Receptor-mediated endocytosis of a ricin-colloidal gold conjugate in vero cells. Intracellular routing to vacuolar and tubulo-vesicular portions of the endosomal system

Medical Countermeasures against Ricin Intoxication

Ricin toxin is a disulfide-linked glycoprotein (AB toxin) comprising one enzymatic A chain (RTA) and one cell-binding B chain (RTB) contained in the castor bean, a Ricinus species. Ricin inhibits peptide chain elongation via disruption of the binding between elongation factors and ribosomes, resulting in apoptosis, inflammation, oxidative stress, and DNA damage, in addition to the classically known rRNA damage. Ricin has been used in traditional medicine throughout the world since prehistoric times. Because ricin toxin is highly toxic and can be readily extracted from beans, it could be used as a bioweapon (CDC B-list). Due to its extreme lethality and potential use as a biological weapon, ricin toxin remains a global public health concern requiring specific countermeasures. Currently, no specific treatment for ricin intoxication is available. This review focuses on the drugs under development. In particular, some examples are reviewed to demonstrate the proof of concept of antibody-based therapy. Chemical inhibitors, small proteins, and vaccines can serve as alternatives to antibodies or may be used in combination with antibodies.

Intracellular Transport and Cytotoxicity of the Protein Toxin Ricin

Ricin can be isolated from the seeds of the castor bean plant (Ricinus communis). It belongs to the ribosome-inactivating protein (RIP) family of toxins classified as a bio-threat agent due to its high toxicity, stability and availability. Ricin is a typical A-B toxin consisting of a single enzymatic A subunit (RTA) and a binding B subunit (RTB) joined by a single disulfide bond. RTA possesses an RNA N-glycosidase activity; it cleaves ribosomal RNA leading to the inhibition of protein synthesis. However, the mechanism of ricin-mediated cell death is quite complex, as a growing number of studies demonstrate that the inhibition of protein synthesis is not always correlated with long term ricin toxicity. To exert its cytotoxic effect, ricin A-chain has to be transported to the cytosol of the host cell. This translocation is preceded by endocytic uptake of the toxin and retrograde traffic through the trans-Golgi network (TGN) and the endoplasmic reticulum (ER). In this article, we describe intracellular trafficking of ricin with particular emphasis on host cell factors that facilitate this transport and contribute to ricin cytotoxicity in mammalian and yeast cells. The current understanding of the mechanisms of ricin-mediated cell death is discussed as well. We also comment on recent reports presenting medical applications for ricin and progress associated with the development of vaccines against this toxin.

Ricin: An Ancient Story for a Timeless Plant Toxin

The castor plant (Ricinus communis L.) has been known since time immemorial in traditional medicine in the pharmacopeia of Mediterranean and eastern ancient cultures. Moreover, it is still used in folk medicine worldwide. Castor bean has been mainly recommended as anti-inflammatory, anthelmintic, anti-bacterial, laxative, abortifacient, for wounds, ulcers, and many other indications. Many cases of human intoxication occurred accidentally or voluntarily with the ingestion of castor seeds or derivatives. Ricinus toxicity depends on several molecules, among them the most important is ricin, a protein belonging to the family of ribosome-inactivating proteins. Ricin is the most studied of this category of proteins and it is also known to the general public, having been used for several biocrimes. This manuscript intends to give the reader an overview of ricin, focusing on the historical path to the current knowledge on this protein. The main steps of ricin research are here reported, with particular regard to its enzymatic activity, structure, and cytotoxicity. Moreover, we discuss ricin toxicity for animals and humans, as well as the relation between bioterrorism and ricin and its impact on environmental toxicity. Ricin has also been used to develop immunotoxins for the elimination of unwanted cells, mainly cancer cells; some of these immunoconjugates gave promising results in clinical trials but also showed critical limitation.

Antibody to ricin a chain hinders intracellular routing of toxin and protects cells even after toxin has been internalized

Background

Mechanisms of antibody-mediated neutralization are of much interest. For plant and bacterial A-B toxins, A chain mediates toxicity and B chain binds target cells. It is generally accepted and taught that antibody (Ab) neutralizes by preventing toxin binding to cells. Yet for some toxins, ricin included, anti-A chain Abs afford greater protection than anti-B. The mechanism(s) whereby Abs to the A chain neutralize toxins are not understood.

Methodology/Principal Findings

We use quantitative confocal imaging, neutralization assays, and other techniques to study how anti-A chain Abs function to protect cells. Without Ab, ricin enters cells and penetrates to the endoplasmic reticulum within 15 min. Within 45–60 min, ricin entering and being expelled from cells reaches equilibrium. These results are consistent with previous observations, and support the validity of our novel methodology. The addition of neutralizing Ab causes ricin accumulation at the cell surface, delays internalization, and postpones retrograde transport of ricin. Ab binds ricin for >6hr as they traffic together through the cell. Ab protects cells even when administered hours after exposure.

Conclusions/Key Findings

We demonstrate the dynamic nature of the interaction between the host cell and toxin, and how Ab can alter the balance in favor of the cell. Ab blocks ricin’s entry into cells, hinders its intracellular routing, and can protect even after ricin is present in the target organelle, providing evidence that the major site of neutralization is intracellular. These data add toxins to the list of pathogenic agents that can be neutralized intracellularly and explain the in vivo efficacy of delayed administration of anti-toxin Abs. The results encourage the use of post-exposure passive Ab therapy, and show the importance of the A chain as a target of Abs.

Uptake of ricinB-quantum dot nanoparticles by a macropinocytosis-like mechanism

Background

There is a huge effort in developing ligand-mediated targeting of nanoparticles to diseased cells and tissue. The plant toxin ricin has been shown to enter cells by utilizing both dynamin-dependent and -independent endocytic pathways. Thus, it is a representative ligand for addressing the important issue of whether even a relatively small ligand-nanoparticle conjugate can gain access to the same endocytic pathways as the free ligand.

