Tandem fusion of albumin-binding domains promoted soluble expression and stability of recombinant trichosanthin in vitro and in vivo.

Trichosanthin (TCS), as a type 1 ribosome-inactivating protein, has a very high cytoplasmic activity in vitro and can quickly kill cancer cells. However, it is easily filtered and cleared by the kidney, which results in the short half-life and severely limits its application. In this study, we constructed several recombinant proteins by fusing the albumin binding domain mutant ABD035(abbreviated as ABD) to the N- or C-terminus of TCS to endow the recombinant TCS fusion protein with a longer half-life property binding with endogenous human serum albumin (HSA) via ABD to effectively exert its anti-tumor activity in vivo. Pull down, Dynamic light scattering and ELISA assays all showed that TCS fused with two ABD sequences at the C-terminus of TCS, has stronger binding capacity to HSA in vitro than TCS with one ABD. In vivo studies in BALB/C mice were performed and the elimination half-life of TCS-ABD-ABD is about 15-fold longer compared to TCS and anti-tumor activity is about 30% higher than that of TCS alone in BALB/C mouse experiments. Moreover, we found that TCS with two ABDs in tandem have the highest soluble expression level, more than 5 times higher than that of TCS, and the yield of purified protein of TCS-ABD-ABD was as high as 68.9 mg/L culture solution, which was about 7-fold higher than that of TCS. Furthermore, MTT assay showed that the anti-tumor activity of TCS-ABD-ABD was significantly higher than TCS fused with only one ABD sequence, indicating that the repeated ABD sequences facilitated the biological activity of TCS. In this paper, the fusion of the albumin-binding domain in tandem with TCS can effectively improve its stability in vivo and also significantly increase its soluble expression, expanding the application of the albumin-binding domain in the high soluble expression and stability of protein drugs.

Genetically-engineered protein prodrug-like nanoconjugates for tumor-targeting biomimetic delivery via a SHEATH strategy.

The delivery issue is a major hurdle against drug development and the clinical application of the cytoplasmic active proteins (e.g., ribosome-inactivating proteins, RIPs). As a case in point, trichosanthin (TCS) has a very high cytoplasmic activity of killing cancer cells, but the translation is hampered by its unfavorable nature, such as the short half-life, poor tumor targeting and cell permeation. To address this issue, a novel delivery method called a smart hitchhike via endogenous albumin-trichosanthin hinge (SHEATH) system was developed by the genetic fusion of an albumin-binding domain (ABD) and a legumain-substrate peptide to TCS. The SHEATH system is characterized by the feature of smart hitchhike by binding to serum albumin via its ABD domain, and the two proteins (i.e., TCS and albumin) thus form a prodrug-like noncovalent nanoconjugate. The TCS could detach from the albumin carrier by responding to the protease legumain cleavage of the substrate peptide at the tumor site. Such a system can take advantage of the albumin-mediated biomimetic delivery to the tumor via the nutrient transporter pathway of albumin-binding proteins (e.g., SPARC). The antitumor effects were evaluated in orthotopic breast cancer animal models and showed remarkably improved antitumor effects. Our work provides a useful protocol for improving the druggability of such a class of protein toxins for targeted cancer therapy by an endogenous albumin-hitchhike strategy.

A novel trichosanthin fusion protein with increased cytotoxicity to tumor cells.

OBJECTIVE: To evaluate the anti-tumor effects of trichosanthin after fusion with a cell penetrating peptide, heparin-binding peptide (HBP), derived from human heparin-binding EGF-like growth factor (HB-EGF). RESULTS: The fusion protein of trichosanthin-HBP was expressed in Escherichia coli BL21 and purified by Ni-NTA affinity chromatography. The HBP domain had no influence on the topological inactivation activity and N-glycosidase activity of trichosanthin. Trichosanthin-HBP significantly inhibited the growth of tested cancer cells which are impervious to trichosanthin. Tumor cell apoptosis and both the mitochondrial- and death receptor-mediated apoptotic signaling pathways induced by trichosanthin-HBP were more significant than those induced by trichosanthin in HeLa cells. CONCLUSION: HBP is an efficient intracellular delivery vehicle for trichosanthin and makes trichosanthin-HBP become a promising agent for cancer therapy.

