Yeast tRNA(Phe) expressed in human cells can be selected by HIV-1 for use as a reverse transcription primer

HIV-1 Subtypes and 5'LTR-Leader Sequence Variants Correlate with Seroconversion Status in Pumwani Sex Worker Cohort

Within the Pumwani sex worker cohort, a subgroup remains seronegative, despite frequent exposure to HIV-1; some of them seroconverted several years later. This study attempts to identify viral variations in 5′LTR-leader sequences (5′LTR-LS) that might contribute to the late seroconversion. The 5′LTR-LS contains sites essential for replication and genome packaging, viz, primer binding site (PBS), major splice donor (SD), and major packaging signal (PS). The 5′LTR-LS of 20 late seroconverters (LSC) and 122 early seroconverters (EC) were amplified, cloned, and sequenced. HelixTree 6.4.3 was employed to classify HIV subtypes and sequence variants based on seroconversion status. We find that HIV-1 subtypes A1.UG and D.UG were overrepresented in the viruses infecting the LSC (P < 0.0001). Specific variants of PBS (Pc < 0.0001), SD1 (Pc < 0.0001), and PS (Pc < 0.0001) were present only in the viral population from EC or LSC. Combinations of PBS [PBS-2 (Pc < 0.0001) and PBS-3 (Pc < 0.0001)] variants with specific SD sequences were only seen in LSC or EC. Combinations of A1.KE or D with specific PBS and SD variants were only present in LSC or EC (Pc < 0.0001). Furthermore, PBS variants only present in LSC co-clustered with PBS references utilizing tRNA^Arg; whereas, the PBS variants identified only in EC co-clustered with PBS references using tRNA^Lys,3 and its variants. This is the first report that specific PBS, SD1, and PS sequence variants within 5′LTR-LS are associated with HIV-1 seroconversion, and it could aid designing effective anti-HIV strategies.

Genetic variation and HIV-associated neurologic disease

HIV-associated neurologic disease continues to be a significant complication in the era of highly active antiretroviral therapy. A substantial subset of the HIV-infected population shows impaired neuropsychological performance as a result of HIV-mediated neuroinflammation and eventual central nervous system (CNS) injury. CNS compartmentalization of HIV, coupled with the evolution of genetically isolated populations in the CNS, is responsible for poor prognosis in patients with AIDS, warranting further investigation and possible additions to the current therapeutic strategy. This chapter reviews key advances in the field of neuropathogenesis and studies that have highlighted how molecular diversity within the HIV genome may impact HIV-associated neurologic disease. We also discuss the possible functional implications of genetic variation within the viral promoter and possibly other regions of the viral genome, especially in the cells of monocyte-macrophage lineage, which are arguably key cellular players in HIV-associated CNS disease.

Forced selection of tRNA(Glu) reveals the importance of two adenosine-rich RNA loops within the U5-PBS for SIV(smmPBj) replication

Simian immunodeficiency virus (SIV) and human immunodeficiency virus (HIV-1) preferentially select and use tRNA(Lys,3) as the primer for initiation of reverse transcription. Previous studies have shown that HIV-1 can be forced to use tRNA(Glu) if mutations are made within the primer-binding site (PBS) and a region upstream, A-loop, to be complementary to the 3'-terminal 18 nucleotides and anticodon loop of tRNA(Glu). To examine the primer preference of SIV, mutations were made within the PBS of SIV(smmPBj) to be complementary to tRNA(Glu). Analysis of the production of infectious virus revealed that SIV(smmPBj) with the PBS complementary to tRNA(Glu) retained approximately 80% infectivity of the wild type. However, modification of the U5 of SIV(smmPBj) to alter nucleotides to be complementary to the anticodon of tRNA(Glu), in combination with the PBS complementary to tRNA(Glu), drastically reduced the production of infectious SIV(smmPBj) to less than 1% that of wild type. The replication of SIV(smmPBj) with the PBS complementary to tRNA(Glu) was similar to that of the wild type virus, while the replication of SIV(smmPBj) with PBS and A-loop complementary to tRNA(Glu) was delayed compared to that of wild type virus. Analysis of the PBS regions revealed that the virus with the PBS complementary to tRNA(Glu) reverted quickly, within 4 days, to be complementary to tRNA(Lys,3), while the virus with PBS and A-loop complementary to tRNA(Glu) retained the PBS for a longer time during in vitro culture although following extended replication both the A-loop and PBS of SIV(smmPBj) reverted to be complementary to tRNA(Lys,3). RNA modeling of SIV(smmPBj) U5-PBS by m-fold revealed two potential A-loop regions. Mutations in either A-loop drastically effected replication in human PBMC. Analysis of the A-loops following in vitro replication revealed that both reverted to the wild type sequence. The results of these studies demonstrate that SIV(smmPBj), like HIV-1, preferentially utilizes tRNA(Lys,3) as a primer for reverse transcription for high level replication, but unlike HIV-1 selection may involve the use of two adenosine-rich loops.

