Translation repression in human cells by microRNA-induced gene silencing requires RCK/p54

RNA interference is triggered by double-stranded RNA that is processed into small interfering RNAs (siRNAs) by Dicer enzyme. Endogenously, RNA interference triggers are created from small noncoding RNAs called microRNAs (miRNAs). RNA-induced silencing complexes (RISC) in human cells can be programmed by exogenously introduced siRNA or endogenously expressed miRNA. siRNA-programmed RISC (siRISC) silences expression by cleaving a perfectly complementary target mRNA, whereas miRNA-induced silencing complexes (miRISC) inhibits translation by binding imperfectly matched sequences in the 3′ UTR of target mRNA. Both RISCs contain Argonaute2 (Ago2), which catalyzes target mRNA cleavage by siRISC and localizes to cytoplasmic mRNA processing bodies (P-bodies). Here, we show that RCK/p54, a DEAD box helicase, interacts with argonaute proteins, Ago1 and Ago2, in affinity-purified active siRISC or miRISC from human cells; directly interacts with Ago1 and Ago2 in vivo, facilitates formation of P-bodies, and is a general repressor of translation. Disrupting P-bodies by depleting Lsm1 did not affect RCK/p54 interactions with argonaute proteins and its function in miRNA-mediated translation repression. Depletion of RCK/p54 disrupted P-bodies and dispersed Ago2 throughout the cytoplasm but did not significantly affect siRNA-mediated RNA functions of RISC. Depleting RCK/p54 released general, miRNA-induced, and let-7-mediated translational repression. Therefore, we propose that translation repression is mediated by miRISC via RCK/p54 and its specificity is dictated by the miRNA sequence binding multiple copies of miRISC to complementary 3′ UTR sites in the target mRNA. These studies also suggest that translation suppression by miRISC does not require P-body structures, and location of miRISC to P-bodies is the consequence of translation repression.     

Thermodynamic and Structural Basis for Relaxation of Specificity in Protein–DNA Recognition

As a novel approach to the structural and functional properties that give rise to extremely stringent sequence specificity in protein–DNA interactions, we have exploited “promiscuous” mutants of EcoRI endonuclease to study the detailed mechanism by which changes in a protein can relax specificity. The A138T promiscuous mutant protein binds more tightly to the cognate GAATTC site than does wild-type EcoRI yet displays relaxed specificity deriving from tighter binding and faster cleavage at EcoRI* sites (one incorrect base pair). AAATTC EcoRI* sites are cleaved by A138T up to 170-fold faster than by wild-type enzyme if the site is abutted by a 5′-purine-pyrimidine (5′-RY) motif. When wild-type protein binds to an EcoRI* site, it forms structurally adapted complexes with thermodynamic parameters of binding that differ markedly from those of specific complexes. By contrast, we show that A138T complexes with 5′-RY-flanked AAATTC sites are virtually indistinguishable from wild-type-specific complexes with respect to the heat capacity change upon binding (?C°_P), the change in excluded macromolecular volume upon association, and contacts to the phosphate backbone. While the preference for the 5′-RY motif implicates contacts to flanking bases as important for relaxed specificity, local effects are not sufficient to explain the large differences in ?C°_P and excluded volume, as these parameters report on global features of the complex. Our findings therefore support the view that specificity does not derive from the additive effects of individual interactions but rather from a set of cooperative events that are uniquely associated with specific recognition.     

The structure of LL-diaminopimelate aminotransferase from Chlamydia trachomatis: implications for its broad substrate specificity

We have previously reported the structures of the native holo and substrate-bound forms of ll-diaminopimelate aminotransferase from Arabidopsis thaliana (AtDAP-AT). Here, we report the crystal and molecular structures of the ll-diaminopimelate aminotransferase from Chlamydia trachomatis (CtDAP-AT) in the apo-form and the pyridoxal-5′-phosphate-bound form. The molecular structure of CtDAP-AT shows that its overall fold is essentially identical with that of AtDAP-AT except that CtDAP-AT adopts an “open” conformation as opposed to the “closed” conformation of AtDAP-AT. Although AtDAP-AT and CtDAP-AT are approximately 40% identical in their primary sequence, they have major differences in their substrate specificities; AtDAP-AT is highly specific for LL-DAP, whereas CtDAP-AT accepts a wider range of substrates. Since all of the residues involved in substrate recognition are highly conserved between AtDAP-AT and CtDAP-AT, we propose that differences in flexibility of the loops lining the active-site region between the two enzymes likely account for the differences in substrate specificity.     

