High-resolution NMR study of a GdAGA tetranucleotide loop that is an improved substrate for ricin, a cytotoxic plant protein.

Ricin is a cytotoxic plant protein that inactivates ribosomes by hydrolyzing the N-glycosidic bond at position A4324 in eukaryotic 28S rRNA. Recent studies showed that a four-nucleotide loop, GAGA, can function as a minimum substrate for ricin (the first adenosine corresponds to the site of depurination). We previously clarified the solution structure of this loop by NMR spectroscopy [Orita et al. (1993) Nucleic Acids Res. 21, 5670-5678]. To elucidate further details of the structural basis for recognition of its substrate by ricin, we studied the properties of a synthetic dodecanucleotide, r1C2U3C4A5G6dA7G8A9U10G11A12G (6dA12mer), which forms an RNA hairpin structure with a GdAGA loop and in which the site of depurination is changed from adenosine to 2'-deoxyadenosine. The N-glycosidase activity against the GdAGA loop of the A-chain of ricin was 26 times higher than that against the GAGA loop. NMR studies indicated that the overall structure of the GdAGA loop was similar to that of the GAGA loop with the exception of the sugar puckers of 6dA and 7G. Therefore, it appears that the 2'-hydroxyl group of adenosine at the depurination site (6A) does not participate in the recognition by ricin of the substrate. Since the 2'-hydroxyl group can potentially destabilize the developing positive charge of the putative transition state intermediate, an oxycarbonium ion, the electronic effect may explain, at least in part, the faster rate of depurination of the GdAGA loop compared to that of GAGA loop. We also show that the amino group of 7G is essential for substrate recognition the ricin A-chain.     

Non-specific deadenylation and deguanylation of naked RNA catalyzed by ricin under acidic condition.

Ricin A-chain catalyzes the hydrolysis of the N-glycosidic bond of a conserved adenosine residue at position 4324 in the sarcin/ricin domain of 28S RNA of rat ribosome. The GAGA tetraloop closed by C-G pairs is required for recognition of the cleavage site on 28S ribosomal RNA by ricin A-chain. In this study, ricin A-chain (reduced ricin) exhibits specific depurination on a synthetic oligoribonucleotide (named SRD RNA) mimic of the sarcin/ricin domain of rat 28S ribosomal RNA under neutral and weak acidic conditions. Furthermore, the activity of intact ricin is also similar to that of ricin A-chain. However, under more acidic conditions, both enzymes lose their site specificity. The alteration in specificity of depurination is not dependent on the GAGA tetraloop of SRD RNA. A higher concentration of KCl inhibits the non-specific N-glycosidase activity much more than the specific activity of ricin A-chain. In addition, characterization of depurination sites by RNA sequencing reveals that under acidic conditions ricin A-chain can release not only adenines, but also guanines from SRD RNA or 5S ribosomal RNA. This is the first report of the non-specific deadenylation and deguanylation activity of ricin A-chain to the naked RNA under acidic conditions.     

Ricin A-chain activity on stem-loop and unstructured DNA substrates

Ricin toxin A-chain (RTA) depurinates a single adenylate on a GAGA stem-loop region of eukaryotic 28S RNA, making it a potent toxin. Steady state rate analysis is used to establish the kinetic parameters for depurination of short RNA, DNA, and RNA-DNA hybrids of GAGA linear segments and stem-loop regions as substrates for RTA. Both stem and tetraloop structures are essential for action on RNA. For DNA stem-loop substrates, stem stability plays a small role in enhancing catalytic turnover but can enhance binding by up to 3 orders of magnitude. DNA sequences of d[GAGA] without stem-loop structures are found to be slow substrates for RTA. In contrast, equivalent RNA sequences exhibit no activity with RTA. Introduction of a deoxyadenosine at the depurination site of short RNA oligonucleotides restores catalytic function. NMR analysis indicates that the short, nonsubstrate GAGA is converted to substrate in GdAGA by the presence of a more flexible ribosyl group at the deoxyadenosine site. Conversion between C2'-endo and C2'-exo conformations at the deoxyadenosine site moves the 3'- and 5'-phosphorus atoms by 1.1 A, and the former is proposed to place them in a catalytically favorable configuration. The ability to use short RNA-DNA hybrids as substrates for RTA permits exploration of related structures to function as substrates and inhibitors.     

