Dichlorodioctylstannane

Publication describes the mechanism of apoptosi of thymocytes after activation of NR3C1.

It is shwon, that adverse effects beloning to immune suppressive substance are an acute effect , beginning after a few hours

Reversibe, dose related thymus atrophy and reduced number of cells in thymus after one time dose of DOTC

decrease thymus weight, number thymocytes, SRBC antibody tiiter was reversible

Survival

All BN and LEW rats injected with 4 mg DOTC/kg body weight (using a concentration of 2 mg DOTC/ml solvent) died within 9 days but LEW survived significantly longer than BN. The percentage surviving also differed significantly on days 1 and 2 but not on days 3, 7 or 9. All animals injected with an equivalent volume of solvent without DOTC survived. It was found that, when the concentration of DOTC injected was increased to 4 mg/ml, both strains survived longer and this concentration was used for all studies described below.

Using the higher concentration, a difference between males and females was detected. The survival rates of BN males differed significantly (P<0.05) from that of females on all days except day 1 after injection of DOTC. LEW males differed significantly from females only on day 7. A significant difference between males of BN (17% survival at day 7) and LEW (58% survival at day 7) was alsoobserved. (LEW x BN) F₁ hybrids (not shown) behaved like the LEW strain with 56 % (5/9) of males surviving 7 days. There werenosignificant differences in survival of females among the 3 strains. All animals (groups of 4 to 6 for each strain) injected with 1 mg DOTC/kg survived.

Immunological parameters

No significant changes,in body weights or spleen weights were detected in any ofthe 3 strains whenratsinjected with DOTC were compared to those injected with solvent alone. The thymic weights and responses to ConA were decreased significantly when BN and LEW rats treated with DOTC were compared to controls. In contrast, the antibody responsesofthe 3 strains were increased, although the increase was not statistically significant. Responses of rats injected with 1 mg DOTC/kg body weight were comparable to those of controls. No significant differences between males andfemales were detected for any of these parameters.

Histopathology

There was a correlation between decreased thymic weightsand alterations detected histologically. BN rats and F₁ hybrids were similar and significant changes were detected only in females treated with DOTC. With LEWrats, significant changes were detected in both males and females. Tissues from ratstreated with solvent alone were all normal.

The major change observed in affected tissues was a marked depletion and thinning of the cortex. The junction between cortex and medulla was also somewhat obscured. With LEW rats, a significant increase in fibrous connective tissue was also observed in the thymus. Because some organotins are potent neurotoxins, the hippocampal formations of brains from the animals were also examined; all were normal. Other areas of the brain were not examined.

Changes in Body Weights

The body weights in animals given DOTC increased less in days 1 - 4 that the control. However, they soon recovered and no significant differences were observed at 8 days after treatment.

Organ Weights

For the thymus, a significantly low weight was observed 1 day after DOTC treatment, and the weight decreased until at least 7

days later. Thereafter, thymus weights of animals given DOTC were still significantly lower than those of control animals at the end of the experiment, although they tended to recover to control levels. Spleen weights were low in DOTC-treated animals in comparison to controls. Significantly low spleen weights in DOTC-treated animals were observed from 6 h to 3 days after treatment. However, these recovered to control levels 4 days after treatment. Although, low liver and kidney weights in DOTC-treated animals were also observed, these were temporary.

Changing pattern of tissue concentrations of dioctyltin and its major metabolite, monooctyltin

Most dioctyltin was accumulated in the liver after DOTC treatment. In the case of monooctyltin, a high accumulation was observed in the liver, but at lower levels than dioctyltin. Di- and monooctyltin concentrations in the liver and kidney increased peaked 2 days after DOTC treatment, and then decreased. Dioctyltin accumulation in the brain was very low, although the levels remained constant from 2 days after treatment. Monooctyltin accumulation in the brain was not detected during the experiment. Also, we could not detect di- or monooctyltin accumulation in the thymus or spleen.

Histological changes

In the histological study, no clear effects of DOTC administration were observed in all tissues examined. On the other hand, the number of TUNEL stained cells, apoptotic cells, in the thymus and spleen increased from 1 to 4 days after DOTC treatment, as compared with the controls. Thereafter, apoptotic cell numbers in the thymus and spleen in animals administered DOTC were similar to those in control animals until 8 days after treatment.

Expression of genes involved in apoptotic pathway in thymus

In the study, 154 probe sets of 97 genes involved in apoptosis were studied between the thymus of controls and DOTC-treated animals These genes were categorized as ones involved in apoptosis by Gene Ontology (GO) Data (Gene Ontology TM Consortium), Gene MicroArray Pathway Profiler or KEGG (Kyoto Encyclopedia of Genes and Genomes). Most of the studied probe sets did not show different expressions. Only three (1369146 a at, 1387690 at and 1368936 at) of the probes corresponding to Ahr, Casp3 and Txnll genes, respectively, showed significantly low signals. A significantly high signal was observed with the probe

for the Nr3cl gene.

Discussion

This is the first report to directly show the changing concentration patterns of dioctyltin and its major metabolite, monooctyltin, in each tissue of animals administered DOTC. Most accumulations of di- and monooctyltin were found in the liver. In other tissues, their accumulations were low or absent. In other tissues, their accumulations were low or absent. Penninks et al. (1987) also showed similar findings concerning the distribution of dioctyltin in tissues using 14C-labeled DOTC administration in rats. A decreased liver weight was observed when accumulations of di- and monooctyltin in the liver reached a peak. However, the liver toxicity of this compound would be low because liver weight recovered to control levels immediately, and no pathological changes were observed. Thymus and spleen weight losses were also found, although tissue accumulations of di- and monooctyltin were not detected. The reduced thymus and spleen weights were maintained longer than that observed in the liver. This suggests that this compound leads to immunotoxicity.

