key: cord-0731482-nqcr52nu authors: Costa, Vincenzo A; Mifsud, Jonathon C O; Gilligan, Dean; Williamson, Jane E; Holmes, Edward C; Geoghegan, Jemma L title: Metagenomic sequencing reveals a lack of virus exchange between native and invasive freshwater fish across the Murray–Darling Basin, Australia date: 2021-04-13 journal: Virus Evol DOI: 10.1093/ve/veab034 sha: a3e6da5d8e939e21fdb697cb0e05f9ef9b2f22c3 doc_id: 731482 cord_uid: nqcr52nu Biological invasions are among the biggest threats to freshwater biodiversity. This is increasingly relevant in the Murray–Darling Basin, Australia, particularly since the introduction of the common carp (Cyprinus carpio). This invasive species now occupies up to ninety per cent of fish biomass, with hugely detrimental impacts on native fauna and flora. To address the ongoing impacts of carp, cyprinid herpesvirus 3 (CyHV-3) has been proposed as a potentially effective biological control agent. Crucially, however, it is unknown whether CyHV-3 and other cyprinid herpesviruses already exist in the Murray–Darling. Further, little is known about those viruses that naturally occur in wild freshwater fauna, and the frequency with which these viruses jump species boundaries. To document the evolution and diversity of freshwater fish viromes and better understand the ecological context to the proposed introduction of CyHV-3, we performed a meta-transcriptomic viral survey of invasive and native fish across the Murray–Darling Basin, covering over 2,200 km of the river system. Across a total of thirty-six RNA libraries representing ten species, we failed to detect CyHV-3 nor any closely related viruses. Rather, meta-transcriptomic analysis identified eighteen vertebrate-associated viruses that could be assigned to the Arenaviridae, Astroviridae, Bornaviridae, Caliciviridae, Coronaviridae, Chuviridae, Flaviviridae, Hantaviridae, Hepeviridae, Paramyxoviridae, Picornaviridae, Poxviridae, Reoviridae and Rhabdoviridae families, and a further twenty-seven that were deemed to be associated with non-vertebrate hosts. Notably, we revealed a marked lack of viruses that are shared among invasive and native fish sampled here, suggesting that there is little virus transmission from common carp to native fish species, despite co-existing for over fifty years. Overall, this study provides the first data on the viruses naturally circulating in a major river system and supports the notion that fish harbour a large diversity of viruses with often deep evolutionary histories. Anthropogenic stressors such as pollution, climate change and the introduction of exotic species continue to pose a significant threat to freshwater habitats, with almost one-third of all fish species threatened by extinction (World Wildlife Fund 2021). The Murray-Darling Basin, the largest freshwater river system in Australia, harbours at least twelve exotic freshwater fish species (Barrett, Bamford, and Jackson 2014) . Key among these are eastern mosquitofish (Gambusia holbrooki), redfin perch (Perca fluviatilis) and, most notably, common carp (Cyprinus carpio). Common carp (also known as European carp) were initially introduced into Australia during the mid-1800s for aquaculture operations and again on several occasions throughout the 1900s (Koehn 2004; Forsyth et al. 2013) . During extensive flooding events during the 1970s, carp spread across much of the basin and now represent up to ninety per cent of total fish biomass (Forsyth et al. 2013) . The invasion of carp has been hugely detrimental to Australian freshwater ecosystems (Koehn 2004; Forsyth et al. 2013) . Impacts include increased water turbidity, decreased light penetration, erosion of riverbanks, changes in the abundance and diversity of native invertebrate communities and outcompeting native fish species for habitat and resources (Koehn 2004; Forsyth et al. 2013; Vilizzi et al. 2014) . Several control methods have been proposed to control invasive carp; nevertheless, their resilience and high fecundity create significant challenges (Hayes et al. 2014 ). This has stimulated research into biological control methods, such as deployment of the virus cyprinid herpesvirus 3 (CyHV-3) (McColl et al. 2017; McColl, Cooke, and Sunarto 2014) . CyHV-3 is a double-stranded DNA virus (family Alloherpesviridae, order Herpesvirales) first isolated from farmed carp in the late 1990s (Matsui et al. 2008) . Since its discovery, it has been responsible for large disease outbreaks worldwide with a mortality rate of up to 80 per cent in domestic carp (Michel et al. 2010) . CyHV-3 is transmitted horizontally through direct contact with skin lesions or secretion of viral particles in freshwater where it can survive for up to 3 days (Shimizu et al. 2006) . The host range of CyHV-3 is currently limited to koi and common carp (Michel et al. 2010) . While CyHV-3 DNA has been identified in goldfish (Carrasius auratus) (Bergmann et al. 2010) , it is still relatively unclear whether infection occurs in these species (Ilouze et al. 2011; Tolo et al. 2021) . Initial laboratory trials suggest that CyHV-3 is safe for nontarget species (McColl et al. 2017 ). However, little is known about the viruses that naturally circulate in Australian native freshwater fauna, including any prior evidence for the existence of CyHV-3 (Kopf et al. 2019) , nor on the time-scales and frequency with which viruses jump between fish hosts. To completely assess the safety and efficacy of any virus biocontrol agent, including CyHV-3, a comprehensive assessment of the viruses that naturally infect both native and