Optimization of PCR for quantification of simian immunodeficiency virus genomic RNA in plasma of rhesus macaques (Macaca mulatta) using armored RNA.

INTRODUCTION: Quantification of plasma viral load (PVL) is used to monitor disease progression in SIV-infected macaques. This study was aimed at optimizing of performance characteristics of the quantitative PCR (qPCR) PVL assay. METHODS: The PVL quantification procedure was optimized by inclusion of an exogenous control hepatitis C virus armored RNA (aRNA), a plasma concentration step, extended digestion with proteinase K, and a second RNA elution step. Efficiency of viral RNA (vRNA) extraction was compared using several commercial vRNA extraction kits. Various parameters of qPCR targeting the gag region of SIVmac239, SIVsmE660, and the LTR region of SIVagmSAB were also optimized. RESULTS: Modifications of the SIV PVL qPCR procedure increased vRNA recovery, reduced inhibition and improved analytical sensitivity. The PVL values determined by this SIV PVL qPCR correlated with quantification results of SIV RNA in the same samples using the 'industry standard' method of branched-DNA (bDNA) signal amplification. CONCLUSIONS: Quantification of SIV genomic RNA in plasma of rhesus macaques using this optimized SIV PVL qPCR is equivalent to the bDNA signal amplification method, less costly and more versatile. Use of heterologous aRNA as an internal control is useful for optimizing performance characteristics of PVL qPCRs.

Storage of cellular 5' mRNA caps in P bodies for viral cap-snatching.

The minus strand and ambisense segmented RNA viruses include multiple important human pathogens and are divided into three families, the Orthomyxoviridae, the Bunyaviridae, and the Arenaviridae. These viruses all initiate viral transcription through the process of "cap-snatching," which involves the acquisition of capped 5' oligonucleotides from cellular mRNA. Hantaviruses are emerging pathogenic viruses of the Bunyaviridae family that replicate in the cytoplasm of infected cells. Cellular mRNAs can be actively translated in polysomes or physically sequestered in cytoplasmic processing bodies (P bodies) where they are degraded or stored for subsequent translation. Here we show that the hantavirus nucleocapsid protein binds with high affinity to the 5' cap of cellular mRNAs, protecting the 5' cap from degradation. We also show that the hantavirus nucleocapsid protein accumulates in P bodies, where it sequesters protected 5' caps. P bodies then serve as a pool of primers during the initiation of viral mRNA synthesis by the viral polymerase. We propose that minus strand segmented viruses replicating in the cytoplasm have co-opted the normal degradation machinery of P bodies for storage of cellular caps. Our data also indicate that modification of the cap-snatching model is warranted to include a role for the nucleocapsid protein in cap acquisition and storage.

Hantavirus N protein exhibits genus-specific recognition of the viral RNA panhandle.

A key genomic characteristic that helps define Hantavirus as a genus of the family Bunyaviridae is the presence of distinctive terminal complementary nucleotides that promote the folding of the viral genomic segments into "panhandle" hairpin structures. The hantavirus nucleocapsid protein (N protein), which is encoded by the smallest of the three negative-sense genomic RNA segments, undergoes in vivo and in vitro trimerization. Trimeric hantavirus N protein specifically recognizes the panhandle structure formed by complementary base sequence of 5' and 3' ends of viral genomic RNA. N protein trimers from the Andes, Puumala, Prospect Hill, Seoul, and Sin Nombre viruses recognize their individual homologous panhandles as well as other hantavirus panhandles with high affinity. In contrast, these hantavirus N proteins bind with markedly reduced affinity to the panhandles from the genera Bunyavirus, Tospovirus, and Phlebovirus or Nairovirus. Interactions between most hantavirus N and heterologous hantavirus viral RNA panhandles are mediated by the nine terminal conserved nucleotides of the panhandle, whereas Sin Nombre virus N requires the first 23 nucleotides for high-affinity binding. Trimeric hantavirus N complexes undergo a prominent conformational change while interacting with panhandles from members of the genus Hantavirus but not while interacting with panhandles from viruses of other genera of the family Bunyaviridae. These data indicate that high-affinity interactions between trimeric N and hantavirus panhandles are conserved within the genus Hantavirus.

