Differential Effect of Chronic Morphine on Neuronal Degeneration in Male vs. Female Mice.

Opioid abuse in the United States has been increasing at an alarming rate over the past 20 years. Sex differences are documented for the rates of opioid-related overdoses, abuse patterns, and drug-induced physiological effects. In our previous study, we demonstrated that chronic oxycodone administration in young female rats is associated with neurodegeneration in the brain. Males and females are susceptible to neurodegenerative diseases via differing mechanisms. To investigate whether opioid exposure affects males and females differently, we treated young mice with chronic morphine. We observed that females had stronger antinociceptive responses to acute morphine and showed a delayed development of tolerance. Males had a higher basal Bax level in the brain that correlated with a higher number of apoptotic cells. Morphine increased Bax levels in both males and females without affecting the numbers of apoptotic cells. Morphine increased activated caspase 3 in axons and increased the MBP level in plasma only in females, suggesting a demyelination process. Our data suggest that males are protected from demyelination by having a higher basal BDNF level. Altogether, our results suggest that males and females have different molecular signaling underlying their patterns in the development of morphine tolerance and drug-induced neuronal degeneration.

SARS-CoV-2 viral protein Nsp2 stimulates translation under normal and hypoxic conditions.

When viruses like SARS-CoV-2 infect cells, they reprogram the repertoire of cellular and viral transcripts that are being translated to optimize their strategy of replication, often targeting host translation initiation factors, particularly eIF4F complex consisting of eIF4E, eIF4G and eIF4A. A proteomic analysis of SARS-CoV-2/human proteins interaction revealed viral Nsp2 and initiation factor eIF4E2, but a role of Nsp2 in regulating translation is still controversial. HEK293T cells stably expressing Nsp2 were tested for protein synthesis rates of synthetic and endogenous mRNAs known to be translated via cap- or IRES-dependent mechanism under normal and hypoxic conditions. Both cap- and IRES-dependent translation were increased in Nsp2-expressing cells under normal and hypoxic conditions, especially mRNAs that require high levels of eIF4F. This could be exploited by the virus to maintain high translation rates of both viral and cellular proteins, particularly in hypoxic conditions as may arise in SARS-CoV-2 patients with poor lung functioning.

Carbonyl-protein content increases in brain and blood of female rats after chronic oxycodone treatment.

BACKGROUND: Opioids are the most effective drugs commonly prescribed to treat pain. Due to their addictive nature, opioid pain relievers are now second to marijuana, ahead of cocaine with respect to dependence. Ours and other studies suggest potential toxic effects of chronic opioid administration leading to neuronal degeneration. It has been suggested that protein carbonylation may represent a sensitive biomarker of cellular degeneration. To evaluate whether prolonged oxycodone administration is associated with accumulation of protein aggregates that may contribute to neuronal degeneration we measured protein carbonylation levels in brain and also in blood plasma of rats after 30-days of 15 mg/kg daily oxycodone administration. RESULTS: We observed a significant increase in the level of carbonylated proteins in rat brain cortex after 30-days of oxycodone treatment compare to that in water treated animals. Also, oxycodone treated rats demonstrated accumulation of insoluble carbonyl-protein aggregates in blood plasma. CONCLUSIONS: Our data suggests that tests detecting insoluble carbonyl-protein aggregates in blood may serve as an inexpensive and minimally invasive method to monitor neuronal degeneration in patients with a history of chronic opioid use. Such methods could be used to detect toxic side effects of other medications and monitor progression of aging and neurodegenerative diseases.

Chronic oxycodone induces axonal degeneration in rat brain.

