Maria J. Gonzalez scite author profile

A significant impediment to the widespread use of noninvasive in vivo vascular imaging techniques is the current lack of suitable intravital imaging probes. We describe here a new strategy to use viral nanoparticles as a platform for the multivalent display of fluorescent dyes to image tissues deep inside living organisms. The bioavailable cowpea mosaic virus (CPMV) can be fluorescently labeled to high densities with no measurable quenching, resulting in exceptionally bright particles with in vivo dispersion properties that allow high-resolution intravital imaging of vascular endothelium for periods of at least 72 h. We show that CPMV nanoparticles can be used to visualize the vasculature and blood flow in living mouse and chick embryos to a depth of up to 500 μm. Furthermore, we show that the intravital visualization of human fibrosarcoma-mediated tumor angiogenesis using fluorescent CPMV provides a means to identify arterial and venous vessels and to monitor the neovascularization of the tumor microenvironment.Intravital vascular imaging has the potential to be a powerful tool for the noninvasive detection and visualization of disease. The resolution of functionally significant changes in structure in the endothelium of microvasculature using fluorescence imaging in live animals has proven challenging, however, because of the inadequate tissue penetration of fluorescent signal 1 .Current agents for fluorescence imaging of microvasculature include microspheres or nanospheres 2 , iron oxide particles 3 , liposomes 4 , dextrans 5 , lectins 6 , antibodies 7 and, more recently, quantum dots 8 . Although many of these particles have specific strengths, issues related to toxicity, stability, bioavailability, cost or chemical flexibility have yet to be overcome. Inorganic synthetic particles tend to aggregate under physiological conditions and can be toxic upon exposure to ultraviolet light 9 . Multivalency with respect to fluorochrome is crucial for achieving the requisite sensitivity for adequate tissue penetration. Thus, a multivalent, biologically compatible platform for the development of fluorescent and magnetic resonance imaging agents is still much needed for both clinical and research applications.

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Hybrid Virus−Polymer Materials. 1. Synthesis and Properties of PEG-Decorated Cowpea Mosaic Virus

Raja

et al. 2003

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Systemic trafficking of plant virus nanoparticles in mice via the oral route

et al. 2005

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The plant virus, cowpea mosaic virus (CPMV), is increasingly being used as a nanoparticle platform for multivalent display of peptides. A growing variety of applications have employed the CPMV display technology including vaccines, antiviral therapeutics, nanoblock chemistry, and materials science. CPMV chimeras can be inexpensively produced from experimentally infected cowpea plants and are completely stable at 37 degrees C and low pH, suggesting that they could be used as edible or mucosally-delivered vaccines or therapeutics. However, the fate of CPMV particles in vivo, or following delivery via the oral route, is unknown. To address this question, we examined CPMV in vitro and in vivo. CPMV was shown to be stable under simulated gastric conditions in vitro. The pattern of localization of CPMV particles to mouse tissues following oral or intravenous dosing was then determined. For several days following oral or intravenous inoculation, CPMV was found in a wide variety of tissues throughout the body, including the spleen, kidney, liver, lung, stomach, small intestine, lymph nodes, brain, and bone marrow. CPMV particles were detected after cardiac perfusion, suggesting that the particles entered the tissues. This pattern was confirmed using methods to specifically detect the viral capsid proteins and the internal viral RNA. The stability of CPMV virions in the gastrointestinal tract followed by their systemic dissemination supports their use as orally bioavailable nanoparticles.

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Viruses and their uses in nanotechnology

Singh

Gonzalez

Manchester

2006

Drug Development Research

168

144

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The use of materials derived from natural sources in materials science has allowed the harnessing of complex structures resulting from eons of evolutionary fine-tuning. A better understanding of the structure and function of viruses has revealed a collection of natural molecular assemblies and containers with a variety of shapes, sizes, stabilities, dynamic properties, and chemical reactivities. Viruses are increasingly being used in materials science, engineering, and nanotechnology as tools and building blocks for electronics, chemistry, and biomedical science. Here we discuss different types of viruses presently in use, their physical properties, and their potential uses in a variety of nanotechnology applications. Drug Dev. Res. 67:23-41, 2006.

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Synthesis and assembly of a full‐length human monoclonal antibody in algal chloroplasts

Tran

Zhou

Pettersson

et al. 2009

Biotech & Bioengineering

158

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Monoclonal antibodies can be effective therapeutics against a variety of human diseases, but currently marketed antibody-based drugs are very expensive compared to other therapeutic options. Here, we show that the eukaryotic green algae Chlamydomonas reinhardtii is capable of synthesizing and assembling a full-length IgG1 human monoclonal antibody (mAb) in transgenic chloroplasts. This antibody, 83K7C, is derived from a human IgG1 directed against anthrax protective antigen 83 (PA83), and has been shown to block the effects of anthrax toxin in animal models. Here we show that 83K7C heavy and light chain proteins expressed in the chloroplast accumulate as soluble proteins that assemble into complexes containing two heavy and two light chain proteins. The algal-expressed 83K7C binds PA83 in vitro with similar affinity to the mammalian-expressed 83K7C antibody. In addition, a second human IgG1 and a mouse IgG1 were also expressed and shown to properly assemble in algal chloroplast. These results show that chloroplasts have the ability to fold and assemble full-length human mAbs, and suggest the potential of algae as a platform for the cost effective production of complex human therapeutic proteins.

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Maria J. Gonzalez

Viral nanoparticles as tools for intravital vascular imaging

Hybrid Virus−Polymer Materials. 1. Synthesis and Properties of PEG-Decorated Cowpea Mosaic Virus

Systemic trafficking of plant virus nanoparticles in mice via the oral route

Viruses and their uses in nanotechnology

Synthesis and assembly of a full‐length human monoclonal antibody in algal chloroplasts

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