Mahesh S. Joshi

DIFFUSION-LIMITED REACTION OF FREE NITRIC OXIDE WITH ERYTHROCYTES

Concentration changes of nitric oxide (NO) were monitored using an NO-sensitive electrode in phosphate-buffered saline (PBS) with either free oxyhemoglobin (oxyHb) or red blood cells (RBCs). In aerated PBS, the half-life of 0.9 μm NO is greater than 4 min. NO is undetectable (<50 nm) when added to a solution of oxyHb because the reaction of NO with oxyHb is rapid. The disappearance rate of NO in PBS containing RBCs is rapid, compared with PBS, but it is much slower (by a factor of approximately 650) than with an equivalent solution of free oxyHb. The half-life of NO is inversely proportional to the concentration of RBCs, independent of oxyHb concentration inside RBCs, and the disappearance rate of NO is first order in NO concentration and first order in the concentration of RBCs. After all the oxyHb reacts with NO to form methemoglobin, the disappearance rate of NO slows greatly. These data indicate that the reaction of NO with oxyhemoglobin within RBCs is limited by the diffusion of NO into the cell, which has also been shown previously for the reaction of O2 with deoxyhemoglobin. Experimental data show that the half-life of NO in the presence of 2.1 × 106 RBCs/ml is 4.2 s. From this value, we estimate that the half-life of NO in whole blood (5 × 109RBCs/ml) will be 1.8 ms. A simple analytical expression for the half-life of NO in PBS with RBCs was derived in this study based on a spherical diffusion model. The calculated half-life of NO from the expression is in good agreement with the experimental values.

Nitric oxide is consumed, rather than conserved, by reaction with oxyhemoglobin under physiological conditions

Although irreversible reaction of NO with the oxyheme of hemoglobin (producing nitrate and methemoglobin) is extremely rapid, it has been proposed that, under normoxic conditions, NO binds preferentially to the minority deoxyheme to subsequently form S-nitrosohemoglobin (SNOHb). Thus, the primary reaction would be conservation, rather than consumption, of nitrogen oxide. Data supporting this conclusion were generated by using addition of a small volume of a concentrated aqueous solution of NO to a normoxic hemoglobin solution. Under these conditions, however, extremely rapid reactions can occur before mixing. We have thus compared bolus NO addition to NO generated homogeneously throughout solution by using NO donors, a more physiologically relevant condition. With bolus addition, multiple hemoglobin species are formed (as judged by visible spectroscopy) as well as both nitrite and nitrate. With donor, only nitrate and methemoglobin are formed, stoichiometric with the amount of NO liberated from the donor. Studies with increasing hemoglobin concentrations reveal that the nitrite-forming reaction (which may be NO autoxidation under these conditions) competes with reaction with hemoglobin. SNOHb formation is detectable with either bolus or donor; however, the amounts formed are much smaller than the amount of NO added (less than 1%). We conclude that the reaction of NO with hemoglobin under normoxic conditions results in consumption, rather than conservation, of NO.

Reactive oxygen species mediate tumor necrosis factor alpha-converting, enzyme-dependent ectodomain shedding induced by phorbol myristate acetate

Ectodomain shedding of cell surface membrane‐anchoring proteins is an important process in a wide variety of physiological events(1, 2). Tumor necrosis factor α (TNF‐α) converting enzyme (TACE) is the first discovered mammalian sheddase responsible for cleavage of several important surface proteins, including TNF‐α, TNF p75 receptor, L‐selectin, and transforming growth factor‐α. Phorbol myristate acetate (PMA) has long been known as a potent agent to enhance ectodomain shedding. However, it is not fully understood how PMA activates TACE and induces ectodomain shedding. Here, we demonstrate that PMA induces both reactive oxygen species (ROS) generation and TNF p75 receptor shedding in Mono Mac 6 cells, a human monocytic cell line, and l‐selectin shedding in Jurkat T‐cells. ROS scavengers significantly attenuated PMA‐induced TNF p75 receptor shedding. Exogenous H2O2 mimicked PMA‐induced enhancement of ectodomain shedding, and H2O2‐induced shedding was blocked by TAPI, a TACE inhibitor. Furthermore, both PMA and H2O2 failed to cause ectodomain shedding in a cell line that lacks TACE activity. By use of an in vitro TACE cleavage assay, H2O2 activated TACE that had been rendered inactive by the addition of the TACE inhibitory pro‐domain sequence. We presume that the mechanism of TACE activation by H2O2 is due to an oxidative attack of the pro‐domain thiol group and disruption of its inhibitory coordination with the Zn++ in the catalytic domain of TACE. These results demonstrate that ROS production is involved in PMA‐induced ectodomain shedding and implicate a role for ROS in other shedding processes.