Cytotoxic genes from traditional Chinese medicine inhibit tumor growth both in vitro and in vivo.

OBJECTIVE: Little effort has been made to study the protein-encoding genes isolated from traditional Chinese medicine (TCM) drugs, and the delivery of these genes into malignant cells through recombinant adeno-associated virus (rAAV) vectors has not been attempted. METHODS: We synthesized the cDNAs of five known cytotoxic proteins isolated from TCM drugs and the FLAG epitope-tagged cDNAs were subcloned into a rAAV plasmid vector. The protein expression was confirmed by Western blot assay. Various cancer cell lines were transfected with the above plasmids and cell growth was monitored both in vitro and in vivo. The best cytotoxic gene was further packaged into rAAV vectors, under the control of a liver cancer-specific promoter. The liver tumor growth was then monitored following intratumor administration of the rAAV vectors. RESULTS: The expression plasmids, encoding individual potential cytotoxic genes tagged with FLAG epitope, were successfully generated and sequenced. Among these genes, trichosanthin (TCS) gene yielded the most promising results for the inhibition of cancer cell growth in vitro. The over-expressed TCS functioned as a type I ribosome-inactivating protein, followed by inducing apoptosis that is associated with the Bcl-PARP signaling pathway. Furthermore, intratumor injection of rAAV vectors containing the TCS gene significantly inhibited the growth of human hepatocellular carcinoma tumors in a murine xenograft model. CONCLUSION: Our studies suggest that the use of TCM cytotoxic genes is a useful therapeutic strategy for treating human cancers in general, and liver tumors in particular.

Maize ribosome-inactivating protein uses Lys158-lys161 to interact with ribosomal protein P2 and the strength of interaction is correlated to the biological activities.

Ribosome-inactivating proteins (RIPs) inactivate prokaryotic or eukaryotic ribosomes by removing a single adenine in the large ribosomal RNA. Here we show maize RIP (MOD), an atypical RIP with an internal inactivation loop, interacts with the ribosomal stalk protein P2 via Lys158-Lys161, which is located in the N-terminal domain and at the base of its internal loop. Due to subtle differences in the structure of maize RIP, hydrophobic interaction with the 'FGLFD' motif of P2 is not as evidenced in MOD-P2 interaction. As a result, interaction of P2 with MOD was weaker than those with trichosanthin and shiga toxin A as reflected by the dissociation constants (K(D)) of their interaction, which are 1037.50 ± 65.75 µM, 611.70 ± 28.13 µM and 194.84 ± 9.47 µM respectively.Despite MOD and TCS target at the same ribosomal protein P2, MOD was found 48 and 10 folds less potent than trichosanthin in ribosome depurination and cytotoxicity to 293T cells respectively, implicating the strength of interaction between RIPs and ribosomal proteins is important for the biological activity of RIPs. Our work illustrates the flexibility on the docking of RIPs on ribosomal proteins for targeting the sarcin-ricin loop and the importance of protein-protein interaction for ribosome-inactivating activity.

[Construction, expression and purification of trichosanthin mutant gene TCS(FYY163-165CSA);].

AIM: To construct and express a trichosanthin (TCS) gene mutant and purify the expressed product in E.coli. METHODS: The potential antigenic determinant was predicted on TCS molecule by computer modeling and induced for site-directed mutation. The gene mutant TCS(FYY163-165CSA); was amplified by PCR using the genomic DNA of Trichosanthes kirilowii as a template and cloned into expression vector pRSET-A, then transfected into E.coli BL21 (DE3) for expression by inducing with IPTG. The expressed product was identified by Western blotting and purified by Ni-NTA affinity column chromatography. RESULTS: The soluble target protein was successfully expressed in E.coli. Homogenous TCS mutant protein was obtained after purification of expressed product. CONCLUSION: The site-directed mutagenesis, expression and purification of TCS provide a new approach for reconstructing TCS.

[Construction and expression of trichosanthin mutant gene TCS(RL28-29CG) and purification of expressed product].

