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Complete genome sequence of Halorubrum pleomorphic virus 8

[version 1; peer review: 1 approved]
Tatiana Demina
https://orcid.org/0000-0003-3746-5533
1Elina Laanto
https://orcid.org/0000-0003-4172-3128
2Hanna M. Oksanen3
Tatiana Demina
https://orcid.org/0000-0003-3746-5533
1Elina Laanto
https://orcid.org/0000-0003-4172-3128
2Hanna M. Oksanen3
PUBLISHED 30 Apr 2026
Author details Author details
OPEN PEER REVIEW
REVIEWER STATUS

This article is included in the Pathogens gateway.

This article is included in the Genomics and Genetics gateway.

Abstract

Pleomorphic archaeal viruses are widespread and abundant in hypersaline environments and beyond. Still, a relatively low number of isolates are available for this viral group. Here, we present the complete genome sequence of Halorubrum pleomorphic viruses 8 (HRPV-8), which was previously isolated from the Samut Sakhon solar saltern, Thailand, on a Halorubrum species. The HRPV-8 genome was assembled into a circular 10,824-bp-long contig with a GC content of 63.2%. The genome annotation resulted in 12 open reading frames, including a VP4-like spike protein-encoding gene, which is a hallmark of pleomorphic archaeal viruses. Seven and three putative proteins in HRPV-8 were 99–100% identical to their counterparts in Halorubrum pleomorphic viruses 2 and 6 (HRPV-2 and HRPV-6), respectively, members of the genus Alphapleolipovirus. The average nucleotide identity values within these three viral genomes were 92–96%. According to VIRIDIC analyses of intergenomic similarities, HRPV-8 represents its own species. Thus, based on the observed pleolipoviral genome architecture and sequence similarities to other alphapleolipoviruses, we propose to classify HRPV-8 as a new species within the Alphapleolipovirus genus of the Pleolipoviridae family.

Keywords

archaea, pleomorphic virus, viral genome, halophilic, solar saltern, Alphapleolipoviridae

Corresponding author: Tatiana Demina
Competing interests: No competing interests were disclosed.
Grant information: The work was supported by the Research Council of Finland (TD: grant 330977) and the Kone Foundation (TD). This project has received funding from the European Research Council (ERC) under the European Union’s Horizon Europe research and innovation programme to EL (grant agreement No 101117204). HMO was supported by the University of Helsinki and Research Council of Finland by funding for FINStruct and Instruct Centre FI, part of Biocenter Finland and Instruct-ERIC and Horizon MSCA 101120407. Open access funded by Helsinki University Library.
The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Copyright:  © 2026 Demina T et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
How to cite: Demina T, Laanto E and Oksanen HM. Complete genome sequence of Halorubrum pleomorphic virus 8 [version 1; peer review: 1 approved]. F1000Research 2026, 15:654 (https://doi.org/10.12688/f1000research.179903.1) First published: 30 Apr 2026, 15:654 (https://doi.org/10.12688/f1000research.179903.1) Latest published: 30 Apr 2026, 15:654 (https://doi.org/10.12688/f1000research.179903.1)

Introduction

Archaeal viruses represent one of the least studied parts of the virosphere. Furthermore, the vast morphological and genetic diversity observed in the known archaeal viruses (Krupovic et al. 2018) suggests that novel viruses await discovery. Hypersaline environments around the world have served as rich sources for isolating archaeal viruses (Atanasova et al. 2012, 2015; Mizuno et al. 2019). So far, the majority of isolated halophilic archaeal viruses display tailed virus particles, while other virus morphotypes, such as pleomorphic, are currently represented by less isolates (Atanasova et al. 2016; Demina and Oksanen 2020). Although originally found in hypersaline environments, pleomorphic archaeal viruses seem to be more widespread than first thought (Medvedeva et al. 2023; Baquero et al. 2024). Currently (as of April 2026), three families within the realm Pleomoviria comprise pleomorphic archaeal viruses: Pleolipoviridae (Liu et al. 2022), Thalassapleoviridae (Baquero et al. 2024; Varsani et al. 2025), and Nanopleoviridae (Zhou et al. 2025), which include viruses associated with archaea within the classes Halobacteria and Archaeoglobi as well as the phylum Nanohaloarchaeota, respectively.

