Pending Reorganization of Hantaviridae to Include Only Completely Sequenced Viruses: A Call to Action

Kuhn, Jens H.; Bradfute, Steven B.; Calisher, Charles H.; Klempa, Boris; Klingström, Jonas; Laenen, Lies; Palacios, Gustavo; Schmaljohn, Connie S.; Tischler, Nicole D.; Maes, Piet

doi:10.3390/v15030660

Open AccessCommentary

Pending Reorganization of Hantaviridae to Include Only Completely Sequenced Viruses: A Call to Action

by

Jens H. Kuhn

^1,*,†

,

Steven B. Bradfute

^2,‡

,

Charles H. Calisher

^3,‡,

Boris Klempa

^4,‡

,

Jonas Klingström

^5,‡

,

Lies Laenen

^6,7,‡

,

Gustavo Palacios

^8,9

,

Connie S. Schmaljohn

¹,

Nicole D. Tischler

^10,11,‡

and

Piet Maes

^6,*,‡

¹

Integrated Research Facility at Fort Detrick, Division of Clinical Research, National Institute of Allergy and Infectious Diseases, National Institutes of Health, Fort Detrick, Frederick, MD 21702, USA

²

Department of Internal Medicine, University of New Mexico Health Sciences Center, Albuquerque, NM 87131, USA

³

Colorado State University, Fort Collins, CO 80523, USA

⁴

Institute of Virology, Biomedical Research Center, Slovak Academy of Sciences, 84505 Bratislava, Slovakia

⁵

Division of Molecular Medicine and Virology, Department of Biomedical and Clinical Sciences, Linköping University, 581 83 Linköping, Sweden

⁶

Zoonotic Infectious Diseases Unit, KU Leuven, Rega Institute, 3000 Leuven, Belgium

⁷

Belgium Department of Laboratory Medicine, University Hospitals Leuven, 3000 Leuven, Belgium

⁸

Department of Microbiology, Icahn School of Medicine at Mount Sinai, New York, NY 10029, USA

⁹

Global Health Emerging Pathogen Institute, Icahn School of Medicine at Mount Sinai, New York, NY 10029, USA

¹⁰

Laboratorio de Virología Molecular, Centro Ciencia & Vida, Fundación Ciencia & Vida, Santiago 8581151, Chile

¹¹

Facultad de Medicina y Ciencia, Universidad San Sebastián, Santiago 7510157, Chile

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^*

Authors to whom correspondence should be addressed.

^†

2020–2023 International Committee on Taxonomy of Viruses (ICTV) Animal dsRNA and ssRNA-Viruses Subcommittee Chair.

^‡

2020–2023 ICTV Hantaviridae Study Group members.

Viruses 2023, 15(3), 660; https://doi.org/10.3390/v15030660

Submission received: 16 February 2023 / Accepted: 21 February 2023 / Published: 28 February 2023

(This article belongs to the Special Issue Hantavirus Ecology, Epidemiology, and Disease, in Memory of Dr. Ho Wang Lee)

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Abstract

:

The official classification of newly discovered or long-known unassigned viruses by the International Committee on Taxonomy of Viruses (ICTV) requires the deposition of coding-complete or -near-complete virus genome sequences in GenBank to fulfill a requirement of the taxonomic proposal (TaxoProp) process. However, this requirement is fairly new; thus, genomic sequence information is fragmented or absent for many already-classified viruses. As a result, taxon-wide modern phylogenetic analyses are often challenging, if not impossible. This problem is particularly eminent among viruses with segmented genomes, such as bunyavirals, which were frequently classified solely based on single-segment sequence information. To solve this issue for one bunyaviral family, Hantaviridae, we call on the community to provide additional sequence information for incompletely sequenced classified viruses by mid-June 2023. Such sequence information may be sufficient to prevent their possible declassification during the ongoing efforts to establish a coherent, consistent, and evolution-based hantavirid taxonomy.

