The C-terminal end of P proteins mediates ribosome inactivation by trichosanthin but does not affect the pokeweed antiviral protein activity

Ribosome inactivating proteins (RIPs) inhibit protein synthesis depurinating a conserved residue in the sarcin/ricin loop of ribosomes. Some RIPs are only active against eukaryotic ribosomes, but other RIPs inactivate with similar efficiency prokaryotic and eukaryotic ribosomes, suggesting that different RIPs would interact with different proteins. The SRL in Trypanosoma cruzi ribosomes is located on a 178b RNA molecule named 28Sδ. In addition, T. cruzi ribosomes are remarkably resistant to TCS. In spite of these peculiarities, we show that TCS specifically depurinate the predicted A⁵¹ residue on 28Sδ. We also demonstrated that the C-terminal end of ribosomal P proteins is needed for full activity of the toxin. In contrast to TCS, PAP inactivated efficiently T.cruzi ribosomes, and most importantly, does not require from the C-terminal end of P proteins. These results could explain, at least partially, the different selectivity of these toxins against prokaryotic and eukaryotic ribosomes.     

Chemical modifications of pokeweed antiviral protein: effects upon ribosome inactivation, antiviral activity and cytotoxicity

Pokeweed antiviral protein (PAP) is a protein known to inactivate eukaryotic ribosomes by an unknown enzymatic action and inhibit the production of mammalian viruses in tissue culture. This protein was subjected to a variety of chemical modifications to determine their effects upon ribosomal inactivation, antiviral action, and cytotoxicity. It was found that modifications of a number of different amino acid residues had similar effects upon all 3 activities. Also the inactivation of PAP with diethylpyrocarbonate was not due to its reaction with a histidine residue but to a modification of an unidentified amino acid residue.     

Cloning of a cDNA encoding a new ribosome-inactivating protein from Beta vulgaris vulgaris (mangold)

By means of a λZAP II cDNA library constructed from seedlings of Beta vulgaris vulgaris and immunoscreening, a cDNA clone containing a partial sequence of a new ribosome-inactivating protein (RIP) was obtained. As confirmed by Western blot analysis, this clone produced a RIP upon induction with IPTG. We called it betavulgin (Bvg). The recombinant protein (re-Bvg) was somewhat smaller than plant-derived RIP (28 versus 30 and 32 kDa), but showed the specific N-glycosidase activity on tobacco ribosomes, confirming its RIP character. The cDNA was sequenced and the missing 5'-end was established by RACE using bvg-specific primers. The entire cDNA was 1080 nucleotides in length and encoded a protein of 272 amino acids with a sequence identity of 26–40% with other RIP.     

A non-toxic pokeweed antiviral protein mutant inhibits pathogen infection via a novel salicylic acid-independent pathway

Pokeweed antiviral protein (PAP), a ribosome-inactivating protein isolated from Phytolacca americana, is characterized by its ability to depurinate the sarcin/ricin (S/R) loop of the large rRNA of prokaryotic and eukaryotic ribosomes. In this study, we present evidence that PAP is associated with ribosomes and depurinates tobacco ribosomes in vivo by removing more than one adenine and a guanine. A mutant of pokeweed antiviral protein, PAPn, which has a single amino acid substitution (G75D), did not bind ribosomes efficiently, indicating that Gly-75 in the N-terminal domain is critical for the binding of PAP to ribosomes. PAPn did not depurinate ribosomes and was non-toxic when expressed in transgenic tobacco plants. Unlike wild-type PAP and a C-terminal deletion mutant, transgenic plants expressing PAPn did not have elevated levels of acidic pathogenesis-related (PR) proteins. PAPn, like other forms of PAP, did not trigger production of salicylic acid (SA) in transgenic plants. Expression of the basic PR proteins, the wound-inducible protein kinase and protease inhibitor II, was induced in PAPn-expressing transgenic plants and these plants were resistant to viral and fungal infection. These results demonstrate that PAPn activates a particular SA-independent, stress-associated signal transduction pathway and confers pathogen resistance in the absence of ribosome binding, rRNA depurination and acidic PR protein production.     

