Primer selection by HIV-1 reverse transcriptase on RNA-tRNA(3Lys) and DNA-tRNA(3Lys) hybrids

History of tRNA research in strasbourg

The tRNA molecules, in addition to translating the genetic code into protein and defining the second genetic code via their aminoacylation by aminoacyl-tRNA synthetases, act in many other cellular functions and dysfunctions. This article, illustrated by personal souvenirs, covers the history of ~60 years tRNA research in Strasbourg. Typical examples point up how the work in Strasbourg was a two-way street, influenced by and at the same time influencing investigators outside of France. All along, research in Strasbourg has nurtured the structural and functional diversity of tRNA. It produced massive sequence and crystallographic data on tRNA and its partners, thereby leading to a deeper physicochemical understanding of tRNA architecture, dynamics, and identity. Moreover, it emphasized the role of nucleoside modifications and in the last two decades, highlighted tRNA idiosyncrasies in plants and organelles, together with cellular and health-focused aspects. The tRNA field benefited from a rich local academic heritage and a strong support by both university and CNRS. Its broad interlinks to the worldwide community of tRNA researchers opens to an exciting future. © 2019 IUBMB Life, 2019 © 2019 IUBMB Life, 71(8):1066-1087, 2019.

Circular RNA (circRNA) was an important bridge in the switch from the RNA world to the DNA world

The concept that life on Earth began as an RNA world has been built upon extensive experimentation demonstrating that many of the building blocks required for living cells could be synthesized in the laboratory under conditions approximating our primordial world. Many of the building blocks for life have also been found in meteorites indicating that meteors may have been a source for these molecules, or more likely, that they represent the chemical library present in most/all bodies in the universe after the big bang. Perhaps the most important support for the concept comes from the fact that some RNA species possess catalytic activity, ribozymes, and that RNA could be reverse transcribe to DNA. The thrust of numerous papers on this topic has been to explore how the available molecules on Earth, at its birth, gave rise to life as we know it today. This paper focuses more on a reverse view of the topic. The "how" molecular building blocks were synthesized is not addressed nor how the "first" RNA molecules were synthesized. We can clearly speculate on the variable environmental conditions and chemistry available on Earth billions of years ago. However, we can never truly replicate the changing conditions or know the chemical composition of Earth at the beginning of time. We can, however, confirm that over millions, perhaps billions of years the basic building blocks for life accumulated sufficiently to initiate evolution to an RNA world followed by our RNA/DNA world. Here we are attempting to take the information from our current knowledge of biology and by inference and extrapolation work backward to hypothesize biological events in the march forward from RNA to DNA. It is proposed that the primordial replicating RNA cell, the ribocyte, evolved from liposomes encompassing required reactants and products for "life" and that ribonucleopeptide complexes formed membrane pores to support bidirectional ion and molecular transport to maintain biological functions and osmolarity. Circular RNA, circRNA, is proposed as a critical stable RNA molecule that served as the genetic precursor for the switch to DNA and the replication of circRNA by a rolling circle mechanism gave rise to the RNA complexity required for the genetic functions of the cell. The replicating ribocyte would have required protein synthesis as well as RNA replication and a model for non-coded and primordial coded protein synthesis is proposed. Finally, the switch from the RNA to the DNA world would have involved the synthesis of an RNA:DNA hybrid prior to the formation of dsDNA. If the hybrid was a circular molecule that ultimately yielded a circular dsDNA molecule, it could predict that the primordial DNA cell would evolve into a bacterial cell with a single circular chromosome. One would hope that continued speculation of the origin of life will spur new directions of research that may never fully answer the questions of the past but add to our ability to regulate potentially harmful biological events in the present and in the future.

