Cellular resistance to the antimelanoma immunotoxin ZME-gelonin and strategies to target resistant cells

 The development of cellular resistance to immunotoxins has been demonstrated in a variety of models and can involve a number of mechanisms. For the present study, an immunotoxin was utilized composed of an antimelanoma antibody ZME-018 recognizing a 240-kDa surface glycoprotein (gp 240) and the plant toxin gelonin. Human melanoma cells (A375-M) were grown in the presence of increasing amounts of ZME-gelonin and a clonal variant (A-375-ZR) was developed that was 100-fold resistant to ZME-gelonin compared to parental cells. Scatchard analysis showed that the A375-M parental cells had 260×10³ ZME-gelonin-binding sites/cell with relatively low affinity (5 nM). In contrast, resistant A375-ZR cells demonstrated a reduced number of low-affinity sites (160×10³/cell), but showed a small number (47×10³) of higher-affinity sites (0.8 nM). Internalization rates and degradation rates of ¹²⁵I-labeled ZME-gelonin were identical in both the parental and resistant cells. A375-ZR cells were found to be more resistant to vincristine and doxorubicin than were parental cells. Both cell lines were almost equally sensitive to native gelonin, 5-fluorouracil (5-FU), cisplatin, melphalan, carmustine, interferon γ (IFNγ) and IFNα. In addition, both cell lines were equally sensitive to another gelonin-antibody conjugate that binds to cell-surface, GD₂ (antibody 14G₂A). However, resistant cells were twice as sensitive to the cytotoxic effects of etoposide than were parental cells. Finally, a variety of agents were tested in combination with ZME-gelonin against A375-ZR cells in an attempt to identify agents to augment immunotoxin cytotoxic effects against resistant cells. The agents 5-FU, cisplatin, IFNγ, IFNα, and etoposide were the most effective in augmenting the cytotoxicity of ZME-gelonin against resistant cells. These studies suggest that development of resistance to one immunotoxin does not cause development of cross-resistance to other gelonin immunotoxins. Further, specific biological response modifiers and chemotherapeutic agents may be effective in augmenting the effectiveness of immunotoxins and specifically targeting or reducing the emergence of immunotoxin-resistant cells. Received: 15 March 1995 / Accepted: 28 November 1995     

A comparative study of the subcellular distribution of native and deglycosylated gelonin in rat liver and kidney

Intravenous injection of gelonin and deglycosylated gelonin led to rapid clearance from the blood. Both molecules distributed similarly in liver and kidney suggesting that they followed the same pathway. Deglycosylation reduced the uptake by a third in liver, but did not affect uptake by kidney. Studies with Triton WR1339 showed a classical lysosomal pathway for both molecules. The deglycosylated molecule was degraded to a greater extent than native gelonin as seen by the presence of acid soluble radioactivity. Cell separation showed that while endothelial cells mainly took up native gelonin, Kupffer cells took up the deglycosylated molecule.     

Liposome-mediated delivery of ribosome inactivating proteins to cells in vitro

This study describes the liposome-mediated delivery of toxins to a variety of cells in vitro. Gelonin, a potent inhibitor of protein synthesis from Gelonium multiflorum, was delivered to the cytoplasm of TLX5 lymphoma cells most effectively by phosphatidylserine vesicles. These liposomes were also capable of inhibiting protein synthesis in XC (transformed rat fibroblasts) and phytohaemagglutinin-stimulated CBA mouse lymphocytes. Phosphatidylcholine liposomes had no capacity to deliver their contents to the cytoplasm, but the addition of cholesterol to the vesicle membrane resulted in an increased capacity. Delivery events were enhanced further by the addition of mixed bovine brain gangliosides to the membrane in the ratio 5:5:1 phosphatidylcholine/cholesterol/gangliosides. The addition of cholesterol to phosphatidylserine vesicles failed to increase the inhibitory effects of the gelonin liposomes. The A chain of diphtheria toxin encapsulated in phosphatidylserine liposomes had no inhibitory effect on the level of protein synthesis in TLX5 or Daudi cells.     

