Human glomerular mesangial cells inactivate leukotriene B4 by reduction into dihydro-leukotriene B4 metabolites

Due to its potent chemotactic properties leukotriene B4 is an important mediator of inflammatory reactions. Cultured human kidney mesangial cells converted exogenously added leukotriene B4 efficiently into three different more lipophilic metabolites, two of them probably representing dihydro-leukotriene B4 isomers. This represents an alternative metabolic pathway, in contrast to leukotriene B4 omega-oxidation found in human polymorphonuclear leukocytes. Both dihydro-leukotriene B4 isomers had nearly completely lost their ability to induce leukocyte chemotaxis as compared to leukotriene B4.

Multifunctional analysis of the interaction of anthralin and its metabolites anthraquinone and anthralin dimer with the inner mitochondrial membrane

We studied the interaction of the antipsoriatic compound anthralin (1.8-dihydroxy-9-anthrone), and its metabolites anthraquinone (1.8-dihydroxy-9.10-anthraquinone) and anthralin dimer (1.8.1'.8'.-tetrahydroxy-10.10'-bis-9[10]-dianthrone) with the inner mitochondrial membrane. Mitochondrial membrane functions such as ubiquinone redox equilibria, redox status of iron sulfur clusters, cyanide-sensitive and cyanide-insensitive oxygen consumption, adenosine triphosphate (ATP) synthesis, ATP hydrolysis, and adenine nucleotide content of mitochondria were analyzed. Anthralin is an inhibitor of mitochondrial oxygen uptake in the presence of ADP and substrate (cyanide-sensitive respiration), inhibits ATP synthesis without affecting ATP hydrolysis, and depletes mitochondria of ATP. Anthralin dimer is a much weaker inhibitor of mitochondrial functions and anthraquinone is almost inactive. Anthralin, but not anthraquinone and anthralin dimer, reverses uncoupler stimulated oxygen consumption, stimulates cyanide-insensitive respiration, reduces mitochondrial ubiquinone-9 and -10 to the corresponding ubiquinols and reduces mitochondrial iron sulfur clusters. Anthralin may induce formation of reactive oxygen species by enhancing autoxidation of mitochondrial components and/or by catalyzed oxidation of anthralin. Taken together, anthralin acts as an electron donor to inner mitochondrial membrane associated redox components, inhibits the electron transport chain, and has an oligomycin-like effect. Anthralin dimer and anthraquinone do not function as electron donors and act by a different reaction mechanism. Respiratory measurements in human keratinocytes revealed similar results as obtained with isolated mitochondria. We suggest that modulation of membrane redox status may be a common concept of anthralin action in target cells such as keratinocytes and neutrophils.

[Report of 2 cases of isolated, primary amyloidosis of the male urethra and urinary bladder of a female]

Primary localized amyloidosis of the bladder and urethra is a rare condition. Two cases of isolated primary amyloidosis, of the urethra in a man and of the bladder in a woman, are reported. The clinical specificity of the location and the specific therapy are discussed. We draw attention to the extended, palette of diagnostic investigations now available and the new classification made possible by the introduction of immunohistochemistry and immunoelectron microscopy.

The severe combined immunodeficiency (scid) mouse. A laboratory model for the analysis of Lyme arthritis and carditis

We report that the spirochete B. burgdorferi induces progressive polyarthritis and carditis in mice with severe combined immunodeficiency syndrome (scid) but not in normal C.B-17 mice. The onset and severity of the disease were dependent on (a) the viability; (b) the infectivity; and (c) the dose of inoculated B. burgdorferi organisms. Infective spirochetes were isolated from both blood and joints of inoculated scid mice. These findings suggest that B. burgdorferi-induced chronic arthritis and carditis in mice develops independently of lymphocyte function and makes the scid mouse an attractive laboratory model to study the role of the immune system in experimental Lyme Borreliosis.