BACKGROUND: Chronic opioid therapy for non-malignant pain conditions has significantly increased over the last 15 years. Recently, the correlation between opioid analgesics and alternations in brain structure, such as leukoencephalopathy, axon demyelination, and white matter lesions, has been demonstrated in patients with a history of long-term use of prescription opioids. The exact mechanisms underlying the neurotoxic effect of opioids on the central nervous system are still not fully understood. We investigated the effect of chronic opioids using an animal model in which female rats were orally gavaged with 15 mg/kg of oxycodone every 24 h for 30 days. In addition we tested oxycodone, morphine and DAMGO in breast adenocarcinoma MCF7 cells, which are known to express the µ-opioid receptor. RESULTS: We observed several changes in the white matter of animals treated with oxycodone: deformation of axonal tracks, reduction in size of axonal fascicles, loss of myelin basic protein and accumulation of amyloid precursor protein beta (ß-APP), suggesting axonal damages by chronic oxycodone. Moreover, we demonstrated activation of pro-apoptotic machinery amid suppression of anti-apoptotic signaling in axonal tracks that correlated with activation of biomarkers of the integrated stress response (ISR) in these structures after oxycodone exposure. Using MCF7 cells, we observed induction of the ISR and pro-apoptotic signaling after opioid treatment. We showed that the ISR inhibitor, ISRIB, suppresses opioid-induced Bax and CHOP expression in MCF7 cells. CONCLUSIONS: Altogether, our data suggest that chronic opioid administration may cause neuronal degeneration by activation of the integrated stress response leading to induction of apoptotic signaling in neurons and also by promoting demyelination in CNS.

Chronic oxycodone induces integrated stress response in rat brain.

BACKGROUND: Oxycodone is an opioid that is prescribed to treat multiple types of pain, especially when other opioids are ineffective. Unfortunately, similar to other opioids, repetitive oxycodone administration has the potential to lead to development of analgesic tolerance, withdrawal, and addiction. Studies demonstrate that chronic opioid exposure, including oxycodone, alters gene expression profiles and that these changes contribute to opioid-induced analgesic effect, tolerance and dependence. However, very little is known about opioids altering the translational machinery of the central nervous system. Considering that opioids induce clinically significant levels of hypoxia, increase intracellular Ca(2+) levels, and induce the production of nitric oxide and extracellular glutamate transmission, we hypothesize that opioids also trigger a defensive mechanism called the integrated stress response (ISR). The key event in the ISR activation, regardless of the trigger, is phosphorylation of translation initiation factor 2 alpha (eIF2α), which modulates expression and translational activation of specific mRNAs important for adaptation to stress. To test this hypothesis, we used an animal model in which female rats were orally gavaged with 15 mg/kg of oxycodone every 24 h for 30 days. RESULTS: We demonstrated increased levels of hsp70 and BiP expression as well as phosphorylation of eIF2α in various rat brain areas after oxycodone administration. Polysomal analysis indicated oxycodone-induced translational stimulation of ATF4 and PDGFRα mRNAs, which have previously been shown to depend on the eIF2α kinase activation. Moreover, using breast adenocarcinoma MCF7 cells, which are known to express the µ-opioid receptor, we observed induction of the ISR pathway after one 24-h treatment with oxycodone. CONCLUSIONS: The combined in vivo and in vitro data suggest that prolonged opioid treatment induces the integrated stress response in the central nervous system; it modulates translational machinery in favor of specific mRNA and this may contribute to the drug-induced changes in neuronal plasticity.

Sodium methyldithiocarbamate exerts broad inhibition of cellular signaling and expression of effector molecules of inflammation.

Sodium methyldithiocarbamate (SMD) is one of the most abundantly used conventional pesticides in the United States. At dosages relevant to occupational exposure, it causes major effects on the immune system in mice, including a decreased resistance to sepsis. This lab has identified some of the mechanisms of action of this compound and some of the immunological parameters affected, but the global effects have not previously been assessed. The purpose of the present study was to conduct transcriptomic analysis of the effects of SMD on lipopolysaccharide-induced expression of mediators important in innate immunity and inflammation. The results revealed broad effects on expression of transcription factors in both branches of Toll-like receptor 4 (TLR4) signaling (MyD88 and TRIF). However, TLR3 and interferon signaling pathways were decreased to a greater extent, and assessment of the effects of SMD on polyinosinic polycytidylic acid-induced cytokine and chemokine production revealed that these responses mediated by TLR3 were indeed sensitive to the effects of SMD, with inhibition occurring at lower dosages than required to inhibit responses to other immunological stimuli tested in our previous studies. In the downstream signaling pathways of these TLRs, functional analysis also revealed that NF-κB activation was inhibited by SMD, as indicated by gene expression analysis and a reporter construct in mice. A previously unreported effect on luteinizing hormone and follicle-stimulating hormone pathways was also observed.