Production of pokeweed antiviral proteins nontoxic to cells by Mutagenesis of PAP-cDNA

Pokeweed antiviral protein (PAP), one of ribosome inactivating proteins (RIPs), has very strong toxicity both to prokaryotic and eukaryotic cells. To produce mutant PAPs nontoxic to cells, the PAP-cDNA was inserted into a yeast-E.coli shuttle vector under the control of galactose promoter, mutagenized using hydroxylamine, and transformed into yeast cells. Transformed yeast cells were selected on the uracil-deficient plate containing glucose or raffinose, and the yeast cells producing mutant PAPs nontoxic to cells were then selected on the galactose plate. Eighteen mutants were obtained by immunoblot analyses of 1,000 transformants: among them, three, ten and five mutants produced unprocessed, mature and truncated PAPs, respectively. Fourteen PAP mutants among them did not inhibit the yeast cell growth, and showed no or less inhibition of protein synthesisin vitro. Six among fourteen mutants were able to protect TMV infection in coinoculation experiment. The mutant PAPs showing an antiviral activity either without or reduced RIP activity contain neither the active site mutation nor C-terminal deletion mutation. These results suggest that both the RIP activity and the antiviral activity will require other amino acid residue(s) besides the active site and that the antiviral acitivity of PAP can be dissociated from its toxicity.     

Development of a cell-free translation system from Cucumis melo: preparation, optimization and evaluation of sensitivity to some translational inhibitors

A very active cell-free translation system was prepared from 4–5-day-old embryonic axes of melon (Cucumis melo L.), a species whose dry seeds contain a powerful translational inhibitor. The system was optimized for Mg²⁺, K⁺, NH₄⁺, high speed supernatant, total wheat germ tRNA, time and temperature. Using a 30 000 × g supernatant, the system translates endogenous messengers and polyuridylic acid very efficiently. Melon ribosomes were inhibited in vitro by several well-known eukaryotic inhibitors including melonin, the protein inhibitor present in the dry seeds of C. melo. Our results suggest that the protein inhibitor does not affect the activity of melon ribosomes neither in vivo nor during their isolation.     

The C-terminus of pokeweed antiviral protein has distinct roles in transport to the cytosol, ribosome depurination and cytotoxicity

Pokeweed antiviral protein (PAP) produced by pokeweed plants is a single-chain (type I) ribosome-inactivating protein (RIP) that depurinates ribosomes at the alpha-sarcin/ricin loop of the large rRNA, resulting in inhibition of translation. Unlike the type II RIPs, which have an active and a binding moiety, PAP has only the active moiety. The mechanism by which toxins without a binding moiety gain access to cytosolic ribosomes is not known. We set up yeast as a simple and genetically tractable system to investigate how PAP accesses ribosomes and showed that the mature form of PAP is targeted to the cytosol from the endomembrane system in yeast. In the present study, we performed a systematic deletion analysis to identify the signal required for transport of PAP to the cytosol. We demonstrate here that processing of the C-terminal extension and sequences at the C-terminus of the mature protein are critical for its accumulation in the cytosol. Using a series of PAP mutants, we identified the C-terminal signal and demonstrated that it is distinct from the sequences required for ribosome depurination and cytotoxicity. The C-terminal motif showed sequence similarity to type II RIPs that retrotranslocate from the endoplasmic reticulum to the cytosol. These results demonstrate that a conserved sequence at the C-terminus of a type I RIP mediates its transport to the cytosol and suggest that type I and II RIPs may use a common signal to enter the cytosol.     

The ribosomal stalk is required for ribosome binding,depurination of the rRNA and cytotoxicity of ricin A chain in Saccharomyces cerevisiae