Initiation of HIV-1 reverse transcription and functional role of nucleocapsid-mediated tRNA/viral genome interactions

HIV-1 reverse transcription is initiated from a tRNA(Lys)(3) molecule annealed to the viral RNA at the primer binding site (PBS). The annealing of tRNA(Lys)(3) requires the opening of its three-dimensional structure and RNA rearrangements to form an efficient initiation complex recognized by the reverse transcriptase. This annealing is mediated by the nucleocapsid protein (NC). In this paper, we first review the actual knowledge about HIV-1 viral RNA and tRNA(Lys)(3) structures. Then, we summarize the studies explaining how NC chaperones the formation of the tRNA(Lys)(3)/PBS binary complex. Additional NMR data that investigated the NC interaction with tRNA(Lys)(3) D-loop are presented. Lastly, we focused on the additional interactions occurring between tRNA(Lys)(3) and the viral RNA and showed that they are dependent on HIV-1 isolates, i.e. the sequence and the structure of the viral RNA.

Secondary structure of the HIV reverse transcription initiation complex by NMR

Initiation of reverse transcription of genomic RNA is a key early step in replication of the human immunodeficiency virus (HIV) upon infection of a host cell. Viral reverse transcriptase initiates from a specific RNA-RNA complex formed between a host transfer RNA (tRNA(Lys)(3)) and a region at the 5' end of genomic RNA; the 3' end of the tRNA acts as a primer for reverse transcription of genomic RNA. We report here the secondary structure of the HIV genomic RNA-human tRNA(Lys)(3) initiation complex using heteronuclear nuclear magnetic resonance methods. We show that both RNAs undergo large-scale conformational changes upon complex formation. Formation of the 18-bp primer helix with the 3' end of tRNA(Lys)(3) drives large conformational rearrangements of the tRNA at the 5' end while maintaining the anticodon loop for potential loop-loop interactions. HIV RNA forms an intramolecular helix adjacent to the intermolecular primer helix. This helix, which must be broken by reverse transcription, likely acts as a kinetic block to reverse transcription.

Assembly, purification and crystallization of an active HIV-1 reverse transcriptase initiation complex

Human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) initiates DNA synthesis from the 3' end of human tRNA(Lys3). We have used cis-acting hammerhead ribozymes to produce homogeneous-length transcribed tRNA(Lys3) and have developed conditions for purifying highly structured RNAs on a modified tube-gel apparatus. Titration experiments show that this RNA can assemble into an initiation complex that contains equimolar amounts of HIV-1 RT, transcribed tRNA(Lys3), and chemically synthesized template RNA. We have purified this complex using gel-filtration chromatography and have found that it is homogeneous with respect to molecular weight, demonstrating that the initiation complex forms a single discrete species at micromolar concentrations. When this initiation complex is supplied with deoxynucleotides, essentially all of the tRNA is used as a primer by HIV-1 RT and is fully extended to the 5' end of the template. Thus, in vitro transcribed tRNA can be used efficiently as a primer by HIV-1 RT. We have also obtained crystals of the HIV-1 initiation complex that require the precisely defined ends of this in vitro transcribed tRNA(Lys3) to grow.

The HIV-1 reverse transcription (RT) process as target for RT inhibitors

Since the Human Immunodeficiency Virus Type 1 (HIV-1) was identified as the etiologic agent of the Acquired Immune Deficiency Syndrome (AIDS), the HIV-1 reverse transcriptase (RT) has been the subject of intensive study. The reverse transcription entails the transition of the single-stranded viral RNA into double-stranded proviral DNA, which is then integrated into the host chromosome. Therefore, the HIV-1 reverse transcriptase plays a pivotal role in the life cycle of the virus and is consequently an interesting target for anti-HIV drug therapy. In the first section, we describe the complex process of reverse transcription and the different activities involved in this process. We then highlight the structure-function relationship of the HIV-1 reverse transcriptase, which is of great importance for a better understanding of resistance development, a major problem in anti-AIDS therapies. Finally, we summarize the mechanisms of HIV resistance toward various RT inhibitors and the implications thereof for the current anti-HIV drug therapies.

