The underlying cause of major cardiovascular events, such as myocardial infarctions and strokes, is atherosclerosis. For accurate diagnosis of this inflammatory disease, molecular imaging is required. Toward this goal, we sought to develop a nanoparticle-based, high aspect ratio, molecularly targeted magnetic resonance MR imaging contrast agent. Specifically, we engineered the plant viral nanoparticle platform tobacco mosaic virus (TMV) to target vascular cell adhesion molecule (VCAM)-1, which is highly expressed on activated endothelial cells at atherosclerotic plaques. To achieve dual optical and MR imaging in an atherosclerotic ApoE−/− mouse model, TMV was modified to carry near-infrared dyes and chelated Gd ions. Our results indicate molecular targeting of atherosclerotic plaques. On the basis of the multivalency and multifunctionality, the targeted TMV-based MR probe increased the detection limit significantly; the injected dose of Gd ions could be further reduced by 3 orders of magnitude compared to the suggested clinical use, demonstrating the utility of targeted nanoparticle cargo delivery.
Viral nanoparticles (VNPs) are a novel class of bionanomaterials that harness the natural biocompatibility of viruses for the development of therapeutics, vaccines, and imaging tools. The plant virus, cowpea mosaic virus (CPMV), has been successfully engineered to create novel cancer-targeted imaging agents by incorporating fluorescent dyes, polyethylene glycol (PEG) polymers, and targeting moieties. Using straightforward conjugation strategies, VNPs with high selectivity for cancer-specific molecular targets can be synthesized for in vivo imaging of tumors. Here we describe the synthesis and purification of CPMV-based VNPs, the functionalization of these VNPs using click chemistry, and their use for imaging xenograft tumors in animal models. VNPs decorated with fluorescent dyes, PEG, and targeting ligands can be synthesized in one day, and imaging studies can be performed over hours, days, or weeks, depending on the application.
The sequence of the P (phosphoprotein) gene of mumps virus has been determined. It has two open reading frames, the first of which probably encodes the NSI (or V) protein of mumps virus. Expression of the P protein requires the insertion of two non-templated residues to link the two ORFs in a process analogous to that observed in the P/V gene of simian virus type 5 to which mumps virus is closely related. Strain differences in the accuracy of insertion of non-templated G residues in the P/V gene transcripts have been described.
Histidine is a convenient tridentate chelator used in the synthesis of technetium-99m radiopharmaceuticals, as it can be pendantly attached to a biomolecule for molecular imaging applications. Once coordinated, it forms a neutral complex that is capable of forming diastereomers at the alpha amine of the histidine. This is demonstrated through the synthesis and characterization of four different histidine chelators; three small molecule chelators, which consist of a benzylated histidine at the alpha amine, and one modified dipeptide, containing a phenylalanine derivative at the C-terminus and a histidine at the N-terminus. Upon rhenium coordination, two products are observed, each having the desired exact mass of the metal-containing species. The two products have been characterized through LC-MS, (1)H, gCOSY, NOESY and ROESY NMR experiments, and the relative stereochemistry determined. The implications of diastereomer formation when using this chelation system for creating molecular imaging agents is also discussed.
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