Discovery The first evidence of the existence of viruses came from experiments with filters that had pores small enough to retain bacteria. In 1892,
Dmitri Ivanovsky used one of these filters to show that sap from a diseased tobacco plant remained infectious to healthy tobacco plants despite having been filtered. Martinus Beijerinck called the filtered, infectious substance a "virus" and this discovery is considered to be the beginning of virology. The subsequent discovery and partial characterization of
bacteriophages by
Frederick Twort and
Félix d'Herelle further catalyzed the field, and by the early 20th century many viruses had been discovered. In 1926,
Thomas Milton Rivers defined viruses as obligate parasites. Viruses were demonstrated to be particles, rather than a fluid, by
Wendell Meredith Stanley, and the invention of the
electron microscope in 1931 allowed their complex structures to be visualised.
Life properties Scientific opinions differ on whether viruses are a form of life or organic structures that interact with living organisms. They have been described as "organisms at the edge of life", and reproduce by creating multiple copies of themselves through self-assembly. Although they have genes, they do not have a cellular structure, which is often seen as the basic unit of life. Viruses do not have their own
metabolism and require a host cell to make new products. They therefore cannot naturally reproduce outside a host cell—although some bacteria such as
rickettsia and
chlamydia are considered living organisms despite the same limitation. Accepted forms of life use
cell division to reproduce, whereas viruses spontaneously assemble within cells. They differ from
autonomous growth of
crystals as they inherit genetic mutations while being subject to natural selection. Virus self-assembly within host cells has implications for the study of the
origin of life, as it lends further credence to the hypothesis that life could have started as
self-assembling organic molecules. Although the living versus non-living debate continues, the virocell model has gained some acceptance.
Structure Viruses display a wide diversity of sizes and shapes, called '
morphologies'. In general, viruses are much smaller than bacteria and more than a thousand bacteriophage viruses would fit inside an
Escherichia coli bacterium's cell. A complete virus particle, known as a
virion, consists of nucleic acid surrounded by a protective coat of protein called a
capsid. These are formed from protein subunits called
capsomeres. Virally-coded protein subunits will self-assemble to form a capsid, in general requiring the presence of the virus genome. Complex viruses code for proteins that assist in the construction of their capsid. Proteins associated with nucleic acid are known as
nucleoproteins, and the association of viral capsid proteins with viral nucleic acid is called a nucleocapsid. The capsid and entire virus structure can be mechanically (physically) probed through
atomic force microscopy. In general, there are five main morphological virus types: ; Helical: These viruses are composed of a single type of capsomere stacked around a central axis to form a
helical structure, which may have a central cavity, or tube. This arrangement results in virions which can be short and highly rigid rods, or long and very flexible filaments. The genetic material (typically single-stranded RNA, but single-stranded DNA in some cases) is bound into the protein helix by interactions between the negatively charged nucleic acid and positive charges on the protein. Overall, the length of a helical capsid is related to the length of the nucleic acid contained within it, and the diameter is dependent on the size and arrangement of capsomeres. The well-studied tobacco mosaic virus are examples of helical viruses. ; Icosahedral: Most animal viruses are icosahedral or near-spherical with chiral
icosahedral symmetry. A
regular icosahedron is the optimum way of forming a closed shell from identical subunits. The minimum number of capsomeres required for each triangular face is 3, which gives 60 for the icosahedron. Many viruses, such as rotavirus, have more than 60 capsomers and appear spherical but they retain this symmetry. To achieve this, the capsomeres at the apices are surrounded by five other capsomeres and are called pentons. Capsomeres on the triangular faces are surrounded by six others and are called
hexons. ; Prolate: This is an icosahedron elongated along the fivefold axis and is a common arrangement of the heads of bacteriophages. This structure is composed of a cylinder with a cap at either end. ; Enveloped:Some species of virus
envelop themselves in a modified form of one of the
cell membranes, either the outer membrane surrounding an infected host cell or internal membranes such as a nuclear membrane or
endoplasmic reticulum, thus gaining an outer lipid bilayer known as a
viral envelope. This membrane is studded with proteins coded for by the viral genome and host genome; the lipid membrane itself and any carbohydrates present originate entirely from the host.
