Multiparameter single-molecule fluorescence spectroscopy reveals heterogeneity of HIV-1 reverse transcriptase:primer/template complexes.

By using single-molecule multiparameter fluorescence detection, fluorescence resonance energy transfer experiments, and newly developed data analysis methods, this study demonstrates directly the existence of three structurally distinct forms of reverse transcriptase (RT):nucleic acid complexes in solution. Single-molecule multiparameter fluorescence detection also provides first information on the structure of a complex not observed by x-ray crystallography. This species did not incorporate nucleotides and is structurally distinct from the other two observed species. We determined that the nucleic acid substrate is bound at a site far removed from the nucleic acid-binding tract observed by crystallography. In contrast, the other two states are identified as being similar to the x-ray crystal structure and represent distinct enzymatically productive stages in DNA polymerization. These species differ by only a 5-A shift in the position of the nucleic acid. Addition of nucleoside triphosphate or of inorganic pyrophosphate allowed us to assign them as the educt and product state in the polymerization reaction cycle; i.e., the educt state is a complex in which the nucleic acid is positioned to allow nucleotide incorporation. The second RT:nucleic acid complex is the product state, which is formed immediately after nucleotide incorporation, but before RT translates to the next nucleotide.

Requirements for minus-strand transfer catalyzed by Rous sarcoma virus reverse transcriptase.

We have examined the specific minus-strand transfer reactions that occur after the synthesis of minus strong-stop DNA and nonspecific strand switching on homopolymeric poly(rA) templates with different types of Rous sarcoma virus (RSV) reverse transcriptases. Three different types of reverse transcriptases can be isolated from virions of RSV: heterodimeric alphabeta and homodimeric alpha and beta. The mechanism of minus-strand transfer was examined using a model primer-template substrate corresponding to the 5'- and 3'-terminal RNA regions of the RSV genome. The results reveal that the RNase H activity of RSV reverse transcriptases is required for minus-strand transfer. Less than 2% of strand transfer of the extended product is detectable with RNase H-deficient enzymes. We could show that the alpha homodimer lacking the integrase domain can perform strand transfer almost as efficiently as the alphabeta and alphaPol heterodimers. In contrast, the activities of beta and Pol for minus-strand transfer are reduced. Furthermore, a two- to fivefold increase in minus-strand transfer activities was observed in the presence of human immunodeficiency virus type 1 nucleocapsid protein.

Temperature-dependent equilibrium between the open and closed conformation of the p66 subunit of HIV-1 reverse transcriptase revealed by site-directed spin labelling.

X-ray crystallographic studies of human immunodeficiency virus type 1 reverse transcriptase complexed with or without substrates or inhibitors show that the heterodimeric enzyme adopts distinct conformations that differ in the orientation of the so-called thumb subdomain in the large subunit. Site-directed spin labelling of mutated residue positions W24C and K287C is applied here to determine the distances between the fingers and thumb subdomains of liganded and unliganded RT in solution. The inter-spin distances of a DNA/DNA and a pseudoknot RNA complexed reverse transcriptase in solution was found to agree with the respective crystal data of the open and closed conformations. For the unliganded reverse transcriptase a temperature-dependent equilibrium between these two states was observed. The fraction of the closed conformation decreased from 95% at 313 K to 65% at 273 K. The spectral separation between the two structures was facilitated by the use of a perdeuterated ([15)N]nitroxide methane-thiosulfonate spin label.

Homodimeric reverse transcriptases from rous sarcoma virus mutated within the polymerase or RNase H active site of one subunit are active.

Heterodimeric reverse transcriptase (RT) alphabeta from Rous sarcoma virus (RSV) possesses an asymmetric subunit organization with the polymerase and RNase H active sites localized in the alpha subunit. To determine whether homodimeric RSV RTs alpha (63 kDa) or beta (95 kDa) assume alpha subunit organization similar to that of the heterodimer, an essential aspartic acid residue was mutated in the active site of either the polymerase (Asp181 > Asn) or the RNase H (Asp505 > Asn). Homodimeric alpha or beta RT consisting of one wild-type and one mutated subunit exhibit polymerase or RNase H activity, respectively, whereas the corresponding doubly mutated enzymes are inactive, indicating that the catalytic sites of the polymerase and RNase H domains are formed by only one subunit of the homodimer.