Transcriptomic analysis of peritoneal cells in a mouse model of sepsis: confirmatory and novel results in early and late sepsis.

BACKGROUND: The events leading to sepsis start with an invasive infection of a primary organ of the body followed by an overwhelming systemic response. Intra-abdominal infections are the second most common cause of sepsis. Peritoneal fluid is the primary site of infection in these cases. A microarray-based approach was used to study the temporal changes in cells from the peritoneal cavity of septic mice and to identify potential biomarkers and therapeutic targets for this subset of sepsis patients. RESULTS: We conducted microarray analysis of the peritoneal cells of mice infected with a non-pathogenic strain of Escherichia coli. Differentially expressed genes were identified at two early (1 h, 2 h) and one late time point (18 h). A multiplexed bead array analysis was used to confirm protein expression for several cytokines which showed differential expression at different time points based on the microarray data. Gene Ontology based hypothesis testing identified a positive bias of differentially expressed genes associated with cellular development and cell death at 2 h and 18 h respectively. Most differentially expressed genes common to all 3 time points had an immune response related function, consistent with the observation that a few bacteria are still present at 18 h. CONCLUSIONS: Transcriptional regulators like PLAGL2, EBF1, TCF7, KLF10 and SBNO2, previously not described in sepsis, are differentially expressed at early and late time points. Expression pattern for key biomarkers in this study is similar to that reported in human sepsis, indicating the suitability of this model for future studies of sepsis, and the observed differences in gene expression suggest species differences or differences in the response of blood leukocytes and peritoneal leukocytes.

Digoxin immune fab protects endothelial cells from ouabain-induced barrier injury.

PROBLEM Endogenous digitalis-like factors (EDLF) inhibit sodium pump Na(+) /K(+) ATPase activity, and maternal EDLF levels are elevated in preeclampsia (PE). This study determined whether digoxin immune Fab (DIF) could protect endothelial cells (ECs) from EDLF-induced endothelial barrier dysfunction. METHOD OF STUDY ECs were treated with escalating doses of ouabain (a known EDLF) in the presence or absence of DIF. EC barrier integrity was examined by junction protein VE-cadherin and occludin expressions. EC permeability was determined by horseradish-peroxidase (HRP) leakage and transendothelial electrical resistance (TEER). RESULTS EC junction protein VE-cadherin distribution was disrupted in cells treated with ouabain. DIF, but not control IgG Fab fragment, blocked ouabain-induced decreases in VE-cadherin and occludin expressions and prevented ouabain-induced HRP leakage and TEER changes. CONCLUSION DIF protects ECs from ouabain-induced barrier injury, providing evidence of beneficial effects of DIF on EC function and supporting that Na(+) /K(+) ATPase might be a therapeutic target to ameliorate endothelial dysfunction.

Factors derived from preeclamptic placentas perturb polarity protein PARD-3 expression and distribution in endothelial cells.

