Direct detection of tissue nitric oxide in septic mice

A Review of Low-Frequency EPR Technology for the Measurement of Brain pO2 and Oxidative Stress

EPR can uniquely measure paramagnetic species. Although commercial EPR was introduced in 1950s, the early studies were mostly restricted to chemicals in solution or cellular experiments using X-band EPR equipment. Due to its limited penetration (<1 mm), experiments with living animals were almost impossible. To overcome these difficulties, Swartz group, along with several other leaders in field, pioneered the technology of low frequency EPR (e.g., L-band, 1-2 GHz). The development of low frequency EPR and the associated probes have dramatically expanded the application of EPR technology into the biomedical research field, providing answers to important scientific questions by measuring specific parameters that are impossible or very difficult to obtain by other approaches. In this review, which is aimed at highlighting the seminal contribution from Swartz group over the last several decades, we will focus on the development of EPR technology that was designed to deal with the potential challenges arising from conducting EPR spectroscopy in living animals. The second half of the review will be concentrated on the application of low frequency EPR in measuring cerebral tissue pO₂ changes and oxidative stress in various physiological and pathophysiological conditions in the brain of animal disease models.

Nitrosyl heme production compared in endotoxemic and hemorrhagic shock

We compared nitric oxide production and nitrosyl hemoglobin steady state concentrations during the early phases of endotoxemic and hemorrhagic shock of equivalent severity. Sprague-Dawley rats were randomly assigned to (1) sham-operated control, (2) hemorrhage, and (3) intravenous endotoxin. Electron paramagnetic resonance spectroscopy was used to measure NO in the vasculature (binding to hemoglobin) and in the liver (binding to cytochrome P450). Despite similar changes in cardiorespiratory variables and identical microvascular pO(2), nitrosyl hemoglobin concentrations were significantly higher in endotoxemic rats than in rats in hemorrhagic shock, suggesting increased rates of NO production. A substantial venous minus arterial concentration gradient was observed for nitrosyl hemoglobin. This increased in line with the plasma total nitrite + nitrate concentration. Nitrosyl hemoglobin formation is likely to occur predominantly in the venous pool, suggesting that removal of NO from hemoglobin in the presence of oxygen may be faster than previously thought. In the liver, an increase in intracellular heme-NO complexes was detected in endotoxemic rats compared with rats in hemorrhagic shock; this was associated with increased reduction of the mitochondrial respiratory chain and is suggestive of NO inhibition of mitochondrial respiration.

Diethyldithiocarbamate-induced cytotoxicity and apoptosis in leukemia cell lines

Diethyldithiocarbamate (DDTC) has been shown to induce cytotoxicity in several different systems. We examined whether the DDTC-induced cytotoxicity was via apoptosis, or in relation to intracellular glutathione (GSH) in various murine and human leukemia cell lines. The cells most sensitive to DDTC-induced cytotoxicity were P388 lymphoid neoplasma cells and NALM-6, a B cell line of acute lymphocytic leukemia (ALL). The next level of susceptible cells included J774.1, having a macrophage function, HL-60 premyelocytic leukemia cells, MOLT-4, an acute lymphoblastic leukemia cell, and Jurkat, a T-cell leukemia. U937 (expressing many monocyte-like characteristics), K562 erythroleukemia and K562/DXR (a multidrug-resistant clone derived from K562) were almost unaffected by DDTC. P388 was also highly susceptible to H(2)O(2), a most useful exogenous reactive oxygen species generator, and was lower in intracellular total GSH content than other leukemia cells. DDTC-induced cytotoxicity was closely related to intracellular GSH, but the level of cellular GSH did not always correlate with H(2)O(2)-induced cytotoxicity in this experiment. K562 had a higher intracellular total GSH content and showed lower susceptibility to DDTC and H(2)O(2), but with the combination of DDTC and DL-buthionine-(S,R)-sulfoximine (BSO), cytotoxicity increased significantly. The ratio of GSH/GSSG in P388 was reduced by DDTC or H(2)O(2). H(2)O(2)-induced cytotoxicity was completely blocked by catalase (CAT), while it was enhanced by superoxide dismutase (SOD). CAT or SOD did not affect DDTC-induced cytotoxicity. N-Acetylcysteine (NAC: 1 mM), a vanguard substance of GSH, and aurintricarboxylic acid (ATA: 100 microM), an endonuclease inhibitor, ameliorated DDTC-induced cytotoxicity and apoptosis. In conclusion, we suggest that DDTC-induced cytotoxicity was via an oxidative shift in the intracellular redox state, and accompanied the activation of endonuclease through apoptosis in leukemia cell lines.

Nitric oxide synthase inhibitors affect nitric oxide synthesis in normoxic but not in ischemic organs during intestinal ischemia and early reperfusion

Inhibition of endogenous nitric oxide (NO) synthesis during early intestinal ischemia/reperfusion (I/R(i)) enhances remote organ damage related to I/R(i). However, the effects of NO synthase (NOS) inhibitors on NO formation in various organs have not yet been specified. We therefore investigated the effects of N-G-monomethyl-L-arginine (L-NMMA), a nonspecific NOS inhibitor, and L-arginine, the NOS substrate, on NO formed in ischemic intestine versus normoxic remote organs (lung and liver). We used electron paramagnetic resonance spectroscopy and a specific NO trap to assay NO in blood, intestine, lung, and liver of rats subjected to local I/R(i), with and without L-NMMA and L-arginine supplementation. We found that I/R(i) increased NO levels in the intestine and blood, but not in the remote organs lung and liver. Administration of L-NMMA before I/R(i) decreased I/R(i)-independent basal NO levels in normoxic lung and liver without influencing I/R(i)-induced increase in NO levels in intestinal tissue or in blood. L-arginine supplementation increased circulating levels of NO, with sensitivity to L-NMMA, without affecting NO levels in normoxic or ischemic tissue. Our data suggest that NOS activity controls the NO generated in normally perfused remote organs during early I/R(i). Hence NOS inhibitors, when administered during I/R(i), decrease physiological NO levels in normoxic remote organs without affecting increased NO levels originating from ischemic intestine. This may explain the harmful effect of nonspecific NOS inhibitors during early I/R(i). In addition, the generation of NO in remote organs is not limited by tissue L-arginine concentrations and, therefore, not influenced by exogenous L-arginine. The protective effect of L-arginine supplementation during I/R(i) is probably related to increasing intravascular NO formation.

