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Marine viruses

January 01, 1970

Marine viruses are defined by their habitat as viruses that are found in marine environments, that is, in the saltwater of seas or oceans or the brackish water of coastal estuaries. Viruses are small infectious agents that can only replicate inside the living cells of a host organism, because they need the replication machinery of the host to do so.[4] They can infect all types of life forms, from animals and plants to microorganisms, including bacteria and archaea.[5]

Structure of a typical virus, in this case a phage.[1] The appearance of these viruses has been likened to a miniature lunar lander.[2] Marine viruses are essential to the regulation of marine ecosystems.[3]

When not inside a cell or in the process of infecting a cell, viruses exist in the form of independent particles called virions. A virion contains a genome (a long molecule that carries genetic information in the form of either DNA or RNA) surrounded by a capsid (a protein coat protecting the genetic material). The shapes of these virus particles range from simple helical and icosahedral forms for some virus species to more complex structures for others. Most virus species have virions that are too small to be seen with an optical microscope. The average virion is about one one-hundredth the linear size of the average bacterium.

A teaspoon of seawater typically contains about fifty million viruses.[6] Most of these viruses are bacteriophages which infect and destroy marine bacteria and control the growth of phytoplankton at the base of the marine food web. Bacteriophages are harmless to plants and animals but are essential to the regulation of marine ecosystems. They supply key mechanisms for recycling ocean carbon and nutrients. In a process known as the viral shunt, organic molecules released from dead bacterial cells stimulate fresh bacterial and algal growth. In particular, the breaking down of bacteria by viruses (lysis) has been shown to enhance nitrogen cycling and stimulate phytoplankton growth. Viral activity also affects the biological pump, the process which sequesters carbon in the deep ocean. By increasing the amount of respiration in the oceans, viruses are indirectly responsible for reducing the amount of carbon dioxide in the atmosphere by approximately 3 gigatonnes of carbon per year.

Marine microorganisms make up about 70% of the total marine biomass. It is estimated marine viruses kill 20% of the microorganism biomass every day. Viruses are the main agents responsible for the rapid destruction of harmful algal blooms which often kill other marine life. The number of viruses in the oceans decreases further offshore and deeper into the water, where there are fewer host organisms. Viruses are an important natural means of transferring genes between different species, which increases genetic diversity and drives evolution. It is thought viruses played a central role in early evolution before the diversification of bacteria, archaea and eukaryotes, at the time of the last universal common ancestor of life on Earth. Viruses are still one of the largest areas of unexplored genetic diversity on Earth.

Background edit

Further information: introduction to viruses and viral evolution

Viruses are now recognised as ancient and as having origins that pre-date the divergence of life into the three domains.[7] They are found wherever there is life and have probably existed since living cells first evolved.[8] The origins of viruses in the evolutionary history of life are unclear because they do not form fossils. Molecular techniques are used to compare the DNA or RNA of viruses and are a useful means of investigating how they arose.[9] Some viruses may have evolved from plasmids—pieces of DNA that can move between cells—while others may have evolved from bacteria. In evolution, viruses are an important means of horizontal gene transfer, which increases genetic diversity.[10]

Opinions differ on whether viruses are a form of life or organic structures that interact with living organisms.[11] They are considered by some to be a life form, because they carry genetic material, reproduce by creating multiple copies of themselves through self-assembly, and evolve through natural selection. However they lack key characteristics such as a cellular structure generally considered necessary to count as life. Because they possess some but not all such qualities, viruses have been described as replicators[12] and as "organisms at the edge of life".[13]

The existence of viruses in the ocean was discovered through electron microscopy and epifluorescence microscopy of ecological water samples, and later through metagenomic sampling of uncultured viral samples.[14][15] Marine viruses, although microscopic and essentially unnoticed by scientists until recently, are the most abundant and diverse biological entities in the ocean. Viruses have an estimated abundance of 1030 in the ocean, or between 106 and 1011 viruses per millilitre.[4] Quantification of marine viruses was originally performed using transmission electron microscopy but has been replaced by epifluorescence or flow cytometry.[16]

Bacteriophages edit

 
Phage injecting its genome into bacteria
Further information: cyanophage and phage ecology

Bacteriophages, often contracted to phages, are viruses that parasitize bacteria for replication. As aptly named, marine phages parasitize marine bacteria, such as cyanobacteria.[17] They are a diverse group of viruses which are the most abundant biological entity in marine environments, because their hosts, bacteria, are typically the numerically dominant cellular life in the sea. There are up to ten times more phages in the oceans than there are bacteria,[18] reaching levels of 250 million bacteriophages per millilitre of seawater.[19] These viruses infect specific bacteria by binding to surface receptor molecules and then entering the cell. Within a short amount of time, in some cases just minutes, bacterial polymerase starts translating viral mRNA into protein. These proteins go on to become either new virions within the cell, helper proteins, which help assembly of new virions, or proteins involved in cell lysis. Viral enzymes aid in the breakdown of the cell membrane, and there are phages that can replicate three hundred phages twenty minutes after injection.[20]

Bacteriophages (phages)
 
Multiple phages attached to a bacterial cell wall at 200,000x magnification
 
Diagram of a typical tailed phage
 
Process of a phage "landing" on a bacterium
The phage first adheres to the cell surface with its tail parallel to or leaning at an angle to the cell surface in the pre-infection stage. The tail then firmly stands on the cell surface and extends its fibers horizontally, rendering the phage infection-competent, after which viral DNA is released into the cell through an extensible tube.[21]
based on observations of the model cyanophage P-SSP7
interacting with the marine Prochlorococcus MED4 bacterium
 
Adsorption of cyanophages onto a marine Prochlorococcus
(a) Slice (~20 nm) through a reconstructed tomogram of P-SSP7 phage incubated with MED4, imaged at ~86 min post-infection. FC and EC show full-DNA capsid phage and empty capsid phage, respectively.
(b) same image visualised by highlighting the cell wall in orange, the plasma membrane in light yellow, the thylakoid membrane in green, carboxysomes in cyan, the polyphosphate body in blue, adsorbed phages on the sides or top of the cell in red, and cytoplasmic granules (probably mostly ribosomes) in light purple.[21]
scale bar: 200 nm

Bacteria defend themselves from bacteriophages by producing enzymes that destroy foreign DNA. These enzymes, called restriction endonucleases, cut up the viral DNA that bacteriophages inject into bacterial cells.[22] Bacteria also contain a system that uses CRISPR sequences to retain fragments of the genomes of viruses that the bacteria have come into contact with in the past, which allows them to block the virus's replication through a form of RNA interference.[23][24] This genetic system provides bacteria with acquired immunity to infection.[25]

 
Cyanophages, viruses that infect cyanobacteria
scale bars: 100 nm
 
The lytic cycle, the reproductive cycle of the bacteriophage, has six stages:
→ attachment: the phage attaches itself to the surface of the host cell
→ penetration: the phage injects its DNA through the cell membrane
→ transcription: the host cell's DNA is degraded and the cell's metabolism
     is directed to initiate phage biosynthesis
→ biosynthesis: the phage DNA replicates inside the cell
→ maturation: the replicated material assembles into fully formed viral phages
lysis: the newly formed phages are released from the infected cell
    (which is itself destroyed in the process) to seek out new host cells [26]