Asymmetric subunit organization of heterodimeric Rous sarcoma virus reverse transcriptase alphabeta: localization of the polymerase and RNase H active sites in the alpha subunit.

The genes encoding the alpha (63-kDa) and beta (95-kDa) subunits of Rous sarcoma virus (RSV) reverse transcriptase (RT) or the entire Pol polypeptide (99 kDa) were mutated in the conserved aspartic acid residue Asp 181 of the polymerase active site (YMDD) or in the conserved Asp 505 residue of the RNase H active site. We have analyzed heterodimeric recombinant RSV alphabeta and alphaPol RTs within which one subunit was selectively mutated. When alphabeta heterodimers contained the Asp 181-->Asn mutation in their beta subunits, about 42% of the wild-type polymerase activity was detected, whereas when the heterodimers contained the same mutation in their alpha subunits, only 7.5% of the wild-type polymerase activity was detected. Similar results were obtained when the conserved Asp 505 residue of the RNase H active site was mutated to Asn. RNase H activity was clearly detectable in alphabeta heterodimers mutated in the beta subunit but was lost when the mutation was present in the alpha subunit. In summary, our data imply that the polymerase and RNase H active sites are located in the alpha subunit of the heterodimeric RSV RT alphabeta.

Refined model for primer/template binding by HIV-1 reverse transcriptase: pre-steady-state kinetic analyses of primer/template binding and nucleotide incorporation events distinguish between different binding modes depending on the nature of the nucleic acid substrate.

The kinetic mechanism of nucleic acid substrate binding and nucleotide incorporation by human immunodeficiency virus type 1 reverse transcriptase (HIV-1 RT) was analysed using synthetic DNA/DNA and DNA/RNA primer/templates (p/t) without predicted secondary structures in the single-stranded region. Determination of the pre-steady-state kinetics of p/t binding by a combination of stopped-flow and quench flow methods indicate a branched binding mechanism for the HIV-1 RT/nucleic acid interaction. Analysis of p/t-RT association by stopped-flow measurements suggest a three-step binding mode with an initial second-order step followed by two isomerisation steps with rates of about 6 s(-1)and 0.5 s(-1), respectively. Determination of the rate-limiting step of the association process via single turnover, single nucleotide incorporation analysis by quench flow measurements revealed two binding events (the initial second-order step cannot be detected with this experimental set-up) with rates of 4 - 7 s(-1)and 0.4 - 0. 7 s(-1), respectively, indicating that both binding events exist in parallel. Thorough pre-steady-state analysis of single turnover, single nucleotide incorporation kinetics showed that dNTP incorporation occurs with a biphasic exponential burst followed by a linear phase. The exponential burst consists of a fast phase with rates of 20 - 60 s(-1) and a slow phase with rates of 0.5 - 2 s(-1), respectively. The relative distribution of these two burst amplitudes differs significantly depending upon which substrate is used. The DNA/RNA-RT complex shows primarily fast incorporation (>80 %) whereas less than 45 % of the DNA/DNA-RT complex incorporate dNTP rapidly. The same relative distribution of amplitudes concerning the two substrates is also found for the association process of RT and p/t. Analysis of dNTP incorporation of the preformed RT-p/t complex in the presence of a nucleic acid competitor shows no effect on the biphasic burst amplitude, however the linear phase disappears. Here, a refined model of the mechanism of RT-p/t binding is presented which is based on the suggestion that two different RT-p/t complexes are formed, i.e. a productive enzyme/substrate complex which is capable of nucleotide incorporation and a non-productive complex which has to undergo an isomerisation before dNTP incorporation can occur. In addition, binding of RT to its substrate can lead to a dead end complex that is not capable of dNTP incorporation.