Nucleotides within the anticodon stem are important for optimal use of tRNA(Lys,3) as the primer for HIV-1 reverse transcription

HIV-1 utilizes tRNA(Lys,3) as the primer for initiation of reverse transcription. To further examine the tRNA sequence and structural requirements for primer selection, we developed a complementation system which required tRNA(Lys) to be provided in trans. We constructed an HIV-1 provirus in which the primer-binding site (PBS) was altered to be complementary to the 3' terminal 18-nucleotides of E. coli tRNA(Lys,3), which shares many bases with mammalian tRNA(Lys,3), and demonstrated that infectious virus was obtained only if the provirus was co-transfected with the plasmid encoding E. coli tRNA(Lys,3). In the current study we have mutated E. coli tRNA(Lys,3) so that nucleotides within the stem of the anticodon stem-loop were made identical to mammalian tRNA(Lys,3). Analysis of the complementation revealed that the modified E. coli tRNA(Lys,3) (E. coli tRNA(Lys,3)-MA) complemented 3-5 times more efficiently than E. coli tRNA(Lys,3). Mutation of nucleotides within the anticodon stem region of E. coli tRNA(Lys,3)-MA that differed from E. coli tRNA(Lys,3) revealed the importance of the nucleotide sequence for efficient use in reverse transcription. The results of our studies highlight that multiple regions of mammalian tRNA(Lys,3) are important for the preference of tRNA(Lys,3) as the primer for HIV-1 reverse transcription.

Analysis of the replication of HIV-1 forced to use tRNAMet(i) supports a link between primer selection, translation and encapsidation

Background

Previous studies have suggested that the process of HIV-1 tRNA primer selection and encapsidation of genomic RNA might be coupled with viral translation. In order to further investigate this relationship, proviruses were constructed in which the primer-binding site (PBS) was altered to be complementary to elongator tRNA^Met (tRNA^Met(e)) (HXB2-Met(e)) or initiator tRNA^Met (tRNA^Met(i)) (HXB2-Met(i)). These tRNA^Met not only differ with respect to the 3' terminal 18-nucleotides, but also with respect to interaction with host cell proteins during protein synthesis.

Results

Consistent with previous studies, HXB2-Met(e) were infectious and maintained this PBS following short-term in vitro culture in SupT1 cells. In contrast, transfection of HBX2-Met(i) produced reduced amounts of virus (as determined by p24) and did not establish a productive infection in SupT1 cells. The low infectivity of the virus with the PBS complementary to tRNA^Met(i) was not due to differences in endogenous levels of cellular tRNA^Met(i) compared to tRNA^Met(e); tRNA^Met(i) was also capable of being selected as the primer for reverse transcription as determined by the endogenous reverse transcription reaction. The PBS of HXB2-Met(i) contains an ATG, which could act as an upstream AUG and syphon scanning ribosomes thereby reducing initiation of translation at the authentic AUG of Gag. To investigate this possibility, a provirus with an A to G change was constructed (HXB2-Met(i)AG). Transfection of HXB2-Met(i)AG resulted in increased production of virus, similar to that for the wild type virus. In contrast to HXB2-Met(i), HXB2-Met(i)AG was able to establish a productive infection in SupT1 cells. Analysis of the PBS following replication revealed the virus favored the genome with the repaired PBS (A to G) even though tRNA^Met(i) was continuously selected as the primer for reverse transcription.

Conclusion

The results of these studies suggest that HIV-1 has access to both tRNA^Met for selection as the replication primer and supports a co-ordination between primer selection, translation and encapsidation during virus replication.

Mutations in the TPsiC loop of E. coli tRNALys,3 have varied effects on in trans complementation of HIV-1 replication

Background

Human immunodeficiency virus (HIV-1) exclusively selects and utilizes tRNA^Lys,3 as the primer for initiation of reverse transcription. Several elements within the TΨC stem loop of tRNA^Lys,3 are postulated to be important for selection and use in reverse transcription. The post-transcriptional modification at nucleotide 58 could play a role during plus-strand synthesis to stop reverse transcriptase from re-copying the tRNA primer. Nucleotides 53 and 54 within the TΨC stem loop of the tRNA have been shown to be important to form the complex between tRNA and the HIV-1 viral genome during initiation of reverse transcription.