The structure of human argonaute-2 in complex with miR-20a

Argonaute proteins lie at the heart of the RNA-induced silencing complex (RISC), wherein they use small RNA guides to recognize targets. Initial insight into the architecture of Argonautes came from studies of prokaryotic proteins, revealing a crescent-shaped base made up of the amino-terminal, PAZ, middle, and PIWI domains. The recently reported crystal structure of human Argonaute-2 (hAgo2), the "slicer" in RNA interference, in complex with a mixed population of RNAs derived from insect cells provides insight into the architecture of a eukaryotic Argonaute protein with defined biochemical and biological functions. Here, we report the structure of human Ago2 bound to a physiologically relevant microRNA, microRNA-20a, at 2.2 ? resolution. The miRNA is anchored at both ends by the Mid and PAZ domains and makes several kinks and turns along the binding groove. Interestingly, miRNA binding confers remarkable stability on hAgo2, locking this otherwise flexible enzyme into a stable conformation.     

Rotations of the 2B sub-domain of E. coli UvrD helicase/translocase coupled to nucleotide and DNA binding

Escherichia coli UvrD is a superfamily 1 DNA helicase and single-stranded DNA (ssDNA) translocase that functions in DNA repair and plasmid replication and as an anti-recombinase by removing RecA protein from ssDNA. UvrD couples ATP binding and hydrolysis to unwind double-stranded DNA and translocate along ssDNA with 3′-to-5′ directionality. Although a UvrD monomer is able to translocate along ssDNA rapidly and processively, DNA helicase activity in vitro requires a minimum of a UvrD dimer. Previous crystal structures of UvrD bound to a ssDNA/duplex DNA junction show that its 2B sub-domain exists in a “closed” state and interacts with the duplex DNA. Here, we report a crystal structure of an apo form of UvrD in which the 2B sub-domain is in an “open” state that differs by an ∼ 160° rotation of the 2B sub-domain. To study the rotational conformational states of the 2B sub-domain in various ligation states, we constructed a series of double-cysteine UvrD mutants and labeled them with fluorophores such that rotation of the 2B sub-domain results in changes in fluorescence resonance energy transfer. These studies show that the open and closed forms can interconvert in solution, with low salt favoring the closed conformation and high salt favoring the open conformation in the absence of DNA. Binding of UvrD to DNA and ATP binding and hydrolysis also affect the rotational conformational state of the 2B sub-domain, suggesting that 2B sub-domain rotation is coupled to the function of this nucleic acid motor enzyme.     

Local and global effects of Mg2+ on Ago and miRNA-target interactions

Three magnesium ions (Mg(2+)), named Mg1 (in Mid domain), Mg2 and Mg3 (both in PIWI domain), located at the small RNA binding domain of Argonaute (Ago) protein, are important for sequence-specific miRNA-target interactions. Such conjunction between the Ago protein and miRNA raises the question: How do Mg(2+) ions participate in the recognition process of miRNA by Ago or its target. Furthermore, it is still unclear whether the Mg(2+) ions contribute to the local or global stability of the miRNA complex. In this work, we have performed a series of 16 independent molecular dynamic simulations (MD) to characterize the functions of Mg(2+), hydration patterns and the conformational events involved in the miRNA-target interactions. The cross correlation analysis shows that Mg1 and Mg2 significantly enhance a locally cooperated movement of the PAZ, PIWI and Mid domains with the average correlation coefficient of ～0.65, producing an "open-closed" motion (rotation Angle, 46.5°) between the PAZ and PIWI domains. Binding of Mg3 can globally stabilize the whole Ago protein with the average RMSD of ～0.34 ?, compared with the systems in absence of Mg3 (average RMSD?=?～0.43 ?). Three structural water molecules surrounding the Mg(2+)-binding regions also stabilize these ions, thus facilitating the recognition of miRNA to its target. In addition, the thermodynamic analysis also verifies the positive contribution of all three Mg(2+) to the binding of miRNA to Ago, as well as the importance Mg2 plays in the cleavage of the miRNA targets.     