Influences of tromantadine and nonoxinol 9 on the stability of red cell membrane

The antiviral compound tromantadine (ViruMerz) and the detergent nonoxinol 9 have been investigated in their effects on biophysical parameters of red cell membranes. Up to a maximum ratio of 1 mol per 800 mol of phospholipids tromantadine enhances the membrane phase transition/separation break at 16-20 degrees C measured by 1-anilinonaphthalene-sulfonate (ANS) fluorescence. It also increases order parameters obtained from spin labeling experiments with 5-doxyl stearic acid. Nonoxinol 9 interacts with the membrane at a maximum ratio of 1 mol per 40 mol of phospholipids determined by UV spectrophotometry. The substance decreases the intensity of the above phase transition/separation break and the order parameters of the spin label 5-doxyl stearic acid. These experiments indicate that tromantadine probably stabilizes the membrane whereas nonoxynol 9 exhibits opposite effects. Combination of both compounds equalizes the influences of the single substances on the above biophysical parameters of red cell membrane with predominance of the nonoxinol 9 effect.

Enzyme release from chick myocytes during hypoxia and reoxygenation: dependence on pH

On reoxygenation of ischemic or hypoxic hearts a sudden release of cytosolic enzymes coupled with hypercontraction and cell injury occurs, which has been termed the "oxygen paradox". We have attempted to imitate this phenomenon in cultured chick myocytes to try to find the cause of this sudden enzyme release. During 4 hours of normoxic perfusion (pH 7.4) monolayer cultures of chick embryonic myocytes retain their normal morphology, beat rhythmically, and show no release of creatine kinase (CK) into the perfusate. Hypoxic perfusion (O2 less than or equal to 0.25 microliter/ml) stops cell contraction (15-20 min) and causes "blebbing" of the sarcolemma (20-30 min). Membrane blebs increase in size and number with continuing hypoxia and eventually the cells become irreversibly damaged. Perfusion at pH 7.4 leads to a release of CK shortly after membrane damage occurs (30-40 min), with peak enzyme levels at 60-90 min. Reoxygenation after 120 min hypoxia does not exacerbate release. Hypoxic perfusion at pH 7.0 suppresses the release of CK from the cells despite extensive membrane blebbing. Normoxic perfusion at pH 7.4 after 100 min hypoxia (pH 7.0) causes an efflux of enzyme from the irreversibly injured cells. This can be prevented by reoxygenating the cells at pH 7.0 and stimulated by raising the pH of the hypoxic perfusate to 7.4. Shorter hypoxic periods (30 mins) at pH 7.0 followed by normoxic perfusion at pH 7.4 lead to a sudden large efflux of CK, arrhythmic contractions and hypercontraction of myofilaments, i.e. the typical symptoms of the "oxygen paradox". Thus changes in external pH can influence the release of intracellular enzymes during hypoxia and reoxygenation.

Avoiding reperfusion injury after limb revascularization: experimental observations and recommendations for clinical application

This study tests the hypothesis that reperfusion injury is the principal cause of limb loss after acute arterial occlusion and that this injury is avoidable. Of 61 isolated hindlimbs amputated at the level of the hip joint, 17 were controls (group I), 5 were perfused without ischemia to establish the validity of the model (group II), and 15 underwent 4 hours of ischemia at room temperature without reperfusion (group III). Acute embolectomy was simulated in 24 limbs after 4 hours of ischemia; 12 were reperfused with standard Krebs-Henseleit solution at 100 mm Hg (group IV), and 12 were reperfused under controlled conditions (i.e., 37 degrees C, 50 mm Hg) with substrate-enriched modified reperfusate (group V). Leg volume, water content, contractile function, and high-energy phosphate content were assessed and data were expressed as mean +/- SD. Four hours of ischemia caused a profound fall in adenosine triphosphate content (4.0 vs 26.0 mmol/L/gm of protein, p less than or equal to 0.001). Uncontrolled reperfusion resulted in severe reperfusion injury; massive edema developed (83% vs 75%, p less than or equal to 0.01), leg volume increased markedly (21.5% above control, p less than or equal to 0.001), and no contractile function followed electrical stimulation. In contrast, controlled reperfusion resulted in normal water content (76.9% vs 75.0%, NS) and minimal change of leg volume (5.5% +/- 5% of control, NS), replenished adenosine triphosphate completely (24.2 vs 26.4 mmol/L/gm of protein, NS), and restored immediate contractile function in all limbs (24.3% +/- 14% of control). This study shows that 4 hours of room-temperature ischemia (18 degrees C) does not produce irreversible damage of the rat hindlimb because the reperfusion injury that follows uncontrolled reperfusion can be avoided. Immediate recovery of contractile function can be restored if the conditions of reperfusion are controlled by gentle reperfusion pressure (50 mm Hg) at 37 degrees C and if a modified substrate-enriched, hyperosmotic, alkalotic, low-Ca++ reperfusate is administered.