Activation of Tumor Necrosis Factor-α-converting Enzyme-mediated Ectodomain Shedding by Nitric Oxide

Ectodomain shedding of cell surface proteins is an important process in a wide variety of physiological and developmental events. Recently, tumor necrosis factor-α-converting enzyme (TACE) has been found to play an essential role in the shedding of several critical surface proteins, which is evidenced by multiple developmental defects exhibited by TACE knockout mice. However, little is known about the physiological activation of TACE. Here, we show that nitric oxide (NO) activates TACE-mediated ectodomain shedding. Using anin vitro model of TACE activation, we show that NO activates TACE by nitrosation of the inhibitory motif of the TACE prodomain. Thus, NO production activates the release of cytokines, cytokine receptors, and adhesion molecules, and NO may be involved in other ectodomain shedding processes.

Receptor-mediated activation of nitric oxide synthesis by arginine in endothelial cells.

Arginine contains the guanidinium group and thus has structural similarity to ligands of imidazoline and α-2 adrenoceptors (α-2 AR). Therefore, we investigated the possibility that exogenous arginine may act as a ligand for these receptors in human umbilical vein endothelial cells and activate intracellular nitric oxide (NO) synthesis. Idazoxan, a mixed antagonist of imidazoline and α-2 adrenoceptors, partly inhibited l-arginine-initiated NO formation as measured by a Griess reaction. Rauwolscine, a highly specific antagonist of α-2 AR, at very low concentrations completely inhibited NO formation. Like l-arginine, agmatine (decarboxylated arginine) also activated NO synthesis, however, at much lower concentrations. We found that dexmedetomidine, a specific agonist of α-2 AR was very potent in activating cellular NO, thus indicating a possible role for α-2 AR in l-arginine-mediated NO synthesis. d-arginine also activated NO production and could be inhibited by imidazoline and α-2 AR antagonists, thus indicating nonsubstrate actions of arginine. Pertussis toxin, an inhibitor of G proteins, attenuated l-arginine-mediated NO synthesis, thus indicating mediation via G proteins. l-type Ca2+ channel blocker nifedipine and phospholipase C inhibitor U73122 inhibited NO formation and thus implicated participation of a second messenger pathway. Finally, in isolated rat gracilis vessels, rauwolscine completely inhibited the l-arginine-initiated vessel relaxation. Taken together, these data provide evidence for binding of arginine to membrane receptor(s), leading to the activation of endothelial NO synthase (eNOS) NO production through a second messenger pathway. These findings provide a previously unrecognized mechanistic explanation for the beneficial effects of l-arginine in the cardiovascular system and thus provide new potential avenues for therapeutic development.

Permeabilization of yeast cells (Kluyveromycesfragilis) to lactose by cetyltrimethylammonium bromide

SummaryWhole cells of lactose fermentingKluyveromyces fragilis had very low β-galactosidase activity. Treating the yeast cells with a cationic detergent cetyltrimethylammonium bromide (0.1%) at 4°C for 5 mins increased the enzyme activity 480 fold. Detergent treated cells readily hydrolysed lactose present in milk and sweet whey and glucose produced was not further metabolized. These detergent permeabilized cells could be used to produce low lactose milk, in the utilization of whey and saccharification of lactose or whey for the production of alcohol.

