The complete genome sequence and genome structure of frangipani mosaic virus

The Forgotten Tobamovirus Genes Encoding the 54 kDa Protein and the 4-6 kDa Proteins

This article reviews the literature concerning the largely forgotten tobamovirus gene products for which no functions have been ascribed. One of these gene products is the 54 kDa protein, representing the RNA-dependent RNA polymerase segment of the 183 kDa protein translated from the I1-subgenomic mRNA, but which has been found only by in vitro translation and not in plants. The other is a collection of small proteins, expressed from alternative reading frames (likely from internal ribosome entry sites) in either or both the movement protein gene or the capsid protein gene. Previously, two small proteins were referred to as the 4-6 kDa proteins, since only single proteins of such size had been characterized from tobacco mosaic virus and tomato mosaic virus genomes. Such putative proteins will be referred to here as P6 proteins, since many new proposed P6 open reading frames could be discerned, from an analysis of 45 of 47 tobamovirus genomes, with a coding capacity of >15 amino acids up to 94 amino acids, whereas other peptides with ≤15 amino acids were not considered here. The distribution of the putative P6 proteins among these tobamoviruses is described, as well as the various classes they fall into, based on their distribution with regard to the organization of other genes in the viral genomes. Models also are presented for possible functions of the 54 kDa protein and the P6 proteins, based on data in the literature.

Pepper Mild Mottle Virus: An Infectious Pathogen in Pepper Production and a Potential Indicator of Domestic Water Quality

Pepper (Capsicum spp.; Family: Solanaceae; 2n = 24) is an important crop cultivated worldwide for the consumption of its fresh and dried processed fruits. Pepper fruits are used as raw materials in a wide variety of industrial processes. As a multipurpose vegetable crop, there is a need to increase the yield. However, yield productivity of pepper is severely constrained by infectious plant pathogens, including viruses, bacteria, fungi, and oomycetes. The pepper mild mottle virus (PMMoV) is currently one of the most damaging pathogens associated with yield losses in pepper production worldwide. In addition to impacts on pepper productivity, PMMoV has been detected in domestic and aquatic water resources, as well as in the excreta of animals, including humans. Therefore, PMMoV has been suggested as a potential indicator of domestic water quality. These findings present additional concerns and trigger the need to control the infectious pathogen in crop production. This review provides an overview of the distribution, economic impacts, management, and genome sequence variation of some isolates of PMMoV. We also describe genetic resources available for crop breeding against PMMoV.

First report of plumeria mosaic virus infecting Plumeria spp. in the United States