Myocardial protection by 2-mercaptopropionylglycine during global ischemia in dogs

The hypothesis was tested, if the addition of 2-mercaptopropionylglycine (MPG, Thiola) to a crystalloid cardioplegic solution provides superior myocardial protection as assessed by biochemical and morphological parameters. Five mongrel dogs underwent a 60-min hypothermic cardioplegic arrest (untreated group). In six dogs, MPG (1.5 mmol/l) was added to the crystalloid cardioplegic solution (treated group). Thereafter a reperfusion phase of 60 min was established. At the end of the reperfusion phase samples for mitochondrial respiration parameters and for mitochondrial energization were collected. Samples for ultrastructure and negative staining were taken at the end of ischemia, and after 15, 30 and 60 min of reperfusion. Hearts which were treated with the MPG-enriched cardioplegic solution showed a better ultrastructure (1 (1/1) vs 2 (2/2), p less than 0.001) and superior preservation of the mitochondrial ATPases (2.4 +/- 2.0 versus 8.4 +/- 2.7, p less than 0.05) as compared to the untreated group at the end of ischemia. At the end of reperfusion, mitochondrial respiration, and energization of the mitochondria was improved significantly with the addition of MPG as compared to the untreated group.

Mitochondrial sulfhydryl groups under oligomycin-inhibited, aging, and uncoupling conditions: beneficial influence of cardioprotective drugs

Uncoupling, oligomycin-inhibited, and aging/swelling conditions comprise three models for mitochondrial dysfunction. In these models, the effects of cardioprotective agents on rat heart mitochondrial membrane -SH reactivity have been studied. For -SH detection two different chromophores were used: dithionitrobenzoate (NbS2) and monobromobimane (MB). The objective of this study is to reveal the influence of three cardioprotective substances against the loss of membrane -SH reactivity: (i) The thiol reagent 2-mercaptopropionylglycine (MPG) prevents the decrease of thiols caused by carbonylcyanide-p-trifluoromethoxyphenylhydrazone (FCCP), aging, and oligomycin measured with MB and NbS2, and the diminution by oleate detected with MB. The small amount of MPG (6 nmol/mg protein), necessary for the protection, agrees with oligomycin sensitivity of the -SH groups concerned. (ii) The active metabolite of molsidomine, 3-morpholinosydnonimine (SIN-1), protects against the decrease of thiols by FCCP, oleate, and aging monitored with MB. In the case of oligomycin -SH groups accessible to NbS2 are protected. (iii) Another antianginal drug, isosorbidedinitrate (ISDN) does not protect membrane thiol groups. In contrast to SIN-1, ISDN probably requires enzymatic activation. It is suggested that MPG as well as SIN-1 may help to restitute the original -SH status of the mitochondrial membrane.

Reactivity of mitochondrial sulfhydryl groups toward dithionitrobenzoic acid and bromobimanes under oligomycin-inhibited and uncoupling conditions

Thiol reactivity was determined in rat heart mitochondria using chromophores of differing polarities: monobromobimane (MB), dithionitrobenzoate (NbS2), and bromobimane-q (MQ). The purpose of this study is to correlate reaction rates of protein thiols in the mitochondrial membrane with the oligomycin-inhibited and uncoupled states: In all cases investigated the reactivity of -SH groups toward MB decreases under the above conditions. In parallel with an increase of their uncoupling activities the uncouplers reduce the reaction rate of thiol groups toward NbS2 and, progressively, toward MQ, indicating differences in sensitivity of thiol groups to uncouplers depending on the polarity of the environment. The pattern of -SH reactivity under inhibition by oligomycin resembles that of carbonylcyanide-p-trifluoromethoxyphenylhydrazone. Functional changes of the mitochondrial membrane probably correlate with reactivity/polarity changes of membrane -SH groups. Masking of membrane thiol groups thus is not specific for uncouplers but is also observed under inhibition with oligomycin.