Influenza virus,
HIV (which causes
AIDS), and
severe acute respiratory syndrome coronavirus 2 (which causes
COVID-19) use this strategy. Most enveloped viruses are dependent on the envelope for their infectivity. The
poxviruses are large, complex viruses that have an unusual morphology. The viral genome is associated with proteins within a central disc structure known as a
nucleoid. The nucleoid is surrounded by a membrane and two lateral bodies of unknown function. The virus has an outer envelope with a thick layer of protein studded over its surface. The whole virion is slightly
pleomorphic, ranging from ovoid to brick-shaped.
Giant viruses Mimivirus is one of the largest characterised viruses, with a capsid diameter of 400 nm. Protein filaments measuring 100 nm project from the surface. The capsid appears hexagonal under an electron microscope, therefore the capsid is probably icosahedral. In 2011, researchers discovered the largest then known virus in samples of water collected from the ocean floor off the coast of Las Cruces, Chile. Provisionally named
Megavirus chilensis, it can be seen with a basic optical microscope. In 2013, the
Pandoravirus genus was discovered in Chile and Australia, and has genomes about twice as large as Megavirus and Mimivirus. All giant viruses have dsDNA genomes and they are classified into several families:
Mimiviridae, Pithoviridae, Pandoraviridae, Phycodnaviridae, and the
Mollivirus genus. Some viruses that infect
Archaea have complex structures unrelated to any other form of virus, with a wide variety of unusual shapes, ranging from spindle-shaped structures to viruses that resemble hooked rods, teardrops or even bottles. Other archaeal viruses resemble the tailed bacteriophages, and can have multiple tail structures.
Genome An enormous variety of genomic structures can be seen among
viral species; as a group, they contain more structural genomic diversity than plants, animals, archaea, or bacteria. There are millions of different types of viruses, but there are doubtlessly many more to be discovered. A virus has either a
DNA or an
RNA genome and is called a
DNA virus or an
RNA virus, respectively. Some RNA viruses, for example retroviruses, have a stage in their replication cycle where the genome is encoded in DNA. Most viruses have RNA genomes. Plant viruses tend to have single-stranded RNA genomes and bacteriophages tend to have double-stranded DNA genomes.
Genome size Genome size varies greatly between species. The smallest—the ssDNA circoviruses, family
Circoviridae—code for only two proteins and have a genome size of only two kilobases; the largest—the
pandoraviruses—have genome sizes of around two megabases which code for about 2500 proteins. In general, RNA viruses have smaller genome sizes than DNA viruses because of a higher error-rate when replicating, and have a maximum upper size limit. Single-strand DNA viruses are an exception to this rule, as mutation rates for these genomes can approach the extreme of the ssRNA virus case.
Genetic mutation and recombination Viruses undergo genetic change by several mechanisms. These include a process called
antigenic drift where individual bases in the DNA or RNA
mutate to other bases. Most of these
point mutations are "silent"—they do not change the protein that the gene encodes—but others can confer evolutionary advantages such as resistance to
antiviral drugs.
Antigenic shift occurs when there is a major change in the genome of the virus. This can be a result of
recombination or
reassortment. The
Influenza A virus is highly prone to reassortment; occasionally this has resulted in novel
strains which have caused
pandemics. RNA viruses often exist as
quasispecies or swarms of viruses of the same species but with slightly different genome nucleoside sequences. Such quasispecies are a prime target for natural selection. Segmented genomes confer evolutionary advantages; different strains of a virus with a segmented genome can shuffle and combine genes and produce progeny viruses (or offspring) that have unique characteristics. This is called reassortment or 'viral sex'.