Characterization of the RNA chaperone activity of hantavirus nucleocapsid protein.

Hantaviruses are tripartite negative-sense RNA viruses and members of the Bunyaviridae family. The nucleocapsid (N) protein, encoded by the smallest of the three genome segments (S), has nonspecific RNA chaperone activity. This activity results in transient dissociation of misfolded RNA structures, may be required for facilitating correct higher-order RNA structure, and may function in viral genome replication. We carried out a series of experiments to further characterize the ability of N to dissociate RNA duplexes. As might be expected, N dissociated RNA duplexes but not DNA duplexes or RNA-DNA heteroduplexes. The RNA-destabilizing activity of N is ATP independent, has a pH optimum of 7.5, and has an Mg(2+) concentration optimum of 1 to 2 mM. N protein is unable to unwind the RNA duplexes that are completely double stranded. However, in the presence of an adjoining single-stranded region, helix unwinding takes place in the 3'-to-5' direction through an unknown mechanism. The N protein trimer specifically recognizes and unwinds the terminal panhandle structure in the viral RNA and remains associated with unwound 5' terminus. We suggest that hantaviral nucleocapsid protein has an active role in hantaviral replication by working cooperatively with viral RNA polymerase. After specific recognition of the panhandle structure by N protein, the unwound 5' terminus likely remains transiently bound to N protein, creating an opportunity for the viral polymerase to initiate transcription at the accessible 3' terminus.

The hantavirus nucleocapsid protein recognizes specific features of the viral RNA panhandle and is altered in conformation upon RNA binding.

Hantaviruses are tripartite negative-sense RNA viruses and members of the Bunyaviridae family. The nucleocapsid (N) protein is the principal structural component of the viral capsid. N forms a stable trimer that specifically recognizes the panhandle structure formed by the viral RNA termini. We used trimeric glutathione S-transferase (GST)-N protein and small RNA panhandles to examine the requirements for specific recognition by Sin Nombre hantavirus N. Trimeric GST-N recognizes the panhandles of the three viral RNAs (S, M, and L) with high affinity, whereas the corresponding plus-strand panhandles of the complementary RNA are recognized with lower affinity. Based on analysis of nucleotide substitutions that alter either the higher-order structure of the panhandle or the primary sequence of the panhandle, both secondary structure and primary sequence are necessary for stable interaction with N. A panhandle 23 nucleotides long is necessary and sufficient for high-affinity binding by N, and stoichiometry calculations indicate that a single N trimer interacts with a single panhandle. Surprisingly, displacement of the panhandle structure away from the terminus does not eliminate recognition by N. The binding of N to the panhandle is an entropy-driven process resulting in initial stable N-RNA interaction followed by a conformational change in N. Taken together, these data provide insight into the molecular events that take place during interaction of N with the panhandle and suggest that specific high-affinity interaction between an RNA binding domain of trimeric N and the panhandle is required for encapsidation of the three viral RNAs.

Trimeric hantavirus nucleocapsid protein binds specifically to the viral RNA panhandle.

Hantaviruses are tripartite negative-sense RNA viruses and members of the Bunyaviridae family. The nucleocapsid (N) protein is encoded by the smallest of the three genome segments (S). N protein is the principal structural component of the viral capsid and is central to the hantavirus replication cycle. We examined intermolecular N-protein interaction and RNA binding by using bacterially expressed Sin Nombre virus N protein. N assembles into di- and trimeric forms. The mono- and dimeric forms exist transiently and assemble into a trimeric form. In contrast, the trimer is highly stable and does not efficiently disassemble into the mono- and dimeric forms. The purified N-protein trimer is able to discriminate between viral and nonviral RNA molecules and, interestingly, recognizes and binds with high affinity the panhandle structure composed of the 3' and 5' ends of the genomic RNA. In contrast, the mono- and dimeric forms of N bind RNA to form a complex that is semispecific and salt sensitive. We suggest that trimerization of N protein is a molecular switch to generate a protein complex that can discriminate between viral and nonviral RNA molecules during the early steps of the encapsidation process.