Results

To further delineate the features of the TΨC stem loop of tRNA^Lys,3 in reverse transcription, we have developed a complementation system in which E. coli tRNA^Lys,3 is provided in trans to an HIV-1 genome in which the PBS is complementary to this tRNA. Successful selection and use of E. coli tRNA^Lys,3 results in the production of infectious virus. We have used this single round infectious system to ascertain the effects that different mutants in the TΨC stem loop of tRNA^Lys,3 have on complementation. Mutants were designed within the TΨC loop (nucleotide 58) and within the stem and loop of the TΨC loop (nucleotides 53 and 54). Analysis of the expression of E. coli tRNA^Lys,3 mutants revealed differences in the capacity for aminoacylation, which is an indication of intracellular stability of the tRNA. Alteration of nucleotide 58 from A to U (A58U), T54G and TG5453CC all resulted in tRNA^Lys,3 that was aminoacylated when expressed in cells, while a T54C mutation resulted in a tRNA^Lys,3 that was not aminoacylated. Both the A58U and T54G mutated tRNA^Lys,3 complemented HIV-1 replication similar to wild type E. coli tRNA^Lys,3. In contrast, the TG5453CC tRNA^Lys,3 mutant did not complement replication.

Conclusion

The results demonstrate that post-transcriptional modification of nucleotide 58 in tRNA^Lys,3 is not essential for HIV-1 reverse transcription. In contrast, nucleotides 53 and 54 of tRNA^Lys,3 are important for aminoacylation and selection and use of the tRNA^Lys,3 in reverse transcription.

Importance of A-loop complementarity with tRNAHis anticodon for continued selection of tRNAHis as the HIV reverse transcription primer

BACKGROUND

Human immunodeficiency virus (HIV-1) preferentially selects tRNALys,3 as the primer for reverse transcription. HIV-1 can be forced to select alternative tRNAs through mutation in the primer-binding site (PBS) and a region upstream of the PBS designated as the A-loop. Alteration of the PBS and A-loop to be complementary to the 3' terminal nucleotides and anticodon of tRNAHis results in HIV-1 that can stably utilize this tRNA for replication.

RESULTS

In the current study, we have investigated the effect that mutations within the A-loop have on the stability of HIV-1 with a PBS complementary to tRNAHis. For these studies, we have altered the A-loop to be complementary to tRNAMet, tRNAGln, tRNAIle, tRNAThr and tRNASer. All substitutions of the A-loops with the PBS complementary to tRNAHis resulted in a reduction of infectious virus obtained following transfection of proviral genomes in the 293T cells. Virus replication in SupT1 cells was also impaired as a result of the alteration of the A-loop. Viruses with the A-loop complementary to tRNALys,3 and tRNASer reverted to utilize tRNALys,3 following in vitro replication. In contrast, viruses with the A-loop complementary to the other tRNAs remained stable and continued to use tRNAHis. RNA modeling of the stem-loop structure revealed that nucleotides were displayed on the loop region that could potentially interact with the anticodon of tRNAHis. To further explore the effects of the A-loop mutations on virus replication, the A-loops complementary to tRNASer or tRNAHis were cloned into the wild type genome with the PBS complementary to tRNALys,3. Transfection of proviral genomes which contained the wild type PBS and A-loops complementary to tRNASer or tRNAHis into 293 T cells did not impact on the production of viruses as measured by p24 antigen ELISA. However, viruses with the A-loop complementary to tRNAHis had greatly reduced infectivity and replicated poorly in SupT1 compared to the wild type or viruses with the A-loop complementary to tRNASer.

CONCLUSION

These studies demonstrate that complementarity of A-loop region with the anticodon of tRNAHis has a pronounced effect on the capacity of HIV-1 to utilize tRNAHis as the primer for reverse transcription. Complementarity between A-loop and anticodon of the tRNA then is important for the selection of the tRNA primer used for reverse transcription.