Plumeria (Plumeria spp.) is a small ornamental tree grown in subtropical and tropical areas, providing shade and attractive and fragrant flowers in public and private landscapes. In Hawaii, plumeria is also commercially grown, with flowers harvested for cut flower and lei production. In 2019, a total of 10 cut flower plumeria farms in Hawaii sold 7,356,702 blossoms, valued at $395,791 (USDA/NASS). In July 2021, a commercial plumeria farm in Maui County, Hawaii reported trees with flowers exhibiting color breaking, and leaves with mosaic and vein banding. To determine if a viral pathogen was present, leaf tissue from a symptomatic plant was processed using a Double-RNA Viral dsRNA Extraction Kit for plant tissue (iNtRON Biotechnology, Korea), followed by random amplification (Melzer et al. 2010). The resulting products underwent paired-end sequencing on a MiSeq platform (Illumina, CA) at the Advanced Studies in Genomics, Proteomics, and Bioinformatics laboratory at the University of Hawaii. Of the 2,913,913 paired-end 300-bp reads generated, Geneious Prime (Biomatters, New Zealand) mapped 350,686 to plumeria mosaic virus (PluMV; KJ395757.1) and 293,911 to frangipani mosaic virus (FrMV; JN555602.2), with mean coverage depths of 10,318 and 7,348 respectively. A 6,648 nt contig representing the near full-length genome of PluMV-HI (OP342599) was found to be >97% identical to PluMV isolates PluMV-DR_TW (KX881422.2) and PluMV-Plu-Ind-1 (KJ395757.1). Similarly, a 6,631 nt contig representing the near full-length genome of FrMV-HI (OP342600) was found to be >98% identical to FrMV isolates FrMV-P (Lim et al. 2010; HM026454.1) and FrMV-Fr-Ind-1 (Kumar et al. 2015; JN555602.2). Bioinformatic analyses (Olmedo-Velarde et al. 2019) of the reads that did not map to PluMV and FrMV suggested the presence of a novel ampelovirus and reovirus in the tissue. To confirm the presence of PluMV and FrMV in Hawaii, leaves were collected in June 2022 from 5 plumeria trees on the Maui County farm and 16 ornamental plumeria trees from Honolulu County. Total RNA extracted as described by Li et al. (2008) as well as non-template (water) and positive (HTS tissue sample) controls underwent RT-PCR using random primers for cDNA synthesis, followed by virus-specific primers for PluMV (1133: 5'-TGGGCAAATAATCCGGCTATAC-3'/1134: 5'CCGGAGAGAGCATCAAACAA-3') and FrMV (1129: 5'-TGAGTTTAGGTCGCAGTTGATAG-3'/1130: 5-'AAAGACCAGAACCTCCAGAAAG-3') in singleplex reactions. The results indicated that all 5 plumeria samples from Maui County were positive for both PluMV and FrMV, whereas 6 out of 16 plumeria samples collected from Honolulu County tested positive for PluMV only. Both PluMV and FrMV are tobamoviruses (Virgaviridae) that can be transmitted mechanically and spread through the introduction and/or movement of cuttings, the primary method of plumeria propagation. Both PluMV and FrMV cause leaf mosaic (Kumar et al. 2015; Lim et al. 2010; Lin et al. 2020) and FrMV may also cause color break or "splash" in flowers, which was observed at the Maui County farm. This represents the first report of PluMV in the USA. FrMV was detected in Florida (Dey et al. 2020), but this is the first report of the virus in Hawaii. Additional surveys are required to determine the incidence of both viruses in other counties of Hawaii. The putative discovery of a novel ampelovirus and reovirus in plumeria warrants further research to characterize these agents and determine their distribution and impact on plumeria health.

Host biology and genomic properties of Plumeria mosaic virus, a tobamovirus discovered in a temple tree in India co-infecting with frangipani mosaic virus

Temple tree (Plumeria rubra f. acutifolia), an important fragrant-flower tree extensively used in the urban landscaping is known to be infected with a tobamovirus, frangipani mosaic virus (FrMV). In this study, we describe another tobamovirus, Plumeria mosaic virus (PluMV) infecting temple tree in India. PluMV was isolated from an old temple tree co-infected with FrMV. The presence of another tobamovirus was initially realized based on the distinct symptoms on Gomphrena globosa (globe amaranth), a non-host of FrMV. PluMV was highly transmissible through simple rub-inoculation. In host-range study, brinjal (Solanum melongena), chilli (Capsicum annuum), datura (Datura stramonium), globe amaranth and tobacco (Nicotiana benthamiana, N. glutinosa, N. tabacum cv. Xanthi) could differentiate PluMV from FrMV. The complete genome sequence of PluMV was determined (6,688 nucleotides [nt], GenBank KJ395757), which showed the genome structure typical of tobamovirus encoding four proteins: small replicase (3,549 nt/130 kDa), large replicase (5,061 nt/188 kDa), movement protein (770 nt/29 kDa) and coat protein (527 nt/19 kDa). The 5' and 3' UTR of PluMV contained 91 and 284 nt, respectively. The PluMV genome was 45 nts longer than that of FrMV and shared only 71.4-71.6% sequence identity with FrMV and  < 50% sequence identity with the rest of the other members of the genus Tobamovirus. PluMV shared a close but a divergent evolutionary relationship with FrMV. Based on the species demarcation guidelines of ICTV (<90% genome sequence identity), PluMV was considered as a new tobamovirus species. As PluMV was serologically related with FrMV, differential diagnostic assays such as simplex and duplex RT-PCR were developed, which revealed that PluMV naturally existed in both the species of temple tree, P. rubra f. acutifolia and P. rubra f. obtusa in India either alone or in mixed infection with FrMV.

