Effect of altering the tRNA(Lys)(3) concentration in human immunodeficiency virus type 1 upon its annealing to viral RNA, GagPol incorporation, and viral infectivity

From Glycolysis to Viral Defense: The Multifaceted Impact of Glycolytic Enzymes on Human Immunodeficiency Virus Type 1 Replication

Viruses require host cells to replicate and proliferate, which indicates that viruses hijack the cellular machinery. Human immunodeficiency virus type 1 (HIV-1) primarily infects CD4-positive T cells, and efficiently uses cellular proteins to replicate. Cells already have proteins that inhibit the replication of the foreign HIV-1, but their function is suppressed by viral proteins. Intriguingly, HIV-1 infection also changes the cellular metabolism to aerobic glycolysis. This phenomenon has been interpreted as a cellular response to maintain homeostasis during viral infection, yet HIV-1 efficiently replicates even in this environment. In this review, we discuss the regulatory role of glycolytic enzymes in viral replication and the impact of aerobic glycolysis on viral infection by introducing various host proteins involved in viral replication. Furthermore, we would like to propose a "glyceraldehyde-3-phosphate dehydrogenase-induced shock (G-shock) and kill strategy" that maximizes the antiviral effect of the glycolytic enzyme glyceraldehyde 3-phosphate dehydrogenase (GAPDH) to eliminate latently HIV-1-infected cells.

Aminoacyl-tRNA Synthetase: A Non-Negligible Molecule in RNA Viral Infection

Infectious diseases such as the ongoing coronavirus disease 2019 (COVID-19) continue to have a huge impact on global health, and the host-virus interaction remains incompletely understood. To address the global threat, in-depth investigations in pathogenesis are essential for interventions in infectious diseases and vaccine development. Interestingly, aminoacyl-transfer RNA (tRNA) synthetases (aaRSs), an ancient enzyme family that was once considered to play housekeeping roles in protein synthesis, are involved in multiple viral infectious diseases. Many aaRSs in eukaryotes present as the components of a cytoplasmic depot system named the multi-synthetase complex (MSC). Upon viral infections, several components of the MSC are released and exert nonenzymatic activities. Host aaRSs can also be utilized to facilitate viral entry and replication. In addition to their intracellular roles, some aaRSs and aaRS-interacting multi-functional proteins (AIMPs) are secreted as active cytokines or function as “molecule communicators” on the cell surface. The interactions between aaRSs and viruses ultimately affect host innate immune responses or facilitate virus invasion. In this review, we summarized the latest advances of the interactions between aaRSs and RNA viruses, with a particular emphasis on the therapeutic potentials of aaRSs in viral infectious diseases.

Hijacking tRNAs From Translation: Regulatory Functions of tRNAs in Mammalian Cell Physiology

Transfer tRNAs (tRNAs) are small non-coding RNAs that are highly conserved in all kingdoms of life. Originally discovered as the molecules that deliver amino acids to the growing polypeptide chain during protein synthesis, tRNAs have been believed for a long time to play exclusive role in translation. However, recent studies have identified key roles for tRNAs and tRNA-derived small RNAs in multiple other processes, including regulation of transcription and translation, posttranslational modifications, stress response, and disease. These emerging roles suggest that tRNAs may be central players in the complex machinery of biological regulatory pathways. Here we overview these non-canonical roles of tRNA in normal physiology and disease, focusing largely on eukaryotic and mammalian systems.

How HIV-1 Integrase Associates with Human Mitochondrial Lysyl-tRNA Synthetase

Replication of human immunodeficiency virus type 1 (HIV-1) requires the packaging of tRNA^Lys,3 from the host cell into the new viral particles. The GagPol viral polyprotein precursor associates with mitochondrial lysyl-tRNA synthetase (mLysRS) in a complex with tRNA^Lys, an essential step to initiate reverse transcription in the virions. The C-terminal integrase moiety of GagPol is essential for its association with mLysRS. We show that integrases from HIV-1 and HIV-2 bind mLysRS with the same efficiency. In this work, we have undertaken to probe the three-dimensional (3D) architecture of the complex of integrase with mLysRS. We first established that the C-terminal domain (CTD) of integrase is the major interacting domain with mLysRS. Using the pBpa-photo crosslinking approach, inter-protein cross-links were observed involving amino acid residues located at the surface of the catalytic domain of mLysRS and of the CTD of integrase. In parallel, using molecular docking simulation, a single structural model of complex was found to outscore other alternative conformations. Consistent with crosslinking experiments, this structural model was further probed experimentally. Five compensatory mutations in the two partners were successfully designed which supports the validity of the model. The complex highlights that binding of integrase could stabilize the tRNA^Lys:mLysRS interaction.

Emerging Roles of tRNAs in RNA Virus Infections

Viruses rely on the host cell translation machinery for efficient synthesis of their own proteins. Emerging evidence highlights different roles for host transfer RNAs (tRNAs) in the process of virus replication. For instance, different RNA viruses manipulate host tRNA pools to favor viral protein translation. Interestingly, specific host tRNAs are used as reverse transcription primers and are packaged into retroviral virions. Recent data also demonstrate the formation of tRNA-derived fragments (tRFs) upon infection to facilitate viral replication. Here, we comprehensively discuss how RNA viruses exploit distinct aspects of the host tRNA biology for their benefit. In light of the recent advances in the field, we propose that host tRNA-related pathways and mechanisms represent promising cellular targets for the development of novel antiviral strategies.

Structure of HIV-1 RT/dsRNA initiation complex prior to nucleotide incorporation

RT is a key enzyme in the life cycle of HIV, and is targeted by multiple antiviral drugs. Although for most of its function RT binds a dsDNA or RNA–DNA template–primer substrate, initiation of reverse transcription involves binding of dsRNA. The current study presents a structure of an RT/dsRNA complex that has the basic components of a reverse transcription initiation complex (RTIC). The unique structural features help understand the significantly slower rate of nucleotide incorporation by an RTIC compared with a catalytically efficient reverse transcription elongation complex. This complex may help in designing new experiments for understanding the intricate and slow process of reverse transcription initiation.

The initiation phase of HIV reverse transcription has features that are distinct from its elongation phase. The first structure of a reverse transcription initiation complex (RTIC) that trapped the complex after incorporation of one ddCMP nucleotide was published recently [Larsen KP, et al. (2018) Nature 557:118–122]. Here we report a crystal structure of a catalytically active HIV-1 RT/dsRNA complex that mimics the state of the RTIC before the first nucleotide incorporation. The structure reveals that the dsRNA-bound conformation of RT is closer to that of RT bound to a nonnucleoside RT inhibitor (NNRTI) and dsDNA; a hyperextended thumb conformation helps to accommodate the relatively wide dsRNA duplex. The RNA primer 3′ end is positioned 5 Å away from the polymerase site; however, unlike in an NNRTI-bound state in which structural elements of RT restrict the movement of the primer, the primer terminus of dsRNA is not blocked from reaching the active site of RT. The observed structural changes and energetic cost of bringing the primer 3′ end to the priming site are hypothesized to explain the slower nucleotide incorporation rate of the RTIC. An unusual crystal lattice interaction of dsRNA with its symmetry mate is reminiscent of the RNA architecture within the extended vRNA–tRNA^Lys3 in the RTIC. This RT/dsRNA complex captures the key structural characteristics and components of the RTIC, including the RT conformational changes and interactions with the dsRNA primer-binding site region, and these features have implications for better understanding of RT initiation.

