David G. Upshall

Inhalation Toxicology and Histopathology of Ricin and Abrin Toxins

AbstractThe inhalation toxicology of ricin (supplied by Sigma) from the seed variety “Hale Queen” and abrin was examined following head-only exposure of rats to a range of concentrations of each toxin generated as an aerosol from solution using a constant-output nebulizer. The inhalation toxicity of an in-house preparation of ricin from a different seed type, Ricinus communis var. zanzibariensis (R. zanzibariensis), was also assessed for comparison. The approximate LCt50 values determined were very similar for the Sigma ricin and abrin (4.54–5.96 and 4.54 mg min m-3, respectively). However, the LCt50 of ricin toxin prepared in-house from seeds of the R. zanzibariensis variety was assessed to be 12.7 mg min m-3. Ricin prepared from this seed variety was therefore less toxic than Sigma ricin by a factor of almost threefold. Given that both ricin preparations were pure by silver-stained, sodium dodecyl sulfate polyacrylamide electrophoresis gels, the data must reflect differences in specific toxicity between...

Protection against inhalation toxicity of ricin and abrin by immunisation.

1 Abrin and ricin are highly toxic plant proteins which are very similar in structure and function and inhibit protein synthesis in eukaryotes. 2 Rats have been immunised against either toxin using formaldehyde-toxoids by three subcutaneous injections at intervals of 3 weeks. For abrin, serum titres in 14 out of 15 rats were raised to between 1 : 12800 and 1 : 51200 after two injections, 6 weeks from the start of the experiment. Titres of between 1 : 256 and 1 : 1024 were also measured in lung washes after challenge with active abrin toxin. 3 The three major antibody classes, IgG, IgM and IgA were present in the immune sera but IgG and IgA only were detected in lung washes. The proportion of IgA to IgG was higher in the lung fluid than in sera. Rats immunised by abrin toxoid were protected against 5 LCt50s of abrin by inhalation but others exposed to ricin were not. 4 For ricin, serum titres ranged from 1 : 800 to 1 : 25600 after two injections and after a third injection the titre range was the same but population samples were weighted towards the higher titres. All rats immunised with ricin toxoid survived the challenge of 5 LCt50s of ricin toxin by inhalation over the observation period of 28 days post-challenge. 5 Representative immunised rats (abrin toxoid) were taken at various times post-exposure, humanely killed and tissues were examined for pathological changes. It was concluded that an apparently severe lung lesion occurred at a later time than in non-immunised, toxin challenged rats. This damage was not lethal over the experimental observation periods. 6 Immunisation by the sub-cutaneous route therefore protects against lethality from challenge by inhalation of ricin or abrin toxins but does not prevent significant lung damage.

Protection by cysteine esters against chemically induced pulmonary oedema

Perfluoroisobutene (PFIB) is a hydrophobic reactive gas produced by the pyrolysis of polytetrafluoroethane which induces pulmonary oedema similar to that induced by phosgene when inhaled. When a lethal dose is inhaled by Porton strain rats total non-protein thiol (NPSH) and glutathione (GSH) in the lung are reduced by between 30 and 49%, respectively. If the endogenous levels of thiols in the lung are reduced by pretreatment with buthionine sulfoximine (BSO) 16 hr before exposure to PFIB, the rats become more susceptible to the effects of the gas. The effect of BSO pretreatment on toxicity was prevented by pretreatment 30 min before exposure, with 5 mmol/kg N-acetylcysteine (NAc). NAc increased the levels of cysteine (CySH) in the lung by 150% and GSH was unaffected. Similarly pretreatment with 3 mmol/kg CySH also protected against toxicity and raised CySH levels by 100%. A series of cysteine esters and cystine dimethyl ester (CDME) have been synthesised which selectively raise lung levels of CySH in the rat lungs after intraperitoneal (i.p.) injection. The methyl ester and CDME raised lung levels of CySH by 4000 and 2000%, respectively, 10 min after i.p. injection whilst GSH levels remained unchanged. Cysteine isopropyl ester raised lung levels of CySH by 10,600% but liver levels by only 1400%. All esters except the t-butyl ester (CTBE) also raised maximal plasma levels of NPSH by up to 500%; however, when NAc was injected plasma levels increased by over 1500%. Rats treated with these esters at 3 mmol/kg and with NAc at 5 mmol/kg were protected against lethal doses of PFIB in all cases except when CTBE was used. It appears that these cysteine esters may distribute preferentially into the lung, unlike NAc. The selective enhancement of pulmonary CySH levels may provide a method for the protection of lungs against inhaled reactive toxicants by increasing intracellular CySH. Levels of CySH may also be raised in epithelial lining fluid thus reducing access of gaseous toxicants to pulmonary tissue.