invasive species is required. Following the advent of meta-transcriptomic sequencing, it is now possible to characterize the entire set of viruses-the virome-within a given host (Shi, Zhang, and Holmes 2018; Zhang, Shi, and Holmes 2018) . Fish, in particular, harbour a high abundance and diversity of viruses often with deep evolutionary histories Zhang et al. 2018) . However, despite the antiquity and diversity of fish viruses, there are few studies of virus diversity and evolution in wild freshwater fish populations, particularly in the context of biological invasions. Determining the viromes of invasive freshwater fish like the common carp will enhance our understanding of the broadscale factors that influence virus emergence and evolution. As the date and site of their introduction is well-documented in Australian waters, these species can potentially provide important information on the both rate of cross-species transmission and how frequently viruses might move between invasive and native species. In addition, despite representing a small fraction of the earth's surface water, freshwater environments serve as a habitat for forty to fifty per cent of total fish species, harbouring the greatest biodiversity per land area (Dudgeon et al. 2006) . Such habitats are subject to rapid environmental change, which may significantly impact species connectivity (Johnson and Paull 2011) . Since contact and exposure between hosts are vital for cross-species transmission of viruses (Parrish et al. 2008) , these species may also inform us on the ecological factors that impact virome composition within a given host. We performed a meta-transcriptomic viral survey of invasive and native freshwater fish species across the Murray-Darling Basin in Australia to document the diversity and evolution of freshwater fish viromes and, from this, better understand the ecological drivers of virus evolution and emergence. To the best of our knowledge, this is the largest survey of freshwater fish viruses undertaken to date. In particular, we aimed to determine whether CyHV-3 is already present in common carp in Australia (Kopf et al. 2019) , and whether there is evidence for transmission of existing viruses between exotic and native species. As such, we provide important information on the ecological and evolutionary context for the potential release of future virus biocontrols. We compared the viromes of native and invasive fish species occupying different areas across the Murray-Darling Basin, Australia (Fig. 1) . Sampling occurred between January and March 2020. A total of seven native fish species were collected: bony herring (Nematalosa erebi) (n¼ 20), spangled perch (Leiopotherapon unicolor) (n ¼ 1), Australian smelt (Retropinna semoni) (n ¼ 12), Murray-Darling rainbowfish (Melanotaenia fluviatilis) (n ¼ 17), flat-headed gudgeon (Philypnodon grandiceps) (n¼ 9), western carp-gudgeon (Hypseleotris spp.) (n ¼ 20) and unspecked hardyhead (Craterocephalus fulvus) (n ¼ 6). Three species of invasive fish were also collected: common carp (C. carpio) (n ¼ 74), goldfish (C. auratus) (n¼ 5) and eastern mosquitofish (G. holbrooki) (n ¼ 15). All fish caught were apparently healthy, with no signs of disease. Fish were caught using boat electrofishing, euthanized and dissected immediately upon capture. Tissue specimens (liver and gills) were placed in RNALater and stored in a portable À80 C freezer, then later in an À80 C freezer in the laboratory at Macquarie University, Sydney. Tissue selection was based on previous studies Geoghegan et al. 2018; Geoghegan et al. 2021) , which show that liver and gill tissue serve as a rich source of viruses. To facilitate virus discovery, multiple individuals (one to ten) were pooled according to species and the location in which they were captured (Supplementary Table S2 and Fig. S1 ). Frozen samples of liver and gill tissue were processed together as a single extraction for each sample. The combined tissues were placed in 600 ll of lysis buffer containing 0.5 per cent foaming reagent (Reagent DX, Qiagen) and 1 per cent of b-mercaptoethanol (Sigma-Aldrich). Submerged tissue samples were homogenized with TissueRuptor (Qiagen) for one minute at 5,000 rpm. To further homogenize tissue samples and remove tissue residues, the homogenate was centrifuged at full speed for three minutes. The homogenate was carefully removed and RNA from the clear supernatant was extracted using the RNeasy Plus Mini Kit (Qiagen, Hilden, Germany) following the manufacturer's protocol. Extracted RNA was quantified using NanoDrop (ThermoFisher) and RNA from each species was pooled corresponding to the site in which they were captured, resulting in thirty-six sample libraries (Supplementary Table S2 ). RNA libraries were constructed using the Truseq Total RNA Library Preparation Protocol (Illumina). To enhance viral discovery and reduce the presence of non-viral reads, host ribosomal RNA (rRNA) was depleted using the Ribo-Zero-Gold Kit (Illumina) and paired-end sequencing (150 bp) was performed on the NovaSeq 500 platform (Illlumina). Sample library construction, rRNA depletion and RNA sequencing were performed at the Australian Genome Research Facility. Raw Illumina sequence reads (forward and reverse) were initially quality trimmed with Trimmomatic v.0.39 (Bolger, Lohse, and Usadel 2014) then assembled into contigs de novo using Trinity RNA-seq v.2.8.5 (Haas et al. 2013) , with the default parameter settings. Assembled contigs were annotated and compared against the NCBI nucleotide (nt) and non-redundant protein (nr) databases