Killing of cultured hepatocytes by conjugates of asialofetuin and EGF linked to the A chains of ricin or diphtheria toxin

A disulfide-linked conjugate between asialofetuin (ASF) and the toxic A chain (RTA) of ricin is as potent a toxin for cultured rat hepatocytes as our previously described conjugate between ASF and fragment A of diphtheria toxin (DTA). An RTA conjugate of epidermal growth factor (EGF) was a potent toxin for 3T3 cells. In contrast, EGF-DTA was essentially nontoxic for 3T3 cells. We have now examined the toxicity of EGF-RTA and EGF-DTA on cultured hepatocytes. The EGF-DTA conjugate, nontoxic to 3T3 cells, is also a potent toxin for hepatocytes. We also observed a decrease with time of culture in the sensitivity of hepatocytes to the ASF and EGF conjugates. This decrease is not a result of a decrease in EGF or asialoglycoprotein receptors.     

An epidermal growth factor-ricin A chain (EGF-RTA)-resistant mutant and an epidermal growth factor-Pseudomonas endotoxin (EGF-PE)-resistant mutant have distinct phenotypes

H2Oe12 is a mutant HeLa cell line selected for resistance to the toxicity of a chimeric protein conjugate composed of epidermal growth factor (EGF) and the toxic A chain of ricin (RTA). ET-28 is a mutant KB cell line selected for resistance to the toxicity of a chimeric protein conjugate composed of EGF and Pseudomonas exotoxin (PE). In this report we describe the presence or absence, in these mutants, of cross-resistance to the two toxic conjugates and the effects of ammonium chloride, leupeptin, and adenovirus cotreatments on toxin efficacies. ET-28 cells, the EGF-PE-resistant cells, are resistant to both EGF-PE and EGF-RTA. In contrast, H2Oe12 cells, the EGF-RTA-resistant cells, are as sensitive to EGF-PE toxicity as are their parent HeLa cells. Ammonium chloride cotreatment substantially reduces the resistance of H2Oe12 cells to EGF-RTA but has little or no effect on the resistance of ET-28 cells to either EGF-RTA or EGF-PE. Leupeptin has no effect on the toxicity of either chimeric conjugate on any of the four cell lines, effect on the toxicity of either chimeric conjugate on any of the four cell lines, despite its demonstrated ability to inhibit cellular degradation of EGF. In contrast, adenovirus cotreatment enhances the toxicity of EGF-RTA and EGF-PE on all cells tested, and completely nullifies the relative resistance of H2Oe12 and ET-28 cells to these toxic conjugates. H2Oe12 and ET-28 cells appear to be altered in distinct, possibly endosomal, functions.     

The role of binding ligand in toxic hybrid proteins: a comparison of EGF-ricin, EGF-ricin A-chain, and ricin

To analyze the influence of ricin B-chain on the toxicity of hybrid-protein conjugates, the rate of cellular uptake of conjugates, and the rate at which ricin A-chain (RTA) is delivered to the cytoplasm, we have constructed toxic hybrid proteins consisting of epidermal growth factor (EGF) coupled in disulfide linkage either to ricin or to RTA. EGF-ricin is no more toxic on A431 cells than EGF-RTA. The two conjugates demonstrate similar kinetics of cellular uptake (defined as antibody irreversible toxicity). EGF-RTA and EGF-ricin, like ricin, required a 2-2 1/2 hour period at 37 degrees before the onset of protein synthesis inhibition occurred. Our results suggest that RTA determines the processes which carry it, either in conjugate or toxin, from the plasma membrane binding site to the cytoplasm following endocytosis, and the ricin B chain is not required for these processes.     

