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{{short description|Species of virus}}
{{Taxobox
{{For|the [[computer virus]] (the ILOVEYOU virus)|ILOVEYOU}}
| name = Lloviu virus (LLOV)
{{Use dmy dates|date=August 2019}}
| virus_group = v
{{Virusbox
| ordo = ''[[Mononegavirales]]''
| parent = Cuevavirus
| familia = ''[[Filoviridae]]''
| species = Lloviu cuevavirus
| genus = ''[[Cuevavirus]]''
| subdivision_ranks = Member virus
| species = ''[[Lloviu cuevavirus]]''
| subdivision = Lloviu virus (LLOV)
}}
}}

'''Lloviu virus''' ('''LLOV''') is an uncultured virus distantly related to the well-known pathogens [[Ebola virus]] and [[Marburg virus]].<ref name=KuhnArch>{{Cite journal
The species '''''Lloviu cuevavirus''''' ({{IPAc-en|ˈ|j|ɒ|v|j|uː|_|ˌ|k|w|ɛ|v|ə|ˈ|v|aɪ|r|ə|s}} {{respell|YOV|ew|_|KWEV|ə|VY|rəs}}) is the [[International Committee on Taxonomy of Viruses|taxonomic]] home of a virus that forms filamentous virion, ''Lloviu virus'' (LLOV). The species is included in the genus ''[[Cuevavirus]]''.<ref name="KuhnArch">{{Cite journal
| last1 = Kuhn | first1 = J. H.
| last1 = Kuhn | first1 = J. H.
| last2 = Becker | first2 = S.
| last2 = Becker | first2 = S.
Line 32: Line 34:
| year = 2010
| year = 2010
| pmid = 21046175
| pmid = 21046175
}}</ref><ref name=Negredo2011>{{Cite journal
}}</ref><ref name="Negredo2011">{{Cite journal
| last1 = Negredo | first1 = A.
| last1 = Negredo | first1 = A.
| last2 = Palacios | first2 = G.
| last2 = Palacios | first2 = G.
| last3 = Vázquez-Morón | first3 = S.
| last3 = Vázquez-Morón | first3 = S.
| last4 = González | first4 = F. L.
| last4 = González | first4 = F. L.
| last5 = Dopazo | first5 = H. N.
| last5 = Dopazo | first5 = H. N.
| last6 = Molero | first6 = F.
| last6 = Molero | first6 = F.
| last7 = Juste | first7 = J.
| last7 = Juste | first7 = J.
| last8 = Quetglas | first8 = J.
| last8 = Quetglas | first8 = J.
| last9 = Savji | first9 = N.
| last9 = Savji | first9 = N.
| author10 = de la Cruz Martínez M
| author10 = de la Cruz Martínez M
| last11 = Herrera | first11 = J. E.
| last11 = Herrera | first11 = J. E.
| last12 = Pizarro | first12 = M.
| last12 = Pizarro | first12 = M.
| last13 = Hutchison | first13 = S. K.
| last13 = Hutchison | first13 = S. K.
| last14 = Echevarría | first14 = J. E.
| last14 = Echevarría | first14 = J. E.
| last15 = Lipkin | first15 = W. I.
| last15 = Lipkin | first15 = W. I.
| last16 = Tenorio | first16 = A.
| last16 = Tenorio | first16 = A.
| editor1-last = Basler
| editor1-last = Basler
| editor1-first = Christopher F
| editor1-first = Christopher F
| title = Discovery of an Ebolavirus-Like Filovirus in Europe
| title = Discovery of an Ebolavirus-Like Filovirus in Europe
| doi = 10.1371/journal.ppat.1002304
| doi = 10.1371/journal.ppat.1002304
| journal = PLoS Pathogens
| journal = PLOS Pathogens
| volume = 7
| volume = 7
| issue = 10
| issue = 10
| pages = e1002304
| pages = e1002304
| year = 2011
| year = 2011
| pmid = 22039362
| pmid = 22039362
| pmc =3197594
| pmc =3197594
| doi-access = free
}}</ref>
}}</ref> LLOV is a distant relative of the commonly known [[Ebola virus]] and [[Marburg virus]].


==Use of term==
Lloviu virus (abbreviated LLOV) is the sole member of the species ''[[Lloviu cuevavirus]]'', which is included genus ''[[Cuevavirus]]'', [[International Committee on Taxonomy of Viruses|family]] ''[[Filoviridae]]'', [[International Committee on Taxonomy of Viruses|order]] ''[[Mononegavirales]]''.<ref name=KuhnArch/><ref name=Negredo2011/> The name Lloviu virus is derived from ''Cueva del Lloviu'', the name of a [[Spain|Spanish]] [[cave]] in which it was first discovered.<ref name=KuhnArch/>
The [[International Committee on Taxonomy of Viruses|species]] ''Lloviu cuevavirus'' is a [[International Committee on Taxonomy of Viruses|virological taxon]] (i.e. a man-made [[concept]]) included in the genus ''[[Cuevavirus]]'', family ''[[Filoviridae]]'', order ''[[Mononegavirales]]''.<ref name=KuhnArch/> The species has a single [[virus]] member, Lloviu virus.<ref name=KuhnArch/> Lloviu virus is the sole member of the species ''Lloviu cuevavirus'', which is included genus ''[[Cuevavirus]]'', [[International Committee on Taxonomy of Viruses|family]] ''[[Filoviridae]]'', [[International Committee on Taxonomy of Viruses|order]] ''[[Mononegavirales]]''.<ref name="KuhnArch" /><ref name="Negredo2011" /> The name Lloviu virus is derived from ''Cueva del Lloviu'' (the name of a [[Spain|Spanish]] [[cave]] in which it was first discovered<ref name="KuhnArch" />) and the [[Taxonomy (biology)|taxonomic]] [[suffix]] ''virus'' (which denotes a virus species).<ref name=KuhnArch/>