Results

Here we present a systematic study concerning the internalization mechanism of ricinB:Quantum dot (QD) nanoparticle conjugates in HeLa cells. Contrary to uptake of ricin itself, we found that internalization of ricinB:QDs was inhibited in HeLa cells expressing dominant-negative dynamin. Both clathrin-, Rho-dependent uptake as well as a specific form of macropinocytosis involve dynamin. However, the ricinB:QD uptake was not affected by siRNA-mediated knockdown of clathrin or inhibition of Rho-dependent uptake caused by treating cells with the Clostridium C3 transferase. RicinB:QD uptake was significantly reduced by cholesterol depletion with methyl-β-cyclodextrin and by inhibitors of actin polymerization such as cytochalasin D. Finally, we found that uptake of ricinB:QDs was blocked by the amiloride analog EIPA, an inhibitor of macropinocytosis. Upon entry, the ricinB:QDs co-localized with dextran, a marker for fluid-phase uptake. Thus, internalization of ricinB:QDs in HeLa cells critically relies on a dynamin-dependent macropinocytosis-like mechanism.

Conclusions

Our results demonstrate that internalization of a ligand-nanoparticle conjugate can be dependent on other endocytic mechanisms than those used by the free ligand, highlighting the challenges of using ligand-mediated targeting of nanoparticles-based drug delivery vehicles to cells of diseased tissues.

Enhanced killing of human epidermoid carcinoma (KB) cells by treatment with ricin encapsulated into sterically stabilized liposomes in combination with monensin

Ricin was encapsulated in various charged liposomes having 5 mol% PEG of different chain length on the surface. The cytotoxicity of ricin entrapped in these liposomal formulations was examined in human epidermoid carcinoma (KB) cells with a view to develop an optimum delivery system for ricin in vivo. It was observed that the cytotoxicity of ricin entrapped in various charged liposomes was significantly dependent on the surface charge as well as chain length of PEG. The maximum cytotoxicity of ricin was observed when it was delivered through negatively charged liposomes having 5 mol% PEG-2000 on the surface. Monensin enhances the cytotoxicity of ricin entrapped in various charged liposomes depending on the surface charge. Maximum potentiation of cytotoxicity of ricin was observed when it was delivered through negatively charged liposomes having 5 mol% PEG-2000 on the surface. Studies on the kinetics of inhibition of protein synthesis by ricin revealed that the lag period of inhibition of protein synthesis is significantly lengthened following its delivery through various charged liposomes. Monensin significantly reduced the lag period of action of ricin. It was also observed that the efficacies of monensin on the enhancement of cytotoxicity of ricin entrapped in various charged PEG-liposomes were highly related to their amount of cell association. The current study has demonstrated that by suitable adjustment of charge, density, and chain length of PEG on the surface of liposomes it would be possible to direct liposomal ricin to human tumor cells for their selective elimination in combination with monensin.

Cytotoxic ribosome-inactivating lectins from plants

A class of heterodimeric plant proteins consisting of a carbohydrate-binding B-chain and an enzymatic A-chain which act on ribosomes to inhibit protein synthesis are amongst the most toxic substances known. The best known example of such a toxic lectin is ricin, produced by the seeds of the castor oil plant, Ricinnus communis. For ricin to reach its substrate in the cytosol, it must be endocytosed, transported through the endomembrane system to reach the compartment from which it is translocated into the cytosol, and there avoid degradation making it possible for a few molecules to inactivate a large proportion of the ribosomes and hence kill the cell. Cell entry by ricin involves the following steps: (i) binding to cell-surface glycolipids and glycoproteins bearing beta-1,4-linked galactose residues through the lectin activity of the B-chain (RTB); (ii) uptake by endocytosis and entry into early endosomes; (iii) transfer by vesicular transport to the trans-Golgi network; (iv) retrograde vesicular transport through the Golgi complex and into the endoplasmic reticulum (ER); (v) reduction of the disulfide bond connecting the A- and B-chains; (vi) a partial unfolding of the A-chain (RTA) to enable it to translocate across the ER membrane via the Sec61p translocon using the pathway normally followed by misfolded ER proteins for targeting to the ER-associated degradation (ERAD) machinery; (vi) refolding in the cytosol into a protease-resistant, enzymatically active structure; (vii) interaction with the sarcin-ricin domain (SRD) of the large ribosome subunit RNA followed by cleavage of a single N-glycosidic bond in the RNA to generate a depurinated, inactive ribosome. In addition to the highly specific action on ribosomes, ricin and related ribosome-inactivating proteins (RIPs) have a less specific action in vitro on DNA and RNA substrates releasing multiple adenine, and in some instances, guanine residues. This polynucleotide:adenosine glycosidase activity has been implicated in the general antiviral, and specifically, the anti HIV-1 activity of several single-chain RIPs which are homologous to the A-chains of the heterodimeric lectins. However, in the absence of clear cause and effect evidence in vivo, such claims should be regarded with caution.

Are caveolae involved in clathrin-independent endocytosis?

In addition to endocytosing molecules via clathrin-coated pits, cells also internalize membrane and fluid by a clathrin-independent endocytic mechanism. In this article we search for the equivalent of clathrin-coated pits in clathrin-independent endocytosis, and discuss some pitfalls in the interpretation of electron micrographs. We also discuss how the early steps in clathrin-independent endocytosis might be analysed morphologically, and we argue that caveolae are not involved in clathrin-independent endocytosis.