Ribosomal RNA identity elements for ricin A-chain recognition and catalysis. Analysis with tetraloop mutants.

Ricin is a cytotoxic protein that inactivates ribosomes by hydrolyzing the N-glycosidic bond between the base and the ribose of the adenosine at position 4324 in eukaryotic 28 S rRNA. Ricin A-chain will also catalyze depurination in naked prokaryotic 16 S rRNA; the adenosine is at position 1014 in a GAGA tetraloop. The rRNA identity elements for recognition by ricin A-chain and for the catalysis of cleavage were examined using synthetic GAGA tetraloop oligoribonucleotides. The RNA designated wild-type, an oligoribonucleotide (19-mer) that approximates the structure of the ricin-sensitive site in 16 S rRNA, and a number of mutants were transcribed in vitro from synthetic DNA templates with phage T7 RNA polymerase. With the wild-type tetraloop oligoribonucleotide the ricin A-chain-catalyzed reaction has a Km of 5.7 microM and a Kcat of 0.01 min-1. The toxin alpha-sarcin, which cleaves the phosphodiester bond on the 3' side of G4325 in 28 S rRNA, does not recognize the tetraloop RNA, although alpha-sarcin does affect a larger synthetic oligoribonucleotide that has a 17-nucleotide loop with a GAGA sequence; thus, there is a clear divergence in the identity elements for the two toxins. Mutants were constructed with all of the possible transitions and transversions of each nucleotide in the GAGA tetraloop; none was recognized by ricin A-chain. Thus, there is an absolute requirement for the integrity of the GAGA sequence in the tetraloop. The helical stem of the tetraloop oligoribonucleotide can be reduced to three base-pairs, indeed, to two base-pairs if the temperature is decreased, without affecting recognition; the nature of these base-pairs does not influence recognition or catalysis by ricin A-chain. If the tetraloop is opened so as to form a GAGA-containing hexaloop, recognition by ricin A-chain is lost. This suggests that during the elongation cycle, a GAGA tetraloop either exists or is formed in the putative 17-member single-stranded region of the ricin domain in 28 S rRNA and this bears on the mechanism of protein synthesis.     

Vinyldeoxyadenosine in a sarcin-ricin RNA loop and its binding to ricin toxin a-chain

8-Vinyl-2'-deoxyadenosine (8vdA) is a fluorophore with a quantum yield comparable to that of 2-aminopurine nucleoside. 8vdA was incorporated into a 10-mer stem-tetraloop RNA (8vdA-10) structure for characterization of the properties of the base, 8-vinyladenine (8-vA), with respect to adenine as a substrate or inhibitor for ribosome-inactivating proteins. Ricin toxin A-chain (RTA) and pokeweed antiviral protein (PAP) catalyze the release of adenine from a specific adenosine on a stem-tetraloop (GAGA) sequence at the elongation factor (eEF2) binding site of the 28S subunit of eukaryotic ribosomes, thereby arresting translation. RTA does not catalyze the release of 8-vinyladenine from 8vdA-10. Molecular dynamics simulations implicate a role for Arg180 in oxacarbenium ion destabilization and the lack of catalysis. However, 8vdA-10 is an active site analogue and inhibits RTA with a Ki value of 2.4 microM. Adenine is also released from the second adenosine in the modified tetraloop, demonstrating an alternative mode for the binding of this motif in the RTA active site. The 8vdA analogue defines the specificities of RTA for the two adenylate depurination sites in a RNA substrate with a GAGA tetraloop. The rate of nonenzymatic acid-catalyzed solvolysis of 8-vinyladenine from the stem-loop RNA is described. Unlike RTA, PAP catalyzes the slow release of 8-vinyladenine from 8vdA-10. The isolation of 8-vA and its physicochemical characterization is described.     