Examination of the toxicity of several protein toxins of plant origin using bovine pulmonary endothelial cells.

The bovine pulmonary endothelial (BPE) cell line was examined as a model to study the toxicity of ricin and abrin toxins currently under investigation. The BPE cell line was examined because ricin has been shown to bind to endothelial cells. Cell viability was assessed using several different biochemical parameters including growth (DNA by binding of gentian violet stain), mitochondrial function (succinate dehydrogenase activity) using MTT and lysosomal integrity (neutral red retention assay). In order to compare toxicities and investigate potential protective compounds, concentrations of toxins causing death of 50% and 70% of the (control) cell population (LC50 and LC70, respectively) were determined. It is concluded that while ricin and abrin share a common mechanism of action ricin is slightly less toxic than abrin. BPE cells are a good model for future mechanistic studies and particularly for initial phase screening of potentially therapeutic compounds. Carbohydrates were used in an attempt to examine which receptor types were involved in the binding and uptake of ricin and abrin by the cell line. It was found that only high concentrations of galactose prevented lethality while mannose apparently had no effect. Furthermore, the molar excess of carbohydrate to toxin required in order to achieve protection indicated that this would be an impractical approach to adopt in vivo.

Cysteine Esters Protect Cultured Rodent Lung Slices from Sulphur Mustard

1 In previous studies an in vitro rat lung slice system was used to investigate the metabolic and structural changes after exposure to known lung toxicants. 2 In this study, the same system was used to identify the ability of cysteine esters to protect against sulphur mustard toxicity. 3 The cyclopentyl (CCPE), cyclohexyl (CCHE), isopropyl (CIPE), methyl (CME) esters of cysteine, cystine dimethyl ester (CDME), cysteine (CySH) and N-acetyl cysteine (NAc) were all non-toxic to cultured rat lung slices at 5 mM (equivalent cysteine concentration) after a pretreatment time of 30 min. 4 Pretreatment with the isopropyl, cyclohexyl, cyclopentyl and methyl esters of cysteine at concentrations higher than 1 mM protected against an IC50 of sulphur mustard, however, neither cysteine nor N-acetylcysteine protected. 5 We propose that the extent of protection is directly related to increased levels of intracellular cysteine provided by the esters of cysteine.

Elevation of cysteine and replenishment of glutathione in rat lung slices by cysteine isopropylester and other cysteine precursors

In this study, we have used a rat lung slice model to compare the ability to several potential cysteine delivery systems (L-cysteine isopropylester, L-cysteine cyclohexylester, N-acetylcysteine, L,2-oxo-4-thiazolidine carboxylic acid and cysteine) to elevate cysteine and glutathione (GSH) levels in control lung slices and slices depleted of their GSH by diethyl maleate. The esters of cysteine produced the greatest rise in lung slice cysteine. All the cysteine delivery systems were capable of replenishing GSH in lung slices previously depleted of GSH by diethyl maleate.

Presence of methenamine/glutathione mixtures reduces the cytotoxic effect of sulphur mustard on cultured SVK-14 human keratinocytes in vitro:

1 The basal epidermal keratinocytes of the skin are a main target for the vesicating agent, sulphur mustard (SM). A human keratinocyte cell line (SVK-14) has been used to model the effects of SM on the basal epidermal keratinocytes and subsequently to test the efficacy of potential prophylactic compounds in reducing the SM-induced cytotoxicity. 2 The cultures were pretreated with mixtures of methe namine (HMT) and glutathione (GSH) for 1 h prior to exposure to 10 μM SM. The viability of the cultures was then assessed using neutral red (NR) dye uptake and crystal violet DNA staining assays at 24 h intervals post exposure. 3 Pretreatment led to a 1.9 fold increase in culture viability (NR assay) compared to those exposed to SM only, and a 2.3 fold increase in cell number (crystal violet assay). Photomicrography showed that pre treatment preserved the morphology of the cultured cells and maintained their mitotic activity whereas those exposed to SM only show non-proliterative cultures with extensive cellular damage. 4 The results of this study show that it is possible to protect mitotically active cultures from the effects of SM, however the measures must be in place prior to SM exposure.