OBJECTIVE: This study aimed to examine (1) whether polarity protein partitioning defective-3 (PARD-3) was expressed in endothelial cells (ECs) and contributed to endothelial barrier integrity and (2) whether altered PARD-3 expression and distribution were associated with disturbed endothelial junction protein VE-cadherin expression induced by factors derived from preeclamptic (PE) placentas. METHODS: PARD-3 and VE-cadherin expressions were examined by immunofluorescent staining and Western blot in confluent ECs and in ECs treated with normal and PE placental conditioned medium (CM). Protein-protein interactions between PARD-3/VE-cadherin, PARD-3/ atypical protein kinase C (aPKCλ), and VE-cadherin/aPKCλ were examined by immuno-precipitation and immunobloting. RESULTS: Similar to VE-cadherin, PARD-3 is localized at the cell contacts in control ECs. Both PARD-3 and VE-cadherin expressions were markedly reduced in cells treated with PE-CM for 2h, but not in cells treated with normal-CM compared to non-treated controls. Cytosol staining of VE-cadherin and PARD-3 was pronounced in cells after 24h treatment with PE-CM. PARD-3/VE-cadherin and PARD-3/aPKCλ complexes were detected in PE-CM treated cells, but not in untreated control cells and in cells after recovery. In contrast, VE-cadherin/aPKCλ complex was detected in control cells and in cells after recovery, but not in PE-CM treated cells. CONCLUSIONS: Polarity protein PARD-3 is localized at cell contacts. Factors-derived from PE placentas not only interrupt junction protein VE-cadherin distribution, but also perturb polarity protein PARD-3 expression and distribution in ECs. The results of PARD-3/VE-cadherin and PARD-3/aPKCλ complexes formation in cells treated with placental CM suggest that factors-derived from placenta could interfere both junction protein and polarity protein functions in ECs.

Innate immunity and inflammation in sepsis: mechanisms of suppressed host resistance in mice treated with ethanol in a binge-drinking model.

Sepsis is a major cause of mortality worldwide. Acute or chonic ethanol exposure typically suppresses innate immunity and inflammation and increases the risk of mortality in patients with sepsis. The study described here was designed to address the mechanism(s) by which acute ethanol exposure alters the course of sepsis. Ethanol administered to mice shortly before Escherichia coli (injected ip to produce sepsis) decreased production of proinflammatory cytokines and chemokines for several hours. Bacteria in the peritoneal cavity decreased over time in control mice and were mostly cleared by 21 h, but in ethanol-treated mice, bacteria increased over time to more than 2 × 10(8) at 21 h. Killing of bacteria in macrophages and neutrophils was apparently compromised by ethanol, as the percentage of these cells that had cleared phagocytosed bacteria increased over time in control mice but not in ethanol-treated mice. The roles of TLR4, MyD88, and myeloperoxidase (MPO) were evaluated using mutant or knockout mice, and these experiments indicated that mice with hyporesponsive TLR4 survived better than those with normal TLR4. Lack of MyD88 or MPO did not significantly alter survival in the presence or absence of ethanol. Ethanol decreased survival in all groups. This indicates that the antimicrobial activities induced though TLR4 are dispensable for survival but contribute to lethality late in the course of sepsis. Thus, the effects of ethanol responsible for lethal outcome in sepsis are not dependent on inhibition of TLR4 signaling, as we and others had previously suspected.

Ethanol inhibits LPS-induced signaling and modulates cytokine production in peritoneal macrophages in vivo in a model for binge drinking.