In 2010, the species and the genus ''[[cuevavirus]]'' were proposed as independent species and genus.<ref name=KuhnArch/> In July 2013, the species and the genus ''[[cuevavirus]]'' were ratified by the [[International Committee on Taxonomy of Viruses]] (ICTV) to be included in its report, therefore the name is now to be italicized.<ref>{{cite web|title=ICTV Taxonomy History for ''Lloviu cuevavirus''|url=http://www.ictvonline.org/taxonomyHistory.asp?taxnode_id=20140725&taxa_name=Lloviu%20cuevavirus|website=International Committee on Taxonomy of Viruses|access-date=7 March 2015}}</ref>
Lloviu virus is pronounced j’ɔːvjuː vaɪrəs ([[IPA]]). According to the rules for taxon naming established by the [[International Committee on Taxonomy of Viruses]] (ICTV), the name Lloviu virus is always to be [[Capitalization|capitalized]] (because "Lloviu" is a proper noun), but is never [[Italic type|italicized]], and may be [[Abbreviation|abbreviated]] (with LLOV being the official abbreviation).


==Virus inclusion criteria==
==Species inclusion criteria==
A virus that fulfills the criteria for being a member of the species ''[[Lloviu cuevavirus]]'' is a Lloviu virus if it has the properties of ''[[Lloviu cuevavirus]]es'' and if its [[genome]] diverges from that of the prototype ''Lloviu cuevavirus'', Lloviu virus variant Bat86 (LLOV/Bat86), by ≤10% at the [[nucleotide]] level.<ref name=KuhnArch/>
A virus that fulfills the criteria for being a member of the genus "''[[Cuevavirus]]''" is a member of the species "Lloviu cuevavirus" if it has the properties of "''cuevaviruses''" (because there is currently only "[[cuevavirus]]" species) and if its genome differs from that of Lloviu virus (variant Bat86) by <30% at the nucleotide level.<ref name=KuhnArch/>

'''Lloviu virus''' ({{IPAc-en|ˈ|j|ɒ|v|j|uː}} {{respell|YOV|yoo}};<ref name=KuhnArch/> '''LLOV''') is a virus distantly related to the well-known pathogens [[Ebola virus]] and [[Marburg virus]].<ref name="KuhnArch"/><ref name="Negredo2011"/>

According to the rules for taxon naming established by the [[International Committee on Taxonomy of Viruses]] (ICTV), the name Lloviu virus is always to be [[Capitalization|capitalized]] (because "Lloviu" is a proper noun), but is never [[Italic type|italicized]], and may be [[Abbreviation|abbreviated]] (with LLOV being the official abbreviation).{{citation needed|date=May 2021}}


==History==
==History==
LLOV was discovered in 2002 in [[common bent-wing bat|Schreibers's long-fingered bats]] (species ''Miniopterus schreibersii'') found dead in Cueva del Lloviu, [[Asturias]], [[Spain]], as well as in caves in Spanish [[Cantabria]] and in caves in [[France]] and [[Portugal]].<ref name=Negredo2011/> It has not yet been proven that the virus is the [[Etiology|etiological]] agent of a novel [[bat]] [[disease]], but healthy Schreibers' long-fingered bats were not found to contain traces of the viruses, thereby at least suggesting that the virus may be [[pathogen]]ic for certain bats. [[Autopsy|Necropsies]] of dead bats did not reveal [[Macroscopic scale|macroscopic]] [[pathology]], but [[microscopic scale|microscopic]] examination suggested [[viral pneumonia]].<ref name=Negredo2011/> Cueva del Lloviu is frequented by [[Tourism|tourists]], yet no human [[infection]]s or [[disease]] has ever been observed, suggesting that LLOV is the second [[Filoviridae|filovirus]] not pathogenic for [[human]]s (the first one being [[Reston virus|Reston virus (RESTV)]]).
LLOV was discovered in 2011 in [[common bent-wing bat|Schreibers's long-fingered bats]] (species ''Miniopterus schreibersii'') that were found dead in Cueva del Lloviu in 2002, [[Asturias]], [[Spain]], as well as in caves in Spanish [[Cantabria]] and in caves in [[France]] and [[Portugal]].<ref name=Negredo2011/> It has not yet been proven that the virus is the [[Etiology|etiological]] agent of a novel bat disease, but healthy Schreibers' long-fingered bats were not found to contain traces of the viruses, thereby at least suggesting that the virus may be [[pathogen]]ic for certain bats. [[Autopsy|Necropsies]] of dead bats did not reveal [[Macroscopic scale|macroscopic]] [[pathology]], but [[microscopic scale|microscopic]] examination suggested [[viral pneumonia]].<ref name=Negredo2011/> No information is available about whether or not LLOV infects humans.<ref>{{cite journal |title=Ebola: Lessons on Vaccine Development |author=Heinz Feldmann |author2=Friederike Feldmann |author3=Andrea Marzi |journal=[[Annual Review of Microbiology]] |volume=72 |pages=423–46 |year=2018 |doi=10.1146/annurev-micro-090817-062414|pmid=30200851 |s2cid=52185735 }}</ref> However, Cueva del Lloviu is frequented by [[Tourism|tourists]] and no human infections or disease has yet been observed, suggesting that it is possible that LLOV might be the second [[Filoviridae|filovirus]] that is not pathogenic for humans (the first one being [[Reston virus|Reston virus (RESTV)]]). {{citation needed|date=July 2020}}