HeLa cell mutants resistant to epidermal growth factor ricin A-chain conjugate

Epidermal growth factor (EGF) was linked to the toxic A chain of ricin toxin (RTA) to produce an EGF-receptor-specific cytotoxic agent, EGF-RTA. Three EGF-RTA-resistant mutants of the human HeLa cell line were selected. These mutant cell lines are 10-fold to more than 100-fold more resistant to EGF-RTA when compared to HeLa cells. The EGF-RTA-resistant mutants have at least as many EGF receptors as parent cells; the basis for the EGF-RTA-resistant phenotype must be distal to EGF binding. The EGF-RTA-resistant cells are not cross-ressitant to ricin or to diphtheria toxin; their mutant phenotype appears to be EGF specific. The EGF-RTA-resistant mutants are able to internalize and degrade EGF. However, the mutants have altered EGF receptor down-regulation and phorbol 12-tetradecanoate 13-acetate modulation properties. EGF-RTA/ammonium chloride and EGF-RTA/adenovirus co-treatment data suggest that the mutant defect(s) which confers EGF-RTA resistance is either in the endosome or at a step(s) in the intracellular EGF processing pathway between the endosome and the lysosome.     

Toxicity of ligand and antibody-directed ricin A-chain conjugates recognizing the epidermal growth factor receptor

Approximately equal amounts of 125I-mAb 225 (a monoclonal antibody recognizing the human epidermal growth factor receptor) and 125I-labeled epidermal growth factor (125I-EGF) were bound by HeLa cells. However, these two EGF receptor binding moieties had different fates after binding. Sixty percent of cell-associated 125I-EGF was internalized. The majority of internalized 125I was released from the cell within 2 hr. In contrast, whereas only 30% of bound 125I-mAb 225 was internalized by HeLa cells, the internalized radioactivity remained cell-associated. EGF and mAb 225 were used to construct ricin A-chain (RTA) conjugates. The two chimeric molecules, EGF-RTA and mAb 225-RTA, were equally toxic to human HeLa cells. EGF-RTA was also toxic to murine 3T3 cells. In contrast, mAb 225-RTA was not toxic to 3T3 cells, consistent with the human EGF-receptor specificity of mAb 225. Neither conjugate was cytotoxic to EGF receptor-deficient 3T3-NR6 cells. Rapidity and potency of protein synthesis inhibition of HeLa cells were equivalent for the two chimeric conjugates, as was the degree to which colony-forming ability was reduced. However, ammonium chloride enhanced the toxicity of EGF-RTA but not mAb 225-RTA, suggesting that the two toxic chimeric toxins--like the unconjugated receptor-binding moieties--are processed differently by HeLa cells.     

Somatic cell mutants resistant to ricin, diphtheria toxin, and to immunotoxins

The human B-cell line Namalwa expresses the common acute lymphoblastic leukemia antigen (CALLA). Frame-shift mutants in Namalwa cell cultures were generated with ICR-191, and mutants were then selected for resistance to ricin or resistance to a conjugate of ricin with the anti-CALLA antibody J5 in the presence of lactose. Three mutants were found that were resistant to ricin and were in addition shown to be resistant to diphtheria toxin, to a J5-ricin conjugate, and to a conjugate between ricin B-chain and gelonin. The mutants, however, were sensitive to a J5-gelonin conjugate. These mutants expressed high levels of CALLA and/or receptors for ricin, and their cell-free translation systems appeared to be as sensitive to the inhibitory action of ricin A-chain and of gelonin as the translation system of wild-type Namalwa cells. The behavior of these mutants was consistent with the hypothesis that these cells possess an alteration of their surface that impedes the passage of ricin and diphtheria toxin across the plasma membrane. A fourth mutant was found to bind reduced quantities of ricin and was resistant to ricin but was sensitive to J5-ricin. The properties of this cell line provide evidence that the binding of antibody-ricin conjugates to cells via the ricin moiety may be prevented without impeding the cytotoxicity of the conjugates.     