Microbes drive the nutrient transformations that sustain Earth's ecosystems,[27] and the viruses that infect these microbes modulate both microbial population size and diversity.[28][21] The cyanobacterium Prochlorococcus, the most abundant oxygenic phototroph on Earth, contributes a substantial fraction of global primary carbon production, and often reaches densities of over 100,000 cells per milliliter in oligotrophic and temperate oceans.[29] Hence, viral (cyanophage) infection and lysis of Prochlorococcus represent an important component of the global carbon cycle. In addition to their ecological role in inducing host mortality, cyanophages influence the metabolism and evolution of their hosts by co-opting and exchanging genes, including core photosynthesis genes.[21]

 
Tailed V22 phages of Alteromonas bacteria [30]
scale bar : 100 nm
 
The non-tailed phage Corticovirus
 
Virions of different families of tailed phages: Myoviridae, Podoviridae and Siphoviridae

For a long time, tailed phages of the order Caudovirales seemed to dominate marine ecosystems in number and diversity of organisms.[17] However, as a result of more recent research, non-tailed viruses appear to dominate multiple depths and oceanic regions.[31] These non-tailed phages also infect marine bacteria, and include the families Corticoviridae,[32] Inoviridae,[33] Microviridae [34] and Autolykiviridae.[35][36][37][38]

As of September 2023, Halomonas phage vB HmeY H4907 is the first virus isolated from the deepest part of the ocean.[39]

Archaeal viruses edit

 
Evolution of the virus world: origin of the main lineages from the primordial gene pool
Characteristic images of RNA and protein structures are shown for each postulated stage of evolution, and characteristic virion images are shown for the emerging classes of viruses. Thin arrows show the postulated movement of genetic pools between inorganic compartments. Block arrows show the origin of different classes of viruses at different stages of pre-cellular evolution.[5]
Further information: Archaeal viruses

Archaean viruses replicate within archaea: these are double-stranded DNA viruses with unusual and sometimes unique shapes.[40][41] These viruses have been studied in most detail in the thermophilic archaea, particularly the orders Sulfolobales and Thermoproteales.[42] Defences against these viruses involve RNA interference from repetitive DNA sequences within archaean genomes that are related to the genes of the viruses.[43][44] Most archaea have CRISPR–Cas systems as an adaptive defence against viruses. These enable archaea to retain sections of viral DNA, which are then used to target and eliminate subsequent infections by the virus using a process similar to RNA interference.[45]

Fungal viruses edit

Further information: mycovirus

Mycoviruses, also known as mycophages, are viruses that infect fungi. The infection of fungal cells is different from that of animal cells. Fungi have a rigid cell wall made of chitin, so most viruses can get inside these cells only after trauma to the cell wall.[46]

  • See, Nerva L, Ciuffo M, Vallino M, Margaria P, Varese G, Gnavi G, Turina M (2016). "Multiple approaches for the detection and characterization of viral and plasmid symbionts from a collection of marine fungi". Virus Research. 219: 22–38. doi:10.1016/j.virusres.2015.10.028. hdl:2318/1527617. PMID 26546154. S2CID 53417720.

Eukaryote viruses edit

 
The second melting pot of virus evolution: origin of eukaryotic viruses. Characteristic images of archaeal, bacterial, and eukaryotic viruses are shown.[5]

Marine protists edit

By 2015, about 40 viruses affecting marine protists had been isolated and examined, most of them viruses of microalgae.[47] The genomes of these marine protist viruses are highly diverse.[48][49] Marine algae can be infected by viruses in the family Phycodnaviridae. These are large (100–560 kb) double-stranded DNA viruses with icosahedral shaped capsids. By 2014, 33 species divided into six genera had been identified within the family,[50][51] which belongs to a super-group of large viruses known as nucleocytoplasmic large DNA viruses. Evidence was published in 2014 suggesting some strains of Phycodnaviridae might infect humans rather than just algal species, as was previously believed.[52] Most genera under this family enter the host cell by cell receptor endocytosis and replicate in the nucleus.

 
A giant coccolithovirus, Emiliania huxleyi virus 86 (arrowed), infecting an Emiliania huxleyi coccolithophore

Phycodnaviridae play important ecological roles by regulating the growth and productivity of their algal hosts. Algal species such Heterosigma akashiwo and the genus Chrysochromulina can form dense blooms which can be damaging to fisheries, resulting in losses in the aquaculture industry.[53] Heterosigma akashiwo virus (HaV) has been suggested for use as a microbial agent to prevent the recurrence of toxic red tides produced by this algal species.[54] The coccolithovirus Emiliania huxleyi virus 86, a giant double-stranded DNA virus, infects the ubiquitous coccolithophore Emiliania huxleyi.[50][51] This virus has one of the largest known genomes among marine viruses.[55] Phycodnaviridae cause death and lysis of freshwater and marine algal species, liberating organic carbon, nitrogen and phosphorus into the water, providing nutrients for the microbial loop.[56]

The virus-to-prokaryote ratio, VPR, is often used as an indicator of the relationship between viruses and hosts. Studies have used VPR to indirectly infer virus impact on marine microbial productivity, mortality, and biogeochemical cycling.[57] However, in making these approximations, scientists assume a VPR of 10:1, the median observed VPR in the surface ocean.[57][18] The actual VPR varies greatly depending on location, so VPR may not be the accurate proxy for viral activity or abundance as it has been treated.[57][58]

Marine invertebrates edit

 
Virus-host interactions in the marine ecosystem,
including viral infection of bacteria, phytoplankton and fish[59]

Marine invertebrates are susceptible to viral diseases.[60][61][62] Sea star wasting disease is a disease of starfish and several other echinoderms that appears sporadically, causing mass mortality of those affected.[63] There are around 40 different species of sea stars that have been affected by this disease. In 2014 it was suggested that the disease is associated with a single-stranded DNA virus now known as the sea star-associated densovirus (SSaDV); however, sea star wasting disease is not fully understood.[64]

Marine vertebrates edit

Fish are particularly prone to infections with rhabdoviruses, which are distinct from, but related to rabies virus. At least nine types of rhabdovirus cause economically important diseases in species including salmon, pike, perch, sea bass, carp and cod. The symptoms include anaemia, bleeding, lethargy and a mortality rate that is affected by the temperature of the water. In hatcheries the diseases are often controlled by increasing the temperature to 15–18 °C.[65]: 442–443  Like all vertebrates, fish suffer from herpes viruses. These ancient viruses have co-evolved with their hosts and are highly species-specific.[65]: 324  In fish, they cause cancerous tumours and non-cancerous growths called hyperplasia.[65]: 325 

In 1984, infectious salmon anemia (ISAv) was discovered in Norway in an Atlantic salmon hatchery. Eighty per cent of the fish in the outbreak died. ISAv, a viral disease, is now a major threat to the viability of Atlantic salmon farming.[66] As the name implies, it causes severe anemia of infected fish. Unlike mammals, the red blood cells of fish have DNA and can become infected with viruses. Management strategies include developing a vaccine and improving genetic resistance to the disease.[67]