Role of host tRNAs and aminoacyl-tRNA synthetases in retroviral replication

The lifecycle of retroviruses and retrotransposons includes a reverse transcription step, wherein dsDNA is synthesized from genomic RNA for subsequent insertion into the host genome. Retroviruses and retrotransposons commonly appropriate major components of the host cell translational machinery, including cellular tRNAs, which are exploited as reverse transcription primers. Nonpriming functions of tRNAs have also been proposed, such as in HIV-1 virion assembly, and tRNA-derived fragments may also be involved in retrovirus and retrotransposon replication. Moreover, host cellular proteins regulate retroviral replication by binding to tRNAs and thereby affecting various steps in the viral lifecycle. For example, in some cases, tRNA primer selection is facilitated by cognate aminoacyl-tRNA synthetases (ARSs), which bind tRNAs and ligate them to their corresponding amino acids, but also have many known nontranslational functions. Multi-omic studies have revealed that ARSs interact with both viral proteins and RNAs and potentially regulate retroviral replication. Here, we review the currently known roles of tRNAs and their derivatives in retroviral and retrotransposon replication and shed light on the roles of tRNA-binding proteins such as ARSs in this process.

Characterization of association of human mitochondrial lysyl-tRNA synthetase with HIV-1 Pol and tRNA3Lys

Background

An important step in human immunodeficiency virus type 1 (HIV-1) replication is the packaging of tRNA₃^Lys from the host cell, which plays the role of primer RNA in the process of initiation of reverse transcription. The viral GagPol polyprotein precursor, and the human mitochondrial lysyl-tRNA synthetase (mLysRS) from the host cell, have been proposed to be involved in the packaging process. More specifically, the catalytic domain of mLysRS is supposed to interact with the transframe (TF or p6*) and integrase (IN) domains of the Pol region of the GagPol polyprotein.

Results

In this work, we report a quantitative characterization of the protein:protein interactions between mLysRS and its viral partners, the Pol polyprotein, and the isolated integrase and transframe domains of Pol. A dissociation constant of 1.3 ± 0.2 nM was determined for the Pol:mLysRS interaction, which exemplifies the robustness of this association. The protease and reverse transcriptase domains of GagPol are dispensable in this association, but the TF and IN domains have to be connected by a linker polypeptide to recapitulate a high affinity partner for mLysRS. The binding of the viral proteins to mLysRS does not dramatically enhance the binding affinity of mLysRS for tRNA₃^Lys.

Conclusions

These data support the conclusion that the complex formed between GagPol, mLysRS and tRNA₃^Lys, which involves direct interactions between the IN and TF domains of Pol with mLysRS, is more robust than suggested by the previous models supposed to be involved in the packaging of tRNA₃^Lys into HIV-1 particles.

Conservation of tRNA mimicry in the 5'-untranslated region of distinct HIV-1 subtypes

Human tRNALys3 serves as the primer for reverse transcription in human immunodeficiency virus type-1 (HIV-1) and anneals to the complementary primer binding site (PBS) in the genome. All tRNALys isoacceptors interact with human lysyl-tRNA synthetase (hLysRS) and are selectively packaged into virions. tRNALys3 must be released from hLysRS in order to anneal to the PBS, and this process is proposed to be facilitated by the interaction of hLysRS with a tRNA-like element (TLE) first identified in the HIV-1 5'-untranslated region (5'-UTR) of the subtype B NL4-3 virus. However, a significant subset of HIV-1 strains represented by the MAL isolate possess a different secondary structure in this region of the genome. Thus, to establish the conservation of this mechanism for primer targeting and release, we investigated the subtype A-like 5'-UTR of the MAL isolate. hLysRS bound to a 229-nt MAL RNA containing the PBS domain with high affinity (Kd = 47 nM), and to a 98-nt truncated construct with ∼10-fold reduced affinity. These results resemble previous studies using analogous NL4-3-derived RNAs. However, in contrast to studies with NL4-3, no binding was observed to smaller stem-loop elements within the MAL PBS domain. The tertiary structure of the 98-nt construct was analyzed using small-angle X-ray scattering, revealing remarkable global structural similarity to the corresponding NL4-3 PBS/TLE region. These results suggest that the tRNA-like structure within the 5'-UTR is conserved across distinct HIV-1 subtypes and that hLysRS recognition of the MAL isolate is likely not conferred by specific sequence elements but by 3D structure.

Cytosolic aminoacyl-tRNA synthetases: Unanticipated relocations for unexpected functions

Prokaryotic and eukaryotic cytosolic aminoacyl-tRNA synthetases (aaRSs) are essentially known for their conventional function of generating the full set of aminoacyl-tRNA species that are needed to incorporate each organism's repertoire of genetically-encoded amino acids during ribosomal translation of messenger RNAs. However, bacterial and eukaryotic cytosolic aaRSs have been shown to exhibit other essential nonconventional functions. Here we review all the subcellular compartments that prokaryotic and eukaryotic cytosolic aaRSs can reach to exert either a conventional or nontranslational role. We describe the physiological and stress conditions, the mechanisms and the signaling pathways that trigger their relocation and the new functions associated with these relocating cytosolic aaRS. Finally, given that these relocating pools of cytosolic aaRSs participate to a wide range of cellular pathways beyond translation, but equally important for cellular homeostasis, we mention some of the pathologies and diseases associated with the dis-regulation or malfunctioning of these nontranslational functions.

The C-terminal domain of glyceraldehyde 3-phosphate dehydrogenase plays an important role in suppression of tRNALys3 packaging into human immunodeficiency virus type-1 particles

Human immunodeficiency virus type-1 (HIV-1) requires the packaging of human tRNA^Lys3 as a primer for effective viral reverse transcription. Previously, we reported that glyceraldehyde 3-phosphate dehydrogenase (GAPDH) suppresses the packaging efficiency of tRNA^Lys3. Although the binding of GAPDH to Pr55^gag is important for the suppression mechanism, it remains unclear which domain of GAPDH is responsible for the interaction with Pr55^gag. In this study, we show that Asp²⁵⁶, Lys²⁶⁰, Lys²⁶³ and Glu²⁶⁷ of GAPDH are important for the suppression of tRNA^Lys3 packaging. Yeast two-hybrid analysis demonstrated that the C-terminal domain of GAPDH (151–335) interacts with both the matrix region (MA; 1–132) and capsid N-terminal domain (CA-NTD; 133–282). The D256R, K263E or E267R mutation of GAPDH led to the loss of the ability to bind to wild-type (WT) MA, and the D256R/K260E double mutation of GAPDH resulted in the loss of detectable binding activity to WT CA-NTD. In contrast, R58E, Q59A or Q63A of MA, and E76R or R82E of CA-NTD abrogated the interaction with the C-terminal domain of GAPDH. Multiple-substituted GAPDH mutant (D256R/K260E/K263E/E267R) retained the oligomeric formation with WT GAPDH in HIV-1 producing cells, but the incorporation level of the hetero-oligomer was decreased in viral particles. Furthermore, the viruses produced from cells expressing the D256R/K260E/K263E/E267R mutant restored tRNA^Lys3 packaging efficiency because the mutant exerted a dominant negative effect by preventing WT GAPDH from binding to MA and CA-NTD and improved the reverse transcription. These findings indicate that the amino acids Asp²⁵⁶, Lys²⁶⁰, Lys²⁶³ and Glu²⁶⁷ of GAPDH is essential for the mechanism of tRNA^Lys3-packaging suppression and the D256R/K260E/K263E/E267R mutant of GAPDH acts in a dominant negative manner to suppress tRNA^Lys3 packaging.

