In naked viruses, membrane breaching is a key step that must be performed for genome transfer into the target cells. Despite its importance, the mechanisms behind this process remain poorly understood. The small protein VP4, encoded by the genomes of most viruses of the order Picornavirales, has been shown to be involved in membrane alterations. Here we analyzed the permeabilization activity of the natively nonmyristoylated VP4 protein from triatoma virus (TrV), a virus belonging to the Dicistroviridae family within the Picornavirales order. The VP4 protein was produced as a C-terminal maltose binding protein (MBP) fusion to achieve its successful expression. This recombinant VP4 protein is able to produce membrane permeabilization in model membranes in a membrane composition-dependent manner. The induced permeability was also influenced by the pH, being greater at higher pH values. We demonstrate that the permeabilization activity elicited by the protein occurs through discrete pores that are inserted on the membrane. Sizing experiments using fluorescent dextrans, cryo-electron microscopy imaging, and other, additional techniques showed that recombinant VP4 forms heterogeneous proteolipidic pores rather than common proteinaceous channels. These results suggest that the VP4 protein may be involved in the membrane alterations required for genome transfer or cell entry steps during dicistrovirus infection.
IMPORTANCE
During viral infection, viruses need to overcome the membrane barrier in order to enter the cell and replicate their genome. In nonenveloped viruses membrane fusion is not possible, and hence, other mechanisms are implemented. Among other proteins, like the capsid-forming proteins and the proteins required for viral replication, several viruses of the orderPicornaviridae contain a small protein called VP4 that has been shown to be involved in membrane alterations. Here we show that the triatoma virus VP4 protein is able to produce membrane permeabilization in model membranes by the formation of heterogeneous dynamic pores. These pores formed by VP4 may be involved in the genome transfer or cell entry steps during viral infection.T he positive single-stranded RNA (ssRNA) virus triatoma virus (TrV) belongs to the Dicistroviridae family in the Picornavirales order. It is a lethal pathogen of the bloodsucking insect Triatoma infestans and of other insect species belonging to the Triatominae subfamily (1, 2). These insects are the main vectors for the transmission of the protozoon Trypanosoma cruzi, the causative agent of Chagas disease (American trypanosomiasis), a neglected tropical disease endemic in Latin America (3). Thus, TrV has been proposed to be a biological control agent that could be used to prevent the spread of this pathogen (4-6).Dicistroviruses were initially referred to as picorna-like viruses due to their similarities with members of the Picornaviridae family: the nonenveloped icosahedral capsid structure, the positive ssRNA genome, and the capsid protein composition. However, dic...