Ricin

Ricin is a heterodimeric protein produced in the seeds of the castor oil plant (Ricinus communis). It is exquisitely potent to mammalian cells, being able to fatally disrupt protein synthesis by attacking the Achilles heel of the ribosome. For this enzyme to reach its substrate, it must not only negotiate the endomembrane system but it must also cross an internal membrane and avoid complete degradation without compromising its activity in any way. Cell entry by ricin involves a series of steps: (i) binding, via the ricin B chain (RTB), to a range of cell surface glycolipids or glycoproteins having beta-1,4-linked galactose residues; (ii) uptake into the cell by endocytosis; (iii) entry of the toxin into early endosomes; (iv) transfer, by vesicular transport, of ricin from early endosomes to the trans-Golgi network; (v) retrograde vesicular transport through the Golgi complex to reach the endoplasmic reticulum; (vi) reduction of the disulphide bond connecting the ricin A chain (RTA) and the RTB; (vii) partial unfolding of the RTA to render it translocationally-competent to cross the endoplasmic reticulum (ER) membrane via the Sec61p translocon in a manner similar to that followed by misfolded ER proteins that, once recognised, are targeted to the ER-associated protein degradation (ERAD) machinery; (viii) avoiding, at least in part, ubiquitination that would lead to rapid degradation by cytosolic proteasomes immediately after membrane translocation when it is still partially unfolded; (ix) refolding into its protease-resistant, biologically active conformation; and (x) interaction with the ribosome to catalyse the depurination reaction. It is clear that ricin can take advantage of many target cell molecules, pathways and processes. It has been reported that a single molecule of ricin reaching the cytosol can kill that cell as a consequence of protein synthesis inhibition. The ready availability of ricin, coupled to its extreme potency when administered intravenously or if inhaled, has identified this protein toxin as a potential biological warfare agent. Therapeutically, its cytotoxicity has encouraged the use of ricin in 'magic bullets' to specifically target and destroy cancer cells, and the unusual intracellular trafficking properties of ricin potentially permit its development as a vaccine vector. Combining our understanding of the ricin structure with ways to cripple its unwanted properties (its enzymatic activity and promotion of vascular leak whilst retaining protein stability and important immunodominant epitopes), will also be crucial in the development of a long awaited protective vaccine against this toxin.

An interaction between ricin and calreticulin that may have implications for toxin trafficking

Here we demonstrate that ricin is able to interact with the molecular chaperone calreticulin both in vitro and in vivo. The interaction occurred with ricin holotoxin, but not with free ricin A chain; and it was prevented in the presence of lactose, suggesting that it was mediated by the lectin activity of the ricin B chain. This lectin is galactose-specific, and metabolic labeling with [(3)H]galactose or treating galactose oxidase-modified calreticulin with sodium [(3)H]borohydride indicated that Vero cell calreticulin possesses a terminally galactosylated oligosaccharide. Brefeldin A treatment indicated that the intracellular interaction occurred initially in a post-Golgi stack compartment, possibly the trans-Golgi network, whereas the reductive separation of ricin subunits occurred in an earlier part of the secretory pathway, most probably the endoplasmic reticulum (ER). Intoxicating Vero cells with ricin whose A chain had been modified to include either a tyrosine sulfation site or the sulfation site plus available N-glycosylation sites, in the presence of Na(2)35SO(4), confirmed that calreticulin interacted with endocytosed ricin that had already undergone retrograde transport to both the Golgi and the ER. Although we cannot exclude the possibility that the interaction between ricin and calreticulin is an indirect one, the data presented are consistent with the idea that calreticulin may function as a recycling carrier for retrograde transport of ricin from the Golgi to the ER.

Effects of suicide transport lesions of the striatopallidal or striatonigral pathways on striatal ultrastructure

In the basal ganglia, centrally active suicide transport agents produce selective lesions of the striatopallidal and striatonigral pathways based on receptor binding and neuropeptide mRNA studies. Anatomical analyses indicate a selective, albeit modest, loss of projection neurons. In the present study, we sought to determine the ultrastructural sequelae in the striatum of suicide transport injections of the globus pallidus (GP) or substantia nigra (SN). Neostriata of adult rats were examined 10 days after lesions of the striatopallidal or striatonigral pathways with OX7-saporin or volkensin. Controls consisted of normal unoperated rats and animals injected into either target with ricin, a toxic lectin that is not transported in the central nervous system. Injections with OX7-saporin or volkensin into the GP or SN produced a decrease in striatal synaptic density of approximately 20%, relative to the contralateral side. Dark degenerating profiles, though very rare in the contralateral striata, were present throughout the neuropil in the ipsilateral striata. In animals with striatopallidal lesions, axospinous synapses of both the asymmetric and symmetric type were decreased in density, while the number of synapses formed with dendritic shafts was unaffected. In addition, the number of striatal mitochondrial profiles was decreased ipsilateral to the lesions. In animals with striatonigral lesions, the number of axospinous and axodendritic synapses of the asymmetric type was decreased ipsilateral to the lesions. Synaptic density and ultrastructural integrity remained unaffected in the striata of animals receiving ricin injections and in the contralateral striata of animals receiving OX7-saporin or volkensin injections. Our results, taken together with previous studies showing marked loss of receptors, uptake sites and mRNA, suggest that while most synapses are present and intact, the efficacy of synaptic transmission may be altered.

Affinity labeling of recombinant ricin A chain with Procion blue MX-R

Recombinant ricin A chain was irreversibly modified by Procion blue MX-R, a dichlorotriazinyl analogue of Cibacron blue F3G-A, at pH 7.5 and 4 degrees C in 90 h with over 95% loss of activity in an in vitro translation assay. The presence of total yeast RNA reduced the covalent attachment of Procion blue MX-R to ricin A chain. Quantitatively modified ricin A chain contained 2 mol Procion blue MX-R/mol 29-kDa subunit. Tryptic digestion and resolution of the peptides by reverse-phase high-performance liquid chromatography yields a blue peptide corresponding to Gln5-Arg26 of ricin A chain. Thus, a likely dye-binding site on recombinant ricin A was identified. This region is removed from the active-site cleft of recombinant ricin A but may be involved in its substrate binding.

