BSMV as a Biotemplate for Palladium Nanomaterial Synthesis

Adigun, Oluwamayowa O.; Retzlaff-Roberts, Erin Lynn; Novikova, G.Ye.; Wang, Long; Kim, Bong-Suk; Ilavský, Ján; Miller, Jeffrey T.; Loesch-Fries, L. Sue; Harris, Michael T.

doi:10.1021/acs.langmuir.6b03341

Cited by 16 publications

(41 citation statements)

References 66 publications

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“…[36,78] In addition to charged amino acids, the polypeptides or oligopeptides with high binding capability to inorganic minerals play an essential role in biomineralization processes (Figure 4). [81,82] Moreover, the M13 phage engineered with a glutamate trimer or tetramer on the major p8 capsid protein can increase the electrostatic interaction with cationic metal ions or metal precursors, which benefits the spontaneous formation of a polycrystalline or metal oxide surrounded virus coat ( Figure 4). [81,82] Moreover, the M13 phage engineered with a glutamate trimer or tetramer on the major p8 capsid protein can increase the electrostatic interaction with cationic metal ions or metal precursors, which benefits the spontaneous formation of a polycrystalline or metal oxide surrounded virus coat ( Figure 4).…”

Section: Genetic Engineeringmentioning

confidence: 99%

“…In addition to charged amino acids, the polypeptides or oligopeptides with high binding capability to inorganic minerals play an essential role in biomineralization processes ( Figure ) . Fusing of hexahistidine oligopeptides to a virus coat protein can increase the binding affinity of histidine to nickel, cobalt, or zinc, which results in the mineralization on the outer surface of the TMV . Moreover, the M13 phage engineered with a glutamate trimer or tetramer on the major p8 capsid protein can increase the electrostatic interaction with cationic metal ions or metal precursors, which benefits the spontaneous formation of a polycrystalline or metal oxide surrounded virus coat (Figure ) .…”

Section: Strategies For Biomineralization‐based Engineeringmentioning

confidence: 99%

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Therapeutic Potential of Biomineralization‐Based Engineering

Wang

Xiao

Hao

et al. 2018

Advanced Therapeutics

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In nature, the biomineralization processes of living organisms produce a wide range of organic-inorganic hybrid materials to achieve various functions. In particular, egg shells can provide extra protection for embryos and maintain air exchange. Inspired by such phenomena, it is assumed that the engineering of organisms with biomimetic materials can lead to significant improvement in organism function. This review summarizes recent progress in biomineralization-based techniques for organism engineering, and demonstrates the therapeutic potential enabled by these techniques. The design and synthesis approaches of biomineralization-based engineering are systemically introduced to guide the controlled modification of different organisms including viruses, bacteria, cells, and proteins using in situ biomineralization, bottom-up self-assembly, chemical and genetic engineering. Tailored organisms promise delivery, protection, cell therapy, vaccine improvement as well as therapeutic detection and imaging. The present review aims to propose a biomineralization-based strategy to promote functional evolution of these organisms, which promises to meet the increasing demand for new therapeutic purpose.

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Section: Genetic Engineeringmentioning

confidence: 99%

Section: Strategies For Biomineralization‐based Engineeringmentioning

confidence: 99%

Therapeutic Potential of Biomineralization‐Based Engineering

Wang

Xiao

Hao

et al. 2018

Advanced Therapeutics

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“…Plant‐produced BSMV has been demonstrated to be a viable biotemplate for mineralization of palladium nanowires, however, biomineralization with BSMV differs from that of TMV. [ 16 ] The surface of BSMV allows metal ion precursor deposition to proceed via a multi‐step Langmuir isotherm that incorporates both electrostatic and covalently adsorbent‐adsorbate interactions. This difference may arise in part due to the larger amount of BSMV surface‐exposed residues, compared to TMV, in an unstructured insertion loop containing 10 amino acids, that protrudes from the particle surface.…”