Blockade of the galactose-binding sites of ricin by its linkage to antibody. Specific cytotoxic effects of the conjugates

A method is described for preparing specific cytotoxic agents by linking intact ricin to antibodies in a manner that produces obstruction of the galactose-binding sites on the B chain of the toxin and so diminishes the capacity of the conjugate to bind non-specifically to cells. The conjugates were synthesised by reacting iodoacetylated ricin with thiolated immunoglobulin and the components of conjugate with reduced galactose-binding capacity were separated by affinity chromatography on Sepharose (a beta-galactosyl matrix) and asialofetuin-Sepharose. Fluorescence-activated cell sorter (FACS) analyses revealed that the fraction of a monoclonal anti-Thy1.1-ricin conjugate that passed through a Sepharose column had markedly diminished capacity to bind non-specifically to Thy1.2-expressing CBA thymocytes and EL4 lymphoma cells. The fraction of conjugate that passed through an asialofetuin-Sepharose column displayed no detectable non-specific binding. Both fractions of conjugate were potent cytotoxic agents for Thy1.1-expressing AKR-A lymphoma cells in tissue culture. They reduced the [3H]leucine incorporation of the cells by 50% at a concentration of 2-5 pM. Comparable inhibition of EL4 cells was only achieved with 3000-7500-fold greater concentrations of conjugate. By contrast, the fraction of anti-Thy1.1-ricin that retained Sepharose-binding capacity showed marked non-specific binding and toxicity to EL4 cells. A conjugate with diminished galactose-binding capacity was also prepared from the W3/25 monoclonal antibody which recognises an antigen upon helper T-lymphocytes in the rat. It elicited powerful and specific toxic effects upon W3/25 antigen-expressing rat T-leukaemia cells. This finding is of particular importance because isolated ricin A-chain disulphide-linked to W3/25 antibody is not cytotoxic. The property of the B-chain in intact ricin conjugates that facilitates delivery of the A-chain to the cytosol thus appears to be independent of galactose recognition. It is concluded that the 'blocked' ricin conjugates combine the advantages of high potency, which is often lacking in antibody-A-chain conjugates, with high specificity, which previously was lacking in intact ricin conjugates.     

A comparative study of ricin and diphtheria toxin-antibody-conjugate kinetics on protein synthesis inactivation

Kinetic data on toxin and antibody-toxin-conjugate inactivation of protein synthesis have been used to assess the variables which affect the transport of these toxins into the cytosol compartment. First-order inactivation rate constants of protein synthesis (ki) are compared under conditions of known receptor occupancy. The effect of inclusion of toxin B chains, both homologous and heterologous, in antibody-toxin conjugates is observed, and factors which affect toxin lag periods are studied. The results show that the inclusion of B chains in conjugates increases ki values 3-10-fold, but only if the B chain is homologous with the A chain. In spite of the augmentation of antibody-toxin-conjugate ki values by homologous toxin B chain, these ki values are only 1/20 those observed with unmodified toxins on sensitive cells. A further difference noted between toxins and antibody-toxin conjugates is the presence of a dose-dependent lag when toxins, but not antibody-toxin conjugates, effect sensitive cell types. This lag period for ricin can be shortened by alkalinizing the cell medium. The kinetic data can be fit by assuming a processing step interposed between the binding of ricin to surface receptors and the interaction of the A chain with ribosomes which is first-order in toxin concentration and pH-dependent. The time constant of this event is reflected in the dose-dependent lag period. It is proposed that antibody-toxin conjugates do not participate in this processing event and therefore fail to achieve the high entry levels exhibited by unmodified toxins.     

Cytoskeletal changes in hepatocytes induced by Microcystis toxins and their relation to hyperphosphorylation of cell proteins.

