Structure and properties of ricin ­ the toxic protein of Ricinus communis / Struktura i wlasciwosci biologiczne rycyny ­ toksycznego bialka racznika pospolitego.

Ricin is a heterodimeric protein that consists of A and B subunits that can be produced in the seeds of the castor oil plant Ricinus communis. Its large quantities are accumulated in byproducts generated during the extraction of castor oil, widely used in the cosmetic and pharmaceutical industry. Ricin is one of the most potent toxins. Toxic effects of ricin are caused by its ability to inhibit protein synthesis and the level of toxicity depends on both dose and route of exposure. There are three route of administration of ricin: oral ingestion, parenteral (injectable) or inhalation. The clinical presentation of ricin toxicity depends on the route of administration. Toxin causes inflammation, gastrointestinal haemorrhages, renal tubular necrosis or hypoglycemia. Although ricin can be lethal, it has the potential for therapeutic use. Ricin A-chain is one of the first examples of a toxin coupled to monoclonal antibodies against cell surface proteins and is used experimentally for the treatment of various cancers. This article discusses the structure of ricin, the mechanism of its synthesis and describes the biological activity of this protein.

Potential therapeutic applications of plant toxin-ricin in cancer: challenges and advances.

Cancer is one of the most common devastating disease affecting millions of people per year worldwide. To fight against cancer, a number of natural plant compounds have been exploited by researchers to discover novel anti-cancer therapeutics with minimum or no side effects and plants have proved their usefulness in anti-cancer therapy in past few years. Ricin, a cytotoxic plant protein isolated from castor bean seeds, is a ribosome-inactivating protein which destroys the cells by inhibiting proteins synthesis. Ricin presents great potential as anti-cancer agent and exerts its anti-cancer activity by inducing apoptosis in cancer cells. In this review, we summarize the current information on anti-cancer properties of plant toxin ricin, its potential applications in cancer therapy, challenges associated with its use as therapeutic agent and the recent advances made to overcome these challenges. Nanotechnology could open the doors for quick development of ricin-based anti-cancer therapeutics. Conceivably, ricin may serve as a chemotherapeutic agent against cancer by utilizing nanocarriers for its targeted delivery to cancer cells.

Cytotoxicity, Apoptosis, Migration Inhibition, and Autophagy-Induced by Crude Ricin from Ricinus communis Seeds in A549 Lung Cancer Cell Lines.

BACKGROUND Ricin protein derived from Ricinus communis seeds is known to have a high toxicity to humans and animals. Several studies revealed that ricin, belonging to ribosome inactivating protein-I, has cytotoxic properties against various types of cancer cell lines. MATERIAL AND METHODS Crude ricin (CR) from the seeds of R. communis was investigated for its cytotoxicity on the A549 cancer cell lines using the MTS assay, and the cell death mechanism was explored using flow cytometry and Western blot methods. The cell migration was measured using a scratch/wound-healing method and the autophagy activity was explored using Western blotting. RESULTS CR showed cytotoxicity against A549 cancer cell lines, with an IC50 of 40.94 ppm. CR induced apoptosis and necrosis, but apoptosis occurred more frequently than necrosis. Apoptosis induced by CR was mediated by the activation of caspase-9 and caspase-3. CR inhibited cell migration in a concentration- and time-dependent manner, with the highest effect occurred at the concentration of 1.0 ppm. The autophagic experiment showed that CR inhibited autophagy in A549 lung cancer cells by decreasing Beclin-1 levels while increasing Atg5 levels in a concentration-dependent manner and CR decreased LC3-II level while increasing p62 level. Cisplatin treatment also inhibited autophagy as it exhibited the same effect on those autophagic proteins as CR. CONCLUSIONS Our findings suggest that CR might be a potential candidate for anticancer drugs, but further study is needed to verify its anticancer properties.

A phase I study of a combination of anti-CD19 and anti-CD22 immunotoxins (Combotox) in adult patients with refractory B-lineage acute lymphoblastic leukaemia.