Permeabilization of yeast cells (Kluyveromyces fragilis) to lactose by digitonin

Abstract Kluyveromyces fragilis , the lactose-fermenting yeast, was made permeable to the disaccharide lactose using the surfactant digitonin. Optimal β-galactosidase activity was observed when the cells were treated with 0.1% digitonin at room temperature for 30 min. The activity measured in these permeabilized cells was 400- to 500-fold greater than in the untreated cells and 25% more than in the cell-free extract prepared by toluene autolysis. These permeabilized cells rapidly hydrolysed lactose in whole milk and sweet whey to glucose and galactose. The glucose was not further degraded by permeabilized cells. In contrast, the untreated cells metabolized the glucose to ethanol.

Nicotine augments glomerular injury in a rat model of acute nephritis.

Background/Aims: Epidemiologic studies suggest that cigarette smoke worsens the progression of renal injury in patients with glomerular diseases. The mechanisms involved have not been elucidated. These studies were designed to determine whether nicotine worsens markers of inflammation including glomerular cell proliferation and fibronectin deposition in an in vivomodel of glomerular injury. Methods: Sprague-Dawley rats were injected with anti-Thy1 antibody and given either tap water or nicotine in the drinking water until sacrifice at day 14. Fibronectin expression was measured by Western blot and immunohistochemistry. COX-2 expression was also determined by Western blot in the kidney cortex of rats treated with nicotine and in cultured human mesangial cells treated with nicotine. Results: Anti-Thy1 antibody administration resulted in a significant increase in the number of cells per glomerulus that was further increased by the administration of nicotine. In nephritic rats, the administration of nicotine significantly increased fibronectin and COX-2 expression. In cultured human mesangial cells we also demonstrated that nicotine increases COX-2 expression and activity and that COX-2 mediates mesangial cell proliferation in response to nicotine. Conclusion: Either in vivo or in vitro treatment with nicotine leads to activation of inflammatory mediators and hallmarks of glomerular injury, which may explain the mechanisms involved in the deleterious effects of cigarette smoking on renal disease.

In situ assay of intracellular enzymes of yeast (Kluyveromyces fragilis) by digitonin permeabilization of cell membrane

The yeast, Kluyveromyces fragilis was permeabilized to a number of low-molecular-weight substrates using digitonin. The activities of intracellular yeast enzymes, viz., alcohol dehydrogenase (ADH), beta-galactosidase, glucose-6-phosphate dehydrogenase, aspartase, and hexokinase were found to be much higher in the permeabilized cells than the untreated cells. The optimum conditions for permeabilization with reference to ADH were 0.1% digitonin at 37 degrees C for 15 min. The ADH activity in permeabilized cells was several-fold higher than that in cell free extracts prepared by either physical or chemical methods.

Increased nitrite reductase activity of fetal versus adult ovine hemoglobin

Growing evidence indicates that nitrite, NO2-, serves as a circulating reservoir of nitric oxide (NO) bioactivity that is activated during physiological and pathological hypoxia. One of the intravascular mechanisms for nitrite conversion to NO is a chemical nitrite reductase activity of deoxyhemoglobin. The rate of NO production from this reaction is increased when hemoglobin is in the R conformation. Because the mammalian fetus exists in a low-oxygen environment compared with the adult and is exposed to episodes of severe ischemia during the normal birthing process, and because fetal hemoglobin assumes the R conformation more readily than adult hemoglobin, we hypothesized that nitrite reduction to NO may be enhanced in the fetal circulation. We found that the reaction was faster for fetal than maternal hemoglobin or blood and that the reactions were fastest at 50-80% oxygen saturation, consistent with an R-state catalysis that is predominant for fetal hemoglobin. Nitrite concentrations were similar in blood taken from chronically instrumented normoxic ewes and their fetuses but were elevated in response to chronic hypoxia. The findings suggest an augmented nitrite reductase activity of fetal hemoglobin and that the production of nitrite may participate in the regulation of vascular NO homeostasis in the fetus.