The heptapeptide toxins produced by the blue-green alga (cyanobacterium) Microcystis aeruginosa are selectively hepatotoxic in mammals. The characteristic post-mortem pathology of the liver is extensive lobular disruption due to sinusoidal breakdown, leakage of blood into the tissue and hepatocyte disintegration. Isolated hepatocytes incubated with toxin show severe structural deformity and surface blebbing. This paper demonstrates the effects of Microcystis toxins on the contraction and aggregation of actin microfilaments, and on the relocation and breakdown of cytokeratin intermediate filaments, in cultured hepatocytes. Earlier work did not show changes in the assembly/disassembly of actin; however, this paper demonstrates the change in cytokeratin from intermediate filaments to distributed granules in the cytoplasm of toxin-affected cells. Acrylamide gel electrophoresis of cytoskeletal fractions from hepatocytes did not show changes in total cytokeratins; however, marked changes in the immunogenicity of cytokeratins at 52 and 58 kDa were seen on toxin exposure of cells. Measurement of 32P-phosphorylation of proteins in toxin-affected cells incubated with [32P]orthophosphate showed a dramatic increase compared to control incubations. This is in agreement with research elsewhere describing phosphatase inhibition in vitro by Microcystis toxins. The data indicate that phosphorylated cytokeratin is a major component of cytoplasmic fraction phosphorylated protein after toxin exposure to hepatocytes. It is concluded that the mechanism of Microcystis toxicity to the hepatocyte is through cytoskeletal damage leading to loss of cell morphology, cell to cell adhesion and finally cellular necrosis. The underlying biochemical lesion is likely to be phosphatase inhibition causing hyperphosphorylation of a number of hepatocyte proteins, including those cytokeratins responsible for microfilament orientation and intermediate filament integrity.     

Specific killing of lymphocytes that cause experimental autoimmune myasthenia gravis by ricin toxin-acetylcholine receptor conjugates

Experimental autoimmune myasthenia gravis (EAMG) is an autoimmune disease in which antibodies to acetylcholine receptor (AChR) cause loss of AChR from muscle, thereby impairing neuromuscular transmission. Here we report the use of a hybrid molecule that contains ricin toxin, irreversibly coupled to AChR to specifically suppress the immune response to AChR in vitro. Lymph node cell cultures from rats with EAMG pretreated with ricin toxin-AChR conjugates exhibited suppressed T helper cell proliferation and B cell antibody synthesis in response to the subsequent addition of AChR. Nonspecific toxicity of the conjugates was measured by suppression of the T cell proliferative response to the mitogen concanavalin A and the antigen keyhole limpet hemocyanin (KLH), and B cell antibody production to KLH. We have evaluated different pretreatment conditions and ricin toxin covalently coupled to AChR in different molar ratios to optimize specific immunosuppression. By varying the number of ricin molecules covalently bound to AChR in the immunotoxin, we were able to minimize the nonspecific toxicity while still maintaining specific killing of AChR-reactive lymphocytes. Furthermore, B cells were more susceptible to specific killing than were the T cells. The specific immunosuppression was potentiated by performing the pretreatment with immunotoxin in the presence of chloroquine. Chloroquine raises lysosomal pH and probably delays the degradation of immunotoxin in the cell. It should be noted that ricin toxin was covalently coupled to AChR by using a novel, non-reducible reaction. These in vitro results suggest that it may be feasible to use immunotoxin molecules to specifically suppress this autoimmune response in vivo.     

Endosomes and toxin translocation

In this review we discuss data obtained by our group regarding the entry of toxins, especially ricin, diphtheria toxin (DT) and Pseudomonas exotoxin A (PE) into animal cells. We studied the translocation process of these toxins using endosomes purified from lymphocytes. This process is rate-limiting for toxicity and enables these toxins to reach the cytosol where they will inactivate the protein synthesis system and kill the cell. We could show that each of these toxins uses a different strategy to cross the endosome membrane. Whereas ricin transmembrane transport only relies on cytosolic ATP hydrolysis, PE first requires exposure to the low endosomal pH (pH-6), presumably to insert into the endosome membrane, before being translocated via a process which also requires cytosolic ATP hydrolysis. DT translocation is directly triggered and energized by the endosome-cytosol pH gradient. Using conjugates with dihydrofolate reductase we could indirectly show that ricin and PE require unfolding for translocation. A deletion approach enabled to produce a more cytotoxic PE mutant by increasing its translocation activity.     