Duplication of the primary encapsidation and dimer linkage region of human immunodeficiency virus type 1 RNA results in the appearance of monomeric RNA in virions.

The dimerization initiation site (DIS) and the dimer linkage sequences (DLS) of human immunodeficiency virus type 1 have been shown to mediate in vitro dimerization of genomic RNA. However, the precise role of the DIS-DLS region in virion assembly and RNA dimerization in virus particles has not been fully elucidated, since deletion or mutation of the DIS-DLS region also abolishes the packaging ability of genomic RNA. To characterize the DIS-DLS region without altering packaging ability, we generated mutant constructs carrying a duplication of approximately 1,000 bases including the encapsidation signal and DIS-DLS (E/DLS) region. We found that duplication of the E/DLS region resulted in the appearance of monomeric RNA in virus particles. No monomers were observed in virions of mutants carrying the E/DLS region only at ectopic positions. Monomers were not observed when pol or env regions were duplicated, indicating an absolute need for two intact E/DLS regions on the same RNA for generating particles with monomeric RNA. These monomeric RNAs were most likely generated by intramolecular interaction between two E/DLS regions on one genome. Moreover, incomplete genome dimerization did not affect RNA packaging and virion formation. Examination of intramolecular interaction between E/DLS regions could be a convenient tool for characterizing the E/DLS region in virion assembly and RNA dimerization within virus particles.

Association of Vpu-binding protein with microtubules and Vpu-dependent redistribution of HIV-1 Gag protein.

The efficient exit of HIV-1 particles from cells requires the action of the viral encoded protein Vpu. Vpu-binding protein (Ubp) is a cellular protein that interacts with both Vpu and the major structural component of the viral capsid (Gag) and appears to affect the efficiency of particle exit. Elucidation of the function of Ubp and characterization of the spatial distribution of Ubp may provide information pertinent to understanding the role of Ubp in virus replication. To investigate the subcellular location of Ubp, and to see whether Vpu affects the intracellular distribution of Gag, we carried out immunofluorescence localization in conjunction with confocal microscopy. Based on this analysis Ubp is present in both the nucleus and the cytoplasm. In the cytoplasm, Ubp appeared to be associated with microtubules as evidenced by cofluorescence with tubulin in the absence and in the presence of colchicine. However, cytoskeletal isolation and detergent extraction of cells resulted in association of Ubp with the soluble fractions, indicating that Ubp is not in tight association with microtubules. Moreover, flotation gradient analysis demonstrated that Ubp is cytoplasmic and not stably associated with the plasma membrane. Interestingly, expression of Vpu in cells resulted in redistribution of both Ubp and Gag to a location near the periphery of the cell. The effect of Vpu on both Ubp and Gag protein has implications for Vpu-mediated particle exit from cells.

Functional interaction of human immunodeficiency virus type 1 Vpu and Gag with a novel member of the tetratricopeptide repeat protein family.

Viral protein U (Vpu) is a protein encoded by human immunodeficiency virus type 1 (HIV-1) that promotes the degradation of the virus receptor, CD4, and enhances the release of virus particles from cells. We isolated a cDNA that encodes a novel cellular protein that interacts with Vpu in vitro, in vivo, and in yeast cells. This Vpu-binding protein (UBP) has a molecular mass of 41 kDa and is expressed ubiquitously in human tissues at the RNA level. UBP is a novel member of the tetratricopeptide repeat (TPR) protein family containing four copies of the 34-amino-acid TPR motif. Other proteins that contain TPR motifs include members of the immunophilin superfamily, organelle-targeting proteins, and a protein phosphatase. UBP also interacts directly with HIV-1 Gag protein, the principal structural component of the viral capsid. However, when Vpu and Gag are coexpressed, stable interaction between UBP and Gag is diminished. Furthermore, overexpression of UBP in virus-producing cells resulted in a significant reduction in HIV-1 virion release. Taken together, these data indicate that UBP plays a role in Vpu-mediated enhancement of particle release.