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Yeast two-hybrid analysis revealed that GAPDH interacts with MA and CA region of HIV-1 precursor proteins via its C-terminal domain.

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Docking simulation predicted that GAPDH helix 10, which is exposed on surface of its tetrameric form surface, interacts with MA and CA.

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Mutagenesis assay on yeast two-hybrid analysis showed that D256R/K260E/K263E/E267R mutant of GAPDH lacks the binding affinity to both MA and CA.

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D256R/K260E/K263E/E267R mutant of GAPDH acts as dominant negative effector on the packaging of tRNA^Lys3.

Association of human mitochondrial lysyl-tRNA synthetase with HIV-1 GagPol does not require other viral proteins

In human, the cytoplasmic (cLysRS) and mitochondrial (mLysRS) species of lysyl-tRNA synthetase are encoded by a single gene. Following HIV-1 infection, mLysRS is selectively taken up into viral particles along with the three tRNA^Lys isoacceptors. The GagPol polyprotein precursor is involved in this process. With the aim to reconstitute in vitro the HIV-1 tRNA₃^Lys packaging complex, we first searched for the putative involvement of another viral protein in the selective viral hijacking of mLysRS only. After screening all the viral proteins, we observed that Vpr and Rev have the potential to interact with mLysRS, but that this association does not take place at the level of the assembly of mLysRS into the packaging complex. We also show that tRNA₃^Lys can form a ternary complex with the two purified proteins mLysRS and the Pol domain of GagPol, which mimicks its packaging complex.

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HIV-1 Rev and Vpr proteins have the capacity to bind human mitochondrial LysRS.

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In the complex between HIV-1 Pol and mitochondrial LysRS, Rev and Vpr are excluded.

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Association of Pol with mLysRS recapitulates the tRNA₃^Lys packaging complex of HIV-1.

Exploiting tRNAs to Boost Virulence

Transfer RNAs (tRNAs) are powerful small RNA entities that are used to translate nucleotide language of genes into the amino acid language of proteins. Their near-uniform length and tertiary structure as well as their high nucleotide similarity and post-transcriptional modifications have made it difficult to characterize individual species quantitatively. However, due to the central role of the tRNA pool in protein biosynthesis as well as newly emerging roles played by tRNAs, their quantitative assessment yields important information, particularly relevant for virus research. Viruses which depend on the host protein expression machinery have evolved various strategies to optimize tRNA usage—either by adapting to the host codon usage or encoding their own tRNAs. Additionally, several viruses bear tRNA-like elements (TLE) in the 5′- and 3′-UTR of their mRNAs. There are different hypotheses concerning the manner in which such structures boost viral protein expression. Furthermore, retroviruses use special tRNAs for packaging and initiating reverse transcription of their genetic material. Since there is a strong specificity of different viruses towards certain tRNAs, different strategies for recruitment are employed. Interestingly, modifications on tRNAs strongly impact their functionality in viruses. Here, we review those intersection points between virus and tRNA research and describe methods for assessing the tRNA pool in terms of concentration, aminoacylation and modification.

The role of A-kinase anchoring protein 95-like protein in annealing of tRNALys3 to HIV-1 RNA

Background

RNA helicase A (RHA), a DExH box protein, promotes annealing of tRNA^Lys3, a primer for reverse transcription, to HIV-1 RNA and assembles into virus particles. A-kinase anchoring protein 95-like protein (HAP95) is a binding partner of RHA. The role of HAP95 in the annealing of tRNA^Lys3 was examined in this study.

Results

HAP95 associates with the reverse transcriptase region of Pol protein of HIV-1. Decreasing endogenous HAP95 in HIV-1-producing 293T cells by siRNA reduces the amount of tRNA^Lys3 annealed on viral RNA. This defect was further deteriorated by knockdown of RHA in the same cells, suggesting a cooperative effect between these two proteins. Biochemical assay in vitro using purified GST-tagged HAP95 shows that HAP95 may inhibit the activity of RHA.

Conclusion

The results support a hypothesis that HAP95 may transiently block RHA’s activity to protect the annealed tRNA^Lys3 on viral RNA in the cells from removing by RHA during the packaging of RHA into virus particles, thus facilitating the annealing of tRNA^Lys3 to HIV-1 RNA.

tRNA synthetase: tRNA aminoacylation and beyond

The aminoacyl-tRNA synthetases are prominently known for their classic function in the first step of protein synthesis, where they bear the responsibility of setting the genetic code. Each enzyme is exquisitely adapted to covalently link a single standard amino acid to its cognate set of tRNA isoacceptors. These ancient enzymes have evolved idiosyncratically to host alternate activities that go far beyond their aminoacylation role and impact a wide range of other metabolic pathways and cell signaling processes. The family of aminoacyl-tRNA synthetases has also been suggested as a remarkable scaffold to incorporate new domains that would drive evolution and the emergence of new organisms with more complex function. Because they are essential, the tRNA synthetases have served as pharmaceutical targets for drug and antibiotic development. The recent unfolding of novel important functions for this family of proteins offers new and promising pathways for therapeutic development to treat diverse human diseases.

Phosphorylation of human immunodeficiency virus type 1 capsid protein at serine 16, required for peptidyl-prolyl isomerase-dependent uncoating, is mediated by virion-incorporated extracellular signal-regulated kinase 2

We reported previously that Pin1 facilitates human immunodeficiency virus type 1 (HIV-1) uncoating by interacting with the capsid core through the phosphorylated Ser(16)-Pro(17) motif. However, the specific kinase responsible for Ser(16) phosphorylation has remained unknown. Here, we showed that virion-associated extracellular signal-regulated kinase 2 (ERK2) phosphorylates Ser(16). The characterization of immature virions produced by exposing chronically HIV-1LAV-1-infected CEM/LAV-1 cells to 10 µM saquinavir indicated that Ser(16) is phosphorylated after the initiation of Pr55(Gag) processing. Furthermore, a mass spectrometry-based in vitro kinase assay demonstrated that ERK2 specifically phosphorylated the Ser(16) residue in the Ser(16)-Pro(17) motif-containing substrate. The treatment of CEM/LAV-1 cells with the ERK2 inhibitor sc-222229 decreased the Ser(16) phosphorylation level inside virions, and virus partially defective in Ser(16) phosphorylation showed impaired reverse transcription and attenuated replication owing to attenuated Pin1-dependent uncoating. Furthermore, the suppression of ERK2 expression by RNA interference in CEM/LAV-1 cells resulted in suppressed ERK2 packaging inside virions and decreased the Ser(16) phosphorylation level inside virions. Interestingly, the ERK2-packaging-defective virus showed impaired reverse transcription and attenuated HIV-1 replication. Taken together, these findings provide insights into the as-yet-obscure processes in Pin1-dependent HIV-1 uncoating.