Kinetic comparison of ricin immunotoxins: biricin conjugate has potentiated cytotoxicity

The plant toxin ricin was chemically coupled to an anti-Thy-1.1 antibody, and the resultant conjugates were fractionated by gel filtration. The cytotoxicity of the conjugate possessing two ricin molecules per immunoglobulin, yielding a first-order inactivation rate of protein synthesis of -0.4 log/h at 200 ng/mL, was well above that expected just from the increase in ricin per unit mass of conjugate, when compared to a conjugate possessing only one ricin per immunoglobulin. On a conjugate molar scale the biricin immunotoxin was determined to be 8 times more potent than the monoricin conjugate; thus, relative to the number of ricin molecules, the coupling of a second ricin to the immunoglobulin quadrupled the observed potency. The concentration of immunotoxin and the resultant inactivation rates of protein synthesis were found to be related through a power function. Additionally, the inactivation kinetics of these conjugates were found to be similar to those of native ricin.     

Comparative study of toxicological and cell cycle effects of okadaic acid and dinophysistoxin-2 in primary rat hepatocytes

AimsTo determine the relative toxicity and effects on the cell cycle of okadaic acid and dinophysistoxin-2 in primary hepatocyte cultures.Main methodsCytotoxicity was determined by the MTT method, caspase-3 activity and lactate dehydrogenase release to the medium. The cell cycle analysis was performed by imaging flow cytometry and the effect of the toxins on cell proliferation was studied by quantitative PCR and confocal microscopy.Key findingsWe show that dinophysistoxin-2 is less toxic than okadaic acid for primary hepatocytes with a similar difference in potency as that observed in vivo in mice after intraperitoneal injection. Both toxins induced apoptosis with caspase-3 increase. They also inhibited the hepatocytes cell cycle in G1 affecting diploid cells and diploid bi-nucleated cells. In proliferating hepatocytes exposed to the toxins, a decrease of p53 gene expression as well as a lower protein level was detected. Studies of the tubulin cytoskeleton in toxin treated cells, showed nuclear localization of this molecule and a granulated tubulin pattern in the cytoplasm.SignificanceThe results presented in this work show that the difference in toxicity between dinophysistoxin-2 and okadaic acid in cultured primary hepatocytes is the same as that observed in vivo after intraperitoneal injection. Okadaic acid and dinophysistoxin-2 arrest the cell cycle of hepatocytes at G1 even in diploid bi-nucleated cells. p53 and tubulin could be involved in the cell cycle inhibitory effect.     

Functional expression of the human transferrin receptor cDNA in Chinese hamster ovary cells deficient in endogenous transferrin receptor

Transferrin (Tf) receptor-variant Chinese hamster ovary cells have been isolated by selection for resistance to two Tf-toxin conjugates. The hybrid toxins contain Tf covalently linked to ricin A chain or a genetically engineered diphtheria toxin fragment. The Tf-receptor-variant (TRV) cells do not have detectable cell-surface Tf receptor; they do not bind fluorescein-Tf or 125I-Tf. TRV cells are at least 100-fold more resistant to the Tf-diphtheria toxin conjugate than are the parent cells. The TRV cells have retained sensitivity to native diphtheria toxin, indicating that the increased resistance to the conjugate is correlated with the loss of Tf binding. The endocytosis of fluorescein-labeled alpha 2-macroglobulin is normal in TRV cells, demonstrating that the defect does not pleiotropically affect endocytosis. Since these cells lack endogenous Tf receptor activity, they are ideally suited for studies of the functional expression of normal or altered Tf receptors introduced into the cells by cDNA transfection. One advantage of this system is that Tf binding and uptake can be used to monitor the behavior of the transfected receptor. A cDNA clone of the human Tf receptor has been transfected into TRV cells. In the stably expressing transfectants, the behavior of the human receptor is very similar to that of the endogenous Chinese hamster ovary cell Tf receptor. Tf binds to cell surface receptors, and is internalized into the para-Golgi region of the cell. Iron is released from Tf, and the apo-Tf and its receptor are recycled back to the cell surface. Thus, the TRV cells can be used to study the behavior of genetically altered Tf receptors in the absence of interfering effects from endogenous receptors.     