Soluble Rous sarcoma virus reverse transcriptases alpha, alphabeta, and beta purified from insect cells are processive DNA polymerases that lack an RNase H 3' --> 5' directed processing activity.

Reverse transcriptase (RT) isolated from Rous sarcoma virus (RSV) consists of heterodimeric RTalphabeta, RTalpha, and RTbeta. The alpha subunit (63 kDa) contains an N-terminal polymerase and a C-terminal RNase H domain. The N terminus of beta (95 kDa) corresponds to alpha with the integrase domain attached to the C terminus (32 kDa). We have constructed baculoviruses expressing the genes for alpha or beta or the entire pol (99 kDa). Infection of insect cells with recombinant virus yielded highly active and soluble RSV RT enzymes that could be purified to >90% homogeneity. HPLC gel filtration showed that alpha is a dimeric enzyme that can be partially monomerized upon the addition of 45% Me(2)SO. DNA synthesis on DNA-DNA and DNA-RNA primer-templates in the presence of competitor substrates revealed that alphabeta and beta as well as alpha are processive polymerases. However, the affinity of beta and alphabeta for primer-template substrates appears to be higher than that of alpha. All RSV enzymes investigated have the potential to displace RNA-RNA duplexes more efficiently than human immunodeficiency virus type 1 RT. Unlike human immunodeficiency virus type 1 RT, RSV RTs can catalyze an initial RNase H endonucleolytic cleavage of the RNA template but not a 3' --> 5' directed processing activity.

Pre-steady-state kinetic characterization of RNA-primed initiation of transcription by HIV-1 reverse transcriptase and analysis of the transition to a processive DNA-primed polymerization mode.

Single-turnover and equilibrium measurements were carried out to determine the basis of the apparently slow, nonprocessive polymerization reaction catalyzed by HIV-1 reverse transcriptase (RT) during transcription initiation, when both the primer and template are composed of RNA. Comparison of the binding and kinetic parameters of a 20-mer, all-RNA primer/35-mer template substrate to one identical in sequence but composed of a 20-mer, all-DNA primer/35-mer RNA template reveals striking differences. Equilibrium titrations yielded a dissociation constant (Kd) >200 nM for the RNA/RNA-RT complex which is at least 200-fold higher than that of the DNA/RNA-substrate (Kd approximately 1 nM). The affinity of the RT-RNA/RNA complex for dTTP was found to be at least 500 times lower (Kd approximately 3.4 mM) than that of the RT-DNA/RNA complex (Kd approximately 6.6 microM). The single-turnover dNTP incorporation time course using the RNA-primer substrate, the DNA-primer substrate, or a series of RNA-primer substrates preextended with one to eight deoxynucleotides showed that dNTP incorporation occurs with a biphasic exponential burst of +1 extension product, followed by a linear phase. At least three different RT-bound forms of the p/ts exist: a fast, kinetically competent form (single-turnover rate approximately 10-50 s-1); a slow form (rate approximately 0.3-1 s-1); and a form that is dead-end (no turnover). The studies further revealed that a switch to a fast, kinetically competent p/t occurs after six dNTPs are incorporated into the RNA primer, with the switch being defined as the transition from a minority to a majority of the p/t bound in the optimal manner.

Analysis of the polymerization kinetics of homodimeric EIAV p51/51 reverse transcriptase implies the formation of a polymerase active site identical to heterodimeric EIAV p66/51 reverse transcriptase.