The HIV-1 matrix domain of Gag is required for Vpu responsiveness during particle release.

HIV-1 viral protein U (Vpu) facilitates virus particle release. To determine whether Gag is sufficient for generation of a target for Vpu-mediated particle release, we expressed HIV-1 Gag protein in the absence of the other viral genes. The resulting particles were still Vpu responsive. Mutational analysis of Gag indicated that the matrix domain (MA) is required for Vpu responsiveness. However, additional mutations in other domains of Gag, which affect the formation of stable virus particles, also abrogate Vpu responsiveness on total Gag release. Coexpression of the wild-type gag gene and a gag mutant lacking the MA domain renders the MA- mutant Vpu responsive. This indicates that Gag molecules lacking MA are still incorporated into particles through association with wild-type Gag molecules and that the resulting composite particles are sufficient for Vpu-mediated exit.

Distinct functions and requirements for the Cys-His boxes of the human immunodeficiency virus type 1 nucleocapsid protein during RNA encapsidation and replication.

The process of retroviral RNA encapsidation involves interaction between trans-acting viral proteins and cis-acting RNA elements. The encapsidation signal on human immunodeficiency virus type 1 (HIV-1) RNA is a multipartite structure composed of functional stem-loop structures. The nucleocapsid (NC) domain of the Gag polyprotein precursor contains two copies of a Cys-His box motif that have been demonstrated to be important in RNA encapsidation. To further characterize the role of the Cys-His boxes of the HIV-1 NC protein in RNA encapsidation, the relative efficiency of RNA encapsidation for virus particles that contained mutations within the Cys-His boxes was measured. Mutations that disrupted the first Cys-His box of the NC protein resulted in virus particles that encapsidated genomic RNA less efficiently and subgenomic RNA more efficiently than did wild-type virus. Mutations within the second Cys-His box did not significantly affect RNA encapsidation. In addition, a full complement of wild-type NC protein in virus particles is not required for efficient RNA encapsidation or virus replication. Finally, both Cys-His boxes of the NC protein play additional roles in virus replication.

Ultrastructure of HIV-1 genomic RNA.

The HIV-1 RNA genome is a dimer which consists of two identical strands of RNA linked near their 5' ends by a dimer linkage structure (DLS). We have structurally characterized full-length HIV-1 genomic RNA isolated from HIV-1 virions by electron microscopy. As in other retroviruses, the HIV-1 RNA genome contains a central dimer linkage structure and additional loop structures within each monomer subunit. In contrast to the DLS of other retroviruses, the DLS region of HIV-1 contains a loop of 323 +/- 44 nucleotides. The free 5' ends of the two RNA strands were not visualized, suggesting that the 5' end regions are involved in interstrand complementary base pairing. Computer modeling identified a single stable structure that was consistent with the electron microscopy data. In this model, the two RNA strands are linked at their 5' ends by two contact points derived from "kissing-loop" interactions between r-u5 and SL1 stem-loops and their counterparts on the second strand. These interactions may contribute to the formation of stable HIV-1 RNA dimers in vivo.

Efficient encapsidation of human immunodeficiency virus type 1 vectors and further characterization of cis elements required for encapsidation.

To determine whether there is a cis-acting effect of translational expression of gag on RNA encapsidation, we compared the encapsidation of wild-type RNA with that of a mutant in which the translation of gag was ablated. This comparison indicated that there is not such a cis effect. To determine what is necessary and sufficient for encapsidation, we measured the relative encapsidation efficiencies of human immunodeficiency virus type 1 vector RNAs containing mutations in domains proximal to the canonical encapsidation signal or containing large deletions in the remainder of the genome. These data indicate that TAR and two additional regions are required for encapsidation and that the 5' end of the genome is sufficient for encapsidation. The Rev-responsive element is required mainly for efficient RNA transport from the nucleus to the cytoplasm. A foreign sequence was found to have a negative effect on encapsidation upon placement within the parental vector. Interestingly, this negative effect was compounded by multiple copies of the sequence.