Spontaneous sister chromatid exchange in normal bone marrow and Ph-positive chronic myelocytic leukemia

The frequency of spontaneous sister chromatid exchange was studied in normal marrow derived from 38 healthy donors and 40 untreated patients with chronic phase CML. The sister chromatid exchange frequency was significantly lower in the leukemic cells (range, 2.32 +/- 1.31 to 4.76 +/- 2.37 per metaphase; mean, 3.18 +/- 0.49) than in normal marrow (range, 2.36 +/- 1.44 to 5.54 +/- 2.24 per metaphase; mean, 3.92 +/- 0.72). The contraction status of chromosomes was comparable in normal and Ph-positive metaphases. The reduction of sister chromatid exchange in leukemic cells was seen in all chromosome groups. The analysis of cell cycle specific proliferation according to the typical staining patterns of metaphases due to the number of cell cycles during which bromodesoxyuridine was substituted, revealed longer cell cycle times for the leukemic cells.

A multiparameter analysis of the perfused rat heart: responses to ischemia, uncouplers and drugs

In perfused rat hearts alterations of aortic flow and mitochondrial membrane potential resulting from uncoupling of oxidative phosphorylation, hypoxia and treatment with a cardioprotective drug (2-mercaptopropionylglycine (MPG) have been studied. Mitochondrial membrane potential was followed by surface fluorimetry on DASPMI stained hearts. This fluorochrome specifically stains mitochondria in living cells; fluorescence intensity is related to the electrochemical gradient. Aortic flow turned out to be a much more sensitive indicator of heart function than ventricular pressure or mitochondrial membrane potential. No direct relationship exists between mitochondrial membrane potential and ATP production under the different metabolic conditions. Two phases of hypoxic mitochondrial damage have been deduced: the first results in derangement of ATP synthases while membrane potential is maintained, the second in irreversible damage of mitochondrial membranes with loss of membrane potential.

A novel cardioprotective regimen for improvement of inner mitochondrial membrane function after ischemic stress

Treatment of the normoxic working rat heart with 1 mmol/l 2-mercaptopropionylglycine (MPG) results in a significant increase of postischemic aortic flow. Measurement of N,N-dimethylaminostyrylmethylpyridinium iodide (DASPMI) fluorescence on the surface of the heart preparation gives semiquantitative information on mitochondrial energization in situ. No differences in fluorescence have been found between therapy and control groups. This finding is confirmed by fluorescence studies on isolated mitochondria. Investigations on postischemic mitochondrial oxygen consumption and ATPase clearly reveal ameliorated function of oxidative phosphorylation and reduced ATP splitting activity by MPG treatment. Mitochondrial energization (i.e. membrane potential) thus does not run strictly parallel with oxidative and phosphorylative capabilities.

Prostaglandin E2 directly protects isolated rat gastric surface cell membranes against bile salts

Rat gastric surface cell membranes were prepared and the effect of taurocholic acid assessed by ESR spectroscopy using the 16-doxylstearic acid spin label. Taurocholic acid increased the polar part of the spectra, indicating an augmented amount of spin label molecules with a polar environment. Concomitantly, mobility of the spin label molecule was augmented. The effect of taurocholic acid was completely prevented by the previous addition of prostaglandin E2. This suggests a direct protective efficiency of prostaglandin E2 on rat gastric surface cell membranes without the metabolic participation of intact cells.

