Short ‘1.2× Genome’ Infectious Clone Initiates Kolmiovirid Replication in Boa constrictor Cells

Human hepatitis D virus (HDV) depends on hepatitis B virus co-infection and its glycoproteins for infectious particle formation. HDV was the sole known deltavirus for decades and believed to be a human-only pathogen. However, since 2018, several groups reported finding HDV-like agents from various hosts but without co-infecting hepadnaviruses. In vitro systems enabling helper virus-independent replication are key for studying the newly discovered deltaviruses. Others and we have successfully used constructs containing multimers of the deltavirus genome for the replication of various deltaviruses via transfection in cell culture. Here, we report the establishment of deltavirus infectious clones with 1.2× genome inserts bearing two copies of the genomic and antigenomic ribozymes. We used Swiss snake colony virus 1 as the model to compare the ability of the previously reported “2× genome” and the “1.2× genome” infectious clones to initiate replication in cell culture. Using immunofluorescence, qRT-PCR, immuno- and northern blotting, we found the 2× and 1.2× genome clones to similarly initiate deltavirus replication in vitro and both induced a persistent infection of snake cells. The 1.2× genome constructs enable easier introduction of modifications required for studying deltavirus replication and cellular interactions.

Rapid multilocus adaptation of clonal cabbage leaf curl virus populations to Arabidopsis thaliana

Cabbage leaf curl virus (CabLCV) has a bipartite single-stranded DNA genome and infects the model plant Arabidopsis thaliana. CabLCV serves as a model for the genus Begomovirus, members of which cause tremendous crop losses worldwide. We have used CabLCV as a model for within-plant virus evolution by inoculating individual plants with infectious clones of both wild-type and mutagenized versions of the CabLCV genome. Consistent with previous reports, detrimental substitutions in the Replication-associated gene (Rep) were readily compensated for by direct reversion and/or alternative mutations. A surprising number of common mutations were detected elsewhere in both viral segments (DNA-A and DNA-B) indicating convergent evolution and suggesting that CabLCV may not be as well adapted to A. thaliana as commonly presumed. Consistent with this idea, a spontaneous coat protein variant consistently rose to higher allele frequency in a hypersusceptible A. thaliana accession (Sei-0) than in another susceptible accession (Col-0). Numerous high-frequency mutations were also detected in a candidate Rep binding site in DNA-B. Our results reinforce the fact that spontaneous mutation of this type of virus occurs rapidly and can change the majority consensus sequence of a within-plant virus population in weeks.

Identification of a Novel Geminivirus in Fraxinus rhynchophylla in Korea

Fraxinus rhynchophylla, common name ash, belongs to the family Oleaceae and is found in China, Korea, North America, the Indian subcontinent, and eastern Russia. It has been used as a traditional herbal medicine in Korea and various parts of the world due to its chemical constituents. During a field survey in March 2019, mild vein thickening (almost negligible) was observed in a few ash trees. High-throughput sequencing of libraries of total DNA from ash trees, rolling-circle amplification (RCA), and polymerase chain reaction (PCR) allowed the identification of a Fraxinus symptomless virus. This virus has five confirmed open reading frames along with a possible sixth open reading frame that encodes the movement protein and is almost 2.7 kb in size, with a nonanucleotide and stem loop structure identical to begomoviruses. In terms of its size and structure, this virus strongly resembles begomoviruses, but does not show any significant sequence identity with them. To confirm movement of the virus within the trees, different parts of infected trees were examined, and viral movement was successfully observed. No satellite molecules or DNA B were identified. Two-step PCR confirmed the virion and complementary strands during replication in both freshly collected infected samples of ash tree and Nicotiana benthamiana samples agro-inoculated with infectious clones. This taxon is so distantly grouped from other known geminiviruses that it likely represents a new geminivirus genus.

Akt Phosphorylation of Hepatitis C Virus NS5B Regulates Polymerase Activity and Hepatitis C Virus Infection

Hepatitis C virus (HCV) is a single-stranded RNA virus of positive polarity [ssRNA(+)] that replicates its genome through the activity of one of its proteins, called NS5B. This viral protein is responsible for copying the positive-polarity RNA genome into a negative-polarity RNA strand, which will be the template for new positive-polarity RNA genomes. The NS5B protein is phosphorylated by cellular kinases, including Akt. In this work, we have identified several amino acids of NS5B that are phosphorylated by Akt, with positions S27, T53, T267, and S282 giving the most robust results. Site-directed mutagenesis of these residues to mimic (Glu mutants) or prevent (Ala mutants) their phosphorylation resulted in a reduced NS5B in vitro RNA polymerase activity, except for the T267E mutant, the only non-conserved position of all those that are phosphorylated. In addition, in vitro transcribed RNAs derived from HCV complete infectious clones carrying mutations T53E/A and S282E/A were transfected in Huh-7.5 permissive cells, and supernatant viral titers were measured at 6 and 15 days post-transfection. No virus was rescued from the mutants except for T53A at 15 days post-transfection whose viral titer was statistically lower as compared to the wild type. Therefore, phosphorylation of NS5B by cellular kinases is a mechanism of viral polymerase inactivation. Whether this inactivation is a consequence of interaction with cellular kinases or a way to generate inactive NS5B that may have other functions are questions that need further experimental work.