Keywords:

actinovirus; agnathovirus; Bunyavirales; Hantaviridae; hantavirid; hantavirus; loanvirus; mobatvirus; orthohantavirus; thottimvirus

1. Introduction

In 2017, the International Committee on Taxonomy of Viruses (ICTV) reacted to the rapid increase in virus discovery via metagenomics and metatranscriptomics by permitting an official virus classification based only on genomic sequence information, as long as that information is coding-complete (i.e., covers all open reading frames) or -near-complete (i.e., lacks only very few terminal or internal nucleotides that are difficult to resolve) [1]. This decision was based on the realization that a true depiction of the virosphere [2] would be impossible if individually characterizing viruses in the laboratory continued to be required; in addition, genomic sequence information enables large-scale phylogenetic analyses and thereby the establishment of evolutionary relationships among viruses in the absence of replicating representatives [1]. However, this decision was prospective, i.e., it applied to the assembly and evaluation of novel taxonomic proposals (TaxoProps) for the classification of newly discovered or previously unclassified viruses into taxa. (For an overview of the taxonomic classification process, the difference between species and virus, and classification methodologies, see Simmonds et al., 2023 [3]) Viruses classified by the ICTV prior to the 2017 decision remained classified even with, in some cases, the complete absence of genomic sequence information. Consequently, many virus taxa are currently mosaics of classified viruses that were placed into the official taxonomy through disparate methodologies using divergent classification criteria. This situation is untenable because the very goal of the ICTV is to “categorize the multitude of known viruses into a single classification scheme that reflects their evolutionary relationships, i.e., their individual phylogenies” [3,4].

The establishment of phylogenies requires genomic sequence information. More importantly, high quality of a virus genome sequence (e.g., sequence read depth and population analysis), redundancy (availability of equally high-quality genome sequences from different isolates of the same virus), completeness of the virus genome, and, in case of viruses with segmented genomes, each individual genome sequence derived from a single isolate enable improved and possibly complementary phylogenetic analyses using different parts of the genomes and their expression products—thus increasing confidence in the resulting taxonomic structures.

The ICTV first and foremost looks to its Study Groups to continuously improve the taxonomy of, typically, family-rank taxa with the long-term vision of achieving the ICTV goal of an accurate depiction of evolutionary virus relationships. Thus, it is largely up to these Study Groups to decide on virus classification criteria (e.g., minimal information necessary for classification) and taxon demarcation criteria (e.g., methodologies and metrics to be used for species and genus demarcation within a family). Here we express the intent of the ICTV Hantaviridae Study Group to resolve the classification problems plaguing the family Hantaviridae, with a first step envisioned to be an overhaul of the family based on analyses only, including viruses associated with coding-complete/-near-complete genome sequence availability in GenBank. We call on the hantavirid community to determine and/or provide missing sequence information for currently classified hantavirids to prevent their potential declassification and to provide such sequence information for currently unclassified viruses so that they can be assigned to species. With the annual ICTV deadline for the submission of TaxoProps this year being likely at the beginning of July, this information is needed by mid-June 2023 and then annually thereafter.

2. Current (2022–2023) Taxonomy of the Bunyaviral Family Hantaviridae

The official hantavirid taxonomy began relatively soon after the description of Hantaan virus (HTNV) in South Korean striped field mice (Apodemus agrarius (Pallas, 1771)) in 1976 [5,6,7] and the subsequent isolation of HTNV in cell culture in 1981 [8]. In 1983, first calls were issued to create an official genus for HTNV and its relatives [9,10,11,12]. In 1987, the genus Hantavirus was officially accepted by the ICTV as part of the family Bunyaviridae [13,14]. The subsequent discovery of hundreds of novel viruses assignable to this family resulted in the promotion of the family to the order Bunyavirales in 2017 [15]. Along with this promotion, the genus Hantavirus was promoted to the monogeneric family Hantaviridae, and all other already-classified viruses were assigned to the genus Orthohantavirus [15]. In 2019, the ICTV Hantaviridae Study Group designated DivErsity pArtitioning by hieRarchical Clustering (DEmARC) as the method of choice for the classification of novel hantavirids [16]. Analyses led to the establishment of the hantavirid genera Loanvirus, Mobatvirus, and Thottimvirus for divergent viruses discovered in bats and eulipotyphlans [17] and the genera Actinovirus, Agnathovirus, and Reptillovirus for divergent viruses discovered in fish and reptiles [18]. The family was then subdivided into four subfamilies: Acanthavirinae (Actinovirus), Agantavirinae (Agnathovirus), Mammantavirinae (Loanvirus, Mobatvirus, Orthohantavirus, and Thottimvirus), and Repantavirinae (Reptillovirus) [18] (for a more detailed history of the taxonomy of family Hantaviridae, see Kuhn and Schmaljohn, 2023 [19]). The current (2022–2023) taxonomy of Hantaviridae [20] is outlined in Table 1.