Complementation of human immunodeficiency virus type 1 replication by intracellular selection of Escherichia coli formula supplied in trans

Human immunodeficiency virus type 1 (HIV-1) exclusively selects tRNA3Lys as the primer for the initiation of reverse transcription, even though both tRNA3Lys and tRNA1,2Lys are found in HIV-1 virions. Alteration of the HIV-1 primer-binding site (PBS) to be complementary to alternate tRNAs results in the use of those tRNAs for replication, indicating that primer complementarity with the PBS is an important determinant of primer selection. In previous studies, we have exploited this fact to develop a system in which yeast (Saccharomyces cerevisiae) tRNAPhe is provided in trans to complement the replication of HIV-1 with a PBS complementary to yeast tRNAPhe. Recent studies have demonstrated that the presence of lysyl-tRNA synthetase in HIV-1 virions might account for the preference for the selection of tRNA3Lys in HIV-1 replication. To establish a complementation system more reflective of HIV-1 primer selection, we have altered the HIV-1 PBS to be complementary to the Escherichia coli tRNA3Lys, which shares near identity with mammalian tRNA3Lys except in the 3'-terminal 18-nucleotide sequence that binds to the PBS. E. coli tRNA3Lys expressed from a plasmid was aminoacylated in mammalian cells. Cotransfection of cells with a plasmid that encodes E. coli tRNA3Lys and a plasmid encoding an HIV-1 provirus with a PBS complementary to E. coli tRNA3Lys resulted in the production of infectious virus. A comparison of the two complementation systems revealed that higher levels of intracellular E. coli tRNA3Lys than of yeast tRNAPhe were needed to achieve equal levels of infectious virus, indicating that there was no preferential selection of E. coli tRNA3Lys. To examine the specificity of tRNALys selection, E. coli tRNA3Lys was modified to tRNA1,2Lys. This tRNA was also aminoacylated when expressed in mammalian cells and complemented the infectivity of HIV-1 at levels similar to those seen for E. coli tRNA3Lys. Additional mutations in the anticodon of E. coli tRNA3Lys were constructed; these mutations did not significantly correlate with the capacity of the tRNA primer to complement infectivity of HIV-1, even though they had a drastic effect on the aminoacylation of the tRNAs. The results of these studies demonstrate that E. coli tRNA3Lys provided in trans can complement HIV-1 genomes with the PBS altered to E. coli tRNA3Lys. However, the capacity of tRNA3Lys to interact with lysyl-tRNA synthetase does not entirely explain the enhanced preference for selection of tRNA3Lys for the replication of HIV-1.

The G490E mutation in reverse transcriptase does not impact tRNA primer selection by HIV-1 with altered PBS and A-loop

The initiation of HIV-1 reverse transcription utilizes a cellular tRNA(Lys,3) as a primer. The 3' terminal 18-nucleotides of the cellular tRNA(Lys,3) are complementary to a region on the viral genome, designated as the primer binding site (PBS). Previous studies have shown that forcing HIV-1 to utilize alternative tRNA primers through alteration of the PBS results in viruses that revert to utilize tRNA(Lys,3) following in vitro replication. In some instances though, HIV-1 has been shown to select alternative tRNAs for initiation of reverse transcription if additional mutations upstream in the U5 region (A-loop) were made to be complementary to these alternative tRNAs. Recently, an HIV-1 has been described in which the U5 region distinct from the A-loop, designated as the primer activation site (PAS), was mutated in conjunction with the PBS to force the virus to use tRNA(Lys1,2) as a primer. An additional mutation in reverse transcriptase (RT), G490E, was found to facilitate the forced use of tRNA(Lys1,2) as the primer. In the current study, we have investigated the impact of the G490E mutation in RT on the selection and use of alternative primers by HIV-1. Viruses were first constructed in which the PBS and A-loop region were made complementary to tRNA(Trp). Previous studies from our laboratory have shown that these viruses are unstable and mutate to select tRNA(Met) or tRNA(Lys1,2). Analysis of the replication of viruses with the U5 and PBS complementary to tRNA(Trp) with or without the G490E mutation revealed no significant differences with respect to infectivity and viral growth in SupT1 or peripheral blood mononuclear cells (PBMC). In addition, the presence of the G490E mutation did not influence the capacity of this virus to revert to utilize tRNA(Met) as the primer for initiation of reverse transcription. In a previous study, we have described an HIV-1 that has been forced to utilize tRNA(Lys1,2) through mutations in the A-loop and PBS. The G490E RT mutation in this virus did not impact on the virus infectivity or growth in SupT1 or PBMC. We did not find a significant fitness advantage to viruses in which the A-loop and PBS were made complementary to tRNA(Lys1,2) that also contained the G490E mutation in RT. The results of these studies then establish that HIV-1 can be forced to use alternative primers through mutations in the U5 (PAS or A-loop) for certain tRNAs. Furthermore, for mutations in the A-loop and PBS, the RT does not play an important role in dictating the selection of the alternative primers to be used for initiation of reverse transcription.