A higher number of apoptotic cells in the thymus was detected from 1 to at least 4 days after DOTC treatment as compared with controls, and this period roughly corresponds to the time of thymus weight decrease. Therefore, the increase in the number of apoptotic cells in these organs would provide an explanation for thymus weight loss, although DOTC also has an inhibitory effect of thymocyte proliferation. It supports the view that dibutyltin and tributyltin, organotins shown to be immunotoxic, similarly cause thymocyte apoptosis.

Spleen weight also decreased after DOTC treatment. The number of apoptotic cells in the spleen as well as in the thymus increased. However, spleen weight reduction was relatively slight, and had recovered to control levels 4 days after treatment. Therefore, the toxicity of this compound to the spleen is relatively low compared to the thymus.

No other histopathological changes were noted in the brain, liver or kidney of animals given DOTC. The body weight of animals administered DOTC was significantly reduced 2 days after DOTC dosing as compared with the controls. However, it recovered immediately and was not significant 8 days after treatment. Therefore, it presented no serious toxicity.

In the study, genes in thymus involved in apoptosis were researched using a microarray technique. Most of the genes examined showed similar expressions between controls and DOTC-treated animals. Only three probes were found showing significantly low hybridization signals and one probe showing a significantly high signal: probes for the genes Ahr, Casp3, Txnll and Nr3cl, respectively. For expression analysis of these genes, not only single but also plural probes were determined in the present hybridization study. No significant difference was found using these plural probe sets. Therefore, it is not clear whether these genes are expressed differentially after DOTC treatment. However, the hybridization signal of these other kinds of probe sets against Ahr (1369147 at) and Txnll (139135 at, 1392058 at, 1388862 at, 1391789 at and 1368936 at) also tended to decrease, and that against Nr3cl (1368222 at and 1397004 at) tended to increase. So, Ahr and Txnll might be candidates of downregulated genes, and Nc3rl might be a candidate of upregulated genes after DOTC treatment. There is a report that nur77 is one of the candidate genes

for inducing apoptosis in the rat thymus after DBTC treatment (Gennari et al., 2002a). Nc3rl is one of nuclear receptor family

genes, like nur77. Therefore, Nc3rl may be a potential candidate gene for organotin-induced apoptosis. In conclusion, exposure

to DOTC causes immunotoxicity in developing rats, and is selectively toxic to thymus and spleen cells. One reason for the observed thymus weight loss may be the increased apoptosis of immune cells (possibly T-cells), as noted in cases of TBTC and DBTC treatment. To elucidate this further, Nc3rl gene expression in the thymus after DOTC treatment needs to be clarified.

Previous studies had shown a slight drop in growth rate in rats fed 150 ppm DOTC-containing diets for longer than 2 weeks, and animals in this investigation were therefore fed diets containing 75 ppm DOTC to avoid any confounding factors.

Thymic weight was markedly reduced in all treated groups whereas no effect on body weight gain or feed uptake was apparent. No histological changes attributable to DOTC treatment were observed in tissue sections of spleen, liver, prostate, seminal vesicles, and testes compared with tissue from control rats by light microscopy. Thymus sections from DOTC-fed rats showed a gross depletion of small thymocytes, septal thickening, and loss of corticomedullary boundaries in all cases. The thymic atrophy was accompanied by some loss of circulating leukocytes (WBC) which was first apparent 4 weeks after commencement of treatment, but showed little further decrease over time of treatment. After 8 weeks treated rats had a mean WBC count of 9.9 X 10²/ mm³ compared to 13.27 X 103/mm³ in control rats (p<0.001) and at 12 weeks the mean WBC count was 10.4 X 10²/mm³ and 13.8 X 10³/mm, respectively (p<0.001). is decrease was not accompanied by a decrease in cell viability which was always greater than 95% as determined by trypan blue exclusion. Analysis of the T-cell subpopulations present in the circulating lymphocytes demonstrated a significant (p<0.01) preferential loss of cells expressing W3/25 phenotype in samples obtained from treated rats. The absolute numbers of W3/25-positive lymphocytes had decreased from a mean of 6.8 X 10³/mm³ in control rats to 4.35 X 10³/ mm³ in DOTC-fed animals after 12 weeks feeding.. No significant difference was found in cells expressing the MCR OX8 phenotype between treated and control rats.

The ability of lymphocytes from treated rats to respond to PHA-induced blastogenesis was reduced at all three concentrations of PHA used in the assay system compared to untreated animals. A decrease of [³H]thymidine incorporation into unstimulated lymphocytes obtained from treated rats was also observed. Thymidine incorporation was 27, 42, and 63% of control values at 1.25, 2.5, and 3.75 µg/ml PHA, respectively, after 8 weeks of DOTC exposure. The level of decreased responsiveness compared to concurrent controls was the same after the 8- and 12-week feeding regimen, and was always very much greater at the suboptimal dose of PHA present during the assay (p<0.01) These assays were unaffected by. the reduction in total lymphocytes obtained from treated compared to control animals, since all tests were performed at a concentration of 1 X 10⁶ lymphocytes per ml.

Both DOTC-treated and control animals were able to mount specific antibody responses against SRBC, a heterologous T-cell-dependent antigen. Hemagglutinin assays showed little difference in responsiveness between the treated and untreated groups after either 8 or 12 weeks of treatment. The slight reduction in antibody production seen after 12 weeks exposure from 4.5 to 4.0 units expressed as loge dilutions are in marked contrast to experiments with nude rats which demonstrated antibody responses of less than 0.5 units.