The family Pleolipoviridae includes three genera: Alpha-, Beta-, and Gammapleolipoviridae (Liu et al. 2022). In addition, the Delta- and Epsilon- genera were proposed (Alarcón-Schumacher et al. 2023). The currently ratified members of the family Pleolipoviridae demonstrate narrow host ranges within the class Halobacteria (Liu et al. 2022), where they establish persistent, non-lytic infections and are thought to exit host cells via budding (Pietilä et al. 2012; Svirskaitė et al. 2016; Alarcón-Schumacher et al. 2022), while some pleolipoviruses are temperate (Liu et al. 2015; Wang et al. 2018; Atanasova et al. 2018; Dyall-Smith et al. 2021; Alarcón-Schumacher et al. 2023). Proviral regions and plasmids related to pleolipoviruses are widely found in archaea, suggesting their long-standing evolutionary relationships as well as the global abundance of these viruses and related mobile genetic elements (Sencilo et al. 2012; Liu et al. 2015; Atanasova et al. 2018; Alarcón-Schumacher et al. 2023).

Pleolipoviral particles are pleomorphic membrane vesicles (typically 40–70 nm in diameter) which consist of two major proteins: a spike protein and an internal membrane protein, each of which can occur in one or two types (Pietilä et al. 2012; El Omari et al. 2019). Interestingly, the relatively short genomes (7–17 nt or bp) vary in structure across the known isolates, and may be circular single-stranded (ss) DNA, circular double-stranded (ds) DNA (also with ss interruptions), or linear ds DNA molecules (Pietilä et al. 2009; Roine et al. 2010; Sencilo et al. 2012). Overall nucleotide similarity between the genomes of pleolipoviruses is relatively low, but a cluster of typically five open reading frames (ORFs) are more conserved, including the gene encoding the spike protein (the VP4-like fusogen), which serves as the hallmark gene of this viral group (Pietilä et al. 2012; Sencilo et al. 2012; El Omari et al. 2019; Alarcón-Schumacher et al. 2023).

Halorubrum pleomorphic virus 8 (HRPV-8) was isolated from an environmental sample collected at a solar saltern in Samut Sakhon, Thailand (Atanasova et al. 2015). HRPV-8 produced turbid plaques on two Halorubrum strains originating from the same location. Although HRPV-8 was not sensitive to chloroform, transmission electron microscopy and the protein profile of the purified virions indicated that it is a pleomorphic virus (Atanasova et al. 2015). Here, we present the complete genome sequence of HRPV-8 and suggest its classification within the genus Alphapleolipovirus of the family Pleolipoviridae.

Methods

Virus purification, nucleic acid extraction, and genome sequencing

HRPV-8 was grown aerobically on Halorubrum sp. SP3–3 in the modified growth medium (MGM) at 37 °C using the double-layer technique as described previously (Atanasova et al. 2012, 2015). Confluent plates were used for preparing the virus stock which was used for virus purification. Viruses were purified using polyethylene glycol 6000 (Ubichem Cat No. KG P001-HS) and NaCl (Fisher Chemicals Cat No. S/3120/63) precipitation, followed by rate-zonal ultracentrifugation in sucrose (VWR Cat No. 27480.294) as described (Atanasova et al. 2012). Nucleic acids were extracted from purified virus particles with PureLink™ Viral RNA/DNA Mini Kit (Thermo Fisher Scientific Cat No. 12280050). Genomic DNA was sequenced by Novogene (UK) using paired-end sequencing (2x150 bp) performed on the Illumina NovaSeq X platform, yielding a total of approximately 1 Gb of raw data.

Genome assembly and analyses

Raw reads were trimmed using fastp v. 0.24.0 (−q 30 -l 50) (Chen et al. 2018) and quality-checked with FastQC v. 0.12.1 (https://www.bioinformatics.babraham.ac.uk/projects/fastqc/). Contigs were assembled using Spades v. 4.2.0 in the --meta mode (Nurk et al. 2017), since the sample contained both viral and host DNA. BBTools Stats was used for assessing the assembly statistics (sourceforge.net/projects/bbmap/). Among assembled contigs, the viral contig that was assigned to Pleolipoviridae with geNomad v. 1.7.6 (database v. 1.7) (Camargo, Roux, et al. 2023b) was used for further analyses as the genome of HRPV-8. The whole genome sequence of HRPV-8 was searched against the NCBI core_nt database (Sayers et al. 2024) and the IMG/VR v. 4 database (Camargo, Nayfach, et al. 2023a) using BLASTn (E-value threshold of 1e-5) (Altschul et al. 1990). Putative functions of the ORFs products in the HRPV-8 genome were predicted using Phold v. 0.2.0 (Bouras et al. 2026) and PHROGs database (Terzian et al. 2021), BLASTp searches against the NCBI nr database (Altschul et al. 1990; Sayers et al. 2024), HHPred searches against the PDB_mmCIF70_25_May and SCOPe70_2.08 databases (probability threshold 95%) (Söding et al. 2005; Gabler et al. 2020), as well as NCBI Conserved Domain searches against the CDD and COG databases (E-value threshold 1e-3) (Marchler-Bauer et al. 2015). FastANI v. 1.33 (Jain et al. 2018) was used to calculate average nucleotide identity (ANI) between viral genomes. Pairwise amino acid identities in HRPV-8, Halorubrum pleomorphic virus 2 (HRPV-2), and Halorubrum pleomorphic virus 6 (HRPV-6) proteins were calculated using EMBOSS Needle (Madeira et al. 2024). Intergenomic similarities were calculated with the VIRIDIC web tool (Moraru et al. 2020). The genome comparisons between HRPV-8 and other pleolipoviral genomes were visualized using Clinker v. 0.0.31 (Gilchrist and Chooi 2021).

