Template and target-site recognition by human LINE-1 in retrotransposition.

The long interspersed element-1 (LINE-1, hereafter L1) retrotransposon has generated nearly one-third of the human genome and serves as an active source of genetic diversity and human disease1. L1 spreads through a mechanism termed target-primed reverse transcription, in which the encoded enzyme (ORF2p) nicks the target DNA to prime reverse transcription of its own or non-self RNAs2. Here we purified full-length L1 ORF2p and biochemically reconstituted robust target-primed reverse transcription with template RNA and target-site DNA. We report cryo-electron microscopy structures of the complete human L1 ORF2p bound to structured template RNAs and initiating cDNA synthesis. The template polyadenosine tract is recognized in a sequence-specific manner by five distinct domains. Among them, an RNA-binding domain bends the template backbone to allow engagement of an RNA hairpin stem with the L1 ORF2p C-terminal segment. Moreover, structure and biochemical reconstitutions demonstrate an unexpected target-site requirement: L1 ORF2p relies on upstream single-stranded DNA to position the adjacent duplex in the endonuclease active site for nicking of the longer DNA strand, with a single nick generating a staggered DNA break. Our research provides insights into the mechanism of ongoing transposition in the human genome and informs the engineering of retrotransposon proteins for gene therapy.

Investigation by atomic force microscopy of the structure of Ty3 retrotransposon particles.

Ty3, a member of the Metaviridiae family of long-terminal-repeat retrotransposons found in Saccharomyces cerevisiae, encodes homologs of retroviral Gag and Gag-Pol proteins, which, together with genomic RNA, assemble into virus-like particles (VLPs) that undergo processing and reverse transcription. The Ty3 structural proteins, capsid and nucleocapsid, contain major homology and nucleocapsid motifs similar to retrovirus capsid and nucleocapsid proteins, but Ty3 lacks a matrix-like structural domain amino terminal to capsid. Mass spectrometry analysis of Ty3 Gag3 processing products defined an acetylated Ser residue as the amino terminus of Gag3/p34, p27, and CA/p24 species and supported a model where p34 and p27 occur in phosphorylated forms. Using atomic force microscopy, VLPs were imaged from cells producing wild-type and protease and reverse transcriptase mutant Ty3. Wild-type VLPs were found to have a broad range of diameters, but the majority, if not all of the particles, exhibited arrangements of capsomeres on their surfaces which were consistent with icosahedral symmetry. Wild-type particles were in the range of 25 to 52 nm in diameter, with particles in the 42- to 52-nm diameter range consistent with T=7 symmetry. Both classes of mutant VLPs fell into a narrower range of 44 to 53 nm in diameter and appeared to be consistent with T=7 icosahedral symmetry. The smaller particles in the wild-type population likely correspond to VLPs that have progressed to reverse transcription or later stages, which do not occur in the protease and reverse transcriptase mutants. Ty3 VLPs did not undergo major external rearrangements during proteolytic maturation.

Structure of the binding site for nonnucleoside inhibitors of the reverse transcriptase of human immunodeficiency virus type 1.

The dipyridodiazepinone Nevirapine is a potent and highly specific inhibitor of the reverse transcriptase (RT) from human immunodeficiency virus type 1 (HIV-1). It is a member of an important class of nonnucleoside drugs that appear to share part or all of the same binding site on the enzyme but are susceptible to a variety of spontaneous drug-resistance mutations. The co-crystal-structure of HIV-1 RT and Nevirapine has been solved previously at 3.5-A resolution and now is partially refined against data extending to 2.9-A spacing. The drug is bound in a hydrophobic pocket and in contact with some 38 protein atoms from the p66 palm and thumb subdomains. Most, but not all, nonnucleoside drug-resistance mutations map to residues in close contact with Nevirapine. The major effects of these mutations are to introduce steric clashes with the drug molecule or to remove favorable protein-drug contacts. Additionally, four residues (Phe-227, Trp-229, Leu-234, and Tyr-319) in contact with Nevirapine have not been selected as sites of drug-resistance mutations, implying that there may be limitations on the number and types of resistance mutations that yield viable virus. Strategies of inhibitor design that target interactions with these conserved residues may yield drugs that are less vulnerable to escape mutations.

