Current status of ribosome inactivating proteins

Ribosome inactivating proteins (RIPs) are a group of naturally occurring plant proteins with a RNA-N-glycosidases activity which depurinate rRNA at a specific universally conserved position (i.e. cleavage of N-glycosidic bond of a specific adenine of 28S rRNA). These proteins are found in different parts of plants, in concentrations ranging from a few micrograms to several hundred mg per 100 g of plant tissues. RIPs exist in two forms, type 1 having a single polypeptide chain with a molecular mass of approximately 30 kDa possessing N-glycosidase activity; and type 2 with two or four polypeptide chains having a molecular mass of approximately 60 kDa and approximately 120 kDa respectively showing lectin activity along with N-glycosidase moiety. Such biomolecules causing cytotoxicity are being exploited for designing immunotoxins/hormonotoxins using heterobifunctional conjugates. These carrier conjugates with the RIPs can influence cellular trafficking and inhibition of protein synthesis. We are witnessing a novel protein from plants that can be utilised for various therapeutical treatments ranging from cancers, AIDS and other viral diseases of present times.     

The 1.4 anstroms structure of dianthin 30 indicates a role of surface potential at the active site of type 1 ribosome inactivating proteins

Ribosome inactivating proteins (RIPs) are plant proteins with enzymatic activity identified as rRNA N-glycosidase (EC 3.2.2.22), which cleaves the N-glycosidic bond of a specific adenine on the ricin/sarcin region of rRNA, thus causing inhibition of protein synthesis. They also depurinate extensively DNA and other polynucleotides. The three-dimensional structure of dianthin 30, a type 1 (single-chain) RIP of Dianthus caryophyllus (leaves), is now described at 1.4 angstroms, a resolution never achieved before for any RIP. The fold typical of RIPs is conserved, despite some differences in the loop regions. The general structure comparison by superimposed alpha-carbon (249 atoms) and the sequence alignment by structure for dianthin 30 and saporin-S6 give a root mean square deviation of 0.625 angstroms. Despite the differences reported for the biological activities of the two RIPs, their structures fit quite well and both show a protein segment containing strands beta7, beta8, and beta9 shorter than other RIPs. However, the surface electrostatic potential in the active site region neatly distinguishes dianthin 30 from saporin-S6. The possible relationship between the charge distribution and the behavior of the proteins toward different substrates is discussed.     

Type 1 ribosome-inactivating proteins depurinate plant 25S rRNA without species specificity.

Four different type 1 ribosome-inactivating proteins (RIPs) with RNA N-glycosidase activity were tested for their ability to attack the large rRNA of plant ribosomes derived from tobacco plants, as well as from the plant species from which the particular RIP had been isolated. Incubation of tobacco ribosomes with RIPs isolated from either Phytolacca americana L. (pokeweed), Dianthus barbatus L. (carnation), Spinacia oleracea L. (spinach) or Chenopodium amaranthicolor Coste and Reyn. (chenopodium) rendered the 25S rRNA sensitive to aniline-catalyzed hydrolysis, generating a single rRNA-fragment of about 350 nucleotides. The same fragment was generated when rRNAs from pokeweed, carnation, spinach or chenopodium ribosomes were aniline-treated without any deliberate treatment of the ribosomes with the respective RIP. This indicated that ribosomes from all RIP-producing plants were already inactivated by their own RIPs during preparation. These results demonstrate that plant ribosomes are generally susceptible to RIP attack, including modification by their own RIPs. Direct sequencing of the newly generated fragments revealed that a single N-glycosidic bond at an adenosine residue within the highly conserved sequence 5'-AGUACGAGAGGA-3' was cleaved by all of the RIPs investigated, a situation also found in animal, yeast and Escherichia coli ribosomes.     

The site of action of six different ribosome-inactivating proteins from plants on eukaryotic ribosomes: the RNA N-glycosidase activity of the proteins

The site of action of six different ribosome-inactivating proteins from plants on eukaryotic ribosomes was studied. Treatment of ribosomes with any one of these proteins caused the 28S rRNA extracted from the inactivated ribosomes to become sensitive to treatment with aniline. A fragment containing about 450 nucleotides was released from the 28S rRNA. Further analysis of the nucleotide sequences of the 450-nucleotide fragments revealed that the aniline-sensitive phosphodiester bond was between A-4324 and G-4325 of the 28S rRNA. These results indicate that all six ribosome-inactivating proteins damage eukaryotic ribosomes by cleaving the N-glycosidic bond at A-4324 of the 28S rRNA of the ribosomes, as does ricin A-chain.     

