Database of articles cited by EMDB/PDB/SASBDB data

Keywords
Structure methods	All X-ray diffraction NMR electron microscopy small angle scattering neutron diffraction fiber diffraction powder diffraction infrared spectroscopy EPR fluorescence transfer theoretical model Hybrid
Author
Journal
IF	>30 >20 >10 >5 all

Title	Designed proteins induce the formation of nanocage-containing extracellular vesicles.
Journal, issue, pages	Nature, Vol. 540, Issue 7632, Page 292-295, Year 2016
Publish date	Dec 8, 2016
Authors	Jörg Votteler / Cassandra Ogohara / Sue Yi / Yang Hsia / Una Nattermann / David M Belnap / Neil P King / Wesley I Sundquist /
PubMed Abstract	Complex biological processes are often performed by self-organizing nanostructures comprising multiple classes of macromolecules, such as ribosomes (proteins and RNA) or enveloped viruses (proteins, ...Complex biological processes are often performed by self-organizing nanostructures comprising multiple classes of macromolecules, such as ribosomes (proteins and RNA) or enveloped viruses (proteins, nucleic acids and lipids). Approaches have been developed for designing self-assembling structures consisting of either nucleic acids or proteins, but strategies for engineering hybrid biological materials are only beginning to emerge. Here we describe the design of self-assembling protein nanocages that direct their own release from human cells inside small vesicles in a manner that resembles some viruses. We refer to these hybrid biomaterials as 'enveloped protein nanocages' (EPNs). Robust EPN biogenesis requires protein sequence elements that encode three distinct functions: membrane binding, self-assembly, and recruitment of the endosomal sorting complexes required for transport (ESCRT) machinery. A variety of synthetic proteins with these functional elements induce EPN biogenesis, highlighting the modularity and generality of the design strategy. Biochemical analyses and cryo-electron microscopy reveal that one design, EPN-01, comprises small (~100 nm) vesicles containing multiple protein nanocages that closely match the structure of the designed 60-subunit self-assembling scaffold. EPNs that incorporate the vesicular stomatitis viral glycoprotein can fuse with target cells and deliver their contents, thereby transferring cargoes from one cell to another. These results show how proteins can be programmed to direct the formation of hybrid biological materials that perform complex tasks, and establish EPNs as a class of designed, modular, genetically-encoded nanomaterials that can transfer molecules between cells.
External links	Nature / PubMed:27919066 / PubMed Central
Methods	EM (single particle)
Resolution	5.7 Å
Structure data	8278 5kp9 EMDB-8278, PDB-5kp9: Structure of Nanoparticle Released from Enveloped Protein Nanoparticle Method: EM (single particle) / Resolution: 5.7 Å
Source	thermotoga maritima (bacteria) human immunodeficiency virus type 1 group m subtype b (isolate bh10)
Keywords	STRUCTURAL PROTEIN / protein design / icosahedral assemblies / cell transduction / enveloped viruses / virus assembly / enveloped protein / nanoparticle