Structural elements of the tRNA TPsiC loop critical for nucleocytoplasmic transport are important for human immunodeficiency virus type 1 primer selection

Human immunodeficiency virus type 1 (HIV-1) selects a host cell tRNA as the primer for the initiation of reverse transcription. In a previous study, transport of the intact tRNA from the nucleus to the cytoplasm during tRNA biogenesis was shown to be a requirement for the selection of the tRNA primer by HIV-1. To further examine the importance of tRNA structure for transport and the selection of the primer, yeast tRNA(Phe) mutants were designed such that the native tRNA structure would be disrupted to various extents. The capacity of the mutant tRNA(Phe) to complement a defective HIV-1 provirus that relies on the expression of yeast tRNA(Phe) for infectivity was determined. We found a direct relationship between intact tRNA conformation and the capacity to be selected by HIV-1 for use in reverse transcription. tRNA(Phe) mutants that retained the capacity for nucleocytoplasmic transport, indicative of overall intact conformation, complemented the defective provirus. The mutant tRNAs were not aminoacylated, and the levels of complementation were lower than that for wild-type tRNA(Phe), which did undergo transport and aminoacylation. Taken together, these results demonstrate that HIV-1 primer selection is most dependent on a tRNA structure necessary for nucleocytoplasmic transport, consistent with primer selection occurring in the cytoplasm at or near the site of protein synthesis.

Analysis of murine leukemia virus replication complemented by yeast tRNA(Phe) reveals inherent preferences for the tRNA primer selected for reverse transcription

The replication of murine leukemia virus (MuLV) requires the capture of a cellular tRNA(Pro) as a primer for reverse transcription. To further study the specificity of primer selection, we have utilized a defective MuLV in which the primer-binding site (PBS) has been altered to be complementary to a nonmammalian tRNA, yeast tRNA(Phe). Infectivity of the defective MuLV is dependent upon co-expression of yeast tRNA(Phe) in the cell. Defective MuLV genomes have been constructed in which the PBS was altered to be complementary to tRNA(Phe) that also encoded the cDNA for tRNA(Phe). Transfection of these defective proviral genomes into cells resulted in the production of infectious MuLV as determined by a single-round assay. The amount of infectious virus produced using this complementation system, though, was approximately 6-fold lower than that produced following transfection of defective proviral genomes with a wild-type PBS complementary to tRNA(Pro). The lower infectivity was not due to reduced expression of tRNA(Phe) in the transfected cells as compared to endogenous tRNA(Pro) or tRNA(Lys,3). Serial passage of the MuLV genome with a PBS complementary to tRNA(Phe) that encoded tRNA(Phe) resulted in amplification of the virus. Using this rescue system, we have passaged the virus for four serial passages, after which time a revertant genome in which the PBS was altered to be complementary to tRNA(Gln) was detected that grew to high titers following subsequent serial passage. The results of these studies suggest that MuLV has preferences for the tRNA primer used in reverse transcription and are discussed with respect to the mechanism of primer selection.

Selection of retroviral reverse transcription primer is coordinated with tRNA biogenesis

Initiation of retrovirus reverse transcription requires the selection of a tRNA primer from the intracellular milieu. To investigate the features of primer selection, a human immunodeficiency virus type 1 (HIV-1) and a murine leukemia virus (MuLV) were created that require yeast tRNA(Phe) to be supplied in trans for infectivity. Wild-type yeast tRNA(Phe) expressed in mammalian cells was transported to the cytoplasm and aminoacylated. In contrast, tRNA(Phe) without the D loop (tRNA(Phe)D(-)) was retained within the nucleus and did not complement infectivity of either HIV-1 or MuLV; however, infectivity was restored when tRNA(Phe)D(-) was directly transfected into the cytoplasm of cells. A tRNA(Phe) mutant (tRNA(Phe)UUA) that did not have the capacity to be aminoacylated was transported to the cytoplasm and did complement infectivity of both HIV-1 and MuLV, albeit at a level less than that with wild-type tRNA(Phe). Collectively, our results demonstrate that the tRNA primer captured by HIV-1 and MuLV occurs after nuclear export of tRNA and supports a model in which primer selection for retroviruses is coordinated with tRNA biogenesis at the intracellular site of protein synthesis.