Marine mammals are also susceptible to marine viral infections. In 1988 and 2002, thousands of harbour seals were killed in Europe by phocine distemper virus.[68] Many other viruses, including caliciviruses, herpesviruses, adenoviruses and parvoviruses, circulate in marine mammal populations.[69]

Giant marine viruses edit

Most viruses range in length from about 20 to 300 nanometers. This can be contrasted with the length of bacteria, which starts at about 400 nanometers. There are also giant viruses, often called giruses, typically about 1000 nanometers (one micron) in length. All giant viruses belong to the phylum Nucleocytoviricota (NCLDV), together with poxviruses. The largest known of these is Tupanvirus. This genus of giant virus was discovered in 2018 in the deep ocean as well as a soda lake, and can reach up to 2.3 microns in total length.[70]

 
The largest known virus, Tupanvirus, named after Tupã, the Guarani supreme god of creation

The discovery and subsequent characterization of giant viruses has triggered some debate concerning their evolutionary origins. The two main hypotheses for their origin are that either they evolved from small viruses, picking up DNA from host organisms, or that they evolved from very complicated organisms into the current form which is not self-sufficient for reproduction.[72] What sort of complicated organism giant viruses might have diverged from is also a topic of debate. One proposal is that the origin point actually represents a fourth domain of life,[73][74] but this has been largely discounted.[75][76]

Virophages edit

Further information: Virophages

Virophages are small, double-stranded DNA viruses that rely on the co-infection of giant viruses. Virophages rely on the viral replication factory of the co-infecting giant virus for their own replication. One of the characteristics of virophages is that they have a parasitic relationship with the co-infecting virus. Their dependence upon the giant virus for replication often results in the deactivation of the giant viruses. The virophage may improve the recovery and survival of the host organism. Unlike other satellite viruses, virophages have a parasitic effect on their co-infecting virus. Virophages have been observed to render a giant virus inactive and thereby improve the condition of the host organism.

All known virophages are grouped into the family Lavidaviridae (from "large virus dependent or associated" + -viridae).[77] The first virophage was discovered in a cooling tower in Paris in 2008. It was discovered with its co-infecting giant virus, Acanthamoeba castellanii mamavirus (ACMV). The virophage was named Sputnik and its replication relied entirely on the co-infection of ACMV and its cytoplasmic replication machinery. Sputnik was also discovered to have an inhibitory effect on ACMV and improved the survival of the host. Other characterised virophages include Sputnik 2, Sputnik 3, Zamilon and Mavirus.[78][79]

Most of these virophages were discovered by analyzing metagenomic data sets. In metagenomic analysis, DNA sequences are run through multiple bioinformatic algorithms which pull out certain important patterns and characteristics. In these data sets are giant viruses and virophages. They are separated by looking for sequences around 17 to 20 kbp long which have similarities to already sequenced virophages. These virophages can have linear or circular double-stranded DNA genomes.[80] Virophages in culture have icosahedral capsid particles that measure around 40 to 80 nanometers long.[81] Virophage particles are so small that electron microscopy must be used to view these particles. Metagenomic sequence-based analyses have been used to predict around 57 complete and partial virophage genomes[82] and in December 2019 to identify 328 high-quality (complete or near-complete) genomes from diverse habitats including the human gut, plant rhizosphere, and terrestrial subsurface, from 27 distinct taxonomic clades.[83]

 
The giant virus CroV attacks C.roenbergensis
 
Cafeteria roenbergensis a bacterivorous marine flagellate
 
A Mavirus virophage (lower left) alongside a giant CroV [84]

A giant marine virus CroV infects and causes the death by lysis of the marine zooflagellate Cafeteria roenbergensis.[85] This impacts coastal ecology because Cafeteria roenbergensis feeds on bacteria found in the water. When there are low numbers of Cafeteria roenbergensis due to extensive CroV infections, the bacterial populations rise exponentially.[86] The impact of CroV on natural populations of C. roenbergensis remains unknown; however, the virus has been found to be very host specific, and does not infect other closely related organisms.[87] Cafeteria roenbergensis is also infected by a second virus, the Mavirus virophage, during co-infection with CroV.[78] This virus interferes with the replication of CroV, which leads to the survival of C. roenbergensis cells. Mavirus is able to integrate into the genome of cells of C. roenbergensis and thereby confer immunity to the population.[79]

Role of marine viruses edit

Although marine viruses have only recently been studied extensively, they are already known to hold critical roles in many ecosystem functions and cycles.[88] Marine viruses offer a number of important ecosystem services and are essential to the regulation of marine ecosystems.[3] Marine bacteriophages and other viruses appear to influence biogeochemical cycles globally, provide and regulate microbial biodiversity, cycle carbon through marine food webs, and are essential in preventing bacterial population explosions.[89]

Viral shunt edit

 
The cycling of marine phytoplankton is helped by viral lysis[90]
Main article: Viral shunt

The dominant hosts for viruses in the ocean are marine microorganisms, such as bacteria.[14] Bacteriophages are harmless to plants and animals, and are essential to the regulation of marine and freshwater ecosystems[91] are important mortality agents of phytoplankton, the base of the foodchain in aquatic environments.[92] They infect and destroy bacteria in aquatic microbial communities, and are one of the most important mechanisms of recycling carbon and nutrient cycling in marine environments. The organic molecules released from the dead bacterial cells stimulate fresh bacterial and algal growth, in a process known as the viral shunt.[93]

In this way, marine viruses are thought to play an important role in nutrient cycles by increasing the efficiency of the biological pump. Viruses cause lysis of living cells, that is, they break the cell membranes down. This releases compounds such as amino acids and nucleic acids, which tend to be recycled near the surface.

Viral activity also enhances the ability of the biological pump to sequester carbon in the deep ocean.[69] Lysis releases more indigestible carbon-rich material like that found in cell walls, which is likely exported to deeper waters. Thus, the material that is exported to deeper waters by the viral shunt is probably more carbon rich than the material from which it was derived.[94][95] By increasing the amount of respiration in the oceans, viruses are indirectly responsible for reducing the amount of carbon dioxide in the atmosphere by about three gigatonnes of carbon per year.[69] Lysis of bacteria by viruses has been shown to also enhance nitrogen cycling and stimulate phytoplankton growth.[96]

The viral shunt pathway is a mechanism that prevents (prokaryotic and eukaryotic) marine microbial particulate organic matter (POM) from migrating up trophic levels by recycling them into dissolved organic matter (DOM), which can be readily taken up by microorganisms. Viral shunting helps maintain diversity within the microbial ecosystem by preventing a single species of marine microbe from dominating the micro-environment.[97] The DOM recycled by the viral shunt pathway is comparable to the amount generated by the other main sources of marine DOM.[98]

 
The viral shunt pathway facilitates the flow of dissolved organic matter (DOM) and particulate organic matter (POM) through the marine food web
 
Connections between the different compartments of the living (bacteria/viruses and phytoplankton/zooplankton) and the nonliving (DOM/POM and inorganic matter) environment [99]