The ribosomal RNA identity elements for ricin and for alpha-sarcin: mutations in the putative CG pair that closes a GAGA tetraloop.

alpha-Sarcin is a ribonuclease that cleaves the phosphodiester bond on the 3' side of G4325 in 28S rRNA; ricin A-chain is a RNA N-glycosidase that depurinates the 5' adjacent A4324. These single covalent modifications inactivate the ribosome. An oligoribonucleotide that reproduces the structure of the sarcin/ricin domain in 28S rRNA was synthesized and mutations were constructed in the 5' C and the 3' G that surround a GAGA tetrad that has the sites of toxin action. Covalent modification of the RNA by ricin, but not by alpha-sarcin, requires a Watson-Crick pair to shut off a putative GAGA tetraloop. Either the recognition elements for the two toxins are different despite their catalyzing covalent modification of adjacent nucleotides in 28S rRNA or there are transitions in the conformation of the alpha-sarcin/ricin domain in 28S rRNA and one conformer is recognized by alpha-sarcin and the other by ricin A-chain.     

High-resolution NMR study of a synthetic oligoribonucleotide with a tetranucleotide GAGA loop that is a substrate for the cytotoxic protein, ricin.

Ricin is a cytotoxic protein that inactivates ribosomes by hydrolyzing the N-glycosidic bond at position A4324 in eukaryotic 28S rRNA. Its substrate domain forms a double helical stem and a 17-base loop that includes the sequence GAGA, the second adenosine of which corresponds to A4324. Recently, studies of mutant RNAs have shown that the four-nucleotide loop, GAGA, can function as a substrate for ricin. To investigate the structure that is recognized by ricin, we studied the properties of a short synthetic substrate, the dodecaribonucleotide r-CUCAGAGAUGAG, which forms a RNA hairpin structure with a GABA loop and a stem of four base pairs. The results of NMR spectroscopy allowed us to construct the solution structure of this oligonucleotide by restrained molecular-dynamic calculations. We found that the stem region exists as an A-form duplex. 5G and 8A in the loop region form an unusual G:A base pair, and the phosphodiester backbone has a turn between 5G and 6A. This turn seems to help ricin to gain access to 6A which is the only site of depurination in the entire structure. The overall structure of the GAGA loop is similar to those of the GAAA and GCAA loops that have been described but that are not recognized by ricin. Therefore, in addition to the adenosine at the depurination site, the neighboring guanosine on the 3' side (7G) may also play a role in the recognition mechanism together with 5G and 8A.     

Ricin A-chain inhibitors resembling the oxacarbenium ion transition state

Ricin toxin A-chain (RTA) is expressed by the castor bean plant and is among the most potent mammalian toxins. Upon activation in the cytosol, RTA depurinates a single adenine from position 4324 of rat 28S ribosomal RNA, causing inactivation of ribosomes by preventing the binding of elongation factors. Kinetic isotope effect studies have established that RTA operates via a D(N)*A(N) mechanism involving an oxacarbenium ion intermediate with bound adenine [Chen, X.-Y., Berti, P. J., and Schramm, V. L. (2000) J. Am. Chem. Soc. 122, 1609-1617]. On the basis of this information, stem-loop RNA molecules were chemically synthesized, incorporating structural features of the oxacarbenium ion-like transition state. A 10-base RNA stem-loop incorporating (1S)-1-(9-deazaadenin-9-yl)-1,4-dideoxy-1,4-imino-D-ribitol at the depurination site binds four times better (0.57 microM) than the 10-base RNA stem-loop with adenosine at the depurination site (2.2 microM). A 10-base RNA stem-loop with 1,2-dideoxyribitol [(2R,3S)-2-(hydroxymethyl)-3-hydroxytetrahydrofuran] at the depurination site binds with a Kd of 3.2 microM and tightens to 0.75 microM in the presence of 9-deazaadenine. A similar RNA stem-loop with 1,4-dideoxy-1,4-imino-D-ribitol at the depurination site binds with a K(d) of 1.3 microM and improves to 0.65 micro;M with 9-deazaadenine added. When (3S,4R)-4-hydroxy-3-(hydroxymethyl)pyrrolidine was incorporated at the depurination site of a 14-base RNA stem-loop, the Kd was 0.48 microM. Addition of 9-deazaadenine tightens the binding to 0.10 microM whereas added adenine increases the affinity to 12 nM. The results of this study are consistent with the unusual dissociative D(N)*A(N) mechanism determined for RTA. Knowledge of this intermediate has led to the design and synthesis of the highest affinity inhibitor reported for the catalytic site of RTA.     