Human immunodeficiency virus type 1 RNA outside the primary encapsidation and dimer linkage region affects RNA dimer stability in vivo.

To characterize the cis-acting determinants that function in RNA dimer formation and maintenance, we examined the stability of RNA dimers isolated from virus particles containing mutations in the encapsidation region of human immunodeficiency virus type 1 (HIV-1). The genomic RNAs of all mutants containing lesions in elements required for in vitro dimerization exhibited thermal stability similar to that of wild-type (WT) HIV-1. These data indicate that the eventual formation of stable dimeric RNA in vivo is not absolutely dependent on the elements that promote dimer formation in vitro. Surprisingly, mutants that lacked a large segment of the middle portion of the genome, outside the likely primary dimer linkage region, formed RNA dimers that were measurably more stable than WT. In addition, the insertion of one or multiple copies of a foreign gene, which resulted in a series of vectors that approached RNA length similar to that of WT RNA, still exhibited augmented dimer stability. These results suggest that there are regions in the HIV-1 genome outside the primary dimer initiation and dimer linkage regions that can negatively affect dimer stability.

Position dependence of functional hairpins important for human immunodeficiency virus type 1 RNA encapsidation in vivo.

At least two hairpins in the 5' untranslated leader region, stem-loops 1 and 3 (SL1 and SL3), contribute to human immunodeficiency virus type 1 RNA encapsidation in vivo. We used a competitive assay, which measures the relative encapsidation efficiency of mutant viral RNA in the presence of competing wild-type RNA, to compare the contributions of SL1, SL3, and two adjacent secondary structures, SL2 and SL4, to encapsidation. SL2 is not required for RNA encapsidation, while SL1, SL3, and SL4 all contribute approximately equally to encapsidation. To determine whether these hairpins function in a position-dependent manner, we interchanged the positions of two of these stem-loop structures. This resulted in substantial diminution of encapsidation, indicating that the secondary structures that comprise E, the encapsidation signal, function only in their correct contexts. Mutation of nucleotides flanking SL1 and SL3 had little effect on encapsidation. We also showed that SL1, while present on both genomic and subgenomic viral RNAs, nonetheless contributes to selective encapsidation of genomic RNA. Taken together, these data are consistent with the formation of a higher-order RNA structure, partially composed of SL1, SL3, and SL4, that functions to effect concurrent encapsidation of full-length RNA and exclusion of subgenomic RNA. Finally, it has been reported that E is required for efficient translation of Gag mRNA in vivo. However, we have found that a variety of mutants, including a mutant lacking the entire region encompassing SL1, SL2, and SL3, still produce RNAs that are efficiently translated. These data indicate that E is unlikely to contribute to efficient Gag mRNA translation in vivo.

Pleiotropic mutations in the HIV-1 matrix protein that affect diverse steps in replication.

The matrix domain of the Gag precursor protein, and the mature matrix protein, which is derived from processing of the Gag precursor, functions in several steps of the human immunodeficiency virus type-1 (HIV-1) life cycle. We made numerous mutations throughout the matrix protein and identified three mutants in the N-terminal portion of the matrix that drastically diminish the ability of the virus to replicate. Each of these replication-defective mutants was unable to acquire efficiently the envelope glycoprotein of HIV-1. To determine whether these same mutations affect other steps in viral replication we pseudotyped mutant particles with the envelope glycoprotein from an amphotropic murine leukemia virus. Each of these mutants was also hampered in other steps in virus replication. Two mutants were defective in entry or uncoating, and the third was hampered in a step following reverse transcription. Since viral replication was analyzed under conditions in which the nuclear localization function of the matrix protein is not required, the matrix protein may be required for an additional replication step following reverse transcription.

