Valentina Farini

The conjugate Rituximab/saporin-S6 completely inhibits clonogenic growth of CD20-expressing cells and produces a synergistic toxic effect with Fludarabine

Immunotoxins are chimeric proteins consisting of a toxin coupled to an antibody. To date, several clinical trials have been conducted, and some are still ongoing, to evaluate their anti-tumor efficacy. In this view, we chemically constructed an anti-CD20 immunotoxin with the mAb Rituximab and the type 1 ribosome-inactivating protein (RIP) saporin-S6, designed for B cells non-Hodgkins lymphoma (NHL) therapy. This immunotoxin showed a specific cytotoxicity for the CD20+ cell lines Raji and D430B, evidenced by inhibition of protein synthesis, evaluation of apoptosis and clonogenic assay. Upon conjugation, saporin-S6 increased its toxicity on target cells by at least 2 logs, with IC50 values of 0.1–0.3 nM. The percentage of AnnexinV+ cells was over 95% in both cell lines treated with 10 nM immunotoxin. A complete elimination of Raji clones was reached with the 10 nM immunotoxin, whereas a mixture of free RIP and mAb gave about 90% of clonogenic growth. Rituximab/saporin-S6, at 10 nM concentration, also induced apoptosis in 80% of lymphoma cells from NHL patients. Moreover, sensitivity of Raji to Rituximab/saporin-S6 was augmented when cells were coincubated with Fludarabine. The synergistic toxic effect of the two drugs led to a total elimination of the neoplastic population.

Saporin induces multiple death pathways in lymphoma cells with different intensity and timing as compared to ricin.

Ribosome-inactivating protein (RIP)-containing immunotoxins are currently used in clinical trials as anti-tumour drugs, in particular against haematological malignancies. In cell killing-based therapies it is important to identify the death pathways induced by the cytotoxic agent. The purpose of this work was to compare the pathways of cell death induced by the RIP saporin with those carried out by ricin in the L540 human Hodgkins lymphoma-derived cell line. Protein synthesis inhibition, activation of caspases, DNA fragmentation and loss of viability have been evaluated. The two toxins triggered a similar DNA fragmentation and cell death, at concentrations giving the same level of cell protein synthesis inhibition, although the inhibitory effect of ricin on protein synthesis was more rapid than that of saporin. Moreover, the intrinsic apoptotic pathway was equally activated by both toxins, whilst ricin activated the extrinsic caspase pathway and the effector caspase-3/7 more efficiently than saporin. The complete inhibition of caspases by Z-VAD was only partially effective in cell rescue which appeared to be time limited. Necrostatin-1, a new inhibitor of non-apoptotic death, rescued cells from death by RIPs, although the effect was also partial and temporary. Despite the high RIP doses used no necrosis was detectable by Annexin V/Propidium Iodide (PI) test. These results suggest that more than one death mechanism was elicited by both ricin and saporin, however, with different timing and strength. The perspective of modulating cell death of neoplastic lymphocytes through different pathways could add new opportunities to reduce side effects and develop combined synergic immuno-chemotherapy.

Structure/function studies on two type 1 ribosome inactivating proteins: Bouganin and lychnin

The three-dimensional structures of two type 1 RIPs, bouganin and lychnin, has been solved. Their adenine polynucleotide glycosylase activity was also determined together with other known RIPs: dianthin 30, PAP-R, momordin I, ricin A chain and saporin-S6. Saporin-S6 releases the highest number of adenine molecules from rat ribosomes, and poly(A), while its efficiency is similar to dianthin 30, bouganin and PAP-R on herring sperm DNA. Measures of the protein synthesis inhibitory activity confirmed that saporin-S6 is the most active. The overall structure of bouganin and lychnin is similar to the other considered RIPs and the typical RIP fold is conserved. The superimpositioning of their C(alpha) atoms highlights some differences in the N-terminal and C-terminal domains. A detailed structural analysis indicates that the efficiency of saporin-S6 on various polynucleotides can be ascribed to a negative electrostatic surface potential at the active site and several exposed positively charged residues in the region around that site. These two conditions, not present at the same time in other examined RIPs, could guarantee an efficient interaction with the substrate and an efficient catalysis.

Binding and intracellular routing of the plant-toxic lectins, lanceolin and stenodactylin

BACKGROUND The present research studied the interaction of two ribosome-inactivating proteins (RIPs) from Adenia genus with HeLa cells. Namely, lanceolin and stenodactylin were examined in comparison to volkensin, another toxic two-chain RIP from Adenia genus. METHODS The binding, endocytosis, intracellular routing, degradation and exocytosis were investigated by measuring the distribution of radiolabelled RIP and by determining its cytotoxicity. RESULTS Stenodactylin was the most toxic, resulting in the greater inhibition of protein synthesis and cell death. Lanceolin and stenodactylin bound to cells with comparable affinity and have a similar number of binding sites (10(5)/cell). The uptake of lanceolin and stenodactylin was 13 and 36 times greater, respectively, than that reported for volkensin. The two toxins bound to cell membrane receptors via their lectin B chain, were endocytosed through a clathrin-independent pathway, were internalised in a manner independent from endosomal acidification, and required routing through the Golgi apparatus, as reported for modeccin and volkensin. Stenodactylin showed greater uptake, exocytosis and re-uptake of non-degraded RIP than lanceolin and volkensin, whereas volkensin had the highest residual activity after being released from the cell. CONCLUSIONS The high cytotoxicity of RIPs from the Adenia genus may depend on the following: high affinity binding to the cell and efficient endocytosis, intracellular routing that appears similar to that of other ricin-like toxic RIPs, partial resistance to proteolysis, and, regarding stenodactylin, high accumulation in cell. GENERAL SIGNIFICANCE The data provide a model that could lead to new strategies for anti-cancer therapy and neuroscience studies.

ATG-saporin-S6 immunotoxin: a new potent and selective drug to eliminate activated lymphocytes and lymphoma cells

Anti‐thymocyte globulins (ATG) are currently used to prevent graft‐versus‐host disease in haematopoietic stem cell transplants from alternative donors and to treat and prevent acute organ rejection after transplantation. Many recent studies have demonstrated that ATG can also be beneficial in patients with myeloma, lymphoma, leukaemia and myelodysplastic syndrome. This study showed, for the first time, that the cytotoxic effect of ATG can been enhanced by conjugation with saporin‐S6, which is one of the most stable and active type‐1 ribosome‐inactivating proteins. The ATG‐saporin‐S6 immunotoxin showed a strong cytotoxic effect on five lymphoma‐ and leukaemia‐derived cell lines as well as on activated lymphocytes while sparing non‐haematological cell lines. ATG‐saporin‐S6 induced a time‐dependent activation of caspase‐3/7 in RAJI cells. The caspase inhibitor Z‐VAD‐fmk partially rescued the cells that were treated with ATG‐saporin‐S6, suggesting that multiple cell death pathways, some of which are caspase independent, play a role in ATG‐saporin‐S6 toxicity. In our experiments ATG increased the complement‐independent cytotoxicity of activated lymphocytes by a magnitude of 3–5 logs after conjugation. These findings suggest that the ATG‐saporin‐S6 immunotoxin is a promising therapeutic tool for many pathological conditions involving T lymphocytes and T and B neoplastic cells.