Changes in nitric oxide, cGMP, and nitrotyrosine concentrations over skin along the meridians in obese subjects.

The purposes of these studies were to quantify the concentrations of total nitrate and nitrite (NO(x)(-)) cyclic guanosine monophosphate (cGMP), and nitrotyrosine over skin surface in normal weight healthy volunteers (n = 64) compared to overweight/obese subjects (n = 54). A semi-circular plastic tube was taped to the skin along acupuncture points (acupoints), meridian line without acupoint (MWOP), and nonmeridian control and filled with a 2-Phenyl-4,4,5,5-tetramethylimidazoline-3-oxide-1-oxyl solution for 20 min. The concentrations of NO(x)(-), cGMP, and nitrotyrosine in the samples were quantified in a blinded fashion using chemiluminescence and enzyme-linked immunosorbent assay, respectively. In normal weight healthy volunteers, NO(x)(-) and cGMP concentrations were consistently increased over the pericardium meridian (PC) 4-7 compared with nonmeridian areas. NO(x)(-) concentration is enhanced over the bladder meridian (BL) 56-57, but cGMP level is similar between the regions. In overweight/obese subjects, NO(x)(-) contents were increased or tended to be elevated over PC and BL regions. cGMP is paradoxically decreased over PC acupoints and nonmeridian control on the forearm but the decreases were blunted along BL regions on the leg. Nitrotyrosine concentrations are markedly elevated (five- to sixfold) over both PC and BL in all areas of overweight/obese subjects. This is the first evidence showing that nitrotyrosine level is tremendously elevated over skin accompanied by paradoxical changes in nitric oxide (NO)-cGMP concentrations over PC skin region in overweight/obese subject. The results suggest that NO-related oxidant inflammation is systemically enhanced while cGMP generation is impaired over PC skin region but not over BL region in obesity.

Responses of nitric oxide-cGMP release in acupuncture point to electroacupuncture in human skin in vivo using dermal microdialysis.

OBJECTIVES: The aim of this study was to examine the release of nitric oxide (NO) and cGMP in response to electroacupuncture (EA) stimulation in the acupuncture point (acupoint), compared to the non-meridian control area. METHODS: Thirty samples of dermal microdialysis data were collected from 24 volunteers at pericardium (PC) 4 and control area. EA was applied to PC 3 by using a 5-V pulse with a duration of 1.0 milliseconds at 10 Hz for 15 minutes. Dialysate samples were continuously collected 20 minutes each before, during, and after EA for two hours. Total nitrite and nitrate (NO(x)(-)) and cGMP in the dialysate were quantified in a blinded fashion. RESULTS: Dialysate NO(x)(-) concentrations were decreased during a 120-minute dialysis in all groups, but reduced NO(x)(-) levels were attenuated predominantly in PC 4 acupoint at 20-40 minutes after EA PC 3. cGMP concentrations were significantly enhanced in acupoint PC 4 by EA PC 3, but not in the non-meridian area. CONCLUSION: We suggest that the attenuation of NO(x)(-) reduction during dialysis reflects an increase in NO release induced by EA stimulation in acupoint and that cGMP mediates the signaling functions of NO to improve local microcirculation, which, at least in part, contributes to the effects of acupuncture.

Blockade of plasmid replication mediated by peptide nucleic acids.

Because peptide nucleic acids (PNAs) are capable of blocking amplification of deoxyribonucleic acid (DNA) by Taq DNA polymerase in vitro, we postulated that PNAs might be able to block replication in vivo. To explore this possibility, we assessed the ability of PNA to specifically block the replication of pUC19 plasmids by allowing a PNA, directed against segments of the Ampr sequence to bind to pUC19 prior to electroporation into Escherichia coli, strain DH10B. Colonies produced by this maneuver not only remained sensitive to ampicillin but were also incapable of blue color production on X-gal-containing media, thus demonstrating true blockade of pUC19 replication, rather than antisense activity. The ability of the PNA to prevent pUC19 replication in these experiments was shown to be dose related. Attempts to prevent the replication of E. coli using a PNA directed against a portion of the lac Z sequence found within the bacterial genome were not uniformly successful. Subsequent experiments showed that the electroporated PNA did not consistently enter a sufficient number of cells for an effect to be demonstrated in the assays used. Nonetheless, this is the first demonstration of in vivo complete replication blockade by a PNA and opens up the potential for new forms of specific antibiosis in both prokaryotic and eukaryotic cells.