As little difference was found in the alteration of thymus-dependent immune responses between 8 and 12 weeks DOTC exposure, investigation into allogenic responsiveness and natural cytotoxicity were carried out only in 8-week exposed animals. Experiments measuring GvH reactions showed slight differences in the weights of draining lymph nodes from F₁ rats injected with cells obtained from DOTC-treated rats compared with those injected with cells from control animals. The reduction in lymph node weight, more discernable when expressed as proliferation index (PI), was not indicative of an impaired allogeneic response. The mean PI was 18.87 and 17.61 for control and DOTC-treated respectively.

A marked reduction in allogenic recognition in in vitro MLR assay. Lymphocytes isolated from treated PVG rats showed a significantly reduced proliferative response when cultured with either syngeneic (p<0.05) or allogeneics (p<0.01) stimulator cells compared to control rats. Natural cytotoxicity, a measure of early killing of allogeneic cells by unsensitized hosts, was also determined after 8 weeks on DOTC-containing diets. Syngeneic recipients (DA rats) were used as negative controls. Whereas the radioactivity recovered from lymph nodes was in excess of that recovered from kidneys in syngeneic recipients (lymph node/kidney = 14.2), both control and DOTC-fed allogeneic PVG rats were able to destroy a substantial proportion of ⁵¹Cr-labeled injected cells within 24 hr. The lymph node to kidney ratio was equal to 0.75 for control and 0.71 for treated animals, demonstrating no significant difference in activity between the two groups.

Antibodies with specificity for self erythrocytes were first detected in 80% of control animals 7 days after the second rat erythrocyte injection. The antibody titer increased rapidly after the third injection and at this stage all control mice were producing a high-titer antibody response. The weekly administration of 20 or 100 mg/kg body wt DOTC prior to each RRBC injection had no significant influence on this response, but 500 mg/kg body wt DOTC significantly depressed the response from Week 3 onwards.

The parallel anti-rat erythrocyte antibody response occurred rapidly, with anti-body being detectable in the serum 7 days after the first injection of RRBCs. The antibody titer was seen to increase following subsequent injections of rat erythrocytes. The administration of 500 mg/kg body wt DOTC caused a statistically significant depression of the response at Weeks 1 (p < 0.05), 4 (p < 0.01), and 5 (p < 0.05); the administration of lower doses of DOTC was without effect. None of the DOTC doses employed affected the 48-hr delayed-type hypersensitivity response against oxazolone assessed during Week 8 of the treatment regime. Hematological analysis performed at the end of the experiment revealed a reduced hemoglobin level in those mice treated with 500 mg/kg body wt DOTC, though RBC and WBC counts remained within the control range. The administration of the lower concentrations of DOTC had no effect on these parameters. Compared with control, relative thymus weight was decreased (p < 0.01) liver weight was increased, but spleen weight was normal in animals receiving 500 mg/kg body wt DOTC weekly. The administration of 20 or 100 mg/kg body weight DOTC, did not influence the relative organ weights.

In all treated groups thymic weight (gram wet weight) was markedly reduced. In the animals fed DOTC-containing diets for 4 weeks, return-to-normal diets resulted in increased cellularity of the thymus, although thymic weight remained significantly reduced. The low thymic weight after treatment was accompanied by a decrease in circulating lymphocytes. Surface marker analysis did not, however, demonstrate a decrease in the proportion of T cells present (80 and 77% for control and treated rats, respectively). Viability, as determined by trypan blue exclusion, was greater than 95% at all times. The PHA-induced lymphocyte blastogenesis was significantly reduced: after 4 weeks of DOTC-containing diet compared to control animals and remained reduced after cessation of treatment.

Histopathological and Ultrastructural Observations

Control rats. Thymuses from untreated rats showed normal thymic morphology and a distinct corticomedullary junction was always apparent at the light microscope level. Ultrastructurally cortical thymocytes were characterised by round nuclei, dense heterochromatin, little cytoplasm, and few mitochondria. The reticular epithelial cells (REC) exhibited slender cytoplasmic processes and large, pale nuclei. The abundant cytoplasm contained tonofilaments and some rough endoplasmic reticulum and mitochondria. Small numbers of electron dense granules were also observed in the cytoplasm along with occassiorial multivesicular bodies. Few macrophages were present in the cortical area.

Adrenalectomized rats. Both at light and electron microscope levels thymuses from operated animals exhibited normal morphological features.

DOTC-treated rats. Thymuses from rats fed DOTC-containing diets for 2 weeks showed a partial loss of cortical thymocytes and indistinct corticomedullary junctions. A number of vacuolated REC was observed together with normal appearing REC. There were few macrophages present and very few pyknotic thymocytes. Ultrastructurally the vacuolated REC showed an increase in both nuclear and cytoplasmic densities with vesiculation of the rough endoplasmic reticulum and an accumulation of intracellular vacuoles, some containing amorphous material. Many of the otherwise normal appearing REC showed an increase in the number of secretory droplets present in the distal cytoplasm. The majority of remaining thymocytes had a normal appearance.

With increasing length of exposure to DOTC there was a continued loss of cortical thymocytes. Positive identification of the corticomedullary junction was not possible and the number of vacuolated REC observed was greatly increased. When the animals were returned to a normal diet a weekly examination of the thymuses showed a considerable repopulation with, however, persistance of hypocellular areas and of numerous vacuolated epithelial cells.

Adrenalectoinized and DOTC-treated rats. Morphological changes following oral DOTC treatment were as marked in adrenalectomized rats as in nonoperated animals.