Crystal structure analysis of the translation factor RF3 (release factor 3)

The bacterial translational GTPases release factor RF3 promotes translation termination by recycling RF1 or RF2. Here, we present the crystal structures of RF3 complexed with GDP and guanosine 3′,5′-(bis)diphosphate (ppGpp) at resolutions of 1.8 and 3.0 Å, respectively. ppGpp is involved in the so-called “stringent response” of bacteria. ppGpp binds at the same site as GDP, suggesting that GDP and ppGpp are two alternative physiologically relevant ligands of RF3. We also found that ppGpp decelerates the recycling of RF1 by RF3. These lines of evidence suggest that RF3 functions both as a cellular metabolic sensor and as a regulator.     

Mechanism of MicroRNA-Target Interaction: Molecular Dynamics Simulations and Thermodynamics Analysis

MicroRNAs (miRNAs) are endogenously produced ∼21-nt riboregulators that associate with Argonaute (Ago) proteins to direct mRNA cleavage or repress the translation of complementary RNAs. Capturing the molecular mechanisms of miRNA interacting with its target will not only reinforce the understanding of underlying RNA interference but also fuel the design of more effective small-interfering RNA strands. To address this, in the present work the RNA-bound (Ago-miRNA, Ago-miRNA-target) and RNA-free Ago forms were analyzed by performing both molecular dynamics simulations and thermodynamic analysis. Based on the principal component analysis results of the simulation trajectories as well as the correlation analysis in fluctuations of residues, we discover that: 1) three important (PAZ, Mid and PIWI) domains exist in Argonaute which define the global dynamics of the protein; 2) the interdomain correlated movements are so crucial for the interaction of Ago-RNAs that they not only facilitate the relaxation of the interactions between residues surrounding the RNA binding channel but also induce certain conformational changes; and 3) it is just these conformational changes that expand the cavity of the active site and open putative pathways for both the substrate uptake and product release. In addition, by thermodynamic analysis we also discover that for both the guide RNA 5′-end recognition and the facilitated site-specific cleavage of the target, the presence of two metal ions (of Mg²⁺) plays a predominant role, and this conclusion is consistent with the observed enzyme catalytic cleavage activity in the ternary complex (Ago-miRNA-mRNA). Our results find that it is the set of arginine amino acids concentrated in the nucleotide-binding channel in Ago, instead of the conventionally-deemed seed base-paring, that makes greater contributions in stabilizing the binding of the nucleic acids to Ago.     

Structure of the Murine Unglycosylated IgG1 Fc Fragment

A prototypic IgG antibody can be divided into two major structural units: the antigen-binding fragment (Fab) and the Fc fragment that mediates effector functions. The IgG Fc fragment is a homodimer of the two C-terminal domains (C_H2 and C_H3) of the heavy chains. Characteristic of the Fc part is the presence of a sugar moiety at the inner face of the C_H2 domains. The structure of this complex branched oligosaccharide is generally resolved in crystal structures of Fc fragments due to numerous well-defined sugar-protein interactions and a small number of sugar-sugar interactions. This suggested that sugars play an important role in the structure of the Fc fragment. To address this question directly, we determined the crystal structure of the unglycosylated Fc fragment of the murine IgG1 MAK33. The structures of the C_H3 domains of the unglycosylated Fc fragment superimpose perfectly with the structure of the isolated MAK33 C_H3 domain. The unglycosylated C_H2 domains, in contrast, approach each other much more closely compared to known structures of partly deglycosylated Fc fragments with rigid-body motions between 10 and 14 Å, leading to a strongly “closed” conformation of the unglycosylated Fc fragment. The glycosylation sites in the C′E loop and the BC and FG loops are well defined in the unglycosylated C_H2 domain, however, with increased mobility and with a significant displacement of about 4.9 Å for the unglycosylated Asn residue compared to the glycosylated structure. Thus, glycosylation both stabilizes the C′E-loop conformation within the C_H2 domain and also helps to ensure an “open” conformation, as seen upon Fc receptor binding. These structural data provide a rationale for the observation that deglycosylation of antibodies often compromises their ability to bind and activate Fcγ receptors.     

