Viruses must overcome diverse intracellular defense mechanisms to establish infection. The Vif (virion infectivity factor) protein of human immunodeficiency virus 1 (HIV-1) acts by overcoming the antiviral activity of APOBEC3G (CEM15), a cytidine deaminase that induces G to A hypermutation in newly synthesized viral DNA. In the absence of Vif, APOBEC3G incorporation into virions renders HIV-1 non-infectious. We report here that Vif counteracts the antiviral activity of APOBEC3G by targeting it for destruction by the ubiquitin-proteasome pathway. Vif forms a complex with APOBEC3G and enhances APOBEC3G ubiquitination, resulting in reduced steady-state APOBEC3G levels and a decrease in protein half-life. Furthermore, Vif-dependent degradation of APOBEC3G is blocked by proteasome inhibitors or ubiquitin mutant K48R. A mutation of highly conserved cysteines or the deletion of a conserved SLQ(Y/F)LA motif in Vif results in mutants that fail to induce APOBEC3G degradation and produce non-infectious HIV-1; however, mutations of conserved phosphorylation sites in Vif that impair viral replication do not affect APOBEC3G degradation, suggesting that Vif is important for other functions in addition to inducing proteasomal degradation of APOBEC3G. Vif is monoubiquitinated in the absence of APOBEC3G but is polyubiquitinated and rapidly degraded when APOBEC3G is coexpressed, suggesting that coexpression accelerates the degradation of both proteins. These results suggest that Vif functions by targeting APOBEC3G for degradation via the ubiquitin-proteasome pathway and implicate the proteasome as a site of dynamic interplay between microbial and cellular defenses.
EloC) through a novel SOCS (suppressor of cytokine signaling)-box that bindsEloC. Vif binding to EloC is negatively regulated by serine phosphorylation in the BC-box motif of the SOCSbox. Vif ubiquitination is promoted by Cul5 in vitro and in vivo, and requires an intact SOCS-box. Thus, autoubiquitination of Vif occurs within the assembled VifCul5 complex, analogous to F-box proteins that are autoubiquitinated within their SCF (Skp1-Cullin-F-box) complex. These findings suggest mechanisms that regulate the assembly and activity of Cul5 E3 complexes through phosphorylation or autoubiquitination of the SOCS-box protein, and identify interactions between Vif and host cell proteins that may be therapeutic targets.Supplemental material is available at http://www.genesdev.org.
One intimidating challenge in protein nanopore-based technologies is designing robust protein scaffolds that remain functionally intact under a broad spectrum of detection conditions. Here, we show that an extensively engineered bacterial ferric hydroxamate uptake component A (FhuA), a β-barrel membrane protein, functions as a robust protein tunnel for the sampling of biomolecular events. The key implementation in this work was the coupling of direct genetic engineering with a refolding approach to produce an unusually stable protein nanopore. More importantly, this nanostructure maintained its stability under many experimental circumstances, some of which, including low ion concentration and highly acidic aqueous phase, are normally employed to gate, destabilize or unfold β-barrel membrane proteins. To demonstrate these advantageous traits, we show that the engineered FhuA-based protein nanopore functioned as a sensing element for examining the proteolytic activity of an enzyme at highly acidic pH and for determining the kinetics of protein-DNA aptamer interactions at physiological salt concentration.
BackgroundAptamers are oligonucleotides that bind proteins and other targets with high affinity and selectivity. Twenty years ago elements of natural selection were adapted to in vitro selection in order to distinguish aptamers among randomized sequence libraries. The primary bottleneck in traditional aptamer discovery is multiple cycles of in vitro evolution.Methodology/Principal FindingsWe show that over-representation of sequences in aptamer libraries and deep sequencing enables acyclic identification of aptamers. We demonstrated this by isolating a known family of aptamers for human α-thrombin. Aptamers were found within a library containing an average of 56,000 copies of each possible randomized 15mer segment. The high affinity sequences were counted many times above the background in 2–6 million reads. Clustering analysis of sequences with more than 10 counts distinguished two sequence motifs with candidates at high abundance. Motif I contained the previously observed consensus 15mer, Thb1 (46,000 counts), and related variants with mostly G/T substitutions; secondary analysis showed that affinity for thrombin correlated with abundance (Kd = 12 nM for Thb1). The signal-to-noise ratio for this experiment was roughly 10,000∶1 for Thb1. Motif II was unrelated to Thb1 with the leading candidate (29,000 counts) being a novel aptamer against hexose sugars in the storage and elution buffers for Concanavilin A (Kd = 0.5 µM for α-methyl-mannoside); ConA was used to immobilize α-thrombin.Conclusions/SignificanceOver-representation together with deep sequencing can dramatically shorten the discovery process, distinguish aptamers having a wide range of affinity for the target, allow an exhaustive search of the sequence space within a simplified library, reduce the quantity of the target required, eliminate cycling artifacts, and should allow multiplexing of sequencing experiments and targets.