3. Future (2024–) Taxonomy of the Bunyaviral Family Hantaviridae

The 2019 taxonomic reorganization of the family Hantaviridae via DEmARC was limited to hantavirids for which coding-complete genome sequence information for the small (S) and medium (M) segments was available; concatenated S + M sequences were used for multiple-sequence alignment to infer phylogeny, and pairwise evolutionary distance (PED) values were calculated using a maximum-likelihood approach with a Whelan and Goldman (WAG) substitution model. A PED cut-off value of 0.1 was used for species demarcation within Hantaviridae [16]. The analysis was limited to the sequences of the S and M segments to maintain the previous hantavirid classification, which was largely based on phenotypic characters and limited protein sequence similarities of individual viruses [21], as much as possible and, in particular, to prevent the declassification of “important” orthohantaviruses (i.e., human pathogens) for which there was no or only fragmented sequence information for the large (L) segment [16].

However, the absence of L-segment sequence information in hantavirid taxonomic analyses is problematic for several reasons. First, the entire taxonomy of the realm Riboviria, which includes negarnaviricot Hantaviridae, is based on a single “hallmark gene”. This hallmark gene is the open reading frame (ORF) encoding an RNA-directed RNA polymerase (RdRp) [22,23], which in the case of hantavirids is a part of the L protein, encoded by the L segment. Thus, the absence of RdRp sequence information prevents the classification of a virus into this realm and, ipso facto, also into any lower-ranked ribovirian taxon. Second, as the name implies, L is by far the longest protein encoded by hantavirids; generally speaking, the main S-segment ORF is 1–3 kb long; the M-segment ORF is 3.2–4.9 kb long; and the L-segment ORF is 6.8–12 kb long (judged by GenBank entries). Thus, an analysis of, for example, concatenated S + M sequences ignores a substantial percentage of a hantavirid’s genome sequence. Third, sequence variability is unevenly distributed among hantavirid segments; the M-segment sequence is the least conserved, whereas the L-segment sequence is the most conserved. Both extremes can be used to achieve disparate goals, such as species and sub-species classifications, which require sequence divergence, and family and subfamily cohesiveness, which requires relatively conserved sequences. Finally, increasing structural information suggests that the Gn/Gc polyprotein encoded by hantavirid and other bunyaviral M segments (at least those of certain nairovirids, phenuivirids, peribunyavirids, and tospovirids) share a common ancestor with the membrane fusion machinery of distantly related positive-strand RNA viruses: alphaviruses (Martellivirales: Togaviridae), rubella virus (Hepelivirales: Matonaviridae), and flaviviruses sensu stricto (Amarillovirales: Flaviviridae) [24]; hence, the M segments are likely independent acquisitions in bunyaviral genome evolution. In addition, an increasing number of negarnaviricots that are being discovered in fungi and invertebrates do not appear to have M segments. Thus, although all currently classified hantavirids have M segments, the reliance on M segments within concatenated S + M data may become insufficient for family-wide analyses and may be inadequate for order-wide analyses.

The ICTV Hantaviridae Study Group decided to reassess the entire family for the 2023–2024 taxonomic cycle and plans to submit a TaxoProp proposing a new family taxonomy by the 2023 submission deadline (beginning of July). While the approaches/methodologies for reanalysis remain under discussion, a decision was made to only assess viruses for which there is S + M + L coding-complete or near-complete sequence information and deem all other viruses unclassifiable a priori. This stringent criterion would, at a minimum, result in the abolishment of six orthohantavirus species (Table 1, red), the declassification (removal from established species) of an additional 11 orthohantaviruses (Table 1, orange), and the possible renaming of two species (Table 1, purple) if word stem links between species and member viruses are desired to be maintained.