New insights into inhibition of human immunodeficiency virus type 1 replication through mutant tRNALys3

BACKGROUND

Host cellular tRNA(Lys3) is exclusively utilized by human immunodeficiency virus type 1 (HIV-1) as a primer for the replication step of reverse transcription (RTion). Consequently, the priming step of HIV-1 RT constitutes a potential target for anti-HIV-1 intervention. Previous studies indicated that a mutant tRNA(Lys3) with 7-nucleotide substitutions in the 3' terminus resulted in aberrant HIV-1 RTion from the trans-activation response region (TAR) and inhibition of HIV-1 replication. However, the mutant tRNA(Lys3) also directed HIV-1 RTion from the normal primer-binding site (PBS) with potentially weakened anti-HIV-1 activity. To achieve improved targeting of HIV-1 RTion at sites not including the PBS, a series of mutant tRNA(Lys3) with extended lengths of mutations containing up to 18 bases complementary to their targeting sites were constructed and characterized.

RESULTS

A positive correlation between the length of mutation in the 3' PBS-binding region of tRNA(Lys3) and the specificity of HIV-1 RTion initiation from the targeting site was demonstrated, as indicated by the potency of HIV-1 inhibition and results of priming assays. Moreover, two mutant tRNA(Lys3)s that targeted the IN-encoding region and Env gene, respectively, both showed a high anti-HIV-1 activity, suggesting that not only the TAR, but also distant sites downstream of the PBS could be effectively targeted by mutant tRNA(Lys3). To increase the expression of mutant tRNA(Lys3), multiple-copy expression cassettes were introduced into target cells with increased anti-HIV-1 potency.

CONCLUSIONS

These results highlight the importance of the length of complementarity between the 3' terminus of the mutant tRNA(Lys3) and its target site, and the feasibility of targeting multiple sites within the HIV-1 genome through mutant tRNA(Lys3). Intervention of the HIV-1 genome conversion through mutant tRNA(Lys3) may constitute an effective approach for development of novel therapeutics against HIV-1 replication and HIV-1-associated diseases.

Molecular mimicry of human tRNALys anti-codon domain by HIV-1 RNA genome facilitates tRNA primer annealing

The primer for initiating reverse transcription in human immunodeficiency virus type 1 (HIV-1) is tRNA(Lys3). Host cell tRNA(Lys) is selectively packaged into HIV-1 through a specific interaction between the major tRNA(Lys)-binding protein, human lysyl-tRNA synthetase (hLysRS), and the viral proteins Gag and GagPol. Annealing of the tRNA primer onto the complementary primer-binding site (PBS) in viral RNA is mediated by the nucleocapsid domain of Gag. The mechanism by which tRNA(Lys3) is targeted to the PBS and released from hLysRS prior to annealing is unknown. Here, we show that hLysRS specifically binds to a tRNA anti-codon-like element (TLE) in the HIV-1 genome, which mimics the anti-codon loop of tRNA(Lys) and is located proximal to the PBS. Mutation of the U-rich sequence within the TLE attenuates binding of hLysRS in vitro and reduces the amount of annealed tRNA(Lys3) in virions. Thus, LysRS binds specifically to the TLE, which is part of a larger LysRS binding domain in the viral RNA that includes elements of the Psi packaging signal. Our results suggest that HIV-1 uses molecular mimicry of the anti-codon of tRNA(Lys) to increase the efficiency of tRNA(Lys3) annealing to viral RNA.

Role of aminoacyl-tRNA synthetases in infectious diseases and targets for therapeutic development

Aminoacyl-tRNA synthetases (AARSs) play a pivotal role in protein synthesis and cell viability. These 22 "housekeeping" enzymes (1 for each standard amino acid plus pyrrolysine and o-phosphoserine) are specifically involved in recognizing and aminoacylating their cognate tRNAs in the cellular pool with the correct amino acid prior to delivery of the charged tRNA to the protein synthesis machinery. Besides serving this canonical function, higher eukaryotic AARSs, some of which are organized in the cytoplasm as a multisynthetase complex of nine enzymes plus additional cellular factors, have also been implicated in a variety of non-canonical roles. AARSs are involved in the regulation of transcription, translation, and various signaling pathways, thereby ensuring cell survival. Based in part on their versatility, AARSs have been recruited by viruses to perform essential functions. For example, host synthetases are packaged into some retroviruses and are required for their replication. Other viruses mimic tRNA-like structures in their genomes, and these motifs are aminoacylated by the host synthetase as part of the viral replication cycle. More recently, it has been shown that certain large DNA viruses infecting animals and other diverse unicellular eukaryotes encode tRNAs, AARSs, and additional components of the protein-synthesis machinery. This chapter will review our current understanding of the role of host AARSs and tRNA-like structures in viruses and discuss their potential as anti-viral drug targets. The identification and development of compounds that target bacterial AARSs, thereby serving as novel antibiotics, will also be discussed. Particular attention will be given to recent work on a number of tRNA-dependent AARS inhibitors and to advances in a new class of natural "pro-drug" antibiotics called Trojan Horse inhibitors. Finally, we will explore how bacteria that naturally produce AARS-targeting antibiotics must protect themselves against cell suicide using naturally antibiotic resistant AARSs, and how horizontal gene transfer of these AARS genes to pathogens may threaten the future use of this class of antibiotics.

Glyceraldehyde 3-phosphate dehydrogenase negatively regulates human immunodeficiency virus type 1 infection

BACKGROUND

Host proteins are incorporated inside human immunodeficiency virus type 1 (HIV-1) virions during assembly and can either positively or negatively regulate HIV-1 infection. Although the identification efficiency of host proteins is improved by mass spectrometry, how those host proteins affect HIV-1 replication has not yet been fully clarified.

RESULTS

In this study, we show that virion-associated glyceraldehyde 3-phosphate dehydrogenase (GAPDH) does not allosterically inactivate HIV-1 reverse transcriptase (RT) but decreases the efficiency of reverse transcription reactions by decreasing the packaging efficiency of lysyl-tRNA synthetase (LysRS) and tRNA(Lys3) into HIV-1 virions. Two-dimensional (2D) gel electrophoresis demonstrated that some isozymes of GAPDH with different isoelectric points were expressed in HIV-1-producing CEM/LAV-1 cells, and a proportion of GAPDH was selectively incorporated into the virions. Suppression of GAPDH expression by RNA interference in CEM/LAV-1 cells resulted in decreased GAPDH packaging inside the virions, and the GAPDH-packaging-defective virus maintained at least control levels of viral production but increased the infectivity. Quantitative analysis of reverse transcription products indicated that the levels of early cDNA products of the GAPDH-packaging-defective virus were higher than those of the control virus owing to the higher packaging efficiencies of LysRS and tRNA(Lys3) into the virions rather than the GAPDH-dependent negative allosteric modulation for RT. Furthermore, immunoprecipitation assay using an anti-GAPDH antibody showed that GAPDH directly interacted with Pr55(gag) and p160(gag)-pol and the overexpression of LysRS in HIV-1-producing cells resulted in a decrease in the efficiency of GAPDH packaging in HIV particles. In contrast, the viruses produced from cells expressing a high level of GAPDH showed decreased infectivity in TZM-bl cells and reverse transcription efficiency in TZM-bl cells and peripheral blood mononuclear cells (PBMCs).