Viruses are the most abundant biological entity in marine environments.[5] On average there are about ten million of them in one milliliter of seawater.[100] Most of these viruses are bacteriophages infecting heterotrophic bacteria and cyanophages infecting cyanobacteria. Viruses easily infect microorganisms in the microbial loop due to their relative abundance compared to microbes.[101] Prokaryotic and eukaryotic mortality contribute to carbon nutrient recycling through cell lysis. There is evidence as well of nitrogen (specifically ammonium) regeneration. This nutrient recycling helps stimulates microbial growth.[102] As much as 25% of the primary production from phytoplankton in the global oceans may be recycled within the microbial loop through viral shunting.[103]

Limiting algal blooms edit

Microorganisms make up about 70% of the marine biomass.[104] It is estimated viruses kill 20% of the microorganism biomass each day and that there are 15 times as many viruses in the oceans as there are bacteria and archaea. Viruses are the main agents responsible for the rapid destruction of harmful algal blooms,[105] which often kill other marine life.[106] Scientists are exploring the potential of marine cyanophages to be used to prevent or reverse eutrophication. The number of viruses in the oceans decreases further offshore and deeper into the water, where there are fewer host organisms.[107]

Gene transfer edit

Marine bacteriophages often contain auxiliary metabolic genes, host-derived genes thought to sustain viral replication by supplementing host metabolism during viral infection.[108]  These genes can impact multiple biogeochemical cycles, including carbon, phosphorus, sulfur, and nitrogen.[109][110][111][112]

Viruses are an important natural means of transferring genes between different species, which increases genetic diversity and drives evolution.[10] It is thought viruses played a central role in early evolution, before bacteria, archaea and eukaryotes diversified, at the time of the last universal common ancestor of life on Earth.[113] Viruses are still one of the largest reservoirs of unexplored genetic diversity on Earth.[107]

Marine habitats edit

Along the coast edit

See also: Mangrove virome

Marine coastal habitats sit at the interface between the land and the ocean. It is likely that RNA viruses play significant roles in these environments.[114]

At the ocean surface edit

 
Viral–bacterial dynamics in the surface microlayer (SML) of the ocean and beyond. DOM = dissolved organic matter, UV = ultraviolet.[115]
See also: Sea surface microlayer

Marine surface habitats sit at the interface between the atmosphere and the ocean. The biofilm-like habitat at the surface of the ocean harbours surface-dwelling microorganisms, commonly referred to as neuston. Viruses in the microlayer, the so-called virioneuston, have recently become of interest to researchers as enigmatic biological entities in the boundary surface layers with potentially important ecological impacts. Given this vast air–water interface sits at the intersection of major air–water exchange processes spanning more than 70% of the global surface area, it is likely to have profound implications for marine biogeochemical cycles, on the microbial loop and gas exchange, as well as the marine food web structure, the global dispersal of airborne viruses originating from the sea surface microlayer, and human health.[115]

In the water column edit

Marine viral activity presents a potential explanation of the paradox of the plankton proposed by George Hutchinson in 1961.[116] The paradox of the plankton is that many plankton species have been identified in small regions in the ocean where limited resources should create competitive exclusion, limiting the number of coexisting species.[116] Marine viruses could play a role in this effect, as viral infection increases as potential contact with hosts increases.[4] Viruses could therefore control the populations of plankton species that grow too abundant, allowing a wide diversity of species to coexist.[4]

In sediments edit

See also: marine sediments

Marine bacteriophages play an important role in deep sea ecosystems. There are between 5x1012 and 1x1013 phages per square metre in deep sea sediments and their abundance closely correlates with the number of prokaryotes found in the sediments. They are responsible for the death of 80% of the prokaryotes found in the sediments, and almost all of these deaths are caused by cell lysis (bursting). This allows nitrogen, carbon, and phosphorus from the living cells to be converted into dissolved organic matter and detritus, contributing to the high rate of nutrient turnover in deep sea sediments. Because of the importance of deep sea sediments in biogeochemical cycles, marine bacteriophages influence the carbon, nitrogen and phosphorus cycles. More research needs to be done to more precisely elucidate these influences.[117]

In hydrothermal vents edit

Further information: hydrothermal vent microbial community

Viruses are part of the hydrothermal vent microbial community and their influence on the microbial ecology in these ecosystems is a burgeoning field of research.[118] Viruses are the most abundant life in the ocean, harboring the greatest reservoir of genetic diversity.[105] As their infections are often fatal, they constitute a significant source of mortality and thus have widespread influence on biological oceanographic processes, evolution and biogeochemical cycling within the ocean.[107] Evidence has been found however to indicate that viruses found in vent habitats have adopted a more mutualistic than parasitic evolutionary strategy in order to survive the extreme and volatile environment they exist in.[119] Deep-sea hydrothermal vents were found to have high numbers of viruses indicating high viral production.[120] Like in other marine environments, deep-sea hydrothermal viruses affect abundance and diversity of prokaryotes and therefore impact microbial biogeochemical cycling by lysing their hosts to replicate.[121] However, in contrast to their role as a source of mortality and population control, viruses have also been postulated to enhance survival of prokaryotes in extreme environments, acting as reservoirs of genetic information. The interactions of the virosphere with microorganisms under environmental stresses is therefore thought to aide microorganism survival through dispersal of host genes through horizontal gene transfer.[122]

Polar regions edit

Further information: Marine food web § Polar microorganisms

In addition to varied topographies and in spite of an extremely cold climate, the polar aquatic regions are teeming with microbial life. Even in sub-glacial regions, cellular life has adapted to these extreme environments where perhaps there are traces of early microbes on Earth. As grazing by macrofauna is limited in most of these polar regions, viruses are being recognised for their role as important agents of mortality, thereby influencing the biogeochemical cycling of nutrients that, in turn, impact community dynamics at seasonal and spatial scales.[123] The polar regions are characterised by truncated food webs, and the role of viruses in ecosystem function is likely to be even greater than elsewhere in the marine food web, yet their diversity is still relatively under-explored, and the way in which they affect polar communities is not well understood,[124] particularly in nutrient cycling.[125][126][127][123]

Distribution edit

Viruses are highly host specific.[128] A marine virus is more likely to infect cooccurring organisms, those that live in the same region the virus lives in.[129] Therefore, biogeography is an important factor in a virion's ability to infect.