Structural and chemical profiling of the human cytosolic sulfotransferases

The human cytosolic sulfotransfases (hSULTs) comprise a family of 12 phase II enzymes involved in the metabolism of drugs and hormones, the bioactivation of carcinogens, and the detoxification of xenobiotics. Knowledge of the structural and mechanistic basis of substrate specificity and activity is crucial for understanding steroid and hormone metabolism, drug sensitivity, pharmacogenomics, and response to environmental toxins. We have determined the crystal structures of five hSULTs for which structural information was lacking, and screened nine of the 12 hSULTs for binding and activity toward a panel of potential substrates and inhibitors, revealing unique “chemical fingerprints” for each protein. The family-wide analysis of the screening and structural data provides a comprehensive, high-level view of the determinants of substrate binding, the mechanisms of inhibition by substrates and environmental toxins, and the functions of the orphan family members SULT1C3 and SULT4A1. Evidence is provided for structural “priming” of the enzyme active site by cofactor binding, which influences the spectrum of small molecules that can bind to each enzyme. The data help explain substrate promiscuity in this family and, at the same time, reveal new similarities between hSULT family members that were previously unrecognized by sequence or structure comparison alone.     

Synthesis, properties and crystal structures of new binuclear lead(II) complexes based on phenyl, naphthyl-containing fluorine β-diketones and substituted 2,2′-bipyridines

Four lead(II) complexes with substituted 2,2′-bipyridine adducts and β-diketonates ligands, [Pb(5,5′-dm-2,2′-bpy)(tfpb)₂]₂1, [Pb(4,4′-dmo-2,2′-bpy)(tfpb)₂]₂2, [Pb(4,4′-dm-2,2′-bpy)(tfnb)₂]₂3 and [Pb(5,5′-dm-2,2′-bpy)(tfnb)₂]₂4, (“4,4′-dm-2,2′-bpy”, “5,5′-dm-2,2′-bpy”, “4,4′-dmo-2,2′-bpy”, “Htfpb” and “Htfnb” are the abbreviations of 4,4′-dimethyl-2,2′-bipyridine, 5,5′-dimethyl-2,2′-bipyridine, 4,4′-dimethoxy-2,2′-bipyridine, 4,4,4-trifluoro-1-phenyl-1,3-butanedione and 4,4,4-trifluoro-1-(2-naphthyl)-1,3-butanedione, respectively) have been synthesized and characterized by elemental analysis, IR, ¹H NMR and ¹³C NMR spectroscopy and also studied by thermal and electrochemical as well as X-ray crystallography. The supramolecular features in these complexes are guided/controlled by weak directional intramolecular interactions.     

The Bin3 RNA methyltransferase is required for repression of caudal translation in the Drosophila embryo

Bin3 was first identified as a Bicoid-interacting protein in a yeast two-hybrid screen. In human cells, a Bin3 ortholog (BCDIN3) methylates the 5′ end of 7SK RNA, but its role in vivo is unknown. Here, we show that in Drosophila, Bin3 is important for dorso-ventral patterning in oogenesis and for anterior–posterior pattern formation during embryogenesis. Embryos that lack Bin3 fail to repress the translation of caudal mRNA and exhibit head involution defects. bin3 mutants also show (1) a severe reduction in the level of 7SK RNA, (2) reduced binding of Bicoid to the caudal 3′ UTR, and (3) genetic interactions with bicoid, and with genes encoding eIF4E, Larp1, polyA binding protein (PABP), and Ago2. 7SK RNA coimmunoprecipitated with Bin3 and is present in Bicoid complexes. These data suggest a model in which Bicoid recruits Bin3 to the caudal 3′ UTR. Bin3's role is to bind and stabilize 7SK RNA, thereby promoting formation of a repressive RNA–protein complex that includes the RNA-binding proteins Larp1, PABP, and Ago2. This complex would prevent translation by blocking eIF4E interactions required for initiation. Our results, together with prior network analysis in human cells, suggest that Bin3 interacts with multiple partner proteins, methylates small non-coding RNAs, and plays diverse roles in development.     

