Antiviral Activity of an Endogenous Parvoviral Element.

Endogenous viral elements (EVEs) are genomic DNA sequences derived from viruses. Some EVEs have open reading frames (ORFs) that can express proteins with physiological roles in their host. Furthermore, some EVEs exhibit a protective role against exogenous viral infection in their host. Endogenous parvoviral elements (EPVs) are highly represented in mammalian genomes, and although some of them contain ORFs, their function is unknown. We have shown that the locus EPV-Dependo.43-ODegus, an EPV with an intact ORF, is transcribed in Octodon degus (degu). Here we examine the antiviral activity of the protein encoded in this EPV, named DeRep. DeRep was produced in bacteria and used to generate antibodies that recognize DeRep in western blots of degu tissue. To test if DeRep could protect against exogenous parvovirus, we challenged cells with the minute virus of mice (MVM), a model autonomous parvovirus. We observed that MVM protein expression, DNA damage induced by replication, viral DNA, and cytopathic effects are reduced when DeRep is expressed in cells. The results of this study demonstrate that DeRep is expressed in degu and can inhibit parvovirus replication. This is the first time that an EPV has been shown to have antiviral activity against an exogenous virus.

Dynein Light-Chain Dynlrb2 Is Essential for Murine Leukemia Virus Traffic and Nuclear Entry.

Murine leukemia virus (MLV) requires the infected cell to divide to access the nucleus to integrate into the host genome. It has been determined that MLV uses the microtubule and actin network to reach the nucleus at the early stages of infection. Several studies have shown that viruses use the dynein motor protein associated with microtubules for their displacement. We have previously reported that dynein light-chain roadblock type 2 (Dynlrb2) knockdown significantly decreases MLV infection compared to nonsilenced cells, suggesting a functional association between this dynein light chain and MLV preintegration complex (PIC). In this study, we aimed to determine if the dynein complex Dynlrb2 subunit plays an essential role in the retrograde transport of MLV. For this, an MLV mutant containing the green fluorescent protein (GFP) fused to the viral protein p12 was used to assay the PIC localization and speed in cells in which the expression of Dynlrb2 was modulated. We found a significant decrease in the arrival of MLV PIC to the nucleus and a reduced net speed of MLV PICs when Dynlrb2 was knocked down. In contrast, an increase in nuclear localization was observed when Dynlrb2 was overexpressed. Our results suggest that Dynlrb2 plays an essential role in MLV retrograde transport. IMPORTANCE Different viruses use different components of cytoplasmic dynein complex to traffic to their replication site. We have found that murine leukemia virus (MLV) depends on dynein light-chain Dynlrb2 for infection, retrograde traffic, and nuclear entry. Our study provides new information regarding the molecular requirements for retrograde transport of MLV preintegration complex and demonstrates the essential role of Dynlrb2 in MLV infection.

Microtubule Retrograde Motors and Their Role in Retroviral Transport.

Following entry into the host cell, retroviruses generate a dsDNA copy of their genomes via reverse transcription, and this viral DNA is subsequently integrated into the chromosomal DNA of the host cell. Before integration can occur, however, retroviral DNA must be transported to the nucleus as part of a 'preintegration complex' (PIC). Transporting the PIC through the crowded environment of the cytoplasm is challenging, and retroviruses have evolved different mechanisms to accomplish this feat. Within a eukaryotic cell, microtubules act as the roads, while the microtubule-associated proteins dynein and kinesin are the vehicles that viruses exploit to achieve retrograde and anterograde trafficking. This review will examine the various mechanisms retroviruses have evolved in order to achieve retrograde trafficking, confirming that each retrovirus has its own strategy to functionally subvert microtubule associated proteins.

Molecular Properties and Evolutionary Origins of a Parvovirus-Derived Myosin Fusion Gene in Guinea Pigs.

Sequences derived from parvoviruses (family Parvoviridae) are relatively common in animal genomes, but the functional significance of these endogenous parvoviral element (EPV) sequences remains unclear. In this study, we used a combination of in silico and molecular biological approaches to investigate a fusion gene carried by guinea pigs (genus Cavia) that is partially derived from an EPV. This gene, named enRep-M9l, encodes a predicted polypeptide gene product comprising a partial myosin9-like (M9l) gene fused to a 3' truncated, EPV-encoded replicase. We examined the genomic and phylogenetic characteristics of the EPV locus (enRep) that encodes the viral portions of enRep-M9l, revealing that it derives from an ancient dependoparvovirus (genus Dependoparvovirus) that was incorporated into the guinea pig germ line between approximately 22 and 35 million years ago (MYA). Despite these ancient origins, the regions of the enRep locus that are expressed in the enRep-M9l gene are conserved across multiple species in the family Caviidae (guinea pigs and cavies), consistent with a potential function at the amino acid level. Using molecular biological approaches, we further demonstrated that (i) enRep-M9l mRNA is broadly transcribed in guinea pig cells, (ii) the cloned enRep-M9l transcript can express a protein of the expected size in guinea pig cells in vitro, and (iii) the expressed protein localizes to the cytosol. Our findings demonstrate that, consistent with a functional role, the enRep-M9l fusion gene is evolutionarily conserved, broadly transcribed, and capable of expressing protein.IMPORTANCE DNA from viruses has been "horizontally transferred" to mammalian genomes during evolution, but the impact of this process on mammalian biology remains poorly understood. The findings of our study indicate that a novel gene has evolved in guinea pigs through fusion of host and virus genes.