Ribosome inactivating proteins (RIPs) like ricin, pokeweed antiviral protein (PAP) and Shiga‐like toxins 1 and 2 (Stx1 and Stx2) share the same substrate, the α‐sarcin/ricin loop, but differ in their specificities towards prokaryotic and eukaryotic ribosomes. Ricin depurinates the eukaryotic ribosomes more efficiently than the prokaryotic ribosomes, while PAP can depurinate both types of ribosomes. Accumulating evidence suggests that different docking sites on the ribosome might be used by different RIPs, providing a basis for understanding the mechanism underlying their kingdom specificity. Our previous results demonstrated that PAP binds to the ribosomal protein L3 to depurinate the α‐sarcin/ricin loop and binding of PAP to L3 was critical for its cytotoxicity. Here, we used surface plasmon resonance to demonstrate that ricin toxin A chain (RTA) binds to the P1 and P2 proteins of the ribosomal stalk in Saccharomyces cerevisiae. Ribosomes from the P protein mutants were depurinated less than the wild‐type ribosomes when treated with RTA in vitro. Ribosome depurination was reduced when RTA was expressed in the ΔP1 and ΔP2 mutants in vivo and these mutants were more resistant to the cytotoxicity of RTA than the wild‐type cells. We further show that while RTA, Stx1 and Stx2 have similar requirements for ribosome depurination, PAP has different requirements, providing evidence that the interaction of RIPs with different ribosomal proteins is responsible for their ribosome specificity.     

Correlation between the activities of five ribosome-inactivating proteins in depurination of tobacco ribosomes and inhibition of tobacco mosaic virus infection

The rRNA depurination activities of five ribosome-inactivating proteins (RIPs) were compared in vitro using yeast and tobacco leaf ribosomes as substrates. All of the RIPs (pokeweed antiviral protein (PAP), dianthin 32, tritin, barley RIP and ricin A-chain) were active on yeast ribosomes. PAP and dianthin 32 were highly active and ricin A-chain weakly active on tobacco ribosomes, whereas tritin and barley RIP were inactive. PAP and dianthin 32 were highly effective in inhibiting the formation of local lesions caused by tobacco mosaic virus (TMV) on tobacco leaves, whereas tritin, barley RIP and ricin A-chain were ineffective. The apparent anomaly between the in vitro rRNA depurination activity, but lack of antiviral activity of ricin A-chain was further investigated by assaying for rRNA depurination in situ following the topical application of the RIP to leaves. No activity was detected, a finding consistent with the apparent lack of antiviral activity of this RIP. Thus, it is concluded that there is a positive correlation between RIP-catalysed depurination of tobacco ribosomes and antiviral activity which gives strong support to the hypothesis that the antiviral activity of RIPs works through ribosome inactivation.     

Active center cleft residues of pokeweed antiviral protein mediate its high-affinity binding to the ribosomal protein L3

Pokeweed antiviral protein (PAP) is a ribosome-inactivating protein (RIP) which catalytically cleaves a specific adenine base from the highly conserved alpha-sarcin/ricin loop (SRL) of the large ribosomal RNA and thereby inhibits the protein synthesis. The ribosomal protein L3, a highly conserved protein located at the peptidyltransferase center of the ribosomes, is involved in binding of PAP to ribosomes and subsequent depurination of the SRL. We have recently discovered that recombinant PAP mutants with alanine substitution of the active center cleft residues (69)NN(70) (FLP-4) and (90)FND(92) (FLP-7) that are not directly involved in the catalytic depurination at the active site exhibit >150-fold reduced ribosome inhibitory activity [(2000) J. Biol. Chem. 275, 3382--3390]. We hypothesized that the partially exposed half of the active site cleft could be the potential docking site for the L3 molecule. Our modeling studies presented herein indicated that PAP residues 90--96, 69--70, and 118--120 potentially interact with L3. Therefore, mutations of these residues were predicted to result in destabilization of interactions with rRNA and lead to a lower binding affinity with L3. In the present structure-function relationship study, coimmunoprecipitation assays with an in vitro synthesized yeast ribosomal protein L3 suggested that these mutant PAP proteins poorly interact with L3. The binding affinities of the mutant PAP proteins for ribosomes and recombinant L3 protein were calculated from rate constants and analysis of binding using surface plasmon resonance biosensor technology. Here, we show that, compared to wild-type PAP, FLP-4/(69)AA(70) and FLP-7/(90)AAA(92) exhibit significantly impaired affinity for ribosomes and L3 protein, which may account for their inability to efficiently inactivate ribosomes. By comparison, recombinant PAP mutants with alanine substitutions of residues (28)KD(29) and (111)SR(112) that are distant from the active center cleft showed normal binding affinity to ribosomes and L3 protein. The single amino acid mutants of PAP with alanine substitution of the active center cleft residues N69 (FLP-20), F90 (FLP-21), N91 (FLP-22), or D92 (FLP-23) also showed reduced ribosome binding as well as reduced L3 binding, further confirming the importance of the active center cleft for the PAP--ribosome and PAP--L3 interactions. The experimental findings presented in this report provide unprecedented evidence that the active center cleft of PAP is important for its in vitro binding to ribosomes via the L3 protein.     