Knowledge of this variation in viral populations across spatiotemporal and other environmental gradients is supported by viral morphology, as determined by transmission electron microscopy (TEM).  Non-tailed viruses appear to be dominant in multiple depths and oceanic regions, followed by the Caudovirales myoviruses, podoviruses, and siphoviruses.[31] However, viruses belonging to families Corticoviridae,[130] Inoviridae[131] and Microviridae[132] are also known to infect diverse marine bacteria. Metagenomic evidence suggests that microviruses (icosahedral ssDNA phages) are particularly prevalent in marine habitats.[132]

Metagenomic approaches to assess viral diversity are often limited by a lack of reference sequences, leaving many sequences unannotated.[133]  However, viral contigs are generated through direct sequencing of a viral fraction, typically generated after 0.02-um filtration of a marine water sample, or through bioinformatics approaches to identify viral contigs or viral genomes from a microbial metagenome.  Novel tools to identify putative viral contigs, such as VirSorter[134] and VirFinder,[135] allow for the assessment of patterns of viral abundance, host range, and functional content of marine bacteriophage.[136][137]

See also edit

References edit

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January 01, 1970
marine, viruses, defined, their, habitat, viruses, that, found, marine, environments, that, saltwater, seas, oceans, brackish, water, coastal, estuaries, viruses, small, infectious, agents, that, only, replicate, inside, living, cells, host, organism, because,. Marine viruses are defined by their habitat as viruses that are found in marine environments that is in the saltwater of seas or oceans or the brackish water of coastal estuaries Viruses are small infectious agents that can only replicate inside the living cells of a host organism because they need the replication machinery of the host to do so 4 They can infect all types of life forms from animals and plants to microorganisms including bacteria and archaea 5 Structure of a typical virus in this case a phage 1 The appearance of these viruses has been likened to a miniature lunar lander 2 Marine viruses are essential to the regulation of marine ecosystems 3 When not inside a cell or in the process of infecting a cell viruses exist in the form of independent particles called virions A virion contains a genome a long molecule that carries genetic information in the form of either DNA or RNA surrounded by a capsid a protein coat protecting the genetic material The shapes of these virus particles range from simple helical and icosahedral forms for some virus species to more complex structures for others Most virus species have virions that are too small to be seen with an optical microscope The average virion is about one one hundredth the linear size of the average bacterium A teaspoon of seawater typically contains about fifty million viruses 6 Most of these viruses are bacteriophages which infect and destroy marine bacteria and control the growth of phytoplankton at the base of the marine food web Bacteriophages are harmless to plants and animals but are essential to the regulation of marine ecosystems They supply key mechanisms for recycling ocean carbon and nutrients In a process known as the viral shunt organic molecules released from dead bacterial cells stimulate fresh bacterial and algal growth In particular the breaking down of bacteria by viruses lysis has been shown to enhance nitrogen cycling and stimulate phytoplankton growth Viral activity also affects the biological pump the process which sequesters carbon in the deep ocean By increasing the amount of respiration in the oceans viruses are indirectly responsible for reducing the amount of carbon dioxide in the atmosphere by approximately 3 gigatonnes of carbon per year Marine microorganisms make up about 70 of the total marine biomass It is estimated marine viruses kill 20 of the microorganism biomass every day Viruses are the main agents responsible for the rapid destruction of harmful algal blooms which often kill other marine life The number of viruses in the oceans decreases further offshore and deeper into the water where there are fewer host organisms Viruses are an important natural means of transferring genes between different species which increases genetic diversity and drives evolution It is thought viruses played a central role in early evolution before the diversification of bacteria archaea and eukaryotes at the time of the last universal common ancestor of life on Earth Viruses are still one of the largest areas of unexplored genetic diversity on Earth Contents 1 Background 2 Bacteriophages 3 Archaeal viruses 4 Fungal viruses 5 Eukaryote viruses 5 1 Marine protists 5 2 Marine invertebrates 5 3 Marine vertebrates 6 Giant marine viruses 7 Virophages 8 Role of marine viruses 8 1 Viral shunt 8 2 Limiting algal blooms 8 3 Gene transfer 9 Marine habitats 9 1 Along the coast 9 2 At the ocean surface 9 3 In the water column 9 4 In sediments 9 5 In hydrothermal vents 9 6 Polar regions 9 7 Distribution 10 See also 11 ReferencesBackground editFurther information introduction to viruses and viral evolution Viruses are now recognised as ancient and as having origins that pre date the divergence of life into the three domains 7 They are found wherever there is life and have probably existed since living cells first evolved 8 The origins of viruses in the evolutionary history of life are unclear because they do not form fossils Molecular techniques are used to compare the DNA or RNA of viruses and are a useful means of investigating how they arose 9 Some viruses may have evolved from plasmids pieces of DNA that can move between cells while others may have evolved from bacteria In evolution viruses are an important means of horizontal gene transfer which increases genetic diversity 10 Opinions differ on whether viruses are a form of life or organic structures that interact with living organisms 11 They are considered by some to be a life form because they carry genetic material reproduce by creating multiple copies of themselves through self assembly and evolve through natural selection However they lack key characteristics such as a cellular structure generally considered necessary to count as life Because they possess some but not all such qualities viruses have been described as replicators 12 and as organisms at the edge of life 13 The existence of viruses in the ocean was discovered through electron microscopy and epifluorescence microscopy of ecological water samples and later through metagenomic sampling of uncultured viral samples 14 15 Marine viruses although microscopic and essentially unnoticed by scientists until recently are the most abundant and diverse biological entities in the ocean Viruses have an estimated abundance of 1030 in the ocean or between 106 and 1011 viruses per millilitre 4 Quantification of marine viruses was originally performed using transmission electron microscopy but has been replaced by epifluorescence or flow cytometry 16 Bacteriophages edit nbsp Phage injecting its genome into bacteria Further information cyanophage and phage ecology Bacteriophages often contracted to phages are viruses that parasitize bacteria for replication As aptly named marine phages parasitize marine bacteria such as cyanobacteria 17 They are a diverse group of viruses which are the most abundant biological entity in marine environments because their hosts bacteria are typically the numerically dominant cellular life in the sea There are up to ten times more phages in the oceans than there are bacteria 18 reaching levels of 250 million bacteriophages per millilitre of seawater 19 These viruses infect specific bacteria by binding to surface receptor molecules and then entering the cell Within a short amount of time in some cases just minutes bacterial polymerase starts translating viral mRNA into protein These proteins go on to become either new virions within the cell helper proteins which help assembly of new virions or proteins involved in cell lysis Viral enzymes aid in the breakdown of the cell membrane and there are phages that can replicate three hundred phages twenty minutes after injection 20 Bacteriophages phages nbsp Multiple phages attached to a bacterial cell wall at 200 000x magnification nbsp Diagram of a typical tailed phage nbsp Process of a phage landing on a bacterium The phage first adheres to the cell surface with its tail parallel to or leaning at an angle to the cell surface in the pre infection stage The tail then firmly stands on the cell surface and extends its fibers horizontally rendering the phage infection competent after which viral DNA is released into the cell through an extensible tube 21 based on observations of the model cyanophage