In vivo and in vitro uptake of an anti-CD30/saporin immunotoxin by rat liver parenchymal and nonparenchymal cells

A Ber-H2/saporin immunotoxin, consisting of the single-chain ribosome-inactivating protein saporin-S6 and the anti-CD30 monoclonal antibody Ber-H2, gave encouraging results in the treatment of refractory Hodgkin's disease but caused a transient hepatotoxicity. The accumulation of Ber-H2/saporin conjugate and of its components by rat liver parenchymal and nonparenchymal cells was studied. The in vivo concentration of intravenously injected Ber-H2/saporin, saporin or Ber-H2 in nonparenchymal cells was 4-, 25- and 11-fold higher, respectively, than that in parenchymal cells. Adherent in vitro cultured nonparenchymal cells, mostly Kupffer cells, accumulated the proteins approximately 10 times more than parenchymal cells; traces of free saporin were taken up by both types of cells. In vitro protein synthesis by both cell types was inhibited by 50% at nanomolar concentrations of saporin. Nonparenchymal cells were sensitive to Ber-H2/saporin at picomolar concentrations, whereas parenchymal cells were unaffected by the immunotoxin up to 100 pmol/L. The results of the uptake of, and the sensitivity to, the immunotoxin suggest that the sensitivity of liver cells is proportional to the uptake and that the in vivo damage to parenchymal cells is at least in part mediated by the toxicity to nonparenchymal liver cells.

Ultrastructural alterations induced in quail ciliary neurons by postganglionic nerve crush and by Ricinus toxin administration, separately and in combination

The response to postganglionic nerve crush and Ricinus toxin administration by the ciliary neurons of the quail ciliary ganglion was investigated at the ultrastructural level. The toxin was either applied at the crush site on the postganglionic nerves or injected into the anterior eye chamber without any other operative intervention. Crush of postganglionic nerves without toxin administration and saline injection into the anterior eye chamber served as controls for the two toxin administration procedures. Postganglionic nerve crush caused a distinct chromatolytic reaction, accompanied by massive detachment of the preganglionic axon terminals from the ciliary neurons and loss of most of the synapses, both chemical and electrical. This process does not induce cell death and is reversible. Saline injection in the anterior eye chamber caused a moderate retrograde reaction in some of the ciliary neurons, presumably as a consequence of paracentesis. The changes consisted mainly of an increase of perikaryal neurofilaments with, at most, a minor detachment of the preganglionic boutons from a small portion of the cell body at the nuclear pole. Ricinus toxin administration induced neuronal degeneration following a pattern common to both delivery modes. The degenerative process consisted of disruption and detachment of polyribosomes from the rough endoplasmic reticulum, an increase of smooth cisterns and tubules, a dramatic increase of neurofilament bundles, compartmentalization of the cytoplasmic organelles and, finally, karyorrhexis and cell lysis. The final stages of Ricinus toxin degeneration involve a progressive accumulation of extracellular flocculo-filamentous material and cell lysis. After administration of Ricinus toxin to the crush site, ricin-affected neurons showed withdrawal of the preganglionic boutons from a portion of the ciliary neuron, especially at the nuclear pole. After Ricinus toxin injection into the anterior eye chamber, however, the bouton shell surrounding the affected ciliary neurons remained intact in the early stages of degeneration. Detachment of the preganglionic terminals and disruption of the cell junctions, therefore, is the consequence of nerve crush and not of the toxin itself. This study demonstrated that quail ciliary neurons are a suitable model for experimental neuropathology and neurotoxicology.

Intracellular dynamics of ricin followed by fluorescence microscopy on living cells reveals a rapid accumulation of the dimeric toxin in the Golgi apparatus

The intracellular dynamics of fluorescent conjugates of the toxic lectin ricin was followed by video fluorescence microscopy on living CHO cells, demonstrating that the ricin heterodimer and its isolated B chain, after binding to the plasma membrane receptors, migrate to and accumulate in the Golgi apparatus following internalization. A ricin derivative labelled with fluorescein on the A chain and rhodamine on the B chain did not display significant splitting of the A-B heterodimer during translocation of the toxin to the Golgi; this novel finding provides support for the hypothesis that further processing of ricin takes place in this cellular compartment.

Effects of brefeldin A on endocytosis, transcytosis and transport to the Golgi complex in polarized MDCK cells

We have studied the effects of brefeldin A (BFA) on endocytosis and intracellular traffic in polarized MDCK cells by using the galactose-binding protein toxin ricin as a membrane marker and HRP as a marker of fluid phase transport. We found that BFA treatment rapidly increased apical endocytosis of both ricin and HRP, whereas basolateral endocytosis was unaffected, as was endocytosis of HRP in the poorly polarized carcinoma cell lines HEp-2 and T47D. Tubular endosomes were induced by BFA both apically and basolaterally in some MDCK cells, comparable with those seen in HEp-2 and T47D cells. In addition, in MDCK cells, BFA induced formation of small (< 300 nm) vesicles, labeled both after apical and basolateral uptake of HRP, as well as some very large (> 700 nm) vacuoles, which were only labeled when HRP was present in the apical medium. In contrast, neither in MDCK nor in HEp-2 or T47D cells, did BFA have any effect on lysosomal morphology. Moreover, transcytosis in the basolateral-apical direction was stimulated both for HRP and ricin. Other vesicular transport routes were less affected or unaffected by BFA treatment. Two closely related structural analogues of BFA (B16 and B21), unable to produce the changes in Golgi and endosomal morphology seen after BFA treatment in a number of different cell lines, were also unable to mimic the effects of BFA on MDCK cells.

Neural lesioning with ribosome-inactivating proteins: suicide transport and immunolesioning

Toxic lectins, plant proteins that inactivate ribosomes, irreversibly inhibit protein synthesis with high efficiency. After intraneural (subepineurial) microinjection, these agents are taken up by axons and are retrogradely transported to the perikarya, where they result in cell death. These 'suicide transport' toxins can produce pathway-specific lesions that are useful in several types of experiment, including cellular localization of neurotransmitter receptors. The toxins can be coupled to monoclonal antibodies to produce immunotoxins: reagents that can make highly selective lesions of specific types of neurons. Central or peripheral neurons that express the low-affinity NGF receptor are selectively destroyed by the immunotoxin 192 IgG-saporin. Development of other anti-neuronal immunotoxins should provide a variety of powerful selective lesioning tools.