Table 1. Scheme of the 2022 [20] and projected 2023 [25] ^% taxonomy of the bunyaviral family Hantaviridae.

Genus	Species Name (2022)	Projected Species Name (2023)	Virus Name (Abbreviation)	Coding-Complete/-Near-Complete Genome Sequence Available in GenBank? ^{^}
Subfamily Acanthavirinae
Actinovirus	Batfish actinovirus	Actinovirus halieutaeae	Wēnlǐng minipizza batfish virus (WEMBV)	Yes
	Goosefish actinovirus	Actinovirus lophii	Wēnlǐng yellow goosefish virus (WEYGV)	Yes
	Perch actinovirus	Actinovirus bernense	Bern perch virus (BRPV)	Yes
	Spikefish actinovirus	Actinovirus triacanthodis	Wēnlǐng red spikefish virus (WERSV)	Yes
Subfamily Agantavirinae
Agnathovirus	Hagfish agnathovirus	Agnathovirus eptatreti	Wēnlǐng hagfish virus (WEHV)	Yes
Subfamily Mammantavirinae
Loanvirus	Brno loanvirus	Loanvirus brunaense	Brno virus (BRNV)	Yes
	Longquan loanvirus	Loanvirus longquanense	Lóngquán virus (LQUV)	Yes
Mobatvirus	Laibin mobatvirus	Mobatvirus laibinense	Láibīn virus (LAIV)	Yes
	Lena mobatvirus	Mobatvirus lenaense	Lena virus (LENV)	Yes
	Nova mobatvirus	Mobatvirus novaense	Nova virus (NVAV)	Yes
	Quezon mobatvirus	Mobatvirus quezonense	Quezon virus (QZNV)	Yes
	Xuan Son mobatvirus	Mobatvirus xuansonense	Xuân Sơn virus (XSV)	Yes
Orthohantavirus	Andes orthohantavirus	Orthohantavirus andesense	Andes virus (ANDV)	Yes
			Castelo dos Sonhos virus (CASV)	No
			Lechiguanas virus (LECV = LECHV)	No
			Orán virus (ORNV)	No
	Asama orthohantavirus	Orthohantavirus asamaense	Asama virus (ASAV)	Yes
	Asikkala orthohantavirus	Orthohantavirus asikkalaense	Asikkala virus (ASIV)	Yes
	Bayou orthohantavirus	Orthohantavirus bayoui	bayou virus (BAYV)	Yes
			Catacamas virus (CATV)	Yes
	Black Creek Canal orthohantavirus	Orthohantavirus nigrorivense	Black Creek Canal virus (BCCV)	Yes
	Bowe orthohantavirus	Orthohantavirus boweense	Bowé virus (BOWV)	Yes
	Bruges orthohantavirus	Orthohantavirus brugesense	Bruges virus (BRGV)	Yes
	Cano Delgadito orthohantavirus	Orthohantavirus delgaditoense	Caño Delgadito virus (CADV)	Yes
	Cao Bang orthohantavirus	Orthohantavirus caobangense	Cao Bằng virus (CBNV)	Yes
			Liánghé virus (LHEV)	No
	Choclo orthohantavirus	Orthohantavirus chocloense	Choclo virus (CHOV)	Yes
	Dabieshan orthohantavirus	Orthohantavirus dabieshanense	Dàbiéshān virus (DBSV)	No
	Dobrava-Belgrade orthohantavirus	Orthohantavirus dobravaense	Dobrava virus (DOBV)	Yes
			Kurkino virus (KURV)	Yes
			Saaremaa virus (SAAV)	No
			Sochi virus (SOCV)	Yes
	El Moro Canyon orthohantavirus	Orthohantavirus moroense	Carrizal virus (CARV)	Yes
			El Moro Canyon virus (ELMCV)	No
			Huitzilac virus (HUIV)	Yes