CONCLUSIONS

These findings indicate that GAPDH negatively regulates HIV-1 infection and provide insights into a novel function of GAPDH in the HIV-1 life cycle and a new host defense mechanism against HIV-1 infection.

Dual role for motif 1 residues of human lysyl-tRNA synthetase in dimerization and packaging into HIV-1

The primer for reverse transcription in human immunodeficiency virus type 1, human tRNA(Lys,3), is selectively packaged into the virion along with tRNA(Lys1,2). Human lysyl-tRNA synthetase (hLysRS), the only cellular factor known to interact specifically with all three tRNA(Lys) isoacceptors, is also selectively packaged into HIV-1. We have previously defined a tRNA(Lys) packaging complex that includes the tRNA(Lys) isoacceptors, LysRS, HIV-1 Gag, GagPol, and viral RNA. Numerous studies support the hypothesis that during tRNA(Lys) packaging, a Gag·GagPol complex interacts with a tRNA(Lys)·LysRS complex, with Gag interacting specifically with the catalytic domain of LysRS, and GagPol interacting with both Gag and tRNA(Lys). In this work, we have identified residues along one face of the motif 1 dimerization helix (H7) of hLysRS that are critical for packaging of the synthetase into virions. Mutation of these residues affects binding to Gag in vitro, as well as the oligomerization state and aminoacylation activity of the synthetase. Taken together, these data suggest that H7 of LysRS has a dual function. In its canonical role it maintains the synthetase dimer interface, whereas in its function in tRNA primer recruitment, it bridges interactions with HIV-1 Gag.

Packaging HIV virion components through dynamic equilibria of a human tRNA synthetase

Aminoacyl tRNA synthetases, components of the translation apparatus, have alternative functions outside of translation. The structural and mechanistic basis of these alternative functions is of great interest. As an example, reverse transcription of the HIV genome is primed by a human lysine-specific tRNA (tRNA(Lys3)) that is packaged (into the virion) by the HIV Gag protein with lysyl-tRNA synthetase (LysRS). Not understood is the structural basis for simultaneous packaging of tRNA(Lys3), LysRS, and Gag. Here, ab initio computational methods, together with our recent high-resolution 3-D structure of human LysRS, produced an energy-minimized model where Gag, tRNA(Lys), and LysRS form a ternary complex. Interestingly, the model requires normally homodimeric LysRS to dissociate into a monomer that bridges between Gag and tRNA(Lys3). Earlier experiments of others and new experiments presented here, which tested an engineered dissociated form of LysRS, were consistent with the ab initio "bridging monomer" model. The results support an emerging theme that alterative functions of tRNA synthetases may come, in part, from protein surfaces exposed by dynamic equilibria.

Profiling non-lysyl tRNAs in HIV-1

During its assembly, human HIV-1 selectively packages the tRNA(Lys) isoacceptors, including tRNA(Lys3), the primer for the reverse transcriptase. However, other low molecular weight RNA species are also seen in the virus. We profiled the tRNAs packaged into HIV-1 using microarray analysis and validated our results by two-dimensional gel electrophoresis and RT-PCR. In addition to tRNA(Lys) isoacceptors, tRNA(Asn) and the rare isoacceptor of tRNA(Ile) are also selectively packaged. In Gag viral-like particles missing the GagPol protein, overall tRNA incorporation is reduced by >80%. This reduction is significantly greater than can be accounted for by the reduction in tRNA(Lys) isoacceptors, tRNA(Asn) and tRNA(Ile), suggesting that incorporation of other tRNAs may also require the GagPol protein. These results demonstrate selective incorporation of non-lysyl tRNAs into HIV-1 and highlight the application of microarrays as a novel method to study tRNA incorporation into viruses.

Initiation of HIV Reverse Transcription

Reverse transcription of retroviral genomes into double stranded DNA is a key event for viral replication. The very first stage of HIV reverse transcription, the initiation step, involves viral and cellular partners that are selectively packaged into the viral particle, leading to an RNA/protein complex with very specific structural and functional features, some of which being, in the case of HIV-1, linked to particular isolates. Recent understanding of the tight spatio-temporal regulation of reverse transcription and its importance for viral infectivity further points toward reverse transcription and potentially its initiation step as an important drug target.

Formation of the tRNALys packaging complex in HIV-1

Human immunodeficiency virus 1 (HIV-1) uses a host cell tRNA(Lys,3) molecule to prime reverse transcription of the viral RNA genome into double-stranded DNA prior to integration into the host genome. All three human tRNA(Lys) isoacceptors along with human lysyl-tRNA synthetase (LysRS) are selectively packaged into HIV-1. Packaging of LysRS requires the viral Gag polyprotein and incorporation of tRNA(Lys) additionally requires the Gag-Pol precursor. A model that incorporates the known interactions between components of the putative packaging complex is presented. The molecular interactions that direct assembly of the tRNA(Lys)/LysRS packaging complex hold promise for the development of new anti-viral agents.

Roles of Gag and NCp7 in facilitating tRNA(Lys)(3) Annealing to viral RNA in human immunodeficiency virus type 1

In protease-negative human immunodeficiency virus type 1 (HIV-1) [Pr(-)], the amount of tRNA(3)(Lys) annealed by Gag is modestly reduced ( approximately 25%) compared to that annealed by mature nucleocapsid (NCp7) in protease-positive HIV-1 [Pr(+)]. However, the tRNA(3)(Lys) annealed by Gag also has a strongly reduced ability to initiate reverse transcription and binds less tightly to viral RNA. Both in vivo and in vitro, APOBEC3G (A3G) inhibits tRNA(3)(Lys) annealing facilitated by NCp7 but not annealing facilitated by Gag. While transient exposure of Pr(-) viral RNA to NCp7 in vitro returns the quality and quantity of tRNA(3)(Lys) annealing to Pr(+) levels, the presence of A3G both prevents this rescue and creates a further reduction in tRNA(3)(Lys) annealing. Since A3G inhibition of NCp7-facilitated tRNA(3)(Lys) annealing in vitro requires the presence of A3G during the annealing process, these results suggest that in Pr(+) viruses NCp7 can displace Gag-annealed tRNA(3)(Lys) and re-anneal it to viral RNA, the re-annealing step being subject to A3G inhibition. This supports the possibility that the initial annealing of tRNA(3)(Lys) in wild-type, Pr(+) virus may be by Gag and not by NCp7, perhaps offering the advantage of Gag's preference for binding to RNA stem-loops in the 5' region of viral RNA near the tRNA(3)(Lys) annealing region.

The structure of the human tRNALys3 anticodon bound to the HIV genome is stabilized by modified nucleosides and adjacent mismatch base pairs

Replication of human immunodeficiency virus (HIV) requires base pairing of the reverse transcriptase primer, human tRNA^Lys3, to the viral RNA. Although the major complementary base pairing occurs between the HIV primer binding sequence (PBS) and the tRNA's 3′-terminus, an important discriminatory, secondary contact occurs between the viral A-rich Loop I, 5′-adjacent to the PBS, and the modified, U-rich anticodon domain of tRNA^Lys3. The importance of individual and combined anticodon modifications to the tRNA/HIV-1 Loop I RNA's interaction was determined. The thermal stabilities of variously modified tRNA anticodon region sequences bound to the Loop I of viral sub(sero)types G and B were analyzed and the structure of one duplex containing two modified nucleosides was determined using NMR spectroscopy and restrained molecular dynamics. The modifications 2-thiouridine, s²U₃₄, and pseudouridine, Ψ₃₉, appreciably stabilized the interaction of the anticodon region with the viral subtype G and B RNAs. The structure of the duplex results in two coaxially stacked A-form RNA stems separated by two mismatched base pairs, U₁₆₂•Ψ₃₉ and G₁₆₃•A₃₈, that maintained a reasonable A-form helix diameter. The tRNA's s²U₃₄ stabilized the interaction between the A-rich HIV Loop I sequence and the U-rich anticodon, whereas the tRNA's Ψ₃₉ stabilized the adjacent mismatched pairs.

