“Virus nanotechnology”的意思、由来-开放百科全书

Virus nanotechnology is one of the very promising and emerging disciplines in nanotechnology. A highly interdisciplinary field, viral nanotechnology occupies the interface between virology, biotechnology, chemistry, and materials science. The fields employs viral nanoparticles (VNPs) and its counterparts of virus-like nanoparticles (VLPs) for potential applications in the diverse fields of electronics, sensors, and most significantly at clinical field.^[1] VNPs and VLPs are attractive building blocks for several reasons. Both particles are on the nanometer-size scale; they are monodisperse with a high degree of symmetry and polyvalency; they can be produced with ease on large scale; they are exceptionally stable and robust, and they are biocompatible, and in some cases, orally bioavailable.^[2] They are "programmable" units that can be modified by either genetic modification or chemical bioconjugation methods.^[3]^[4]

Viruses

A virus is a biological infective agent that infect living hosts and reproduces inside the host cells. Viral infect all forms of life; can cause disease in humans, animals, plants and even insects. The science of studying viruses also called as Virology. Unlike most living things, viruses do not have cells that divide; new viruses are assembled in the infected host cells. Therefore, viruses are ultimately called as obligatory parasites. Viruses contain genetic materials (either DNA or RNA) which give them the ability to mutate and evolve. It also has a protective coat termed the capsid which is made up of multiple numbers of protein monomers called capsomer. Some viruses have additional structural features such as a lipid envelope over capsid or they may consist of separate head and tail structures. E.g. Bacteriophage. Every year novel viruses emerged with the potential to cause disease and death worldwide. Today, over 5000 species of viruses have been discovered and described.^[5]

Viruses spread in many ways. Just as many viruses are very specific as to which host species or tissue they attack, each species of virus relies on a particular method for propagation. Plant viruses are often spread from plant to plant by insects and other organisms, known as vectors. Some viruses of animals, including humans, are spread by exposure to infected bodily fluids. Viral infections can cause disease in humans, animals and even plants.

What is Nanotechnology?

Nanotechnology is the manipulation or self-assembly of individual atoms, molecules, or, molecular clusters into structures to create materials and devices with new or vastly different properties. Nanotechnology can work from the top down (which means reducing the size of the smallest structures to the nanoscale) or bottom up (which involves manipulating individual atoms and molecules into nanostructures) .The definition of nanotechnology is based on the prefix "nano" which is from the Greek word meaning "dwarf". In more technical terms, the word "nano" means 10-9, or one billionth of something. For a meaningful comparison, a virus is roughly 100 nanometers (nm) in size. So that a virus can also call as a nanoparticle. The word nanotechnology is generally used when referring to materials with the size of 0.1 to 100 nanometres, however, it is also inherent that these materials should display different properties from bulk (or micrometric and larger) materials as a result of their size.^[1] These differences include physical strength, chemical reactivity, electrical conductance, magnetism and optical effects.

Nanotechnology has an almost limitless string of applications in biology, biotechnology, and biomedicine.^[6] Nanotechnology has engendered a growing sense of excitement due to the ability to produce and utilize materials, devices, and systems through the control of matter on the nanometer scale (1 to 50 nm). This bottom-up approach requires less material and causes less pollution. Nanotechnology has had several commercial applications in advanced laser technology, hard coatings, photography, pharmaceuticals, printing, chemical-mechanical polishing, and cosmetics.^[7] Soon, there will be lighter cars using nanoparticle reinforced polymers, orally applicable insulin, artificial joints made from nanoparticulate materials, and low-calorie foods with nanoparticulate taste enhancers.^[8]

Viruses as Building Blocks in Nanotechnology

Viruses have long been studied as deadly pathogens to cause disease in all living forms.^[9] By the 1950s, researchers had begun thinking of viruses as tools in addition of pathogens. Bacteriophage genomes and components of the protein expression machinery have been widely utilized as tools for understanding the fundamental cellular process. On the basis of these studies, several viruses have been exploited as expression systems in biotechnology. Later in the 1970s, viruses are used as a vector for the benefit of humans.^[10] Since that, often viruses are used as vectors for gene therapy, cancer control and control of harmful or damaging organisms, in both agriculture and medicine.^[11]^[12]^[13]^[14]^[15]