with an e-value threshold of 1  10 À5 using BLASTn and Diamond (BLASTX) (Buchfink, Xie, and Huson 2014) . To initially distinguish between invertebrate and vertebrate-associated viruses, contigs that matched viral sequences were inspected using Geneious v.11.1.5 (Kearse et al. 2012 ) and translated into amino acid sequences. Amino acid sequences were then used as a single query in additional sequence comparisons against the NCBI nt and nr databases using BLAST algorithms. This method was also used to remove false-positives (e.g. host genes and endogenous viral elements) from our analyses. To help exclude instances of index hopping, viral sequences that were identified in multiple libraries were also inspected using Geneious Prime (www.geneious.com) and amino acid pairwise alignments between viral sequences were performed with Multiple Alignment using Fast Fourier Transform (MAFFT) v.7.450 (Katoh and Standley 2013) , using the E-INS-i algorithm. Abundances of identical viral transcripts were then calculated (see below) and sequences that were present at frequency of less than one per cent of that of the number of reads present in the dominant library were excluded. To determine whether a virus was novel, we followed the broad criteria specified by The International Committee on Taxonomy of Viruses (http://www.ictvonline.org/). To determine the evolutionary history of the viruses identified in this study and further distinguish between vertebrate and invertebrate-associated viruses (which are usually phylogenetically distinct), we estimated phylogenetic trees using amino acid sequences of stable genomic regions such as RNA-dependent RNA polymerase (RdRp) or DNA polymerase for DNA viruses. To this end, we combined our sequences with background sequences for each respective virus family taken from NCBI/GenBank. Amino acid sequences were aligned with MAFFT v.7.450 using the E-INS-i algorithm. To remove ambiguous regions in the sequence alignment, amino acid sequences were trimmed using trimAl v.1.2 (Capella-Gutié rrez, Silla-Martínez, and Gabaldó n 2009). To estimate phylogenetic trees, selection of the best-fit model of amino acid substitution was determined using the Akaike information criterion (AIC), corrected AIC, and the Bayesian information criterion with the ModelFinder function (-m MFP) in IQ-TREE (Nguyen et al. 2015; Kalyaanamoorthy et al. 2017) . Sequence data were analysed using a maximum likelihood (ML) approach in IQ-TREE, with 1,000 bootstrap replicates. Phylogenetic trees were annotated with FigTree v.1.4.2. and further edited using Adobe Illustrator (https://www.adobe.com). To quantify the relative abundance of viral transcripts within the host transcriptome, the RNA-Seq by Expectation (RSEM) value was estimated using Trinity (Haas et al. 2013) , and raw counts from each transcript were standardized against the total number of reads within the given sequencing library. We also used this approach to estimate the relative abundance of a host reference gene, ribosomal protein S13 (RPS13), which is stably expressed in fish. To assess any differences in virome composition between hosts and sites, we calculated alpha diversity (virome richness and Shannon diversity) using Rhea packages (Lagkouvardos et al. 2017) . Generalized linear models (GLM) were used to identify the impact of host taxonomy (i.e. species), host geography (i.e. site), water temperature, water pH, water turbidity and species origin (i.e. invasive or native) on both vertebrate-associated virus composition (abundance, richness and diversity) and those viruses likely associated with non-fish hosts: the latter should not be affected by aspects of fish biology and hence effectively constitute a negative control. All GLM models were tested using a likelihood-ratio test (v 2 ) and a Tukey's post hoc analysis (glht) was performed using the multcomp package (Hothorn, Bretz, and Westfall 2008) . To assess viral diversity between samples, we calculated beta diversity using a Bray Curtis dissimilarity with the phyloseq package (McMurdle and Holmes 2013). Differences in virome composition between native and invasive species were calculated using permanova (Adonis test), with the vegan package (Dixon 2003) . All statistical analyses were carried out on RStudio V1.2.1335 and plotted using the ggplot2 package (Valero-Mora 2015). We characterized the viromes of ten freshwater ray-finned fish species across seven taxonomic orders (two invasive and five native) at thirteen locations across the Murray-Darling Basin in Australia. Total RNA-sequencing was performed on thirty-six libraries, resulting in a median of 76,528,534 (range 66,015,138-95,168 ,951) reads per library. De novo assembly of the sequencing reads resulted in a median of 617,588 contigs (range 198,446-1,989,596) per library, with a total of 23,976,218 contigs generated. Analysis of the host reference gene, RPS13, revealed abundances of 0.000001-0.0002 per cent, suggesting an inconsistent sequence coverage across all RNA libraries, which may have impacted virus discovery (Fig. 2 ). We identified eighteen viral sequences that were associated with vertebrate hosts and a further twenty-seven that were likely associated with algae, invertebrates and protists in the freshwater environment (Supplementary Figs. S1 and S2). Because such non-vertebrate viruses were likely derived from diet or contamination of gill tissue, we primarily focused on vertebrate-associated viruses. Among the likely vertebrate-associated viruses, we identified viral sequences from fourteen viral families. With