A comparison of the conformations of the 5'-triphosphates of zidovudine (AZT) and thymidine bound to HIV-1 reverse transcriptase.

Nuclear Overhauser effect experiments were performed at 500 MHz to determine the conformations of AZTTP and dTTP when bound to HIV-1 reverse transcriptase. The conformations of both ligands were found to be similar in the bound state. The orientation of the glycosidic angle is anti (chi = -120 degrees +/- 12 for AZTTP and -110 degrees +/- 12 for dTTP), gamma is +sc and the pucker of the 3'-azido-2',3'-dideoxy- and 2'-deoxyribose rings is predominantly C4' exo (P = 60 degrees +/- 10 for AZTTP and 55 degrees +/- 8 for dTTP). These results indicate that the unusual C4'endo/C3'exo pucker (P = 215 degrees) reported for the dideoxyribose ring of AZT in the solid state does not play a role in the interaction of HIV-1 reverse transcriptase with AZTTP.

Direct observation of reverse transcriptases by scanning tunneling microscopy.

First images on a nanometer scale of reverse transcriptases (RT) of the human immunodeficiency virus (HIV-1) and of the Moloney murine leukemia virus (MuLV) obtained by scanning tunneling microscopy (STM) are reported. The common feature of the observed molecules is a ring-type or horseshoe shape with hole diameters of approximately 30 A. The STM images are compared with high resolution transmission electron microscopy (TEM) and existing structure predictions. The similarities of the structural data obtained by STM and TEM and their agreement with the structure prediction for the RT of HIV-1 shows the principal possibility to image such biomolecules by STM.

Interaction of tRNALys with the p66/p66 form of HIV-1 reverse transcriptase stimulates DNA polymerase and ribonuclease H activities.

The precursor homodimeric p66/p66 form of human immunodeficiency virus type-1 reverse transcriptase (HIV-1 RT) possesses the DNA polymerase and RNase H activities involved in the synthesis of the double-stranded provirus DNA. Reverse transcription is initiated from tRNALys in the case of HIV-1. The present study confirmed that interactions between HIV-1 RT and tRNALys induce protein conformational changes and demonstrated that these interactions stimulate the enzymatic activities associated with the p66 subunit. Thus, the p66/p66 form of the enzyme is strongly stimulated in both DNA polymerase and RNase H activities. Preincubation of the enzyme with tRNA is an obligatory step to obtain the stimulatory effect. The affinity of template, primer, or substrate for RT p66/p66 did not change when the enzyme was preincubated with tRNALys at stimulatory concentrations; the interaction of tRNA with p66/p66 has an effect only on the maximal rate of polymerization. It is further shown that the RNase H domain of RT is much more accessible to protease attack than the DNA polymerase active site.

Crystal structure of the ribonuclease H domain of HIV-1 reverse transcriptase.

The crystal structure of the ribonuclease (RNase) H domain of HIV-1 reverse transcriptase (RT) has been determined at a resolution of 2.4 A and refined to a crystallographic R factor of 0.20. The protein folds into a five-stranded mixed beta sheet flanked by an asymmetric distribution of four alpha helices. Two divalent metal cations bind in the active site surrounded by a cluster of four conserved acidic amino acid residues. The overall structure is similar in most respects to the RNase H from Escherichia coli. Structural features characteristic of the retroviral protein suggest how it may interface with the DNA polymerase domain of p66 in the mature RT heterodimer. These features also offer insights into why the isolated RNase H domain is catalytically inactive but when combined in vitro with the isolated p51 domain of RT RNase H activity can be reconstituted. Surprisingly, the peptide bond cleaved by HIV-1 protease near the polymerase-RNase H junction of p66 is completely inaccessible to solvent in the structure reported here. This suggests that the homodimeric p66-p66 precursor of mature RT is asymmetric with one of the two RNase H domains at least partially unfolded.