In vitro selection of RNA molecules that inhibit the activity of ricin A-chain

The cytotoxin ricin disables translation by depurinating a conserved site in eukaryotic rRNA. In vitro selection has been used to generate RNA ligands (aptamers) specific for the catalytic ricin A-chain (RTA). The anti-RTA aptamers bear no resemblance to the normal RTA substrate, the sarcin-ricin loop (SRL), and were not depurinated by RTA. An initial 80-nucleotide RNA ligand was minimized to a 31-nucleotide aptamer that contained all sequences and structures necessary for interacting with RTA. This minimal RNA formed high affinity complexes with RTA (K(d) = 7.3 nM) which could compete directly with the SRL for binding to RTA. The aptamer inhibited RTA depurination of the SRL and could partially protect translation from RTA inhibition. The IC(50) of the aptamer for RTA in an in vitro translation assay is 100 nM, roughly 3 orders of magnitude lower than a small molecule inhibitor of ricin, pteroic acid, and 2 orders of magnitude lower than the best known RNA inhibitor. The novel anti-RTA aptamers may find application as diagnostic reagents for a potential biological warfare agent and hold promise as scaffolds for the development of strong ricin inhibitors.     

Inhibition of ricin A-chain with pyrrolidine mimics of the oxacarbenium ion transition state

Ricin A-chain (RTA) catalyzes the hydrolytic depurination of a specific adenosine at position 4324 of 28S rRNA. Kinetic isotope effects on the hydrolysis of a small 10mer stem-tetraloop oligonucleotide substrate established the mechanism of the reaction as D(N)*A(N), involving an oxacarbenium ion intermediate in a highly dissociative transition state. An inhibitor with a protonated 1,4-dideoxy-1,4-imino-D-ribitol moiety, a 4-azasugar mimic, at the depurination site in the tetraloop of a 14mer oligonucleotide with a 5 bp duplex stem structure had previously been shown to bind to RTA with a K(d) of 480 nM, which improved to 12 nM upon addition of adenine. Second-generation stem-tetraloop inhibitors have been synthesized that incorporate a methylene bridge between the nitrogen of a 1-azasugar mimic, namely, (3S,4R)-3-hydroxy-4-(hydroxymethyl)pyrrolidine, and substituents, including phenyl, 8-aza-9-deazaadenyl, and 9-deazaadenyl groups, that mimic the activated leaving group at the transition state. The values for the dissociation constants (K(i)) for these were 99 nM for the phenyl 10mer, 163 and 94 nM for the 8-aza-9-deazaadenyl 10- and 14mers, respectively, and 280 nM for the 9-deazaadenyl 14mer. All of these compounds are among the tightest binding molecules known for RTA. A related phenyl-substituted inhibitor with a deoxyguanosine on the 5'-side of the depurination site was also synthesized on the basis of stem-loop substrate specificity studies. This molecule binds with a K(i) of 26 nM and is the tightest binding "one-piece" inhibitor. 8-Aza-9-deaza- and 9-deazaadenyl substituents provide an increased pK(a) at N7, a protonation site en route to the transition state. The binding of these inhibitors is not improved relative to the binding of their phenyl counterpart, however, suggesting that RTA might also employ protonation at N1 and N3 of the adenine moiety to activate the substrate during catalysis. Studies with methylated adenines support this argument. That the various stem-loop inhibitors have similar potencies suggests that an optimal one-piece inhibitor remains to be identified. The second-generation inhibitors described here incorporate ribose mimics missing the 2-hydroxy group. On the basis of inhibition data and substrate specificity studies, the 2'-hydroxyl group at the depurination site seems to be critical for recruitment as well as catalysis by RTA.     