the exception of a novel poxvirus (family Poxviridae), a doublestranded DNA virus, all the viruses identified possessed RNA genomes. The most abundant vertebrate-associated viral transcripts were those assigned to the Arenaviridae (49% of all vertebrate-associated viruses), Hepeviridae (20%), Chuviridae (21%), Astroviridae (3%) and Flaviviridae (2%) families. Other likely vertebrate viral transcripts detected were assigned to the Coronaviridae (<1%) Caliciviridae (<1%), Picornaviridae (<1%), Paramyxoviridae (<1%), Hantaviridae (<1%), Bornaviridae (<1%), Poxviridae (<1%), Reoviridae (<1%) and Rhabdoviridae (<1%) families. The most common vertebrate-associated viruses identified were astroviruses, detected in three host species (eastern mosquitofish, Murray-Darling rainbowfish, spangled perch). In addition, arenaviruses were detected in two host species (western carp-gudgeon, eastern mosquitofish) along with hepeviruses (common carp, eastern mosquitofish). All other viruses were identified in one host species (Fig. 3) . Among the viruses likely associated with non-vertebrate hosts (i.e. those infecting arthropods, fungi, plants and protozoans), a large proportion (70%) were unclassified, comprising picorna-like viruses, rhabdo-like viruses, tombus-like viruses and narna-like viruses (Shi et al. 2016) (Supplementary Fig. S1 ). We also detected viral transcripts that could be assigned to the Nodaviridae (27.1%), Permutotetraviridae (1.3%), Dicistroviridae (1.2%) and Phenuiviridae (<1%) families. Although viruses within the Nodaviridae have been shown to infect fish (Hameed et al. 2019), all of the nodavirus sequences identified here clustered with viruses from invertebrate hosts ( Supplementary Fig. S2 ), strongly suggesting they were similarly associated with fish diet or contamination of gill tissue. To infer the phylogenetic relationships and hence the evolutionary history of the viruses newly identified here, we focused on stable genomic regions such as the RdRp in RNA viruses and DNA polymerase in the case of the novel poxvirus. Using these genomic regions, we identified seven negative-sense single-stranded RNA (-ssRNA) viruses (families Arenaviridae, Bornaviridae, Chuviridae, Hantaviridae, Paramyxoviridae, Rhabdoviridae), nine positive-sense single-stranded RNA (þssRNA) viruses (families Astroviridae, Caliciviridae, Coronaviridae, Flaviviridae, Hepeviridae, Picornaviridae), one double-stranded RNA (dsRNA) virus (family Reoviridae) and one double-stranded DNA (dsDNA) virus (family Poxviridae). We now describe each of these groups in turn. We identified -ssRNA viruses that occupied phylogenetic positions that were broadly indicative of long-term virus-host co-divergence, with many fish viruses falling basal to reptile, avian and mammalian viruses (Fig. 4) . Notably, we identified two novel arenaviruses that clustered with members of the newly formed Antennavirus genus that includes fish hosts Abudurexiti et al. 2019) . Western carp-gudgeon arenavirus found at Narrabri creek shared 36.9 per cent amino acid sequence similarity with its closest relative, Wenling frogfish arenavirus 1 ) and grouped with recently discovered arenaviruses from pygmy gobies (Eviota zebrina) sampled from an Australian coral reef (Geoghegan et al. 2021) . Eastern mosquitofish arenavirus found in the Macquarie River shared 84.5 per cent amino acid sequence similarity with its closest available relative, Wenling frogfish arenavirus 1. The divergent hantavirus detected in the Murray-Darling rainbowfish falls basal to mammalian hantaviruses (orthohantaviruses) and clustered with members of the Actantavirinae and Agantavirinae subfamilies that include ray-finned and jawless fish hosts Abudurexiti et al. 2019) (Fig. 4) . This virus had only 27.3 per cent amino acid similarity with its closest relative, Bern perch virus (NCBI/GenBank: QGM12349.1). Broad patterns of virus-host co-divergence can similarly be seen in the cultervirus identified in carp from Lake Burrendong. BLAST analysis identified sharpbelly cultervirus ) as the closest relative of all genomic regions, including the L gene (93% amino acid similarity), glycoprotein (86.3%) and nucleoprotein (92.9%). Our virological survey revealed the complete genome of a novel chuvirus in the unspecked hardyhead in the Edward River. This Hardyhead chuvirus displayed three open reading frames, representing the L protein (RdRp), glycoprotein and nucleoprotein. Our analysis identified Guangdong red-banded snake chuvirus ) as the closest relative of the L protein (44% amino acid similarity), Wenling fish chu-like virus We also detected a novel paramyxovirus in western carpgudgeon in the Bogan River. This divergent viral sequence shared 35.2 per cent L gene amino acid similarity with its closest relative, Wenling tonguesole paramyxovirus (genus Cynoglossusvirus, family Paramyxoviridae) . These viruses grouped with Wenzhou pacific spadenose shark paramyxovirus (genus Scoliodonvirus), together falling basal to other members of the Paramyxoviridae family. In addition, a novel rhabdovirus in common carp similarly formed a distinct clade, basal to other fish-infecting rhabdoviruses. This virus shared 35.7 per cent amino acid L gene sequence similarity with Beihai dimarhabdovirus that was also identified in fish and clustered with other dimarhabdoviruses, including those found in the spotted paddle-tail newt from China ) and the big brown bat (Eptesicus fuscus) from the USA (NCBI/Genbank: QPO14166.1). Across all genera within the Rhabdoviridae, lyssaviruses were the closest relatives to this