Conformational flexibility facilitates self-assembly of complex DNA nanostructures
Molecular self-assembly is a promising approach to the preparation of nanostructures. DNA, in particular, shows great potential to be a superb molecular system. Synthetic DNA molecules have been programmed to assemble into a wide range of nanostructures. It is generally believed that rigidities of DNA nanomotifs (tiles) are essential for programmable self-assembly of well defined nanostructures. Recently, we have shown that adequate conformational flexibility could be exploited for assembling 3D objects, including tetrahedra, dodecahedra, and buckyballs, out of DNA three-point star motifs. In the current study, we have integrated tensegrity principle into this concept to assemble well defined, complex nanostructures in both 2D and 3D. A symmetric five-pointstar motif (tile) has been designed to assemble into icosahedra or large nanocages depending on the concentration and flexibility of the DNA tiles. In both cases, the DNA tiles exhibit significant flexibilities and undergo substantial conformational changes, either symmetrically bending out of the plane or asymmetrically bending in the plane. In contrast to the complicated natures of the assembled structures, the approach presented here is simple and only requires three different component DNA strands. These results demonstrate that conformational flexibility could be explored to generate complex DNA nanostructures. The basic concept might be further extended to other biomacromolecular systems, such as RNA and proteins.icosahedron ͉ three-dimensional ͉ polyhedron ͉ cryo-EM ͉ molecular cages M olecular self-assembly provides a bottom-up approach to the preparation of nanostructures (1-3). DNA, in particular, shows great potential to be a superb molecular system (4). In the last 20 years, DNA has been explored as building blocks for nanoconstructions, including preparation of periodic and aperiodic 2D nanopatterns (5-8) and 3D polyhedra (9-14). Most of the branched DNA structures are intrinsically flexible and are not suitable building blocks for construction of well defined geometric structures. How to overcome the conformational flexibility of branched DNA structures is a major challenge in structural DNA nanotechnology. In the last decade, a series of rigid structural motifs have been successfully engineered that lead to the rapid evolution of structural DNA nanotechnology (4). However, with more experience and knowledge, it is possible to controllably introduce the conformational flexibility to prepare complex DNA nanostructures (15). In our recent study of 3D self-assembly of DNA three-point-star tiles (16), we found that DNA tetrahedra could be readily assembled, and the tetrahedra are well behaved during sample characterizations. In contrast, DNA dodecahedra and buckyballs have significantly lower assembly yields and are prone to deformation. This phenomenon can be explained by the geometrical differences of these structures. Tetrahedra consist of triangular faces, but others do not. According to tensegrity principle, triangular faces will lead to rigid s...
The norovirus P particle is an octahedral nanoparticle formed by 24 copies of the protrusion (P) domain of the norovirus capsid protein. This P particle is easily produced in Escherichia coli, extremely stable, and highly immunogenic. There are three surface loops per P domain, making a total of 72 loops per particle, and these are potential sites for foreign antigen presentation for immune enhancement. To prove this concept, a small peptide (His tag, 7 amino acids [aa]) and a large antigen (rotavirus VP8, 159 aa) were inserted into one of the loops. Neither insertion affects P particle formation, while both antigens were presented well on the P particle surface. The immune-enhancement effect of the P particle was demonstrated by significantly increased antibody titers induced by the P particle-presented antigens compared to the titers induced by free antigens. In addition, the measured neutralization antibody titers and levels of protection against rotavirus shedding in mice immunized with the VP8 chimeric P particles were significantly higher than those of mice immunized with the free VP8 antigen. Sera from P particle-VP8 chimera-vaccinated animals also blocked norovirus virus-like particle (VLP) binding to the histo-blood group antigen (HBGA) receptors. From these data, the P particle appears to be an excellent vaccine platform for antigen presentation. The readily available three surface loops and the great capacity for foreign antigen insertion make this platform attractive for wide application in vaccine development and antibody production. The P particle-VP8 chimeras may serve as a dual vaccine against both rotavirus and norovirus.Biomaterials and bioengineering are fast-growing areas that have become critical parts of modern medicine. Because of their versatility and propensity to form arrays, viral structural proteins are ideal substrates in building presentation systems. Through genetic engineering, the self-assembled viral particles have been used as vaccine platforms for antigen presentation. Successful examples have been reported for several viruses, including a Flock House virus (FHV) virus-like particle (VLP) containing an antigen of Bacillus anthracis (20), hepatitis B virus (HBV) capsid-like particle (CLP) containing a surface antigen (OspA) of Borrelia burgdorferi (13,22,23), and the cowpea mosaic virus (CPMV) presenting a number of different antigens (4,5,10,16,17,25,26,38), although limitations in these presentation systems have also been described.In our previous study of human noroviruses, we discovered a unique subviral particle, the P particle, which can be used for antigen presentation. Noroviruses cause epidemics of acute gastroenteritis in humans. The viruses are nonenveloped, containing an outer protein capsid consisting of a single major structural protein, the capsid protein (VP1). The capsid protein has two major domains, the shell (S) domain forming the interior shell and the protrusion (P) domain constituting the arch-like protruding structures of the virus (28). These two domain...
Noroviruses are an important cause of epidemic acute gastroenteritis and the viruses recognize human histo-blood group antigens (HBGAs) as receptors. The protruding (P) domain of noroviral capsid, the receptor binding domain, forms subviral particles in vitro that retain the receptor binding function. In this study we characterized the structure and HBGA-binding function of the P particle. Structure reconstruction using cryo-EM showed that the P particles are comprised of 12 P dimers that are organized in octahedral symmetry. The dimeric packing of the proteins in the P particles is similar to that in the norovirus capsid, in which the P2 subdomain with the receptor-binding interface is located at the outermost surface of the P particle. The P particles are immunogenic and reveal similar antigenic and HBGA-binding profiles with their parental virus-like particle, further confirming the shared surface structures between the two types of particles. The P particles are easily produced in E. coli and yeast and are stable, which are potentially useful for broad application including vaccine development against noroviruses.
SIBLING (Small Integrin-Binding Ligand N-linked Glycoproteins) family is the major group of noncollagenous proteins in bone and dentin. These extremely acidic and highly phosphorylated extracellular proteins play critical roles in the formation of collagenous mineralized tissues. While the lack of individual SIBLINGs causes significant mineralization defects in vivo, none of them led to a complete cessation of mineralization suggesting that these proteins have overlapping functions. To assess whether different SIBLINGs regulate biomineralization in a similar manner, and how phosphorylation impacts their activity, we studied the effects of two SIBLINGs, dentin matrix protein 1 (DMP1) and dentin phosphophoryn (DPP), on mineral morphology and organization in vitro. Our results demonstrate distinct differences in the effects of these proteins on mineralization. We show that phosphorylation has a profound effect on the regulation of mineralization by both proteins. Specifically, both phosphorylated proteins facilitated organized mineralization of collagen fibrils and phosphorylated DMP1 induced formation of organized mineral bundles in the absence of collagen. In summary, these results indicate that the primary structure and phosphorylation uniquely determine functions of individual SIBLINGs in regulation of mineral morphology and organization.
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