Repair of DNA containing Fapy.dG and its beta-C-nucleoside analogue by formamidopyrimidine DNA glycosylase and MutY

Fapy.dG is produced in DNA as a result of oxidative stress. Under some conditions Fapy.dG is formed in greater yields than 8-oxodG from a common chemical precursor. Recently, Fapy.dG and its C-nucleoside analogue were incorporated in chemically synthesized oligonucleotides at defined sites. Like 8-oxodG, Fapy.dG instructs DNA polymerase to misincorporate dA opposite it in vitro. The interactions of DNA containing Fapy.dG or the nonhydrolyzable analogue with Fpg and MutY are described. Fpg excises Fapy.dG (K(M) = 2.0 nM, k(cat) = 0.14 min(-1)) opposite dC approximately 17-fold more efficiently than when mispaired with dA, which is misinserted by DNA polymerase in vitro. Fpg also prefers to bind duplexes containing Fapy.dG.dC or beta-C-Fapy.dG.dC compared to those in which the lesion is opposite dA. MutY incises dA when it is opposite Fapy.dG and strongly binds duplexes containing the lesion or beta-C-Fapy.dG. Incision from Fapy.dG.dA is faster than from dG.dA mispairs but slower than from DNA containing 8-oxodG opposite dA. These data demonstrate that Fapy.dG closely resembles the interactions of 8-oxodG with two members of the GO repair pathway in vitro. The similar effects of Fapy.dG and 8-oxodG on DNA polymerase and repair enzymes in vitro raise the question as to whether Fapy.dG elicits similar effects in vivo.     

Ribosome-mediated folding of partially unfolded ricin A-chain

After endocytic uptake by mammalian cells, the cytotoxic protein ricin is transported to the endoplasmic reticulum, whereupon the A-chain must cross the lumenal membrane to reach its ribosomal substrates. It is assumed that membrane traversal is preceded by unfolding of ricin A-chain, followed by refolding in the cytosol to generate the native, biologically active toxin. Here we describe biochemical and biophysical analyses of the unfolding of ricin A-chain and its refolding in vitro. We show that native ricin A-chain is surprisingly unstable at pH 7.0, unfolding non-cooperatively above 37 degrees C to generate a partially unfolded state. This species has conformational properties typical of a molten globule, and cannot be refolded to the native state by manipulation of the buffer conditions or by the addition of a stem-loop dodecaribonucleotide or deproteinized Escherichia coli ribosomal RNA, both of which are substrates for ricin A-chain. By contrast, in the presence of salt-washed ribosomes, partially unfolded ricin A-chain regains full catalytic activity. The data suggest that the conformational stability of ricin A-chain is ideally poised for translocation from the endoplasmic reticulum. Within the cytosol, ricin A-chain molecules may then refold in the presence of ribosomes, resulting in ribosome depurination and cell death.     

NMR studies of the exocyclic 1,N6-ethenodeoxyadenosine adduct (epsilon dA) opposite deoxyguanosine in a DNA duplex. Epsilon dA(syn).dG(anti) pairing at the lesion site