Systemic LPS injection leads to granulocyte influx into normal and injured brain: effects of ICAM-1 deficiency

The lipopolysaccharide (LPS) constituents of the gram-negative bacterial wall are among the most potent activators of inflammation. In the current study, we examined the effect of subcutaneous injection of Escherichia coli LPS on leukocyte influx into the normal and injured brain using endogenous peroxidase (EP). Normal brain parenchyma does not contain granulocytes and this does not change after indirect trauma, in facial axotomy. However, systemic injection of 1 mg LPS led to a gradual appearance of EP-positive parenchymal granulocytes within 12 h, with a maximum at 1-4 days after injection. Facial axotomy (day 14) led to a further 50-300% increase in granulocyte number. Of the five mouse strains tested in the current study, four--Balb/C, FVB, C57Bl/6, and C3H/N--showed vigorous granulocyte influx (60-90 cells per 20-microm section in axotomized facial nucleus, 20-40 cells per section on the contralateral side). The influx was an order of magnitude lower in the SJL mice. The peroxidase-positive cells were immunoreactive for neutrophil antigen 7/4 and alpha M beta 2 integrin, were negative for IBA1 (monocytes) and CD3 (T cells), and could be prelabeled by subcutaneous injection with rhodamine B isothiocyanate (RITC), confirming their origin as blood-borne granulocytes. All RITC-positive cells were IBA1 negative. This influx of granulocytes was accompanied by a disruption of the blood-brain barrier to albumin and induction of the cell adhesion molecule ICAM-1 on affected blood vessels. Transgenic deletion of ICAM-1 led to a more than 50% reduction in the number of infiltrating granulocytes compared to litter-matched wild-type controls, in normal brain as well as in axotomized facial motor nucleus. In summary, systemic injection of LPS leads to invasion of granulocytes into the mouse brain and a breakdown of the blood-brain barrier to blood-borne cells and to soluble molecules. Moreover, this mechanism may play a pathogenic role in the etiology of meningitis and in severe bacterial sepsis.

Nitric oxide-forming reaction between the iron-N-methyl-D-glucamine dithiocarbamate complex and nitrite

The objective of this study was to elucidate the origin of the nitric oxide-forming reactions from nitrite in the presence of the iron-N-methyl-D-glucamine dithiocarbamate complex ((MGD)(2)Fe(2+)). The (MGD)(2)Fe(2+) complex is commonly used in electron paramagnetic resonance (EPR) spectroscopic detection of NO both in vivo and in vitro. Although it is widely believed that only NO can react with (MGD)(2)Fe(2+) complex to form the (MGD)(2)Fe(2+).NO complex, a recent article reported that the (MGD)(2)Fe(2+) complex can react not only with NO, but also with nitrite to produce the characteristic triplet EPR signal of (MGD)(2)Fe(2+).NO (Hiramoto, K., Tomiyama, S., and Kikugawa, K. (1997) Free Radical Res. 27, 505-509). However, no detailed reaction mechanisms were given. Alternatively, nitrite is considered to be a spontaneous NO donor, especially at acidic pH values (Samouilov, A., Kuppusamy, P., and Zweier, J. L. (1998) Arch Biochem. Biophys. 357, 1-7). However, its production of nitric oxide at physiological pH is unclear. In this report, we demonstrate that the (MGD)(2)Fe(2+) complex and nitrite reacted to form NO as follows: 1) (MGD)(2)Fe(2).NO complex was produced at pH 7.4; 2) concomitantly, the (MGD)(3)Fe(3+) complex, which is the oxidized form of (MGD)(2)Fe(2+), was formed; 3) the rate of formation of the (MGD)(2)Fe(2+).NO complex was a function of the concentration of [Fe(2+)](2), [MGD], [H(+)] and [nitrite].

Developing in vivo EPR oximetry for clinical use

This paper describes the rationale for carrying out electron paramagnetic resonance (EPR) oximetry studies in human subjects in the clinical setting and the potential approaches and specific steps needed to make such studies feasible and useful. While the approach is described specifically for EPR oximetry, many of the principles may apply to the initial clinical uses of other techniques. The suggested operational approach is to have the initial applications occur in as clinically useful and simple a manner as possible, with the expectation that once the technique is introduced and accepted in the clinical setting, that more complex and/or more technically difficult applications will be able to be developed. The initial approach will be based on EPR spectroscopy at 1.2 GHz focusing on applications for which in vivo EPR provides a clearly useful approach to important clinical problems for which currently there is no good alternative method. The EPR measurements can be carried out non-invasively by measurements within 10 mm of the surface after the placement of the paramagnetic material at the site of interest, or by the placement of a needle/catheter in the site of interest for the required time period. The suggested initial clinical applications are guiding therapy for individual patients with tumors or vascular disease, by direct measurements of tissue pO2.