Providence virus: An animal virus that replicates in plants or a plant virus that infects and replicates in animal cells?

INTRODUCTION: Emerging viral diseases, most of which are zoonotic, pose a significant threat to global health. There is a critical need to identify potential new viral pathogens and the challenge is to identify the reservoirs from which these viruses might emerge. Deep sequencing of invertebrate transcriptomes has revealed a plethora of viruses, many of which represent novel lineages representing both plant and animal viruses and little is known about the potential threat that these viruses pose. METHODS: Providence virus, an insect virus, was used to establish a productive infection in Vigna unguiculata (cowpea) plants. Providence virus particles purified from these cowpea plants were used to infect two mammalian cell lines. FINDINGS: Here, we present evidence that Providence virus, a non-enveloped insect RNA virus, isolated from a lepidopteran midgut cell line can establish a productive infection in plants as well as in animal cells. The observation that Providence virus can readily infect both plants and mammalian cell culture lines demonstrates the ability of an insect RNA virus to establish productive infections across two kingdoms, in plants and invertebrate and vertebrate animal cell lines. CONCLUSIONS: The study highlights the potential of phytophagous insects as reservoirs for viral re-assortment and that plants should be considered as reservoirs for emerging viruses that may be potentially pathogenic to humans.

Complex pathways for regulation of pyrimidine metabolism by carbon catabolite repression and quorum sensing in Pseudomonas putida RU-KM3S.

Pseudomonads are metabolically versatile microbes that employ complex regulatory networks to control gene expression, particularly with respect to carbon and nitrogen metabolism. The aim of this study was to characterise the regulatory networks that control pyrimidine metabolism (hydantoin-hydrolysing activity) in Pseudomonas putida strain RU-KM3S, focussing on transcriptional activation of dihydropyrimidinase (Dhp) and ß-ureidopropionase (Bup), encoding dhp and bup, respectively. The two genes are arranged divergently on the chromosome and are separated by ORF1, encoding a putative transporter, which lies upstream of and in the same orientation as bup. The results from this study reveal that pyrimidine metabolism, as a function of Bup and Dhp activity in P. putida RU-KM3S, is controlled by a complex regulatory network including several global pathways in addition to induction by the substrate. Three major control pathways act at the level of transcriptional and include: (1) induction of transcriptional activation in the presence of hydantoin, (2) carbon catabolite repression mediated via a pathway independent of Crc and (3) quorum sensing that does not require a putative lux box located upstream of the dhp transcriptional start. Finally, the data suggest a minor role for the global regulators Anr, Vfr and Crc, likely through regulation of the activity of transcription factors interacting directly with the bup/ORF1-dhp promoter.