	Fugong orthohantavirus	Orthohantavirus fugongense	Fúgòng virus (FUGV)	Yes
	Fusong orthohantavirus	Orthohantavirus fusongense	Fǔsōng virus (FUSV)	No
	Hantaan orthohantavirus	Orthohantavirus hantanense	Amur virus (AMRV)	Yes
			Hantaan virus (HTNV)	Yes
			Soochong virus (SOOV)	Yes
	Jeju orthohantavirus	Orthohantavirus jejuense	Jeju virus (JJUV)	Yes
	Kenkeme orthohantavirus	Orthohantavirus kenkemeense	Kenkeme virus (KKMV)	Yes
	Khabarovsk orthohantavirus	Orthohantavirus khabarovskense	Khabarovsk virus (KHAV)	Yes
			Topografov virus (TOPV)	Yes
	Laguna Negra orthohantavirus	Orthohantavirus negraense	Laguna Negra virus (LANV)	No
			Maripa virus (MARV)	Yes
			Rio Mamoré virus (RIOMV)	Yes
	Luxi orthohantavirus	Orthohantavirus luxiense	Lúxī virus (LUXV)	Yes
	Maporal orthohantavirus	Orthohantavirus maporalense	Maporal virus (MAPV)	Yes
	Montano orthohantavirus	Orthohantavirus montanoense	Montaño virus (MTNV)	Yes
	Necocli orthohantavirus	Orthohantavirus necocliense	Necoclí virus (NECV)	No
	Oxbow orthohantavirus	Orthohantavirus oxbowense	Oxbow virus (OXBV)	No
	Prospect Hill orthohantavirus	Orthohantavirus prospectense	Prospect Hill virus (PHV)	Yes
	Puumala orthohantavirus	Orthohantavirus puumalaense	Hokkaido virus (HOKV)	Yes
			Muju virus (MUJV)	Yes
			Puumala virus (PUUV)	Yes
	Robina orthohantavirus	Orthohantavirus robinaense	Robina virus (ROBV) *	Yes
	Rockport orthohantavirus	Orthohantavirus rockportense	Rockport virus (RKPV)	Yes
	Sangassou orthohantavirus	Orthohantavirus sangassouense	Sangassou virus (SANGV)	Yes
	Seewis orthohantavirus	Orthohantavirus seewisense	Seewis virus (SWSV)	No
	Seoul orthohantavirus	Orthohantavirus seoulense	gōu virus (GOUV)	No
			Seoul virus (SEOV)	Yes
	Sin Nombre orthohantavirus	Orthohantavirus sinnombreense	New York virus (NYV)	No
			Sin Nombre virus (SNV)	Yes
	Tatenale orthohantavirus	Orthohantavirus tatenalense	Tatenale virus (TATV)	Yes
	Thailand orthohantavirus	Orthohantavirus thailandense	Anjozorobe virus (ANJZV)	Yes
			Serang virus (SERV)	No
			Thailand virus (THAIV)	Yes
	Tigray orthohantavirus	Orthohantavirus tigrayense	Tigray virus (TIGV)	Yes
	Tula orthohantavirus	Orthohantavirus tulaense	Adler virus (ADLV)	No
			Tula virus (TULV)	Yes
	Yakeshi orthohantavirus	Orthohantavirus yakeshiense	Yákèshí virus (YKSV)	No
Thottimvirus	Imjin thottimvirus	Thottimvirus imjinense	Imjin virus (MJNV)	Yes
	Thottapalayam thottimvirus	Thottimvirus thottapalayamense	Thottapalayam virus (TPMV)	Yes
Subfamily Repantavirinae
Reptillovirus	Gecko reptillovirus	Reptillovirus hemidactyli	Hǎinán oriental leaf-toed gecko virus (HOLGV)	Yes