Methods for analysis of incorporation and annealing methods for analysis of tRNA(Lys) in HIV-1

In HIV-1, tRNA(Lys3) serves as the primer for reverse transcription of minus strand strong stop cDNA. During viral assembly, the tRNA(Lys) isoacceptors, tRNA(Lys1,2) and tRNA(Lys3), are selectively packaged into the virion. The selectively packaging of tRNA(Lys3) facilitates the annealing of tRNA(Lys3) to the viral genome and the initiation of reverse transcription. We describe herein a set of experimental approaches for studying the mechanism by which tRNA(Lys) is selectively incorporated into HIV-1 and investigate how primer tRNA(Lys3) is annealed to viral genome. The methods described will also help in the analysis of cellular RNAs packaged in the virus particles.

Inability of human immunodeficiency virus type 1 produced in murine cells to selectively incorporate primer formula

Attempts to use the mouse as a model system for studying AIDS are stymied by the multiple blocks to human immunodeficiency virus type 1 (HIV-1) replication that exist in mouse cells at the levels of viral entry, transcription, and Gag assembly and processing. In this report, we describe an additional block in the selective packaging of tRNA(3Lys) into HIV-1 produced in murine cells. HIV-1 and murine leukemia virus (MuLV) use tRNA(3Lys) and tRNA(Pro), respectively, as primers for reverse transcription. Selective packaging of tRNA(3Lys) into HIV-1 produced in human cells is much stronger than that for tRNA(Pro) incorporation into MuLV produced in murine cells, and different packaging mechanisms are used. Thus, both lysyl-tRNA synthetase and GagPol are required for tRNA(3Lys) packaging into HIV-1, but neither prolyl-tRNA synthetase nor GagPol is required for tRNA(Pro) packaging into MuLV. In this report, we show that when HIV-1 is produced in murine cells, the virus switches from an HIV-1-like incorporation of tRNA(3Lys) to an MuLV-like packaging of tRNA(Pro). The primer binding site in viral RNA remains complementary to tRNA(3Lys), resulting in a significant decrease in reverse transcription and infectivity. Reduction in tRNA(3Lys) incorporation occurs even though both murine lysyl-tRNA synthetase and HIV-1 GagPol are packaged into the HIV-1 produced in murine cells. Nevertheless, the murine cell is able to support the select incorporation of tRNA(3Lys) into another retrovirus that uses tRNA(3Lys) as a primer, the mouse mammary tumor virus.

Interactions of reverse transcriptase sequences in Pol with Gag and LysRS in the HIV-1 tRNALys3 packaging/annealing complex

During HIV-1 assembly, tRNA(Lys3), the primer for reverse transcriptase (RT) in HIV-1, is selectively packaged into the virus due to a specific interaction between Gag and lysyl-tRNA synthetase (LysRS). However, while Gag alone will incorporate LysRS, tRNA(Lys3) packaging also requires the presence of RT thumb domain sequences in GagPol. The formation of a tRNA(Lys3) packaging/annealing complex involves an interaction between Gag/GagPol/viral RNA and LysRS/tRNA(Lys), and herein, we have investigated whether the transfer of tRNA(Lys3) from LysRS to RT sequences in Pol by a currently unknown mechanism is facilitated by an interaction between LysRS and Pol. We demonstrate that, in addition to its interaction with Gag, LysRS also interacts with sequences within the connection/RNaseH domains in RT. However, cytoplasmic Gag/Pol interactions, detected by either coimmunoprecipitation or incorporation of Pol into Gag viral-like particles, were found to be insensitive to the overexpression or underexpression of LysRS, indicating that a Gag/LysRS/RT interaction is not essential for Gag/Pol interactions. Based on this and previous work, including the observation that the RT connection domain is not required for tRNA(Lys3) packaging, but is required for tRNA(Lys3) annealing, a model is proposed for a tRNA(Lys3) packaging/annealing complex in which the interaction of Gag with Pol sequences during early viral assembly facilitates the retention in budding viruses of both tRNA(Lys3) and early Pol processing intermediates, with tRNA(Lys3) annealing to viral RNA further facilitated by the LysRS/RT interaction.

HIV-1 reverse transcription initiation: a potential target for novel antivirals?

Reverse transcription is an essential step in the retroviral life cycle, as it converts the genomic RNA into DNA. In this review, we describe recent developments concerning the initiation step of this complex, multi-step reaction. During initiation of reverse transcription, a cellular tRNA primer is placed onto a complementary sequence in the viral genome, called the primer binding site or PBS. The viral enzyme reverse transcriptase (RT) recognizes this RNA-RNA complex, and catalyzes the extension of the 3' end of the tRNA primer, with the viral RNA (vRNA) acting as template. The initiation step is highly specific and most retroviruses are restricted to the use of the cognate, self-tRNA primer. Human immunodeficiency virus type 1 (HIV-1) uses the cellular tRNA(Lys,3) molecule as primer for reverse transcription. No spontaneous switches in tRNA usage by HIV-1 or other retroviruses have been described and attempts to change the identity of the tRNA primer were unsuccessful in the past. These observations indicate that the virus strongly prefers the self-primer, suggesting that a very specific mechanism for primer selection must exist. Indeed, tRNA primers are selectively packaged into virus particles, are specifically recognized by RT and are placed onto the viral RNA genome via base pairing to the PBS and other sequence motifs, thus rendering a specific initiation complex. Analysis of this critical step in the viral life cycle may result in the discovery of novel antiviral drugs in the battle against HIV/AIDS.

APOBEC3G inhibits DNA strand transfer during HIV-1 reverse transcription

Human APOBEC3G (hA3G) has been identified as an anti-HIV-1 host factor. The presence of hA3G in HIV-1 strongly inhibits the ability of the virus to produce new viral DNA upon infection. In this report, we demonstrate that the reduction of late viral DNA synthesis is due to the inhibition by hA3G of the strand transfer steps that occur during reverse transcription. Analysis of viral cDNA intermediates in vivo reveals that hA3G causes an inhibition of the minus and plus strand transfers, without having a significant impact on DNA elongation. Using an in vitro system to measure minus strand transfer similarly shows a dose-dependent reduction of strand transfer by hA3G. This inhibition of strand transfer occurs independently the editing activity of hA3G and is correlated with its ability to prevent RNaseH degradation of the template RNA.