The mature nucleocapsid protein of HIV-1, NCp7, and the NC-domains in gag-precursors are attractive targets for anti-AIDS drug discovery. The stability of the 1:1 complex of NCp7 with a 20mer mimic of stem-loop 3 RNA (SL3, also called psi-RNA, in the packaging domain of genomic RNA) is strongly affected by changes in ionic strength. NC-domains recognize and specifically package genomic HIV-1 RNA, while electrostatic attractions and high concentrations of protein and RNA drive NCp7 to completely coat the RNA in the mature virion. The specific interactions from NCp7-binding to loop bases of SL3 produce 1:1 complexes in solutions that have [NaCl] at or above 0.2 M, while the electrostatic interactions can dominate at and below 0.15 M NaCl, leading to complexes that have mainly 1:2 RNA:protein. Persistent, non-equilibrium mixtures of 1:1 and protein-excess complexes can exist at these lower salt concentrations, where the distribution of complexes depends on the order of addition of RNA and protein. Adding salt causes rapid rearrangement of metastable multi-protein complexes to 1:1. The stability of complexes is also affected by the nature of the added salt, with 0.018 M MgCl 2 and 0.200 M added NaCl producing the same K d (21 ± 2 nM); acetate ion stabilizes the 1:1 complex by more than a factor of two compared to the same concentration of chloride ion. Maintaining a salt concentration of 0.2 M NaCl or 18 mM MgCl 2 is sufficient for experiments to distinguish drug candidates that disrupt the specific SL3-NCp7 interactions in the 1:1 complex. Keywords RNA; HIV-1; nucleocapsid protein; fluorescenceThe nucleocapsid protein of HIV-1 is an attractive anti-AIDS drug target. In addition to its role in packaging the RNA (1-4), it has chaperoning functions (5-6), helps refold the RNA dimer (7-9), and anneals the primer tRNA onto genomic RNA for reverse transcription (10-11). It also interacts with viral proteins including reverse transcriptase (12-13), and the accessory protein, Vpr, to play a role in stable integration of the proviral DNA in the chromosomes of infected cells (14). Drugs targeted at NC have the potential to interfere with critical functions at many stages of the viral infection cycle (6,9,11,(15)(16)(17)(18). NIH Public Access Author ManuscriptBiochemistry. Author manuscript; available in PMC 2011 May 4. NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author ManuscriptIn retroviruses similar to HIV-1 about 2,000 polyprotein precursors (gag and gag-pol) assemble at the inner membrane of the forming virion (19)(20)(21). Each of these proteins contains a nucleocapsid domain that is required for packaging genomic RNA into new virus particles. The 55 kD gag precursor polyprotein is later processed by the viral protease to structural proteins, including the mature NCp7 (20). NC-domains within gag precursors bind to the RNA with several RNA-NC interactions responsible for full discrimination of genomic from nongenomic RNA (22-27). Both sequence-specific and non-sequence-specific contacts contribut...
We have studied the binding of neomycin to a 171mer RNA (psi-RNA) from the packaging region of the LAI strain of human immunodeficiency virus type-1, HIV-1 (LAI). The RNase I footprinting studies reveal that the primary binding site for the drug is in stem-loop 1, which contains the dimer initiation site of HIV-1. Loading this site with neomycin causes a structural change in the RNA, allowing nucleotides in the neighboring stem-loop 2 to participate in the drug site. Drug binding to secondary sites induces structural changes in other stem-loops of the RNA. Footprinting plots, showing cutting at a site as a function of drug concentration, were analyzed using a two-state model to obtain relative site-specific binding constants. Circular dichroism measurements show that neomycin binding to psi-RNA changes the intensity of the strong negative CD band at 208 nm, confirming that neomycin induces structural changes. Melting studies of the RNA showed melting transitions in the absence of drug at 28.2, 37.2, 47.4, 55.5 and 60.8 degrees C. Only the first two were affected by drug binding, the reason for this being explained by our analysis.
The genome of the human immunodeficiency virus (HIV) exists as a dimer of two identical RNA molecules hydrogen bonded to each other near their 5' ends. The dimer, known to be important for viral infectivity, is formed by two monomers interacting through a stem-loop structure called the dimer initiation site (DIS). An initially formed intermediate, the "kissing" dimer, is unstable and rearranges to the stable, duplex form. In this report we use nondenaturing polyacrylamide gel electrophoresis to measure the monomer-dimer equilibrium constant of three RNA sequences, 41-, 27-, and 19-mers, located in the DIS of the MAL isolate of HIV-1. Experiments in which the RNA was equilibrated at various temperatures before electrophoresis revealed that interconversion is rapid for all the sequences, so that they reach equilibrium in the loading well of the gel at 5 degrees C before they enter the gel proper. However, interconversion kinetics in the gel are slow, so autoradiographic spot intensities can be used to measure the amounts of monomer and dimer present when the sample entered the gel. After correction for the amount of RNA added with the radiolabel and dilution of samples in the loading well of the gel, dimerization equilibrium constants were calculated from spot intensities. The calculated values of the dimerization constant K at 5 degrees C were approximately 10(5), approximately 10(6), and approximately 10(8) M(-1) for the 41-, 27-, and 19-mers, respectively, in solutions of ionic strength, I, of about 100 mM. The decrease in K by three orders of magnitude between the 19-mer and 41-mer is due in part to the change in rotational entropy of rodlike molecules on dimerization and in part to the increased conformational entropy of the monomers. As expected, increased ionic strength increases the dimerization constant for all three RNAs. For the 41-mer, however, K has a maximum value at I approximately 140 mM. The origin of the decrease in K for higher I is unknown but it may be due to formation of species (perhaps higher order oligomers) that do not enter the gel. The 41-mer exists in two dimeric forms assigned to the kissing and duplex dimers. The ratio of kissing to duplex form at 5 degrees C is 0.48 +/- 0.22 at I = 113 mM and 0.91 +/- 0.35 at I = 183 mM. The observed decrease in K with RNA length suggests that the dimerization constant of the packaging region of HIV-1 is small, < approximately 10(5) M(-1), implying that the nucleocapsid protein is important in promoting dimerization in the capsid of the virus.
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