Hydrocortisone treated rats. Animals treated with hydrocortisone showed severe depletion of cortical thymocytes and loss of the corticomedullary junction. No alteration in the appearance and distribution of REC was observed, but macrophages were present in greatly increased numbers. Ultrastructural ex-amination showed that the macrophages contained large lipid droplets within secondary lysosomes.

Reduction of thymic weight was first apparent 48 h after DOTC administration. Alterations in thymocyte activity was apparent prior to the decline in thymic weight loss. Studies on thymocytes obtained from untreated rats and rats 24, 48 and 72 h after commencement of treatment demonstrated a marked decline in both the basal level of DNA synthesizing cells present in the thymus, and the degree of spontaneous in vitro proliferative activity.

When thymocytes were incubated together with tritiated thymidine for 30 min, a progressive decrease in thymidine incorporation was evident. Decrease in thymidine uptake occurred before thymic involution was apparent, and significant difference were apparent 24 h after the first oral intake of DOTC when compared to thymocytes obtained from untreated rats (p<0.05). Mitotic activity was almost entirely absent in thymocytes obtained after two administrations of DOTC (P<0.001), although considerable thymic tissue was still present in the treated rats.

Proliferation of thymocytes obtained from untreated rats continued during a 3 h incubation period, reflecting the spontaneous proliferative capacity of thymocytes when maintained in in vitro cultures. In contrast, DNA synthesis was significantly decreased in cell populations obtained from rats 72 h after commencement of treatment (P<0.001) indicating a marked decline in mitotic activity.

Sera obtained from DOTC-treated rats inhibited the mitogen responsiveness of thymocytes obtained from control rats. The ability of thymocytes to respond to PHA stimulation was significantly reduced when the cells were cultured in the presence of either 2.5 or 5% rat sera obtained from treated animals. The inhibitory effect of serum samples was evident shortly after commencement of DOTC administration, and was greater when sub-optimal concentrations of PHA were used . At this PHA level (1.0 µg/ml), sera obtained 24 h after commencement of DOTC treatment significantly reduced PHA-induced thymocyte blastogenesis (P<0.05) when added to the culture medium at 50%. Sera obtained 48 and 72 h after commencement of treatment caused a highly significant depression of thymocyte responsiveness at both PHA levels. Similar results were obtained with 2.5% sera although reduction in thymocyte proliferation was less marked than at the higher concentration of rat sera. Addition of rat sera obtained from untreated control rats had no inhibitory effect on the thymocyte proliferative response and the level of thymidine incorporation was similar to that obtained under standard culture conditions. Addition of DOTC (7.5 µg/ml) to control sera did not cause any depression of thymocyte proliferation.

Test 1

At post mortem, thymuses from pregnant rats maintained on control diets showed slight thymic involution; however the thymuses from both virgin and pregnant DOTC treated rats were markedly atrophied. Tissue sections of thymuses from post partum control animals apeared normal, with a clear distinction between cortex and medulla. Reticulo-epithelial cells (RECs) were present in both the cortex and medulla and often contained large numbers of non-osmiophillic vacuoles. Virgin animals exposed to DOTC for the same period showed massive thymocyte depletion in the cortical region, the number of thymocytes was also slightly reduced in the medullary region. There was no marked increase in the degree of vacuolation in the RECs. Pregnant animals given DOTC during pregnancy and killed immediately post partum presented a similar picture in terms of thymocyte depletion, however, the degree of vacuolation in the RECs was greatly increased. It would therefore appear that the changes in the thymus occurring during pregnancy are qualitatively, but not quantitatively similar to those observed during DOTC-exposure. In both instances there was evidence of vacuolation in RECs however, the degree of vacuolation observed as well as the number of vacuolated cells was greater in rats exposed during pregnancy. It therefore appears that the changes in endocrine control that occur during pregnancy may exacerbate the effects of DOTC.

Test 2

It was apparent that almost all of the radioactivity was excreted in the faeces by 48 hrs. Nevertheless the presence of radioactivity in the liver and urine indicated that a small proportion of the administered compound was absorbed and possibly metabolised. Furthermore although only a minute amount of label was found to be present in the thymus significantly more was found in the pituitary.

Despite the very specific action DOTC has on rat thymic tissues only a trace of radioactivity was found associated with the organ, it therefore seems unlikely that thymic atrophy is the result of a local DOTC-mediated toxic event. The observation that label was also present in the pituitary lends further support to the postulate that endocrine factors may play a role in DOTC induced thymic atrophy.

Atrophy of Thymus and Thymus-Dependent Lymphoid Tissues in Rats Fed Di-n-Octyltindichloride

In rats fed di-n-octyltindichloride (DOTC) at dietary levels of 0, 50 or 150 mg/kg diet (ppm) a prominent and dose-related decrease of thymus and popliteal lymph node weight was noted.Thymic atrophy progressively increased Already after a 4-day feeding period thymus weights were significantly lower as compared to control animals. Thymus weights of rats fed 50 or 150 ppm DOTC for 4 weeks were only 48% and 16% of the control weights. Histologically, lymphocyte depletion was observed in the thymus and in thymus-dependent areas of the spleen and lymph nodes, whereas in other organs no treatment-related histopathologic changes were noted. Although most of the lymphoid tissue of the thymus had disappeared, signs of cell destruction (karyorrhexis and "starry sky" formation) as seen after treatment with corticosteroids antimetabolites, alkylating agents, and other antitumor compounds were never observed after DOTC treatment. This does not, however, exclude lymphocytotoxicity, as the viability of nucleated cells isolated from thymus and spleen of rats fed 50 or 150 ppm DOTC for 4 weeks was significantly decreased. However, the effect on thymocyte number was much more pronounced than the effect on all viability. Already, after 2 days feeding of DOTC the total number of thymocytcs showed a dose-related decrease but cell viability was unaltered (as measured with the dye exclusion test). Total thymocyte counts progressively diminished to 33% and 6% of the control value at week 4 in animals fed 50 or 150 ppm DOTC, respectively. These data indicate that DOTC primarily induces an inhibition of the division of thymic lymphocytes and secondarily causes cell death.