Seroreactivity of additional [[common bent-wing bat|Schreibers's long-fingered bats]] were reported from North Spain from 2015, suggesting the circulation of the virus among those bat colonies. However [[Polymerase chain reaction|PCR]] positive animals were not found.<ref>{{Cite journal|last1=Ramírez de Arellano|first1=Eva|last2=Sanchez-Lockhart|first2=Mariano|last3=Perteguer|first3=Maria J.|last4=Bartlett|first4=Maggie|last5=Ortiz|first5=Marta|last6=Campioli|first6=Pamela|last7=Hernández|first7=Ana|last8=Gonzalez|first8=Jeanette|last9=Garcia|first9=Karla|last10=Ramos|first10=Manolo|last11=Jiménez-Clavero|first11=Miguel Ángel|date=2019-04-19|title=First Evidence of Antibodies Against Lloviu Virus in Schreiber's Bent-Winged Insectivorous Bats Demonstrate a Wide Circulation of the Virus in Spain|journal=Viruses|volume=11|issue=4|page=360|doi=10.3390/v11040360|issn=1999-4915|pmc=6521100|pmid=31010201|doi-access=free}}</ref>

Additional [[common bent-wing bat|Schreibers's long-fingered bat]] die-off events were reported from [[Hungary]] in 2013, 2016 and 2017. The presence of LLOV was confirmed in bat carcasses from 2016, presenting hemorrhagic symptoms.<ref>{{Cite journal|last1=Kemenesi|first1=Gábor|last2=Kurucz|first2=Kornélia|last3=Dallos|first3=Bianka|last4=Zana|first4=Brigitta|last5=Földes|first5=Fanni|last6=Boldogh|first6=Sándor|last7=Görföl|first7=Tamás|last8=Carroll|first8=Miles W|last9=Jakab|first9=Ferenc|date=2018-04-18|title=Re-emergence of Lloviu virus in Miniopterus schreibersii bats, Hungary, 2016|journal=Emerging Microbes & Infections|volume=7|issue=1|page=66|doi=10.1038/s41426-018-0067-4|issn=2222-1751|pmc=5906664|pmid=29670087}}</ref> Updated genome data was obtained from the Hungarian samples in 2020, using the [[Nanopore sequencing]] technique.<ref>{{Cite web|title=Historical moment in #filovirus research, sequencing the complete genome of #lloviuvirus in 50 minutes after a decade. @nanopore @TthGborEndre1 #filoviridae #emergingdisease #bat #virologypic.twitter.com/4a5fiWaIuz|url=https://twitter.com/GaborKemenesi/status/1267104764925534211|last=Kemenesi|first=Gabor|date=2020-05-31|website=@GaborKemenesi|language=en|access-date=2020-06-01}}</ref> The infectious virus was isolated from [[common bent-wing bat|Schreibers's long-fingered bat]] in Hungary, making it only the third filovirus along with [[Marburg virus|Marburg]] and [[Ravn virus|Ravn]] viruses ever isolated from bats.<ref name=":0">{{Cite journal |last1=Kemenesi |first1=Gábor |last2=Tóth |first2=Gábor E. |last3=Mayora-Neto |first3=Martin |last4=Scott |first4=Simon |last5=Temperton |first5=Nigel |last6=Wright |first6=Edward |last7=Mühlberger |first7=Elke |last8=Hume |first8=Adam J. |last9=Suder |first9=Ellen L. |last10=Zana |first10=Brigitta |last11=Boldogh |first11=Sándor A. |date=2022-03-31 |title=Isolation of infectious Lloviu virus from Schreiber's bats in Hungary |journal=Nature Communications |language=en |volume=13 |issue=1 |page=1706 |doi=10.1038/s41467-022-29298-1|pmid=35361761 |pmc=8971391 |bibcode=2022NatCo..13.1706K |issn=2041-1723}}</ref>


