Architecture of the VE-cadherin hexamer.

Vascular endothelial-cadherin (VE-cadherin) is the major constituent of the adherens junctions of endothelial cells and plays a key role in angiogenesis and vascular permeability. The ectodomains EC1-4 of VE-cadherin are known to form hexamers in solution. To examine the mechanism of homotypic association of VE-cadherin, we have made a 3D reconstruction of the EC1-4 hexamer using electron microscopy and produced a homology model based on the known structure of C-cadherin EC1-5. The hexamer consists of a trimer of dimers with each N-terminal EC1 module making an antiparallel dimeric contact, and the EC4 modules forming extensive trimeric interactions. Each EC1-4 molecule makes a helical curve allowing some torsional flexibility to the edifice. While there is no direct evidence for the existence of hexamers of cadherin at adherens junctions, the model that we have produced provides indirect evidence since it can be used to explain some of the disparate results for adherens junctions. It is in accord with the X-ray and electron microscopy results, which demonstrate that the EC1 dimer is central to homotypic cadherin interaction. It provides an explanation for the force measurements of the interaction between opposing cadherin layers, which have previously been interpreted as resulting from three different interdigitating interactions. It is in accord with observations of native junctions by cryo-electron microscopy. The fact that this hexameric model of VE-cadherin can be used to explain more of the existing data on adherens junctions than any other model alone argues in favour of the existence of the hexamer at the adherens junction. In the context of the cell-cell junction these cis-trimers close to the membrane, and trans-dimers from opposing membranes, would increase the avidity of the bond.

Structure of an insect parvovirus (Junonia coenia Densovirus) determined by cryo-electron microscopy.

Junonia coenia densovirus (JcDNV) belongs to the densovirus genus of the Parvoviridae family and infects the larvae of the Common Buckeye butterfly. Its capsid is icosahedral and consists of viral proteins VP1 (88 kDa), VP2 (58 kDa), VP3 (52 kDa) and VP4 (47 kDa). Each viral protein has the same C terminus but differs in the length of its N-terminal extension. Virus-like-particles (VLPs) assemble spontaneously when the individual viral proteins are expressed by a recombinant baculovirus. We present here the structure of native JcDNV at 8.7A resolution and of the two VLPs formed essentially from VP2 and VP4 at 17 A resolution, as determined by cryo-electron microscopy. The capsid displays a remarkably smooth surface, with only two very small spikes that define a pentagonal plateau on the 5-fold axes. JcDNV is very closely related to Galleria mellonella densovirus (GmDNV), whose structure is known (94% sequence identity with VP4 and 96% similarity). We compare these structures in order to locate the structural changes and mutations that may be involved in the species shift of these densoviruses. A single mutation at the tip of one of the two small spikes is a strong candidate as a species shift determinant. Difference imaging reveals that the 21 disordered amino acid residues at the N terminus of the capsid protein VP4 are located inside the capsid at the 5-fold axis, but the additional 94 amino acid residue extension of VP2 is not visible, suggesting that it is highly disordered. There is strong evidence of DNA ordering associated with the 3-fold axes of the capsid.

Nonneutralizing human rhinovirus serotype 2-specific monoclonal antibody 2G2 attaches to the region that undergoes the most dramatic changes upon release of the viral RNA.

The monoclonal antibody 2G2 has been used extensively for detection and quantification of structural changes of human rhinovirus serotype 2 during infection. It recognizes exclusively A and B subviral particles, not native virus. We have elucidated the basis of this selectivity by determining the footprint of 2G2. Since viral escape mutants obviously cannot be obtained, the structures of complexes between Fab fragments of 2G2 and 80S subviral B particles were determined by cryoelectron microscopy. The footprint of the antibody corresponds to the capsid region that we predicted would undergo the most dramatic changes upon RNA release.

Cryoelectron microscopy analysis of the structural changes associated with human rhinovirus type 14 uncoating.