Improvement of myocardial function after global hypoxia by protection of the inner mitochondrial membrane

In the present study the hypothesis is tested that hypoxia causes morphological damage to the inner mitochondrial membrane and that this damage can be reversed by modification of the reoxygenated perfusate. Using the working rat heart model, hearts in group I (n = 40) were subjected to a 30 min normothermic, normoxic phase and a 90 min hypoxic phase, followed by 60 min reoxygenation. Hearts in group II (n = 32) were also subjected to a 30 min normoxic and a 90 min hypoxic phase. However, after 30 min of reoxygenation 1.5 mmol/l 2-mercaptopropionylglycine (MPG) was injected in the reoxygenated solution in order to test its ability to improve mitochondrial function. Mitochondrial function was assessed by measuring oxygen uptake (ST3), ST4, respiratory control index (RCI), ADP/O and oxidative phosphorylation rate (OPR). In addition mechanical function (heart rate, aortic and coronary flow, cardiac output, stroke volume) was monitored along with ultrastructural parameters. 90 min of hypoxia caused a deterioration of all parameters with persistent impairment in hemodynamic, morphologic and biochemical functions after 60 min of reoxygenation (group I). The role of the ATP-synthetases in the pathogenesis of oxygen-paradox is discussed. In contrast, the MPG-enriched reoxygenated solution (group II) improved hemodynamics, ultrastructure and mitochondrial function significantly (alpha = 0.05). It is concluded from these data that the ATP-synthetases are damaged during oxygen-deficiency and that MPG may be a useful drug for protecting the inner mitochondrial membranes during reoxygenation.

Free radical scavenging drugs, assessed by ESR studies: influence of hemoglobin

To monitor free radical scavenging properties of drugs, the 'stable' radical 2,2,6,6-tetramethylpiperidino-1-oxyl (TEMPO) was used. The sydnonimine molsidomine (SIN-1) effectively reduced the ESR signal whereas the nitrate isosorbidemononitrate (ISMN) did not. Thiol reagents like 2-mercaptopropionylglycine (MPG) or glutathione (GSH) only were effective in the presence of Fe2+ or Fe3+. Protein-bound iron in hemoglobin proved about four times more effective in reducing ESR signal height by thiols. It is suggested that the decrease in thiol content adds to the lack in protein bound iron of hemoglobin to induce the burst of free radicals in hypoxia (ischemia) and reperfusion.

31P-NMR spectroscopic investigations and mitochondrial studies on the cardioprotective efficiency of 2-mercaptopropionylglycine

Contents of high energy phosphates in the isolated perfused rat heart were followed during ischemia and reperfusion using 31P NMR spectroscopy. Application of 2-mercaptopropionylglycine resulted in significantly higher content of ATP in the reperfusion phase whereas during ischemia no differences between control and therapy hearts were found. Analysis of postischemic mitochondrial function reveals that improved ATP level is paralleled by an increased respiratory control index and a reduced ATPase activity. It is suggested that 2-mercaptopropionylglycine may cause increase of high energy phosphates during reperfusion by improving mitochondrial oxidative phosphorylation.

On the interaction between anthralin and mitochondria: a revision

Anthralin is an inhibitor of oxidative phosphorylation at concentrations found in vivo. ADP-stimulated oxygen consumption is diminished. Consequently, the rate of ATP synthesis is reduced and mitochondrial ATP content declines. Neither the isolated ATPase (F1F0-ATPase), nor the mitochondrial membrane-bound ATPase are influenced by the drug. Respiration under resting conditions is not affected. The experimental data unequivocally indicate that anthralin is not an uncoupler of oxidative phosphorylation, as previously stated. Furthermore, the interpretation that respiratory deficiency induced in yeast strains by anthralin is a consequence of petite mutations has to be reconsidered. Under in vivo conditions, anthralin inhibits respiration per se. Our experiments, including the electron spin resonance spectroscopy, reveal that anthralin alters mitochondrial membrane structure and function simultaneously. A redox or free-radical mediated step may be involved. In consequence, inhibition of ATP production occurs which may become the limiting factor for increased cellular metabolism in psoriasis.

ATP synthase complex from beef heart mitochondria. Separation of protein bands in the region of 28-31 kDa

ATPase/ATP synthase preparations originally contain protein bands in the 28-31-kDa region. The present study demonstrates separation of the band at 29 kDa (adenine nucleotide translocator) from a band at approximately 31 kDa. In cholate/ammonium sulfate-extracted ATP synthases removal of the 31-kDa band results in decrease of ATP-Pi exchange and oligomycin sensitivity of the ATPase activity. It is suggested that the protein band at 31 kDa is heterogeneous, containing diverse activities, the identities of which are yet to be determined.