clade (Fig. 4) , with Murray-Darling carp rhabdovirus sharing 31.6 per cent amino acid L gene similarity with rabies lyssavirus (Tordo et al. 1988 ). We identified a viral sequence in common carp that shared 50.7 per cent RdRp sequence similarity with Pacific salmon nidovirus (family Coronaviridae) (Mordecai et al. 2019). Murray-Darling carp letovirus also exhibited sequence similarity (46.2%) with gammacoronaviruses, including bottlenose dolphin coronavirus and beluga whale coronavirus (Mihindukulasuriya et al. 2008; Woo et al. 2014) . This virus grouped with both Pacific salmon nidovirus and Microhyla letovirus (Bukhari et al. 2018) , which together form an outgroup to all other coronaviruses (Fig. 6) . We also identified a novel flavivirus (genus Flavivirus, family Flaviviridae) in western carp-gudgeon in the Bogan River. This viral sequence exhibited thirty-three to thirty-six per cent NS5 amino acid sequence similarity with its closest relatives, Cyclopterus lumpus virus (Skoge et al. 2018) , Tamana bat virus (de Lamballerie et al. 2002) , salmon flavivirus (Soto et al. 2020) and Wenzhou shark flavivirus . All these viruses fall basal to vector-borne viruses within the genus Flavivirus (Fig. 7) . Among other positive-sense RNA viruses identified, a novel astrovirus, calicivirus and picornavirus all grouped with other fish hosts and expanded the phylogenetic diversity of these virus families (Fig. 7) . The novel astrovirus identified in Murray-Darling rainbowfish shared forty per cent RdRp amino acid similarity with Wuhan astro-like virus . This virus clustered with other astro-like viruses discovered in fish, including Beihai mudskipper astro-like virus and Guangdong catfish astro-like virus ). This was similarly observed in Australian smelt picornavirus, which clustered with picornaviruses found in other freshwater fish, including those from eels (Anguilla anguilla) (Fichtner et al. 2013 ) and carp sampled from China salmonid hosts and minoviruses associated with cyprinid hosts (Vinjé et al. 2019) . Recently, several caliciviruses have been discovered in ray-finned and jawless fish (Mikalsen et al. 2014; Shi et al. 2018) . The novel calicivirus identified in bony herring expands the diversity of fish viruses as it shared eighty per cent amino acid similarity with Atlantic salmon calicivirus (Mikalsen et al. 2014 ) and clustered with other freshwater fish caliciviruses, including Wuhan carp calicivirus and Guangdong pseudohemiculter dispar calicivirus . We identified a novel dsRNA virus in carp in the Castlereagh River that could be assigned to the Reoviridae. This divergent virus shared forty per cent RdRp amino acid similarity with its closest relative, Wenling scaldfish reovirus , together forming a clade basal to the genus Aquareovirus that are known to cause considerable disease in some fish species (Chen et al. 2018) (Fig. 8) . A key observation of our study was the absence of Cyprinid herpesviruses, including CyHV-3, as well as other Alloherpesviridae, in any of the thirty-six RNA libraries. Similarly, although members of the Hepadnaviridae are commonly detected in fish (Dill et al. 2016; Lauber et al. 2017; Geoghegan et al. 2018; Geoghegan et al. 2021 ) they were notably absent in our samples. The only DNA virus detected in this study was a novel poxvirus (Poxviridae) identified in western carp-gudgeon. This virus shared DNA polymerase amino acid sequence similarity with salmon gill poxvirus (SGPV) (61%) (Gjessing et al. 2015) . We also detected other genomic regions such as DNA-dependent RNA polymerase subunit rpo22 (49.5%), DNA-dependent RNA polymerase subunit rpo19 (40%), DNA binding virion core protein I1L (28.1%), A16L (32.9%) and SGPV079 (40%) (Supplementary Table S1 ). Both SGPV and western carp-gudgeon poxvirus form a highly divergent clade within the subfamily Chordopoxvirinae that is strongly indicative of virus-host co-divergence (Fig. 9 ). We next examined whether and how vertebrate virome composition in a range of native and introduced Murray-Darling Basin fish was associated host ecological factors, namely host species, geography (i.e. sampling site), water quality (temperature, pH and turbidity). GLMs revealed host species (v 2 ¼ 7.5 À6 , df ¼ 9, P ¼ 0.001) as the best predictor of viral abundance (i.e. the standardized number of viral sequencing reads) (Fig. 2) . In particular, the eastern mosquitofish had significantly higher viral abundance compared to Australian smelt (Tukey: z ¼ 3.976, P ¼ 0.002), bony herring (Tukey: z ¼ 4.334, P ¼ 0.001), western carp-gudgeon (Tukey: z ¼ 4.019, P ¼ 0.002), common carp (Tukey: z ¼ 4.665, P ¼ 0.001), flat-headed gudgeon (Tukey: z ¼ 3.632, P ¼ 0.001), goldfish (Tukey: z ¼ 3.632, P ¼ 0.001) and rainbowfish (Tukey: z ¼ 4.110, P ¼ 0.001). However, the high viral abundance in the eastern mosquitofish was driven by one sample containing an extremely high abundance of arenaviruses, accounting for seventy-six per cent of its total vertebrate virome and forty-nine per cent of all vertebrate-associated viral reads. We found no evidence for an association between viral abundance and host geography (P ¼ 0.111), water turbidity (P ¼ 0.804), water temperature (P ¼ 0.709) nor water pH (P ¼ 0.141). We calculated alpha diversity to assess any differences in virome composition (abundance and diversity) between hosts and sites. This included the observed virus species richness (the number of viruses found in each sequencing library) and Shannon diversity (both the number of viral families and abundance of viral reads in a given host). We found no