Pokeweed antiviral protein cleaves double-stranded supercoiled DNA using the same active site required to depurinate rRNA

Ribosome-inactivating proteins (RIPs) are N-glycosylases that remove a specific adenine from the sarcin/ricin loop of the large rRNA in a manner analogous to N-glycosylases that are involved in DNA repair. Some RIPs have been reported to remove adenines from single-stranded DNA and cleave double-stranded supercoiled DNA. The molecular basis for the activity of RIPs on double-stranded DNA is not known. Pokeweed antiviral protein (PAP), a single-chain RIP from Phytolacca americana, cleaves supercoiled DNA into relaxed and linear forms. Double-stranded DNA treated with PAP contains apurinic/apyrimidinic (AP) sites due to the removal of adenine. Using an active-site mutant of PAP (PAPx) which does not depurinate rRNA, we present evidence that double-stranded DNA treated with PAPx does not contain AP sites and is not cleaved. These results demonstrate for the first time that PAP cleaves supercoiled double-stranded DNA using the same active site that is required for depurination of rRNA.     

The C-terminal fragment of the ribosomal P protein complexed to trichosanthin reveals the interaction between the ribosome-inactivating protein and the ribosome

Ribosome-inactivating proteins (RIPs) inhibit protein synthesis by enzymatically depurinating a specific adenine residue at the sarcin-ricin loop of the 28S rRNA, which thereby prevents the binding of elongation factors to the GTPase activation centre of the ribosome. Here, we present the 2.2 Å crystal structure of trichosanthin (TCS) complexed to the peptide SDDDMGFGLFD, which corresponds to the conserved C-terminal elongation factor binding domain of the ribosomal P protein. The N-terminal region of this peptide interacts with Lys173, Arg174 and Lys177 in TCS, while the C-terminal region is inserted into a hydrophobic pocket. The interaction with the P protein contributes to the ribosome-inactivating activity of TCS. This 11-mer C-terminal P peptide can be docked with selected important plant and bacterial RIPs, indicating that a similar interaction may also occur with other RIPs.     

Elderberry (Sambucus nigra L.) seed proteins inhibit protein synthesis and display strong immunoreactivity with rabbit polyclonal antibodies raised against the type 2 ribosome-inactivating protein nigrin b

Affinity chromatography-purifled elderberry (Sambucus nigraL.) seed proteins strongly inhibited protein synthesis and displayedthe 28S rRNA N-glycosidase activity characteristic of all typesof ribosome-inactivating proteins (RIPs). Western blot analysisrevealed several proteins that reacted with antibodies raisedagainst the novel non-toxic type 2 ribosome-inactivating proteinnigrin b isolated from elder bark, thus indicating the presenceof a new type 2 RIP. Key words: Anti-nigrin b antibodies, protein synthesis, seeds, elder seeds, Sambucus nigra     

Ribosome inactivating proteins from plants inhibiting viruses

Many plants contain ribosome inactivating proteins (RIPs) with N-glycosidase activity, which depurinate large ribosomal RNA and arrest protein synthesis. RIPs so far tested inhibit replication of mRNA as well as DNA viruses and these proteins, isolated from plants, are found to be effective against a broad range of viruses such as human immunodeficiency virus (HIV), hepatitis B virus (HBV) and herpes simplex virus (HSV). Most of the research work related to RIPs has been focused on antiviral activity against HIV; however, the exact mechanism of antiviral activity is still not clear. The mechanism of antiviral activity was thought to follow inactivation of the host cell ribosome, leading to inhibition of viral protein translation and host cell death. Enzymatic activity of RIPs is not limited to depurination of the large rRNA, in addition they can depurinate viral DNA as well as RNA. Recently, Phase I/II clinical trials have demonstrated the potential use of RIPs for treating patients with HIV disease. The aim of this review is to focus on various RIPs from plants associated with anti-HIV activity.     

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.     

Ribosome-inactivating proteins with an emphasis on bacterial RIPs and their potential medical applications

Ribosome-inactivating proteins (RIPs) are toxic due to their N-glycosidase activity catalyzing depurination at the universally conserved α-sarcin loop of the 60S ribosomal subunit. In addition, RIPs have been shown to also have other enzymatic activities, including polynucleotide:adenosine glycosidase activity. RIPs are mainly produced by different plant species, but are additionally found in a number of bacteria, fungi, algae and some mammalian tissues. This review describes the occurrence of RIPs, with special emphasis on bacterial RIPs, including the Shiga toxin and RIP in Streptomyces coelicolor recently identified in S. coelicolor. The properties of RIPs, such as enzymatic activity and targeting specificity, and how their unique biological activity could be potentially turned into medical or agricultural tools to combat tumors, viruses and fungi, are highlighted.     