Results

Raw data included 6,754,300 read pairs, which were trimmed to 6,183,469 read pairs. From trimmed reads, 461 contigs were assembled (min = 56 bp, max = 486,959 bp, N50 = 123,392 bp). From these contigs, only two were identified as viral by geNomad: one unclassified provirus (37,872 bp) and one virus assigned to the family Pleolipoviridae (10,879 bp). The latter one displayed terminal 55-bp-long repeats, which reflected the assembly artifact from a circular template, since the used k-mer was 55. The artificial nature of the repeat was confirmed by rerunning SPAdes with the k-mer size of 77 which produced the 10,901-bp-long pleolipoviral contig with different terminal repeats of 77 bp. Thus, one of the repeats was removed, resulting in a 10,824-bp-long circular sequence, which represents the complete genome sequence of HRPV-8. Its GC content is 63.2%.

Whole-genome searches against the NCBI core_nt database retrieved the best two hits to the Halorubrum pleomorphic viruses 2 and 6 (HRPV-2: 97% coverage, 95% nt identity; HRPV-6: 78% coverage, 96% nt identity) as well as multiple hits to the sequences of halophilic archaea and other pleolipoviruses, albeit with significantly lower coverage (≤37%) ( Table 1). The ANI values between HRPV-8 versus HRPV-2 and HRPV-8 versus HRPV-6 were 95.6% and 91.5%, respectively. For comparison, the ANI between HRPV-2 and HRPV-6 is 94.7%. Searching against the IMG/VR v. 4 database with the HRPV-8 whole genome as a query retrieved hits only to HRPV-2 and HRPV-6. The VIRIDIC analysis of intergenomic similarities between HRPV-8, HRPV-2, HRPV-6 and other current members of the Alphapleolipovirus genus suggested that HRPV-8 is a separate species ( Figure 1).

Table 1. Best BLASTn hits of the HRPV-8 genome to viral genomes.

Hit*Coverage, %Nt identity, %GenBank acc noReference
Halorubrum pleomorphic virus 2 (HRPV-2)9795NC_017087 (Sencilo et al. 2012)
Halorubrum pleomorphic virus 6 (HRPV-6)7896NC_017089 (Sencilo et al. 2012)
Halorubrum virus Humcor23574MW344764(Dyall-Smith et al. 2021)
Halorubrum pleomorphic virus 9 (HRPV9)1167NC_048160 (Atanasova et al. 2018)
Tebenquiche pleomorphic virus 1 (Tebi-PV1)772PX315772(Queiss et al. 2025)
Halorubrum pleomorphic virus 3 (HRPV-3)670NC_017088 (Sencilo et al. 2012)
Halorubrum pleomorphic virus 1 (HRPV-1)669NC_012558 (Pietilä et al. 2009)
Haloferax virus Halfgib1667MW344766(Dyall-Smith et al. 2021)
Halorubrum pleomorphic virus 13 (HRPV13)568OM747534(宋珊珊 et al. 2022)

* the NCBI core_nt database; E-value threshold of 1e-5; search dated 29.1.26.

a088bdda-2ec4-410e-8206-fb0b48cc365d_figure1.gif

Figure 1. The genome of HRPV-8 and pleolipoviruses that are currently classified within the genus Alphapleolipovirus of the family Pleolipoviridae.

(A) Genome comparisons were visualized with Clinker. ORFs are colored based on annotations (see the color code, ORFs with unknown functions are shown in grey). Shading of black between ORFs shows % protein identity (see the inset) between ORF products. (B) Intergenomic similarities visualized as a heatmap with VIRIDIC.

