Multivalent Ligand Displayed on Plant Virus Induces Rapid Onset of Bone Differentiation

Viruses are monodispersed biomacromolecules with well-defined 3-D structures at the nanometer level. The relative ease to manipulate viral coat protein gene to display numerous functional groups affords an attractive feature for these nanomaterials, and the inability of plant viruses to infect mammalian hosts poses little or no cytotoxic concerns. As such, these nanosized molecular tools serve as powerful templates for many pharmacological applications ranging as multifunctional theranostic agents with tissue targeting motifs and imaging agents, potent vaccine scaffolds to induce cellular immunity and for probing cellular functions as synthetic biomaterials. The results herein show that combination of serum-free, chemically defined media with genetically modified plant virus induces rapid onset of key bone differentiation markers for bone marrow derived mesenchymal stem cells within two days. The xeno-free culture is often a key step toward development of ex vivo implants, and the early onset of osteocalcin, BMP-2 and calcium sequestration are some of the key molecular markers in the progression toward bone formation. The results herein will provide some key insights to engineering functional materials for rapid bone repair

Mutant Plant Viruses with Cell Binding Motifs Provide Differential Adhesion Strengths and Morphologies

The ability of Tobacco mosaic virus (TMV) to tolerate various amino acid insertions near its carboxy terminus is well-known. Typically these inserts are based on antigenic sequences for vaccine development with plant viruses as carriers. However, we determined that the structural symmetries and the size range of the viruses could also be modeled to mimic the extracellular matrix proteins by inserting cell-binding sequences to the virus coat protein. The extracellular matrix proteins play important roles in guiding cell adhesion, migration, proliferation, and stem cell differentiation. Previous studies with TMV demonstrated that the native and phosphate-modified virus particles enhanced stem cell differentiation toward bone-like tissues. Based on these studies, we sought to design and screen multiple genetically modified TMV mutants with reported cell adhesion sequences to expand the virus-based tools for cell studies. Here, we report the design of these mutants with cell binding amino acid motifs derived from several proteins, the stabilities of the mutants against proteases during purification and storage, and a simple and rapid functional assay to quantitatively determine adhesion strengths by centrifugal adhesion assay. Among the mutants, we found that cells on TMV expressing RGD motifs formed filopodial extensions with weaker attachment profiles, whereas the cells on TMV expressing collagen I mimetic sequence displayed little spreading but higher attachment strengths

<i>In Vivo</i> Virus-Based Macrofluorogenic Probes Target Azide-Labeled Surface Glycans in MCF‑7 Breast Cancer Cells

Chemical addressability of viral particles has played a pivotal role in adapting these biogenic macromolecules for various applications ranging from medicine to inorganic catalysis. Cowpea mosaic virus possesses multiple features that are advantageous for the next generation of virus-based nanotechnology: consistent multimeric assemblies dictated by its genetic code, facile large scale production, and lack of observable toxicity in humans. Herein, the chemistry of the viral particles is extended with the use of Cu-free strain-promoted azide–alkyne cycloaddition reaction, or SPAAC reaction. The elimination of Cu, its cocatalyst and reducing agent, simplifies the reaction scheme to a more straightforward approach, which can be directly applied to living systems. As a proof of concept, the viral particles modified with the azadibenzylcyclooctyne functional groups are utilized to trigger and amplify a weak fluorescent signal (azidocoumarin) in live cell cultures to visualize the non-natural sugars. Future adaptations of this platform may be developed to enhance biosensing applications

Porous Alginate Hydrogel Functionalized with Virus as Three-Dimensional Scaffolds for Bone Differentiation

In regenerative medicine, a synthetic extracellular matrix is crucial for supporting stem cells during its differentiation process to integrate into surrounding tissues. Hydrogels are used extensively in biomaterials as synthetic matrices to support the cells. However, to mimic the biological niche of a functional tissue, various chemical functionalities are necessary. We present here, a method of functionalizing a highly porous hydrogel with functional groups by mixing the hydrogel with a plant virus, tobacco mosaic virus (TMV), and its mutant. The implication of this process resides with the three important features of TMV: its well-defined genetic/chemical modularity, its multivalency (TMV capsid is composed of 2130 copies of identical subunits), and its well-defined structural features. Previous studies utilizing the native TMV on two-dimensional supports accelerated mesenchymal stem cell differentiation, and surfaces modified with genetically modified viral particles further enhanced cell attachment and differentiation. Herein we demonstrate that functionalization of a porous alginate scaffold can be achieved by the addition of viral particles with minimal processing and downstream purifications, and the cell attachment and differentiation within the macroporous scaffold can be effectively manipulated by altering the peptide or small molecule displayed on the viral particles

Thermally Controlled Release of Anticancer Drug from Self-Assembled γ-Substituted Amphiphilic Poly(ε-caprolactone) Micellar Nanoparticles

A thermo-responsive poly­{γ-2-[2-(2-methoxyethoxy)­ethoxy]­ethoxy-ε-caprolactone}-<i>b</i>-poly­(γ-octyloxy-ε-caprolactone) (<b>PMEEECL-</b><i><b>b</b></i><b>-POCTCL</b>) diblock copolymer was synthesized by ring-opening polymerization using tin octanoate (Sn­(Oct)₂) catalyst and a fluorescent dansyl initiator. The <b>PMEEECL-</b><i><b>b</b></i><b>-POCTCL</b> had a lower critical solution temperature (LCST) of 38 °C, and it was employed to prepare thermally responsive micelles. Nile Red and Doxorubicin (DOX) were loaded into the micelles, and the micellar stability and drug carrying ability were investigated. The size and the morphology of the cargo-loaded micelles were determined by DLS, AFM, and TEM. The Nile-Red-loaded polymeric micelles were found to be stable in the presence of both fetal bovine serum and bovine serum albumin over a 72 h period and displayed thermo-responsive in vitro drug release. The blank micelles showed a low cytotoxicity. As comparison, the micelles loaded with DOX showed a much higher in vitro cytotoxicity against MCF-7 human breast cancer cell line when the incubation temperature was elevated above the LCST. Confocal laser scanning microscopy was used to study the cellular uptake and showed that the DOX-loaded micelles were internalized into the cells via an endocytosis pathway