Toxin-induced cell lysis: protection by 3-methyladenine and cycloheximide

The protein toxins ricin, abrin, Shiga toxin, and diphtheria toxin were found to induce lysis of several cell lines in a manner characteristic for programmed cell death or apoptosis. The toxins induced DNA degradation, and light and electron microscopical studies revealed that lysis was preceded by reorganization of intracellular vacuoles, cell blebbing, and chromatin condensation both in Vero and in MDCK cells. Cell lysis was efficiently inhibited by cycloheximide and 3-methyladenine (3MA), a specific inhibitor of autophagy. Cycloheximide, which like 3MA inhibits autophagy, protected even when added at a time when the protein synthesis had been blocked by ricin, suggesting that the effect of cycloheximide on cell lysis is independent of its ability to inhibit protein synthesis. Also theophylline and dibutyryl-cGMP had some protective effect, whereas a number of compounds reported to protect against apoptosis in other systems were without protective effects. The data suggest that autophagy is important for the toxin-induced cell lysis.

Uptake of injected 125I-ricin by rat liver in vivo. Subcellular distribution and characterization of the internalized ligand

Subcellular-fractionation techniques were used to characterize the endocytic pathway followed by ricin in rat liver in vivo and tentatively identify the site(s) at which the ricin interchain disulphide bridge is split. After injection of 125I-ricin, hepatic uptake of radioactivity was maximum at 30 min (40% of injected dose). At 5 min, about 80% of the radioactivity in the homogenate was recovered in the microsomal (P) fraction, but later on the recovery of the radioactivity in the mitochondrial-lysosomal (ML) fractions progressively increased (50% at 30 min) at the expense of that in the P fraction. Subfractionation of the P and ML fractions on analytical sucrose-density gradients revealed a time-dependent translocation of the radioactivity from low- to high-density endocytic structures, with median relative densities at 5 and 60 min of about 1.15 and 1.16 (P fraction) and 1.19 and 1.22 (ML fraction) respectively. The late distribution of the radioactivity in the ML fraction was similar to that of the lysosomal marker acid phosphatase. Studies with co-injected lactose and mannan showed that ricin was internalized mainly via the mannose receptor. In the presence of mannan, the late recovery of radioactivity in the ML fraction was decreased, and the distribution of the radioactivity associated with the P fraction was shifted toward lower densities (median relative density 1.13), indicating a different pathway of endocytosis. Analysis of the radioactivity associated with the ML and S fractions by SDS/PAGE revealed a time-dependent increase in the amount of intact A- and B-chains and low-molecular-mass products. When ML fractions containing partially processed ricin were incubated at 37 degrees C at pH 5 or at pH 7.2 in the presence of ATP, only low-molecular-mass products were generated. We conclude that internalized ricin associates with endocytic structures whose size and density of equilibration increase with time, and that, although detectable in these structures, reduction of the ricin interchain disulphide bridge occurs to a large extent in the cytosol.

Comparative studies on internalization of gold labelled mistletoe lectin I (MLI), its subunits, and of an immunotoxin into mouse L 1210V leukemia cells

Using a preembedding electron microscopic technique, the binding and internalization of gold labelled mistletoe lectin I (MLI.Au), its 2 A subunits (MLI-A.Au) and of the B subunit (MLI-B.Au) in murine L 1210V leukemia cells was analysed. Furthermore, the endocytosis of a gold marked immunotoxin (MoAb-16-MLI-A.Au), consisting of a monoclonal antibody (MoAb-16) reacting with L 1210V cells and the cytotoxic A subunits (MLI-A) was detected. The cells were incubated with MLI.Au, MLI-A.Au, MLI-B.Au, or MoAb-16-MLI-A.Au at 37 degrees C for 1, 3, 5, 10, 20 or 30 min, respectively. Remarkable differences were found in the endocytotic pathway and internalization kinetics. The endocytosis of MLI, its subunits and of the immunotoxin has been compared to that of the other ligands in various systems.

Isolation and preliminary characterization of the major membrane boundaries of the endocytic pathway in lymphocytes

Plasma membrane, coated pits, endosomes, and lysosomes were isolated from a mouse T lymphoma cell line using a density shift protocol in which these compartments were selectively loaded with gold conjugates. The plasma membrane was prepared after selective labeling for 1 h at 2 degrees C with gold-ricin and gave a yield of 40% according to enzymatic and antigenic markers. Endosomes were obtained by loading the cells for 2 h at 22 degrees C with gold complexed to an antimouse transferrin receptor mAb. Coated pits were isolated using a similar procedure, but after an incubation at 10 degrees C, which allowed deep invagination of the pits but prevented internalization. The yield (calculated using the recovery of [125I]transferrin) was 32% for endosomes and 10% for coated pits. Finally lysosomes were prepared by loading the cells for 18 h at 37 degrees C with gold low density lipoproteins (LDLs) followed by a 3-h chase at 37 degrees C with LDL alone. The final lysosome yield (based on the recovery of lysosomal enzymes) was 16%. Studies of the protein composition of these cellular compartments on two-dimensional gels showed that while some major proteins are present throughout the pathway, specific proteins can be identified in each of the isolated fractions. The greatest change in the pattern of protein constituents seen along the pathway was between endosomal and lysosomal preparations.

Internalization of the cytotoxic molecules of T101 F(ab')2-(ricin-A-chain) immunotoxin into human T-leukemic cells

We have investigated the internalization step of an immunotoxin and its relationship with cytotoxicity, with the F(ab')2-T101(ricin-A-chain) immunotoxin, directed against the CD5 antigen expressed on leukemic CEM cells. We first demonstrated that the biological action of the conjugate was related to its entry into the cell by an energy-dependent endocytotic process. We also found that during the first hours of cell intoxication, internalization is not the rate-limiting step of immunotoxin cytotoxicity. Internalization becomes limiting in cell intoxication only when the entry rate is low. Lastly we show that ammonium chloride, which strongly enhances immunotoxin potency, acts on internalized molecules for a very short time, suggesting that this enhancer affects an early intracellular step.