P SSP7interacting with the marine Prochlorococcus MED4 bacterium nbsp Adsorption of cyanophages onto a marine Prochlorococcus a Slice 20 nm through a reconstructed tomogram of P SSP7 phage incubated with MED4 imaged at 86 min post infection FC and EC show full DNA capsid phage and empty capsid phage respectively b same image visualised by highlighting the cell wall in orange the plasma membrane in light yellow the thylakoid membrane in green carboxysomes in cyan the polyphosphate body in blue adsorbed phages on the sides or top of the cell in red and cytoplasmic granules probably mostly ribosomes in light purple 21 scale bar 200 nm Bacteria defend themselves from bacteriophages by producing enzymes that destroy foreign DNA These enzymes called restriction endonucleases cut up the viral DNA that bacteriophages inject into bacterial cells 22 Bacteria also contain a system that uses CRISPR sequences to retain fragments of the genomes of viruses that the bacteria have come into contact with in the past which allows them to block the virus s replication through a form of RNA interference 23 24 This genetic system provides bacteria with acquired immunity to infection 25 nbsp Cyanophages viruses that infect cyanobacteriascale bars 100 nm nbsp The lytic cycle the reproductive cycle of the bacteriophage has six stages attachment the phage attaches itself to the surface of the host cell penetration the phage injects its DNA through the cell membrane transcription the host cell s DNA is degraded and the cell s metabolism is directed to initiate phage biosynthesis biosynthesis the phage DNA replicates inside the cell maturation the replicated material assembles into fully formed viral phages lysis the newly formed phages are released from the infected cell which is itself destroyed in the process to seek out new host cells 26 Microbes drive the nutrient transformations that sustain Earth s ecosystems 27 and the viruses that infect these microbes modulate both microbial population size and diversity 28 21 The cyanobacterium Prochlorococcus the most abundant oxygenic phototroph on Earth contributes a substantial fraction of global primary carbon production and often reaches densities of over 100 000 cells per milliliter in oligotrophic and temperate oceans 29 Hence viral cyanophage infection and lysis of Prochlorococcus represent an important component of the global carbon cycle In addition to their ecological role in inducing host mortality cyanophages influence the metabolism and evolution of their hosts by co opting and exchanging genes including core photosynthesis genes 21 nbsp Tailed V22 phages of Alteromonas bacteria 30 scale bar 100 nm nbsp The non tailed phage Corticovirus nbsp Virions of different families of tailed phages Myoviridae Podoviridae and Siphoviridae For a long time tailed phages of the order Caudovirales seemed to dominate marine ecosystems in number and diversity of organisms 17 However as a result of more recent research non tailed viruses appear to dominate multiple depths and oceanic regions 31 These non tailed phages also infect marine bacteria and include the families Corticoviridae 32 Inoviridae 33 Microviridae 34 and Autolykiviridae 35 36 37 38 As of September 2023 Halomonas phage vB HmeY H4907 is the first virus isolated from the deepest part of the ocean 39 Archaeal viruses edit nbsp Evolution of the virus world origin of the main lineages from the primordial gene pool Characteristic images of RNA and protein structures are shown for each postulated stage of evolution and characteristic virion images are shown for the emerging classes of viruses Thin arrows show the postulated movement of genetic pools between inorganic compartments Block arrows show the origin of different classes of viruses at different stages of pre cellular evolution 5 Further information Archaeal viruses Archaean viruses replicate within archaea these are double stranded DNA viruses with unusual and sometimes unique shapes 40 41 These viruses have been studied in most detail in the thermophilic archaea particularly the orders Sulfolobales and Thermoproteales 42 Defences against these viruses involve RNA interference from repetitive DNA sequences within archaean genomes that are related to the genes of the viruses 43 44 Most archaea have CRISPR Cas systems as an adaptive defence against viruses These enable archaea to retain sections of viral DNA which are then used to target and eliminate subsequent infections by the virus using a process similar to RNA interference 45 Fungal viruses editFurther information mycovirus Mycoviruses also known as mycophages are viruses that infect fungi The infection of fungal cells is different from that of animal cells Fungi have a rigid cell wall made of chitin so most viruses can get inside these cells only after trauma to the cell wall 46 See Nerva L Ciuffo M Vallino M Margaria P Varese G Gnavi G Turina M 2016 Multiple approaches for the detection and characterization of viral and plasmid symbionts from a collection of marine fungi Virus Research 219 22 38 doi 10 1016 j virusres 2015 10 028 hdl 2318 1527617 PMID 26546154 S2CID 53417720 Eukaryote viruses edit nbsp The second melting pot of virus evolution origin of eukaryotic viruses Characteristic images of archaeal bacterial and eukaryotic viruses are shown 5 Marine protists edit By 2015 about 40 viruses affecting marine protists had been isolated and examined most of them viruses of microalgae 47 The genomes of these marine protist viruses are highly diverse 48 49 Marine algae can be infected by viruses in the family Phycodnaviridae These are large 100 560 kb double stranded DNA viruses with icosahedral shaped capsids By 2014 33 species divided into six genera had been identified within the family 50 51 which belongs to a super group of large viruses known as nucleocytoplasmic large DNA viruses Evidence was published in 2014 suggesting some strains of Phycodnaviridae might infect humans rather than just algal species as was previously believed 52 Most genera under this family enter the host cell by cell receptor endocytosis and replicate in the nucleus nbsp A giant coccolithovirus Emiliania huxleyi virus 86 arrowed infecting an Emiliania huxleyi coccolithophore Phycodnaviridae play important ecological roles by regulating the growth and productivity of their algal hosts Algal species such Heterosigma akashiwo and the genus Chrysochromulina can form dense blooms which can be damaging to fisheries resulting in losses in the aquaculture industry 53 Heterosigma akashiwo virus HaV has been suggested for use as a microbial agent to prevent the recurrence of toxic red tides produced by this algal species 54 The coccolithovirus Emiliania huxleyi virus 86 a giant double stranded DNA virus infects the ubiquitous coccolithophore Emiliania huxleyi 50 51 This virus has one of the largest known genomes among marine viruses 55 Phycodnaviridae cause death and lysis of freshwater and marine algal species liberating organic carbon nitrogen and phosphorus into the water providing nutrients for the microbial loop 56 The virus to prokaryote ratio VPR is often used as an indicator of the relationship between viruses and hosts Studies have used VPR to indirectly infer virus impact on marine microbial productivity mortality and biogeochemical cycling 57 However in making these approximations scientists assume a VPR of 10 1 the median observed VPR in the surface ocean 57 18 The actual VPR varies greatly depending on location so VPR may not be the accurate proxy for viral activity or abundance as it has been treated 57 58 Marine invertebrates edit nbsp Virus host interactions in the marine ecosystem including viral infection of bacteria phytoplankton and fish 59 Marine invertebrates are susceptible to viral diseases 60 61 62 Sea star wasting disease is a disease of starfish and several other echinoderms that appears sporadically causing mass mortality of those affected 63 There are around 40 different species of sea stars that have been affected by this disease In 2014 it was suggested that the disease is associated with a single stranded DNA virus now known as the sea star associated densovirus SSaDV however sea star wasting disease is not fully understood 64 Marine vertebrates edit Fish are particularly prone to infections with rhabdoviruses which are distinct from but related to rabies virus At least nine types of rhabdovirus cause economically important diseases in species including salmon pike perch sea bass carp and cod The symptoms include anaemia bleeding lethargy and a mortality rate that is affected by the temperature of the water In hatcheries the diseases are often controlled by increasing the temperature to 15 18 C 65 442 443 Like all vertebrates fish suffer from herpes viruses These ancient viruses have co evolved with their hosts and are highly species