association between observed viral species richness and host species (P ¼ 0.286), host geography (P ¼ 0.748), water turbidity (P ¼ 0.826), water temperature (P ¼ 0.625) and water pH (P ¼ 0.115). Similarly, there was also no observed association between Shannon diversity and host taxonomy (P ¼ 0.117), host geography (P ¼ 0.551), water turbidity (P ¼ 0.546), water temperature (P ¼ 0.206) and water pH (P ¼ 0.039). While carp and native fish species were sampled together at ten out of thirteen sites (Fig. 1) , they shared no vertebrate-associated viruses. Similarly, no vertebrate-associated viruses were shared among any of the native fish species. Although we identified hepeviruses in common carp and eastern mosquitofish, these were highly divergent and exhibited only twenty per cent amino acid similarity such that they reflect ancient divergence events. These viruses were also distinct in that Murray-Darling carp hepevirus clustered with ray-finned fish hosts eastern mosquitofish) and bastroviruses (spangled perch and eastern mosquitofish) (Fig. 3) . However, the arenaviruses identified in the eastern mosquitofish and western carp-gudgeon were highly divergent, exhibiting only 27.9 per cent amino acid similarity, with western carp-gudgeon arenavirus falling basal to eastern mosquitofish arenavirus (Fig. 4) . The bastroviruses detected in eastern mosquitofish and spangled perch shared 57.1 per cent RdRp amino acid similarity and formed a distinct clade with other bastrovirus sequences identified in Culex mosquitos (Sadeghi et al. 2018) , bats (NCBI/GenBank: NC_035471.1) and sewage samples in Brazil (Dos Anjos, Nagata, and Melo 2017) (Supplementary Fig. S3 ). Because bastroviruses have genomic features that resemble hepeviruses (Reuter et al. 2018) , both these contigs had matches to invertebrate and vertebrate-associated hepeviruses such that their true hosts could not be easily determined. We also examined whether there were any differences in alpha and beta diversity between native and invasive Figure 6 . Phylogenetic relationships within the virus order Nidovirales. The novel letovirus detected in common carp is labelled with a black circle. The phylogenetic tree was estimated using the orf1ab polypeptide (polymerase associated) and midpoint rooted for clarity alone. Scale bar represents amino acid substitutions per site. Bootstrap values are shown as a percentage. Taxon labels are highlighted: blue, fish; red, mammals; green, birds and reptiles; yellow, amphibians. Virus taxonomic names are labelled to the right. Tip labels represent virus name and NCBI/GenBank IDs. freshwater fish. Accordingly, we found no association between host origin (i.e. invasive or native) and virome abundance (P ¼ 0.390). When assessing alpha diversity, we similarly found no association between host origin and virome richness (P ¼ 0.626) nor Shannon diversity (P ¼ 0.425). Likewise, this result was also observed when examining beta diversity (P ¼ 0.602). To assess any associations between host ecology and non-vertebrate viruses, we similarly performed GLMs using the aforementioned ecological factors as a negative control. As expected, this revealed no association between non-vertebrate viral abundance and host taxonomy (P ¼ 0.200), host geography (P ¼ 0.101), host origin (P ¼ 0.998), water turbidity (P ¼ 0.421), water temperature (0.282) and water pH (P ¼ 0.343). We similarly found no association between non-vertebrate virome richness and host taxonomy (P ¼ 0.204), host geography (P ¼ 0.090), host origin (P ¼ 0.675), water turbidity (P ¼ 0.398), water temperature (P ¼ 0.072) and water pH (P ¼ 0.461). We also found no evidence for an association between Shannon diversity and host taxonomy (P ¼ 0.691), host geography (P ¼ 0.173), host origin (P ¼ 0.876), water turbidity (P ¼ 0.571), water temperature (P ¼ 0.334) and water pH (P ¼ 0.578). This was also observed when assessing statistical associations between beta diversity and host species (P ¼ 0.684), host origin (P ¼ 0.239) and host geography (P ¼ 0.501). Our meta-transcriptomic viral survey of native and invasive fish across the Murray-Darling Basin, Australia, revealed a high diversity and abundance of viruses, including the identification of 45 novel virus species that infected seemingly healthy fish or non-vertebrate hosts in the freshwater environment. Crucially, however, we observed no clear examples of recent cross-species transmission among any fish hosts, including between invasive and native species, nor any evidence for the presence of CyHV-3 from a total of thirty-six RNA sequencing libraries. Hence, these data provide further evidence of the absence of CyHV-3 in Australia (McColl and Crane 2013; McColl, Cooke, and Sunarto 2014; McColl et al. 2017) . Similarly, our analysis failed to detect other cypriniviruses (i.e. CyHV-1, CyHV-2), despite previous reports of the presence of CyHV-2 in the Murray-Darling Basin (Stephens, Raidal, and Jones 2004; Becker et al. 2014) . While we observed no cypriniviruses in our analysis, such viruses typically induce latent infections in fish hosts and may become transcriptionally inactive (Michel et al. 2010 ). Thus, cypriniviruses in a latent stage may be difficult to detect using the transcriptome-based methods described here. Despite this, a viral survey of CyHV-1, CyHV-2 and CyHV-3 was previously conducted on carp across eight sites in the Murray-Darling Basin (McColl and Crane 2013). Using PCR amplicon sequencing, this study similarly failed to identify all three cypriniviruses in 849 carp DNA samples. This suggests that our