Inhibition of tRNA₃(Lys)-primed reverse transcription by human APOBEC3G during human immunodeficiency virus type 1 replication

Cells are categorized as being permissive or nonpermissive according to their ability to produce infectious human immunodeficiency virus type 1 (HIV-1) lacking the viral protein Vif. Nonpermissive cells express the human cytidine deaminase APOBEC3G (hA3G), and Vif has been shown to bind to APOBEC3G and facilitate its degradation. Vif-negative HIV-1 virions produced in nonpermissive cells incorporate hA3G and have a severely reduced ability to produce viral DNA in newly infected cells. While it has been proposed that the reduction in DNA production is due to hA3G-facilitated deamination of cytidine, followed by DNA degradation, we provide evidence here that a decrease in the synthesis of the DNA by reverse transcriptase may account for a significant part of this reduction. During the infection of cells with Vif-negative HIV-1 produced from 293T cells transiently expressing hA3G, much of the inhibition of early (> or =50% reduction) and late (> or =95% reduction) viral DNA production, and of viral infectivity (> or =95% reduction), can occur independently of DNA deamination. The inhibition of the production of early minus-sense strong stop DNA is also correlated with a similar inability of tRNA(3)(Lys) to prime reverse transcription. A similar reduction in tRNA(3)(Lys) priming and viral infectivity is also seen in the naturally nonpermissive cell H9, albeit at significantly lower levels of hA3G expression.

A probability model predicting initiation efficiency of retroviral vectors with two primer-binding sites

Initiation of reverse transcription in retroviruses occurs at a specific point in the viral genome, called the primer-binding site (PBS). The efficiency of reverse transcription initiation is not known. We previously published a paper describing reverse transcription of the retroviral vector S-2PBS containing two PBSs. Reverse transcription of this vector results in a provirus with one of four possible structures, depending, in part, on the PBSs used to initiate reverse transcription. Using Southern blotting analyses of DNA from infected cells, we measured the relative proportions of proviruses with different structures. Although the analysis allowed us to detect multiple initiation events occurring in a single virion, the measurement of frequency of such events was not possible. In this paper, we have built a probability model, which describes the reverse transcription process and predicts the outcomes of different initiation scenarios. By fitting the predicted outcomes to the observed data, we have been able to estimate the initiation efficiency in this system as approximately 0.4 initiation per PBS. In addition, we show that even though multiple models of reverse transcription can explain the observed data, all of these models predict approximately the same initiation efficiency. This initiation efficiency is discussed in relation to general replication strategies of retroviruses.

Defective replication in human immunodeficiency virus type 1 when non-primers are used for reverse transcription

tRNA(3Lys), the primer for reverse transcriptase in human immunodeficiency virus type 1 (HIV-1), anneals to the primer binding site (PBS) in HIV-1 RNA. It has been shown that altering the PBS and U5 regions upstream of the PBS in HIV-1 so as to be complementary to sequences in tRNA(Met) or tRNA(His) will allow these tRNA species to be stably used as primers for reverse transcription. We have examined the replication of these mutant viruses in Sup-T1 cells. When Sup-T1 cells are infected by cocultivation with HIV-1-transfected 293T cells, viruses using tRNA(His) or tRNA(Met) are produced at rates that are approximately 1/10 or 1/100, respectively, of rates for wild-type virions that use tRNA(3Lys). When Sup-T1 cells are directly infected with equal amounts of these different viruses isolated from the culture supernatant of transfected 293T cells, virions using tRNA(Met) are produced at 1/100 the rate of wild-type viruses, and production of virions using tRNA(His) is not detected. Both wild-type and mutant virions selectively package tRNA(Lys) only, and examination of the ability of total viral RNA to prime reverse transcription in vitro indicates a >80% reduction in the annealing of tRNA(His) or tRNA(Met) to the mutant viral RNAs. PCR analysis of which of the three primer tRNAs is used indicates that only tRNA(3Lys) is detected as primer in wild-type virions and only tRNA(His) is detected as primer in virions containing a PBS complementary to tRNA(His), while the mutant viruses containing a PBS complementary to tRNA(Met) use both tRNA(Met) and tRNA(1,2Lys) as primer tRNAs.

Inhibition of cellular HIV-1 protease activity by lysyl-tRNA synthetase

During early assembly of human immunodeficiency virus type 1 (HIV-1), an assembly complex is formed, the components of which include genomic RNA, Gag, GagPol, tRNA(Lys), and lysyl tRNA synthetase (LysRS). Directly increasing or decreasing cellular expression of LysRS results in corresponding changes in viral infectivity and in the viral concentrations of LysRS, tRNA(Lys), and, surprisingly, reverse transcriptase (RT). Since altering the cellular expression of LysRS does not lead to a change in the incorporation of the RT precursor protein, GagPol, in protease-negative HIV-1, we propose that the altered viral content of RT resulting from alterations in cellular LysRS concentration results from the ability of LysRS to inhibit premature activation of Gag-Pol viral protease within the complex. Supporting this hypothesis, we find that increases and decreases in cellular LysRS expression are accompanied by 5-8-fold increases and 5-fold decreases, respectively, in the cytoplasmic proteolysis of Gag and GagPol to mature viral proteins. Using a novel bioluminescence resonance energy transfer assay to directly measure HIV-1 protease activity in vivo also indicates that the overexpression of LysRS in the cell reduces viral protease activity.

Cellular distribution of Lysyl-tRNA synthetase and its interaction with Gag during human immunodeficiency virus type 1 assembly

Lysyl-tRNA synthetase (LysRS) is packaged into human immunodeficiency virus type 1 (HIV-1) via its interaction with Gag, and this enzyme facilitates the selective packaging of tRNA(3)(Lys), the primer for initiating reverse transcription, into HIV-1. The Gag/LysRS interaction is detected at detergent-resistant membrane but not in membrane-free cell compartments that contain Gag and LysRS. LysRS is found (i). in the nucleus, (ii). in a cytoplasmic high-molecular-weight aminoacyl-tRNA synthetase complex (HMW aaRS complex), (iii). in mitochondria, and (iv). associated with plasma membrane. The cytoplasmic form of LysRS lacking the mitochondrial import signal was previously shown to be efficiently packaged into virions, and in this report we also show that LysRS compartments in nuclei, in the HMW aaRS complex, and at the membrane are also not required as a primary source for viral LysRS. Exogenous mutant LysRS species unable to either enter the nucleus or bind to the cell membrane are still incorporated into virions. Many HMW aaRS components are not packaged into the virion along with LysRS, and the interaction of LysRS with p38, a protein that binds tightly to LysRS in the HMW aaRS complex, is not required for the incorporation of LysRS into virions. These data indicate that newly synthesized LysRS may interact rapidly with Gag before the enzyme has the opportunity to move to the above-mentioned cellular compartments. In confirmation of this idea, we found that newly synthesized LysRS is associated with Gag after a 10-min pulse with [(35)S]cysteine/methionine. This observation is also supported by previous work indicating that the incorporation of LysRS into HIV-1 is very sensitive to the inhibition of new synthesis of LysRS.