AIM: To construct and express a trichosanthin(TCS)gene mutant and purify the expressed product. METHODS: Predict the potential antigenic determinant on TCS molecule by computer modeling and induce site-directed mutation. Amplify gene mutant TCS(RL28-29CG); by PCR using the genomic DNA of Trichosanthes kirilowii as a template and insert into expression vector pRSET-A, then transform to E.coli BL21(DE3)for expression under induction of IPTG. Purify the expressed product by Ni-NTA afinity column chromatography. RESULTS: The target protein in a soluble form was successfully expressed in E.coli. Homogenous TCS mutant protein was obtained after purification of expressed product. CONCLUSION: TCS mutant gene TCS(RL28-29CG); is succ-essfully constructed and expressed.

A novel sorting strategy of trichosanthin for hijacking human immunodeficiency virus type 1.

Trichosanthin (TCS) is a type I ribosome-inactivating protein that plays dual role of plant toxin and anti-viral peptide. The sorting mechanism of such an exogenous protein is in long pursuit. Here, we examined TCS trafficking in cells expressing the HIV-1 scaffold protein Gag, and we found that TCS preferentially targets the Gag budding sites at plasma membrane or late endosomes depending on cell types. Lipid raft membrane but not the Gag protein mediates the association of TCS with viral components. After Gag budding, TCS is then released in association with the virus-like particles to generate TCS-enriched virions. The resulting TCS-enriched HIV-1 exhibits severely impaired infectivity. Overall, the observations indicate the existence of a unique and elaborate sorting strategy for hijacking HIV-1.

[A comparative study on the properties of trichosanthin before and after site-directed PEGylation].

OBJECTIVE: To construct PEGylated trichosanthin (TCS) mutein and analyze its bioactivities, immunogenicity, acute toxicity, and pharmacokinetics. METHODS: The potential antigenic determinant site YFF81-83 in the molecule of TCS was selected to undergo site-directed mutagenesis. Thus, a TCS mutein named TCS(YFF81-83ACS) was constructed and expressed in Escherichia coli of the line BL21 (DE3). Wild TCS (wTCS), TCSY(FF81-83ACS), and PEGylated TCS(YFF81-83ACS) (PEG- TCS(YFF81-83ACS)) of different concentrations were incubated with the supercoiled plasmid pUC19 to detect the DNAse activity, mixed with rabbit reticulocyte lysate to detect the ribosome inactivation activity, subcutaneously injected into 6 mice respectively to measure the serum IgG and IgE levels, intravenously injected into mice to observe the toxicity, and intravenously injected into SD rats to observe its -plasma half-life. RESULTS: The DNAse activity of the PEG-TCS(YFF81-83ACS) was similar to that of the wTCS. The ribosome inactivation activity of the PEG-TCS(YFF81-83ACS) was 1/9-1/8 of that of the wTCS (P < 0.05). The serum IgE and IgG levels of the PEG-TCS(YFF81-83ACS) were both significantly lower than those of the wTCS (both P < 0.05). The LD50 of the PEG-TCS(YFF81-83ACS) was 1.8 times that of the wTCS (P < 0.05). The mean residence time and plasma half-life of the PEG-TCS(YFF81-83ACS) were significantly increased and its plasma clearance was significantly decreased (all P < 0.05). CONCLUSION: Site-directed mutagenesis and PEGylation of TCS provide a new approach for reconstructing TCS.

Effect of site-directed PEGylation of trichosanthin on its biological activity, immunogenicity, and pharmacokinetics.

Trichosanthin (TCS) is a type I ribosome-inactivating protein (RIP) with multiple biological and pharmacological activities. It has been approved effective in the clinical treatment of AIDS and tumor, but its strong immunogenicity and short plasma half-life have limited the clinical administration. To reduce the immunogenicity and prolong the plasma half-life of this compound, three TCS muteins (M(1), M(2) and M(3)) and two PEGylated TCS muteins (PM(1) and PM(2)) were constructed by site-directed mutagenesis and PEGylation, respectively. Compared with the unmodified TCS, both PEGylated TCS showed a 3- to 4-fold decrease in immunogenicity, a 0.5- to 0.8-fold decrease in non-specific toxicity, and a 4.5- to 6-fold increase in plasma half-life. But there is a problem of activity reduction. The increased circulating half-life in vivo may compensate for the reduced activity. Together with the other benefits of PEGylation such as reduced immunogenicity and toxicity, it is worthwhile to further explore the potential application of the PEGylated TCS as a better therapeutic agent for AIDS and tumor.