Effects of bepridil on heart mitochondrial membrane and the isolated rat heart preparation

Bepridil (Cordium) was found to activate rat heart mitochondrial membrane-bound ATPase at concentrations of 10 nmol/l-10 mumol/l. By contrast, oligomycin-sensitive ATPase from beef heart mitochondria was inhibited at concentrations of 1-10 mumol/l. In both systems sensitivity toward the inhibitor oligomycin was reduced. Under the influence of the drug, RCR (coupling degree of electron transport to ATP synthesis), ST3 (oxygen uptake in presence of substrate and ADP) and OPR (oxidative phosphorylation rate, amount of ATP synthesized in mitochondrial metabolic state ST3) values are reduced, indicating partial inhibition of oxidative phosphorylation. At 0.25 mumol/l concentration of bepridil, in the isolated normoxic working rat heart preparation aortic flow was reduced to zero. No changes in oxidative phosphorylation parameters were found in mitochondria isolated from these preparations. In the isolated, working rat heart preparation bepridil at a concentration of 0.05 mumol/l reduced aortic flow to about 75% of its original value. In this preparation, no cardioprotective effects (neither on aortic flow nor on mitochondrial function) could be demonstrated during postischemic reperfusion. It is suggested, that in vitro mitochondrial activities of bepridil are not related to in vivo action of the drug.

Uncoupler- and hypoxia-induced damage in the working rat heart and its treatment. II. Hypoxic reduction of aortic flow and its reversal

In the working rat heart we investigated heart function (aortic and coronary flow) during a normoxic, a hypoxic, and a reoxygenation phase after hypoxia. A depressed heart function was obtained by limiting oxygen supply and reducing left ventricular filling pressure (preload). After hypoxic perfusion for about 90 min, reoxygenation resulted in a 50% decrease of aortic flow. Lactate production and release increased immediately after oxygen deprivation and reached a maximum after about 35 min of hypoxia. Following reoxygenation, lactate release decreased. Lactate dehydrogenase became significant after reoxygenation. After stabilization of aortic flow at 50% in the reoxygenation phase different reagents were examined for their influence on heart performance. 1.5 mM of 2-Mercaptopropionylglycine (MPG) significantly increased aortic flow by 40%. The oxidized form of MPG (ox-MPG) at a concentration of 0.6 mM increased aortic flow by 125%. A molecular mechanism is proposed involving reorientation of the ATPase molecules at their membrane sites.

Uncoupler- and hypoxia-induced damage in the working rat heart and its treatment. I. Observations with uncouplers of oxidative phosphorylation

In the isolated working rat heart, the damaging effect of 0.05-0.06 microM Carbonylcyanide-p-trifluoro-methoxyphenylhydrazone (FCCP) was reversible within 20 sec by perfusion with fresh buffer. Cysteine 3 mM restored the aortic flow to the initial value within an additional 15-20 sec. Thereafter, the FCCP effect became irreversible due to a progressive structural membrane change. The structural change by FCCP is probably brought about by 'internalization' of polar groups (R-SH; R-NH3+) of the mitochondrial (and other) membrane.

Sister chromatid exchange in normal and Ph1-positive leukemic cells after mitomycin-C treatment in vitro

The sister chromatid exchange (SCE) frequency was investigated in normal bone marrow and Ph1-positive cells of chronic myelocytic leukemia (CML) patients with and without mitomycin-C (MMC) treatment in vitro. Even though the spontaneous SCE frequency was found to be significantly lower in CML cells, the absolute SCE values after MMC treatment did not differ between leukemic and normal cells, and this seems to indicate an equilization of SCE rates. However, the fact that leukemic cells with lower spontaneous SCE rates need a further increase of SCE to reach values equal to those of normal cells might indicate a somewhat higher susceptibility of leukemic cells to DNA damage by MMC. This interpretation appears to be confirmed by the fact that the inhibition of cellular proliferation at higher MMC doses considerably reduced the number of leukemic cells that was able to divide twice during a given culture time.