Novel agents are needed for patients with refractory and relapsed acute lymphoblastic leukaemia (ALL). Combotox is a 1:1 mixture of two immunotoxins (ITs), prepared by coupling deglycosylated ricin A chain (dgRTA) to monoclonal antibodies directed against CD22 (RFB4-dgRTA) and CD19 (HD37-dgRTA). Pre-clinical data demonstrated that Combotox was effective in killing both pre-B-ALL cell lines and cells from patients with pre-B ALL. A clinical study of paediatric patients in which 3 of 17 patients with ALL experienced complete remission, supported the preclinical work and motivated this study. This study was a Phase I, dose-escalation trial using Combotox in adults with refractory or relapsed B-lineage-ALL. A cycle consisted of three doses, with one dose given every other day. Dose levels were 3, 5, 6, 7 and 8 mg/m(2) per dose. Seventeen patients, aged 19-72 years, were enrolled in this multi-institution study. The maximum tolerated dose was 7 mg/m(2) /dose (21 mg/m(2) /cycle) and vascular leak syndrome was the dose-limiting toxicity. Two patients developed reversible grade 3 elevations in liver function tests. One patient achieved partial remission and proceeded to allogeneic stem cell transplantation. All patients with peripheral blasts experienced decreased blast counts following the administration of Combotox. Thus, Combotox can be safely administered to adults with refractory leukaemia.

Novel Binding Mechanisms of Fusion Broad Range Anti-Infective Protein Ricin A Chain Mutant-Pokeweed Antiviral Protein 1 (RTAM-PAP1) against SARS-CoV-2 Key Proteins in Silico.

The deadly pandemic named COVID-19, caused by a new coronavirus (SARS-CoV-2), emerged in 2019 and is still spreading globally at a dangerous pace. As of today, there are no proven vaccines, therapies, or even strategies to fight off this virus. Here, we describe the in silico docking results of a novel broad range anti-infective fusion protein RTAM-PAP1 against the various key proteins of SARS-CoV-2 using the latest protein-ligand docking software. RTAM-PAP1 was compared against the SARS-CoV-2 B38 antibody, ricin A chain, a pokeweed antiviral protein from leaves, and the lectin griffithsin using the special CoDockPP COVID-19 version. These experiments revealed novel binding mechanisms of RTAM-PAP1 with a high affinity to numerous SARS-CoV-2 key proteins. RTAM-PAP1 was further characterized in a preliminary toxicity study in mice and was found to be a potential therapeutic candidate. These findings might lead to the discovery of novel SARS-CoV-2 targets and therapeutic protein structures with outstanding functions.

A phase 1 study of Combotox in pediatric patients with refractory B-lineage acute lymphoblastic leukemia.

BACKGROUND: Acute lymphoblastic leukemia (ALL) is the most common cancer in children. Combotox is a 1:1 mixture of RFB4-dgA and HD37-dgA which are immunotoxins that target the CD22 and CD19 antigens, respectively. Combotox has different toxicities and targets than chemotherapy and is, thus, a new candidate for the treatment of patients with relapsed ALL. Preclinical data have demonstrated which Combotox is effective in killing pre-B-ALL cell lines and cells from patients with pre-B ALL. METHODS: We designed and conducted a Phase 1 dose-escalation study using Combotox in children with refractory or relapsed B-lineage-ALL. Seventeen patients aged 1 to 16 years were enrolled in this multi-institution study. They were treated at 4-dose levels: 2 mg/m2, 4 mg/m2, 5 mg/m2, and 6 mg/m2. RESULTS: The maximum tolerated dose was 5 mg/m2 and graft versus host disease defined the maximum tolerated dose. Three patients experienced complete remission. Six additional patients experienced a decrease of >95% in their peripheral blood blast counts, and 1 patient experienced a decrease of 75%. CONCLUSIONS: Combotox can be safely administered to children with refractory leukemia. It has clinically important anticancer activity as a single agent. The recommended dose for future studies is 5 mg/m2/dose.

Immunotoxins in cancer therapy: Review and update.

