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.     

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.     

Non-specific depurination activity of saporin-S6, a ribosome-inactivating protein, under acidic conditions

Among five ribosome-inactivating proteins tested only saporin-S6 could efficiently release the adenine from adenosine 20 of the synthetic oligoribonucleotide (SRD RNA) mimic of the sarcin/ricin domain of rat 28S rRNA with a Km of 9 microM and a kcat of approximately 0.4 min(-1) at pH 7.6. The optimal pH for the depurination activity of saporin-S6 is 5.0. However, saporin-S6 lost its site-specificity of depurination on SRD RNA around the optimal pH. The non-specific depurination activity of saporin-S6 was dependent on the enzyme concentration and pH conditions. These results are valuable to understand the diversity and the depurination mechanism of ribosome-inactivating proteins.     

Eukaryotic elongation factor 2 can bind to the synthetic oligoribonucleotide that mimics sarcin/ricin domain of rat 28S ribosomal RNA

Eukaryotic elongation factor 2 (eEF2) catalyzes the translocation of peptidyl-tRNA from the A site to P site by binding to the ribosome. In this work, the complex formation of rat liver eEF2 with a synthetic oligoribonucleotide (SRD RNA) that mimics sarcin/ricin domain of rat 28S ribosomal RNA is invested in vitro. Purified eEF2 can specifically bind SRD RNA to form a stable complex. tRNA competes with SRD RNA in binding to eEF2 in a less extent. Pretreatment of eEF2 with GDP or ADP-ribosylation of eEF2 by diphtheria toxin can obviously reduce the ability of eEF2 to form the complex with the synthetic oligoribonucleotide. These results indicate that eEF2 is likely to bind directly to the sarcin/ricin domain of 28S ribosomal RNA in the process of protein synthesis.     

Nonspecific deadenylation on sarcin/ricin domain RNA catalyzed by gelonin under acidic conditions

Gelonin is a single-chain ribosome-inactivating protein that can hydrolyze the glycosidic bond of a highly conserved adenosine residue in the sarcin/ricin domain (SRD) of the largest RNA in ribosome and thus irreversibly inhibit protein synthesis. Recently, the specificity in substrate recognition was challenged by the fact that gelonin could remove adenines from some other oligoribonucleotide substrates. However, the site specificity of gelonin to deadenylate various substrates were unknown. Hereby, the effect of pH values upon site specificity of the deadenylation activity of gelonin was studied using the synthetic oligoribonucleotide (named SRD RNA) that mimicked the ribosomal SRD. Interestingly, gelonin gradually acquired the ability to nonspecifically remove adenines from SRD RNA when pH values changed from neutral to acidic conditions. Another two SRD RNA mutants, either with the conserved adenosine deleted or with the tetraloop converted, showed very similar cleavage style to wild-type SRD RNA, underscoring the important role of pH value in site specificity of recognition by gelonin. Furthermore, the RNA N-glycosidase activity of gelonin was also enhanced with the decreasing of pH values. In addition, no obvious change was observed in the molecular conformation of gelonin at various pH values. Taken together, our data implied that the protonation of adenosines in SRD RNA was potentially an important factor for the nonspecific deadenlyation by gelonin.     

A translational fidelity mutation in the universally conserved sarcin/ricin domain of 25S yeast ribosomal RNA.

Recent evidence suggests that ribosomal RNAs have functional roles in translation. We describe here a new ribosomal RNA mutation that causes translational suppression and antibiotic resistance in eukaryotic cells. Using random mutagenesis of the cloned ribosomal RNA gene and in vivo selection, we isolated a C --> U mutation in the universally conserved sarcin/ricin domain in Saccharomyces cerevisiae 25S ribosomal RNA. This mutation changes the putative CG pair, which closes the GAGA tetraloop in the sarcin/ricin domain, into a weaker UG pair without eliminating ribosomal sensitivity to ricin. We show that suppression of several UGA, UAG, and frameshift mutations is evident when a portion of the cellular ribosomal RNA contains the C --> U mutation. Cells that contain essentially all mutant ribosomal RNA grow only 10% slower than the wild-type, but show increased suppression as well as resistance to paramomycin, G418, and hygromycin, and sensitivity to cycloheximide. Our results provide genetic evidence for the participation of the sarcin/ricin loop in maintaining translational accuracy and are discussed in terms of a hypothesis that this ribosomal RNA region normally undergoes a conformational change during translation.     

