Mitochondrial Function Influences Expression of Methamphetamine-Induced Motor Sensitization

Repeated methamphetamine use leads to neuronal maladaptations resulting in addictions. Mechanisms that underpin such adaptations have high energy requirements, implicating mitochondria involvement in addiction-related processes. We pharmacologically explored this possibility in methamphetamine self-administering rats. Motor sensitization a readout that is thought to reflect brain maladaptations akin to those occurring in methamphetamine abusing humans. This was assessed to determine (i) if a short access self-administration protocol results in the expression of motor sensitization, (iii) if and when, mitochondrial function is critical for protracted maintenance and (iii) whether drug contingency influences motor sensitization. Rats self-administered iv methamphetamine for 3 hours per day for 14 days. Those with iv cannula that failed patency were redeployed as non-contingent methamphetamine-matched animals. At three different times during forced abstinence, mitochondrial function was impaired with a low dose of the toxin, rotenone (1mg/kg/day) via a osmotic minipump. Motor sensitization was determined during an acute treatment of methamphetamine (1.25mg/kg sc) on abstinence day 62. Methamphetamine self-administration was sufficient to induce motor sensitization. Rotenone administration prevented the expression of sensitization, but the profile depended on abstinence time exposure. Drug contingency also influenced sensitization profiles. Mitochondrial function underpins neuronal plasticity associated with maintenance of motor sensitization induced by methamphetamine self-administration.

COX-2-derived prostaglandins as mediators of the deleterious effects of nicotine in chronic kidney disease

Tobacco smoking has been identified as a risk factor in the progression of chronic kidney disease (CKD). In previous studies, we showed that nicotine induces cyclooxygenase (COX)-2 expression in vivo and in vitro and that the administration of nicotine in vivo worsens the severity of renal injury in a model of subtotal renal ablation. In the present study, we tested the role of COX-2-derived prostaglandins on the deleterious effects of nicotine in CKD. Sham and 5/6 nephrectomy (5/6Nx) rats received tap water or nicotine (100 μg/mL) in the drinking water for 12 wk. Additional groups also systemically received the COX-2 inhibitor NS-398 (1.5 mg·kg−1·day−1 via osmotic minipump). The administration of nicotine worsened renal injury and proteinuria in 5/6Nx rats and increased proteinuria in sham rats. 5/6Nx rats had increased cortical production of the prostaglandins PGE2, PGI2, PGD2, and PGF2α and of thromboxane A2. In these rats, nicotine reduced the production of all prostaglandins examined except thromboxane A2. Treatment with the COX-2 inhibitor NS-398 resulted in complete inhibition of all prostaglandins studied and ameliorated renal injury and proteinuria in 5/6Nx rats on nicotine but not in 5/6 Nx rats on tap water. Nicotine also reduced the expression of megalin in all groups examined, and this was partially prevented by COX-2 inhibition. In the present study, we showed that in CKD, nicotine worsens renal injury at least in part by producing an imbalance in the production of prostaglandins. This imbalance in the production of prostaglandins likely plays a role in the deleterious effects of smoking on the progression of CKD.

Anti-neuroinflammation ameliorates systemic inflammation-induced mitochondrial DNA impairment in the nucleus of the solitary tract and cardiovascular reflex dysfunction

Background Decreased heart rate variability (HRV) leads to cardiovascular diseases and increased mortality in clinical studies. However, the underlying mechanisms are still inconclusive. Systemic inflammation-induced neuroinflammation is known to impair the autonomic center of cardiovascular regulation. The dynamic stability of blood pressure and heart rate (HR) is regulated by modulation of the reciprocal responses of sympathetic and parasympathetic tone by the baroreflex, which is controlled by the nucleus of the solitary tract (NTS). Methods Systemic inflammation was induced by E. coli lipopolysaccharide (LPS, 1.2 mg/kg/day, 7 days) peritoneal infusion via an osmotic minipump in normotensive Sprague-Dawley rats. Systolic blood pressure (SBP) and HR were measured by femoral artery cannulation and recorded on a polygraph under anesthesia. The low-frequency (LF; 0.25–0.8 Hz) and high-frequency (HF; 0.8–2.4 Hz) components of SBP were adopted as the indices for sympathetic vasomotor tone and parasympathetic vasomotor tone, while the baroreflex effectiveness index (BEI) was adopted from the analysis of SBP and pulse interval (PI). The plasma levels of proinflammatory cytokines and mitochondrial DNA (mtDNA) oxidative damage were analyzed by ELISA. Protein expression was evaluated by Western blot. The distribution of oxidative mtDNA was probed by immunofluorescence. Pharmacological agents were delivered via infusion into the cisterna magna with an osmotic minipump. Results The suppression of baroreflex sensitivity was concurrent with increased SBP and decreased HR. Neuroinflammatory factors, including TNF-α, CD11b, and Iba-1, were detected in the NTS of the LPS group. Moreover, indices of mtDNA damage, including 8-OHdG and γ-H2AX, were significantly increased in neuronal mitochondria. Pentoxifylline or minocycline intracisternal (IC) infusion effectively prevented mtDNA damage, suggesting that cytokine and microglial activation contributed to mtDNA damage. Synchronically, baroreflex sensitivity was effectively protected, and the elevated blood pressure was significantly relieved. In addition, the mtDNA repair mechanism was significantly enhanced by pentoxifylline or minocycline. Conclusion These results suggest that neuronal mtDNA damage in the NTS induced by neuroinflammation could be the core factor in deteriorating baroreflex desensitization and subsequent cardiovascular dysfunction. Therefore, the enhancement of base excision repair (BER) signaling in mitochondria could be a potential therapeutic strategy for cardiovascular reflex dysregulation.