findings may reflect a true absence of CyHV-3 in Australian waterways, although additional surveillance studies will be required to further address this issue. Although carp and native fish have co-existed in the Murray-Darling Basin for over 50 years (Forsyth et al. 2013) , they shared no vertebrate-associated viruses. The only instance of co-occurrence of viruses from the same family in both invasive and native species was the presence of arenaviruses in native carp-gudgeon and invasive mosquitofish. However, these viruses were so divergent that they likely represent ancient common ancestry rather than recent cross-species transmission (Fig. 4) . Eastern mosquitofish, introduced into Australia during the early 1920s to control mosquito populations (Ayres, Pettigrove, and Hoffman 2010) , are now widespread across the Murray-Darling Basin and have become a successful invasive species (Macdonald et al. 2012) . Their abundance primarily impacts smaller native fish (such as carp-gudgeon, rainbowfish and hardyheads) since they typically outcompete these species and disrupt food webs (Macdonald et al. 2012) . As well as being highly divergent, western carp-gudgeon arenavirus formed a basal clade with a recently discovered arenavirus in the pygmy goby sampled from an Australian coral reef (Geoghegan et al. 2021 ), a member of the same fish order (Gobiiformes). These data further suggest that arenaviruses may have been circulating in Gobiiform fishes (gobies and gudgeons) in Australia prior to the introduction of eastern mosquitofish. We also identified a novel coronavirus-Murray-Darling carp letovirus-that shared 50.7 per cent amino acid sequence similarity with Pacific salmon nidovirus and 46.2 per cent amino acid similarity with gammacoronaviruses. The Coronaviridae (order Nidovirales) can be split into two subfamilies: the Orthocoronavirinae, associated with birds and mammals, and the Letovirinae associated with amphibians (Bukhari et al. 2018 ). Both Murray-Darling carp letovirus and Pacific salmon nidovirus formed a sister clade to only member of the Letovirinae subfamily, Microhyla letovirus (genus Alphaletovirus) identified in the ornamental pygmy frog (Microhyla fissipes) (Fig. 6) , suggests that fish may be common and ancient hosts for the Letovirinae. It is also notable that Murray-Darling carp letovirus and Pacific salmon nidovirus are highly divergent from the other Nidovirales that are known to infect fish (e.g. Chinook salmon bafinivirus) (Cano et al. 2020) . The phylogenetic range of the Chuviridae largely incorporates invertebrate hosts with diverse genomes (segmented, unsegmented and circular) (Jun-Hua et al. 2015) . Recently, chuviruses have been discovered in vertebrates, all possessing three segments Argenta et al. 2020) . The novel chuvirus detected here in the unspecked hardyhead displayed these genomic features with the L gene (RdRp), S gene (glycoprotein) and N gene (nucleoprotein) all related to fish and reptile viruses (Fig. 5) . The phylogenetic position of this vertebrate clade suggests the ancestors of the viruses may be of invertebrate origin, particularly those that inhabit aquatic ecosystems. For instance, the closest related invertebrate viruses were Wenzhou crab virus (Jun-Hua et al. 2015) , Imjin River virus (mosquitos) (Hang et al. 2016) and Atrato chu-like virus (mosquitos). Similarly, chuvirus endogenous viral elements have been detected in several freshwater fish species . We identified a novel flavivirus in western carp-gudgeon from the Bogan River. This virus falls basal to mammalian vector-borne viruses in phylogenetic trees, grouping with viruses from other vertebrate hosts including Cyclopterus lumpus virus, Tamana bat virus and Wenzhou shark flavivirus. Although western carp-gudgeon flavivirus was detected in apparently healthy fish, in vivo flavivirus replication was recently demonstrated in Chinook salmon (Oncorhynchus tshawytscha) that were associated with abnormal mortalities in the Eel River, California (Soto et al. 2020) . While there is still no clear link between flavivirus infection, transmission and disease in aquatic hosts, these data suggest that flaviviruses may be common in fish species. Moreover, the basal phylogenetic positions of aquatic flaviviruses also suggest that these viruses may be the ancestors of notable vector-borne viruses (Fig. 7) . Nevertheless, gaps still remain in the evolutionary history of the genus Flavivirus and will likely be bridged with additional metagenomic studies. In broad terms, the evolutionary histories of many vertebrate viral families appear to generally follow patterns of longterm virus-host co-divergence, albeit with regular cross-species transmission Zhang et al. 2018 ). This evolutionary pattern can be observed in the phylogenies of the cultervirus, poxvirus and arenaviruses identified here. The Bornaviridae contain three genera with eleven currently classified viral species that infect mammals, birds and reptiles (Amarasinghe et al. 2019 ). The only fish virus identified to date falls within the genus Cultervirus, comprising Sharpbelly cultervirus from China . We identified this virus (i.e. transcripts with 93% L gene amino acid similarity) in common carp in Australia. Intriguingly, both fish hosts are members of the Cyprinidae that date as far back as the Cretaceous to Jurassic periods (Hughes et al. 2018; Betancur et al. 2017) . Molecular clock dating using endogenous viral elements also showed that culterviruses likely emerged early on during the course of vertebrate evolution, more than fifty million years