Per the ICTV, viruses are real objects that are assigned to concepts/categories called taxa. Species, genera, subfamilies, families, and orders are taxa. Taxon names are always italicized and always begin with a capital letter. Virus names are not italicized and are not capitalized, except if the name or a name component is a proper noun [3,26]. This table lists the virus names with their correct (lack of) capitalization; ^% if ratified in the March 2023 ICTV-wide vote; ^{^} as judged by preliminary analyses of GenBank-deposited sequences but requiring careful reanalysis; * Robina virus might be a mobatvirus, possibly requiring reclassification [27].

On the other hand, the forthcoming analysis may include previously unclassified potential hantavirids for which sufficient S + M + L sequences have been deposited. A cursory survey revealed that at least two potential loanviruses, one potential mobatvirus, 16 potential orthohantaviruses, and one potential thottimvirus could be classified or be identified as isolates of already-classified viruses (Table 2, green).

4. Discussion

Hantavirid taxonomy is clearly in disarray, as exemplified by the numerous viruses with different names in the literature that may only represent isolates of other named viruses rather than being distinct viruses (species with several members in Table 1; numerous viruses listed in Table 2). Table 1 and Table 2 clarify that the diversity of hantavirids is only incompletely represented by the current taxonomy and family-wide analyses of hantavirids, and, therefore, the most appropriate sub-family taxon distribution is largely impossible because of the lack of evolutionary meaningful taxonomic markers (e.g., segment sequences, hallmark genes, and gene motifs). Even a relatively limited hantavirid classification inclusion criterion, such as the requirement of coding-complete/-near-complete sequences, will have a noticeable impact on the current taxonomy through the declassification of at least 17 orthohantaviruses (Table 1) and the classification of up to 20 hantavirids (Table 2). Taxonomic changes would likely be even more drastic if classification inclusion criteria were set more stringently; for instance, the ICTV Hantaviridae Study Group might additionally require that the S, M, and L genome segment sequences of a particular virus must be derived from the same isolate (rather than being a mosaic from isolates collected in different places at different times) and/or that specific sequencing standards [93,94] would have to be fulfilled to increase “trust” that the sequence is correct.

We call on the hantavirid and wider bunyaviral community to provide additional and/or improved sequence information for any incompletely sequenced putative hantavirid prior to mid-June 2023 to support the ICTV Hantaviridae Study Group’s current effort to establish an updated, coherent, consistent, and evolution-based hantavirid taxonomy. These sequences ought to be deposited into GenBank, ideally along with notifying the Study Group that additional information has become available for inclusion in analyses.

During the upcoming months, the ICTV Hantaviridae Study Group will make initial decisions on:

the minimal requirement(s) for hantavirid classification (e.g., definitions of “near-complete genome sequence” and minimal sequence quality);
the method(s) for hantavirid classification (e.g., DEmARC and/or pairwise sequence comparison [PASC]);
the minimum input information (e.g., concatenated S + M or S + L or M + L or S + M + L genomic segment sequences; individual phylogenies and pairwise sequence comparisons for each genome segment);
the possible resolution of “species complexes” (i.e., species that currently harbor more than one member virus [e.g., Andes orthohantavirus/Orthohantavirus andesense]);
which particular sequences should be regarded as type/reference sequences for each species and be ultimately represented in The National Center for Biotechnology Information (NCBI) Reference Sequence (RefSeq) database.

All of these decisions will crucially depend on the availability of expanded high-quality hantavirid genomic sequence information. In the absence of this information, a decision may be forced to drastically reboot and simplify hantavirid taxonomy by removing the “virus status” from many unclassified hantavirids to discourage the use of their currently assigned names—effectively putting many hantavirids “on hold” until sufficient sequence information becomes available to assess their taxonomic statuses.

Author Contributions

Conceptualization, J.H.K.; writing—original draft preparation, J.H.K.; writing—review and editing, all authors. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported in part through Laulima Government Solutions, LLC, prime contract with the National Institutes of Health (NIH) National Institute of Allergy and Infectious Diseases (NIAID) under Contract No. HHSN272201800013C. J.H.K. performed this work as an employee of Tunnell Government Services (TGS), a subcontractor of Laulima Government Solutions, LLC, under Contract No. HHSN272201800013C.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

The authors thank Anya Crane (Integrated Research Facility at Fort Detrick, Division of Clinical Research, National Institute of Allergy and Infectious Diseases, National Institutes of Health, Fort Detrick, Frederick, MD, USA) for critically editing the manuscript.

Conflicts of Interest

The authors declare no conflict of interest.

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Table 2. Unclassified potential hantavirids.

