Identification and characterization of recent retrovirus in Rhinolophus ferrumequinum bats.

An investigation into retrovirus was conducted in six species of bats (Myotis aurascens, Myotis petax, Myotis macrodactylus, Miniopterus fuliginosus, Rhinolophus ferrumequinum, and Pipistrellus abramus) inhabiting South Korea. Exogenous retroviruses (XRVs) were detected in the tissue samples of R. ferrumequinum individuals by PCR assay. Proviruses were identified in all tissue samples through viral quantification using a digital PCR assay per organ (lung, intestine, heart, brain, wing, kidney, and liver), with viral loads varying greatly between each organ. In phylogenetic analysis based on the whole genome, the Korean bat retroviruses and the R. ferrumequinum retrovirus (RfRV) strain formed a new clade distinct from the Gammaretrovirus clade. The phylogenetic results determined these viruses to be RfRV-like viruses. In the Simplot comparison, Korean RfRV-like viruses exhibited relatively strong fluctuated patterns in the latter part of the envelope gene area compared to other gene areas. Several point mutations within this region (6,878-7,774 bp) of these viruses were observed compared to the RfRV sequence. One Korean RfRV-like virus (named Y4b strain) was successfully recovered in the Raw 264.7 cell line, and virus particles replicated in the cells were confirmed by transmission electron microscopy. RfRVs (or RfRV-like viruses) have been spreading since their first discovery in 2012, and the Korean RfRV-like viruses were assumed to be XRVs that evolved from RfRV.IMPORTANCER. ferrumequinum retrovirus (RfRV)-like viruses were identified in greater horseshoe bats in South Korea. These RfRV-like viruses were considered exogenous retroviruses (XRVs) that emerged from RfRV. Varying amounts of provirus detected in different organs suggest ongoing viral activity, replication, and de novo integration in certain organs. Additionally, the successful recovery of the virus in the Raw 264.7 cell line provides strong evidence supporting their status as XRVs. These viruses have now been identified in South Korea and, more recently, in Kenya since RfRV was discovered in China in 2012, indicating that RfRVs (or RfRV-like viruses) have spread worldwide.

Genetic characterization and pathogenicity in a mouse model of newly isolated bat-originated mammalian orthoreovirus in South Korea.

Mammalian orthoreoviruses (MRVs) infect a wide range of hosts, including humans, livestock, and wildlife. In the present study, we isolated a novel Mammalian orthoreovirus from the intestine of a microbat (Myotis aurascens) and investigated its biological and pathological characteristics. Phylogenetic analysis indicated that the new isolate was serotype 2, sharing the segments with those from different hosts. Our results showed that it can infect a wide range of cell lines from different mammalian species, including human, swine, and non-human primate cell lines. Additionally, media containing trypsin, yeast extract, and tryptose phosphate broth promoted virus propagation in primate cell lines and most human cell lines, but not in A549 and porcine cell lines. Mice infected with this strain via the intranasal route, but not via the oral route, exhibited weight loss and respiratory distress. The virus is distributed in a broad range of organs and causes lung damage. In vitro and in vivo experiments also suggested that the new virus could be a neurotropic infectious strain that can infect a neuroblastoma cell line and replicate in the brains of infected mice. Additionally, it caused a delayed immune response, as indicated by the high expression levels of cytokines and chemokines only at 14 days post-infection (dpi). These data provide an important understanding of the genetics and pathogenicity of mammalian orthoreoviruses in bats at risk of spillover infections.IMPORTANCEMammalian orthoreoviruses (MRVs) have a broad range of hosts and can cause serious respiratory and gastroenteritis diseases in humans and livestock. Some strains infect the central nervous system, causing severe encephalitis. In this study, we identified BatMRV2/SNU1/Korea/2021, a reassortment of MRV serotype 2, isolated from bats with broad tissue tropism, including the neurological system. In addition, it has been shown to cause respiratory syndrome in mouse models. The given data will provide more evidence of the risk of mammalian orthoreovirus transmission from wildlife to various animal species and the sources of spillover infections.

First Isolation of Pseudogymnoascus destructans, the Fungal Causative Agent of White-Nose Syndrome, in Korean Bats (Myotis petax)

White-nose syndrome (WNS), caused by Pseudogymnoascus destructans (Pd), is a lethal fungal disease that affects hibernating bats in North America. Recently, the presence of Pd was reported in countries neighboring Korea. However, Pd has not been investigated in Korea. Therefore, this study aimed to identify the presence of Pd in Korean bats. Altogether, wings from 241 bats were collected from 13 cities and cultured. A total of 79 fungal colonies were isolated, and two isolates were identified as Pd using polymerase chain reaction. Of the nine bat species captured in 13 cities, Pd was isolated only from Myotis petax in Goryeong. Atypical, curved conidia were observed in two isolated fungal colonies. Although histological lesions were not observed by hematoxylin and eosin or periodic acid−Schiff staining, fungal invasion was observed in the tissue sections. Taken together, these results confirmed the presence of Pd in Korean bats and suggest the possibility of WNS outbreaks in Korean bats. This is the first report of the isolation and molecular analysis of Pd from Korean bats.

Genetic diversity of bat coronaviruses and comparative genetic analysis of MERS-related coronaviruses in South Korea.