Immunotoxins are a novel class of cancer therapeutics that contains a cytotoxic agent fused to a targeting moiety. Various toxic agents from different sources are used in immunotoxin development, including bacterial, plant and human origin cytotoxic elements. Although bacterial and plant-derived toxins are highly toxic and commonly used in immunotoxins, their immunogenicity for human restricted their application in cancer therapy. Here, we discuss the advantages and limitations of bacterial toxins such as Pseudomonas and Diphtheria toxins, plant toxins such as ricin and gelonin, and some endogenous protein of human origin such as RNases and Granzymes. This article will also review different generations of immunotoxins with special focus on immunotoxins which are under clinical trials or approved for clinical use. Finally, current deimmunization strategies for development of new less-immunogenic recombinant immunotoxins will be discussed. ABBREVIATIONS: mAbs: Monoclonal antibodies; EF2: elongation factor 2; ITs: Immunotoxins; DT: Diphtheria toxin; PE: Pseudomonas exotoxin; dgA: de-glycosylated A-chain of ricin; rGel: recombinant de-glycosylated form of gelonin; NKC: natural killer cells; HTR: human transferrin receptor; EGF: epidermal growth factor; GM-CSF: granulocyte-macrophage colony-stimulating factor; DAB389: truncated Diphtheria toxin; B-CCL: B-cell chronic lymphocytic leukemia; RCC: renal cell carcinoma; GVHD: Graft-versus-host disease; EGFR: epidermal growth factor receptor; AML: acute myeloid leukemia; Fab: fragment antigen-binding; dsFv: disulfide-stabilized fragment variable; scFv: single-chain fragment variable; B-ALL: B-lineage Acute Lymphoblastic Leukemia; Fv: fragment variable; HCL: hairy cell leukemia; IL-2R: Interleukin-2 receptor; CR: complete response; CLL: chronic lymphocytic leukemia; ATL: adult T-cell leukemia; DARPins: designed Ankyrin repeat proteins; pmol: picomolar; HAMA: human-anti mouse antibody.

Lectin derivatives of methotrexate and chlorambucil as chemotherapeutic agents.

Methotrexate and chlorambucil, each covalently linked to either abrus agglutinin, abrin, ricinus agglutinin, ricin, or concanavalin A, were prepared. A single dose of the derivative injected ip into sarcoma 180-bearing noninbred N:NIH(S) white mice resulted in prolongation of the survival time and was more effective than an equivalent dose of free drug and lectin. Drug-lectin also showed a higher inhibitory effect on the DNA biosynthesis of the tumor cell than did an equivalent dose of the free drug and lectin.

Thy 1.2+ leukemia cells eradicated from in vitro leukemia-bone marrow cell mixtures by antibody-toxin conjugates.

A conjugate constituted by a monoclonal anti-Thy 1.2 antibody chemically coupled to the toxic subunit of ricin was synthesized. The conjugate was specifically cytotoxic for Thy 1.2+ (EL 4) but not for Thy 1.2- (BW5147) thymoma cells. In vitro treatment of bone marrow-leukemia cell mixtures (10:1 and 1:1 bone marrow to EL 4 cell ratios) with anti-Thy 1.2-ricin A chain totally eradicated EL 4 tumor cells, while the number of myeloid colony-forming units and pluripotent colony-forming units developed in vitro and in vivo was unaffected, which suggested that the treatment had no toxic side effects at least on the precursor cells examined.

Restoration of interferon alpha potentiation of a recombinant ricin A chain immunotoxin following cytoreduction of xenografts of advanced ovarian tumors.

BACKGROUND: We have demonstrated that, in the human ovarian carcinoma cell line (OVCAR-3), recombinant human interferon alpha (rHuIFN-alpha) potentiated in vitro inhibition of protein synthesis by immunotoxins. The antitumor activity of intracavitary immunotoxin administered to nude mice 5 days after tumor cell injection was enhanced by a nontherapeutic dose of rHuIFN-alpha, as evidenced by increased survival time. PURPOSE: Our purpose was to determine the outcome of treatment with immunotoxin and rHuIFN-alpha in xenografts of more advanced tumors. METHODS: At 10 or 15 days after tumor cell injection, nude mice with peritoneal OVCAR-3 xenografts were treated intraperitoneally with immunotoxin or with 454A12 monoclonal antibody (MAb) recombinant ricin A chain (rRA), alone or combined with a nontherapeutic dose of rHuIFN-alpha. The immunotoxin was composed of rRA covalently bound to an anti-CD71 (transferrin receptor) MAb. In other experiments, mice were treated intraperitoneally with cyclophosphamide and cisplatin to reduce tumor size on days 20 and 27 after tumor cell inoculation and then, beginning on day 40, with immunotoxin alone or combined with rHuIFN-alpha. RESULTS: Initiation of treatment 10 days after OVCAR-3 transplantation significantly increased median survival from 41 to 89 days (10% survivors on day 120) with 454A12 MAb rRA alone and to more than 120 days (70% survivors) with 454A12 MAb rRA combined with rHuIFN-alpha (P < .0001). The increase in survival time between tumor-bearing mice treated with immunotoxin combined with rHuIFN-alpha and those treated with immunotoxin alone was statistically significant (P = .017). In contrast, the 15-day transplant tumors were not curable with immunotoxin therapy (survival, 72 days; 0% survivors) and were refractory to rHuIFN-alpha potentiation (survival, 75 days; 0% survivors). After the second course of chemotherapy to reduce the size of the advanced tumors (day 40), during the ascites cell count nadir, initiation of treatment with 454A12 MAb rRA alone or combined with rHuIFN-alpha resulted in significantly different survival times of 129 and 162 days, respectively (P = .0037). Pathologic examination of surviving mice treated with chemotherapy and 454A12 MAb rRA alone or in combination with rHuIFN-alpha revealed that one (17%) of six mice and 11 (65%) of 17 were tumor free, respectively. CONCLUSIONS: The synergy between immunotoxins and IFN-alpha is dependent on tumor burden. These agents are less effective against large tumor burdens (i.e., advanced stage disease), but their beneficial effects re-emerge after cytoreduction by combination chemotherapy. IMPLICATIONS: The ideal setting for testing the efficacy of intracavitary immunotoxin combined with rHuIFN-alpha after front-line chemotherapy is in patients with residual tumor refractory to additional chemotherapy or in those with toxic effects that prevent delivery of effective doses.