specific 65 324 In fish they cause cancerous tumours and non cancerous growths called hyperplasia 65 325 In 1984 infectious salmon anemia ISAv was discovered in Norway in an Atlantic salmon hatchery Eighty per cent of the fish in the outbreak died ISAv a viral disease is now a major threat to the viability of Atlantic salmon farming 66 As the name implies it causes severe anemia of infected fish Unlike mammals the red blood cells of fish have DNA and can become infected with viruses Management strategies include developing a vaccine and improving genetic resistance to the disease 67 Marine mammals are also susceptible to marine viral infections In 1988 and 2002 thousands of harbour seals were killed in Europe by phocine distemper virus 68 Many other viruses including caliciviruses herpesviruses adenoviruses and parvoviruses circulate in marine mammal populations 69 Giant marine viruses editMost viruses range in length from about 20 to 300 nanometers This can be contrasted with the length of bacteria which starts at about 400 nanometers There are also giant viruses often called giruses typically about 1000 nanometers one micron in length All giant viruses belong to the phylum Nucleocytoviricota NCLDV together with poxviruses The largest known of these is Tupanvirus This genus of giant virus was discovered in 2018 in the deep ocean as well as a soda lake and can reach up to 2 3 microns in total length 70 nbsp The largest known virus Tupanvirus named after Tupa the Guarani supreme god of creation nbsp The giant mimivirus nbsp Cryo electron micrograph of the CroV giant virus 71 scale bar 0 2 µm The discovery and subsequent characterization of giant viruses has triggered some debate concerning their evolutionary origins The two main hypotheses for their origin are that either they evolved from small viruses picking up DNA from host organisms or that they evolved from very complicated organisms into the current form which is not self sufficient for reproduction 72 What sort of complicated organism giant viruses might have diverged from is also a topic of debate One proposal is that the origin point actually represents a fourth domain of life 73 74 but this has been largely discounted 75 76 Virophages editFurther information Virophages Virophages are small double stranded DNA viruses that rely on the co infection of giant viruses Virophages rely on the viral replication factory of the co infecting giant virus for their own replication One of the characteristics of virophages is that they have a parasitic relationship with the co infecting virus Their dependence upon the giant virus for replication often results in the deactivation of the giant viruses The virophage may improve the recovery and survival of the host organism Unlike other satellite viruses virophages have a parasitic effect on their co infecting virus Virophages have been observed to render a giant virus inactive and thereby improve the condition of the host organism All known virophages are grouped into the family Lavidaviridae from large virus dependent or associated viridae 77 The first virophage was discovered in a cooling tower in Paris in 2008 It was discovered with its co infecting giant virus Acanthamoeba castellanii mamavirus ACMV The virophage was named Sputnik and its replication relied entirely on the co infection of ACMV and its cytoplasmic replication machinery Sputnik was also discovered to have an inhibitory effect on ACMV and improved the survival of the host Other characterised virophages include Sputnik 2 Sputnik 3 Zamilon and Mavirus 78 79 Most of these virophages were discovered by analyzing metagenomic data sets In metagenomic analysis DNA sequences are run through multiple bioinformatic algorithms which pull out certain important patterns and characteristics In these data sets are giant viruses and virophages They are separated by looking for sequences around 17 to 20 kbp long which have similarities to already sequenced virophages These virophages can have linear or circular double stranded DNA genomes 80 Virophages in culture have icosahedral capsid particles that measure around 40 to 80 nanometers long 81 Virophage particles are so small that electron microscopy must be used to view these particles Metagenomic sequence based analyses have been used to predict around 57 complete and partial virophage genomes 82 and in December 2019 to identify 328 high quality complete or near complete genomes from diverse habitats including the human gut plant rhizosphere and terrestrial subsurface from 27 distinct taxonomic clades 83 nbsp The giant virus CroV attacks C roenbergensis nbsp Cafeteria roenbergensis a bacterivorous marine flagellate nbsp A Mavirus virophage lower left alongside a giant CroV 84 A giant marine virus CroV infects and causes the death by lysis of the marine zooflagellate Cafeteria roenbergensis 85 This impacts coastal ecology because Cafeteria roenbergensis feeds on bacteria found in the water When there are low numbers of Cafeteria roenbergensis due to extensive CroV infections the bacterial populations rise exponentially 86 The impact of CroV on natural populations of C roenbergensis remains unknown however the virus has been found to be very host specific and does not infect other closely related organisms 87 Cafeteria roenbergensis is also infected by a second virus the Mavirus virophage during co infection with CroV 78 This virus interferes with the replication of CroV which leads to the survival of C roenbergensis cells Mavirus is able to integrate into the genome of cells of C roenbergensis and thereby confer immunity to the population 79 Role of marine viruses editAlthough marine viruses have only recently been studied extensively they are already known to hold critical roles in many ecosystem functions and cycles 88 Marine viruses offer a number of important ecosystem services and are essential to the regulation of marine ecosystems 3 Marine bacteriophages and other viruses appear to influence biogeochemical cycles globally provide and regulate microbial biodiversity cycle carbon through marine food webs and are essential in preventing bacterial population explosions 89 Viral shunt edit nbsp The cycling of marine phytoplankton is helped by viral lysis 90 Main article Viral shunt The dominant hosts for viruses in the ocean are marine microorganisms such as bacteria 14 Bacteriophages are harmless to plants and animals and are essential to the regulation of marine and freshwater ecosystems 91 are important mortality agents of phytoplankton the base of the foodchain in aquatic environments 92 They infect and destroy bacteria in aquatic microbial communities and are one of the most important mechanisms of recycling carbon and nutrient cycling in marine environments The organic molecules released from the dead bacterial cells stimulate fresh bacterial and algal growth in a process known as the viral shunt 93 In this way marine viruses are thought to play an important role in nutrient cycles by increasing the efficiency of the biological pump Viruses cause lysis of living cells that is they break the cell membranes down This releases compounds such as amino acids and nucleic acids which tend to be recycled near the surface Viral activity also enhances the ability of the biological pump to sequester carbon in the deep ocean 69 Lysis releases more indigestible carbon rich material like that found in cell walls which is likely exported to deeper waters Thus the material that is exported to deeper waters by the viral shunt is probably more carbon rich than the material from which it was derived 94 95 By increasing the amount of respiration in the oceans viruses are indirectly responsible for reducing the amount of carbon dioxide in the atmosphere by about three gigatonnes of carbon per year 69 Lysis of bacteria by viruses has been shown to also enhance nitrogen cycling and stimulate phytoplankton growth 96 The viral shunt pathway is a mechanism that prevents prokaryotic and eukaryotic marine microbial particulate organic matter POM from migrating up trophic levels by recycling them into dissolved organic matter DOM which can be readily taken up by microorganisms Viral shunting helps maintain diversity within the microbial ecosystem by preventing a single species of marine microbe from dominating the micro environment 97 The DOM recycled by the viral shunt pathway is comparable to the amount generated by the other main sources of marine DOM 98 nbsp The viral shunt pathway facilitates the flow of dissolved organic matter DOM and particulate organic matter POM through the marine food web nbsp Connections between the different compartments of the living bacteria viruses and phytoplankton zooplankton and the nonliving DOM POM and inorganic matter environment 99 Viruses are the most abundant biological entity in marine environments 5 On average