Bats have been identified as a natural reservoir of several potentially zoonotic viruses, including Lyssavirus, Ebola virus, Marburg virus, Hendra virus, Nipah virus, as well as severe acute respiratory syndrome and Middle East respiratory syndrome coronavirus (CoV). Here, we performed a molecular epidemiological investigation of South Korean bat viruses. Genetic comparative analysis was performed on the spike glycoprotein gene of the detected MERS-related CoVs. Among 1640 samples (348 oral swabs, 1199 faecal samples, 83 urine samples and 10 bat carcass) collected across 24 South Korean provinces during 2017-2019, CoV was detected in 82 samples (75 faeces and seven oral swab samples) from 11 provinces. Surveillance over the 3 years during which samples were collected revealed significantly higher CoV detection rates between spring and autumn, and a high detection rate in Vespertillionidae and Rhinolophidae bats. Our phylogenetic analysis shows that Korean bat CoVs are genetically diverse regardless of their spatiotemporal distribution and their host species, and that the discovered bat CoVs belong to various subgenera within the Alpha- and Betacoronavirus genera. Twenty detected MERS-related CoVs belonging to the genus Betacoronavirus were similar to the Ia io bat CoV NL140422 and NL13845 strains. A comprehensive genetic analysis of two Korean bat MERS-related CoV spike receptor binding domain (RBDs) (176 and 267 strains) showed that the 18 critical residues that are involved in interactions with the human DPP4 receptor are most similar to the NL13845 strain, which is known to not bind with hDPP4. A deeper analysis of the interfacing residues in the Korean bat MERS-related CoVs RBD-hDPP4 complexes showed that the Korean bat CoVs has fewer polar contacts than the NL13845 strain. Although further study will be needed, these results suggest that Korean bat MERS-related CoVs are unlikely to bind with hDPP4. Nevertheless, these findings highlight the need for continuous monitoring to identifying the origin of new infectious diseases, specifically mutant CoV.

Genomic Characterization of a Novel Alphacoronavirus Isolated from Bats, Korea, 2020.

Coronavirus, an important zoonotic disease, raises concerns of future pandemics. The bat is considered a source of noticeable viruses resulting in human and livestock infections, especially the coronavirus. Therefore, surveillance and genetic analysis of coronaviruses in bats are essential in order to prevent the risk of future diseases. In this study, the genome of HCQD-2020, a novel alphacoronavirus detected in a bat (Eptesicus serotinus), was assembled and described using next-generation sequencing and bioinformatics analysis. The comparison of the whole-genome sequence and the conserved amino acid sequence of replicated proteins revealed that the new strain was distantly related with other known species in the Alphacoronavirus genus. Phylogenetic construction indicated that this strain formed a separated branch with other species, suggesting a new species of Alphacoronavirus. Additionally, in silico prediction also revealed the risk of cross-species infection of this strain, especially in the order Artiodactyla. In summary, this study provided the genetic characteristics of a possible new species belonging to Alphacoronavirus.

Novel viruses detected in bats in the Republic of Korea.

Bats are natural reservoirs for potential zoonotic viruses. In this study, next-generation sequencing was performed to obtain entire genome sequences of picornavirus from a picornavirus-positive bat feces sample (16BF77) and to explore novel viruses in a pooled bat sample (16BP) from samples collected in South Korea, 2016. Fourteen mammalian viral sequences were identified from 16BF77 and 29 from 16BP, and verified by RT-PCR. The most abundant virus in 16BF77 was picornavirus. Highly variable picornavirus sequences encoding 3Dpol were classified into genera Kobuvirus, Shanbavirus, and an unassigned group within the family Picornaviridae. Amino acid differences between these partial 3Dpol sequences were ≥ 65.7%. Results showed that one bat was co-infected by picornaviruses of more than two genera. Retrovirus, coronavirus, and rotavirus A sequences also were found in the BP sample. The retrovirus and coronavirus genomes were identified in nine and eight bats, respectively. Korean bat retroviruses and coronavirus demonstrated strong genetic relationships with a Chinese bat retrovirus (RfRV) and coronavirus (HKU5-1), respectively. A co-infection was identified in one bat with a retrovirus and a coronavirus. Our results indicate that Korean bats were multiply infected by several mammal viruses.

The complete mitochondrial genome of long-tailed whiskered bat, Myotis frater (Myotis, Vespertilionidae).

Here, we report the complete mitogenome of Myotis frater with the GenBank accession number MH177276 as a first step to elucidate genetic characteristics of this species. Its mitogenome was 17,089 bp long and consisted of 13 protein-coding genes (PCGs), two rRNA genes, 22 tRNA genes, and a control region. The gene order and composition of M. frater was similar to that of most other vertebrates. The base composition of the 13 PCG in descending order was A (33.8%), C (22.7%), T (30.4%), and G (13.1%), with an AT content of 64.2%. Four overlapping regions in ATP8/ATP6, ATP6/COX3, ND4L/ND4, and ND5/ND6, among the 13 PCGs were found. The 935 bp long control region is located between tRNA-Pro and tRNA-Phe with 4 ATTACATAATACATTATATGTATAATCGTACATTAAATTAACTCCCACATGAATATTAAGCATGTCCATACTAATATTAAT-repeat at 5' region and 45 ACGCAT-repeat at 3' terminus. Phylogenetic analysis suggested that M. frater is most closely related to M. bechsteinii (KX757757), it was supported by 100% bootstrap under both ML and NJ tree.

The complete mitochondrial genome sequence of the Korean hare (Lepus coreanus).

The complete mitogenome of the Korean hare (Lepus coreanus) was determined by the long and accurate polymerase chain reaction and primer-walking methods. The mitogenome of the Korean hare is 17,472 bp in length and contains sequences that encode 13 protein genes, 22 tRNAs, 2 rRNAs and a noncoding control region. The mitogenome is arranged in an identical order to that found in most other vertebrates. All mitochondrial genes are encoded on the heavy strand, except for eight tRNA genes and the ND6 gene. The control region contains putative termination associated elements, conserved sequence blocks and short and long tandem repeats motifs.