Binding and Cleavage Specificities of Human Argonaute2

The endonuclease Argonaute2 (Ago2) mediates the degradation of the target mRNA within the RNA-induced silencing complex. We determined the binding and cleavage properties of recombinant human Ago2. Human Ago2 was unable to cleave preformed RNA duplexes and exhibited weaker binding affinity for RNA duplexes compared with the single strand RNA. The enzyme exhibited greater RNase H activity in the presence of Mn²⁺ compared with Mg²⁺. Human Ago2 exhibited weaker binding affinities and reduced cleavage activities for antisense RNAs with either a 5′-terminal hydroxyl or abasic nucleotide. Binding kinetics suggest that the 5′-terminal heterocycle base nucleates the interaction between the enzyme and the antisense RNA, and the 5′-phosphate stabilizes the interaction. Mn²⁺ ameliorated the effects of the 5′-terminal hydroxyl or abasic nucleotide on Ago2 cleavage activity and binding affinity. Nucleotide substitutions at the 3′ terminus of the antisense RNA had no effect on human Ago2 cleavage activity, whereas 2′-methoxyethyl substitutions at position 2 reduced binding and cleavage activity and 12–14 reduced the cleavage activity. RNase protection assays indicated that human Ago2 interacts with the first 14 nucleotides at the 5′-pole of the antisense RNA. Human Ago2 preloaded with the antisense RNA exhibited greater binding affinities for longer sense RNAs suggesting that the enzyme interacts with regions in the sense RNA outside the site for antisense hybridization. Finally, transiently expressed human Ago2 immunoprecipitated from HeLa cells contained the double strand RNA-binding protein human immunodeficiency virus, type 1, trans-activating response RNA-binding protein, and deletion mutants of Ago2 showed that trans-activating response RNA-binding protein interacts with the PIWI domain of the enzyme.RNA interference is a mechanism by which double-stranded RNA triggers the loss of RNA of homologous sequence (1). Long double strand RNAs are processed by the double strand endonuclease Dicer into short RNA duplexes (siRNA)² ranging from 21 to 23 nucleotides in length (2). The double strand RNA-binding proteins Dicer and human immunodeficiency virus, type 1, trans-activating response RNA-binding protein (TRBP) transfer the siRNAs to the RNA-induced silencing complex (RISC) (3). The antisense strand of the siRNA binds to the RISC endonuclease Argonaute 2 (Ago2), which then cleaves the target mRNA at a single phosphodiester bond bridging the ribonucleotides opposing the 10th and 11th nucleotide from the 5′ terminus of the antisense strand (4–11).The structure-activity relationships of siRNAs in human cultured cells have been studied extensively, but these types of studies offer few insights into the underlying mechanisms contributing to the observed activities of the siRNA and, in particular, their interaction with the RISC endonuclease human Ago2. Surprisingly, the little that is known about the interaction between human Ago2 and the substrate comes from a single report describing the preliminary characterization of recombinant human Ago2 (11). Specifically, human Ago2 cleavage activity was magnesium-dependent, and the antisense RNA containing a phosphate at the 5′ terminus exhibited greater cleavage activity compared with the antisense RNA with a 5′-hydroxyl. The enzyme was unable to cleave a DNA target or use a DNA antisense strand to trigger the cleavage of a complementary