Rationale Synthetic psychostimulant abuse, including cathinone-derived 3,4-methylenedioxypyrovalerone (MDPV), continues to increase in many countries. Similar to cocaine but with greater potency, MDPV elicits a transient sympathomimetic response by blocking cellular uptake of dopamine (DA) and norepinephrine (NE)—administration in some users is reported as euphoria-inducing much like cocaine and amphetamine. Pharmacological agents that disrupt excitatory transmission onto midbrain DA-producing neurons, including hypothalamic hypocretin/orexin (hcrt/ox) receptor antagonists, present attractive targets to aide abstinence maintenance by reducing psychostimulant-associated reward and reinforcement. Objective The present study sought to assess the degree to which suvorexant, a dual hcrt/ox receptor antagonist, influences drug-taking as well as ultrasonic vocalizations (USVs) associated with MDPV self-administration. Methods Rats were trained to self-administer MDPV (~0.03 mg/kg/inf, 3-s) for 14 days under a fixed-ratio 1 schedule of reinforcement, and effects of suvorexant (0, 3, 10, 30 mg/kg, i.p.) on drug-taking was assessed. USVs were recorded during a 30-minute pre-lever period as well as during 2-hours of MDPV self-administration. Results We observed that suvorexant modestly suppressed the number of MDPV infusions earned. Notably, we observed that suvorexant reduced 50-kHz USVs associated with pre- and post-lever time-points but did not noticeably alter call type profiles. Upon comparison of the two measures, we observed trending positive associations between suvorexant-induced changes in drug-taking and 50-kHz USVs. Conclusions Results from this exploratory study provide support for: (1) studying how suvorexant may provide benefit to humans with stimulant use disorders, (2) identifying a potential role for orexin transmission in cathinone abuse, and (3) further interrogating the potential utility of rat USVs to predict drug consumption in preclinical models of substance use disorders.
Background Preconditioning of the heart ameliorates doxorubicin (Dox)-induced cardiotoxicity. We tested whether pretreating cardiomyocytes by mitochondrial-targeted antioxidants, mitoquinone (MitoQ) or SKQ1, would provide better protection against Dox than co-treatment. Methods We investigated the dose-response relationship of MitoQ, SKQ1, and vitamin C on Dox-induced damage on H9c2 cardiomyoblasts when drugs were given concurrently with Dox (e.g., co-treatment) or 24 h prior to Dox (e.g., pretreatment). Moreover, their effects on intracellular and mitochondrial oxidative stress were evaluated by 2,7-dichlorofluorescin diacetate and MitoSOX, respectively. Results Dox (0.5–50 μM, n = 6) dose-dependently reduced cell viability. By contrast, co-treatment of MitoQ (0.05–10 μM, n = 6) and SKQ1 (0.05–10 μM, n = 6), but not vitamin C (1–2000 μM, n = 3), significantly improved cell viability only at intermediate doses (0.5–1 μM). MitoQ (1 μM) and SKQ1 (1 μM) significantly increased cell viability to 1.79 ± 0.12 and 1.59 ± 0.08 relative to Dox alone, respectively (both p < 0.05). Interestingly, when given as pretreatment, only higher doses of MitoQ (2.5 μM, n = 9) and SKQ1 (5 μM, n = 7) showed maximal protection and improved cell viability to 2.19 ± 0.13 and 1.65 ± 0.07 relative to Dox alone, respectively (both p < 0.01), which was better than that of co-treatment. Moreover, the protective effects were attributed to the significant reduction in Dox-induced intracellular and mitochondrial oxidative stress. Conclusion The data suggest that MitoQ and SKQ1, but not vitamin C, mitigated DOX-induced damage. Moreover, MitoQ pretreatment showed significantly higher cardioprotection than its co-treatment and SKQ1, which may be due to its better antioxidant effects.
Mephedrone (4-methylmethcathinone (4-MMC)) (MEPH) is a new psychoactive substance (NPS) of the synthetic cathinone class. MEPH has a chiral center and exists as two enantiomers (R-,S-MEPH), yet stereospecific effects of MEPH have not been extensively investigated in preclinical assays. Because significant behavioral and neurochemical differences can exist between enantiomers, probing effects of stereochemistry on biological activity enables separation of adverse and therapeutic effects. Our prior work showed that R-MEPH, relative to S-MEPH, produced greater locomotor activation, place preference, and facilitation of brain reward thresholds in rodents. The present study sought to determine if MEPH enantiomers display stereospecific reward and reinforcement in rat self-administration assays. In Experiment 1, rats were trained to self-administer racemic MEPH (0.50 mg/kg/inf), and dose substitution effects of R-MEPH (0.50 mg/kg/inf) and S-MEPH (0.25, 0.50, 2.00 mg/kg/inf) were examined. In Experiment 2, separate rats were trained to self-administer R-MEPH (0.25, 0.50, 2.00 mg/kg/inf) or S-MEPH (0.25, 0.50, 2.00 mg/kg/inf) and were thereafter evaluated under progressive-ratio access conditions. Within this cohort, 50 kHz ultrasonic vocalizations (USVs) were recorded to measure potential differences in subjective positive affect associated with MEPH enantiomer self-administration. We identified enantiomer- and dose-dependent effects on infusions earned during self-administration following acquisition of racemic MEPH, with greatest infusions under low-effort, fixed-ratio 1 access conditions from low-dose S-MEPH self-administration. When taxed with progressive-ratio access conditions, rats trained to self-administer R-MEPH showed higher break points than those of rats trained to self-administer S-MEPH. Additionally, R-MEPH elicited greatest rates of 50 kHz USVs compared to S-MEPH. Taken together, these data suggest that the R-enantiomer of MEPH is primarily responsible for the rewarding, reinforcing, and motivational properties of racemic MEPH, which increases our understanding of stereospecific preferences pertaining to MEPH abuse.