Adenine nucleotide N-glycosidase activity of the A-chain of cinnamomin characterized by 1H-nuclear magnetic resonance

Plant ribosome-inactivating proteins specifically cleave an N-glycosidic bond of a unique adenosine in the largest ribosomal RNA, releasing an adenine from ribosomes of different sources. Here, 1H-nuclear magnetic resonance is used to analyze the enzymatic products of the A-chain of cinnamomin, a type-II ribosome-inactivating protein (RIP) acting on the nucleotides in situ. The enzymatic activities of the RIP on nine nucleotides are compared. Cinnamomin A-chain can cleave the N-glycosidic bond and release an adenine base from adenine nucleotides except 5'-ATP; however, it cannot act on 5'-GMP, 5'-CMP, and 5'-UMP. The A-chain in the mixture of cinnamomin A- and B-chain exhibits higher activity toward adenine nucleotides than the A-chain alone does, suggesting that the B-chain can conformationally stabilize the A-chain. Intact cinnamomin also exhibits lower activity toward adenine nucleotides. However, cinnamomin B-chain and heat-denatured intact cinnamomin cannot hydrolyze all the tested nucleotides. We conclude that hydrolysis of the N-C glycosidic bond of nucleotide compounds by cinnamomin A-chain has a base preference, and the negatively charged phosphate group(s) reduces the recognition ability of the A-chain to adenine nucleotide.     

植物核糖体失活蛋白及其应用进展

植物核糖体失活蛋白（ribosome-inactivating proteins,RIPs）是一类作用于真核细胞rRNA,并破坏其核糖体结构,抑制蛋白质生物合成的毒蛋白,主要应用在农业和医学领域。在农业领域,主要应用在转基因植物中,增强其抗病毒、抗菌以及抗虫活性。在医学领域,主用应用于抗肿瘤、抗艾滋病病毒等研究中。对核糖体失活蛋白的一些性质和应用进展进行综述。     

Vicia sativa L. 'Run-off' and Purified Ribosomes: Polyphenylalanine Synthesis and Molecular Action of Ribosome-inactivating Proteins

A ‘run-off’ cell-free translation system (a 30000x g supernatant; S 30) has been prepared from 4–5-d-oldembryonic axes of Vicia sativa L., a plant lacking ribosome-inactivatingprotein activities which is very sensitive to certain RIPs butnot to others. The system was able to generate a high rate ofpolyphenylalanine synthesis upon addition of polyuridylic acid.From this supernatant, purified ribosomes and a 100000 x g supernatantwere prepared which were able to perform polyphenylalanine synthesiswhen mixed together (reconstituted system). The most importanttranslation parameters were optimized in each case. Both theS 30 and the reconstituted system displayed differential sensitivitiesto certain RIPs. The purified RIP-inactivated ribosomes wereable to release a 370 nucleotide rRNA fragment diagnostic forRIPs upon treatment of the isolated rRNA with acid aniline. Key words: Translation, polyphenylalanine synthesis, ribosomes, ribosome-inactivating proteins, Vicia sativa     

核糖体单链失活蛋白在无细胞体系中的活性

核糖体单链失活蛋白是一类广泛分布于植物中的蛋白质,它能使真核细胞核糖体60S亚基失活。本文报道了一些核糖体单链失活蛋白的制备、纯化以及在兔网织红细胞裂解液中对蛋白质生物合成的抑制活性及它们对完整细胞的毒性。其中多数的核糖体单链失活蛋白是首次被分离纯化并对其毒性进行研究的。     

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.     

The site of action of the A-chain of mistletoe lectin I on eukaryotic ribosomes. The RNA N-glycosidase activity of the protein

The site of action of the A-chain of mistletoe lectin (ML-A) from Viscum album on eukaryotic ribosomes was studied. Treatment of rat liver ribosomes with ML-A, followed by treatment of the isolated rRNA with aniline, caused the release of a fragment with about 450 nucleotides from 28 S rRNA. Further analysis of nucleotide sequences of this fragment revealed that the aniline-sensitive site of phosphodiester bond was between positions A-4324 and G-4325 in 28 S rRNA. These results indicate that ML-A inactivates the ribosomes by cleaving a N-glycosidic bond at A-4324 of 28 S rRNA in the ribosomes as ricin A-chain does.     