Adsorptive endocytosis and membrane recycling by cultured primary bovine brain microvessel endothelial cell monolayers

The dynamics of membrane recycling were examined in primary cultures of brain microvessel endothelial cells (BMECs). Because the BMEC surface was dominated by galactosylated glycoconjugates, ricin agglutinin (RCAI) was used as a tracer to follow the endocytosis and recycling of RCAI binding sites. These binding sites accounted for 75% of the iodinatable or most externally disposed plasma membrane proteins. Because greater than 90% of the RCAI that had bound to BMECs was removed by a brief, nontoxic treatment with galactose, the amounts and kinetics for internalization and efflux of [125I]RCAI were measured. Both endocytosis and efflux were energy dependent. By using pseudo-first-order kinetics, the t1/2 values for RCAI binding, internalization and efflux were 5, 18 and 13-14 min, respectively. By comparing efflux with and without galactose present, we found that 60% of the RCAI binding sites that had been internalized were returned to the cell surface and reinternalized. Quantifying the distribution of gold-RCAI following internalization showed kinetics consistent with that obtained using radiolabeled RCAI. Both horseradish peroxidase (HRP) and gold-conjugated RCAI that had bound BMEC at 4 degrees C became localized within more caveolae within 2.5 min of warming to 37 degrees C to permit endocytosis. With time, RCAI appeared within endosomes and tubules and vesicles of which some were located in the trans-Golgi network (TGN). The distribution of HRP-RCAI contrasted with that of free HRP, which was not routed to the TGN. The absence of RCAI conjugates in association with the basolateral membrane domain suggested the presence of functional tight junctions and maintenance of polarity throughout the duration of these experiments. These results showed that membrane recycling was more extensive and much slower than fluid-phase endocytosis in cultured BMECs. Moreover, we found that endocytosis of membrane by BMECs in culture was similar to that reported for brain endothelium in vivo in that a fraction of the cell surface membrane was routed to the TGN.

Endocytosis of wheat germ agglutinin binding sites from the cell surface into a tubular endosomal network

By using fluorescence and electron microscopy, the endocytic pathway encountered by cell surface components after they had bound wheat germ agglutinin (WGA) was visualized. The majority of these components are thought to consist of sialylated glycoproteins (HMWAG) that represent a subpopulation of the total cell surface proteins but most of the externally disposed plasma membrane proteins of the cell. Examination of semi-thin sections by medium- and high-voltage electron microscopy revealed the three-dimensional organization of vesicular and tubular endosomes. Binding of either fluorescein isothiocyanate-, horseradish peroxidase-, or ferritin-conjugated WGA to cells at 4 degrees C showed that the HMWAG were distributed uniformly over the cell surface. Warming of surface-labeled cells to 37 degrees C resulted in the endocytosis of WGA into peripheral endosomes via invagination of regions of both coated and uncoated membrane. The peripheral endosome appeared as isolated complexes comprising a vesicular element (300-400 nm diam.) surrounded by and continuous with tubular cisternae (45-60 nm diam.), which did not interconnect the endosomes. After 30 min or more label also became localized in a network of anastomosing tubules (45-60 nm diam.) that were located in the centrosomal region of the cell. Endocytosed WGA-HMWAG complexes did not become associated with cisternae of the Golgi apparatus, although tubular and vesicular endosomes were noted in the vicinity of the trans-Golgi region. The accumulation of WGA-HMWAG in the endosomes within the centrosomal region was inhibited when cells were incubated at 18 degrees C. None of these compartments contained acid phosphatase activity, a result that is consistent with other data that the HMWAG do not pass through lysosomes initially. The kinetics of labeling were consistent with the interpretation that recycling of most of the WGA binding surface glycoproteins occurred rapidly from early peripheral endosomes followed by the late trans-Golgi compartment. In conclusion, a portion of cell surface glycoproteins are routed to a complex arrangement of tubular and vesicular compartments following endocytosis that includes a putative post-endosomal, tubular reticulum that appears to be separate from the trans-most Golgi saccule.

Internalized ricin and the plasma membrane glycoprotein MAM-6 colocalize in the trans-Golgi network of T47D human breast carcinoma cells

We have analyzed the intracellular transport of endocytosed ricin in the human breast carcinoma cell line T47D. Cells were incubated with ricin (10 micrograms/ml) for 1 h at 37 degrees C. Marked reduction in the protein synthesis did not take place until the end of this period. To detect ricin immunocytochemically, a rabbit anti-ricin serum was used. Gel electrophoresis followed by immunoblotting revealed that the antiserum reacted specifically with ricin and detected both the ricin A-chain and the ricin B-chain. Immunofluorescence experiments showed endocytosed ricin in endosomal and lysosomal vacuoles throughout the cytoplasm, as well as in a typical perinuclear position corresponding to the Golgi region. Using the monoclonal mouse antibody 115D8 directed toward the high-molecular-weight membrane glycoprotein MAM-6 of human breast epithelial cells, we similarly obtained a swarms of small vesicles throughout the cytoplasm. To further analyze the apparent colocalization of ricin and MAM-6 in the perinuclear Golgi region, immunogold cytochemistry on ultracryosections was performed. MAM-6 was detected mainly in Golgi stacks and associated trans-Golgi network (TGN) profiles, in 0.1 to 0.2-micron secretory vesicles, and on the cell surface. Ricin was detected on the cell surface, in endosomes and lysosomes, and also in the TGN. Furthermore, by using immunogold double labeling, internalized ricin was found to colocalize with MAM-6 in the TGN.