Targeted toxin therapy for the treatment of cancer.

Protein toxins such as Pseudomonas exotoxin, diphtheria toxin, and ricin may be useful in cancer therapy because they are among the most potent cell-killing agents. One molecule of a toxin delivered to the cytoplasm of a cancer cell will be lethal for that cell. However, to be therapeutically useful, these toxins need to be targeted to specific sites on the surface of cancer cells, then be internalized and ultimately reach the cell cytoplasm. This process is accomplished by eliminating binding to toxin receptors and redirecting the cell-killing activity of the toxin to receptors or antigens present on cancer cells. Typically, toxins are conjugated to cell-binding proteins such as monoclonal antibodies or growth factors. These conjugates bind and kill cancer cells selectively while normal cells, which don't bind the conjugates, are spared. Because the genes for many protein toxins have been cloned, it is possible to make genetic modifications to their structure. By deleting the DNA that codes for the toxin binding region and replacing it with various complementary DNA encoding other cell-binding proteins, it has been possible to make chimeric toxins that kill cells on the basis of the newly acquired binding activity. The ability to make these chimeras may be useful in designing future toxin-based anticancer therapies.

Elimination of neuroblastoma and small-cell lung cancer cells with an anti-neural cell adhesion molecule immunotoxin.

BACKGROUND: The development of immunotoxins has been hampered by difficulties, particularly in solid tumors, of finding appropriate target antigens and of linking sufficiently potent toxins. PURPOSE: We evaluated the tissue specificity of an immunotoxin, N901-blocked ricin (N901-bR), and assessed its potential for eliminating neural cell adhesion molecule (NCAM)-positive tumor cells in conditions appropriate for in vitro purging, prior to autologous stem cell transplantation, and its potential for myelosuppression. N901-bR consists of a monoclonal antibody (MAb), N901, directed against CD56, an antigen of the family of NCAMs, covalently linked to blocked ricin as the cytotoxic effector moiety. METHODS: The tissue specificity of the N901 MAb and the N901-bR immunotoxin was tested against a wide array of human tumor tissues and normal human tissues by immunohistochemical staining. The cytotoxic activity of N901-bR was tested against both small-cell lung cancer (SCLC) cells and neuroblastoma cells, either alone or among normal bone marrow mononuclear cells, and the efficacy of this treatment to specifically eliminate these cells was evaluated in a limiting dilution assay. In addition, normal bone marrow mononuclear cells were incubated with N901-bR, and the toxic effects of the immunotoxin on normal hematopoietic progenitors was evaluated. RESULTS: N901 and N901-bR exhibited specificity for several neoplasms of neuroectodermal origin, including SCLC and neuroblastoma. Staining of normal tissues was essentially limited to various neuroendocrine cells, cardiac muscle cells, and cells in peripheral nerve tissue. We observed a time- and dose-dependent elimination of tumor cells in vitro, with three logs (i.e., > 99.9%) of malignant cells being killed following only 5 hours of exposure to 10 nM N901-bR. Unconjugated N901 MAb specifically blocked the elimination of NCAM-positive cells by N901-bR, whereas neither an isotype-matched control MAb nor galactose (the ligand of native ricin) had any effect on the activity of the immunotoxin, confirming the specificity of its cytotoxic activity. Importantly, N901-bR used under optimal conditions for in vitro tumor cell depletion was not toxic to hematopoietic precursors. CONCLUSIONS: N901-bR has the properties required to target CD56, an antigen present not only on cells from a large number of cancers of neuroendocrine origin, but also on some important normal tissues. In addition, treatment with this immunotoxin results in the highly effective and specific elimination of neuroblastoma and SCLC cells and does not affect normal hematopoietic progenitors. IMPLICATIONS: N901-bR may have clinical utility for purging of neuroblastoma cells and SCLC cells before autologous stem cell transplantation. Further toxicology studies are warranted to assess the potential of N901-bR for in vivo administration.