Cytotoxic ribosome-inactivating lectins from plants

A class of heterodimeric plant proteins consisting of a carbohydrate-binding B-chain and an enzymatic A-chain which act on ribosomes to inhibit protein synthesis are amongst the most toxic substances known. The best known example of such a toxic lectin is ricin, produced by the seeds of the castor oil plant, Ricinnus communis. For ricin to reach its substrate in the cytosol, it must be endocytosed, transported through the endomembrane system to reach the compartment from which it is translocated into the cytosol, and there avoid degradation making it possible for a few molecules to inactivate a large proportion of the ribosomes and hence kill the cell. Cell entry by ricin involves the following steps: (i) binding to cell-surface glycolipids and glycoproteins bearing beta-1,4-linked galactose residues through the lectin activity of the B-chain (RTB); (ii) uptake by endocytosis and entry into early endosomes; (iii) transfer by vesicular transport to the trans-Golgi network; (iv) retrograde vesicular transport through the Golgi complex and into the endoplasmic reticulum (ER); (v) reduction of the disulfide bond connecting the A- and B-chains; (vi) a partial unfolding of the A-chain (RTA) to enable it to translocate across the ER membrane via the Sec61p translocon using the pathway normally followed by misfolded ER proteins for targeting to the ER-associated degradation (ERAD) machinery; (vi) refolding in the cytosol into a protease-resistant, enzymatically active structure; (vii) interaction with the sarcin-ricin domain (SRD) of the large ribosome subunit RNA followed by cleavage of a single N-glycosidic bond in the RNA to generate a depurinated, inactive ribosome. In addition to the highly specific action on ribosomes, ricin and related ribosome-inactivating proteins (RIPs) have a less specific action in vitro on DNA and RNA substrates releasing multiple adenine, and in some instances, guanine residues. This polynucleotide:adenosine glycosidase activity has been implicated in the general antiviral, and specifically, the anti HIV-1 activity of several single-chain RIPs which are homologous to the A-chains of the heterodimeric lectins. However, in the absence of clear cause and effect evidence in vivo, such claims should be regarded with caution.     

Isolation and characterization of an RIP (ribosome-inactivating protein)-like protein from tobacco with dual enzymatic activity

Ribosome-inactivating proteins (RIPs) are N-glycosidases that remove a specific adenine from the sarcin/ricin loop of the large rRNA, thus arresting protein synthesis at the translocation step. In the present study, a protein termed tobacco RIP (TRIP) was isolated from tobacco (Nicotiana tabacum) leaves and purified using ion exchange and gel filtration chromatography in combination with yeast ribosome depurination assays. TRIP has a molecular mass of 26 kD as evidenced by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and showed strong N-glycosidase activity as manifested by the depurination of yeast rRNA. Purified TRIP showed immunoreactivity with antibodies of RIPs from Mirabilis expansa. TRIP released fewer amounts of adenine residues from ribosomal (Artemia sp. and rat ribosomes) and non-ribosomal substrates (herring sperm DNA, rRNA, and tRNA) compared with other RIPs. TRIP inhibited translation in wheat (Triticum aestivum) germ more efficiently than in rabbit reticulocytes, showing an IC50 at 30 ng in the former system. Antimicrobial assays using highly purified TRIP (50 microg mL(-1)) conducted against various fungi and bacterial pathogens showed the strongest inhibitory activity against Trichoderma reesei and Pseudomonas solancearum. A 15-amino acid internal polypeptide sequence of TRIP was identical with the internal sequences of the iron-superoxide dismutase (Fe-SOD) from wild tobacco (Nicotiana plumbaginifolia), Arabidopsis, and potato (Solanum tuberosum). Purified TRIP showed SOD activity, and Escherichia coli Fe-SOD was observed to have RIP activity too. Thus, TRIP may be considered a dual activity enzyme showing RIP-like activity and Fe-SOD characteristics.     

Bacterial expression and enzymatic activity analysis of ME1, a ribosome-inactivating protein from Mirabilis expansa

Ribosome-inactivating proteins (RIPs) are toxic proteins synthesized by many plants and some bacteria, that specifically depurinate the 28S RNA and thus interrupt protein translation. RIPs hold broad interest because of their potential use as plant defense factors against pathogens. However, study of the activity of type I RIPs has been hampered since their expression in Escherichia coli has typically been toxic to the model system. Mirabilis expansa, an Andean root crop, produces a type I RIP called ME1 in large quantities in its storage roots. In this study, the cDNA sequence of ME1 was used to successfully express the recombinant ME1 protein in E. coli. The production of recombinant ME1 in E. coli was confirmed by Western blot analysis using anti-ME1 antibodies. The studies with fluorescence-labeled ME1 showed that ME1 can enter bacteria and be distributed in the cytoplasm uniformly, indicating its ability to access the protein synthesis machinery of the bacteria. The recombinant enzyme was active and depurinated yeast ribosomes. However, both native and recombinant ME1 proteins failed to depurinate the E. coli ribosomes, explaining the non-toxicity of recombinant ME1 to E. coli. Structural modeling of ME1 showed that it has folding patterns similar to other RIPs, indicating that ME1 and PAP, which share a similar folding pattern, can show different substrate specificity towards E. coli ribosomes. The results presented here are very significant, as few reports are available in the area of bacterial interaction with type I RIPs.