Abstract P288: Systemic Administration of an Angiotensin Type-2 Receptor Agonist Decreases Renal Regulatory T Cells

There is increasing evidence supporting a critical role of the immune system in the development of hypertension. Our lab has previously reported sex differences in the renal T cell profile in both Spontaneously Hypertensive Rats (SHR) and Angiotensin II (Ang II) models of hypertension, with females having more anti-inflammatory regulatory T cells (Tregs) than males. Ang II has a well-defined role in the activation of pro-inflammatory T cells in hypertension via the angiotensin type-1 receptor (AT1R). Less is known about the role of the angiotensin type-2 receptor (AT2R) in the regulation of immune cells, although the AT2R has been shown to be cardioprotective and AT2R expression is greater in females than males. Based on the potential anti-hypertensive role of AT2Rs, we hypothesized that administration of an AT2R agonist, Compound 21 (C21), would increase renal Tregs, and this increase would be greater in females due to greater AT2R expression. Male and female SHR (10 weeks of age, n=3-4) were implanted with telemetry units for continuous monitoring of mean arterial pressure (MAP). Following 10 days of recovery, baseline MAP was recorded for 5 days. Rats were then divided into the following treatment groups: surgical controls, low dose C21 (150 ng/kg/min, sc by osmotic minipump), high dose C21 (300 ng/kg/min, sc by osmotic minipump). Kidneys were harvested after 2 weeks of treatment and flow cytometry was performed on whole kidney homogenates. MAP was not altered by C21 treatment in males (137±4 vs 134±4 vs 134±4 mmHg; n.s.) or females (128±2 vs 136±5 vs 134±4 mmHg; n.s.). Interestingly, despite having no effect on MAP, there was a significant decrease in renal CD3 + CD4 + FoxP3 + Tregs in females following both low and high doses of C21 (data expressed as % CD3 + CD4 + cells: 6±0.6 vs 3±0.6 vs 3.5±1.3 %, respectively; p=0.02). Tregs decrease in males following the high dose of C21 only (data expressed as % CD3 + CD4 + cells: 3.3±0.3 vs 3.3±0.5 vs 1.7±0.7 %, respectively; p=0.05). Total CD3 + T cells, CD3 + CD4 + T cells, and Th17 cells were not altered by C21 treatment. In conclusion, AT2R activation suppresses renal Tregs, and females are more sensitive than males. These data suggest a novel role for AT2R regulation in the kidney in hypertension.

Evaluating the control: minipump implantation and breathing behavior in the neonatal rat

We evaluated genioglossus (GG) gross motoneuron morphology, electromyographic (EMG) activities, and respiratory patterning in rat pups allowed to develop without interference (unexposed) and pups born to dams subjected to osmotic minipump implantation in utero (saline-exposed). In experiment 1, 48 Sprague-Dawley rat pups (Charles-River Laboratories), ages postnatal day 7 (P7) through postnatal day 10 (P10), were drawn from two experimental groups, saline-exposed ( n = 24) and unexposed ( n = 24), and studied on P7, P8, P9, or P10. Pups in both groups were sedated (Inactin hydrate, 70 mg/kg), and fine-wire electrodes were inserted into the GG muscle of the tongue and intercostal muscles to record EMG activities during breathing in air and at three levels of normoxic hypercapnia [inspired CO2 fraction (FiCO2): 0.03, 0.06, and 0.09]. Using this approach, we assessed breathing frequency, heart rate, apnea type, respiratory event types, and respiratory stability. In experiment 2, 16 rat pups were drawn from the same experimental groups, saline-exposed ( n = 9) and unexposed ( n = 7), and used in motoneuron-labeling studies. In these pups a retrograde dye was injected into the GG muscle, and the brain stems were subsequently harvested and sliced. Labeled GG motoneurons were identified with microscopy, impaled, and filled with Lucifer yellow. Double-labeled motoneurons were reconstructed, and the number of primary projections and soma volumes were calculated. Whereas pups in each group exhibited the same number ( P = 0.226) and duration ( P = 0.093) of respiratory event types and comparable motoneuron morphologies, pups in the implant group exhibited more central apneas and respiratory instability relative to pups allowed to develop without interference.