BACKGROUND: Previous reports indicate that ethanol, in a binge drinking model in mice, inhibits the production of pro-inflammatory cytokines in vivo. However, the inhibition of signaling through TLR4 has not been investigated in this experimental model in vivo. Considering evidence that signaling can be very different in vitro and in vivo, the present study was conducted to determine if effects of ethanol on TLR4 signaling reported for cells in culture or cells removed from ethanol treated mice and stimulated in culture also occur when ethanol treatment and TLR4 activation occur in vivo. RESULTS: Phosphorylated p38, ERK, and c-Jun (nuclear) were quantified with kits or by western blot using samples taken 15, 30, and 60 min after stimulation of peritoneal macrophages with lipopolysaccharide in vivo. Effects of ethanol were assessed by administering ethanol by gavage at 6 g/kg 30 min before administration of lipopolysaccharide (LPS). Cytokine concentrations in the samples of peritoneal lavage fluid and in serum were determined at 1, 2, and 6 hr after lipopolysaccharide administration. All of these data were used to measure the area under the concentration vs time curve, which provided an indication of the overall effects of ethanol in this system. Ethanol suppressed production of most pro-inflammatory cytokines to a similar degree as it inhibited key TLR4 signaling events. However, NF-kappaB (p65) translocation to the nucleus was not inhibited by ethanol. To determine if NF-kappaB composed of other subunits was inhibited, transgenic mice with a luciferase reporter were used. This revealed a reproducible inhibition of NF-kappaB activity, which is consistent with the observed inhibition of cytokines whose expression is known to be NF-kappaB dependent. CONCLUSION: Overall, the effects of ethanol on signalling in vivo were similar to those reported for in vitro exposure to ethanol and/or lipopolysaccharide. However, inhibition of the activation of NF-kappaB was not detected as translocation of p65 to the nucleus but was detected using transgenic reporter mice. The observation that ethanol given 24 hr before dosing with LPS modulated production of some cytokines indicates a persistent effect which does not require continued presence of ethanol.

The role of stress mediators in modulation of cytokine production by ethanol.

Acute ethanol exposure in humans and in animal models activates the hypothalamic-pituitary-adrenal (HPA) axis and the sympathetic nervous system (SNS); the resultant increases in concentration of neuroendocrine mediators contribute to some of the immunosuppressive effects of ethanol. However, the role of these mediators in the ethanol-induced inhibition of inflammatory responses is not clear. This is complicated by the fact that most inflammatory stimuli also activate the HPA axis and SNS, and it has not been determined if ethanol plus an inflammatory stimulus increases these stress responses. Addressing this issue is the major focus of the study described herein. Complementary approaches were used, including quantitative assessment of the stress response in mice treated with polyinosinic-polycytidylic acid (poly I:C, as an inflammatory stimulus) and inhibition of the production or action of key HPA axis and SNS mediators. Treatment of mice with ethanol shortly before treatment with poly I:C yielded a significant increase in the corticosterone response as compared to the response to poly I:C alone, but the increase was small and not likely sufficient to account for the anti-inflammatory effects of ethanol. Inhibition of catecholamine and glucocorticoid production by adrenalectomy, and inhibition of catecholamine action with a sustained release antagonist (nadalol) supported this conclusion and revealed that "excess" stress responses associated with ethanol treatment is not the mechanism of suppression of pro-inflammatory cytokine production, but stress-induced corticosterone does regulate production of several of these cytokines, which has not previously been reported.

Oxidative stress and sodium methyldithiocarbamate-induced modulation of the macrophage response to lipopolysaccharide in vivo.

Sodium methyldithiocarbamate (SMD) is the third most abundantly used conventional pesticide in the United States, and hundreds of thousands of persons are exposed to this compound or its major breakdown product, methylisothiocyanate, at levels greater than recommended by the Environmental Protection Agency. A previous study suggests three mechanisms of action involved to some degree in the inhibition of inflammation and decreased resistance to infection caused by exposure of mice to the compound. One of these mechanisms is oxidative stress. The purpose of the present study was to confirm that this mechanism is involved in the effects of SMD on cytokine production by peritoneal macrophages and to further characterize its role in altered cytokine production. Results indicated that SMD significantly decreased the intracellular concentration of reduced glutathione (GSH), suggesting oxidative stress. This was further indicated by the upregulation of genes involved in the "response to oxidative stress" as determined by microarray analysis. These effects were associated with the inhibition of lipopolysaccharide (LPS)-induced production of several proinflammatory cytokines. Experimental depletion of GSH with buthionine sulfoximine (BSO) partially prevented the decrease in LPS-induced interleukin (IL)-6 production caused by SMD and completely prevented the decrease in IL-12. In contrast, BSO plus SMD substantially enhanced the production of IL-10. These results along with results from a previous study are consistent with the hypothesis that SMD causes oxidative stress, which contributes to modulation of cytokine production. However, oxidative stress alone cannot explain the increased IL-10 production caused by SMD.