Structural variability of the initiation complex of HIV-1 reverse transcription

HIV-1 reverse transcription is initiated from a tRNA(3)(Lys) molecule annealed to the viral RNA at the primer binding site (PBS), but the structure of the initiation complex of reverse transcription remains controversial. Here, we performed in situ structural probing, as well as in vitro structural and functional studies, of the initiation complexes formed by highly divergent isolates (MAL and NL4.3/HXB2). Our results show that the structure of the initiation complex is not conserved. In MAL, and according to sequence analysis in 14% of HIV-1 isolates, formation of the initiation complex is accompanied by complex rearrangements of the viral RNA, and extensive interactions with tRNA(3)(Lys) are required for efficient initiation of reverse transcription. In NL4.3, HXB2, and most isolates, tRNA(3)(Lys) annealing minimally affects the viral RNA structure and no interaction outside the PBS is required for optimal initiation of reverse transcription. We suggest that in MAL, extensive interactions with tRNA(3)(Lys) are required to drive the structural rearrangements generating the structural elements ultimately recognized by reverse transcriptase. In NL4.3 and HXB2, these elements are already present in the viral RNA prior to tRNA(3)(Lys) annealing, thus explaining that extensive interactions with the primer are not required. Interestingly, such interactions are required in HXB2 mutants designed to use a non-cognate tRNA as primer (tRNA(His)). In the latter case, the extended interactions are required to counteract a negative contribution associate with the alternate primer.

Ability of wild-type and mutant lysyl-tRNA synthetase to facilitate tRNA(Lys) incorporation into human immunodeficiency virus type 1

The major human tRNA(Lys) isoacceptors, tRNA1,2Lys and tRNA3Lys, are selectively packaged into human immunodeficiency virus type 1 (HIV-1) during assembly, where tRNA3Lys acts as a primer for reverse transcription. Lysyl-tRNA synthetase (LysRS) is also incorporated into HIV-1, independently of tRNA(Lys), via its interaction with Gag, and it is a strong candidate for being the signal that specifically targets tRNA(Lys) for viral incorporation. Expression of exogenous wild-type LysRS in cells results in an approximately twofold increase in the viral packaging of both LysRS and tRNA(Lys). Herein, we show that this increase in tRNA(Lys) incorporation into virions is dependent upon the ability of LysRS to bind to tRNA(Lys) but not upon its ability to aminoacylate the tRNA(Lys). COS7 cells were cotransfected with plasmids coding for both HIV-1 and either wild-type or mutant human LysRS, all of which are incorporated into virions with similar efficiency. However, N-terminally truncated LysRS, which binds poorly to tRNA(Lys), does not increase tRNA(Lys) packaging into viruses, while C-terminally truncated LysRS, which binds to but does not aminoacylate tRNA(Lys), still facilitates an increase in tRNA(Lys) packaging into virions.

Incorporation of pol into human immunodeficiency virus type 1 Gag virus-like particles occurs independently of the upstream Gag domain in Gag-pol

By using particle-associated reverse transcriptase (RT) activity as an assay for Pol incorporation into human immunodeficiency virus type 1 (HIV-1) Gag virus-like particles (VLPs), it has been found that truncated, protease-negative, Gag-Pol missing cis Gag sequences is still incorporated into Gag VLPs, albeit at significantly reduced levels (10 to 20% of the level of wild-type Gag-Pol). In this work, we have directly measured the incorporation of truncated Gag-Pol species into Gag VLPs and have found that truncated Gag-Pol that is missing all sequences upstream of RT is still incorporated into Gag VLPs at levels approximating 70% of that achieved by wild-type Gag-Pol. Neither protease nor integrase regions in Pol are required for its incorporation, implying an interaction between Gag and RT sequences in the Pol protein. While the incorporation of Gag-Pol into Gag VLPs is reduced 12-fold by the replacement of the nucleocapsid within Gag with a leucine zipper motif, this mutation does not affect Pol incorporation. However, the deletion of p6 in Gag reduces Pol incorporation into Gag VLPs four- to fivefold. Pol shows the same ability as Gag-Pol to selectively package tRNA(Lys) into Gag VLPs, and primer tRNA(3)(Lys) is found annealed to the viral genomic RNA. These data suggest that after the initial separation of Gag from Pol during cleavage of Gag-Pol by viral protease, the Pol species still retains the capacity to bind to both Gag and tRNA(3)(Lys), which may be required for Pol and tRNA(3)(Lys) to be retained in the assembling virion until budding is completed.

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

All naturally occurring human immune deficiency viruses (HIV-1) select and use tRNA(Lys,3) as the primer for reverse transcription. Studies to elucidate the mechanism of tRNA selection from the intracellular milieu have been hampered due to the difficulties in manipulating the endogenous levels of tRNA(Lys,3). We have previously described a mutant HIV-1 with a primer binding site (PBS) complementary to yeast tRNA(Phe) (psHIV-Phe) that relies on transfection of yeast tRNA(Phe) for infectivity. To more accurately recapitulate the selection process, a cDNA was designed for the intracellular expression of the yeast tRNA(Phe). Increasing amounts of the plasmid encoding tRNA(Phe) resulted in a corresponding increase in levels of yeast tRNA(Phe) in the cell. The yeast tRNA(Phe) isolated from cells transfected with the cDNA for yeast tRNA(Phe), or in the cell lines expressing yeast tRNA(Phe), were aminoacylated, indicating that the expressed yeast tRNA(Phe) was incorporated into tRNA biogenesis pathways and translation. Increasing the cytoplasmic levels of tRNA(Phe) resulted in increased encapsidation of tRNA(Phe) in viruses with a PBS complementary to tRNA(Phe) (psHIV-Phe) or tRNA(Lys,3) (wild-type HIV-1). Production of infectious psHIV-Phe was dependent on the amount of cotransfected tRNA(Phe) cDNA. Increasing amounts of plasmids encoding yeast tRNA(Phe) produced an increase of infectious psHIV-Phe that plateaued at a level lower than that from the transfection of the wild-type genome, which uses tRNA(Lys,3) as the primer for reverse transcription. Cell lines were generated that expressed yeast tRNA(Phe) at levels approximately 0.1% of that for tRNA(Lys,3). Even with this reduced level of yeast tRNA(Phe), the cell lines complemented psHIV-Phe over background levels. The results of these studies demonstrate that intracellular levels of primer tRNA can have a direct effect on HIV-1 infectivity and further support the role for PBS-tRNA complementarity in the primer selection process.

Specific inhibition of the synthesis of human lysyl-tRNA synthetase results in decreases in tRNA(Lys) incorporation, tRNA(3)(Lys) annealing to viral RNA, and viral infectivity in human immunodeficiency virus type 1

The major human tRNA(Lys) isoacceptors, and, are selectively packaged into human immunodeficiency virus type 1 (HIV-1) during assembly, where acts as a primer for reverse transcription. Lysyl-tRNA synthetase (LysRS) is also incorporated into HIV-1, independently of tRNA(Lys), via its interaction with Gag, and is a strong candidate for being the signal that specifically targets tRNA(Lys) for viral incorporation. We have transfected 293T cells with HIV-1 proviral DNA and short interfering RNA (siRNA) specific for LysRS to study the effect of diminished cellular LysRS upon tRNA(Lys) packaging, annealing to viral genomic RNA, and viral production and infectivity. At early time points after siRNA transfection, an 80% inhibition of LysRS incorporation into viruses reflects an 80% reduction of newly synthesized LysRS, rather than a more limited 20 to 25% decrease in the concentration of total cell LysRS, indicating that newly synthesized LysRS in the cell may be the main source of viral LysRS. Viruses produced from cells transfected with siRNA show reduced tRNA(Lys) packaging, reduced annealing to viral RNA, and reduced viral infectivity.