Potential Genus Affiliation ^{^}	Virus ^%	Coding-Complete/-Near-Complete Genome Sequence Available in GenBank? ^{^}
Actinovirus	Murray-Darling rainbowfish hantavirus [28]	No
	pygmy goby hantavirus [29]	No
Loanvirus	Huángpí virus [30]	No
	Magboi virus [31]	No
	Méliandou hantavirus [32]	No
	Mouyassué virus [33]	Yes
	Ponan loanvirus [Not associated with a publication]	Yes
Mobatvirus	Đakrông virus [34]	Yes
	Kiwira virus [27]	No
	Altai virus [35,36]	No
	Makokou virus [37]	No
	Sarawak mobatvirus [38]	No
Orthohantavirus	Academ virus [39]	No
	Alto Paraguay virus [40]	No
	Amga virus [41]	No
	Anajatuba virus [42]	No
	Ape Aimé–Itapúa virus [43] ¹	No
	Araraquara virus [44] ¹	No
	Araucaria virus [45] ¹	No
	Artybash virus [46] ²	Yes
	Ash River virus [47]	No
	Asturias virus [Not associated with a publication]	No
	Azagny virus [48]	No
	Belgrade virus [49]	No
	Bermejo virus [50] ¹	No
	Biya river virus [Unpublished]	No
	Bloodland Lake virus [Not associated with a publication] ³	No
	Blue River virus [51] ³	No
	Boginia virus [52]	No
	Buenos Aires virus [53] ¹	No
	Calabazo virus [54]	No
	Cajuru virus [55] ¹	No
	Camp Riley virus [56]	No
	Central Plata virus [57] ¹	No
	CGRn9415 virus [58] ⁴	No
	Dode virus [59]	No
	Fox Creek virus [Listed in [21]]	No
	Girard Point virus [60] ⁴	No
	hantavirus sp. strain Tamarin/BRA/SM22/2014 [Not associated with a publication] ¹	No
	HoJo virus [61] ⁵	No
	Hu39694 virus [62] ¹	No
	Iamonia virus [Listed in [21]]	No
	Isla Vista virus [63]	No
	Itapúa virus [64] ¹	No
	Jaborá virus [43] ¹	No
	Jemez Springs virus [47]	No
	jerboa hantavirus [65]	No
	Jīngmén Rattus norvegicus orthohantavirus 1 [Not associated with a publication]	Yes
	Juquitiba virus [66] ¹	No
	Jurong virus [67] ⁶	No
	Kielder hantavirus [68]	No
	Landiras virus [69]	No
	Lanka virus [70]	Yes
	Leakey virus [71]	No
	Limestone Canyon virus [72]	No
	Lohja virus [73] ²	No
	Maciel virus [62] ¹	No
	Malacky virus [74] ⁷	No
	Monongahela virus [75] ³	Yes
	Muleshoe virus [76]	No
	Ñeembucu virus [64] ¹	No
	Paranoá virus [77] ¹	No
	Pergamino virus [62] ¹	No
	Playa de Oro virus [78]	No
	Powell Butte virus [Listed in [21]]	No
	prairie vole virus [Unpublished]	No
	Qiān Hú Shān virus/Qiāndǎo Lake virus [79]	No
	Rio Mearim virus [42]	No
	Río Segundo virus [80]	No
	Rusne virus [81]	Yes
	Sapporo rat virus [82] ⁴	No
	Sarufutsu virus [Not associated with a publication]	No
	Shěnyáng virus [83]	No
	Taimyr virus [84]	No
	Tanganya virus [85]	No
	Traemmersee virus [86] ⁸	Yes
	Tualatin River virus [Listed in [21]]	No
	Tunari virus [87] ¹	No
	Uurainen virus [Not associated with a publication] ²	No
	Ussuri virus [Not associated with a publication] ⁹	Yes
	Vladivostok virus [Not associated with a publication]	No
	Wēnzhōu Niviventer niviventer orthohantavirus 1 [Not associated with a publication]	Yes
	Wùfēng Chodsigoa smithii orthohantavirus 1 [Not associated with a publication]	Yes
	Xìnyì virus [88] ¹⁰	Yes
	Yuánjiāng virus [83]	Yes
Thottimvirus	Dàhónggōu creek virus [89]	No
	Kilimanjaro virus [90]	No
	Uluguru virus [90]	No
	Wēnzhōu Suncus murinus thottimvirus 1 [Not associated with a publication]	Yes
Reptillovirus	skink hantavirus [91]	No
New?	coleopteran hanta-related virus OKIAV221 [92]	No
	plecopteran hanta-related virus OKIAV215 [92]	No