[Antitumor effect of recombinant immunotoxin EGF-TCS in nude mice bearing human hepatocellular carcinoma].

OBJECTIVE: To evaluate the anti-tumor effect of recombinant toxin EGF-TCS against transplanted human hepatocellular carcinoma in nude mice. METHODS: Human hepatocellular carcinoma BEL-7,402 cells were inoculated subcutaneously in the right axillary region of nude mice, and 6 days later, EGF-TCS was injected intravenously at 100, 50, and 25 microg/kg. The mice were executed on the next day of drug withdrawal and the tumors were weighed and the tumor inhibition rate calculated. Immunohistochemistry was also performed on the tumor tissues to provide clue for the possible pathways of tumor inhibition. RESULTS: EGF-TCS markedly inhibited the tumor growth in nude mice, with a tumor inhibition rate of 71.3%, 60.87% and 45.22% corresponding to EGF-TCS dosage of 100, 50, and 25 microg/kg, respectively. Variance analysis suggested that EGF-Linker-TCS could significantly inhibit the tumor growth in the mice (F=8.712, P=0.006), and immunohistochemistry showed significantly inhibited angiogenesis in the tumors by EGF-TCS. No blood vessels were found in the tumor tissues in high dosage group, and there were also reduced blood vessels in the other two smaller dose groups in comparison with the untreated model group, indicating that EGF-TCS inhibited tumor growth and migration by inhibiting tumor angiogenesis. CONCLUSION: EGF-TCS can inhibit the growth of solid tumors in nude mice, suggesting the potential value of this preparation in cancer therapy.

[Gene cloning, expression and purification of fusion protein epidermal growth factor-linker-trichosanthin].

OBJECTIVE: To construct a recombinant expression vector of the fusion protein epidermal growth factor (EGF)-Linker-trichosanthin (TCS) and achieve its expression in E. coli to obtain purified EGF-linker-TCS fusion protein. METHODS: The gene fragments of EGF-linker were amplified by PCR and inserted into the expression plasmid PQE30-TCS, followed by transformation of the recombinant plasmid into E. coli M15 for expression of the fusion protein. Ni-FF column chromatography was utilized for purification of the expressed product. RESULTS: The recombinant plasmid PQE30-EGF-linker-TCS was stably and highly expressed in E. coli M15. The expressed product existed in the form of soluble protein accounting for about 40% of total cellular protein and reached a purity of above 95% after purification with Ni-FF column chromatography. CONCLUSION: The recombinant plasmid PQE30/EGF-linker-TCS has been successfully constructed, which provides a basis for further structural and functional study of EGF and TCS and their potential clinical application for cancer therapy.

Interaction between trichosanthin, a ribosome-inactivating protein, and the ribosomal stalk protein P2 by chemical shift perturbation and mutagenesis analyses.

Trichosanthin (TCS) is a type I ribosome-inactivating protein that inactivates ribosome by enzymatically depurinating the A(4324) at the alpha-sarcin/ricin loop of 28S rRNA. We have shown in this and previous studies that TCS interacts with human acidic ribosomal proteins P0, P1 and P2, which constitute the lateral stalk of eukaryotic ribosome. Deletion mutagenesis showed that TCS interacts with the C-terminal tail of P2, the sequences of which are conserved in P0, P1 and P2. The P2-binding site on TCS was mapped to the C-terminal domain by chemical shift perturbation experiments. Scanning charge-to-alanine mutagenesis has shown that K173, R174 and K177 in the C-terminal domain of TCS are involved in interacting with the P2, presumably through forming charge-charge interactions to the conserved DDD motif at the C-terminal tail of P2. A triple-alanine variant K173A/R174A/K177A of TCS, which fails to bind P2 and ribosomal stalk in vitro, was found to be 18-fold less active in inhibiting translation in rabbit reticulocyte lysate, suggesting that interaction with P-proteins is required for full activity of TCS. In an analogy to the role of stalk proteins in binding elongation factors, we propose that interaction with acidic ribosomal stalk proteins help TCS to locate its RNA substrate.