The total number and viability of spleen and peripheral lymph node cells was less severely decreased by DOTC, than the number and viability of thymus cells. After 4 weeks feeding of 150 ppm DOTC, the numbers of nucleated spleen and peripheral lymph node cells were 75% and 70%, respectively, of the control counts. The total number of peripheral blood lymphocytes was generally unaltered by organoun treatment. Also, the number and viability of bone marrow cells was not decreased by DOTC feeding. Effects of organotin compounds on bone marrow stem cells are further excluded by the spleen colony assay technique with balb/c mice. This experiment was carried out with di-n-butyltin dichloride (DBTC), a compound with effects on lymphoid tissue similar to those observed with DOTC. The numbers of 10-day spleen colonies produced in lethally irradiated recipient mice injected with bone marrow cells of donor mice treated 1 or 3 days before cell transplantation with 0, 2, or 10 mg DBTC/kg intravenously, were essentially the same. In addition, spleen weights of mice reconstituted with bone marrow cells from DBTC-treated and -untreated animals were comparable. Thus, neither the number and viability of bone marrow cells nor the number of colony-forming stem cells was decreased by organotin treatment. These results further support the selective cytotoxicity of DOTC for thymus and thymus-dependent lymphocytes.

A selective lymphocyte depletion in the thymus can also be induced by a stress-related release of glucocorticoids. The selective effects of DOTC on the thymus are not related to stress since:

(1) Thymus weights were as severely decreased in adrenalectomized as in sham-adrenalectomized DOTC-fed rats;

(2) relative adrenal weights were the same in DOTC-fed and control animals;

(3) histologically, no signs of hyperactivity of the adrenal cortex, nor destruction of lymphocytes in the thymic cortex were observed; and

(4) in vitro, DOTC is cytotoxic for rat thymocytes.

Reversibility of Thymus Atrophy

Although DOTC-induced thymus atrophy occurs rapidly and its severity mimics a "chemical thymectomy," the atrophy was completely reversible. A 78% reduction of thymus weight induced by feeding 150 ppm DOTC for 4 weeks was followed by a fast recovery, when the animals were returned to the stock diet. After a rehabilitation period of 2 weeks, thymus weights of DOTC treated animals did not differ significantly from the controls. After 4 weeks thymus weights of treated animals were even higher than the controls, which is considered to be a compensatory reaction as is seen in many healing processes. Eight weeks after treatment thymus weights were the same as the controls. By restriction of food intake in weanling rats for 28 days, they induced a thymus reduction of 81%. But on rehabilitation the thymus weight returned to control values within 16 days. The similarity of the recovery of the thymus after DOTC feeding and nutritional deprivation suggests that the half-life of DOTC may be short.

Intravenous Treatment Study in Rats

After repeated intravenous injections of DOTC a marked thymus atrophy was observed. This atrophy occurred already at doses of 1 and 2 mg/kg, which did not affect other organ systems nor the body weight of the animals. Even a single injection of 1 mg/kg DOTC caused thymus atrophy, which was most pronounced 4 days after treatment. Given by the intravenous route DOTC was severely toxic. Doses of 10 mg/kg body weight produced death in about 50% of the animals (both mice and rats).

Species Differences

Lymphoid atrophy did not occur in guinea pigs, Japanese quail, or chickens. However, after intravenous administration of DOTC in rats and mice, comparable thymus effects were found. So there may be differences in uptake and/or distribution between rats and mice after oral administration. Although a selective organotin-induced lymphoid atrophy could not be established in guinea pigs, weanling animals fed 150 ppm DOTC died within 3 weeks. These animals appeared to be emaciated, showed abdominal edema and enlarged caecums filled with a fluid. Because of the antibacterial activity of dialkyltin compounds, caecal fermentation was disturbed, by which the production of free fatty acids in the caecum was almost completely inhibited Morphologically a severe villous atrophy was observed in the gastrointestinal tract of these animals, which may be related to the cytotoxic activity of DOTC. Japanese quail appeared to be very insensitive to the toxic effects of dialkyltin compounds, since feeding levels up to 600 ppm did not induce any sign of toxicity.

IMMUNE FUNCTION STUDIES AFTER IN VIVO EXPOSURE TO ORGANOTIN COMPOUNDS

Since the thymus and thymus-derived lymphocytes play a central role in the immune system, a number of immune function studies were performed in rats, rnieq and guinea pigs. In the thymus (blood-borne) stem cells migrate into the cortex where, under the stimulatory and perhaps regulatory influence of thymic epithelial cells, cell division and differentiation begin, giving rise to the forming of various subclasses of (thymus-derived) T-lymphocytes. This process starts at an early stage of ontogeny. So, thymectomy of neonates results in a reduced number of lymphocytes a diminished capacity to produce serum antibodies, and failure to reject skin grafts from foreign strains. These animals often die within 3 or 4 months from runting disease,a. Thymic ablation of adult animals is not accompanied by severe disturbances in lymphopoiesis or immune functions. As DOTC causes a severe thymic atrophy suggestive of a "chemical thymectomy," the immune function studies presented here are carried out with animals treated after weaning age as well as exposed during the developmental phase of the immune system (pre and/or postnatal exposure).