Hymenoic acid, a novel specific inhibitor of human DNA polymerase lambda from a fungus of Hymenochaetaceae sp

Hymenoic acid (1) is a natural compound isolated from cultures of a fungus, Hymenochaetaceae sp., and this structure was determined by spectroscopic analyses. Compound 1 is a novel sesquiterpene, trans-4-[(1′E,5′S)-5′-carboxy-1′-methyl-1′-hexenyl]cyclohexanecarboxylic acid. This compound selectively inhibited the activity of human DNA polymerase λ (pol λ) in vitro, and 50% inhibition was observed at a concentration of 91.7 μM. Compound 1 did not influence the activities of the other seven mammalian pols (i.e., pols , γ, δ, ε, η, ι, and κ), but also showed no effect even on the activity of pol β, which is thought to have a very similar three-dimensional structure to the pol β-like region of pol λ. This compound also did not inhibit the activities of prokaryotic pols and other DNA metabolic enzymes tested. These results suggested that compound 1 could be a selective inhibitor of eukaryotic pol λ. This compound had no inhibitory activities against two N-terminal truncated pol λ, del-1 pol λ (lacking nuclear localization signal (NLS), BRCA1 C-terminus (BRCT) domain [residues 133–575]), and del-2 pol λ (lacking NLS, BRCT, domain and proline-rich region [residues 245–575]). The compound 1-induced inhibition of intact pol λ activity was non-competitive with respect to both the DNA template-primer and the dNTP substrate. On the basis of these results, the pol λ inhibitory mechanism of compound 1 is discussed.     

A new member of YER057c family in Trypanosoma cruzi is adjacent to an ABC-transporter

Tcp17 is a Trypanosoma cruzi gene located contiguous to the ABC-transporter tcpgp2. The protein contains 160 amino acid residues with a predicted molecular mass of 16.5 kDa. Western blot analysis using a polyclonal antiserum against recombinant TCP17 revealed that the protein is only expressed in the epimastigote form of the parasite; we did not detect the protein either in the amastigote or trypomastigote forms. A sequence comparison of TCP17 showed a remarkable homology with a conserved family of prokaryotic and eukaryotic proteins called YER057c whose function has not yet been characterized. Here, we propose a new signature of this family considering the N-terminal: [IV]–X(4)–[AV]–[AP]–X–[AP]–X(3)–Y–X(9)–[LIVF]–X(2)–[SA]–G–[QS], and the C-terminal: [AT]–R–X(2)–[IVFY]–X–[VC]–X(2)–L–P–X(4)–[LIVM]–E–[IVM]–[DE] motifs. Immunofluorescence and immunoelectron microscopy studies suggest that the protein has a wide distribution in the cell, with a higher concentration in the external side of the plasma membrane, on the Golgi complex and on cytoplasmic vacuoles. Although the physiological function of TCP17 is unknown, its conservation in evolution suggests biological relevance in the parasite.     

Inhibition of Pokeweed Antiviral Protein (PAP) by Turnip Mosaic Virus Genome-linked Protein (VPg)

Pokeweed antiviral protein (PAP) from Phytolacca americana is a ribosome-inactivating protein (RIP) and an RNA N-glycosidase that removes specific purine residues from the sarcin/ricin loop of large rRNA, arresting protein synthesis at the translocation step. PAP is also a cap-binding protein and is a potent antiviral agent against many plant, animal, and human viruses. To elucidate the mechanism of RNA depurination, and to understand how PAP recognizes and targets various RNAs, the interactions between PAP and turnip mosaic virus genome-linked protein (VPg) were investigated. VPg can function as a cap analog in cap-independent translation and potentially target PAP to uncapped IRES-containing RNA. In this work, fluorescence spectroscopy and HPLC techniques were used to quantitatively describe PAP depurination activity and PAP-VPg interactions. PAP binds to VPg with high affinity (29.5 nm); the reaction is enthalpically driven and entropically favored. Further, VPg is a potent inhibitor of PAP depurination of RNA in wheat germ lysate and competes with structured RNA derived from tobacco etch virus for PAP binding. VPg may confer an evolutionary advantage by suppressing one of the plant defense mechanisms and also suggests the possible use of this protein against the cytotoxic activity of ribosome-inactivating proteins.     