HIV-1 particle release mediated by Vpu is distinct from that mediated by p6.

Vpu and the C-terminal peptide of Gag (p6) are both HIV-1-encoded proteins that augment the release of virus particles from cells. We examined the functional relationship between these proteins and their activities during particle release. Our results indicate that efficient HIV-1 particle release from HeLa and Jurkat cells depends on the presence of Vpu. However, Vpu is dispensable for efficient release from Cos cells. In contrast, p6 is required for efficient release from Cos cells but not from Jurkat or HeLa cells. These data suggest that Vpu and p6 have distinct activities in virus exit from different cell lines. Intracellular proteolytic processing of Gag precursor protein is more complete in Cos cells than in HeLa cells. However, this processing has little or no effect on Vpu- or p6-mediated particle release. p6 is required for incorporation of yet another virus protein (Vpr) into cells but our data suggest that Vpr plays no role in p6-dependent particle release. Vpu also facilitates the degradation of CD4 in virus producing cells but, in contrast to particle release, the ability of Vpu to facilitate the degradation of CD4 is not cell line-dependent.

The human immunodeficiency virus type 1 encapsidation site is a multipartite RNA element composed of functional hairpin structures.

We analyzed the leader region of human immunodeficiency virus type 1 (HIV-1) RNA to decipher the nature of the cis-acting E/psi element required for encapsidation of viral RNA into virus particles. Our data indicate that, for RNA encapsidation, there are at least two functional subregions in the leader region. One subregion is located at a position immediately proximal to the major splice donor, and the second is located between the splice donor and the beginning of the gag gene. This suggests that at least two discrete cis-acting elements are recognition signals for encapsidation. To determine whether specific putative RNA secondary structures serve as the signal(s) for encapsidation, we constructed primary base substitution mutations that would be expected to destabilize these potential structures and second-site compensatory mutations that would restore secondary structure. Analysis of these mutants allowed the identification of two discrete hairpins that facilitate RNA encapsidation in vivo. Thus, the HIV-1 E/psi region is a multipartite element composed of specific and functional RNA secondary structures. Compensation of the primary mutations by the second-site mutations could not be attained in trans. This indicates that interstrand base pairing between these two stem regions within the hairpins does not appear to be the basis for HIV-1 RNA dimer formation. Comparison of the hypothetical RNA secondary structures from 10 replication-competent HIV-1 strains suggests that a subset of the hydrogen-bonded base pairs within the stems of the hairpins is likely to be required for function in cis.

Examination of TAR-independent Trans activation by human immunodeficiency virus type 1 Tat in human glial cells.

Astrocytic glial cells derived from central nervous system (CNS) can support human immunodeficiency virus type 1 (HIV-1) replication in cell culture, may be infected in tissue culture, and are thought to be a large HIV-1 reservoir in vivo. The Tat protein of HIV-1 interacts with a cis-acting target sequence referred to as TAR. However, Tat can also stimulate gene expression directed from some heterologous promoters and, in certain circumstances, an HIV-1 long terminal repeat (LTR) that lacks the TAR element. Therefore, we attempted to investigate Tat trans activation of HIV-1 LTR in the astrocytic glial cells. Using transfection of LTR-reporter gene constructs and HIV-1 proviral constructs, we demonstrate TAR-dependent replication in astrocytic cells. We also examined the expression of HIV-1 env gene from an LTR that lacks TAR element. In a previous study (Kim and Panganiban: J Virol 67:3739-3747, 1993), we observed that env expression is trans activated only by the full-length Tat protein through a TAR-independent manner in HeLa cells. However, in astrocytic glial cells, the trans activation of env expression from the LTR-lacking TAR element was mediated by the first exon peptide of Tat as well as the full-length Tat peptide through a post-transcriptional mechanism rather than a transcriptional one. This result suggests that cell type-specific factor(s) is involved in the TAR-independent Tat responsiveness.