there are about ten million of them in one milliliter of seawater 100 Most of these viruses are bacteriophages infecting heterotrophic bacteria and cyanophages infecting cyanobacteria Viruses easily infect microorganisms in the microbial loop due to their relative abundance compared to microbes 101 Prokaryotic and eukaryotic mortality contribute to carbon nutrient recycling through cell lysis There is evidence as well of nitrogen specifically ammonium regeneration This nutrient recycling helps stimulates microbial growth 102 As much as 25 of the primary production from phytoplankton in the global oceans may be recycled within the microbial loop through viral shunting 103 Limiting algal blooms edit Microorganisms make up about 70 of the marine biomass 104 It is estimated viruses kill 20 of the microorganism biomass each day and that there are 15 times as many viruses in the oceans as there are bacteria and archaea Viruses are the main agents responsible for the rapid destruction of harmful algal blooms 105 which often kill other marine life 106 Scientists are exploring the potential of marine cyanophages to be used to prevent or reverse eutrophication The number of viruses in the oceans decreases further offshore and deeper into the water where there are fewer host organisms 107 Gene transfer edit Marine bacteriophages often contain auxiliary metabolic genes host derived genes thought to sustain viral replication by supplementing host metabolism during viral infection 108 These genes can impact multiple biogeochemical cycles including carbon phosphorus sulfur and nitrogen 109 110 111 112 Viruses are an important natural means of transferring genes between different species which increases genetic diversity and drives evolution 10 It is thought viruses played a central role in early evolution before bacteria archaea and eukaryotes diversified at the time of the last universal common ancestor of life on Earth 113 Viruses are still one of the largest reservoirs of unexplored genetic diversity on Earth 107 Marine habitats editAlong the coast edit See also Mangrove virome Marine coastal habitats sit at the interface between the land and the ocean It is likely that RNA viruses play significant roles in these environments 114 At the ocean surface edit nbsp Viral bacterial dynamics in the surface microlayer SML of the ocean and beyond DOM dissolved organic matter UV ultraviolet 115 See also Sea surface microlayer Marine surface habitats sit at the interface between the atmosphere and the ocean The biofilm like habitat at the surface of the ocean harbours surface dwelling microorganisms commonly referred to as neuston Viruses in the microlayer the so called virioneuston have recently become of interest to researchers as enigmatic biological entities in the boundary surface layers with potentially important ecological impacts Given this vast air water interface sits at the intersection of major air water exchange processes spanning more than 70 of the global surface area it is likely to have profound implications for marine biogeochemical cycles on the microbial loop and gas exchange as well as the marine food web structure the global dispersal of airborne viruses originating from the sea surface microlayer and human health 115 In the water column edit Marine viral activity presents a potential explanation of the paradox of the plankton proposed by George Hutchinson in 1961 116 The paradox of the plankton is that many plankton species have been identified in small regions in the ocean where limited resources should create competitive exclusion limiting the number of coexisting species 116 Marine viruses could play a role in this effect as viral infection increases as potential contact with hosts increases 4 Viruses could therefore control the populations of plankton species that grow too abundant allowing a wide diversity of species to coexist 4 In sediments edit See also marine sediments Marine bacteriophages play an important role in deep sea ecosystems There are between 5x1012 and 1x1013 phages per square metre in deep sea sediments and their abundance closely correlates with the number of prokaryotes found in the sediments They are responsible for the death of 80 of the prokaryotes found in the sediments and almost all of these deaths are caused by cell lysis bursting This allows nitrogen carbon and phosphorus from the living cells to be converted into dissolved organic matter and detritus contributing to the high rate of nutrient turnover in deep sea sediments Because of the importance of deep sea sediments in biogeochemical cycles marine bacteriophages influence the carbon nitrogen and phosphorus cycles More research needs to be done to more precisely elucidate these influences 117 In hydrothermal vents edit Further information hydrothermal vent microbial community Viruses are part of the hydrothermal vent microbial community and their influence on the microbial ecology in these ecosystems is a burgeoning field of research 118 Viruses are the most abundant life in the ocean harboring the greatest reservoir of genetic diversity 105 As their infections are often fatal they constitute a significant source of mortality and thus have widespread influence on biological oceanographic processes evolution and biogeochemical cycling within the ocean 107 Evidence has been found however to indicate that viruses found in vent habitats have adopted a more mutualistic than parasitic evolutionary strategy in order to survive the extreme and volatile environment they exist in 119 Deep sea hydrothermal vents were found to have high numbers of viruses indicating high viral production 120 Like in other marine environments deep sea hydrothermal viruses affect abundance and diversity of prokaryotes and therefore impact microbial biogeochemical cycling by lysing their hosts to replicate 121 However in contrast to their role as a source of mortality and population control viruses have also been postulated to enhance survival of prokaryotes in extreme environments acting as reservoirs of genetic information The interactions of the virosphere with microorganisms under environmental stresses is therefore thought to aide microorganism survival through dispersal of host genes through horizontal gene transfer 122 Polar regions edit Further information Marine food web Polar microorganisms In addition to varied topographies and in spite of an extremely cold climate the polar aquatic regions are teeming with microbial life Even in sub glacial regions cellular life has adapted to these extreme environments where perhaps there are traces of early microbes on Earth As grazing by macrofauna is limited in most of these polar regions viruses are being recognised for their role as important agents of mortality thereby influencing the biogeochemical cycling of nutrients that in turn impact community dynamics at seasonal and spatial scales 123 The polar regions are characterised by truncated food webs and the role of viruses in ecosystem function is likely to be even greater than elsewhere in the marine food web yet their diversity is still relatively under explored and the way in which they affect polar communities is not well understood 124 particularly in nutrient cycling 125 126 127 123 Distribution edit Viruses are highly host specific 128 A marine virus is more likely to infect cooccurring organisms those that live in the same region the virus lives in 129 Therefore biogeography is an important factor in a virion s ability to infect Knowledge of this variation in viral populations across spatiotemporal and other environmental gradients is supported by viral morphology as determined by transmission electron microscopy TEM Non tailed viruses appear to be dominant in multiple depths and oceanic regions followed by the Caudovirales myoviruses podoviruses and siphoviruses 31 However viruses belonging to families Corticoviridae 130 Inoviridae 131 and Microviridae 132 are also known to infect diverse marine bacteria Metagenomic evidence suggests that microviruses icosahedral ssDNA phages are particularly prevalent in marine habitats 132 Metagenomic approaches to assess viral diversity are often limited by a lack of reference sequences leaving many sequences unannotated 133 However viral contigs are generated through direct sequencing of a viral fraction typically generated after 0 02 um filtration of a marine water sample or through bioinformatics approaches to identify viral contigs or viral genomes from a microbial metagenome Novel tools to identify putative viral contigs such as VirSorter 134 and VirFinder 135 allow for the assessment of patterns of viral abundance host range and functional content of marine bacteriophage 136 137 See also edit nbsp Marine life portal nbsp Oceans portal nbsp Viruses portal Human 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