Low-level ectopic expression of Fushi tarazu in Drosophila melanogaster results in ftz(Ual/Rpl)-like phenotypes and rescues ftz phenotypes

The protein encoded by the Drosophila pair-rule gene fushi tarazu (ftz) is required for the formation of the even-numbered parasegments. Here we analyze the phenotypes of ectopic expression of FTZ and FTZ protein deletions from the Tubulin 1 (Tub1) promoter. Fusion of ftz to the Tub1 promoter resulted in low-level ectopic expression of FTZ relative to FTZ expressed from the endogenous ftz gene. The effects of ectopic expression of four FTZ proteins, FTZ^1–413 (full length wild-type FTZ), FTZ^Δ257–316 (a complete deletion of the HD), FTZ^Δ101–150 (a deletion that includes the major FTZ-F1 binding site) and FTZ^Δ151–209 were determined. Ectopic expression of FTZ^1–413, FTZ^Δ257–316 and FTZ^Δ101–151 did not result in an anti-ftz phenotype; however, ectopic expression of FTZ^1–413, and FTZ^Δ257–316 did result in a ftz^Ual/Rpl-like phenotype. In addition, low-level ectopic expression of FTZ^1–413 and FTZ^Δ257–316 rescued ftz phenotypes. This was an important observation because the even-numbered parasegment pattern of FTZ expression is considered important for normal segmentation. Therefore, the rescue of ftz phenotypes by low-level FTZ expression in all cells of the embryo suggests that the even-numbered parasegment expression pattern of FTZ is not the sole factor restricting FTZ action. Low-level ectopic expression of FTZ^Δ151–209 resulted in the anti-ftz phenotype and rescued hypomorphic ftz-f1 phenotypes indicating that FTZ^Δ151–209 is a hyperactive FTZ molecule. Therefore, the region encompassing amino acids 151–209 of FTZ is required in some manner for repression of FTZ activity. These results are discussed in relation to the current understanding of the mechanism of FTZ action.     

Single-chain ribosome inactivating proteins from plants depurinate Escherichia coli 23S ribosomal RNA.

The rRNA N-glycosidase activities of the catalytically active A chains of the heterodimeric ribosome inactivating proteins (RIPs) ricin and abrin, the single-chain RIPs dianthin 30, dianthin 32, and the leaf and seed forms of pokeweed antiviral protein (PAP) were assayed on E. coli ribosomes. All of the single-chain RIPs were active on E. coli ribosomes as judged by the release of a 243 nucleotide fragment from the 3′ end of 23S rRNA following aniline treatment of the RNA. In contrast, E. coli ribosomes were refractory to the A chains of ricin and abrin. The position of the modification of 23S rRNA by dianthin 32 was determined by primer extension and found to be A₂₆₆₀, which lies in a sequence that is highly conserved in all species.     

Depurination of plant ribosomes by pokeweed antiviral protein

Mammalian ribosomes have been shown to be enzymatically modified by ribosomal inactivating protein (RIPs) via specific depurination of rRNA. Here we report that ribosomes isolated from wheat germ contain intact and undepurinated rRNA and are depurinated by pokeweed antiviral protein (PAP). Pokeweed ribosomes isolated under the same conditions are depurinated. Total RNA isolated from pokeweed in the presence of strong denaturants was found to pbe partially depurinated. We conclude that wheat germ ribosomes are resistant to the endogenous RIP, tritin, but are sensitive to PAP and that pokeweed ribosomes can be depurinated by the N-glycosidase activity of endogenous PAP during isolation.     