==Virology==
==Virology==


===Genome===
===Genome===
LLOV has yet to be isolated in [[tissue culture]] or living [[animal]]s, but its genome has been determined in its entirety with exception of the [[Three prime untranslated region|3']] and [[Five prime untranslated region|5' UTRs]].<ref name=Negredo2011/> Like all [[Mononegavirales|mononegaviruses]], LLOV virions contain a non-infectious, linear nonsegmented, single-stranded [[RNA]] [[genome]] of negative polarity that most likely possesses inverse-complementary 3' and 5' termini, does not possess a [[5' cap]], is not [[Polyadenylation|polyadenylated]], and is not [[Covalent bond|covalently]] linked to a [[protein]].<ref name=King2011>{{Citation|last1=Easton|first1=A.|last2=Pringle|first2=C. R.|chapter=Order Mononegavirales|year=2011|editor-last=King|editor-first=Andrew M. Q.|editor2-last=Adams|editor2-first=Michael J.|editor3-last=Carstens|editor3-first=Eric B.|display-editors = 3 |editor4-last=Lefkowitz|editor4-first=Elliot J.|title=Virus Taxonomy—Ninth Report of the International Committee on Taxonomy of Viruses|pages=653–657|publisher=Elsevier/Academic Press|location=London, UK|isbn=978-0-12-384684-6}}</ref> The LLOV genome is probably approximately 19 [[base pair|kb]] long and contains seven [[gene]]s in the order [[Three prime untranslated region|3'-UTR]]-''NP''-''VP35''-''VP40''-''GP''-''VP30''-''VP24''-''L''-[[Five prime untranslated region|5'-UTR]]. In contrast to [[ebolavirus]]es and [[marburgvirus]]es, which synthesize seven mRNAs to express the seven structural proteins, LLOV seems to produce only six [[Messenger RNA|mRNAs]], i.e. one mRNA (''VP24''/''L'') is thought to be [[Cistron|bicistronic]]. LLOV genomic [[Transcription (genetics)|transcriptional termination sites]] are identical to those of ebolavirus genomes but different from those of marburgvirus genomes. LLOV [[Transcription (genetics)|transcriptional initiation sites]] are unique.<ref name=Negredo2011/>
Although LLOV was isolated in [[tissue culture]], yet its genome has been determined in its entirety with exception of the [[Three prime untranslated region|3']] and [[Five prime untranslated region|5' UTRs]].<ref name=Negredo2011/><ref name=":0" /> Like all [[Mononegavirales|mononegaviruses]], LLOV virions contain a non-infectious, linear nonsegmented, single-stranded [[RNA]] [[genome]] of negative polarity that most likely possesses inverse-complementary 3' and 5' termini, does not possess a [[5' cap]], is not [[Polyadenylation|polyadenylated]], and is not [[Covalent bond|covalently]] linked to a [[protein]].<ref name=King2011>{{Citation|last1=Easton|first1=A.|last2=Pringle|first2=C. R.|chapter=Order Mononegavirales|year=2011|editor-last=King|editor-first=Andrew M. Q.|editor2-last=Adams|editor2-first=Michael J.|editor3-last=Carstens|editor3-first=Eric B.|display-editors = 3 |editor4-last=Lefkowitz|editor4-first=Elliot J.|title=Virus Taxonomy—Ninth Report of the International Committee on Taxonomy of Viruses|pages=653–657|publisher=Elsevier/Academic Press|location=London, UK|isbn=978-0-12-384684-6}}</ref> The LLOV genome is probably approximately 19 [[base pair|kb]] long and contains seven [[gene]]s in the order [[Three prime untranslated region|3'-UTR]]-''NP''-''VP35''-''VP40''-''GP''-''VP30''-''VP24''-''L''-[[Five prime untranslated region|5'-UTR]]. In contrast to [[ebolavirus]]es and [[Marburgvirus]]es, which synthesize seven mRNAs to express the seven structural proteins, LLOV seems to produce only six [[Messenger RNA|mRNAs]], i.e. one mRNA (''VP24''/''L'') is thought to be [[Cistron|bicistronic]]. LLOV genomic [[Transcription (genetics)|transcriptional termination sites]] are identical to those of [[ebolavirus]] genomes but different from those of [[Marburgvirus]] genomes. LLOV [[Transcription (genetics)|transcriptional initiation sites]] are unique.<ref name=Negredo2011/>