Patterns of immunotoxicity associated with chronic as compared with acute exposure to chemical or physical stressors and their relevance with regard to the role of stress and with regard to immunotoxicity testing.

Previous studies have demonstrated that the stress response induced by some drugs and chemicals contributes in a predictable way to alteration of particular immunological parameters in mice. It has not been determined if mice can become tolerant or habituated with regard to the stress response and consequent immunological effects. Addressing this issue was the purpose of the present study. Mice were dosed daily for 28 days with atrazine, ethanol, propanil, or subjected to restraint, which are known to induce neuroendocrine stress responses and thereby to alter several immunological parameters. On day 29, a blood sample was taken and the spleen was removed for analysis of cellular phenotypes, differential cell counts (for blood), and natural killer (NK) cell activity. Corticosterone concentration at various times after dosing (or restraint) was also measured. Comparison of these results with results from previous studies with a single acute exposure revealed that the corticosterone response was almost completely absent in mice treated with ethanol, reduced in mice treated with restraint and propanil, and for atrazine the response was the same as noted for acute exposure. In most cases, the changes in immunological parameters were consistent with expectations based on these corticosterone responses. However, in a few cases (e.g., NK cell activity), it was clear that there were effects not mediated by stress. These results indicate that the nature of the stressor determines whether mice become tolerant with regard to the stress response and consequent immunological effects. This finding has practical implications for safety testing in mice.

Involvement of three mechanisms in the alteration of cytokine responses by sodium methyldithiocarbamate.

Sodium methyldithiocarbamate (SMD) is the third most abundantly used conventional pesticide in the U.S. We recently reported that it alters the induction of cytokine production mediated though Toll-like receptor (TLR) 4 at relevant dosages in mice. Its chemical properties and evidence from the literature suggest the potential mechanisms of action for this compound. It could either act as a free radical scavenger (by means of its free S(-)group) or promote oxidation by breaking down to form methylisothiocyanate, which can deplete glutathione. It is a potent copper chelator and may affect the availability of copper to a number of copper-dependent enzymes (including some signaling molecules). SMD induces a classical neuroendocrine stress response characterized by elevated serum corticosterone concentrations, which could affect cytokine production. Although each of these mechanisms could potentially contribute to altered cytokine responses, direct evidence is lacking. The present study was conducted to obtain such evidence. The role of redox balance was investigated by pretreating mice with N-acetyl cysteine (NAC), which increases cellular glutathione concentrations, before administration of SMD. NAC exacerbated the SMD-induced suppression of IL-12 and the SMD-induced enhancement of IL-10 in the serum. The role of copper chelation was investigated by comparing the effects of SMD with an equimolar dose to SMD that was administered in the form of a copper chelation complex. Addition of copper significantly decreased the action of SMD on IL-12 production but not on IL-10 production. The role of the stress response was investigated by pretreating mice with antagonists of corticosterone and catecholamines. This treatment partially prevented the action of SMD on IL-10 and IL-12 in the peritoneal fluid. The results suggest that all of the proposed mechanisms have some role in the alteration of cytokine production by SMD.

Greater than additive suppression of TLR3-induced IL-6 responses by administration of dieldrin and atrazine.