Proton NMR studies are reported on the complementary d(C-A-T-G-G-G-T-A-C).d(G-T-A-C-epsilon A-C-A-T-G) nonanucleotide duplex (designated epsilon dA.dG 9-mer duplex), which contains exocyclic adduct 1,N6-ethenodeoxyadenosine positioned opposite deoxyguanosine in the center of the helix. The present study focuses on the alignment of dG5 and epsilon dA14 at the lesion site in the epsilon dA.dG 9-mer duplex at neutral pH. This alignment has been characterized by monitoring the NOEs originating from the NH1 proton of dG5 and the H2, H5, and H7/H8 protons of epsilon dA14 in the central d(G4-G5-G6).d(C13-epsilon A14-C15) trinucleotide segment of the epsilon dA.dG 9-mer duplex. These NOE patterns establish that epsilon dA14 adopts a syn glycosidic torsion angle that positions the exocyclic ring toward the major groove edge while all the other bases including dG5 adopt anti glycosidic torsion angles. We detect a set of intra- and interstrand NOEs between protons (exchangeable and nonexchangeable) on adjacent residues in the d(G4-G5-G6).d(C13-epsilon A14-C15) trinucleotide segment which establish formation of right-handed helical conformations on both strands and stacking of the dG5(anti).epsilon dA14(syn) pair between stable dG4.dC15 and dG6.dC13 pairs. The energy-minimized conformation of the central d(G4-G5-G6).d(C13-epsilon A14-C15) segment establishes that the dG5(anti).epsilon dA14(syn) alignment is stabilized by two hydrogen bonds from the NH1 and NH2-2 of dG5(anti) to N9 and N1 of epsilon dA14(syn), respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ribosomal RNA identity elements for ricin A-chain recognition and catalysis

Ricin is a cytotoxic protein that inactivates ribosomes by hydrolyzing the N-glycosidic bond between the base and the ribose at position A4324 in eukaryotic 28 S rRNA. The requirements for the recognition by ricin A-chain of this nucleotide and for the catalysis of cleavage were examined using a synthetic oligoribonucleotide that reproduces the sequence and the secondary structure of the RNA domain (a helical stem, a bulged nucleotide, and a 17-member single-stranded loop). The wild-type RNA (35mer) and a number of mutants were transcribed in vitro from synthetic DNA templates with phage T7 RNA polymerase. With the wild-type oligoribonucleotide the ricin A-chain catalyzed reaction has a Km of 13.55 microM and a Kcat of 0.023 min-1. Recognition and catalysis by ricin A-chain has an absolute requirement for A at the position that corresponds to 4324. The helical stem is also essential; however, the number of base-pairs can be reduced from the seven found in 28 S rRNA to three without loss of identity. The nature of these base-pairs can affect catalysis. A change of the second set from one canonical (G.C) to another (U.A) reduces sensitivity to ricin A-chain; whereas, a change of the third pair (U.A----G.C) produces supersensitivity. The bulged nucleotide does not contribute to identification. Hydrolysis is affected by altering the nucleotides in the universal sequence surrounding A4324 or by changing the position in the loop of the tetranucleotide GA(ricin)GA: all of these mutants have a null phenotype. If ribosomes are treated first with alpha-sarcin to cleave the phosphodiester bond at G4325 ricin can still catalyze depurination at A4324. This implies that cleavage by alpha-sarcin at the center of what has been presumed to be a 17 nucleotide single-stranded loop in 28 S rRNA produces ends that are constrained in some way. On the other hand, hydrolysis by alpha-sarcin of the corresponding position in the synthetic oligoribonucleotide prevents recognition by ricin A-chain. The results suggest that the loop has a complex structure, affected by ribosomal proteins, and this bears on the function in protein synthesis of the alpha-sarcin/ricin rRNA domain.     

Binding of ricin A-chain to negatively charged phospholipid vesicles leads to protein structural changes and destabilizes the lipid bilayer

Ricin is a heterodimeric protein toxin in which a catalytic polypeptide (the A-chain or RTA) is linked by a disulfide bond to a cell-binding polypeptide (the B-chain or RTB). During cell entry, ricin undergoes retrograde vesicular transport to reach the endoplasmic reticulum (ER) lumen, from where RTA translocates into the cytosol, probably by masquerading as a substrate for the ER-associated protein degradation (ERAD) pathway. In partitioning studies in Triton X-114 solution, RTA is predominantly found in the detergent phase, whereas ricin holotoxin, native RTB, and several single-chain ribosome-inactivating proteins (RIPs) are in the aqueous phase. Fluorescence spectroscopy and far-UV circular dichroism (CD) demonstrated significant structural changes in RTA as a result of its interaction with liposomes containing negatively charged phospholipid (POPG). These lipid-induced structural changes markedly increased the trypsin sensitivity of RTA and, on the basis of the protein fluorescence determinations, abolished its ability to bind to adenine, the product resulting from RTA-catalyzed depurination of 28S ribosomal RNA. RTA also released trapped calcein from POPG vesicles, indicating that it destabilized the lipid bilayer. We speculate that membrane-induced partial unfolding of RTA during cell entry may facilitate its recognition as an ERAD substrate.     