Fluoxetine Dose and Administration Method Differentially Affect Hippocampal Plasticity in Adult Female Rats

Selective serotonin reuptake inhibitor medications are one of the most common treatments for mood disorders. In humans, these medications are taken orally, usually once per day. Unfortunately, administration of antidepressant medications in rodent models is often through injection, oral gavage, or minipump implant, all relatively stressful procedures. The aim of the present study was to investigate how administration of the commonly used SSRI, fluoxetine, via a wafer cookie, compares to fluoxetine administration using an osmotic minipump, with regards to serum drug levels and hippocampal plasticity. For this experiment, adult female Sprague-Dawley rats were divided over the two administration methods: (1) cookie and (2) osmotic minipump and three fluoxetine treatment doses: 0, 5, or 10 mg/kg/day. Results show that a fluoxetine dose of 5 mg/kg/day, but not 10 mg/kg/day, results in comparable serum levels of fluoxetine and its active metabolite norfluoxetine between the two administration methods. Furthermore, minipump administration of fluoxetine resulted in higher levels of cell proliferation in the granule cell layer (GCL) at a 5 mg dose compared to a 10 mg dose. Synaptophysin expression in the GCL, but not CA3, was significantly lower after fluoxetine treatment, regardless of administration method. These data suggest that the administration method and dose of fluoxetine can differentially affect hippocampal plasticity in the adult female rat.

Abstract 493: Impact of Renal Vasoconstriction on the Relationship Between Blood Pressure and Renal Injury in Angiotensin II-induced Hypertensive Rats

Ang II is thought to play a prominent role in the development of hypertension-induced renal disease via BP dependent and independent pathways; however the quantitative relationships between BP and renal injury have not been rigorously examined in Ang II-induced hypertension. The major goals of the present study were to assess: 1) the relationship between BP and renal injury in rats with hypertension induced by Ang II vs. renal mass reduction (RMR) and 2) the pressure-flow relationships in conscious Ang II-infused rats. One group of male Sprague-Dawley rats (Charles River) were implanted with a BP radiotransmitter and 10 days later administered Ang II (n=12; 500 ng/kg/min via osmotic minipump) or subjected to 3/4 RMR via right uninephrectomy + infarction of ∼ 1/2 of the left kidney (RKI, n=5). BP was measured continuously and kidneys were perfused fixed at 6 weeks for the assessment of renal injury. In a separate experiment, MAP and RBF (Transonic) were measured in conscious chronically instrumented rats. After recovery from surgery (∼7 days), baseline MAP and RBF were assessed (∼4 hours @ 200 Hz) on 2 consecutive days. Subsequently, rats were administered Ang II (n=6; 500 ng/kg/min) or saline (n=7; sham) via osmotic minipump and MAP and RBF were again assessed every 2-3 days for 10 days. Despite a higher average systolic BP over 6 weeks in Ang II (174±3 mmHg) vs. RKI (165±6 mmHg) rats, glomerulosclerosis (GS) was higher (p<0.05) in RKI (15±7% out of 100 glomeruli) vs. Ang II (6±1% out of 100 glomeruli) rats. Moreover, the slope of the relationship between BP and %GS (Δ%GS/ΔmmHg) was greater in RKI vs. Ang II rats. Both MAP (98±2 vs. 99±3 mmHg) and RBF (8.1±1vs. 8.2±1 ml/min) were similar at baseline in Ang II and sham rats, respectively. MAP was elevated by day 3 (123±6 mmHg) and further increased to 157±5 mmHg by day 10 in Ang II rats. Conversely, RBF was decreased at day 3 (6.6±0.6 ml/min) and the vasoconstriction persisted over the experimental protocol as RBF further decreased to 5.6±0.7 ml/min at day 10 in Ang II rats. In conclusion, Ang II-induced hypertension is associated with a diminished susceptibility to renal injury as compared to rats with RMR likely due, in part, to the AngII-induced vasoconstriction, which reduces BP transmission to the renal microvasculature.

Renal Inhibition of Heme Oxygenase-1 Increases Blood Pressure in Angiotensin II-Dependent Hypertension

The goal of this study was to test the hypothesis that renal medullary heme oxygenase (HO) acts as a buffer against Ang-II dependent hypertension. To test this hypothesis, renal medullary HO activity was blocked using QC-13, an imidazole-dioxolane HO-1 inhibitor, or SnMP, a classical porphyrin based HO inhibitor. HO inhibitors were infused via IRMI catheters throughout the study starting 3 days prior to implantation of an osmotic minipump which delivered Ang II or saline vehicle. MAP was increased by Ang II infusion and further increased by IRMI infusion of QC-13 or SnMP. MAP averaged113±3,120±7,141±2,153±2, and154±3 mmHg in vehicle, vehicle + IRMI QC-13, Ang II, Ang II + IRMI QC-13, and Ang II + IRMI SnMP treated mice, respectively (n=6). Inhibition of renal medullary HO activity with QC-13 in Ang II infused mice was also associated with a significant increase in superoxide production as well as significant decreases in antioxidant enzymes catalase and MnSOD. These results demonstrate that renal inhibition of HO exacerbates Ang II dependent hypertension through a mechanism which is associated with increases in superoxide production and decreases in antioxidant enzymes.