Section: Viral Particle Self‐assembly and Metal Nanoparticle Synthesismentioning

confidence: 99%

“…[ 16 ] BSMV has a similar architecture to TMV ( 1 ) but presents distinct surface functional groups that accelerate nanoparticle synthesis and increase nanoparticle density for increased electrical and thermal conductivities and analyte sensitivity as sensors. [ 16 ] BSMV particles encapsidate one of three nucleic acids to produce a distribution of particles at one of three lengths (108, 125, 148 nm). [ 33 ] The evolutionary similarities between TMV and BSMV may allow successful engineering strategies from TMV to be applied in BSMV to expand and enhance the properties of BSMV‐derived biotemplates.…”

Section: Introductionmentioning

confidence: 99%

Engineering Tobacco Mosaic Virus and Its Virus‐Like‐Particles for Synthesis of Biotemplated Nanomaterials

Lee

Pussepitiyalage

Lee

et al. 2020

Biotechnology Journal

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Biomolecules are increasingly attractive templates for the synthesis of functional nanomaterials. Chief among them is the plant tobacco mosaic virus (TMV) due to its high aspect ratio, narrow size distribution, diverse biochemical functionalities presented on the surface, and compatibility with a number of chemical conjugations. These properties are also easily manipulated by genetic modification to enable the synthesis of a range of metallic and non-metallic nanomaterials for diverse applications. This article reviews the characteristics of TMV and related viruses, and their virus-like particle (VLP) derivatives, and how these may be manipulated to extend their use and function. A focus of recent efforts has been on greater understanding and control of the self-assembly processes that drive biotemplate formation. How these features have been exploited in engineering applications such as, sensing, catalysis, and energy storage are briefly outlined. While control of VLP surface features is well-established, fewer tools exist to control VLP self-assembly, which limits efforts to control template uniformity and synthesis of certain templated nanomaterials. However, emerging advances in synthetic biology, machine learning, and other fields promise to accelerate efforts to control template uniformity and nanomaterial synthesis enabling more widescale industrial use of VLP-based biotemplates.

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“…A lattice with an accurate spacing of 0.4 nm was readily prepared, its structure characterized by HRTEM and SEM, and the feasibility of its functionality as a lead zirconate titanate (PZT) device demonstrated. Gold dendrites were co-deposited with M13 virus as a biosensor platform for nitrite ions by Seo et al [68] and tunable core-shell barley stripe mosaic virus (BMMV)–palladium nanowires were readily obtained, as described by Adigum et al [69].…”

Section: Viral Envelopes As Biotemplatesmentioning

confidence: 99%

Protein-Mediated Biotemplating on the Nanoscale

Freeman

2017

Biomimetics

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Purified proteins offer a homogeneous population of biological nanoparticles, equipped in many cases with specific binding sites enabling the directed self-assembly of envisaged one-, twoor three-dimensional arrays. These arrays may serve as nanoscale biotemplates for the preparation of novel functional composite materials, which exhibit potential applications, especially in the fields of nanoelectronics and optical devices. This review provides an overview of the field of protein-mediated biotemplating, focussing on achievements made throughout the past decade. It is comprised of seven sections designed according to the size and configuration of the protein-made biotemplate. Each section describes the design and size of the biotemplate, the resulting hybrid structures, the fabrication methodology, the analytical tools employed for the structural analysis of the hybrids obtained, and, finally, their claimed/intended applications and a feasibility demonstration (whenever available). In conclusion, a short assessment of the overall status of the achievements already made vs. the future challenges of this field is provided.

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BSMV as a Biotemplate for Palladium Nanomaterial Synthesis

Cited by 16 publications

References 66 publications

Therapeutic Potential of Biomineralization‐Based Engineering

Therapeutic Potential of Biomineralization‐Based Engineering

Engineering Tobacco Mosaic Virus and Its Virus‐Like‐Particles for Synthesis of Biotemplated Nanomaterials

Protein-Mediated Biotemplating on the Nanoscale

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