It appears that all immune reactions in which T-lymphocytes participate are compromised in the rat. Cell-mediated immunity was depressed in all test systems (delayed type hypersensitivity to tuberculin, skin graft rejection, graft-versus-host reaction, resistance to Listeria monocytogenes infection, lymphocyte transformation by T-cell mitogens). However, the humoral response was impaired with sheep red blood cells (SRBC) a thymus-dependent antigen, but the antibody response to E.coli ( lipopolysacharide (LPS) a thymus-independent antigen was unaffected. The response of lymphocytes from thymus and spleen to the T-cell mitogens phytoheamagglutinin (PHA) and concanavalin A (Con A) was severely depressed, in particular in pups that were exposed postnatally by oral intubation during 3 weeks following birth, whereas the response to the B-cell mitogen LPS was not impaired. From these data, it seems likely that DOTC suppresses various subpopulations of T-lymphocytes without affecting B lymphocytes. This selectivity may be explained by a selective toxic action on lymphocytes in the thymus, resulting in a reduced number and reduced responsiveness of peripheral T-lymphocytes. Also macrophages do not seem to be compromised, since blood monocyte numbers (as precursors of macrophages) and the in vivo phagocytizing capacity of macrophages as measured by the clearance of carbon particles were the same for treated and control animals.

Immune functions of DOTC-fed mice and guinea pigs were not impaired, which is in agreement with the absence of lymphoid atrophy observed in these species. No function studies were performed in mice that were exposed to these compounds by the intravenous route.

A remarkable effect of DOTC, probably not related to the immune system is the increase of endotoxin sensitivity. Weanling rats fed 150 ppm of the organotin compounds for 4 weeks died from an i.v. injection of 100 µg/E.coli LPS whereas the controls died at concentrations of 2500 µg LPS.

IN VITRO STUDIES

A cytotoxic effect of DOTC is demonstrated in suspension cultures of rat thymocytes.

In contrast to the effect on rat thymocytes, DOTC did not reduce rat bone marrow cell survival under the same culture conditions. Number and viability of rat bone marrow cells remained the same when cultured with 0, 5, or 50 µg of DOTC/ml for periods up to 40 hr.

Besides this difference in sensitivity between rat thymus and bone marrow cells, also a difference was found between thymocytes from various species. The viability of human thymocytes was not distinctly decreased, but these cells aggregated in a dose-dependent fashion in the presence of 0.5 and more DOTC per ml medium. Agglutination did not occur when the cells were cultured at low concentrations in a shaking waterbath. But, the ability of these thymocytes to form so-called E-rosettes with SRBC was rapidly reduced indicating that DOTC interferes with lymphocytic receptors for SRBC that are specific for human T-lymphocytes. The number of E-rosettes decreased in a direct proportion to the dose of organotin compounds in the incubation medium. Concentrations as low as 0.5 µg DOTC/ml already decreased the formation of E-rosettes.

Besides the dye exclusion test, which measures cell death, also the effects of various compounds on cell division in mitogen-stimulated as well as unstimulated lymphocyte cultures were studied. In the presence of DOTC, the division of thymus and spleen lymphocytes was dose-relatedly inhibited. At a concentration of 0.5 µg/ml medium DOTC, as well as the other dialkyl compounds tested, induced a complete inhibition of DNA synthesis of rat thymocytes. The viability of spleen and thymus cells was not impaired at these concentrations by the dialkyltin compounds. Therefore we conclude that dialkyltin compounds primarily induce an inhibition of cell proliferation and secondarily cause cell death.

In the lymphocyte transformation test no distinct differences in antiproliferatire activity of the various dialkyltins were observed. So, the differences in lymphocytotoxicity observed after in vivo exposure between the water soluble and water insoluble dialkyltins can not be explained by differences in in vitro activity of these compounds.

Species differences as observed after in vivo exposure to organotin compounds, did not occur in the lymphocyte transformation test, since comparable effects were found on DNA-replication of rat and mouse as well as human thymocytes. This indicates an absence of species differences in organotin sensitivity in vitro. Although, with viability testing, species differences in vitro were noted. This discrepancy can not be explained yet, but indicates that the absence of organotin-induced cell death, as measured with a dye exclusion test, will not exclude a cytotoxic action of these compounds.

The estertin compound bis-ß-carbobutoxyethyltin dichloride, which did not cause lymphoid atrophy in vivo, actively decreased the thymidine uptake of lymphocytes in vitro. However, its hydrolysis product only slightly decreases thymidine incorporation at the maximum concentration of 360 µg per ml medium. Probably, bis-13-carboxyethyltin does not enter lymphocytes. Also other dicarboxylic acids, such as succinic acid and fumaric acid are not able to penetrate cells.

A remarkable although not large difference was noted in the blast transformation test between thymus and bone marrow cells. Complete inhibition of DNA-replication of bone marrow cells occurred at concentrations 5 times higher than with thymus and spleen cells. Also with tumor cell lines inhibition of DNA replication was obtained, but often at higher concentrations than with thymocytes.

Oral Route

DOTC caused a significant decrease in thymus weight at both feeding levels in male and female rats. This was seen as a dose related effect.

At necropsy, a pronounced reduction in size of the thymus was found in all animals fed DOTC.

The most prominent effect found was lymphocyte depletion in lymphoid organs, and it was most pronounced in the thymic cortex of animals fed DOTC. At the 150-ppm level, the cortex was almost completely depleted. Signs of cell destruction, such as karyorrhexis or "starry sky" formation was never observed. Also, lymphocyte depletion was present in the thymus-dependent areas of the spleen and popliteal lymph node (respectively, periarteriolar lymphocyte sheets and paracortical areas). Other treatment-related histopathological changes were not noted.