Intein-mediated fusion expression, high efficient refolding, and one-step purification of gelonin toxin

An open reading frame of gelonin (Gel), one of ribosome inactivating proteins, was inserted into the vector pBSL-C which contains the coding region of chitin binding domain (CBD)-intein, resulting in the fusion expression of CBD-intein-Gel in Escherichia coli BL21 (DE3) by the induction of IPTG. The fusion product formed an aggregate of the misfolded protein, commonly referred to as inclusion bodies (IBs). The IBs were denatured and then refolded by step-wise dialysis. About 69% fusion protein was in vitro refolded to native state in the presence of GSSG and GSH as monitored by size-exclusion HPLC. The refolded CBD-intein-Gel was loaded onto chitin beads column equilibrated with 10 mM Tris buffer, 500 mM NaCl, pH 8.5, and about 2.4 mgGel/L culture with 96% homogeneity was directly eluted from the captured column by incubation at 25 degrees C under pH 6.5 for 48 h based on intein C-terminal self-cleavage. Western blot, ELISA, and in vitro inhibition of protein synthesis demonstrated that the bioactivity of recombinant Gel was comparable to that of native Gel purified from seeds. This implied that the purified Gel by this method is biologically active and suitable for further studies.     

Role of aromatic stack pairing at the catalytic site of gelonin protein

Aromatic–aromatic interactions play an important role in the enzyme–substrate recognition mechanism and in stabilization of proteins. Gelonin – a ribosome inactivating protein (RIP) from the plant Gelonium multiflorum – belongs to type-I RIPs and shows N-glycosylation activity which has been used as a model to explain the role of aromatic–aromatic stack pairing in RIPs. RIPs have a different substrate binding site and catalytic site. Role of tyrosine residues at the binding site has already been known but the role of tyrosine residues at catalytic site is still unclear. In this study, the role of tyrosine–adenine–tyrosine aromatic stack pairing at the catalytic site was studied by in silico mutation studies using molecular dynamic simulations. Through this study we report that, despite the fact that aromatic stack pairing aids in recognition of adenine at binding site, both the tyrosine residues of stack pairing play a crucial role in the stabilization of adenine at catalytic site. In the absence of both the tyrosine residues, adenine was unstable at catalytic site that results in the inhibition of N-glycosylation activity of gelonin protein. Hence, this study highlights the importance of π–π stack pairing in the N-glycosidic activity of gelonin by determining its role in stabilizing adenine at catalytic site.     

Convergent potency of internalized gelonin immunotoxins across varied cell lines, antigens, and targeting moieties

Gelonin-based immunotoxins vary widely in their cytotoxic potency as a function of antigen density, target cell internalization and trafficking kinetics, and conjugate properties. We have synthesized novel gelonin immunotoxins using two different binding scaffold types (single-chain antibody variable fragments and fibronectin domains) targeting two different tumor antigens (carcinoembryonic antigen and EGF receptor). Constructs were characterized using an antigen-negative cell line (HT-1080), cell lines positive for each antigen (HT-1080(CEA) for carcinoembryonic antigen and A431 for EGF receptor), and a cell line positive for both antigens (HT-29). Immunotoxins exhibited K(d) values between 8 and 15 nm and showed 20-2000-fold enhanced cytotoxicity compared with gelonin (IC(50) ～ 0.25-30 nM versus 500 nM). Using quantitative fluorescence flow cytometry, we measured internalization of gelonin (via pinocytosis) and gelonin-based immunotoxins (via antigen-dependent, receptor-mediated endocytosis). Results were matched with cytotoxicity measurements made at equivalent concentration and exposures. Unexpectedly, when matched internalization and cytotoxicity data were combined, a conserved internalized cytotoxicity curve was generated that was common across experimental conditions. Considerable variations in antigen expression, trafficking kinetics, extracellular immunotoxin concentration, and exposure time were all found to collapse to a single potency curve on the basis of internalized immunotoxin. Fifty percent cytotoxicity occurred when ～ 5 × 10(6) toxin molecules were internalized regardless of the mechanism of uptake. Cytotoxicity observed at a threshold internalization was consistent with the hypothesis that endosomal escape is a common, highly inefficient, rate-limiting step following internalization by any means tested. Methods designed to enhance endosomal escape might be utilized to improve the potency of gelonin-based immunotoxins.     