Y55 and D78 are crucial amino acid residues of a new IgE epitope on trichosanthin.

Trichosanthin (TCS) possesses many biological and pharmaceutical activities, but its strong immunogenicity limits its clinical application. To reduce the immunogenicity of TCS, we modified the reported method for the prediction of antigenic site and identified two crucial amino acid residues (Y55 and D78) for a new epitope. We mutated these two residues into glycine and serine, respectively, and obtained three mutants, Y55G, D78S, and Y55G/D78S. These mutants induced less amount of Ig and IgG antibodies in C57BL/6J mice than wild-type TCS (wTCS) (p<0.01) and almost lost the ability to induce IgE antibody production. The mutants stimulated fewer TCS-specific B cells in C57BL/6J mice than wTCS (p<0.01). Compared with wTCS, Y55G, D78S, and Y55G/D78S lost 26.9%, 17.9%, and 98.7% specific binding ability to anti-TCS monoclonal antibody TCS4E9, respectively. These mutants still retained RNA N-glycosidase activity. In conclusion, Y55 and D78 are two crucial amino acid residues of a new IgE epitope on TCS, and their mutation reduces the immunogenicity of TCS, but still retained the enzymatic activity.

[A new molecular method to authenticate radix trichosanthis as well as its adulterants and substitutes].

OBJECTIVE: To explore a new molecular method to authenticate Radix Trichosanthis. METHOD: Three 20 mer primers based on the ITS sequence was designed. The PCR reaction system was optimized and applied to nineteen different sources of Radix Trichosanthis and nine adulterants and substitutes. RESULT: Polymorphic map of Radix Trichosanthis and its adulterants was obtained from primer TKS1-64. 560 bp and 960 bp bands were authentic markers for Radix Trichosanthis. CONCLUSION: Primer TKS1-64F possesses the advantages of good stability and reproducibility. This new method is named as anchored primer amplification polymorphism DNA(APAPD). It was a potential method to used in molecular identification of other meteria medica.

Recent advances in trichosanthin, a ribosome-inactivating protein with multiple pharmacological properties.

Trichosanthin (TCS), a ribosome-inactivating protein extracted from the root tuber of Chinese medicinal herb Trichosanthes kirilowii Maximowicz, has multiple pharmacological properties including abortifacient, anti-tumor and anti-HIV. It is traditionally used to induce abortion but its antigenicity and short plasma half-life have limited the repeated clinical administration. In this review, work to locating antigenic sites and prolonging plasma half-life are discussed. Studies on structure-function relationship and mechanism of cell entry are also covered. Recently, TCS has been found to induce apoptosis, enhance the action of chemokines and inhibit HIV-1 integrase. These findings give new insights on the pharmacological properties of TCS and other members of ribosome-inactivating proteins.

Site-directed PEGylation of trichosanthin retained its anti-HIV activity with reduced potency in vitro.

Trichosanthin (TCS) was the first ribosome inactivating protein found to possess anti-HIV-1 activity. Phase I/II clinical trial of this compound had been done. Antigenicity and short plasma half-life were the major side effects preventing further clinical trial. Modification of TCS is therefore necessary to revive the interest to develop this compound as an anti-HIV agent. Three potential antigenic sites (Ser-7, Lys-173, and Gln-219) were identified by computer modeling. Through site-directed mutagenesis, these three antigenic amino acids were mutated to a cysteine residue resulting in 3 TCS mutants, namely S7C, K173C, and Q219C. These mutants were further coupled to polyethylene glycol with a molecular size of 20kDa (PEG) via the cysteine residue. This produced another three TCS derivatives, namely PEG20k-S7C, PEG20k-K173C, and PEG20k-Q219C. PEGylation had been widely used recently to decrease immunogenicity by masking the antigenic sites and prolong plasma half-life by expanding the molecular size. The in vitro anti-HIV-1 activity of these mutants and derivatives was tested. Results showed that the anti-HIV-1 activity of S7C, K173C, and Q219C was decreased by about 1.5- to 5.5-fold with slightly lower cytotoxicity. On the other hand, PEGylation produced larger decrease (20- to 30-fold) in anti-HIV activity. Cytotoxicity was, however, weakened only slightly by about 3-fold. The in vitro study showed that the anti-HIV activity of PEGylated TCS was retained with reduced potency. The in vivo activity is expected to have only slightly changed due to other beneficial effects like prolonged half-life.

