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A cryo-EM structure of toxin component TcdA1 embedded in lipid nanodiscs reveals details of the mechanism used by this bacterial toxin to insert into the host cell membrane.
Structural and functional analyses of HopZ1a, a member of the YopJ family of bacterial type III–secreted effectors, reveal the structural basis of YopJ effectors’ noncanonical acetyltransferase activity and allosteric regulation by inositol hexakisphosphate.
Cryo-EM and tomography imaging of influenza virus fusion with target membranes reveal structural intermediates of HA surface glycoprotein and their interactions with membranes as well as ultrastructural changes in the virus that accompany membrane fusion.
Analyses in supported lipid bilayers and in cells shed light on the roles of multiple SOS-membrane interactions in SOS's membrane recruitment and association, processive activation of Ras and signal attenuation.
An interactive structure-based approach was used to improve a vaccine antigen against respiratory syncytium virus (RSV), thus leading to immunogens with higher stability that elicit higher neutralizing titers in mice.
A cryo-EM structure of yeast AAA+ protein disaggregase Hsp104 with AMP-PNP reveals a spiral arrangement of the protomers and a continuous path for polypeptide translocation that explains Hsp104's processivity mechanism during disaggregation.
The inability of A-form RNA to form Hoogsteen base pairs provides a mechanism for how post-transcriptional modifications can disrupt RNA structure and might help explain why DNA is the molecular choice for storing genetic information.
Light-scattering kinetics and atomic force and electron microscopy analyses show that Hsp70-mediated disassembly of clathrin cages occurs via a collision-pressure mechanism consistent with the entropic pulling model.
The crystal structure of the phage anti-CRISPR protein AcrF3 in complex with Cas3 reveals its mode of inhibition of the CRISPR–Cas bacterial immune system.
The crystal structure of full-length NS1 protein from Zika virus reveals an extended surface for membrane association and a highly variable polar surface.
The eukaryotic Elongator complex participates in modification of uridines in tRNAs. Structural and functional work on a bacterial Elp3, the catalytic subunit of Elongator, provides insight into the function and mechanism of this important enzyme.
Mass spectrometry, kinetics studies and in silico analyses indicate that multiple copies of the Skp chaperone are required for sequestration of 16-stranded or larger OMPs and prevention of their aggregation.
The complete architecture of the yeast COG tethering complex is revealed by negative-stain electron microscopy, showing an intricate shape with up to five flexible legs.
Electron microscopy analyses of tethering complexes from different families, GARP and HOPS, show that they share a similar architecture featuring long flexible legs. The findings suggest that multisubunit tethering complexes use related structural frameworks to accomplish their functions.
A cryo-EM structure of the human 26S proteasome in a resting state at an average resolution of 3.5 Å reveals details in the interactions between subunits. An additional structure of the proteasome with USP14 bound suggests a mechanism for its activation.
A crystal structure of the Zika virus NS3 RNA helicase reveals similarities to the RNA helicase from Dengue virus, with variability in loops typically involved in binding ATP and RNA, and aids in identification of potentially druggable hotspots.
Structural and functional analysis of the Swi2/Snf2 remodeler demonstrates that the catalytic core of the protein is a competent remodeling machine, which rests in an inactive conformation poised for activation.
EPR spectroscopy analyses elucidate how lipids affect the conformational dynamics of a multidrug secondary transporter, LmrP, and indicate a key role of the lipid headgroups in shaping the conformational-energy landscape of the transporter.
Solid-state NMR analyses reveal that the free backbone carbonyl groups associated with proline residues in the transmembrane helices play a key role in mediating rhodopsin activation.