RNA (11). In addition, UV cross-linking experiments showed that single strand but not double strand RNA was able to cross-link with the recombinant enzyme. Finally, unlike RISC activity from cellular extracts, which has been shown to catalyze multiple rounds of cleavage, recombinant Ago2 exhibited single-turnover kinetics (11, 12).The architecture of the human Ago2 protein consists of a PIWI domain at the amino terminus, a centrally located Mid domain and a PAZ domain at the carboxyl terminus (13–17). The PIWI domain constitutes the catalytic domain of the enzyme and exhibits a three-dimensional structure similar to RNase H, sharing the same aspartic acid-aspartic acid-glutamic acid (DDE) catalytic triad and metal cofactor requirements (10, 16, 17). Recently, the structures of argonaute from Thermus thermophilus and Archaeoglobus fulgidus bound to the antisense strand have been solved (15, 18). The structures show that the PAZ, Mid, and PIWI domains form an extended nucleic acid binding surface for the antisense strand. In addition, a basic binding pocket positioned within the Mid domain and a basic cleft in the PIWI domain were shown to bind, respectively, the 5′-terminal phosphate and the backbone at the 5′-pole of the antisense strand (15, 18). Aside from the two 3′-terminal nucleotides of the antisense strand, which were shown to bind a hydrophobic pocket within the PAZ domain, no interactions were observed between the enzyme and the 3′-pole of the antisense strand. An important difference between the structures of the two prokaryotic proteins was that the A. fulgidus protein contained a tyrosine residue positioned in the basic binding pocket, which formed a stacking interaction with the heterocycle base of the 5′-terminal nucleotide in the antisense strand. The human Ago2 protein appears to differ significantly from the prokaryotic argonaute proteins in that the key amino acids that make up the nucleic acid binding surface of the prokaryotic proteins are not conserved in the human enzyme. Consequently, the structures of the prokaryotic proteins appear to offer limited insights into the interaction between the human enzyme and the antisense strand of the siRNA.Given that Ago2 is responsible for the siRNA-mediated cleavage of the target RNA, understanding the properties important for the interaction between the antisense strand and Ago2 could lead to the identification of siRNA configurations with improved potency. To better understand the substrate specificity of human Ago2, we determined the cleavage activities, binding affinities, and binding kinetics of human Ago2 for various antisense oligonucleotides. The antisense oligonucleotides were designed to evaluate the interaction between human Ago2 and various regions in the antisense RNA, including the 5′ and 3′ termini and 2′-hydroxyl. The activities and binding affinities were compared for two different preparations of the enzyme as follows: a human Ago2 protein containing a glutathione S-transferase tag (GST-Ago2) that was expressed in insect cells and purified to homogeneity and an HA-tagged protein that was expressed in HeLa cells and immunoprecipitated with HA antibody (HA-Ago2). In addition, we evaluated the effects of divalent cation metals on the substrate specificity of human Ago2. Finally, we identified endogenous TRBP in the immunoprecipitated HA-Ago2 preparation and demonstrated using deletion mutants that the PIWI domain of Ago2 interacts with TRBP.     

