Association of poly I:C RNA and plasmid DNA onto MnO nanorods mediated by PAMAM.

In this study, manganese oxide (MnO) nanorods and its association with polyamidoamine dendrimer (PAMAM) and macromolecular RNA were analyzed. Because manganese is found naturally in cells and tissues and binds proteins and nucleic acids, nanomaterials derived from manganese, such as first generation MnO, may have potential as a biocompatible delivery agent for therapeutic or diagnostic biomedical applications. Nucleic acids have a powerful influence over cell processes, such as gene transcription and RNA processing; however, macromolecular RNA is particularly difficult to stabilize as a nanoparticle and to transport across cell membranes while maintaining structure and function. PAMAM is a cationic, branching dendrimer known to form strong complexes with nucleic acids and to protect them from degradation and is also considered to be a cell penetrating material. There is currently much interest in polyinosinic:polycytidylic RNA (poly I:C) because of its potent and specific immunogenic properties and as a solo or combination therapy. In order to address this potential, here, as a first step, we used PAMAM to attach poly I:C onto MnO nanorods. Morphology of the MnO nanorods was examined by field emission scanning electron microscopy (FESEM) and their composition by energy dispersive X-ray microanalysis (EDX). Evidence was generated for RNA:PAMAM:MnO nanorod binding by a gel shift assay using gel electrophoresis, a sedimentation assay using UV spectroscopy, and zeta potential shifts using dynamic laser light scattering. The data suggest that RNA was successfully attached to the MnO nanorods using PAMAM, and this suggestion was supported by direct visualization of the ternary complexes with FESEM characterizations. In order to confirm that the associations were biocompatible and taken up by cells, MTT assays were carried out to assess the metabolic activity of HeLa cells after incubation with the complexes and appropriate controls. Subsequently, we performed transfection assays using PAMAM:MnO complexes with pDNA encoding a green fluorescent protein reporter gene instead of RNA. The results suggest that the complexes had minimal impact on metabolic activity and were readily taken up by cells, and the fluorescent protein was expressed. From the evidence, we conclude that complexes of PAMAM:MnO interact with nucleic acids to form associations that are well-tolerated and readily taken up by cells.

CSGID Solves Structures and Identifies Phenotypes for Five Enzymes in Toxoplasma gondii.

Toxoplasma gondii, an Apicomplexan parasite, causes significant morbidity and mortality, including severe disease in immunocompromised hosts and devastating congenital disease, with no effective treatment for the bradyzoite stage. To address this, we used the Tropical Disease Research database, crystallography, molecular modeling, and antisense to identify and characterize a range of potential therapeutic targets for toxoplasmosis. Phosphoglycerate mutase II (PGMII), nucleoside diphosphate kinase (NDK), ribulose phosphate 3-epimerase (RPE), ribose-5-phosphate isomerase (RPI), and ornithine aminotransferase (OAT) were structurally characterized. Crystallography revealed insights into the overall structure, protein oligomeric states and molecular details of active sites important for ligand recognition. Literature and molecular modeling suggested potential inhibitors and druggability. The targets were further studied with vivoPMO to interrupt enzyme synthesis, identifying the targets as potentially important to parasitic replication and, therefore, of therapeutic interest. Targeted vivoPMO resulted in statistically significant perturbation of parasite replication without concomitant host cell toxicity, consistent with a previous CRISPR/Cas9 screen showing PGM, RPE, and RPI contribute to parasite fitness. PGM, RPE, and RPI have the greatest promise for affecting replication in tachyzoites. These targets are shared between other medically important parasites and may have wider therapeutic potential.

Structure of the Essential Mtb FadD32 Enzyme: A Promising Drug Target for Treating Tuberculosis.

Mycolic acids are indispensible lipids of Mycobacterium tuberculosis (Mtb), the causative agent of tuberculosis (TB), and contribute to the distinctive architecture and impermeability of the mycobacterial cell envelope. FadD32 plays a pivotal role in mycolic acid biosynthesis by functionally linking fatty acid synthase (FAS) and polyketide synthase (PKS) biosynthetic pathways. FadD32, a fatty acyl-AMP ligase (FAAL), represents one of the best genetically and chemically validated new TB drug targets. We have determined the three-dimensional crystal structure of Mtb FadD32 in complex with a ligand specifically designed to stabilize the catalytically active adenylate-conformation, which provides a foundation for structure-based drug design efforts against this essential protein. The structure also captures the unique interactions of a FAAL-specific insertion sequence and provides insight into the specificity and mechanism of fatty acid transfer.