Homodimeric EIAV p51/51 and heterodimeric EIAV p66/51 reverse transcriptase were purified in order to compare the different modes of DNA synthesis supported by the enzymes. Analysis of the dimerization behavior of the EIAV enzymes indicates that the dimer stability of EIAV reverse transcriptase enzymes is higher than that of their HIV-1 reverse transcriptase counterparts. EIAV p51/51 polymerizes DNA distributively whereas DNA synthesis by EIAV p66/51 is processive. Steady-state and pre-steady-state kinetic analyses of primer/template binding and nucleotide incorporation were performed with both enzymes to determine the reasons for the different polymerization behavior. Equilibrium fluorescence titrations demonstrated that the Kd values of EIAV p51/51 for binding of DNA/DNA and DNA/RNA substrates are increased 10-fold and 28-fold, respectively, as compared to EIAV p66/51. Stopped-flow measurements with DNA/DNA show that the increase in the Kd is in part due to a 17. 4-fold higher dissociation rate constant (k-1) for EIAV p51/51. Additionally, with EIAV p51/51, kdiss is increased 7-fold for DNA/DNA and 14-fold for DNA/RNA primer/template substrates, respectively. The lack of the RNase H domain in EIAV p51/51 leads to differences in the pre-steady-state kinetics of nucleotide incorporation on DNA/DNA and DNA/RNA templates. The burst of both enzymes is composed of two phases for both substrates, and the values for the corresponding pre-steady-state burst rates, kpol1 and kpol2, are similar for both enzymes, implying the formation of identical polymerase active sites. However, the amplitudes of the two phases differ with DNA/DNA templates, indicating a different distribution between two states varying greatly in their kinetic competence.

Single-step kinetics of HIV-1 reverse transcriptase mutants responsible for virus resistance to nucleoside inhibitors zidovudine and 3-TC.

Two mutants of HIV-1 reverse transcriptase (RT) associated with high-level resistance of the virus to AZT (RT-AZT: D67N, K70R, T215Y, K219Q, and M41L) or 3-TC (RT-3TC: M184V) were expressed in Escherichia coli and purified. None of these mutants showed significant changes in the affinity and kinetics of binding to a DNA/DNA primer/template. RT-AZT was investigated in detail with respect to its kinetics of incorporation of nucleotides. No change in the relative rates of TMP and AZTMP incorporation could be detected for RT-AZT with respect to wild type RT. These results imply that there is no increased discrimination against AZTTP in the mutant. This was found for DNA/DNA and DNA/RNA primer/template. Additionally, rapid kinetics of incorporation of 3'-amino-3'-deoxythymidine 5'-monophosphate (a possible metabolite of AZT) were investigated and compared with TMP incorporation, but no difference in its relative rates of incorporation between wild type RT and RT-AZT was detected. In contrast, the already very slow rate of incorporation of 3-TCMP seen with wild type enzyme was drastically reduced (by a factor of 23 and 36 with DNA/DNA primer/template and DNA/RNA primer/template, respectively) for RT-3TC, showing a clear correlation between in vitro and in vivo effects. The affinity of 3-TCTP to the RT-3TC-primer/template complex was not affected by the mutation M184V. A 1.6-fold cross-resistance to ddATP, the converted form of the prodrug ddI, could also be shown for RT-3TC, but no cross-resistance to ddCTP was detected. Additionally, rapid kinetics of AZTMP incorporation by RT-3TC were investigated. There was an indication of a slightly higher rate of incorporation of AZTMP by RT-3TC than wild type RT.

Kinetic analysis of four HIV-1 reverse transcriptase enzymes mutated in the primer grip region of p66. Implications for DNA synthesis and dimerization.

The highly conserved primer grip region in the p66 subunit of HIV-1 reverse transcriptase (RT) is formed by the beta12-beta13 hairpin (residues 227-235). It has been proposed to play a role in aligning the 3'-OH end of the primer in a position for nucleophilic attack on an incoming dNTP. To analyze the importance of the primer grip for RT function, mutant RTs were used that contain single alanine substitutions of residues Trp229, Met230, Gly231, and Tyr232 in the p66 subunit of the heterodimeric p66/51 enzyme. Steady-state and pre-steady-state kinetic analyses of the enzymes were performed. All mutant enzymes revealed reduced polymerase activity. Mutation of Y232A showed the smallest effect on polymerase function. Equilibrium fluorescence titrations demonstrated that the affinity of the mutants for tRNA was only slightly affected. However, the affinity for primer-template DNA was reduced 27-fold for mutant p66(W229A)/51 and 23-fold for mutant p66(G231A)/51, and the maximal pre-steady-state rate of nucleotide incorporation, kpol, was reduced 27-fold for p66(W229A)/51 and 70-fold for p66(G231A)/51, respectively. Mutant p66(M230A)/51 revealed no reduced affinity for primer-template but showed a 71-fold reduced affinity for dTTP. Additionally, the mutations Trp229 and Gly231 affected the stability of the RT heterodimer.