In vitro evidence for the interaction of tRNA(3)(Lys) with U3 during the first strand transfer of HIV-1 reverse transcription

Over the course of its evolution, HIV-1 has taken maximum advantage of its tRNA(3)(Lys)primer by utilizing it in several steps of reverse transcription. Here, we have identified a conserved nonanucleotide sequence in the U3 region of HIV-1 RNA that is complementary to the anticodon stem of tRNA(3)(Lys). In order to test its possible role in the first strand transfer reaction, we applied an assay using a donor RNA corresponding to the 5'-part and an acceptor RNA spanning the 3'-part of HIV-1 RNA. In addition, we constructed two acceptor RNAs in which the nonanucleotide sequence complementary to tRNA(3)(Lys)was either substituted (S) or deleted (Delta). We used either natural tRNA(3)(Lys)or an 18 nt DNA as primer and measured the efficiency of (-) strand strong stop DNA transfer in the presence of wild-type, S or Delta acceptor RNA. Mutations in U3 did not decrease the transfer efficiency when reverse transcription was primed with the 18mer DNA. However, they significantly reduced the strand transfer efficiency in the tRNA(3)(Lys)-primed reactions. This reduction was also observed in the presence of nucleocapsid protein. These results suggest that tRNA(3)(Lys)increases (-) strand strong stop transfer by interacting with the U3 region of the genomic RNA. Sequence comparisons suggest that such long range interactions also exist in other lentiviruses.

Residues in the alphaH and alphaI helices of the HIV-1 reverse transcriptase thumb subdomain required for the specificity of RNase H-catalyzed removal of the polypurine tract primer

During retrovirus replication, reverse transcriptase (RT) must specifically interact with the polypurine tract (PPT) to generate and subsequently remove the RNA primer for plus-strand DNA synthesis. We have investigated the role that human immunodeficiency virus-1 RT residues in the alphaH and alphaI helices in the thumb subdomain play in specific RNase H cleavage at the 3'-end of the PPT; an in vitro assay modeling the primer removal step was used. Analysis of alanine-scanning mutants revealed that a subgroup exhibits an unusual phenotype in which the PPT is cleaved up to seven bases from its 3'-end. Further analysis of alphaH mutants (G262A, K263A, N265A, and W266A) with changes in residues in or near a structural motif known as the minor groove binding track showed that the RNase H activity of these mutants is more dramatically affected with PPT substrates than with non-PPT substrates. Vertical scan mutants at position 266 were all defective in specific RNase H cleavage, consistent with conservation of tryptophan at this position among lentiviral RTs. Our results indicate that residues in the thumb subdomain and the minor groove binding track in particular, are crucial for unique interactions between RT and the PPT required for correct positioning and precise RNase H cleavage.

Molecular requirements for human immunodeficiency virus type 1 plus-strand transfer: analysis in reconstituted and endogenous reverse transcription systems

We have developed a reconstituted system which models the events associated with human immunodeficiency virus type 1 (HIV-1) plus-strand transfer. These events include synthesis of plus-strand strong-stop DNA [(+) SSDNA] from a minus-strand DNA donor template covalently attached to human tRNA3Lys, tRNA primer removal, and annealing of (+) SSDNA to the minus-strand DNA acceptor template. Termination of (+) SSDNA synthesis at the methyl A (nucleotide 58) near the 3' end of tRNA3Lys reconstitutes the 18-nucleotide primer binding site (PBS). Analysis of (+) SSDNA synthesis in vitro and in HIV-1 endogenous reactions indicated another major termination site: the pseudouridine at nucleotide 55. In certain HIV-1 strains, complementarity between nucleotides 56 to 58 and the first three bases downstream of the PBS could allow all of the (+) SSDNA products to be productively transferred. Undermodification of the tRNA may be responsible for termination beyond the methyl A. In studies of tRNA removal, we find that initial cleavage of the 3' rA by RNase H is not sufficient to achieve successful strand transfer. The RNA-DNA hybrid formed by the penultimate 17 bases of tRNA still annealed to (+) SSDNA must also be destabilized. This can occur by removal of additional 3'-terminal bases by RNase H (added either in cis or trans). Alternatively, the nucleic acid chaperone activity of nucleocapsid protein (NC) can catalyze this destabilization. NC stimulates annealing of the complementary PBS sequences in (+) SSDNA and the acceptor DNA template. Reverse transcriptase also promotes annealing but to a lesser extent than NC.