Short '1.2× genome' infectious clone initiates deltavirus replication in Boa constrictor cells

Human hepatitis D virus (HDV), discovered in 1977, represented the sole known deltavirus for decades. The dependence on hepatitis B virus (HBV) co-infection and its glycoproteins for infectious particle formation led to the assumption that deltaviruses are human-only pathogens. However, since 2018, several reports have described identification of HDV-like agents from various hosts but without co-infecting hepadnaviruses. Indeed, we demonstrated that Swiss snake colony virus 1 (SwSCV-1) uses arenaviruses as the helper for infectious particle formation, thus shaking the dogmatic alliance with hepadnaviruses for completing deltavirus life cycle. In vitro systems enabling helper virus-independent replication are key for studying the newly discovered deltaviruses. Others and we have successfully used constructs containing multimers of the deltavirus genome for the replication of various deltaviruses via transfection in cell culture. Here, we report the establishment of deltavirus infectious clones with 1.2× genome inserts bearing two copies of the genomic and antigenomic ribozymes. We used SwSCV-1 as the model to compare the ability of the previously reported "2× genome" and the "1.2× genome" plasmid constructs/infectious clones to initiate replication in cell culture. Using immunofluorescence, qRT-PCR, immuno- and northern blotting, we found the 2× and 1.2× genome clones to similarly initiate deltavirus replication in vitro and both induced a persistent infection of snake cells. We hypothesize that duplicating the ribozymes facilitates the cleavage of genome multimers into unit-length pieces during the initial round of replication. The 1.2× genome constructs enable easier introduction of modifications required for studying deltavirus replication and cellular interactions.

Construction of Full-Length Infectious Clones of Turnip Mosaic Virus Isolates Infecting Perilla Frutescens and Genetic Analysis of Recently Emerged Strains of Tumv in Korea

Perilla is an annual herb with a unique aroma and taste and has been cultivated in Korea for hundreds of years. Owing to the highly edible and medicinal value of Perilla plants, it has been widely cultivated in many Asian and European countries. Recently, several viruses have been reported to cause diseases in Perilla in Korea, including turnip mosaic virus (TuMV) which is known as a brassica pathogen due to its significant damage to brassica crops. In this study, we determined the complete genome sequences of two new TuMV isolates originating from Perilla in Korea. Full-length infectious cDNA clones of these two isolates were constructed and their infectivity was tested by agroinfiltration on Nicotiana benthamiana and sap inoculation on Chinese cabbage and radish. In addition, we analyzed the phylogenetic relationship of six new Korean TuMV isolates and determined their respective affiliation with the four major groups. We also conducted recombination analysis for isolates recently occurring in Korean using RDP4 software, which provided new insight into the evolutionary relationships among Korean isolates of TuMV.

Construction of Full-length Infectious cDNA Clones of Two Korean Isolates of Turnip Mosaic Virus Breaking Resistance in Brassica Napus

In this work, two new Turnip mosaic virus (TuMV) strains (Canola-12 and Canola-14) overcoming resistance in canola (Brassica napus) were isolated from a B. napus sample which showed typical TuMV-like symptoms and was collected from Gimcheon city, South Korea in 2020. Complete genomes and infectious clones of each isolate were obtained. Phylogenetic analysis indicated that the strains isolated from canola belonged to the World-B group. Both infectious clones which were driven by 35S and T7 promoters induced systemic symptoms on Nicotiana benthamiana and B. napus. To our knowledge, this is the first report of TuMV infecting B. napus in South Korea.

Infectious Clones of Tomato Chlorosis Virus: Toward Increasing Efficiency by Introducing the Hepatitis Delta Virus Ribozyme

Tomato chlorosis virus (ToCV) is an emergent plant pathogen that causes a yellow leaf disorder in tomato and other solanaceous crops. ToCV is a positive-sense, single stranded (ss)RNA bipartite virus with long and flexuous virions belonging to the genus Crininivirus (family Closteroviridae). ToCV is phloem-limited, transmissible by whiteflies, and causes symptoms of interveinal chlorosis, bronzing, and necrosis in the lower leaves of tomato accompanied by a decline in vigor and reduction in fruit yield. The availability of infectious virus clones is a valuable tool for reverse genetic studies that has been long been hampered in the case of closterovirids due to their genome size and complexity. Here, attempts were made to improve the infectivity of the available agroinfectious cDNA ToCV clones (isolate AT80/99-IC from Spain) by adding the hepatitis delta virus (HDV) ribozyme fused to the 3′ end of both genome components, RNA1 and RNA2. The inclusion of the ribozyme generated a viral progeny with RNA1 3′ ends more similar to that present in the clone used for agroinoculation. Nevertheless, the obtained clones were not able to infect tomato plants by direct agroinoculation, like the original clones. However, the infectivity of the clones carrying the HDV ribozyme in Nicotiana benthamiana plants increased, on average, by two-fold compared with the previously available clones.

The identification of Tautoneura mori as the vector of mulberry crinkle leaf virus and the infectivity of infectious clones in mulberry

Mulberry crinkle leaf virus (MCLV) is a novel geminivirus identified from mulberry. The pathogenicity and the natural vector of transmission have remained unknown for MCLV. Here, the infectious clones which consisted of the complete tandem dimeric genome of MCLV in a binary vector were constructed and agro-inoculated into mulberry seedlings. The results showed that the infectious clones of MCLV were systemically infectious to mulberry, but the infected mulberry plants did not show any virus-like symptoms. The natural transmission vectors of MCLV were also identified from possible vector insects occurring on the MCLV-infected mulberry plants. The vector ability of Tautoneura mori Matsumura was identified through inoculation assay. Three of 21 (14.3%) seedlings inoculated with T. mori collected from MCLV-infected mulberry plants grown naturally were detected to be MCLV-positive 50 days post-inoculation. These MCLV-positive mulberry plants did also not show any virus-like symptoms. Collectively, it is suggested that MCLV is infectious to mulberry plants, but MCLV alone does not induce symptoms. The leafhopper T. mori was for the first time determined experimentally to be a transmission vector of MCLV.