Release of the human rhinovirus (HRV) genome into the cytoplasm of the cell involves a concerted structural modification of the viral capsid. The intracellular adhesion molecule 1 (ICAM-1) cellular receptor of the major-group HRVs and the low-density lipoprotein (LDL) receptor of the minor-group HRVs have different nonoverlapping binding sites. While ICAM-1 binding catalyzes uncoating, LDL receptor binding does not. Uncoating of minor-group HRVs is initiated by the low pH of late endosomes. We have studied the conformational changes concomitant with uncoating in the major-group HRV14 and compared them with previous results for the minor-group HRV2. The structure of empty HRV14 was determined by cryoelectron microscopy, and the atomic structure of native HRV14 was used to examine the conformational changes of the capsid and its constituent viral proteins. For both HRV2 and HRV14, the transformation from full to empty capsid involves an overall 4% expansion and an iris type of movement of viral protein VP1 to open up a 10-A-diameter channel on the fivefold axis to allow exit of the RNA genome. The beta-cylinders formed by the N termini of the VP3 molecules inside the capsid on the fivefold axis all open up in HRV2, but we propose that only one opens up in HRV14. The release of VP4 is less efficient in HRV14 than in HRV2, and the N termini of VP1 may exit at different points. The N-terminal loop of VP2 is modified in both viruses, probably to detach the RNA, but it bends only inwards in HRV2.

Characterization of the performance of a 200-kV field emission gun for cryo-electron microscopy of biological molecules.

The value of an electron microscope equipped with a field emission gun (FEG) was first revealed in materials science applications. More recently, the FEG has played a crucial role in breaking the 10A barrier in single-particle reconstructions of frozen hydrated biological molecules. The standard high-resolution performance tests for electron microscopes are made close to focus, at several hundreds of A underfocus at a magnification of 500,000x or more. While this is appropriate for materials science specimens, it is not suitable for observing frozen hydrated biological specimens with which the optimum underfocus is of the order of 1 micron or so and the magnification is limited by radiation damage to roughly 30,000 to 60,000x. Thus, in order to access the performance of a cryo-electron microscope for high-resolution 3D electron microscopy of biological molecules, additional tests are necessary. We present here resolution tests of a 200-kV FEG using frozen hydrated virus suspensions. The extent and amplitude of the contrast transfer function are used as a test of the performance. We propose that small spherical viruses close to 300A in diameter, such as the picornaviruses or phages, make good specimens for testing the performance of an electron microscope in cryo-mode.

The concerted conformational changes during human rhinovirus 2 uncoating.

Delivery of the rhinovirus genome into the cytoplasm involves a cooperative structural modification of the viral capsid. We have studied this phenomenon for human rhinovirus serotype 2 (HRV2). The structure of the empty capsid has been determined to a resolution of better than 15 A by cryo-electron microscopy, and the atomic structure of native HRV2 was used to examine conformational changes of the capsid. The two proteins around the 5-fold axes make an iris type of movement to open a 10 A diameter channel which allows the RNA genome to exit, and the N terminus of VP1 exits the capsid at the pseudo 3-fold axis. A remarkable modification occurs at the 2-fold axes where the N-terminal loop of VP2 bends inward, probably to detach the RNA.

A cellular receptor of human rhinovirus type 2, the very-low-density lipoprotein receptor, binds to two neighboring proteins of the viral capsid.

The very-low-density lipoprotein receptor (VLDL-R) is a receptor for the minor-group human rhinoviruses (HRVs). Only two of the eight binding repeats of the VLDL-R bind to HRV2, and their footprints describe an annulus on the dome at each fivefold axis. By studying the complex formed between a selection of soluble fragments of the VLDL-R and HRV2, we demonstrate that it is the second and third repeats that bind. We also show that artificial concatemers of the same repeat can bind to HRV2 with the same footprint as that for the native receptor. In a 16-A-resolution cryoelectron microscopy map of HRV2 in complex with the VLDL-R, the individual repeats are defined. The third repeat is strongly bound to charged and polar residues of the HI and BC loops of viral protein 1 (VP1), while the second repeat is more weakly bound to the neighboring VP1. The footprint of the strongly bound third repeat extends down the north side of the canyon. Since the receptor molecule can bind to two adjacent copies of VP1, we suggest that the bound receptor "staples" the VP1s together and must be detached before release of the RNA can occur. When the receptor is bound to neighboring sites on HRV2, steric hindrance prevents binding of the second repeat.