Uptake and intracellular fate of gelonin,a ribosome-inactivating protein,in rat liver

Gelonin, a type 1 ribosome-inactivating protein, has been used as toxin conjugate for several therapeutic purposes. We have investigated the endocytosis of gelonin by rat liver in vivo. Subcellular distribution of [125I]gelonin was established after differential and isopycnic centrifugation. Fractions were analyzed for acid-soluble and acid-precipitable radioactivity. Results show that gelonin is rapidly cleared from the blood and within 15min reaches a peak (25% of total injected) in the liver. With time, radioactivity associated with the liver markedly decreases. Two important observations are made: (a) Radioactivity associated with all fractions, at any time point, is greater than 80% acid precipitable. (b) Even at 5min, a significant amount of intact gelonin is present in the cytosolic fraction. Our work suggests that, though gelonin is rapidly cleared from the blood, there are still intact molecules that have entered the cytosol where they could exert their toxic effect.     

Characterization of murine and humanized anti-CD33, gelonin immunotoxins reactive against myeloid leukemias

M195 antibodies recognize CD33, an antigen present on acute myeloid leukemia blasts as well as some myeloid progenitor cells, but not on the ultimate hematopoietic progenitor stem cell. Immunotoxins (IT) reactive with human myeloid leukemias were constructed by conjugating gelonin, a single-chain ribosome-inactivating protein, to murine and genetically engineered, humanized M195 antibodies via anN-succinimidyl-3-(2-pyridyldithio)-propionate linkage. No losses of gelonin cytotoxic activity or M195 binding activity were observed after conjugation of up to two toxin molecules per antibody. Toxin conjugates displayed specific, potent toxicity for CD33⁺ cells. The murine and humanized IT were not toxic to CD33^– cells and were 600 and 4500 times more potent, respectively, than free gelonin in inhibiting CD33⁺ HL60 cells. Treatment of HL60 cells with 1 g/ml HuM195-gelonin resulted in more than 1000 times lower colony formation; normal bone marrow mononuclear cell colonyforming units treated with HuM195-IT were reduced by a factor of 10. HL60 leukemia cells could be effectively purged from an excess of normal bone marrow cells. Exposure of target cells to IT for as little as 30 min was as effective as continuous exposure of IT for up to 6 days. However, measures of the efficacy of the immunotoxin were directly related to the length of time of observation after IT exposure and were inversely related to cell concentration. M195-gelonin immunoconjugates are potential candidates for therapeutic use in in vivo or ex vivo bone marrow purging of myeloid leukemias.These studies were supported in part by the Lucille P. Markey Charitable Trust, ACS Grant No. IM551, NIH PO1CA33049, NIH RO1CA55349. Research conducted, in part, by the Clayton Foundation for Research. David A Scheinberg is a Lucille P. Markey Scholar     

On the contentious sequence and glycosylation motif of the ribosome inactivating plant protein gelonin

The amino acid sequence and the glycosylation motif of the ribosome inactivating protein (RIP) gelonin are identified by Fourier transform ion cyclotron resonance mass spectrometry. Intact gelonin as isolated from the seeds of Gelonium multiflorum consists of at least three different post-translational modified forms: analysis of gelonin peptides as obtained by proteolytic digestion is consistent with the amino acid sequence published by Nolan et al. High resolution mass determination established a glycosylation pattern of GlcNAc2Man(3-5)Xyl. N189 was identified as glycosylation site. The proposed glycan structure is consistent with a standard plant N-glycosylation pattern as found in other RIP. Based on these results we suggest that gelonin is located in the vacuole of Gelonium multiflorum seeds.