===Structure===
===Structure===
Line 82: Line 94:
| last2 = Jahrling | first2 = P. B.
| last2 = Jahrling | first2 = P. B.
| title = Differentiation of filoviruses by electron microscopy
| title = Differentiation of filoviruses by electron microscopy
| journal = Virus research
| journal = Virus Research
| volume = 39
| volume = 39
| issue = 2–3
| issue = 2–3
Line 89: Line 101:
| pmid = 8837880
| pmid = 8837880
| doi=10.1016/0168-1702(95)00080-1
| doi=10.1016/0168-1702(95)00080-1
| url = https://zenodo.org/record/1258399
}}</ref> The LLOV genome suggests that LLOV particles consist of seven structural proteins. At the center would be the [[Helix|helical]] [[ribonucleoprotein|ribonucleocapsid]], which would consist of the genomic RNA wrapped around a [[polymer]] of [[nucleoprotein]]s (NP). Associated with the ribonucleoprotein would be the [[RNA-dependent RNA polymerase]] (L) with the polymerase cofactor (VP35) and a transcription activator (VP30). The ribonucleoprotein would be embedded in a matrix, formed by the major (VP40) and minor (VP24) matrix proteins. These particles would be surrounded by a [[lipid bilayer|lipid membrane]] derived from the host cell membrane. The membrane would anchor a glycoprotein (GP<sub>1,2</sub>) that projects 7 to 10&nbsp;nm spikes away from its surface. While nearly identical to ebolavirions and marburgvirions in structure, lloviuvirions may be [[antigen]]ically distinct from both (just as they are from each other).
}}</ref> The LLOV genome suggests that LLOV particles consist of seven structural proteins. At the center would be the [[Helix|helical]] [[ribonucleoprotein|ribonucleocapsid]], which would consist of the genomic RNA wrapped around a [[polymer]] of [[nucleoprotein]]s (NP). Associated with the ribonucleoprotein would be the [[RNA-dependent RNA polymerase]] (L) with the polymerase cofactor (VP35) and a transcription activator (VP30). The ribonucleoprotein would be embedded in a matrix, formed by the major (VP40) and minor (VP24) matrix proteins. These particles would be surrounded by a [[lipid bilayer|lipid membrane]] derived from the host cell membrane. The membrane would anchor a glycoprotein (GP<sub>1,2</sub>) that projects 7 to 10&nbsp;nm spikes away from its surface. While nearly identical to ebolavirions and marburgvirions in structure, lloviuvirions may be [[antigen]]ically distinct from both (just as they are from each other).{{original research inline|date=August 2019}}


===Replication===
===Replication===
The LLOV [[Biological life cycle|life cycle]] is hypothesized to begin with virion attachment to specific cell-surface [[Receptor (biochemistry)|receptors]], followed by internalization, [[Lipid bilayer fusion|fusion]] of the virion envelope with [[Endosome|endosomal]] membranes and the concomitant release of the virus [[nucleocapsid]] into the [[cytosol]]. LLOV glycoprotein (GP) is cleaved by endosomal cysteine proteases ([[cathepsin]]s) and the cleaved glycoprotein interacts with the intracelluar entry receptor, Niemann-Pick C1 ([[NPC1]]).<ref>{{cite journal |vauthors=Ng M, Ndungo E, Jangra RK, Cai Y, Postnikova E, Radoshitzky SR, Dye JM, Ramirez de Arellano E, Negredo A, Palacios G, Kuhn JH, Chandran K | date = 2014 | title = Cell entry by a novel European filovirus requires host endosomal cysteine proteases and Niemann–PickC1 | journal = Virology | pages = 637&ndash;46 | pmid = 25310500 | doi = 10.1016/j.virol.2014.08.019 }}</ref> The virus RdRp would partially uncoat the nucleocapsid and [[Transcription (genetics)|transcribe]] the [[genes]] into positive-stranded [[mRNA]]s, which would then be [[translation (biology)|translated]] into structural and nonstructural [[proteins]]. LLOV L would bind to a single [[Promoter (biology)|promoter]] located at the 3' end of the genome. Transcription would either terminate after a gene or continue to the next gene downstream. This means that genes close to the 3' end of the genome would be transcribed in the greatest abundance, whereas those toward the 5' end would be least likely to be transcribed. The gene order would therefore be a simple but effective form of transcriptional regulation. The most abundant protein produced would be the [[nucleoprotein]], whose [[concentration]] in the cell would determine when L switches from gene transcription to genome replication. Replication would result in full-length, positive-stranded antigenomes that would in turn be transcribed into negative-stranded virus progeny genome copies. Newly synthesized structural proteins and genomes would self-assemble and accumulate near the inside of the [[cell membrane]]. Virions would [[Budding|bud]] off from the cell, gaining their envelopes from the cellular membrane they bud from. The mature progeny particles would then infect other cells to repeat the cycle.<ref name=King2011/>
The LLOV [[Biological life cycle|life cycle]] is hypothesized to begin with virion attachment to specific cell-surface [[Receptor (biochemistry)|receptors]], followed by internalization, [[Lipid bilayer fusion|fusion]] of the virion envelope with [[Endosome|endosomal]] membranes and the concomitant release of the virus [[nucleocapsid]] into the [[cytosol]]. LLOV glycoprotein (GP) is cleaved by endosomal cysteine proteases ([[cathepsin]]s) and the cleaved glycoprotein interacts with the intracellular entry receptor, Niemann-Pick C1 ([[NPC1]]).<ref>{{cite journal |vauthors=Ng M, Ndungo E, Jangra RK, Cai Y, Postnikova E, Radoshitzky SR, Dye JM, Ramirez de Arellano E, Negredo A, Palacios G, Kuhn JH, Chandran K | date = 2014 | title = Cell entry by a novel European filovirus requires host endosomal cysteine proteases and Niemann–PickC1 | journal = Virology | pages = 637–46 | pmid = 25310500 | doi = 10.1016/j.virol.2014.08.019 | volume=468–470 | pmc=4252868}}</ref> The virus RdRp would partially uncoat the nucleocapsid and [[Transcription (genetics)|transcribe]] the [[genes]] into positive-stranded [[mRNA]]s, which would then be [[translation (biology)|translated]] into structural and nonstructural [[proteins]]. LLOV L would bind to a single [[Promoter (biology)|promoter]] located at the 3' end of the genome. Transcription would either terminate after a gene or continue to the next gene downstream. This means that genes close to the 3' end of the genome would be transcribed in the greatest abundance, whereas those toward the 5' end would be least likely to be transcribed. The gene order would therefore be a simple but effective form of transcriptional regulation. The most abundant protein produced would be the [[nucleoprotein]], whose [[concentration]] in the cell would determine when L switches from gene transcription to genome replication. Replication would result in full-length, positive-stranded antigenomes that would in turn be transcribed into negative-stranded virus progeny genome copies. Newly synthesized structural proteins and genomes would self-assemble and accumulate near the inside of the [[cell membrane]]. Virions would [[Budding|bud]] off from the cell, gaining their envelopes from the cellular membrane they bud from. The mature progeny particles would then infect other cells to repeat the cycle.<ref name=King2011/>