Phase I study of an anti-breast cancer immunotoxin by continuous infusion: report of a targeted toxic effect not predicted by animal studies.

260F9 Monoclonal antibody-recombinant ricin A chain, an immunotoxin reactive with approximately 50% of breast carcinomas, was given by continuous iv infusion at a dose of 50 micrograms/kg per day or 100 micrograms/kg per day. Five patients with refractory breast cancer received treatment for from 6 to 8 days. Severe toxic effects, including marked fluid overload and debilitating sensorimotor neuropathies, occurred in most patients. Immunoperoxidase studies suggested that 260F9 monoclonal antibody targeting of the Schwann cells may have induced demyelination and subsequent neuropathy. This is the first report of a targeted toxic effect due to an immunoconjugate.

An immunotoxin composed of monoclonal anti-Thy 1.1 antibody and a ribosome-inactivating protein from Saponaria officinalis: potent antitumor effects in vitro and in vivo.

The ribosome-inactivating protein saporin, from Saponaria officinalis, was coupled by a disulfide bond to monoclonal anti-Thy 1.1 antibody (OX7) and to its F(ab')2 fragment. The immunotoxins were at least as toxic as the plant toxin ricin to the Thy 1.1-expressing cell lines AKR-A and BW5147 in tissue culture. They reduced the rate at which the cells incorporated [3H]leucine into protein by 50% at cell concentrations of 1.5-3 X 10(-11) and 3 X 10(-12) M, respectively. The toxic effect was specific. No toxicity was seen when the immunotoxins were applied to Thy 1.2-expressing EL 4 lymphoma cells at 3 X 10(-8) M, and a control immunotoxin made from an antibody (R10) of irrelevant specificity was without effect on AKA-A cells. Further, the treatment of spleen cells from AKR mice with OX7-saporin at 10(-8) M abolished their response to the T-lymphocyte mitogen concanavalin A, without impairing their response to the B-lymphocyte mitogen lipopolysaccharide. A single iv injection of OX7-saporin into nu/nu randombred mice bearing peritoneal AKR-A lymphoma cells prolonged the survival time of the animals by an extent corresponding to that expected if 99.999% of the tumor cells had been eradicated by the immunotoxin. None of the control materials (unconjugated OX7, unconjugated saporin, OX7 plus saporin, or R10-saporin) delayed tumor growth. The OX7 F(ab')2-saporin conjugate was also highly effective as an antitumor agent, although significantly less so than the conjugate made with intact OX7. Unexpectedly, the acute toxicity of saporin to mice (median lethal dose = 6.8 mg/kg) was elevated eightfold to sixteenfold by conjugation to OX7, R10, or OX7 F(ab')2. Histologic examination of recipients of the immunotoxin revealed gross damage to hepatic parenchymal cells and to the white pulp of the spleen, neither of which was caused by unconjugated saporin. Ricin A-chain coupled to OX7 antibody was one hundredfold to one thousandfold less effective than OX7-saporin as an antitumor agent in vivo, although the two immunotoxins were equally cytotoxic to AKR-A cells in vitro.

Targeted anticancer immunotoxins and cytotoxic agents with direct killing moieties.