Common and distinctive features of GNRA tetraloops based on a GUAA tetraloop structure at 1.4 A resolution

GNRA tetraloops (N is A, C, G, or U; R is A or G) are basic building blocks of RNA structure that often interact with proteins or other RNA structural elements. Understanding sequence-dependent structural variation among different GNRA tetraloops is an important step toward elucidating the molecular basis of specific GNRA tetraloop recognition by proteins and RNAs. Details of the geometry and hydration of this motif have been based on high-resolution crystallographic structures of the GRRA subset of tetraloops; less is known about the GYRA subset (Y is C or U). We report here the structure of a GUAA tetraloop determined to 1.4 A resolution to better define these details and any distinctive features of GYRA tetraloops. The tetraloop is part of a 27-nt structure that mimics the universal sarcin/ricin loop from Escherichia coli 23S ribosomal RNA in which a GUAA tetraloop replaces the conserved GAGA tetraloop. The adenosines of the GUAA tetraloop form an intermolecular contact that is a commonplace RNA tertiary interaction called an A-minor motif. This is the first structure to reveal in great detail the geometry and hydration of a GUAA tetraloop and an A-minor motif. Comparison of tetraloop structures shows a common backbone geometry for each of the eight possible tetraloop sequences and suggests a common hydration. After backbone atom superposition, equivalent bases from different tetraloops unexpectedly depart from coplanarity by as much as 48 degrees. This variation displaces the functional groups of tetraloops implicated in protein and RNA binding, providing a recognition feature.     

Structural Insights into the Neutralization Mechanism of Monoclonal Antibody 6C2 against Ricin

Ricin belongs to the type II ribosome-inactivating proteins that depurinate the universally conserved α-sarcin loop of rRNA. The RNA N-glycosidase activity of ricin also largely depends on the ribosomal proteins that play an important role during the process of rRNA depurination. Therefore, the study of the interaction between ricin and the ribosomal elements will be better to understand the catalysis mechanism of ricin. The antibody 6C2 is a mouse monoclonal antibody exhibiting unusually potent neutralizing ability against ricin, but the neutralization mechanism remains unknown. Here, we report the 2.8 Å crystal structure of 6C2 Fab in complex with the A-chain of ricin (RTA), which reveals an extensive antigen-antibody interface that contains both hydrogen bonds and van der Waals contacts. The complementarity-determining region loops H1, H2, H3, and L3 form a pocket to accommodate the epitope on the RTA (residues Asp⁹⁶–Thr¹¹⁶). ELISA results show that Gln⁹⁸, Glu⁹⁹, Glu¹⁰², and Thr¹⁰⁵ (RTA) are the key residues that play an important role in recognizing 6C2. With the perturbation of the 6C2 Fab-RTA interface, 6C2 loses its neutralization ability, measured based on the inhibition of protein synthesis in a cell-free system. Finally, we propose that the neutralization mechanism of 6C2 against ricin is that the binding of 6C2 hinders the interaction between RTA and the ribosome and the surface plasmon resonance and pulldown results confirm our hypothesis. In short, our data explain the neutralization mechanism of mAb 6C2 against ricin and provide a structural basis for the development of improved antibody drugs with better specificity and higher affinity.     