^{^} As judged by preliminary analyses of GenBank-deposited sequences but requiring careful reanalysis; ^% this list is based on a cursory analysis of the hantavirid literature and GenBank; the list may not be all-inclusive and may contain errors; ¹ likely members of the species Andes orthohantavirus/Orthohantavirus andesense and possibly isolates of Andes virus (ANDV); ² likely members of the species Seewis orthohantavirus/Orthohantavirus seewisense and possibly isolates of Seewis virus (SWSV); ³ likely members of the species Sin Nombre orthohantavirus/Orthohantavirus sinnombreense and possibly isolates of Sin Nombre virus (SNV); ⁴ likely members of the species Seoul orthohantavirus/Orthohantavirus seoulense and possibly isolates of Seoul virus (SEOV); ⁵ likely a member of the species Hantaan orthohantavirus/Orthohantavirus hantanense and possibly an isolate of Hantaan virus (HTNV); ⁶ likely a member of species Thailand orthohantavirus/Orthohantavirus thailandense, and possibly an isolate of Thailand virus (THAIV); ⁷ likely a member of the species Tula orthohantavirus/Orthohantavirus tulaense and possibly an isolate of Tula virus (TULV); ⁸ likely a member of the species Tatenale orthohantavirus/Orthohantavirus tatenalense and possibly an isolate of Tatenale virus (TATV); ⁹ likely a member of the species Puumala orthohantavirus/Orthohantavirus puumalaense and possibly an isolate of Puumala virus (PUUV); ¹⁰ likely a member of the species Cao Bang orthohantavirus/Orthohantavirus caobangense and possibly an isolate of Cao Bằng virus (CBNV).

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Kuhn, J.H.; Bradfute, S.B.; Calisher, C.H.; Klempa, B.; Klingström, J.; Laenen, L.; Palacios, G.; Schmaljohn, C.S.; Tischler, N.D.; Maes, P. Pending Reorganization of Hantaviridae to Include Only Completely Sequenced Viruses: A Call to Action. Viruses 2023, 15, 660. https://doi.org/10.3390/v15030660

AMA Style

Kuhn JH, Bradfute SB, Calisher CH, Klempa B, Klingström J, Laenen L, Palacios G, Schmaljohn CS, Tischler ND, Maes P. Pending Reorganization of Hantaviridae to Include Only Completely Sequenced Viruses: A Call to Action. Viruses. 2023; 15(3):660. https://doi.org/10.3390/v15030660

Chicago/Turabian Style

Kuhn, Jens H., Steven B. Bradfute, Charles H. Calisher, Boris Klempa, Jonas Klingström, Lies Laenen, Gustavo Palacios, Connie S. Schmaljohn, Nicole D. Tischler, and Piet Maes. 2023. "Pending Reorganization of Hantaviridae to Include Only Completely Sequenced Viruses: A Call to Action" Viruses 15, no. 3: 660. https://doi.org/10.3390/v15030660

APA Style

Kuhn, J. H., Bradfute, S. B., Calisher, C. H., Klempa, B., Klingström, J., Laenen, L., Palacios, G., Schmaljohn, C. S., Tischler, N. D., & Maes, P. (2023). Pending Reorganization of Hantaviridae to Include Only Completely Sequenced Viruses: A Call to Action. Viruses, 15(3), 660. https://doi.org/10.3390/v15030660

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Pending Reorganization of Hantaviridae to Include Only Completely Sequenced Viruses: A Call to Action

Abstract

1. Introduction

2. Current (2022–2023) Taxonomy of the Bunyaviral Family Hantaviridae

3. Future (2024–) Taxonomy of the Bunyaviral Family Hantaviridae

4. Discussion

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Acknowledgments

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