RIP and RALyase cleave the sarcin/ricin domain, a critical domain for ribosome function, during senescence of wheat coleoptiles

Type-I ribosome-inactivating protein (RIP), which is found in many plants, catalyzes depurination of a specific adenine in the sarcin/ricin domain (SRD) of the large rRNA causing loss of ribosomal activity. Previously, we found a RNA apurinic site-specific lyase (RALyase) that catalytically cleaved the phosphodiester bond at the RIP-dependent depurination site by β-elimination reaction. Here we show that both the RIP activity and RIP-RALyase-mediated cleavage of SRD in the cytoplasmic ribosome were induced at the late stage of senescence of wheat coleoptiles. Following this process, tissue death was observed. Furthermore, transgenic tobacco plants expressing glucocorticoid-induced RIP developed senescence-like phenotype. Our results suggest that ribosome inactivation due to the cleavage of SRD by the inducible RIP and constitutively expressed RALyase may be a unique plant system that mediates programmed cell death at the late senescent stage.     

Ricin A-chain substrate specificity in RNA, DNA, and hybrid stem-loop structures

Ricin toxin A-chain (RTA) is the catalytic subunit of ricin, a heterodimeric toxin from castor beans. Its ribosomal inactivating activity arises from depurination of a single adenine from position A(4324) in a GAGA tetraloop from 28S ribosomal RNA. Minimal substrate requirements are the GAGA tetraloop and stem of two or more base pairs. Depurination activity also occurs on stem-loop DNA with the same sequence, but with the k(cat) reduced 200-fold. Systematic variation of RNA 5'-G(1)C(2)G(3)C(4)[G(5)A(6)G(7)A(8)]G(9)C(10)G(11)C(12)-3' 12mers via replacement of each nucleotide in the tetraloop with a deoxynucleotide showed a 16-fold increase in k(cat) for A(6) --> dA(6) but reduced k(cat) up to 300-fold for the other sites. Methylation of individual 2'-hydroxyls in a similar experiment reduced k(cat) by as much as 3 x 10(-3)-fold. In stem-loop DNA, replacement of d[G(5)A(6)G(7)A(8)] with individual ribonucleotides resulted in small kinetic changes, except for the dA(6) --> A(6) replacement for which k(cat) decreased 6-fold. Insertion of d[G(5)A(6)G(7)A(8)] into an RNA stem-loop or G(5)A(6)G(7)A(8) into a DNA stem-loop reduced k(cat) by 30- and 5-fold, respectively. Multiple substitutions of deoxyribonucleotides into RNA stem-loops in one case (dG(5),dG(7)) decreased k(cat)/K(m) by 10(5)-fold, while a second change (dG(5),dA(8)) decreased k(cat) by 100-fold. Mapping these interactions on the structure of GAGA stem-loop RNA suggests that all the loop 2'-hydroxyl groups play a significant role in the action of ricin A-chain. Improved binding of RNA-DNA stem-loop hybrids provides a scaffold for inhibitor design. Replacing the adenosine of the RTA depurination site with deoxyadenosine in a small RNA stem-loop increased k(cat) 20-fold to 1660 min(-1), a value similar to RTA's k(cat) on intact ribosomes.     

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.     

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.     

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.     

A new class of enzyme acting on damaged ribosomes: ribosomal RNA apurinic site specific lyase found in wheat germ

A new enzyme, which we named ribosomal RNA apurinic site specific lyase (RALyase), is described. The protein was found in wheat embryos and has a molecular weight of 50 625 Da. The enzyme specifically cleaves the phosphodiester bond at the 3' side of the apurinic site introduced by ribosome-inactivating proteins into the sarcin/ricin domain of 28S rRNA. The 3' and 5' ends of wheat 28S rRNA at the cleavage site are 5'-GUACG-alpha-hydroxy-alpha, beta-unsaturated aldehyde and pGAGGA-3', demonstrating that the enzyme catalyzes a beta-elimination reaction. The substrate specificity of the enzyme is extremely high: it acts only at the apurinic site in the sarcin/ricin domain of intact ribosomes, not on deproteinized rRNA or DNA containing apurinic sites. The amino acid sequences of five endopeptidase LysC-liberated peptides from the purified enzyme were determined and used to obtain a cDNA sequence. The open reading frame encodes a protein of 456 amino acids, and a homology search revealed a related rice protein. Similar enzyme activities were also found in other plants that express ribosome-inactivating proteins. We believe that RALyase is part of a complex self-defense mechanism.     

Crystal structures of restrictocin-inhibitor complexes with implications for RNA recognition and base flipping.

The cytotoxin sarcin disrupts elongation factor binding and protein synthesis by specifically cleaving one phosphodiester bond in ribosomes. To elucidate the molecular basis of toxin action, we determined three cocrystal structures of the sarcin homolog restrictocin bound to different analogs that mimic the target sarcin/ricin loop (SRL) structure of the rat 28S rRNA. In these structures, restrictocin contacts the bulged-G motif and an unfolded form of the tetraloop of the SRL RNA. In one structure, toxin loops guide selection of the target site by contacting the base critical for recognition (G4319) and the surrounding S-shaped backbone. In another structure, base flipping of the tetraloop enables cleavage by placing the target nucleotide in the active site with the nucleophile nearly inline for attack on the scissile bond. These structures provide the first views of how a site-specific protein endonuclease recognizes and cleaves a folded RNA substrate.     