The RNA N-glycosidase activity of ricin A-chain

The RNA N-glycosidase activity of ricin A-chain has been characterized. When rat liver ribosomes were used as substrates, the A-chain cleaved the N-glycosidic bond at A-4324 in 28S rRNA. An apparent Michaelis constant (Km) for the reaction was determined to be 2.6 microM and the turnover number (Kcat) was 1777 min-1. When naked rRNA was the substrate, the A-chain cleaved the same bond in 28S rRNA but at a greatly reduced rate. The Km value was 5.8 microM. The results suggest that the A-chain has a similar affinity for 28S rRNA in both ribosomes and the naked states. When the deproteinized Escherichia coli rRNA was the substrates, ricin A-chain cleaved a N-glycosidic bond at A-2600 in 23S rRNA which corresponds to the ricin-site in 28S rRNA of rat liver ribosomes, while the A-chain has little activity on 23S rRNA in the ribosomes. The results suggest that ricin A-chain acts directly on RNA by recognizing a certain structure in the molecules. Using the secondary structure models for each species of rRNA, we have deduced a loop and stem structure having GAGA in the loop to be a minimum requirement for the substrate of ricin A-chain.     

The effect of mutations surrounding and within the active site on the catalytic activity of ricin A chain.

Models for the binding of the sarcin-ricin loop (SRL) of 28S ribosomal RNA to ricin A chain (RTA) suggest that several surface exposed arginine residues surrounding the active site cleft make important interactions with the RNA substrate. The data presented in this study suggest differing roles for these arginyl residues. Substitution of Arg48 or Arg213 with Ala lowered the activity of RTA 10-fold. Furthermore, substitution of Arg213 with Asp lowered the activity of RTA 100-fold. The crystal structure of this RTA variant showed it to have an unaltered tertiary structure, suggesting that the positively charged state of Arg213 is crucial for activity. Substitution of Arg258 with Ala had no effect on activity, although substitution with Asp lowered activity 10-fold. Substitution of Arg134 prevented expression of folded protein, suggesting a structural role for this residue. Several models have been proposed for the binding of the SRL to the active site of RTA in which the principal difference lies in the conformation of the second 'G' in the target GAGA motif in the 28S rRNA substrate. In one model, the sidechain of Asn122 is proposed to make interactions with this G, whereas another model proposes interactions with Asp75 and Asn78. Site-directed mutagenesis of these residues of RTA favours the first of these models, as substitution of Asn78 with Ser yielded an RTA variant whose activity was essentially wild-type, whereas substitution of Asn122 reduced activity 37.5-fold. Substitution of Asp75 failed to yield significant folded protein, suggesting a structural role for this residue.     

Pokeweed antiviral protein isoforms PAP-I, PAP-II, and PAP-III depurinate RNA of human immunodeficiency virus (HIV)-1.

Pokeweed antiviral protein (PAP) is a naturally occurring broad-spectrum antiviral agent with potent anti-human immunodeficiency virus (HIV)-1 activity by an as yet undeciphered molecular mechanism. In the present study, we sought to determine if PAP is capable of recognizing and depurinating viral RNA. Depurination of viral RNA was monitored by directly measuring the amount of the adenine base released from the viral RNA species using quantitative high-performance liquid chromatography. Our findings presented herein provide direct evidence that three different PAP isoforms from Phytolacca americana (PAP-I from spring leaves, PAP-II from early summer leaves, and PAP-III from late summer leaves) cause concentration-dependent depurination of genomic RNA (63 to 400 pmols of adenine released per micrograms of RNA) purified from human immunodeficiency virus type-I (HIV-I), plant virus (tobacco mosaic virus (TMV), and bacteriophage (MS 2). In contrast to the three PAP isoforms, ricin A chain (RTA) failed to cause detectable depurination of viral RNA even at 5 microM, although it was as effective as PAP in inhibiting protein synthesis in cell-free translation assays. PAP-I, PAP-II, and PAP-III (but not RTA) inhibited the replication of HIV-1 in human peripheral blood mononuclear cells with IC(50) values of 17 nM, 25 nM, and 16 nM, respectively. These findings indicate that the highly conserved active site residues responsible for the depurination of rRNA by PAP or RTA are not sufficient for the recognition and depurination of viral RNA. Our study prompts the hypothesis that the potent antiviral activity of PAP may in part be due to its unique ability to extensively depurinate viral RNA, including HIV-1 RNA.