P. aeruginosa PilT Structures with and without Nucleotide Reveal a Dynamic Type IV Pilus Retraction Motor

Type IV pili are bacterial extracellular filaments that can be retracted to create force and motility. Retraction is accomplished by the motor protein PilT. Crystal structures of Pseudomonas aeruginosa PilT with and without bound β,γ-methyleneadenosine-5′-triphosphate have been solved at 2.6 Å and 3.1 Å resolution, respectively, revealing an interlocking hexamer formed by the action of a crystallographic 2-fold symmetry operator on three subunits in the asymmetric unit and held together by extensive ionic interactions. The roles of two invariant carboxylates, Asp Box motif Glu163 and Walker B motif Glu204, have been assigned to Mg²⁺ binding and catalysis, respectively. The nucleotide ligands in each of the subunits in the asymmetric unit of the β,γ-methyleneadenosine-5′-triphosphate-bound PilT are not equally well ordered. Similarly, the three subunits in the asymmetric unit of both structures exhibit differing relative conformations of the two domains. The 12° and 20° domain rotations indicate motions that occur during the ATP-coupled mechanism of the disassembly of pili into membrane-localized pilin monomers. Integrating these observations, we propose a three-state “Ready, Active, Release” model for the action of PilT.     

Biophysical Characterization of an Ensemble of Intramolecular i-Motifs Formed by the Human c-MYC NHE III1 P1 Promoter Mutant Sequence

i-Motif-forming sequences are present in or near the regulatory regions of >40% of all genes, including known oncogenes. We report here the results of a biophysical characterization and computational study of an ensemble of intramolecular i-motifs that model the polypyrimidine sequence in the human c-MYC P1 promoter. Circular dichroism results demonstrate that the mutant sequence (5′-CTT TCC TAC CCTCCC TAC CCT AA-3′) can adopt multiple “i-motif-like,” classical i-motif, and single-stranded structures as a function of pH. The classical i-motif structures are predominant in the pH range 4.2-5.2. The “i-motif-like” and single-stranded structures are the most significant species in solution at pH higher and lower, respectively, than that range. Differential scanning calorimetry results demonstrate an equilibrium mixture of at least three i-motif folded conformations with T_m values of 38.1, 46.6, and 49.5°C at pH 5.0. The proposed ensemble of three folded conformations includes the three lowest-energy conformations obtained by computational modeling and two folded conformers that were proposed in a previous NMR study. The NMR study did not report the most stable conformer found in this study.     

microRNA-122 Dependent Binding of Ago2 Protein to Hepatitis C Virus RNA Is Associated with Enhanced RNA Stability and Translation Stimulation

Translation of Hepatitis C Virus (HCV) RNA is directed by an internal ribosome entry site (IRES) in the 5′-untranslated region (5′-UTR). HCV translation is stimulated by the liver-specific microRNA-122 (miR-122) that binds to two binding sites between the stem-loops I and II near the 5′-end of the 5′-UTR. Here, we show that Argonaute (Ago) 2 protein binds to the HCV 5′-UTR in a miR-122-dependent manner, whereas the HCV 3′-UTR does not bind Ago2. miR-122 also recruits Ago1 to the HCV 5’-UTR. Only miRNA duplex precursors of the correct length stimulate HCV translation, indicating that the duplex miR-122 precursors are unwound by a complex that measures their length. Insertions in the 5′-UTR between the miR-122 binding sites and the IRES only slightly decrease translation stimulation by miR-122. In contrast, partially masking the miR-122 binding sites in a stem-loop structure impairs Ago2 binding and translation stimulation by miR-122. In an RNA decay assay, also miR-122-mediated RNA stability contributes to HCV translation stimulation. These results suggest that Ago2 protein is directly involved in loading miR-122 to the HCV RNA and mediating RNA stability and translation stimulation.     

Structural lability in stem-loop 1 drives a 5' UTR-3' UTR interaction in coronavirus replication

The leader RNA of the 5′ untranslated region (UTR) of coronaviral genomes contains two stem-loop structures denoted SL1 and SL2. Herein, we show that SL1 is functionally and structurally bipartite. While the upper region of SL1 is required to be paired, we observe strong genetic selection against viruses that contain a deletion of A35, an extrahelical nucleotide that destabilizes SL1, in favor of genomes that contain a diverse panel of destabilizing second-site mutations, due to introduction of a noncanonical base pair near A35. Viruses containing destabilizing SL1-ΔA35 mutations also contain one of two specific mutations in the 3′ UTR. Thermal denaturation and imino proton solvent exchange experiments reveal that the lower half of SL1 is unstable and that second-site SL1-ΔA35 substitutions are characterized by one or more features of the wild-type SL1. We propose a “dynamic SL1” model, in which the base of SL1 has an optimized lability required to mediate a physical interaction between the 5′ UTR and the 3′ UTR that stimulates subgenomic RNA synthesis. Although not conserved at the nucleotide sequence level, these general structural characteristics of SL1 appear to be conserved in other coronaviral genomes.     

The crystal structure of the SV40 T-antigen origin binding domain in complex with DNA

DNA replication is initiated upon binding of “initiators” to origins of replication. In simian virus 40 (SV40), the core origin contains four pentanucleotide binding sites organized as pairs of inverted repeats. Here we describe the crystal structures of the origin binding domain (obd) of the SV40 large T-antigen (T-ag) both with and without a subfragment of origin-containing DNA. In the co-structure, two T-ag obds are oriented in a head-to-head fashion on the same face of the DNA, and each T-ag obd engages the major groove. Although the obds are very close to each other when bound to this DNA target, they do not contact one another. These data provide a high-resolution structural model that explains site-specific binding to the origin and suggests how these interactions help direct the oligomerization events that culminate in assembly of the helicase-active dodecameric complex of T-ag.