==References==
==References==
{{reflist|2}}
{{reflist}}
{{Refend}}


==External links==
==External links==
{{Refbegin}}
{{Wikispecies}}
* [http://talk.ictvonline.org International Committee on Taxonomy of Viruses (ICTV)]
* [https://ictv.global/ International Committee on Taxonomy of Viruses (ICTV)]


{{Taxonbar|from1=Q20003768|from2=Q6662207}}
{{filoviridae}}
{{filoviridae}}


[[Category:Bat diseases]]
[[Category:Bat virome]]
[[Category:Animal virology]]
[[Category:Arthropod-borne viral fevers and viral haemorrhagic fevers]]
[[Category:Arthropod-borne viral fevers and viral haemorrhagic fevers]]
[[Category:Biological weapons]]
[[Category:Biological weapons]]
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[[Category:Filoviridae]]
[[Category:Filoviridae]]
[[Category:Zoonoses]]
[[Category:Zoonoses]]
[[Category:Animal viral diseases]]

Revision as of 22:31, 23 November 2023

For the computer virus (the ILOVEYOU virus), see ILOVEYOU.

Lloviu cuevavirus
Virus classification Edit this classification
(unranked): Virus
Realm: Riboviria
Kingdom: Orthornavirae
Phylum: Negarnaviricota
Class: Monjiviricetes
Order: Mononegavirales
Family: Filoviridae
Genus: Cuevavirus
Species:
Lloviu cuevavirus
Member virus

Lloviu virus (LLOV)

The species Lloviu cuevavirus (/ˈjɒvj ˌkwɛvəˈvrəs/ YOV-ew KWEV-ə-VY-rəs) is the taxonomic home of a virus that forms filamentous virion, Lloviu virus (LLOV). The species is included in the genus Cuevavirus.[1][2] LLOV is a distant relative of the commonly known Ebola virus and Marburg virus.

Use of term

The species Lloviu cuevavirus is a virological taxon (i.e. a man-made concept) included in the genus Cuevavirus, family Filoviridae, order Mononegavirales.[1] The species has a single virus member, Lloviu virus.[1] Lloviu virus is the sole member of the species Lloviu cuevavirus, which is included genus Cuevavirus, family Filoviridae, order Mononegavirales.[1][2] The name Lloviu virus is derived from Cueva del Lloviu (the name of a Spanish cave in which it was first discovered[1]) and the taxonomic suffix virus (which denotes a virus species).[1]

In 2010, the species and the genus cuevavirus were proposed as independent species and genus.[1] In July 2013, the species and the genus cuevavirus were ratified by the International Committee on Taxonomy of Viruses (ICTV) to be included in its report, therefore the name is now to be italicized.[3]

Species inclusion criteria

A virus that fulfills the criteria for being a member of the genus "Cuevavirus" is a member of the species "Lloviu cuevavirus" if it has the properties of "cuevaviruses" (because there is currently only "cuevavirus" species) and if its genome differs from that of Lloviu virus (variant Bat86) by <30% at the nucleotide level.[1]

Lloviu virus (/ˈjɒvj/ YOV-yoo;[1] LLOV) is a virus distantly related to the well-known pathogens Ebola virus and Marburg virus.[1][2]

According to the rules for taxon naming established by the International Committee on Taxonomy of Viruses (ICTV), the name Lloviu virus is always to be capitalized (because "Lloviu" is a proper noun), but is never italicized, and may be abbreviated (with LLOV being the official abbreviation).[citation needed]