Other animal species

Growth of guinea pigs on the DOTC diet showed a dose-related decrease. At the 100-ppm level, growth was severely inhibited. One guinea pig of the highest dose group died and the remaining animals were in very poor condition. The general appearance of quail fed DOTC did not differ from that of the controls; body weights were the same in the various groups.

In contrast to rats, weights of lymphoid organ were not affected by DOTC in quail. In guinea pigs, however, thymus weight was significantly decreased at the 100-ppm level and was associated with a strongly decreased body weight. In addition, the relative adrenal weights of these animals were markedly increased from 0.41 ± 0.09 mg/g body weight in the control group to 0.61 ± 0.06 mg/g in the 100-ppm group (p < 0.001). The weights of the liver and kidney did not differ between the test and control groups.

At pathological examination, the guinea pigs fed 100 ppm of DOTC appeared to he emaciated. Two animals showed abdominal edema. The content of the gastrointestinal tract contained fluid. A reduction in size of the thymus was found in six guinea pigs al 100 ppm of DOTC. Histologically, there was marked depletion of lymphocytes in the thymic cortex. At variance with rats, in the cortex "starry sky" appearance was noted; ie. phagocytosis of pycnotic lymphocytes by macrophages. Also, the Hassal corpuscles were conspicuous.

Rats: Recovery experiment

Body weights of DOTC-treated animals were significantly reduced up to 2 weeks after treatment and remained lower than the controls during the whole period. During Week 3, three animals of the DOTC group died. They showed thickened and dilated bile ducts and abdominal edema.

The severe reduction of thymus weight (78%) induced by 150 ppm of DOTC for 4 weeks was followed by fast recovery. After 2 weeks feeding of the stock diet, thymus weights of DOTC-treated animals did not differ significantly from the controls. After 4 weeks, thymus weights of treated animals were higher than the controls. This is considered to be a compensatory reaction as is seen in many healing processes. Eight weeks after treatment thymus weights were the same as the controls.

Intravenous Route

Rats

DOTC was observed to have a strong effect on thymus weight. This is in agreement with the feeding experiment. Thymus atrophy was present at doses of 1 and 2 mg/kg, which did not affect growth or liver and kidney weights. At the 4-mg/kg dose, thymus weight was severely depressed. However, at this dose ncreased kidney weight was noticed. The weights of spleen and adrenals were not affected by this route of administration of DOTC.

At microscopic examination, thymus atrophy, associated with lymphocyte depletion. was observed in animals repeatedly dosed with 1, 2, or 4 mg/kg. Other treatment-related histopathological changes were not noted.

A dose-related reduction of thymus weight. cell number, and cell viability was present in all treatment groups (1, 2, 4, and 8 mg/kg).

Only at the highest dose level was body weight reduced; thymus weight was 24% of the control value, whereas cell number was only 7% of that of the controls.

in Vitro Experiments

The effect of DOTC on rat thymocyte cultures showed decreased cell count and viability at concentrations of 0.012 and 0.12 mM.

In contrast DOTC did not reduce rat bone marrow cell survival under the same culture conditions. Number and viability of rat bone marrow cells were the same when cultured with 0, 5, or 50 µg of DOTC/ml for periods up to 40 hr.

Acute oral dosing of adult female rats with DOTC on 10 consecutive days (Experiment I) resulted in thymic atrophy at all doses and significant suppression of the LP response to both T- and B-cell mitogens at 20 mg/kg/d. The most dramatic suppression was a 66% decrease observed for the response to PHA. Splenic NK cell activity against both YAC-1 and W/Fu targets was unaffected by DOTC at the doses examined. Since no changes in NK activity were observed at any E:T ratio, only the 50:1 data are shown. The primary antibody response to SRBC as measured by the IgM PFC assay was also unaffected at the doses examined.

Exposure to DOTC during d 10-20 of gestation (Experiment II) caused significant increases in the body, spleen, and thymus weights of 6-wk-old offspring born to dams dosed at 50 mg/kg/d. This increase in body and organ weights was observed for both male and female offspring. The LP response of splenocytes from female offspring was significantly (p < .01) lower compared with controls for Con A, PWM, and STM. No decrease in the LP response was observed for male offspring. NK cell activity was unaffected by this treatment.

The offspring in Experiment III were evaluated at 4, 8, and 16 weeks of age. No consistent, significant changes in body or lymphoid organ weights were observed at the 3 ages examined, although differences were observed in female body weights and male spleen weights of 8-week-old offspring nursed by dams exposed to 40 mg/kg/d. No consistent alterations in the LP response were observed for rats at 4 and 16 wk of age, although a significant decrease in the LP response to Con A, PWM, and STM was observed for 8-weeks-old male rats nursed by darns exposed to 40 mg/kg/d. Similarly, no significant differences were observed between control and dosed groups in NK activity or in the IgM PFC response to SRBC, although there was an increase, albeit not significant, in the PFC response for 8-week-old male rats nursed by dams exposed to 40 mg/kg/d.

Maternal pre- and postnatal exposure to DOTC (Experiment IV) caused no observable effects on the immune parameters measured in, their offspring. No significant differences were observed for body and lymphoid organ weights, LP responses, or NK activity in 8-week-old rats born to dams dosed on d 11-20 of gestation and d 2-11 postpartum with DOTC at 20 or 30 mg/kg/d.