HRPV-8 genome annotation with Phold resulted in 12 predicted ORFs, most of which encoded gene products of unknown functions ( Table 2). Consistent with the observed ANI values, seven proteins were (almost) identical (99–100% amino acid identity) in HRPV-8 and HRPV-2 ( Table 2, Figure 1). Three of these were also 99–100% identical to their counterparts in HRVP-6. Based on the Phold prediction, Conserved Domain search, as well as similarities to other pleolipoviruses, gp1 was annotated as a putative DNA replication initiation protein in HRPV-8. gp2 was predicted as a single-stranded DNA binding protein by Phold. gp3 was predicted to be an internal membrane protein, as it was similar to such proteins in other pleolipoviruses. HHPred searches and observed similarities to counterparts in HRPV-2 and HRPV-6 suggested that gp4 was a spike protein (VP4-like). gp5 was annotated as an ATPase based on the Phold prediction, HHPred and Conserved Domain searches, as well as similarities to other pleolipoviruses. gp12 had multiple hits to antitoxin and DNA-binding proteins in HHPred searches, while Conserved Domain search against the COG database recruited a hit to DNA gyrase/topoisomerase IV, subunit A (Replication, recombination and repair, COG0188).

Table 2. Genome annotation of HRPV-8.

ORF*Gene productStart, ntEnd, ntStrandPhold hit to PHROG category, noPutative functionAmino acid identity (%) to a counterpart in
HRPV-2HRPV-6
ORF1gp111,968forward713DNA replication initiation99.598.9
ORF2gp22,4942,877forward4932ssDNA binding protein100100
ORF3gp32,8773,278forward5900Internal membrane protein10085.7
ORF4gp43,3025,119forward2231Spike protein (membrane fusion)59.154.9
ORF5gp55,1285,658forward1938Unknown99.499.4
ORF6gp65,6556,491forwardNo hitUnknown96.493.5
ORF7gp76,8857,838forward1675ATPase99.497.5
ORF8gp88,0898,286reverseNo hitUnknown98.5NA**
ORF9gp98,2838,549reverseNo hitUnknown36.8NA
ORF10gp108,5428,910reverseNo hitUnknown77.9NA
ORF11gp119,38410,265reverseNo hitUnknown34.9NA
ORF12gp1210,42210,646reverse24852DNA gyrase/topoisomerase subunit10095.9

* ORFs were numbered starting from the replication initiation protein-encoding ORF, consistently with other alphapleolipoviruses

** NA, not applicable (in case of no counterparts)

Conclusions

HRPV-8 genome sequence is highly similar to those of the viruses HRPV-2 and HRPV-6, which are currently classified within the Alphapleolipovirus genus of the Pleolipoviridae family as the species of Alphapleolipovirus thailandense and Alphapleolipovirus samutsakhonense, respectively. While a few proteins were (almost) identical in HRPV-8, HRPV-2, and HRPV-6, the VP4-like spike proteins (a hallmark of pleomorphic archaeal viruses) share only 55–63% amino acid identities in these three viruses. The VIRIDIC-based comparisons of alphapleolipoviruses suggest that HRPV-8 is a separate species. Based on the observed similarities, we propose to classify HRPV-8 as a new member of the Alphapleolipovirus genus. The HRPV-8 sequence presented here contributes to resolving the genetic diversity of pleomorphic archaeal viruses, highlighting the mosaicisms of their genomes.

Data availability

NCBI GenBank: HRPV-8 complete genome sequence [HPRV-8]. Accession number PX963965.

Acknowledgements

Facilities and expertise of the Instruct-HiLIFE Biocomplex unit at the University of Helsinki, a member of Instruct-ERIC Centre Finland, FINStruct, and Biocenter Finland are gratefully acknowledged. Sari Korhonen (University of Helsinki) is thanked for her skillful technical assistance.

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Demina T, Laanto E and Oksanen HM. Complete genome sequence of Halorubrum pleomorphic virus 8 [version 1; peer review: 1 approved]. F1000Research 2026, 15:654 (https://doi.org/10.12688/f1000research.179903.1)
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The authors describe the recovery of a complete genomic sequence of poorly characterized archaeal virus belonging to the Pleolipoviridae family that infects halophilic archaea of genus Halorubrum. After comparison with other known viruses of the same family, they ... Continue reading
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    keyboard_arrow_left Back to all reports
    Alongside their report, reviewers assign a status to the article:
    Approved - the paper is scientifically sound in its current form and only minor, if any, improvements are suggested
    Approved with reservations - A number of small changes, sometimes more significant revisions are required to address specific details and improve the papers academic merit.
    Not approved - fundamental flaws in the paper seriously undermine the findings and conclusions
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