Current risk assessment practices do not consider possible synergistic or antagonistic interactions of compounds to which persons may be exposed during the same period of time. This may simply reflect the minimal amount of data available on such interactions, particularly with regard to immunotoxicology. Therefore, this study was conducted to determine if such interactions occur between the most abundantly used conventional pesticide in the United States (atrazine) and a legacy pesticide that is still present in the United States food supply at levels greater than recognized as safe (dieldrin). The results provide evidence that greater than additive effects on signaling and cytokine production occur and suggest that evaluation of common mixtures for such effects may be needed. The compounds both separately and together directly inhibited cytokine production induced by polyinosinic-polycytidylic acid (poly I:C) by macrophages in cell culture. Subcutaneous administration of dieldrin (10-20 mg/kg, daily for 7 d) and atrazine (one dose on Day 7, 100-200 mg/kg) inhibited the production of IL-6 and IL-12 in the peritoneal cavity in a dose-dependent manner, but IL-10 was either increased or not affected. The suppression of IL-6 production and inhibition of NF-kappa B activation was greater than additive when comparing animals given both compounds to those given either compound separately. However, at lower dosages of both compounds (10 mg/kg dieldrin and 50 mg/kg atrazine), the effect was much greater than additive on IL-6 production (adding the individual effects of atrazine and dieldrin on IL-6 production indicates 20% suppression, whereas the combination yields 80% suppression) and essentially additive for inhibition of the activation of c-JUN (a component of the transcription factor, AP-1). Previously published results indicate that atrazine induces a neuroendocrine stress response, and results reported here indicate that dieldrin at 20 mg/kg increases serum corticosterone concentrations, indicating a stress response. This and other possible mechanisms of the greater than additive effects on cytokine production are discussed. Dieldrin and atrazine administered orally (as opposed to subcutaneously as in the other experiments) also effectively suppressed IL-6 production. These results suggest that interactions other than additive effects for compounds with similar mechanisms of action should be considered in risk assessment. Finally, a molecular mechanism for the greater than additive inhibition of IL-6 production is proposed and a mathematical model incorporating that mechanism is presented.

Sodium methyldithiocarbamate inhibits MAP kinase activation through toll-like receptor 4, alters cytokine production by mouse peritoneal macrophages, and suppresses innate immunity.

Sodium methyldithiocarbamate (SMD; trade name, Metam Sodium) is an abundantly used soil fumigant that can cause adverse health effects in humans, including some immunological manifestations. The mechanisms by which SMD acts, and its targets within the immune system are not fully understood. Initial experiments demonstrated that SMD administered by oral gavage substantially decreased IL-12 production and increased IL-10 production induced by lipopolysaccharide in mice. The present study was conducted to further characterize these effects and to evaluate our working hypothesis that the mechanism for these effects involves alteration in signaling through toll-like receptor 4 and that this would suppress innate immunity to infection. SMD decreased the activation of MAP kinases and AP-1 but not NF-kappaB in peritoneal macrophages. The expression of mRNA for IL-1alpha, IL-1beta, IL-18, IFN-gamma, IL-12 p35, IL-12 p40, and macrophage migration inhibitory factor (MIF) was inhibited by SMD, whereas mRNA for IL-10 was increased. SMD increased the IL-10 concentration in the peritoneal cavity and serum and decreased the concentration of IL-12 p40 in the serum, peritoneal cavity, and intracellularly in peritoneal cells (which are >80% macrophages). Similar effects on LPS-induced cytokine production were observed following dermal administration of SMD. The major breakdown product of SMD, methylisothiocyanate (MITC), caused similar effects on cytokine production at dosages as low as 17 mg/kg, a dosage relevant to human exposure levels associated with agricultural use of SMD. Treatment of mice with SMD decreased survival following challenge with non-pathogenic Escherichia coli within 24-48 h, demonstrating suppression of innate immunity.

Sodium methyldithiocarbamate causes thymic atrophy by an indirect mechanism of corticosterone up-regulation.