In diabetics, formation of advanced glycation end (AGE) products has been closely associated with cardiovascular complications. In order to mitigate the injury caused by AGEs, it is critical to understand the influence of the AGE precursor methylglyoxal. Methylglyoxal is a glycation intermediate and it has been found to be elevated in the blood of diabetic patients. The impact of methylglyoxal on cardiac cells is not well elucidated. In this study, the effects of methylglyoxal on H9C2 myoblast cell viability were evaluated. Thereafter, methylglyoxal induced cell injury was investigated by co‐treatment of methylglyoxal with metformin, aminoguanidine hydrochloride, or pyridoxamine dihydrochloride. Cell viability was evaluated after incubation of drugs for 24 hours by measuring absorbance at 450 nm by using tetrazolium to differentiate metabolically active and inactive cells (e.g., CCK‐8 kit). We found that methylglyoxal (1200 μM) significantly reduced cell viability by 72±6% when compared to the untreated control (n=4, p<0.05). By contrast, co‐treatment of metformin (1–80 mM) significantly reduced methylglyoxal‐induced cell injury and increased cell viability to 69% – 122± 6% (n=4, p<0.05 vs. methylglyoxal) when compared to the untreated control. Similarly, aminoguanidine hydrochloride (250–1000 μM) treated cells significantly increased cell viability to 77% – 109±10% (n=4, p<0.05 vs. methylglyoxal) when compared to the untreated control. Additionally, pyridoxamine dihydrochloride (0.1–15 μM, n=4) showed dose‐dependent protection to increase cell viability. Highest pyridoxamine (15 μM) treated cells completely abolished methylglyoxal induced cell injury by increasing cell viability to 99± 4% (p<0.05 vs. methylglyoxal) when compared to the untreated control. However, when the three drugs were washed out from the medium prior to the addition of the methylglyoxal, the protective effects were lost and cell viability was reduced similarly as methylglyoxal (n=1). Administration of all three drugs alone did not affect cell viability after incubation for 24 hours. The preliminary data suggests that metformin, aminoguanidine hydrochloride, or pyridoxamine dihydrochloride, when incubated concurrently with a high concentration of methylglyoxal, protect cardiac cells from methylglyoxal‐induced cell injury. The mechanism underlying the protective effects will be further investigated.Support or Funding InformationThis study was supported by the Center for Chronic Disorders of Aging, the Division of Research and the Department of Bio‐Medical Sciences at Philadelphia College of Osteopathic Medicine.This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.
Protein kinase C beta II (PKCβII) activates polymorphonuclear leukocyte (PMN) superoxide (SO) production via NADPH oxidase (NOX-2) phosphorylation to exacerbate myocardial ischemia/reperfusion (I/R) injury. In prior studies, myristoylation (myr) of PKCβII peptide inhibitor (N-myr-SLNPEWNET; myr-PKCβII-), which disrupts PKCβII translocation/phosphorylation of NOX-2, was shown to dose-dependently attenuate PMN SO release induced by phorbol 12-myristate 13-acetate (PMA), a broad-spectrum PKC agonist. However, the role of myr on the inhibitory effects of myr-PKCβII- has yet to be elucidated. We hypothesized that myr-PKCβII peptide activator (N-myr-SVEIWD; myr-PKCβII+) would augment, myr-PKCβII- would attenuate, and scrambled myr-PKCβII- (N-myr-WNPESLNTE; myr-PKCβII-scram), a control for myr, would not affect PMA-induced PMN SO release compared to unconjugated peptides and nontreated controls. Rat PMNs (5х10 6 ) were incubated for 15 min at 37 o C in the presence/absence of SO dismutase (SOD; 10 μg/mL), unconjugated PKCβII+/-, myr-PKCβII+/-, or myr-PKCβII-scram (all 20 μM). SO release was measured by the change in absorbance at 550 nm via ferricytochrome c reduction after PMA (100 nM) stimulation for 390 sec. Data were analyzed by ANOVA using Student-Newman-Keuls post hoc analysis. Myr-PKCβII- significantly attenuated SO release (0.30±0.02; n=27; p<0.05) compared to nontreated controls (0.46±0.01; n=73), myr-PKCβII+ (0.46±0.03; n=25), unconjugated PKCβII+ (0.43±0.04; n=15), PKCβII- (0.43±0.02; n=22) and myr-PKCβII-scram (0.65±0.04; n=22). SOD (n=8), which rapidly converts SO to H 2 O 2 , significantly reduced absorbance by 94±7%, indicating that absorbance increased mainly due to PMA stimulation. Cell viability (trypan blue exclusion) was similar in all groups (94±2%). Unexpectedly, myr-PKCβII-scram significantly stimulated the highest increase in absorbance compared to all groups (p<0.01). Future studies will determine whether myr-PKCβII-scram augments absorbance by a different mechanism. Results suggest that myr improves myr-PKCβII- delivery compared to unconjugated PKCβII- but does not affect inhibition of PMA-induced PMN SO release. Myr-PKCβII- may thus effectively limit inflammation-induced I/R injury.
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