Tobamovirus 3'-Terminal Gene Overlap May be a Mechanism for within-Host Fitness Improvement

Overlapping genes (OGs) are a universal phenomenon in all kingdoms, and viruses display a high content of OGs combined with a high rate of evolution. It is believed that the mechanism of gene overlap is based on overprinting of an existing gene. OGs help virus genes compress a maximum amount of information into short sequences, conferring viral proteins with novel features and thereby increasing their within-host fitness. Analysis of tobamovirus 3′-terminal genes reveals at least two modes of OG organization and mechanisms of interaction with the host. Originally isolated from Solanaceae species, viruses (referred to as Solanaceae-infecting) such as tobacco mosaic virus do not show 3′-terminal overlap between movement protein (MP) and coat protein (CP) genes but do contain open reading frame 6 (ORF6), which overlaps with both genes. Conversely, tobamoviruses, originally isolated from Brassicaceae species (referred to as Brassicaceae-infecting) and also able to infect Solanaceae plants, have no ORF6 but are characterized by overlapping MP and CP genes. Our analysis showed that the MP/CP overlap of Brassicaceae-infecting tobamoviruses results in the following: (i) genome compression and strengthening of subgenomic promoters; (ii) CP gene early expression directly from genomic and dicistronic MP subgenomic mRNA using an internal ribosome entry site (IRES) and a stable hairpin structure in the overlapping region; (iii) loss of ORF6, which influences the symptomatology of Solanaceae-infecting tobamoviruses; and (iv) acquisition of an IRES polypurine-rich region encoding an MP nuclear localization signal. We believe that MP/CP gene overlap may constitute a mechanism for host range expansion and virus adjustment to Brassicaceae plants.

Molecular characterisation of a novel recombinant Ribgrass mosaic virus strain FSHS

Background

The genus Tobamovirus (Virgaviridae) comprises 33 accepted species with the recent addition of eight new viruses and is divided in to three subgroups based on the origin of assembly of the virion and host range. Within the subgroup 1 tobamoviruses the orchid-associated tobamovirus was hypothesized to be a chimeric derivative of recombinations between genome fragments from subgroup 3 and 1. Recombination events involving RdRp, movement and coat protein genes are recorded within subgroup 1 and 2. However natural recombinations have not previously been reported between subgroup 3 tobamoviruses.

Findings

The organization and phylogenetic analyses of the complete genome and the different ORFs placed the new isolate within the Ribgrass mosaic virus clade of subgroup 3 tobamoviruses. Recombination detection analyses indicated that the isolate was a chimeric genome with fragments of high similarity to Ribgrass mosaic virus (RMV) strains NZ-439 (HQ667978) and Actinidia-AC (GQ401365.1) infecting herbaceous Plantago sp. and woody Actinidia spp., respectively. The recombinant differed across the whole genome by 3-8 % from other published RMV genomes.

Conclusion

In this investigation we report an intra-specific recombination between RMV strains NZ-439 (HQ667978) and Actinidia-AC (GQ401365.1), in the replicase component between viral-methyltransferase and viral-helicase regions, resulting in a novel RMV strain FSHS (JQ319720.1) that represents the first described natural recombinant within the RMV cluster of subgroup 3 tobamoviruses.

Electronic supplementary material

The online version of this article (doi:10.1186/s12985-016-0487-5) contains supplementary material, which is available to authorized users.

