Stimulation of mouse macrophage antigen presentation by cocaine

Transplantation with Lewis bone marrow induces the reinstatement of cocaine-seeking behavior in male F344 resistant rats

One of the main challenges to understand drug addiction is defining the biological mechanisms that underlie individual differences in recidivism. Studies of these mechanisms have mainly focused on the brain, yet we demonstrate here a significant influence of the peripheral immune system on this phenomenon. Lewis (LEW) and Fischer 344 (F344) rats have different immunological profiles and they display a distinct vulnerability to the reinforcing effects of cocaine, with F344 more resistant to reinstate cocaine-seeking behavior. Bone marrow from male LEW and F344 rats was transferred to male F344 rats (F344/LEW-BM and F344/F344-BM, respectively), and these rats were trained to self-administer cocaine over 21 days. Following extinction, these animals received a sub-threshold primer dose of cocaine to evaluate reinstatement. F344/LEW-BM but not F344/F344-BM rats reinstated cocaine-seeking behavior, in conjunction with changes in their peripheral immune cell populations to a profile that corresponded to that of the LEW donors. After cocaine exposure, higher CD4⁺ T-cells and lower CD4⁺CD25⁺ T-cells levels were observed in F344/LEW-BM rats referred to control, and the splenic expression of Il-17a, Tgf-β, Tlr-2, Tlr-4 and Il-1β was altered in both groups. We propose that peripheral T-cells respond to cocaine, with CD4⁺ T-cells in particular undergoing Th17 polarization and generating long-term memory, these cells releasing mediators that trigger central mechanisms to induce reinstatement after a second encounter. This immune response may explain the high rates of recidivism observed despite long periods of detoxification, shedding light on the mechanisms underlying the vulnerability and resilience of specific individuals, and opening new perspectives for personalized medicine in the treatment of relapse.

Cocaine increases inducible nitric oxide synthase expression in rats: effects of acute and binge administration

The present studies assessed the effects of acute and binge cocaine administration on the in vivo production of inducible nitric oxide synthase in a rat model of endotoxemia. Inducible nitric oxide synthase is a key enzyme involved in host defense and inflammatory responses consequent to infection through its production of nitric oxide. Male Lewis rats received subcutaneous injections of saline or selected doses of cocaine (7.5-30 mg/kg) at the same time as a 50 microg/kg dose of lipopolysaccharide (LPS). Animals in the binge cocaine experiments received two additional injections of cocaine or saline at 2 and 4 h after the initial injections. All animals were sacrificed 6 h after initial drug administration and tissues harvested for determination of iNOS protein levels. Plasma nitrite/nitrate levels were also assayed to assess any treatment-related differences in the degradative by-products of nitric oxide metabolism. Western blot analyses of iNOS expression indicated that both acute and binge cocaine treatment resulted in significant increases in iNOS expression in all tissues assayed. Furthermore, acute and binge cocaine treatment also dose-dependently increased plasma nitrite levels. These data suggest that cocaine may impact resistance to gram-negative infections and severity of these infections via modulation of nitric oxide parameters.

Evidence of increased DNA content of murine thymocytes caused by cocaine

C57BL mice were injected intraperitoneally daily with 10 to 50 mg/kg of cocaine for five days. Four hours after the last injection, the thymuses were removed, and the effects on DNA and protein content of the surviving cells were measured. A dose-dependent increase in DNA content per cell, determined by UV spectrophotometric analysis, and a dose-dependent increase in protein content per cell, as measured using the Bio-Rad reagent, were observed. The increase in DNA content per cell was confirmed by H33258 staining of DNA as well as the diphenylamine assay. These changes were also observed when normal thymocytes were cultured with cocaine. Cell cycle analysis by flow cytometry of cocaine-treated cultures revealed the presence of aneuploid cells with increased DNA content. Fewer cells with aneuploidy were observed in experiments with significant apoptosis. Since both aneuploidy and enhanced apoptosis can be induced by cocaine and the amount of aneuploidy cells varies inversely with the degree of apoptosis, we hypothesize that cocaine causes DNA/chromosome damage, which eventually leads to cell death via the apoptosis pathway.