which are fragments of the molecule. The spectroscopic study of the radicals involved in the formation processes present non-rigidity. The interconversion of their equilibrium geometries has important spectroscopic effects on CH 3CO and CH 3COCH 2, but is negligible for CH 2CHO.
RESUMEN
Magnetic Ni0.7Co0.3Fe2O4 nanoparticles that were prepared via the rapid combustion process were functionalized and modified to obtain magnetic Ni0.7Co0.3Fe2O4@SiO2-CHO nanocomposites, on which penicillin G acylase (PGA) was covalently immobilized. Selections of immobilization concentration and time of fixation were explored. Catalytic performance of immobilized PGA was characterized. The free PGA had greatest activity at pH 8.0 and 45oC while immobilized PGA's a ctivities peaked a t pH 7.5 and 45°C. Immobilized PGA had better thermal stability than free PGA at the range of 30-50°C for different time intervals. The activity of free PGA would be 0 and that of immobilized PGA still retained some activities at 60°C after 2 h. Vmax and Km of immobilized PGA were 1.55 mol/min and 0.15 mol/l, respectively. Free PGA's Vmax and Km separately were 0.74 mol/min and 0.028 mol/l. Immobilized PGA displayed more than 50% activity after 10 successive cycles. We concluded that immobilized PGA with magnetic Ni0.7Co0.3Fe2O4@SiO2-CHO nanocomposites could become a novel example for the immobilization of other amidohydrolases.