Characterisation and diagnosis of frangipani mosaic virus from India

Frangipani mosaic virus (FrMV) is known to infect frangipani tree (Plumeria rubra f. acutifolia) in India but the virus has not been characterized at genomic level and diagnosis is not available. In the present study, an isolate of FrMV (FrMV-Ind-1) showing greenish mosaic and vein-banding symptoms in P. rubra f. acutifolia in New Delhi was characterized based on host reactions, serology and genome sequence. The virus isolate induced local symptoms on several new experimental host species: Capsicum annuum (chilli), Nicotiana benthamiana, Solanum lycopersicum and S. melongena. N. benthamiana could be used as an efficient propagation host as it developed systemic mottle mosaic symptoms all round the year. The genome of FrMV-Ind-1 was 6643 (JN555602) nucleotides long with genome organization similar to tobamoviruses. The Indian isolate of FrMV shared a very close genome sequence identity (98.3 %) with the lone isolate of FrMV-P from Australia. FrMV-Ind-1 together with FrMV-P formed a new phylogenetic group i.e. Apocynaceae-infecting tobamovirus. The polyclonal antiserum generated through the purified virus preparation was successfully utilized to detect the virus in field samples of frangipani by ELISA. Of the eight different tobamoviruses tested, FrMV-Ind-1 shared distant serological relationships with only cucumber green mottle mosaic virus, tobacco mosaic virus, bell pepper mottle virus and kyuri green mottle mosaic virus. RT-PCR based on coat protein gene primer successfully detected the virus in frangipani plants. This study is the first comprehensive description of FrMV occurring in India.

Natural recombination between tobacco and tomato mosaic viruses

Tobacco mosaic virus (TMV) is a positive-sense plant RNA virus which has a wide host range and a worldwide distribution. Other than a troublesome pathogen, TMV is regarded as a model system pioneering biologic research for a century. The tomato strain of TMV has been recognized to be a distinct tobamovirus as the tomato mosaic virus (ToMV). Recombination has been increasingly recognized as an important factor generating genetic diversity in many RNA viruses. However, it is still unclear whether recombination can function in driving the evolution of tobamoviruses. Herein, based on sequence comparison, we found three recombinants involving each viral gene, all of which might be derived from homologous or aberrant homologous recombination between TMV and ToMV. The study provided evidence that recombination did contribute to the genetic diversity of tobamoviruses.

The complete genome sequence of a member of a new species of tobamovirus (rattail cactus necrosis-associated virus) isolated from Aporcactus flagelliformis

In this study, we identified a new tobamovirus from diseased Aporcactus flagelliformis cactus plants, named it rattail cactus necrosis-associated virus (RCNaV), and determined its complete genome sequence. The full RCNaV genome consisted of 6,506 nucleotides and contained four open reading frames coding for proteins of M(r) 128 kDa (3,441 nt), 185 kDa (4,929 nt), 55 kDa (1452 nt), 36 kDa (1,005 nt) and 19 kDa (513 nt) from the 5' to 3' end, respectively. The overall similarities for the four ORFs of RCNaV were from 32.5% to 64.1% and from 17.0% to 67.3% to those of the other tobamoviruses, at the nucleotide and amino acid level, respectively. Comparison of the coding and non-coding regions of the virus with those of other tobamoviruses showed that RCNaV is the most closely related to cactus mild mottle virus.

The complete genome sequence and genome structure of passion fruit mosaic virus

In this study, we determined the complete sequence of the genomic RNA of a Florida isolate of maracuja mosaic virus (MarMV-FL) and compared it to that of a Peru isolate of the virus (MarMV-P) and those of other known tobamoviruses. Complete sequence analysis revealed that the isolate should be considered a member of a new species and named passion fruit mosaic virus (PafMV). The genomic RNA of PafMV consists of 6,791 nucleotides and encodes four open reading frames (ORFs) coding for proteins of 125 kDa (1,101 aa), 184 kDa (1,612 aa), 34 kDa (311 aa) and 18 kDa (164 aa) in consecutive order from the 5' to the 3' end. The sequence homologies of the four ORFs of PafMV were from 78.8% to 81.6% to those of MarMV-P at the amino acid level. The sequence homologies of the four ORFs of PafMV ranged from 36.0% to 77.9% and from 21.7% to 81.6% to those of other tobamoviruses, at the nucleotide and amino acid level, respectively. Phylogenetic analysis revealed that these PafMV-encoded proteins are closely related to those of MarMV-P. In conclusion, the results indicate that PafMV and MarMV-P belong to different species within the genus Tobamovirus.