History

LLOV was discovered in 2011 in Schreibers's long-fingered bats (species Miniopterus schreibersii) that were found dead in Cueva del Lloviu in 2002, Asturias, Spain, as well as in caves in Spanish Cantabria and in caves in France and Portugal.[2] It has not yet been proven that the virus is the etiological agent of a novel bat disease, but healthy Schreibers' long-fingered bats were not found to contain traces of the viruses, thereby at least suggesting that the virus may be pathogenic for certain bats. Necropsies of dead bats did not reveal macroscopic pathology, but microscopic examination suggested viral pneumonia.[2] No information is available about whether or not LLOV infects humans.[4] However, Cueva del Lloviu is frequented by tourists and no human infections or disease has yet been observed, suggesting that it is possible that LLOV might be the second filovirus that is not pathogenic for humans (the first one being Reston virus (RESTV)). [citation needed]

Seroreactivity of additional Schreibers's long-fingered bats were reported from North Spain from 2015, suggesting the circulation of the virus among those bat colonies. However PCR positive animals were not found.[5]

Additional Schreibers's long-fingered bat die-off events were reported from Hungary in 2013, 2016 and 2017. The presence of LLOV was confirmed in bat carcasses from 2016, presenting hemorrhagic symptoms.[6] Updated genome data was obtained from the Hungarian samples in 2020, using the Nanopore sequencing technique.[7] The infectious virus was isolated from Schreibers's long-fingered bat in Hungary, making it only the third filovirus along with Marburg and Ravn viruses ever isolated from bats.[8]

Virology

Genome

Although LLOV was isolated in tissue culture, yet its genome has been determined in its entirety with exception of the 3' and 5' UTRs.[2][8] Like all mononegaviruses, LLOV virions contain a non-infectious, linear nonsegmented, single-stranded RNA genome of negative polarity that most likely possesses inverse-complementary 3' and 5' termini, does not possess a 5' cap, is not polyadenylated, and is not covalently linked to a protein.[9] The LLOV genome is probably approximately 19 kb long and contains seven genes in the order 3'-UTR-NP-VP35-VP40-GP-VP30-VP24-L-5'-UTR. In contrast to ebolaviruses and Marburgviruses, which synthesize seven mRNAs to express the seven structural proteins, LLOV seems to produce only six mRNAs, i.e. one mRNA (VP24/L) is thought to be bicistronic. LLOV genomic transcriptional termination sites are identical to those of ebolavirus genomes but different from those of Marburgvirus genomes. LLOV transcriptional initiation sites are unique.[2]

Structure

The structure of LLOV virions has not yet been described. Like all other filoviruses, LLOV virions are expected to be filamentous particles that may appear in the shape of a shepherd's crook or in the shape of a "U" or a "6", and they may be coiled, toroid, or branched. Their diameter is expected to be 80 nm in width, but vary in length.[10] The LLOV genome suggests that LLOV particles consist of seven structural proteins. At the center would be the helical ribonucleocapsid, which would consist of the genomic RNA wrapped around a polymer of nucleoproteins (NP). Associated with the ribonucleoprotein would be the RNA-dependent RNA polymerase (L) with the polymerase cofactor (VP35) and a transcription activator (VP30). The ribonucleoprotein would be embedded in a matrix, formed by the major (VP40) and minor (VP24) matrix proteins. These particles would be surrounded by a lipid membrane derived from the host cell membrane. The membrane would anchor a glycoprotein (GP1,2) that projects 7 to 10 nm spikes away from its surface. While nearly identical to ebolavirions and marburgvirions in structure, lloviuvirions may be antigenically distinct from both (just as they are from each other).[original research?]

Replication

The LLOV life cycle is hypothesized to begin with virion attachment to specific cell-surface receptors, followed by internalization, fusion of the virion envelope with endosomal membranes and the concomitant release of the virus nucleocapsid into the cytosol. LLOV glycoprotein (GP) is cleaved by endosomal cysteine proteases (cathepsins) and the cleaved glycoprotein interacts with the intracellular entry receptor, Niemann-Pick C1 (NPC1).[11] The virus RdRp would partially uncoat the nucleocapsid and transcribe the genes into positive-stranded mRNAs, which would then be translated into structural and nonstructural proteins. LLOV L would bind to a single promoter located at the 3' end of the genome. Transcription would either terminate after a gene or continue to the next gene downstream. This means that genes close to the 3' end of the genome would be transcribed in the greatest abundance, whereas those toward the 5' end would be least likely to be transcribed. The gene order would therefore be a simple but effective form of transcriptional regulation. The most abundant protein produced would be the nucleoprotein, whose concentration in the cell would determine when L switches from gene transcription to genome replication. Replication would result in full-length, positive-stranded antigenomes that would in turn be transcribed into negative-stranded virus progeny genome copies. Newly synthesized structural proteins and genomes would self-assemble and accumulate near the inside of the cell membrane. Virions would bud off from the cell, gaining their envelopes from the cellular membrane they bud from. The mature progeny particles would then infect other cells to repeat the cycle.[9]