Solution conformation of brazzein by H nuclear magnetic resonance: resonance assignment and secondary structure

Brazzein is a sweet-tasting protein isolated from the fruit of the West African plant Pentadiplandra brazzeana Baillon. It is the smallest and the most water-soluble sweet protein discovered so far, it is also highly thermostable. The proton NMR study of brazzein at 600 MHz (pH 3.5, 300K) is presented. Complete sequence specific assignment of the individual backbone and sidechain proton resonances were achieved using through-bond and through-space connectivities obtained from standard two-dimensional NMR techniques. The secondary structure of brazzein contains one -helix (residues 21–29), one short 3₁₀-helix (residues 14–17), two strands of antiparallel β-sheet (residues 34–39, 44–50) and probably a third strand (residues 5–7) near the N-terminus.     

On the interaction of the synthetic 53–58 fragment of lac repressor with DNA

The hexapeptide fragment 53–58 of the lac repressor protein (Ala-Gln-Gln-Leu-Ala-Gly) was synthesized. Circular dichroic spectrum of the peptide has negative bands at 195 and 225 nm (weak). The hexapeptide, which has no basic residues, stabilized the AT rich Clostridium perfringens DNA, but had no effect, significantly, on the melting profile of either poly dA · poly dT or poly d(A-T)·poly d(A-T). The melting temperature of Micrococcus lysodeikticus DNA with a high GC content, was unaffected by the peptide.     

Substrate specificity of a maize ribosome-inactivating protein differs across diverse taxa.

The superfamily of ribosome-inactivating proteins (RIPs) consists of toxins that catalytically inactivate ribosomes at a universally conserved region of the large ribosomal RNA. RIPs carry out a single N-glycosidation event that alters the binding site of the translational elongational factor eEF1A and causes a cessation of protein synthesis that leads to subsequent cell death. Maize RIP1 is a kernel-specific RIP with the unusual property of being produced as a zymogen, proRIP1. ProRIP1 accumulates during seed development and becomes active during germination when cellular proteases remove acidic residues from a central domain and both termini. These deletions also result in RIP activation in vitro. However, the effectiveness of RIP1 activity against target ribosomes remains species-dependent. To determine the potential efficiency of maize RIP1 as a plant defense protein, we used quantitative RNA gel blots to detect products of RIP activity against intact ribosomal substrates from various species. We determined the enzyme specificity of recombinant maize proRIP1 (rproRIP1), papain-activated rproRIP1 and MOD1 (an active deletion mutant of rproRIP1) against ribosomal substrates with differing levels of RIP sensitivity. The rproRIP1 had no detectable enzymatic activity against ribosomes from any of the species assayed. The papain-activated rproRIP1 was more active than MOD1 against ribosomes from either rabbit or the corn pathogen, Aspergillus flavus, but the difference was much more marked when rabbit ribosomes were used as a substrate. The papain-activated rproRIP1 was much more active against rabbit ribosomes than homologous Zea mays ribosomes and had no detectable effect on Escherichia coli ribosomes.     

X-ray crystallographic analysis of the structural basis for the interactions of pokeweed antiviral protein with its active site inhibitor and ribosomal RNA substrate analogs.

The pokeweed antiviral protein (PAP) belongs to a family of ribosome-inactivating proteins (RIP), which depurinate ribosomal RNA through their site-specific N-glycosidase activity. We report low temperature, three-dimensional structures of PAP co-crystallized with adenyl-guanosine (ApG) and adenyl-cytosine-cytosine (ApCpC). Crystal structures of 2.0-2.1 A resolution revealed that both ApG or ApCpC nucleotides are cleaved by PAP, leaving only the adenine base clearly visible in the active site pocket of PAP. ApCpC does not resemble any known natural substrate for any ribosome-inactivating proteins and its cleavage by PAP provides unprecedented evidence for a broad spectrum N-glycosidase activity of PAP toward adenine-containing single stranded RNA. We also report the analysis of a 2.1 A crystal structure of PAP complexed with the RIP inhibitor pteoric acid. The pterin ring is strongly bound in the active site, forming four hydrogen bonds with active site residues and one hydrogen bond with the coordinated water molecule. The second 180 degrees rotation conformation of pterin ring can form only three hydrogen bonds in the active site and is less energetically favorable. The benzoate moiety is parallel to the protein surface of PAP and forms only one hydrogen bond with the guanido group of Arg135.