Are Temporal Differences in GDNF and NOS Isoform Induction Contributors to Neurodegeneration? A Fluorescence Microscopy-Based Study.

BACKGROUND: Specific factors in Parkinson's disease have become targets as to their protective and degenerative effects. We have demonstrated that cytokines and PD-CSF detrimentally affect microglia and astrocyte growth. While glial cell-derived neurotrophic factor (GDNF) has been recognized as a possible neuron-rescue agent, nitric oxide synthase (NOS) has been implicated in neurodegenerative processes. OBJECTIVE: To demonstrate that glial cell activation, cytokine production, and NOS induction, play an intimate role in the loss of dopaminergic signaling, via mechanisms that are a result of inflammation and inflammatory stimuli. METHODS: Study animals were sacrificed following endotoxin treatment and tissue sections were harvested and probed for GDNF and NOS isomers by fluorescence deconvolution microscopy. Fluorescence was mapped and quantified for each probe. RESULTS: An immune cell influx into 'vulnerable' areas of the brain was seen, and three NOS isomers, inducible (iNOS), neuronal (nNOS) and endothelial (eNOS), were synthesized in the brains, a finding which suggests that each isomer has a role in neurodegeneration. eNOS was found associated with blood vessels, while iNOS was associated with glial and matrix cells and nNOS was located with both glia and neurons. Following endotoxin treatment, serum levels of nitric oxide were higher at 6-8 hours, while tissue levels of NOS were elevated for much longer. Thus, induction of NOS occurred earlier than the induction of GDNF. CONCLUSION: Our findings suggest that the protective abilities of GDNF to combat neural destruction are not available rapidly enough, and do not remain at sufficiently high levels long enough to assert its protective effects. (250).

Active hexose correlated compound modulates LPS-induced hypotension and gut injury in rats.

We hypothesized that AHCC; (Amino UP Chemical Co., Ltd., Sapporo, Japan), a mushroom mycelium extract obtained from liquid culture of Lentinula edodes, restores immune function in LPS-induced inflammation in the gut, especially when the nitric oxide signaling pathway is impaired. This is the first inter-disciplinary proposal to identify molecular mechanisms involved in LPS-induced immune dysfunction in the gut in conscious animals treated or non-treated with AHCC, a promoter of immune support. Specifically, we have tested the effects of AHCC on LPS-induced deleterious effects on blood pressure and gut injury in conscious rats. The time course of biological markers of innate/acquired immune responses, and inflammation/oxidative stress is fully described in the present manuscript. Rats were randomly assigned into 3 groups (N=6 per group). Group 1 received 10% of AHCC in drinking water for 5days; Group 2 received lipopolysaccharide (LPS; Escherichia coli 0111:B4 purchased from Sigma) only at 20mg/kg IV; Group 3 received combined treatments (AHCC + LPS). LPS was administered at 20mg/kg IV, 5days following AHCC treatment. We have demonstrated that AHCC decreased the LPS-deleterious effects of blood pressure and also decreased inflammatory markers e.g., cytokines, nitric oxide and edema formation. Finally, AHCC diminished lymphocyte infiltration, restoring gut architecture. Because AHCC was administered prior to LPS, our results indicate the potential impact of AHCC's prophylactic effects on LPS inflammation. Consequently, additional experiments are warrant to assess its therapeutic effects in sepsis-induced inflammation.

Lactoferrin moderates LPS-induced hypotensive response and gut injury in rats.

Hypotension is a physiologic state of low blood pressure, the causes of which range from dehydration to underlying serious medical disorders. The aim of this study was to assess the utility of lactoferrin (LF), a natural immunomodulator, to restrain LPS-induced hypotension in rats. LF has previously demonstrated a role in mediation of immune responses, including control of inflammatory cytokine production during acute inflammation. Rats were administered with LF by gavage at 1h or 18 h prior to LPS injections. Heart rate (HR) and mean arterial blood pressure (MAP) were continuously recorded post LPS administration for 6 h. Simultaneously to hemodynamic measurements, serum was examined for TNF-α, IL-6, and TGF-ß production. At termination, the proximal duodenum was subjected to histopathological analysis. LF administered at 1h prior to LPS protected rats from the LPS-induced hypotension. The protective effect on MAP was also apparent when LF was administered as a pretreatment 18 h prior to LPS challenge, although the effect was lessened. For all groups, LF pretreatment led to a minor, but insignificant, improvement in HR post LPS administration. In addition, when rats were given LF 1 h before LPS, they showed a significant decrease in serum TNF-α and IL-6 production. LF did not affect the production level of serum TGF-ß. Of high importance, LF was able to confer histo-pathological protection of intestinal tissue post LPS administration, for both the 1h and 18 h LF pretreatment groups. These studies indicate a potential for clinical utility of LF to control hypotension.

