Rev-Independent Simian Immunodeficiency Virus Strains Are Nonpathogenic in Neonatal Macaques

ABSTRACT The viral protein Rev is essential for the export of the subset of unspliced and partially spliced lentiviral mRNAs and the production of structural proteins. Rev and its RNA binding site RRE can be replaced in both human immunodeficiency virus (HIV) and simian immunodeficiency virus (SIV) by the constitutive RNA transport element CTE of the simian type D retroviruses. We used neonatal macaques as a sensitive animal model to evaluate the pathogenicity of a pair of SIV mutant strains generated from Rev-independent molecular clones of SIVmac239 which differ only in the presence of the nef open reading frame. After high primary viremia, all animals remained persistently infected at levels below the threshold of detection. All macaques infected as neonates developed normally, and none showed any signs of immune dysfunction or disease during follow-up ranging from 2.3 to 4 years. Therefore, the Rev-RRE regulatory mechanism plays a key role in the maintenance of high levels of virus propagation, which is independent of the presence of nef. These data demonstrate that Rev regulation plays an important role in the pathogenicity of SIV. Replacement of Rev-RRE by the CTE provides a novel approach to dramatically lower the virulence of a pathogenic lentivirus. These data further suggest that antiretroviral strategies leading to even a partial block of Rev function may modulate disease progression in HIV-infected individuals.

Retroviral Constitutive Transport Element Evolved from Cellular TAP(NXF1)-Binding Sequences

ABSTRACT The constitutive transport element (CTE) of type D retroviruses serves as a signal of nuclear export of unspliced viral RNAs. The human TAP(NXF1) protein, a cellular mRNA export factor, directly binds to CTE and mediates nuclear export of CTE-containing RNAs. Here, we use genomic SELEX (systematic evolution of ligands by exponential enrichment) to show that the human genome encodes a family of high-affinity TAP ligands. These TAP-binding elements (TBE) are 15-bp minisatellite repeats that are homologous to the core TAP-binding sites in CTE. The repeats are positioned similarly in the RNA secondary structures of CTE and TBE. Like CTE, TBE is an active nuclear export signal. CTE elements of different species share sequence similarities to TBE in the regions that are neutral for CTE function. This conservation points to a possible common ancestry of the two elements, and in fact, TBE has properties expected from a primordial CTE. Additionally, a molecular fossil of a TBE-like minisatellite is found in the genome of a modern retroelement. These findings constitute direct evidence of an evolutionary link between TBE-related minisatellites and CTE.

Sodium-Dependent Neutral Amino Acid Transporter Type 1 Is an Auxiliary Receptor for Baboon Endogenous Retrovirus

ABSTRACT The baboon endogenous retrovirus (BaEV) belongs to a large, widely dispersed interference group that includes the RD114 feline endogenous virus and primate type D retroviruses. Recently, we and another laboratory independently cloned a human receptor for these viruses and identified it as the human sodium-dependent neutral amino acid transporter type 2 (hASCT2). Interestingly, mouse and rat cells are efficiently infected by BaEV but only become susceptible to RD114 and type D retroviruses if the cells are pretreated with tunicamycin, an inhibitor of protein N-linked glycosylation. To investigate this host range difference, we cloned and analyzed NIH Swiss mouse ASCT2 (mASCT2). Surprisingly, mASCT2 did not mediate BaEV infection, which implied that mouse cells might have an alternative receptor for this virus. In addition, elimination of the two N-linked oligosaccharides from mASCT2 by mutagenesis, as substantiated by proteinN-glycosidase F digestions and Western immunoblotting, did not enable it to function as a receptor for RD114 or type D retroviruses. Based on these results, we found that the related ASCT1 transporters of humans and mice are efficient receptors for BaEV but are relatively inactive for RD114 and type D retroviruses. Furthermore, elimination of the two N-linked oligosaccharides from extracellular loop 2 of mASCT1 by mutagenesis enabled it to function as an efficient receptor for RD114 and type D retroviruses. Thus, we infer that the tunicamycin-dependent infection of mouse cells by RD114 and type D retroviruses is caused by deglycosylation of mASCT1, which unmasks previously buried sites for viral interactions. In contrast, BaEV efficiently employs the glycosylated forms of mASCT1 that occur normally in untreated mouse cells.

Improved Mg2+-Based Reverse Transcriptase Assay for Detection of Primate Retroviruses

The reverse transcriptase (RT) assay is a simple, relatively inexpensive, widely used assay that can detect all retroviruses (known and novel retroviruses as well as infectious and defective retroviruses) on the basis of the divalent cation requirement of their RT enzyme, i.e., Mg2+ or Mn2+. Descriptions of various RT assays have been published; however, they cannot be directly applied to the analysis of biological products or clinical samples without further standardization to determine the lower limit of virus detection (sensitivity), assay variability (reproducibility), or ability to detect different retroviruses (specificity). We describe the detection of type E and type D primate retroviruses, which may be pathogenic for humans, by a new 32P-based, Mg2+-containing RT assay. The results show that the sensitivity of detection is <3.2 50% tissue culture infective doses (TCID50s) for human immunodeficiency virus type 1 (HIV-1) and <1 TCID50 for simian immunodeficiency virus isolated from a rhesus macaque (SIVmac). Analysis of recombinant HIV-1 RT enzyme indicated that 10−5 U, which is equivalent to 4.25 × 104 virions, could be detected. Additionally, genetically distinct type D retroviruses such as simian AIDS retrovirus and squirrel monkey retrovirus were also detected in the assay with similar sensitivities. Thus, the improved RT assay can be used to detect genetically divergent Mg2+-dependent retroviruses of human and simian origin that can infect human cells and that therefore pose a potential health risk to humans.

Retroviral Diversity and Distribution in Vertebrates

ABSTRACT We used the PCR to screen for the presence of endogenous retroviruses within the genomes of 18 vertebrate orders across eight classes, concentrating on reptilian, amphibian, and piscine hosts. Thirty novel retroviral sequences were isolated and characterized by sequencing approximately 1 kb of their encoded protease and reverse transcriptase genes. Isolation of novel viruses from so many disparate hosts suggests that retroviruses are likely to be ubiquitous within all but the most basal vertebrate classes and, furthermore, gives a good indication of the overall retroviral diversity within vertebrates. Phylogenetic analysis demonstrated that viruses clustering with (but not necessarily closely related to) the spumaviruses and murine leukemia viruses are widespread and abundant in vertebrate genomes. In contrast, we were unable to identify any viruses from hosts outside of mammals and birds which grouped with the other five currently recognized retroviral genera: the lentiviruses, human T-cell leukemia-related viruses, avian leukemia virus-related retroviruses, type D retroviruses, and mammalian type B retroviruses. There was also some indication that viruses isolated from individual vertebrate classes tended to cluster together in phylogenetic reconstructions. This implies that the horizontal transmission of at least some retroviruses, between some vertebrate classes, occurs relatively infrequently. It is likely that many of the retroviral sequences described here are distinct enough from those of previously characterized viruses to represent novel retroviral genera.