Despite the progress of the bioinformatics approach to characterize cell-surface antigens and receptors on tumor cells, it remains difficult to generate novel cancer vaccines or neutralizing monoclonal antibody therapeutics. Among targeted cancer therapeutics, biologicals with targetable antibodies or ligands conjugated or fused to toxins or chemicals for direct cell-killing ability have been developed over the last 2 decades. These conjugated or fused chimeric proteins are termed immunotoxins or cytotoxic agents. Two agents, DAB389IL-2 (ONTAKTM) targeting the interleukin-2 receptor and CD33-calicheamicin (Mylotarg), have been approved by the FDA for cutaneous T-cell lymphoma (CTCL) and relapsed acute myeloid leukemia (AML), respectively. Such targetable agents, including RFB4(dsFv)-PE38 (BL22), IL13-PE38QQR, and Tf-CRM107, are being tested in clinical trials. Several agents using unique technology such as a cleavable adapter or immunoliposomes with antibodies are also in the preclinical stage. This review summarizes the generation, mechanism, and development of these agents. In addition, possible future directions of this therapeutic approach are discussed.

Inhibition of human T-cell tumor growth by T101-ricin A-chain in an athymic mouse model.

An immunotoxin prepared with the pan-T-cell, anti-CD5, antibody T101, and purified ricin A-chain (RTA) was selectively cytotoxic in vitro, inactivating protein synthesis in the human T-cell line MOLT-4 but not in the human B-cell line 8392. Modulation studies showed that the immunoconjugate was more rapidly cleared from the cell surface than unconjugated T101. Preclinical evaluation of T101-RTA was conducted in a human T-cell, athymic mouse model (Dillman et al., Cancer Res., 45:5632-5336, 1985). Tumor-bearing mice received single i.p. injections of saline, T101, UPC-10 (irrelevant IgG2a), unconjugated RTA, an irrelevant conjugate, UPC-10-RTA, a mixture of T101 plus RTA, or T101-RTA. T101-RTA was the most effective reagent. Thirty animals given injections of 33 micrograms of T101 showed reductions in tumor growth (compared to tumor growth in animals receiving phosphate-buffered saline) but no complete regressions. No decrease in tumor growth was observed with UPC-10. Animals given 12 micrograms of free RTA exhibited reduced tumor growth but only one complete regression was observed; similar results were obtained with mice given 45 micrograms of UPC-10-RTA or a mixture of 33 micrograms of T101 plus 12 micrograms of RTA. Eleven complete regressions and 18 partial regressions were produced in the 46 animals given injections of 45 micrograms of T101-RTA and tumor growth was almost completely blocked. No toxicity was observed in any experimental arm. These results suggest that T101-RTA may be administered safely and with significant antitumor effect.

Anti-B4-blocked ricin immunotoxin shows therapeutic efficacy in four different SCID mouse tumor models.

Anti-CD19 monoclonal antibody anti-B4 (IgG1) conjugated to the novel toxin-blocked ricin forms a potent immunotoxin, anti-B4-blocked ricin, that kills greater than 4.5 logs of CD19-positive cells in vitro after a 24-h exposure to a conjugate concentration of 5 x 10(-9) M (1.11 micrograms/ml). The efficacy of anti-B4-blocked ricin in vivo was assessed in survival models of SCID mice bearing either a human B-cell lymphoma (Namalwa), a human non-T and non-B acute lymphoblastic leukemia (Nalm-6), or a murine B-cell lymphoma transfected with the human CD19 gene (300B4). In one model, 5 x 10(7) tumor cells were injected i.p., and 1 h later the mice were treated with i.v. bolus injections of anti-B4-blocked ricin at 100 micrograms/kg/day for 5 days. Controls included similar treatment with anti-B4 antibody (72 micrograms/kg/day or 2 mg/kg/day for 5 days) alone or with the isotype-matched nonspecific immunotoxin, N901-blocked ricin (100 micrograms/kg/day). In a second model, 4 x 10(6) tumor cells were injected i.v., and 7 days later mice were treated i.v. as above. Anti-B4-blocked ricin showed efficacy by killing in vivo up to 3 logs of tumor cells, which was manifested in significant prolongation of the life of the treated animals. Only very limited or no effects were observed in animals treated with either anti-B4 antibody alone or N901-blocked ricin control conjugate. The concentration of anti-B4-blocked ricin in the blood of animals was 150 ng/ml after the first i.v. injection and about 800 ng/ml following the fifth injection of conjugate. This increase may be due to damage to the reticuloendothelial system by anti-B4-blocked ricin, since the rate of clearance of carbon from blood also decreased 5-fold after five injections as compared to the rate after only one injection. These studies indicate that anti-B4-blocked ricin has the potential to increase survival times of hosts with malignant disease.