Distribution of NOS isoforms in a porcine endotoxin shock model.

Sepsis is a major cause of morbidity and mortality. NO, an endogenous vasodilator, has been associated with the hypotension, catecholamine hyporesponsiveness, and myocardial depression of septic shock. Although iNOS is thought to be responsible for the hypotension and loss of vascular tone occurring several hours after endotoxin administration, little is known on the effects of constitutive eNOS on LPS-induced organ dysfunction. This study assessed the distribution of eNOS and iNOS in various vascular beds in conscious pigs challenged with LPS. Cardiac and regional hemodynamic parameters were recorded over 8 h in the presence and absence of aminoguanidine, a rather selective inhibitor of iNOS activity, and N-methyl-L-arginine, a nonspecific NOS inhibitor. Our data show that LPS-induced cardiac depression was associated with coronary, renal, and mesenteric vasoconstrictions and a hepatic vasodilatation. LPS also induced increases in eNOS in the heart and lungs, whereas iNOS was mostly detected in the liver. Nitrotyrosine formation was mainly detected in the lungs, with traces in the kidney, liver, and gut. Accordingly, our results suggest that the early decrease in blood pressure and cardiac depression are likely due to activated eNOS, whereas both isoforms are involved in the hepatic vasodilation. In contrast, carotid, coronary, mesenteric, and renal vasoconstrictions were significant at 5 and/ or 6 h after LPS infusion, suggesting that NO is not the primary mediator, facilitating and/or unmasking the release of vasoconstrictor mediators. Consequently, developing newer tissue- or isoform-specific NOS inhibitors can lead to novel therapeutic agents in septic shock.

NOS inhibitors exhibit antinociceptive properties in the rat formalin test.

PURPOSE: To assess the systemic and nociceptive effects of nitric oxide synthase (NOS) inhibitors in the modulation of acute pain in rats subjected to the formalin test. METHODS: Formalin 5% was injected in the hind paw in the presence and absence of NOS inhibitors (e.g., 7-nitro indazole, N-nitro-L-arginine and aminoguanidine). Catheters were chronically implanted to continuously record mean arterial blood pressure (MAP) and heart rate (HR). MAP, HR and paw lifting time were recorded at control and every five minutes for 35 min following formalin and NOS inhibitors. RESULTS: Formalin injected into the rat hind paw induced a biphasic nociceptive behaviour: an initial acute phase (phase 1: during zero to five minutes after the formalin injection) followed by a prolonged tonic response (phase 2: beginning about ten minutes after the formalin injection). Aminoguanidine, an inhibitor of the inducible NOS and 7-nitro indazole, an inhibitor of the neuronal NOS, did not affect phase 1, whereas N-nitro-L-arginine, a non-selective NOS inhibitor decreased it (49%). All three NOS inhibitors diminished nociceptive behaviours during phase 2. L-arginine reversed antinociceptive effects of N-nitro-L-arginine in phase 1 and in phase 2. Pressor effects induced by formalin in phase 1 were abolished following all three NOS inhibitors. During phase 2, formalin-induced pressor effects remained unaffected by N-nitro-L-arginine and aminoguanidine but were inhibited by 7-nitro indazole. CONCLUSION: Our data demonstrate that NO is predominantly generated by vascular endothelial NOS in phase 1 and phase 2, whereas the neuronal NOS and the inducible NOS exhibit antinociceptive effects through a non-NO related pathway in phases 1 and 2 in rats subjected to the formalin test.