References

  1. ^ a b c d e f g h i j Kuhn, J. H.; Becker, S.; Ebihara, H.; Geisbert, T. W.; Johnson, K. M.; Kawaoka, Y.; Lipkin, W. I.; Negredo, A. I.; Netesov, S. V.; Nichol, S. T.; Palacios, G.; Peters, C. J.; Tenorio, A.; Volchkov, V. E.; Jahrling, P. B. (2010). "Proposal for a revised taxonomy of the family Filoviridae: Classification, names of taxa and viruses, and virus abbreviations". Archives of Virology. 155 (12): 2083–2103. doi:10.1007/s00705-010-0814-x. PMC 3074192. PMID 21046175.
  2. ^ a b c d e f g Negredo, A.; Palacios, G.; Vázquez-Morón, S.; González, F. L.; Dopazo, H. N.; Molero, F.; Juste, J.; Quetglas, J.; Savji, N.; de la Cruz Martínez M; Herrera, J. E.; Pizarro, M.; Hutchison, S. K.; Echevarría, J. E.; Lipkin, W. I.; Tenorio, A. (2011). Basler, Christopher F (ed.). "Discovery of an Ebolavirus-Like Filovirus in Europe". PLOS Pathogens. 7 (10): e1002304. doi:10.1371/journal.ppat.1002304. PMC 3197594. PMID 22039362.
  3. ^ "ICTV Taxonomy History for Lloviu cuevavirus". International Committee on Taxonomy of Viruses. Retrieved 7 March 2015.
  4. ^ Heinz Feldmann; Friederike Feldmann; Andrea Marzi (2018). "Ebola: Lessons on Vaccine Development". Annual Review of Microbiology. 72: 423–46. doi:10.1146/annurev-micro-090817-062414. PMID 30200851. S2CID 52185735.
  5. ^ Ramírez de Arellano, Eva; Sanchez-Lockhart, Mariano; Perteguer, Maria J.; Bartlett, Maggie; Ortiz, Marta; Campioli, Pamela; Hernández, Ana; Gonzalez, Jeanette; Garcia, Karla; Ramos, Manolo; Jiménez-Clavero, Miguel Ángel (19 April 2019). "First Evidence of Antibodies Against Lloviu Virus in Schreiber's Bent-Winged Insectivorous Bats Demonstrate a Wide Circulation of the Virus in Spain". Viruses. 11 (4): 360. doi:10.3390/v11040360. ISSN 1999-4915. PMC 6521100. PMID 31010201.
  6. ^ Kemenesi, Gábor; Kurucz, Kornélia; Dallos, Bianka; Zana, Brigitta; Földes, Fanni; Boldogh, Sándor; Görföl, Tamás; Carroll, Miles W; Jakab, Ferenc (18 April 2018). "Re-emergence of Lloviu virus in Miniopterus schreibersii bats, Hungary, 2016". Emerging Microbes & Infections. 7 (1): 66. doi:10.1038/s41426-018-0067-4. ISSN 2222-1751. PMC 5906664. PMID 29670087.
  7. ^ Kemenesi, Gabor (31 May 2020). "Historical moment in #filovirus research, sequencing the complete genome of #lloviuvirus in 50 minutes after a decade. @nanopore @TthGborEndre1 #filoviridae #emergingdisease #bat #virologypic.twitter.com/4a5fiWaIuz". @GaborKemenesi. Retrieved 1 June 2020.
  8. ^ a b Kemenesi, Gábor; Tóth, Gábor E.; Mayora-Neto, Martin; Scott, Simon; Temperton, Nigel; Wright, Edward; Mühlberger, Elke; Hume, Adam J.; Suder, Ellen L.; Zana, Brigitta; Boldogh, Sándor A. (31 March 2022). "Isolation of infectious Lloviu virus from Schreiber's bats in Hungary". Nature Communications. 13 (1): 1706. Bibcode:2022NatCo..13.1706K. doi:10.1038/s41467-022-29298-1. ISSN 2041-1723. PMC 8971391. PMID 35361761.
  9. ^ a b Easton, A.; Pringle, C. R. (2011), "Order Mononegavirales", in King, Andrew M. Q.; Adams, Michael J.; Carstens, Eric B.; et al. (eds.), Virus Taxonomy—Ninth Report of the International Committee on Taxonomy of Viruses, London, UK: Elsevier/Academic Press, pp. 653–657, ISBN 978-0-12-384684-6
  10. ^ Geisbert, T. W.; Jahrling, P. B. (1995). "Differentiation of filoviruses by electron microscopy". Virus Research. 39 (2–3): 129–150. doi:10.1016/0168-1702(95)00080-1. PMID 8837880.
  11. ^ Ng M, Ndungo E, Jangra RK, Cai Y, Postnikova E, Radoshitzky SR, Dye JM, Ramirez de Arellano E, Negredo A, Palacios G, Kuhn JH, Chandran K (2014). "Cell entry by a novel European filovirus requires host endosomal cysteine proteases and Niemann–PickC1". Virology. 468–470: 637–46. doi:10.1016/j.virol.2014.08.019. PMC 4252868. PMID 25310500.

External links

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