Nucleoside modifications affect the structure and stability of the anticodon of tRNA(Lys,3)

NMR spectroscopy was used to determine the solution structures of RNA oligonucleotides comprising the anticodon domain of tRNA(Lys,3). The structural effects of the pseudouridine modification at position 39 were investigated and are well correlated with changes in thermodynamic parameters. The loop conformation differs from that seen in tRNA(Phe) and provides an explanation of the critical role of modification in this tRNA.

Role of post-transcriptional modifications of primer tRNALys,3 in the fidelity and efficacy of plus strand DNA transfer during HIV-1 reverse transcription

During HIV reverse transcription, (+) strand DNA synthesis is primed by an RNase H-resistant sequence, the polypurine tract, and continues as far as a 18-nt double-stranded RNA region corresponding to the 3' end of tRNALys,3 hybridized to the viral primer binding site (PBS). Before (+) strand DNA transfer, reverse transcriptase (RT) needs to unwind the double-stranded tRNA-PBS RNA in order to reverse-transcribe the 3' end of primer tRNALys,3. Since the detailed mechanism of (+) strand DNA transfer remains incompletely understood, we developed an in vitro system to closely examine this mechanism, composed of HIV 5' RNA, natural modified tRNALys,3, synthetic unmodified tRNALys,3 or oligonucleotides (RNA or DNA) complementary to the PBS, as well as the viral proteins RT and nucleocapsid protein (NCp7). Prior to (+) strand DNA transfer, RT stalls at the double-stranded tRNA-PBS RNA complex and is able to reverse-transcribe modified nucleosides of natural tRNALys,3. Modified nucleoside m1A-58 of natural tRNALys,3 is only partially effective as a stop signal, as RT can transcribe as far as the hyper-modified adenosine (ms2t6A-37) in the anticodon loop. m1A-58 is almost always transcribed into A, whereas other modified nucleosides are transcribed correctly, except for m7G-46, which is sometimes transcribed into T. In contrast, synthetic tRNALys,3, an RNA PBS primer, and a DNA PBS primer are completely reverse-transcribed. In the presence of an acceptor template, (+) strand DNA transfer is efficient only with templates containing natural tRNALys,3 or the RNA PBS primer. Sequence analysis of transfer products revealed frequent errors at the transfer site with synthetic tRNALys,3, not observed with natural tRNALys,3. Thus, modified nucleoside m1A-58, present in all retroviral tRNA primers, appears to be important for both efficacy and fidelity of (+) strand DNA transfer. We show that other factors such as the nature of the (-) PBS of the acceptor template and the RNase H activity of RT also influence the efficacy of (+) strand DNA transfer.

Stabilization of the anticodon stem-loop of tRNALys,3 by an A+-C base-pair and by pseudouridine

NMR spectroscopy was used to determine the solution structures of RNA oligonucleotides comprising the anticodon domain of tRNALys,3. The structural effects of the pseudouridine modification at position 39 were investigated and are well correlated with changes in thermodynamic parameters derived from temperature dependent UV measurements. The pseudouridine-containing hairpin is thermodynamically more stable than the unmodified hairpin by 5 degreesC, and this corresponds with increased base stacking on the 3' side of the tRNA anticodon loop. An A+38-C32 base-pair also forms at the base of the anticodon stem with an approximate pKa of 6 for A38. Formation of the A+-C base-pair increases the Tm of both pseudouridine modified and unmodified RNA hairpins by 5-6 degreesC, and decreases the DeltaG degrees for hairpin formation by 1 kcal/mol. Solution structures were determined for both psi39 and unmodified hairpins under limiting pH conditions at pH 5 and pH 7 to assess the structural effects of both psi modification and the additional A+-C base-pair on tRNALys,3 structure. The A+38-C32 base-pair strengthens the 31-39 base-pair, and induces formation of a dynamic U33-A37 base-pair that effectively reduces the normal seven nucleotide anticodon loop to a three nucleotide UUU loop. These undermodified tRNALys,3 anticodon loops are distinctly different from those seen for other tRNAs exemplified by tRNAPhe. The conformation of the tRNA loop has important implications for the role of nucleoside modification in codon-anticodon recognition and for utilization of tRNALys,3 by HIV-1 as the native reverse transcriptase primer.