Prevention of toxin-induced cytoskeletal disruption and apoptotic liver cell death by the grapefruit flavonoid, naringin

The protein phosphatase-inhibitory algal toxins, okadaic acid and microcystin-LR, induced overphosphorylation of keratin and disruption of the keratin cytoskeleton in freshly isolated rat hepatocytes. In hepatocyte cultures, the toxins elicited DNA fragmentation and apoptotic cell death within 24 h. All these toxin effects could be prevented by the grapefruit flavonoid, naringin. The cytoprotective effect of naringin was apparently limited to normal hepatocytes, since the toxin-induced apoptosis of hepatoma cells, rat or human, was not prevented by the flavonoid.     

Targeted inhibition of transferrin-mediated iron uptake in Hep G2 hepatoma cells

We have used a model system consisting of two human hepatoma cell lines, Hep G2, representing well differentiated normal hepatocytes, and PLC/PRF/5, representing poorly differentiated malignant hepatocytes, to demonstrate that the differential presence of asialoglycoprotein receptor activity in these cell lines can be used to influence transferrin-mediated iron uptake. We based our experiments on the following facts: Hep G2 cells possess receptors that bind, internalize, and degrade galactose-terminal (asialo-)glycoproteins; PLC/PRF/5 cells have barely detectable asialoglycoprotein receptor activity; both cell lines possess active transferrin-mediated iron uptake; transferrin releases iron during acidification of intracellular vesicular compartments; primary amines, e.g. primaquine, inhibit acidification and iron release from transferrin. When added to culture medium, [55Fe]transferrin delivered 55Fe well to both cell lines. As expected, in the presence of [55Fe]transferrin, free primaquine caused a concentration-dependent decrease in 55Fe uptake in both cell lines. To create a targetable conjugate, primaquine was covalently coupled to asialofetuin to form asialofetuin-primaquine. When PLC/PRF/5 (asialoglycoprotein receptor (-)) cells were preincubated with this conjugate, transferrin-mediated 55Fe uptake was unaffected. However, transferrin-mediated 55Fe uptake by Hep G2 (asialoglycoprotein receptor (+)) cells under identical conditions was specifically decreased by 55% compared to control cells incubated without the conjugate.     

Epidermal growth factor labeled beta-amanitin-poly-L-ornithine: preparation and evidence for specific cytotoxicity

Poly-L-ornithine with an average molecular weight of 32K was reacted with beta-amanitin hydroxysuccinimide ester to form an amide-linked toxin conjugate. Loading of the polymeric chain with amanitin was high, corresponding to up to 35% of the total weight. To this amatoxin vehicle we attached a targeting molecule, human recombinant leucine-21 epidermal growth factor (hrEGFL), via a disulfide-containing linker moiety. A typical average stoichiometry of the hrEGFL labeled toxin conjugate was (L-Orn)164(beta-amanitin)19(COC2H4SSC2H4CO-hrEGFL)2. The affinity for EGF receptors of hrEGFL bound in this conjugate was tested by using A 431 cells. The affinity was eight times lower than that of unsubstituted hrEGFL but regarded as high enough for studying specific toxicity effects with cells bearing EGF receptors. We found that beta-amanitin in the labeled conjugate was able to inhibit the growth of A 431 cells at a concentration of 28 nM, 80 times lower than for native beta-amanitin and 20 times lower than for poly-L-ornithine-bound beta-amanitin without the hrEGFL label. The approximately 20-fold enhancement of cytotoxicity suggests a specific internalization of the toxin conjugate mediated by the hormone label. This idea is supported by the fact that also in another transformed fibroblast cell line, with an increased though smaller number of EGF receptors than A 431 cells, the corresponding enhancement of cytotoxicity was demonstrable but less pronounced (7-fold). The hormone-mediated increase in cytotoxicity of EGF labeled poly-L-ornithine-beta-amanitin conjugates, combined with their moderate toxicity in the mouse, encourages further examination of such compounds in tumor model systems in vivo.(ABSTRACT TRUNCATED AT 250 WORDS)     