In contrast to those experiments in which the darns were dosed with DOTC, exposure of newborn pups to DOTC during the first 3 weeks of life, 3 times per week, caused significant decreases in the LP responses. In Experiment V both male and female littermates were exposed to DOTC at 10 mg/kg-d. At 8 week of age, no differences were observed in body or lymphoid organ weights or in NK activity. However, the LP responses to Con A, PHA, and PWM were significantly (p < .01) lower in both males and females dosed with DOTC compared with controls. The reduction in the PHA response of DOTC-treated rats was more pronounced than Con A and PWM responses (i.e., 75% vs. 64% and 63%, respectively). At 12 weeks of age the LP responses of treated rats were comparable to controls.

In a subsequent experiment, in which neonatal male rats were dosed with DOTC (Experiment VI), significant reductions in the LP response to Con A and PHA at all exposure doses, STM at 10 and 15 mg/kg/d and PWM at 15 mg/kg/d were observed at 7 weeks of age. The PHA response was significantly lower at 10 weeks of age at all exposure doses. NK cell activity was not affected at any age. In both Experiments V and VI, significant reductions in the LP response of splenocytes were observed from 4 to 7 weeks following the last exposure to DOTC. These alterations were observed in the absence of decreases in body or lymphoid organ weights. Analysis of the splenic T-lymphocyte subsets in 7-week old rats in Experiment VI revealed no alteration in the percentage or absolute number of W3/25- and OX8-positive cells between control and 15 mg/kg/d DOTC-dosed rats. (Control rats had 28.5 ± 0.9% W3/25+ and 30.5 ± 1.8% OX8+ cells, and rats dosed at 15 mg/kg/d had 25.6 ± 2.2% W3/25+ and 33.7 ± 1.8% OX8+ cells.) This lack of difference between control and DOTC-treated rats for these two lymphocyte subsets occurred despite significant reduction in the LP response of splenocytes to Con A (67%) and PHA (61%) for DOTC-treated rats. It is interesting to note that, in addition to those observations regarding T-lymphocytes of splenic origin, no consistent change was observed in the LP response to Con A or PHA of thymocytes from 7- and 10-week-old rats exposed to DOTC in Experiment VI.

In order to test the hypothesis that the developing immune system is potentially more susceptible to perturbation by an immunotoxicant than the fully developed immune system, an experiment was conducted in which young adult (8 weeks old) functionally mature rats were dosed with DOTC on a schedule identical to that used in Experiments V and VI. Three days after the last dosing a significant reduction was observed in the thymus weights of rats dosed at 10 and 20 mg/kg/d. No changes in body or spleen weights or in adrenal weights were observed between control and DOTC-dosed rats. The LP response to Con A was reduced at 20 mg/kg/d and to PHA at 10 and 20 mg/kg/d. The LP response to PWM was reduced at 10 and 20 mg/kg/d, albeit significantly only at 10 mg/kg/d. At 4 weeks after the last dosing, however, all parameters tested had returned to control levels. Once again, NK cell activity was not affected by this dosing scheme.

The changes in thymus realted to the changes in gene expression caused by DOTC.

The activation of Nr3c1, also known as GR (glucorticoide receptor), by dioctyltin dichloride causes can explain the adverse effects in the immune system.

Thymic attrophy after 48h, a lterations in thymocyte activity were apparent prior to decline in thymic weight loss

thymic atrophy and weight decrease in thymus

"Thymic atrophy produced by certain organotins, such as triphenyltin, tributyltin, dibutyltin, and dioctyltin compounds, involves a decrease in the number of cortical thymocytes, resulting in reduced thymus weight. With prolonged exposure, T-cell-mediated immune responses are. Loss of thymocytes appears to involve suppression of proliferation of immature thymocytes and, at higher dosages, apoptosis of mature thymocytes. These appear to be direct effects on the thymus as both cytotoxicity and apoptosis have been observed in thymocyte cell cultures exposed to di- or tributyltin . Cytotoxicity of butyltin compounds in thymocyte cultures involves suppression of DNA and protein synthesis (), and also induction of the expression of genes involved in apoptosis, such asnur77, a transcription factor member of the steroid/thyroid hormone receptor superfamily (Gennari et al. 2002b). An early and, possibly, the initiating event of apoptosis is a rise in cytosolic ionized calcium (Ca2+) concentration, caused both by intracellular calcium stores as well as by disruption of calcium transport at the cell membrane. Disruption of the regulation of intracellular calcium levels and, possibly, direct effects on energy metabolism of mitochondria either contributes to or gives rise to the uncontrolled production of reactive oxygen species, release of cytochromecto the cytosol, and the proteolytic and nucleolytic cascade of apoptosis. Modification of the cytoskeleton through Ca2+ -independent disruption of F-actin may also contribute to DNA fragmentation.

Alkyltin compounds, in particular butyltin compounds, suppress T-cell-mediated immune responses,

Including antibody formation against foreign antigens, delayed hypersensitivity reactions, and allograft rejection. These effects appear to result from suppression of proliferation of immature thymocytes (CD4-CD8+) which would, otherwise, differentiate into mature T-cells possessing

the complete antigen-recognizing T-cell receptor complex, resulting in lower numbers of circulating

functional T-cells. Suppression of lymphoproliferative responses to T- and B-cell mitogens also has been demonstrated for triphenyltin. Direct effects on lymphocyte function may also contribute certain aspects of immune suppression observed in animals exposed to butyltin compounds, including decreased natural killer cell activity.In vitro, butyltin compounds suppress cytotoxic activity of human natural killer cells that function in the immune response to tumors and virally-infected cells. Mechanisms for suppression of killer cells appear to involve loss of cell surface receptors important for binding to target cells, possibly secondary to a loss of regulation of intracellular cAMP, and disruption of the transcription of genes for the cytotoxic proteins granzyme B and perforin, which are proteins contained in granules released by NK cells."

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