Initiation of (-) strand DNA synthesis from tRNA(3Lys) on lentiviral RNAs: implications of specific HIV-1 RNA-tRNA(3Lys) interactions inhibiting primer utilization by retroviral reverse transcriptases.

Initiation of minus (-) strand DNA synthesis was examined on templates containing R, U5, and primer-binding site regions of the human immunodeficiency virus type 1 (HIV-1), feline immunodeficiency virus (FIV), and equine infectious anemia virus (EIAV) genomic RNA. DNA synthesis was initiated from (i) an oligoribonucleotide complementary to the primer-binding sites, (ii) synthetic tRNA(3Lys), and (iii) natural tRNA(3Lys), by the reverse transcriptases of HIV-1, FIV, EIAV, simian immunodeficiency virus, HIV type 2 (HIV-2), Moloney murine leukemia virus, and avian myeloblastosis virus. All enzymes used an oligonucleotide on wild-type HIV-1 RNA, whereas only a limited number initiated (-) strand DNA synthesis from either tRNA(3Lys). In contrast, all enzymes supported efficient tRNA(3Lys)-primed (-) strand DNA synthesis on the genomes of FIV and EIAV. This may be in part attributable to the observation that the U5-inverted repeat stem-loop of the EIAV and FIV genomes lacks an A-rich loop shown with HIV-1 to interact with the U-rich tRNA anticodon loop. Deletion of this loop in HIV-1 RNA, or disrupting a critical loop-loop complex by tRNA(3Lys) extended by 9 nt, restored synthesis of HIV-1 (-) strand DNA from primer tRNA(3Lys) by all enzymes. Thus, divergent evolution of lentiviruses may have resulted in different mechanisms to use the same host tRNA for initiation of reverse transcription.

Involvement of C-terminal structural elements of equine infectious anemia virus reverse transcriptase in DNA polymerase and ribonuclease H activities.

In order to investigate the modes of DNA synthesis supported by the 66 and 51 kDa subunits of equine infectious anemia virus reverse transcriptase (EIAV RT), recombinant p66 polypeptides containing a modified ribonuclease H (RNase H) domain were purified and evaluated. Defined heteropolymeric template-primer combinations and high-resolution gel electrophoresis provided a qualitative evaluation of DNA polymerase and RNase H activities, while DNase I footprinting revealed features of replication complexes containing the truncated enzymes. Removal of alpha-helix E' and the conserved beta 5'-alphaE' "His-loop" in p66delta20 RT uncouples the RNase H activities, alters affinity for template-primer and dictates how the replicating enzyme responds to secondary structure on both DNA and RNA templates. Despite these alterations, DNase I footprinting shows no major difference in the overall structure of DNA-directed DNA synthesis complexes. In contrast, removing 47 C-terminal residues, which includes alpha-helix D', beta-strand 5' and alpha-Helix E', yields an enzyme with distributive DNA polymerase properties closely resembling the purified p51 subunit.

Evaluation of human immunodeficiency virus type 1 reverse transcriptase primer tRNA binding by fluorescence spectroscopy: specificity and comparison to primer/template binding.