Substrate binding and catalysis in trichosanthin occur in different sites as revealed by the complex structures of several E85 mutants.

Trichosanthin (TCS) is a type I ribosome-inactivating protein (RIP) which possesses rRNA N-glycosidase activity. In recent years, its immunomodulatory, anti-tumor and anti-HIV properties have been revealed. Here we report the crystal structures of several E85 mutant TCS complexes with adenosine-5'-monophosphate (AMP) and adenine. In E85Q TCS/AMP and E85A TCS/AMP, near the active site of the molecule and parallel to the aromatic ring of Tyr70, an AMP molecule is bound to the mutant without being hydrolyzed. In the E85R TCS/adenine complex, the hydrolyzed product adenine is located in the active pocket where it occupies a position similar to that in the TCS/NADPH complex. Significantly, AMP is bound in a position different to that of adenine. In comparison with these structures, we suggest that there are at least two subsites in the active site of TCS, one for initial substrate recognition as revealed by the AMP site and another for catalysis as represented by the NADPH site. Based on these complex structures, the function of residue 85 and the mechanism of catalysis are proposed.

The structural basis of Trp192 and the C-terminal region in trichosanthin for activity and conformational stability.

Trichosanthin (TCS) is a type I ribosome-inactivating protein (RIP) possessing N-glycosidase activity. TCS has various pharmacological properties, including immunomodulatory, anti-tumor and anti-HIV activities. Up to seven C-terminal residues of TCS (TCS-C7) can be deleted resulting in lower antigenicity with minimal effects on its activity. However, an additional problem is that the minimal effects on activity are higher than the reduction in antigenicity. In the present work, the crystal structure of TCS-C7 was determined. It shows the details of the C-terminal residues of TCS-C7, and in particular the hydrogen bonds between P35 and L240, S196 and L240, and W192 and L239, which play an important role in maintaining the structure of TCS-C7. Further analysis shows that the hydrogen bonds related to Leu240 are key in maintaining the relationship between N- and C-terminal domains. The major role of the C-terminal tail appears to stabilize the structure of TCS. The conformation between helix H7 at the N-terminal domain and the C-terminal tail at the C-terminal domain is also revealed. Two mutants, TCS-W192F and TCS-C7-W192F, were prepared and crystal structures were determined. These variants have greatly reduced ribosome-inactivating activities compared with TCS and TCS-C7, respectively, and TCS-W192F and TCS-C7-W192F have a similar stability in guanidine hydrochloride compared with TCS-C7. This suggests that Trp192 can affect the ribosome-inactivating activity of TCS.

Change in pH-dependent membrane insertion characteristics of trichosanthin caused by deletion of its last seven C-terminal amino acid residues.

Trichosanthin (TCS) is a type I ribosome-inactivating protein (RIP) that can selectively kill some types of cells at low concentration (0.1-1 nM). The pH-dependent membrane insertion ability of TCS makes it possible that the internalized toxin avoids degradation in lysosomes and further undergoes transportation into the cytosol by some still unidentified mechanism. Here, we show that deletion of C-terminal residues affects interactions of modified TCS (C7-TCS) with lipids and reduces its pH-dependent membrane insertion ability. Fluorescence measurements indicate that at low pH C7-TCS undergoes profound conformational changes that causes exposure of a hydrophobic region and leads to oligomerization of the C7-TCS molecules. The results suggest that the membrane insertion of TCS at low pH might be important for translocation of TCS into the cytosol, which is important for exertion of the RIP activity of TCS. Deletion of the last seven C-terminal residues of TCS would reduce both its RIP activity in vitro and cytotoxicity in vivo, with the degree of decrease being more significant for the cytotoxicity in vivo.