High-yield isolation of functionally competent endosomes from mouse lymphocytes

A discontinuous-sucrose-gradient procedure for isolating endosomes from mouse lymphoma cells has been developed. After centrifugation, most organelles (especially mitochondria and lysosomes) are recovered in the denser fractions of the gradient, whereas a mixture of plasma membrane and endosomes is present at lighter densities. The endosome recovery in this fraction can be increased (by 100%) by (a) a mild trypsin treatment of the postnuclear supernatant and (b) loading the cell endosomes with a saturating concentration of low-density lipoproteins. Removal of the plasma-membrane contamination was achieved by preincubating the cells with a gold-ricin complex at 4 degrees C. On centrifugation, the gold-loaded membranes sediment to the bottom of the gradient. The endosome preparation isolated by these procedures is less than 6% contaminated by other organelles and contains 42% of internalized 125I-transferrin. We show that these isolated endosomes are functional, as displayed by their ability to fuse and to acidify in a cell-free system. Endosome fusion was studied by a new assay based on the use of fluorescence resonance energy transfer. This fusion is dependent on ATP and on a cytosolic, thermoresistant but trypsin- and N-ethylmaleimide-sensitive, protein factor. Early endosomes fuse more actively among themselves than with late-endocytic vesicles, and they fuse only slowly with plasma-membrane vesicles.

Distribution of ricin within the mammalian para-aortic lymph node. II. Comparison of the localization, after intramuscular dosage of colloidal gold-labelled ricin in vivo, with in vitro binding characteristics of the native toxin

Previous work has shown that, following an intramuscular injection of ricin, the toxin becomes localized within histiocytes in the sinuses of lymph nodes draining the 'wound' site. When ricin labelled with colloidal gold was similarly injected, it was found within the same lymphoid cells as seen with native ricin. Biologically inert Indian ink apparently follows a similar fate, as demonstrated by the appearance of carbon particles within sinus histiocytes, as soon as 1 h after intramuscular injection. When the binding in vitro of Indian ink or ricin toxin to sections of lymph node was examined, ricin was seen to bind to the surfaces of the same sinusoidal cells and also, with a much lower frequency, to follicular lymphocytes, whereas Indian ink failed to bind. This indicated an interaction between ricin and cell membrane components. Moreover, this binding was inhibited markedly by the galactose-containing disaccharide, lactose, a target sugar specified by the lectin binding site of ricin and to a much lesser extent by the monosaccharide mannose.

Anti-ricin antibody protects against systemic toxicity without affecting suicide transport

Ricin is an effective suicide transport agent which reliably destroys sensory and motor neurons in anatomically selective fashion after peripheral nerve application. In the present study, we gave subcutaneous injections of commercially available antiricin antibody (ARA) at the time of ricin application to peripheral nerves. The ARA protected rats against systemic ricin poisoning without altering the suicide transport activity of ricin. This approach removes a significant barrier to the routine use of ricin and should prove useful when ricin is employed to ablate large peripheral nerves. However, antibody protection permits use of such large ricin doses that the toxin may diffuse within the CNS destroying neurons adjacent to those that project through the injected nerve. Consequently, antibody and ricin doses must be optimized for any particular experimental situation.

Hepatic metabolism of colloidal gold-low-density lipoprotein complexes in the rat: evidence for bulk excretion of lysosomal contents into bile

Rats were treated with 17 alpha-ethinyl estradiol to induce high levels of low-density lipoprotein receptors in hepatocytes. When these rats were given intravenous injections of low-density lipoprotein-colloidal gold complexes, most of the gold (labeled with 195Au) appeared to be taken up by Kupffer cells, as were complexes of colloidal gold with albumin or polyvinylpyrrolidone. However, when these rats were also administered gadolinium chloride, which blocks Kupffer cell activity, most of the low-density lipoprotein-gold (but not gold complexed with albumin or polyvinylpyrrolidone) was taken up into hepatocytes by receptor-mediated endocytosis and concentrated in peribiliary lysosomes, as determined by electron microscopy. Colloidal gold taken up as a complex with low-density lipoprotein was excreted into the feces via the common bile duct at a maximal rate of about 5% daily, 4 to 12 days after injection. Thereafter, the rate of gold excretion fell off until reaching a plateau after 3 weeks. At this late time, most of the colloidal gold was shown by electron microscopy to be in Kupffer cells, whereas earlier (6 days after injection) it was contained mainly in older hepatocytic lysosomes, identified by lipofuscin granules. It is concluded that, in rats, hepatocytic lysosomes empty most of their contents into bile every week or two, apparently by exocytosis.

Acute and chronic effects of the neurolytic agent ricin on dorsal root ganglia, spinal cord, and nerves

The short- and long-term effects of ricin injections into nerves have been evaluated with light microscopy in the dorsal root ganglia, spinal cord, and peripheral nerves in rats and cats. Dorsal root ganglion cells initially exhibited chromatolysis, followed by gliosis and cell death. These changes were associated with Fink-Heimer degeneration in the somatotopically appropriate region of the dorsal horn. There were no signs of chromatolysis in dorsal horn neurons in ricin-injected animals, but chromatolytic motoneurons were observed. Ricin produced acute necrosis of injected nerves and dissolution of axoplasm. At long survival times (greater than 4 weeks) some apparently regenerating axons were seen in the injection sites of rats. Cell counts indicated that a substantial percentage of dorsal root ganglion neurons associated with the injected nerves were killed, but the presence of regenerating axons suggested that some cells survived the ricin treatment. Although the lesion may not always be complete, even with maximum sublethal doses, this method appears to be useful for specifically destroying afferent fibers associated with a particular nerve without transynaptic destruction of dorsal horn neurons.

The expression of functional ricin B-chain in Saccharomyces cerevisiae

Yeast cells transformed with plasmids containing ricin B-chain coding sequences expressed this heterologous protein. When ricin B-chain was expressed in a form which resulted in its deposition in the yeast cytosol it formed insoluble aggregates which were devoid of galactose-binding activity. In contrast, when DNA fusions were constructed, in which the B-chain coding sequence was preceded by either the preproalpha-factor leader sequence or the native preproricin signal sequence, the recombinant B-chain products were soluble and biologically active. Both the homologous yeast signal peptide and the heterologous plant signal peptide directed the expressed product into the lumen of the yeast endoplasmic reticulum. As a result, the recombinant B-chain products were processed at the N-terminus, glycosylated and folded into an active conformation, presumably stabilized by correct intrachain disulphide bond formation.