A host cell-derived tRNA3Lys molecule is utilized by human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) to prime DNA synthesis from the viral RNA genome. We performed fluorescence titration experiments to characterize the interaction between RT and its natural primer, tRNA3Lys, and to address RT's putative role in the required and specific packaging of tRNA3Lys into the budding virus. Titration of RT with tRNA3Lys resulted in a 30% maximal quenching of RT tryptophan fluorescence, from which a dissociation constant (Kd) of 57.6 +/- 7.5 nM was derived. Titration of RT with Escherichia coli tRNA2Glu, E. coli tRNA2Tyr, E. coli tRNALys, yeast tRNAPhe, or in vitro-synthesized human tRNA3Lys (no base modifications) resulted in similar fluorescence changes and Kd values as obtained for the natural tRNA3Lys. The specific interaction between RT and tRNA3Lys during viral assembly suggested by previous in vivo studies is therefore not present in the fully processed, in vitro form of RT. Other factors during viral assembly must therefore cooperate in the packaging of tRNA3Lys. The nonspecific and ionic strength dependent RT-tRNA interaction detected in the present studies suggests that the overall shape and charges of tRNA constitute recognition features for RT binding. The fluorescence of the wyebutine base contained on the anticodon loop of yeast tRNAPhe was found to increase upon RT binding, supporting speculation that RT interacts with the anticodon loop of tRNA. The individual tRNAs also displaced a fluorescent DNA primer/template (p/t) substrate from RT, indicating overlapping tRNA and p/t binding sites. Cubic fit evaluation of the displacement titrations allowed further assessment of the affinities of the two competing ligands. The presence of both overlapping and separate p/t and tRNA binding regions on RT was tested by examination of the affinity of a possible RT bisubstrate type inhibitor, containing motifs proposed to be essential for both tRNA and p/t binding. Reverse transcriptase was found to bind to the mutant tRNA 10-fold more tightly than to the unaltered tRNA (Kd = 4.5 +/- 1.0 and 44.6 +/- 6.6 nM, respectively). Further analyses revealed that the tighter affinity is probably due to a preferred p/t binding mode and not to one expected if separate tRNA and p/t binding regions are accessed simultaneously by the same molecule.

An expanded model of replicating human immunodeficiency virus reverse transcriptase.

Replication complexes containing wild-type and RNase H-deficient p66/p51 human immunodeficiency virus type 1 reverse transcriptase (HIV-1 RT) were analyzed by DNase I and S1 footprinting. While crystallography and chemical footprinting data demonstrate that 15-18 bases of primer and template occupy the DNA polymerase and RNase H active centers, enzymatic footprinting suggests that a larger portion of substrate is encompassed by the replicating enzyme. Independent of the position of DNA synthesis arrest, template nucleotides +7 to -23 and primer nucleotides -1 to -25 are nuclease resistant. On both DNA strands, position -20 remains accessible to DNase I cleavage, suggestive of an alteration in nucleic acid structure between exiting the RNase H catalytic center and leaving the C-terminal p66 domain. A model of HIV-1 RT containing an extended single-stranded template and duplex region was constructed on the basis of the structure of an RT/DNA complex. Mapping of footprint data onto this model shows consistency between biochemical and structural data, implicating a contribution from domains proximal to the catalytic centers.

Molecular analysis of the phosphoenolpyruvate-dependent L-sorbose: phosphotransferase system from Klebsiella pneumoniae and of its multidomain structure.

We have cloned a 3.4 kb DNA fragment from the chromosome of Klebsiella pneumoniae that codes for a phosphoenolpyruvate-dependent L-sorbose: phosphotransferase system (PTS). The cloned fragment was sequenced and four open reading frames coding for 135 (sorF), 164 (sorB), 266 (sorA) and 274 (sorM) amino acids, respectively, were found. The corresponding proteins could be detected in a T7 overexpression system, which yielded molecular masses of about 14,000 for SorF, 19,000 for SorB, 25,000 for SorA and 27,000 for SorM. SorF and SorB have all the characteristics of soluble and intracellular proteins in accordance with their functions as EIIASor and EIIBSor domains of the L-sorbose PTS. SorA and SorM, by contrast, are strongly hydrophobic, membrane-bound proteins with two to five putative transmembrane helices that alternate with a series of hydrophilic loops. They correspond to domains EIICSor and EIIDSor. The four proteins of the L-sorbose PTS resemble closely (27%-60%) the four subunits of a D-fructose PTS (EIIALev, EIIBLev, EIICLev, and EIIDLev) from Bacillus subtilis and the three subunits of the D-mannose PTS (EIIA,BMan, EIICMan, and EIIDMan) from Escherichia coli K-12. The three systems constitute a new PTS family, and sequence comparisons revealed highly conserved structures for the membrane-bound proteins. A consensus sequence for the membrane proteins was used to postulate a model for their integration into the membrane.