Antidisialoganglioside ricin A-chain immunotoxins show potent antitumor effects in vitro and in a disseminated human neuroblastoma severe combined immunodeficiency mouse model.

Several monoclonal antibodies (mAbs) were screened on different neuroblastoma cell lines to evaluate ricin A-chain immunotoxins for possible use against human neuroblastoma. Four mAbs were identified that exhibited high antitumor activity against neuroblastoma cell lines as measured in an indirect cytotoxicity assay. These mAbs, including 14G2a (antidisialoganglioside), ch14.18 (a humanized switch variant), BW704 (antidisialoganglioside), and chCE7 (anti-glycoprotein of M(r) 190,000), were subsequently linked via the bivalent linker N-succinimidyloxycarbonyl-alpha-methyl-alpha-(2-piridyldithio++ +)toluene to deglycosylated ricin A chain. The most potent immunotoxin, 14G2a.dgA, inhibited the protein synthesis of neuroblastoma cell lines IMR5 and NMB by 50% at concentrations of 6 x 10(-12) M. To test the antitumor efficacy of these immunotoxins in vivo, we developed a disseminated human neuroblastoma model in severe combined immunodeficiency mice. Treatment of tumor-bearing mice with 14G2a.dgA 12 days after tumor challenge resulted in a significant prolongation of survival as compared with phosphate-buffered saline-treated controls (16.8 versus 6.5 weeks). We conclude that ricin A-chain immunotoxins might be of potential use in the treatment of human neuroblastoma.

Antitumor activity of intraperitoneal immunotoxins in a nude mouse model of human malignant mesothelioma.

Immunotoxins directed against human transferrin receptor have been evaluated in a nude mouse model of human malignant mesothelioma. Immunotoxins were constructed by linking ricin A chain to murine monoclonal antibodies reactive with the human transferrin receptor. A chain was obtained either by isolation from the parent toxin or by recombinant DNA techniques. These immunotoxins acted as potent in vitro cytotoxins against human malignant mesothelioma cells (H-MESO-1) (ID50, 2 X 10(-9) M). Cytotoxic potency and kinetics of cell kill were potentiated in vitro by the carboxylic ionophore monensin. For in vivo trials, nude mice were injected i.p. with 6-9 X 10(6) human malignant mesothelioma cells 24 h prior to the start of i.p. immunotoxin treatments. The survival of tumor-bearing mice was extended by 149-404%, representing a probable cell kill of 2-4 logs. Specificity of this antitransferrin receptor immunotoxin response was confirmed by the ineffectiveness of irrelevant control immunotoxins and blockade of specific immunotoxin action by excess free antibody. Monensin showed limited in vivo potentiation of immunotoxin effect, but a derivative formed by esterification of monensin with linoleic acid gave improved survival times over treatment with immunotoxin alone. Immunotoxins constructed with ricin A chain have significant tumoricidal activity in this model of regional antitumor therapy. These results may have direct relevance for treatment of i.p. malignancy in clinical settings.

An immunotoxin cytotoxic for breast cancer cells in vitro.

A potent immunotoxin was formed by conjugating the murine monoclonal antibody 323/A3 to the A chain of ricin. The 323/A3 antibody recognizes an antigen expressed by most human breast cancers. When binding of 323/A3 is examined by enzyme-linked immunosorption assay, three human breast cell lines displayed strong binding, whereas two human breast cell lines and three non-breast cell lines displayed little or no binding. When the cell lines were tested at a concentration of 0.1 microgram/ml, those cell lines which displayed an abundance of antigen by enzyme-linked immunosorption assay were most sensitive to the effects of the 323/A3 immunotoxin. On the other hand, cell lines which displayed little or no antigen by enzyme-linked immunosorption assay were not inhibited by the immunotoxin at this concentration. Further examination of the effects of immunotoxin concentration on protein synthesis confirmed the sensitivity of those cell lines rich in the 323/A3 antigen over a broad dose range. Similarly, three cell lines which displayed little of the 323/A3 antigen demonstrated little inhibition of protein synthesis with various concentrations of 323/A3 immunotoxin. However, two cell lines which displayed little antigen were intermediate in their sensitivity to the 323/A3 immunotoxin. Preclinical evaluation of immunotoxins as potential therapeutic agents will require accurate and sensitive screening of a wide variety of cell types. The 323/A3 remains of interest in studying the effects of immunotoxin in a defined in vivo model system.