Recently, a new approach to exploiting viruses and their capsids for biotechnology began to change toward using them for nanotechnology application. Researchers Douglas and Young (Montana State University, Bozeman, MT, USA) were the first to consider the utility of a virus capsid as a nanomaterial.^[16] They have taken plant virus Cowpea Chlorotic Mottle Virus (CCMV) for their study. CCMV showed a highly dynamic platform with pH and metal ion dependent structural transitions. Douglas and Young made use of these capsid dynamics and exchanged the natural cargo (nucleic acid) with synthetic materials. Since then many materials have been encapsulated into CCMV and other VNPs. At about the same time, the research team led by Mann (University of Bristol, UK) pioneered a new area using the rod-shaped particles of TMV (Tobacco Mosaic Virus). The particles were used as templates for the fabrication of a range of metallized nanotube structures using mineralization techniques.^[17] Following that invention, TMV particles have been utilized to generate various structures (nanotubes and nanowires) for use in batteries and data storage devices.^[18]^[19]

Viral capsids have attracted great interest in the field of nanobiology because of their nanoscale size, symmetrical structural organization, load capacity, controllable self-assembly, and ease of modification. viruses are essentially naturally occurring nanomaterials capable of self-assembly with a high degree of precision.^[3] Viral capsid- nanoparticle hybrid structures, which combine the bio-activities of virus capsids with the functions of nanoparticles, are a new class of bionanomaterials that have many potential applications as therapeutic and diagnostic vectors, imaging agents, and advanced nanomaterial synthesis reactors.^[3]

Plant viruses in nanotechnology

Plant virus-based systems, in particular, are among the most advanced and exploited for their potential use as bioinspired structured nanomaterials and nano-vectors.Plant virus nanoparticles are non-infectious to mammalian cells also proved by Raja muthuramalingam et al. 2018.^[20] Plant viruses have a size particularly suitable for nanoscale applications and can offer several advantages. In fact, they are structurally uniform, robust, biodegradable and easy to produce.^[3] Moreover, many are the examples regarding functionalization of plant virus-based nanoparticles by means of modification of their external surface and by loading cargo molecules into their internal cavity. This plasticity in terms of nanoparticles engineering is the ground on which multivalency, payload containment and targeted delivery can be fully exploited.^[21]

The capsids of most plant viruses are simple and robust structures consisting of multiple copies of one or a few types of protein subunit arranged with either icosahedral or helical symmetry. The capsids can be produced in large quantities either by the infection of plants or by the expression of the subunit(s) in a variety of heterologous systems. In view of their relative simplicity and ease of production, plant virus particles or virus-like particles (VLPs) have attracted much interest over the past 20 years for applications in both bio- and nanotechnology [Lomonossoff, 2011^[22]]. As result, plant virus particles have been subjected to both genetic and chemical modification, have been used to encapsulate foreign material and have themselves, been incorporated into supramolecular structures. Significantly, plant viruses studied are not human pathogens, which have no natural tendency to interact with human cell surface receptors.^[23] Recently, a plant pathogenic virus are reported to used to synthesize a noble hybrid metal nanomaterials used as biosemiconductor.^[20]

Plant viruses

Viruses cause several destructive plant diseases and are accountable for massive losses in crop production and quality in all parts of the world. Infected plants may show a range of symptoms depending on the disease but often there is severe leaf curling, stunting (abnormalities in the whole plant) and leaf yellowing (either of the whole leaf or in a pattern of stripes or blotches).^[24] Most plant viruses are therefore transmitted by a vector organism (insects, nematodes, plasmodiophorids and mites) that feeds on the plant or (in some diseases) are introduced through wounds made, for example during agriculture practices (e.g. pruning). Many plant viruses, for example, tobacco mosaic virus, have been used as model systems to provide a basic understanding of how viruses express genes and replicate. Others permitted the elucidation of the processes underlying RNA silencing, now recognised as a core epigenetic mechanism underpinning numerous areas of biology.^[25]

Some properties of viral nanoparticles

Manifold plant virus platform technologies are being developed and studied for many applications^[33] including:

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