Footprint analysis of replicating murine leukemia virus reverse transcriptase.

Replication complexes that contained either murine leukemia virus reverse transcriptase (MLV RT) or a variant reverse transcriptase without a ribonuclease (RNase) H domain (delta RH MLV RT) were visualized by enzymatic footprinting. Wild-type MLV RT protected template nucleotides +6 to -27, and primer nucleotides -1 to -26 of primers that had first been extended by one or four nucleotides. Although it catalyzed DNA synthesis, delta RH MLV RT stably bound template-primer only under conditions of reduced ionic strength and protected the duplex portion only as far as position -15. Despite altered hydrolysis profiles, both enzymes covered primarily the template-primer duplex, contradicting recent predictions based on the structure of rat DNA polymerase beta.

Mutating the "primer grip" of p66 HIV-1 reverse transcriptase implicates tryptophan-229 in template-primer utilization.

"BcgI cassette" mutagenesis was used to prepare variants of p66 human immunodeficiency virus (HIV)-1 reverse transcriptase with amino acid substitutions between residues Glu224 and Trp229. Mutant polypeptides were reconstituted in vitro with wild type p51 to generate the "selectively mutated" heterodimer series p66(224A)/p51-p66(229A)/p51. Purified enzymes were characterized with respect to dimerization, DNA polymerase, RNase H, and tRNA(Lys-3) binding. The combined analyses indicate that while alteration of p66 residues Glu224-Leu228 has minimal consequences, the DNA polymerase activities of mutant p66(229A)/p51 are impaired. DNase I footprinting illustrates that this mutant does not form a stable replication complex with a model template-primer. In vivo studies indicate that the equivalent mutation eliminates viral infectivity, suggesting a contribution of Trp229 toward architecture of the p66 primer grip.

Alternative modes of polymerization distinguish the subunits of equine infectious anemia virus reverse transcriptase.

A comparative study of recombinant 51- and 66-kDa subunits comprising equine infectious anemia virus reverse transcriptase (EIAV RT) is reported. Both polypeptides sedimented as stable homodimers (molecular mass, 102 and 132 kDa, respectively) when analyzed by rate sedimentation through glycerol gradients. Consistent with their dimer composition, each preparation displayed considerable levels of both RNA- and DNA-dependent DNA polymerase activity on different homopolymeric template/primer combinations. However, a detailed analysis of the polymerization products indicated qualitative differences. Whereas p66 EIAV RT proceeded essentially unimpaired along both RNA and DNA templates, p51-catalyzed DNA synthesis was interrupted close to or in the immediate vicinity of the primer. A series of "programmed" 2-step polymerization reactions suggests that p51 EIAV RT enters an abortive mode of polymerization. Duplication of this observation with p51 human immunodeficiency virus-1 RT, together with recent observations from murine RT, suggests that lack of a ribonuclease H domain and loss of contact with the nascent product from the polymerase active center have profound consequences on the mode of polymerization.

Modulation of HIV-1 reverse transcriptase function in "selectively deleted" p66/p51 heterodimers.

A contribution of the 51-kDa subunit of human immunodeficiency virus type-1 reverse transcriptase to activities of the parental heterodimer (p66/p51) was assessed in "selectively deleted" heterodimers whose p51 component contained C-terminal truncations of 13, 19, or 25 residues. Analyses included (i) efficiency of reconstitution into heterodimer, (ii) retention of polymerase and ribonuclease H (RNase H) function, and (iii) interaction with the HIV replication primer, tRNA(Lys,3). Our data suggest that these features of heterodimer reverse transcriptase can be modulated by the extent of the C-terminal p51 deletion. Severely impaired tRNA binding in a selectively deleted heterodimer whose 51-kDa subunit lacks 13 residues, despite retention of enzymatic functions, strengthens arguments for p51 involvement in tRNA binding.