Sodium methyldithiocarbamate (SMD) is an agricultural fumigant-type pesticide commonly used as a pre-plant biocide. SMD is currently listed by the US Environmental Protection Agency (EPA) as the third most commonly used conventional pesticide. Previously, SMD has been shown to be immunotoxic in mice. Initial immunotoxicological studies indicated that thymocytes are major targets of SMD or its breakdown products in mice. The purpose of the present study was to determine if this effect was mediated by an SMD-induced stress response. The decrease in thymus weight correlated to a decrease in all thymocyte subpopulations. However, as seen in earlier studies, the double positive (CD4(+)CD8(+)) thymocyte subpopulation was more selectively decreased than the other subpopulations. The double negative (CD4(-)CD8(-)) and single positive (CD4(+)CD8(-) or CD4(-)CD8(+)) thymocyte subpopulations decreased in absolute numbers while increasing in percentage of the remaining cells in the thymus after SMD intoxication. In the current study, SMD caused an increase in serum corticosterone, a stress-related hormone. Blocking corticosterone either by 1) adrenalectomy or by 2) chemically blocking synthesis of nascent corticosterone in adrenal-competent animals abrogated the thymocyte atrophy caused by SMD. However, an additional stressor (restraint) did not act additively or synergistically to increase atrophy. Therefore, it is likely that SMD causes thymic atrophy by increasing serum corticosterone.

Differences in IL-10 and IL-12 production patterns and differences in the effects of acute ethanol treatment on macrophages in vivo and in vitro.

Several recent studies have documented that signaling can be fundamentally different in vivo and in vitro. However, studies of signaling and cytokine production by macrophages are often conducted in vitro, without confirmation in vivo. In addition, the direct effects of drugs and chemicals, including ethanol, on these processes are also often investigated in vitro. The purpose of the present study was to compare production of interleukin-6 (IL-6), IL-10, and IL-12 by macrophages in response to two different ligands for toll-like receptors and the effects of acute ethanol exposure on these responses in vivo and in vitro. The macrophage-like cell line RAW 264.7 is also widely used in cytokine and signaling studies, so these cells were also evaluated in this study. The results indicate that IL-6 production and the effects of Ethanol on IL-6 were similar in vivo and in vitro. In contrast, IL-10 was produced to a much greater extent in vitro than in vivo, and IL-12 was often undetectable in vitro even though it was produced at greater concentrations than IL-10 in vivo. To determine the role of altered secretion of preformed IL-10 as compared to new synthesis, cells were treated in vitro with protein and mRNA synthesis inhibitors. The results suggest that preformed IL-10 is released in vivo, but almost all IL-10 secreted in vitro is newly synthesized. Ethanol suppressed IL-12 and enhanced or had no effect on IL-10 production in vivo, whereas it decreased IL-10 production in vitro. These effects were similar at different times and using different concentrations of toll-like receptor ligands. In general, RAW 264.7 cells responded similarly to peritoneal macrophages in vitro. This suggests that results for cytokine studies and probably signaling studies as well that are conducted in vitro should be interpreted with caution and confirmed in vivo, particularly if they involve IL-10 and IL-12.

Modeling and predicting stress-induced immunosuppression in mice using blood parameters.

Previous studies have shown that the area under the corticosterone concentration vs. time curve (AUC) can be used to model and predict the effects of restraint stress and chemical stressors on a variety of immunological parameters in the mouse spleen and thymus. In order to complete a risk assessment parallelogram, similar data are needed with blood as the source of immune system cells, because this is the only tissue routinely available from human subjects. Therefore, studies were conducted using treatments for which the corticosterone AUC values are already known: exogenous corticosterone, restraint, propanil, atrazine, and ethanol. Immunological parameters were measured using peripheral blood from mice treated with a series of dosages of each of these agents. Flow cytometry was used to quantify MHC II, B220, CD4, and CD8 cells. Leukocyte and differential counts were done. Spleen cell number and NK cell activity were evaluated to confirm similarity to previous studies. Immune parameter data from mouse blood indicate that MHC II expression has consistent quantitative relationships to corticosterone AUC values, similar to but less consistent than those observed in the spleen. Other immune parameters tended to have greater variability in the blood than in the spleen. The pattern observed in the spleen in which the chemical stressors generally produced very similar effects as noted for restraint stress (at the same corticosterone AUC values) was not observed for blood leukocytes. Nevertheless, MHC class II expression seems to provide a reasonably consistent indication of stress exposure in blood and spleen.