The effect of sulphur mustard on glutathione levels in rat lung slices and the influence of treatment with arylthiols and cysteine esters

1 Sulphur mustard reacts directly with benzenethiols and cysteine esters in aqueous medium. 2 Benzenethiols diffuse into lung slices in short term culture. 3 Treatment of lung slices in short term culture with benzenethiols does not protect cellular glutathione from conjugation with sulphur mustard. 4 Following uptake of cysteine ester into lung slices cysteine is elevated but this does not protect cellular glutathione from sulphur mustard.

Structure-activity relationships of cysteine esters and their effects on thiol levels in rat lung in vitro.

Pretreatment with cysteine esters increases cysteine (CySH) levels in rat lung and protects against the lethal effects of inhaled perfluoroisobutene in vivo. There are marked differences in the duration of protection achieved with different cysteine esters. In this study we have compared the uptake and metabolism of CySH, N-acetyl cysteine (NAc), cysteine esters and cystine esters in vitro using rat lung and liver homogenates and lung slices. Liver homogenates metabolized CySH and cysteine esters faster than lung homogenates. The half life (T1/2) of CySH in lung was 58.8 +/- 17.3 min and in liver was 14.0 +/- 1.6 min (mean +/- SEM). T1/2 of the esters in lung ranged between 6.5 and 12.1 min and in liver between 1.9 and 5.3 min. Cysteine tertiary butyl ester, which does not protect in vivo, was not hydrolysed to CySH by lung or liver homogenates. All esters increased and prolonged intracellular CySH concentrations in lung slices to a much greater extent than CySH itself. NAc did not raise intracellular CySH above that of the controls and no NAc appeared within the slice. After CySH incubation intracellular CySH was 0.9 +/- 0.1 nmol/mg wet wt at 10 min whereas after incubation with the esters it ranged between 2.60 and 3.65 nmol/mg wet wt. Cysteine cyclohexyl ester prolonged the increase of CySH the longest and cysteine methyl ester the shortest. CySH levels with cysteine cyclohexyl ester were 2.74 +/- 0.15 and 4.13 +/- 0.37 nmol/mg wet wt at 10 and 60 min, respectively, whereas with cysteine methyl ester, CySH levels were 2.60 +/- 0.5 and 1.25 +/- 0.08 nmol/mg wet wt at similar times. Cystine esters increased intracellular concentrations of both cystine and CySH. CySH concentrations ranged between 2.92 and 3.19 nmol/mg wet wt and cystine between 1.39 and 1.47 nmol/mg wet wt at 60 min. The elevation and duration of CySH in lung slices is well correlated with the duration of protection against perfluoroisobutene achieved in vivo.

Thiol Levels in Rat Bronchio-Alveolar Lavage Fluid after Administration of Cysteine Esters

1 The intraperitoneal administration of cysteine, N-acetylcysteine, the methyl, isopropyl, cyclo pentyl, neo pentyl, cyclo hexyl and tertiary butyl esters of cysteine and of cystine dimethyl ester increased the levels of total non-protein sulphydryls and cysteine in the bronchioalveolar lavage fluid and plasma of rats. In all cases the non-protein sulphydryl levels reflected the increased cysteine levels. 2 Cysteine, N-acetylcysteine, the cysteine esters and cystine dimethyl ester raised the levels of non-protein sulphydryls and hence cysteine in the bronchioalveolar lining fluid as follows: CIPE > CCPE > CME > CDME > CneoPE > CCHE > Nac > CySH > CTBE. 3 Plasma levels of NPSH were increased as follows: Nac > CySH > CCPE > CCHE > CneoPE > CIPE > CME > CDME > CTBE. 4 All except CTBE have been shown to protect against the lethal effects of inhaled perfluoroisobutene, a pyrolysis product of polytetrafluoroethene which induces a fulminating pulmonary oedema. 5 This study showed that by raising the levels of thiols in the bronchioalveolar lavage fluid (BALF), the epithelial cells lining the bronchiolar, alveolar regions of the lung could be protected against inhaled toxicants. 6 It is proposed that increased thiol levels in the BALF may contribute to the overall protection induced by these compounds by reacting with inhaled electrophiles to prevent or reduce damage to tissue in close proximity to the airways.