Saporin and ricin A chain follow different intracellular routes to enter the cytosol of intoxicated cells

Several protein toxins, such as the potent plant toxin ricin, enter mammalian cells by endocytosis and undergo retrograde transport via the Golgi complex to reach the endoplasmic reticulum (ER). In this compartment the catalytic moieties exploit the ER-associated degradation (ERAD) pathway to reach their cytosolic targets. Bacterial toxins such as cholera toxin or Pseudomonas exotoxin A carry KDEL or KDEL-like C-terminal tetrapeptides for efficient delivery to the ER. Chimeric toxins containing monomeric plant ribosome-inactivating proteins linked to various targeting moieties are highly cytotoxic, but it remains unclear how these molecules travel within the target cell to reach cytosolic ribosomes. We investigated the intracellular pathways of saporin, a monomeric plant ribosome-inactivating protein that can enter cells by receptor-mediated endocytosis. Saporin toxicity was not affected by treatment with Brefeldin A or chloroquine, indicating that this toxin follows a Golgi-independent pathway to the cytosol and does not require a low pH for membrane translocation. In intoxicated Vero or HeLa cells, ricin but not saporin could be clearly visualized in the Golgi complex using immunofluorescence. The saporin signal was not evident in the Golgi, but was found to partially overlap with that of a late endosome/lysosome marker. Consistently, the toxicities of saporin or saporin-based targeted chimeric polypeptides were not enhanced by the addition of ER retrieval sequences. Thus, the intracellular movement of saporin differs from that followed by ricin and other protein toxins that rely on Golgi-mediated retrograde transport to reach their retrotranslocation site.     

Detection of glycosylated and deglycosylated extensin precursors by indirect competitive ELISA

As part of their defense mechanism against herbivores or phytophagous insects, many plant tissues contain lectins. Some of these lectins are potent toxins which kill animal cells by arresting protein synthesis. An attractive strategy for developing specifically cytotoxic chemotherapeutic agents is to link cell type-specific monoclonal antibodies to potent toxins. The plant protein ricin has emerged as the toxin of choice for such constructs.     

A novel G418 conjugate results in targeted selection of genetically protected hepatocytes without bystander toxicity

G418, an aminoglycoside neomycin analogue, is an antimicrobial agent that interferes with protein synthesis and has been used extensively for selection of mammalian cell lines that possess neomycin resistance (NR). It is potent and nonspecific in its effects that occur through tight binding to ribosomal elements. Because of the potent intracellular effect, we wondered whether G418 could be used to select a specific cell type based on receptor-mediated endocytosis. The objective of this study was to target G418 specifically to liver cells via asialoglycoprotein receptors (AsGR) which are known to be highly selective for these cells. A novel G418 conjugate was synthesized chemically by coupling G418 to a galactose-terminating carrier protein, asialoorosomucoid (AsOR), in a molar ratio of 5:1. AsOR-G418 conjugates inhibited viability of AsGR (+) cells by 84.3%, while inhibition in AsGR (-) cells was only by 19%. In AsGR (+) cells, stably transfected with a NR gene, the conjugate decreased viability by less than 9%. Furthermore, incubation of conjugate in cocultures of AsGR (+), and AsGR (-) cells did not result in the loss of viability of neighboring AsGR (-) cells. Our data demonstrate for the first time that G418 can be covalently bound to AsOR to form a conjugate for hepatocyte-specific targeting and toxicity. AsOR-G418 conjugates may be useful tools for genetic manipulation of human liver cells in the presence of nonhepatic cells.