Posttranscriptional modification of retroviral primers is required for late stages of DNA replication

During reverse transcription of retroviral RNA, synthesis of (-) strand DNA is primed by a cellular tRNA that anneals to an 18-nt primer binding site within the 5' long terminal repeat. For (+) strand synthesis using a (-) strand DNA template linked to the tRNA primer, only the first 18 nt of tRNA are replicated to regenerate the primer binding site, creating the (+) strand strong stop DNA intermediate and providing a 3' terminus capable of strand transfer and further elongation. On model HIV templates that approximate the (-) strand linked to natural modified or synthetic unmodified tRNA3Lys, we find that a (+) strand strong stop intermediate of the proper length is generated only on templates containing the natural, modified tRNA3Lys, suggesting that a posttranscriptional modification provides the termination signal. In the presence of a recipient template, synthesis after strand transfer occurs only from intermediates generated from templates containing modified tRNA3Lys. Reverse transcriptase from Moloney murine leukemia virus and avian myoblastosis virus shows the same requirement for a modified tRNA3Lys template. Because all retroviral tRNA primers contain the same 1-methyl-A58 modification, our results suggest that 1-methyl-A58 is generally required for termination of replication 18 nt into the tRNA sequence, generating the (+) strand intermediate, strand transfer, and subsequent synthesis of the entire (+) strand. The possibility that the host methyl transferase responsible for methylating A58 may provide a target for HIV chemotherapy is discussed.

Alanine-scanning mutations in the "primer grip" of p66 HIV-1 reverse transcriptase result in selective loss of RNA priming activity

Alanine-scanning mutants of the primer grip region of human immunodeficiency virus type 1 reverse transcriptase were tested for their ability to extend RNA and DNA versions of the polypurine tract primer, and an oligonucleotide representing the 18-nucleotide sequence at the 3' end of tRNALys3. A majority of the mutant enzymes were either completely or severely deficient in RNA priming activity, but, with only one exception, were able to efficiently extend DNA versions of the same primers. The mutant enzymes were able to bind to RNA primers, indicating that the defect in RNA priming was not simply a loss of binding activity. Mutations at positions 229, 233, and 235 dramatically reduced the amount of specific RNase H cleavage at the 3' terminus of the polypurine tract, which is required for primer removal. An alanine substitution at position 232 led to loss of cleavage specificity, although total activity was close to the wild-type level. Taken together, these results demonstrate for the first time that there are residues in human immunodeficiency virus type 1 reverse transcriptase which are specifically involved in protein-nucleic acid interactions with RNA primers.

Structural and functional evidence that initiation and elongation of HIV-1 reverse transcription are distinct processes

Retroviral reverse transcription starts with the extension of a cellular tRNA primer bound near the 5' end of the viral genomic RNA at a site called the primer binding site (PBS). Formation of the HIV-1 initiation complex between tRNA3(Lys), viral RNA and reverse transcriptase probably occurs during encapsidation of these components. tRNA3(Lys) is thought to be selectively packaged by interaction with the reverse transcriptase domain of the Pr160Gag-Pol precursor protein, then annealed to the PBS of viral RNA with the help of the nucleocapsid protein. tRNA3(Lys) and HIV-1 viral RNA form a highly-structured complex, with extended interactions between the two molecules. Two different modes of reverse transcription have been distinguished: initiation, a tRNA3(Lys)-specific and distributive mode of polymerization corresponding to the addition of the first five nucleotides, followed by elongation, a non-specific and processive mode of DNA synthesis. These two modes are reminiscent of the initiation and elongation processes previously observed with DNA-dependent RNA polymerases.