Isolation and enzymatic characterization of lamjapin, the first ribosome-inactivating protein from cryptogamic algal plant (Laminaria japonica A).

Lamjapin, a novel type Iota ribosome-inactivating protein, has been isolated from kelp (Laminaria japonica A), a marine alga. This protein has been extensively purified through multiple chromatography columns. With a molecular mass of approximately 36 kDa, lamjapin is slightly larger than the other known single-chain ribosome-inactivating proteins from the higher plants. Lamjapin can inhibit protein synthesis in rabbit reticulocyte lysate with an IC50 of 0.69 nm. It can depurinate at multiple sites of RNA in rat ribosome and produce the diagnostic R-fragment and three additional larger fragments after the aniline reaction. Lamjapin can deadenylate specifically at the site A20 of the synthetic oligoribonucleotide (35-mer) substrate that mimics the sarcin/ricin domain (SRD) of rat ribosomal 28S RNA. However, it cannot hydrolyze the N-C glycosidic bond of guanosine, cytidine or uridine at the corresponding site of the A20 of three mutant SRD RNAs. Lamjapin exhibits the same base and position requirement as the ribosome-inactivating proteins from higher plants. We conclude that lamjapin is an RNA N-glycosidase that belongs to the ribosome-inactivating protein family. This study reports for the first time that ribosome-inactivating protein exists in the lower cryptogamic algal plant.     

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.     

Molecular dynamics simulations of sarcin-ricin rRNA motif

Explicit solvent molecular dynamics (MD) simulations were carried out for sarcin–ricin domain (SRD) motifs from 23S (Escherichia coli) and 28S (rat) rRNAs. The SRD motif consists of GAGA tetraloop, G-bulged cross-strand A-stack, flexible region and duplex part. Detailed analysis of the overall dynamics, base pairing, hydration, cation binding and other SRD features is presented. The SRD is surprisingly static in multiple 25 ns long simulations and lacks any non-local motions, with root mean square deviation (r.m.s.d.) values between averaged MD and high-resolution X-ray structures of 1–1.4 Å. Modest dynamics is observed in the tetraloop, namely, rotation of adenine in its apex and subtle reversible shift of the tetraloop with respect to the adjacent base pair. The deformed flexible region in low-resolution rat X-ray structure is repaired by simulations. The simulations reveal few backbone flips, which do not affect positions of bases and do not indicate a force field imbalance. Non-Watson–Crick base pairs are rigid and mediated by long-residency water molecules while there are several modest cation-binding sites around SRD. In summary, SRD is an unusually stiff rRNA building block. Its intrinsic structural and dynamical signatures seen in simulations are strikingly distinct from other rRNA motifs such as Loop E and Kink-turns.     

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.     

Enzymatic specificity of three ribosome-inactivating proteins against fungal ribosomes,and correlation with antifungal activity

Ribosome-inactivating proteins (RIPs) are enzymes that cleave a specific adenine base from the highly conserved sarcin/ricin (S/R) loop of the large ribosomal RNA, thus arresting protein synthesis at the translocation step. In the present study, we employed three RIPs to dissect the antifungal activity of RIPs as plant defense proteins. We measured the catalytic activity of RAT (the catalytic A-chain of ricin from Ricinus communis L.), saporin-S6 (from Saponaria officinalis L.), and ME (RIP from Mirabilis expansa R&P) against intact ribosomal substrates isolated from various pathogenic fungi. We further determined the enzymatic specificity of these three RIPs against fungal ribosomes, from Rhizoctonia solani Kuhn, Alternaria solani Sorauer, Trichoderma reesei Simmons and Candida albicans Berkhout, and correlated the data with antifungal activity. RAT showed the strongest toxicity against all tested fungal ribosomes, except for the ribosomes isolated from C. albicans, which were most susceptible to saporin. RAT and saporin showed higher enzymatic activity than ME against ribosomes from all of the fungal species assayed, but did not show detectable antifungal activity. In contrast, ME showed substantial inhibitory activity against fungal growth. Using N-hydroxysuccinimide-fluorescein labeling of RIPs and fluorescence microscopy, we determined that ME was targeted to the surface of fungal cells and transferred into the cells. Thus, ME caused ribosome depurination and subsequent fungal mortality. In contrast, saporin did not interact with fungal cells, correlating with its lack of antifungal activity.     

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.     

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.