Estimation of the amount of internalized ricin that reaches the trans-Golgi network

We have used a protocol for internalization of ricin, a ligand binding to plasma membrane glycoproteins and glycolipids with terminal galactosyl residues, and infection with the vesicular stomatitis virus ts 045 mutant in BHK-21 cells to determine whether internalized plasma membrane molecules tagged by ricin reach distinct compartments of the biosynthetic-exocytic pathway. At 39.5 degrees C newly synthesized G protein of ts 045 was largely prevented from leaving the endoplasmic reticulum. At the same temperature ricin was endocytosed and reached, in addition to endosomes and lysosomes, elements of the Golgi complex. When the temperature was lowered to 19.5 degrees C, no more ricin was delivered to the Golgi complex, but now G protein accumulated in the Golgi stacks and the trans-Golgi network (TGN). Double-labeling immunogold cytochemistry on ultracryosections was used to detect G protein and ricin simultaneously. These data, combined with stereological and biochemical methods, showed that approximately 5% of the total amount of ricin within the cells, corresponding to 6-8 X 10(4) molecules per cell, colocalized with G protein in the Golgi complex after 60 min at 39.5 degrees C. Of this amount approximately 70-80% was present in the TGN. Since most of the ricin molecules remain bound to their binding sites at the low pH prevailing in compartments of the endocytic pathway, the results indicate that a fraction of the internalized plasma membrane molecules with terminal galactose are not recycled directly from endosomes or delivered to lysosomes, but are routed to the Golgi complex. Also, the results presented here, in combination with other recent studies on ricin internalization, suggest that translocation of the toxic ricin A-chain to the cytosol occurs in the TGN.

Modeccin and volkensin but not abrin are effective suicide transport agents in rat CNS

Suicide transport is a term applied to the technique of producing anatomically selective neural lesions using axonally transported cytotoxins. Because the cytotoxic lectins, abrin, modeccin and volkensin are effective suicide transport agents in the peripheral nervous system, the present study sought to determine if they were effective suicide transport agents in the rat CNS. Toxins were stereotactically pressure microinjected unilaterally into the caudate nucleus of rats. After 2-13 days survival, brain sections were processed for catecholamine histofluorescence or Nissl stained with Cresyl violet. All 3 agents produced extensive necrosis at the caudate injection site. In addition, modeccin and volkensin but not abrin produced destruction of neurons in the ipsilateral substantia nigra and intralaminar thalamus. Histofluorescence confirmed loss of dopaminergic neurons from the ipsilateral substantia nigra after modeccin or volkensin but not abrin injections. These results indicate that modeccin and volkensin are effective suicide transport agents within the rat CNS, presumably due to retrograde axonal transport of the toxins. These agents may prove extremely useful in producing anatomically selective lesions of neurons afferent to a toxin injection site.

Inhibition of endocytosis from coated pits by acidification of the cytosol

Binding and endocytosis of the ligands transferrin, epidermal growth factor (EGF), and ricin were measured in a number of different cell lines after treatment of cells with compounds that react with SH-groups and under conditions where the cytosolic pH was lowered. N-ethylmalemide and diamide irreversibly inhibited endocytosis of all ligands tested, whereas low pH in the cytosol strongly inhibited endocytosis of transferrin and EGF. Data obtained by electron microscopy indicated that the formation of coated vesicles from coated pits is inhibited in acidified cells. Entry of ricin was much less affected, and ricin endocytosed under these conditions was able to intoxicate the cells. At low pH in the cytosol there was a calcium-dependent increase in the number of transferrin receptors at the cell surface. The increase was even larger in the presence of the calcium ionophore A23187, whereas it was completely blocked by the calmodulin antagonists trifluoperazine and W7. The results show that endocytosis from coated pits can be inhibited in a reversible way by acidification of the cytosol and they suggest that a second pathway of endocytosis exists, possibly involving formation of vesicles from uncoated areas of the membrane.

The presence of retinopetal fibres in the optic nerve of the Mongolian gerbil (Meriones unguiculatus): a horseradish peroxidase in vitro study

Mongolian gerbils were enucleated, and a crystal of HRP placed on the cut surface of the transected optic nerves emerging from the eyeballs. After incubation in an oxygenated medium, glutaraldehyde fixation, cryo-sectioning and reaction of the sections for peroxidase activity, HRP-labelled fibres were observed in the optic nerve fibre layer of the retina. Some of the labelled fibres penetrated in the external direction from the ganglion cell layer into outer retinal layers. HRP-labelled fibres were observed in the inner plexiform layer, inner nuclear layer, as well as the outer plexiform layer. In the outer plexiform layer arborization of the fibres was prominent especially close to the outer nuclear layer. In all layers some fibres were beaded. Due to the lack of trans-synaptic transport by use of this in vitro method the study strongly indicates the presence of an efferent innervation of the retina of the Mongolian gerbil. A preliminary report on this research has been presented at the Tenth European Neuroscience Meeting, Marseille (1986).

Acidification of the cytosol inhibits endocytosis from coated pits

Acidification of the cytosol of a number of different cell lines strongly reduced the endocytic uptake of transferrin and epidermal growth factor. The number of transferrin binding sites at the cell surface was increased in acidified cells. Electron microscopic studies showed that the number of coated pits at the cell surface was not reduced in cells with acidified cytosol. Experiments with transferrin-horseradish peroxidase conjugates and a monoclonal anti-transferrin receptor antibody demonstrated that transferrin receptors were present in approximately 75% of the coated pits both in control cells and in cells with acidified cytosol. The data therefore indicate that the reason for the reduced endocytic uptake of transferrin at internal pH less than 6.5 is an inhibition of the pinching off of coated vesicles. In contrast, acidification of the cytosol had only little effect on the uptake of ricin and the fluid phase marker lucifer yellow. Ricin endocytosed by cells with acidified cytosol exhibited full toxic effect on the cells. Although the pathway of this uptake in acidified cells remains uncertain, some coated pits may still be involved. However, the data are also consistent with the possibility that an alternative endocytic pathway involving smooth (uncoated) pits exists.