Genetic recombination is a process by which a strand of DNA (or RNA) is broken and then joined to the end of a different DNA (or RNA) molecule. This can occur when viruses infect cells simultaneously and studies of
viral evolution have shown that recombination has been rampant in the species studied. Recombination is common to both RNA and DNA viruses.
Coronaviruses have a single-strand positive-sense
RNA genome. Replication of the
genome is catalyzed by an
RNA-dependent RNA polymerase. The mechanism of
recombination used by coronaviruses likely involves template switching by the polymerase during genome replication. This process appears to be an adaptation for coping with genome damage.
Replication cycle s into bacterial cells (not to scale) Viral populations do not grow through cell division, because they are acellular. Instead, they use the machinery and metabolism of a host cell to produce multiple copies of themselves, and they assemble in the cell. When infected, the host cell is forced to rapidly produce thousands of copies of the original virus. Their life cycle differs greatly between species, but there are six basic stages in their life cycle:
Penetration or
viral entry follows attachment: Virions enter the host cell through receptor-mediated
endocytosis or
membrane fusion. The infection of plant and fungal cells is different from that of animal cells. Plants have a rigid cell wall made of
cellulose, and fungi one of chitin, so most viruses can get inside these cells only after trauma to the cell wall. Bacteria, like plants, have strong cell walls that a virus must breach to infect the cell. Given that bacterial cell walls are much thinner than plant cell walls due to their much smaller size, some viruses have evolved mechanisms that inject their genome into the bacterial cell across the cell wall, while the viral capsid remains outside.
Replication of viruses involves primarily multiplication of the genome. Replication involves the synthesis of viral messenger RNA (mRNA) from "early" genes (with exceptions for positive-sense RNA viruses), viral
protein synthesis, possible assembly of viral proteins, then viral genome replication mediated by early or regulatory protein expression. This may be followed, for complex viruses with larger genomes, by one or more further rounds of mRNA synthesis: "late" gene expression is, in general, of structural or virion proteins.
Assembly – Following the structure-mediated self-assembly of the virus particles, some modification of the proteins often occurs. In viruses such as HIV, this modification (sometimes called maturation) occurs after the virus has been released from the host cell.
Release – Viruses can be
released from the host cell by
lysis, a process that kills the cell by bursting its membrane and cell wall if present: this is a feature of many bacterial and some animal viruses. Some viruses undergo a
lysogenic cycle where the viral genome is incorporated by
genetic recombination into a specific place in the host's chromosome. The viral genome is then known as a "
provirus" or, in the case of bacteriophages a "
prophage". They are susceptible to
antiviral drugs that inhibit the reverse transcriptase enzyme, e.g.
zidovudine and
lamivudine. An example of the first type is
HIV, which is a retrovirus. Examples of the second type are the
Hepadnaviridae, which includes Hepatitis B virus. Often cell death is caused by cessation of its normal activities because of suppression by virus-specific proteins, not all of which are components of the virus particle. The distinction between cytopathic and harmless is gradual. Some viruses, such as
Epstein–Barr virus, can cause cells to proliferate without causing malignancy, while others, such as
papillomaviruses, are established causes of cancer.
Dormant and latent infections Some viruses cause no apparent changes to the infected cell. Cells in which the virus is
latent and inactive show few signs of infection and often function normally. This causes persistent infections and the virus is often dormant for many months or years. This is often the case with
herpes viruses.
Host range Viruses are by far the most abundant biological entities on Earth and they outnumber all the others put together. They infect all types of cellular life including animals, plants,
bacteria and
fungi. The complete set of viruses in an organism or habitat is called the
virome; for example, all human viruses constitute the
human virome.
Novel viruses A
novel virus is one that has not previously been recorded. It can be a virus that is isolated from its
natural reservoir or isolated as the result of
spread to an animal or human host where the virus had not been identified before. It can be an
emergent virus, one that represents a new virus, but it can also be an extant virus that has not been
previously identified. The
SARS-CoV-2 coronavirus that caused the COVID-19 pandemic is an example of a novel virus. == Classification ==