ago . Patterns of long-term virus-host co-divergence can also be seen in the evolutionary history of the Chordopoxvirinae. Western carp-gudgeon poxvirus expands the host range of the Chordopoxvirinae subfamily within the Poxviridae, forming a highly divergent clade with the only other fish-infecting chordopoxvirus discovered to date, SGPV (Fig. 9 ). Since its classification in 2015, several cases of SGPV have been identified in farmed salmon with complex gill disease, although the reservoir host is unknown (Gjessing et al. 2017) . The phylogeny of the Chordopoxvirinae mirrors that of vertebrate hosts, strongly suggesting long-term virus-host co-divergence (Fig. 9) . Similarly, the phylogeny of the Arenaviridae displays a basal fish clade that is characterized by long branches with a large degree of divergence (Fig. 4) . On this evolutionary backbone of ancient virus-host co-divergence, we also detected cases of cross-species virus transmission during evolutionary history, although the time-scales of these events are uncertain. For example, we discovered a novel reovirus that formed a basal divergent clade to other fish viruses within the genus Aquareovirus (Fig. 8) . Murray-Darling carp reovirus was more closely related to viruses that infect scaldfish ) rather than other cyprinid hosts, which are highly susceptible to reovirus infection (e.g. 80% mortality in grass carp) (Chen et al. 2018) . These patterns were also observed in the phylogeny of the Rhabdoviridae, with Murray-Darling carp rhabdovirus forming a distinct phylogenetic clade with other recently discovered rhabdoviruses in fish, the big brown bat (NCBI/Genbank: QPO14166.1) and the spotted paddle-tail newt ). Rhabdoviruses exhibit a very broad host range including invertebrates, plants, mammals, fish, amphibians, birds and reptiles (Bourhy et al. 2005) . Notable among the Rhabdoviridae are the lyssaviruses that can cause high mortality in human populations (e.g. rabies lyssavirus). Intriguingly, Murray-Darling carp rhabdovirus and its closest relatives form a sister clade to the genus Lyssavirus, suggesting these viruses may have a fish-infecting ancestor (Fig. 4) . Although carp are widespread and abundant across the Murray-Darling Basin, they displayed lower viral abundance than some of the other hosts sampled (Fig. 2) . This could be partly explained by the large phylogenetic distance between carp and other fish in the Murray-Darling Basin. For instance, aside from bony herring, all the fish studied here are members of the Acanthopterygii (Percomorpha). This could also explain why invasive mosquitofish harboured similar viruses to native gudgeon species (e.g. arenaviruses). Although not always the case (Parrish et al. 2008) , cross-species virus transmission often occurs between phylogenetically related hosts, particularly those that display conserved cell receptors (Longdon et al. 2014; Dennehy 2017 ). In addition, it has been widely suggested that introduced populations are associated with a lower pathogen prevalence and diversity than native species (Phillips et al. 2010; Mark et al. 2003) . For example, because invasive species are often established from a small founder population, they likely carry and acquire only a small proportion of pathogens in the novel environment. Once a species rapidly becomes invasive, the diversity of pathogens in this population should remain small, such that the lack of disease likely facilitates the success of invasive species (Mark et al. 2003; Phillips et al. 2010) . It is important to note, however, that there were necessary variations within our sampling. For instance, carp and native fish species were sampled together at ten out of thirteen sites, with carp sampled from all thirteen sites (Fig. 1) . In addition, all other fish species were sampled from one to five sites. While an artefact of the distribution of the fish, such gaps obviously limit the power of our statistical analyses and perhaps prevent the detection of ecological associations on virome composition within host species, including between invasive and native fish. In addition, due to animal ethics constraints, we were limited to only a subset of native fish species. Nevertheless, the native species examined in this study are generally those present in the highest densities. Finally, our analysis detected no viruses that are listed as reportable notifiable aquatic diseases in the Murray-Darling Basin (Australian Health Committee 2020). Such notifiable aquatic diseases include epizootic haematopoietic necrosis virus (EHNV-Iridoviridae) and spring viraemia of carp virus (SVCV-Rhabdoviridae). EHNV is known to cause high-impact infections in redfin perch and is capable of infecting other freshwater fish in the Murray-Darling Basin, including silver perch (Bidyanus bidyanus), Macquarie perch (Macquaria australasica), Murray-Darling rainbowfish, freshwater catfish (Tandanus tandanus) and invasive mosquitofish (Becker et al. 2013) . Although thought to be endemic to the Murray-Darling Basin (upper Murrumbidgee River), EHNV was last reported in 2012 (Becker et al. 2019) . Similarly, we did not detect the emerging dwarf gourami iridovirus (Iridoviridae) that causes infectious spleen and kidney necrosis in several species of native Australian fish (Go et al. 2006; Rimmer et al. 2017) . In sum, our metagenomic surveillance revealed a marked lack of virus exchange between native and invasive fish species in the Murray-Darling Basin, including those viruses found in invasive common carp. 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