THE AUTODIGESTION HYPOTHESIS AND RECEPTOR CLEAVAGE IN DIABETES AND HYPERTENSION.

One of the key features of cardiovascular complications, such as hypertension or diabetes, is that they often appear at the same time in the same individual together with other forms of co-morbidities. While clinically a recognized phenomenon, no molecular mechanism for such co-morbidities has received universal acceptance. We propose a new hypothesis that provides a molecular basis for co-morbidities in hypertension due to unchecked proteolytic activity and receptor destruction. Testing of the hypothesis in the spontaneously hypertensive rat reveals an unchecked matrix metalloproteinase and serine protease activity in plasma and on several cardiovascular and parenchymal cells. The elevated proteolytic activity causes extracellular cleavage of multiple receptor types, such that cleavage of one receptor type leads to loss of the function carried out by this receptor. Proteolytic cleavage of the extracellular domain of the ß(2) adrenergic receptor in arteries and arterioles causes vasoconstriction and elevation of the central blood pressure while cleavage of the extracellular domain of the insulin receptor leads to insulin resistance and lack of transmembrane glucose transport. A diverse set of cell dysfunctions in the spontaneously hypertensive rat are accompanied by cleavage of the membrane receptors that are involved in these functions. Chronic inhibition of the unchecked protease activity in the spontaneously hypertensive rat serves to restore the extracellular receptor density and alleviates the corresponding cell dysfunctions. The mild unchecked proteolytic activity in the spontaneously hypertensive rat points towards a chronic autodigestion process as a contributor to the end organ injury encountered in this rat strain. The presence of various soluble receptors, which consist of extracellular fragments of membrane receptors, in the plasma of hypertensive and diabetic patients suggest that the autodigestion process may also be present in man.

Impairment of selectin-mediated leukocyte adhesion to venular endothelium in spontaneously hypertensive rats.

The present study was designed to elucidate whether molecular mechanisms for leukocyte adhesion to microvascular endothelium may differ between spontaneously hypertensive rats and Wistar Kyoto rats. Leukocyte rolling and adhesion were investigated while monitoring venular wall shear rates in the mesenteric microcirculation stimulated with histamine or tert-butyl hydroperoxide in the two strains. In Wistar Kyoto rats, 10 microM histamine as well as 500 microM tertbutyl hydroperoxide promoted a significant reduction of venular leukocyte rolling velocity and subsequent adhesion. These changes in leukocyte behavior were blocked by monoclonal antibodies against P-selectin (PB 1.3) and against sialyl Lewis X-like carbohydrates (2H5). However, spontaneously hypertensive rats exhibited a blunted response of the stimulus-elicited leukocyte rolling, which was associated with impairment of venular P-selectin expression as well as a decrease in the expression of sialyl Lewis X-like carbohydrates on circulating neutrophils. No significant differences were detected between the two strains not only in the surface CD11b/CD18 expression but also in the CD18-mediated adhesivity of neutrophils to intracellular adhesion molecule-1 transfectants in vitro. These results suggest that impairment of selectin-mediated leukocyte adhesion is an event responsible for disorders of inflammatory responses in spontaneously hypertensive rats.

Preliminary profiling of blood transcriptome in a rat model of hemorrhagic shock.

Hemorrhagic shock is a leading cause of morbidity and mortality worldwide. Significant blood loss may lead to decreased blood pressure and inadequate tissue perfusion with resultant organ failure and death, even after replacement of lost blood volume. One reason for this high acuity is that the fundamental mechanisms of shock are poorly understood. Proteomic and metabolomic approaches have been used to investigate the molecular events occurring in hemorrhagic shock but, to our knowledge, a systematic analysis of the transcriptomic profile is missing. Therefore, a pilot analysis using paired-end RNA sequencing was used to identify changes that occur in the blood transcriptome of rats subjected to hemorrhagic shock after blood reinfusion. Hemorrhagic shock was induced using a Wigger's shock model. The transcriptome of whole blood from shocked animals shows modulation of genes related to inflammation and immune response (Tlr13, Il1b, Ccl6, Lgals3), antioxidant functions (Mt2A, Mt1), tissue injury and repair pathways (Gpnmb, Trim72) and lipid mediators (Alox5ap, Ltb4r, Ptger2) compared with control animals. These findings are congruent with results obtained in hemorrhagic shock analysis by other authors using metabolomics and proteomics. The analysis of blood transcriptome may be a valuable tool to understand the biological changes occurring in hemorrhagic shock and a promising approach for the identification of novel biomarkers and therapeutic targets. Impact statement This study provides the first pilot analysis of the changes occurring in transcriptome expression of whole blood in hemorrhagic shock (HS) rats. We showed that the analysis of blood transcriptome is a useful approach to investigate pathways and functional alterations in this disease condition. This pilot study encourages the possible application of transcriptome analysis in the clinical setting, for the molecular profiling of whole blood in HS patients.

Oxidative stress in the Dahl hypertensive rat.

Enhanced production of oxygen free radicals may play a role in hypertension by affecting vascular smooth muscle contraction, resistance to blood flow, and organ damage. The aim of this study was to determine whether oxygen free radicals are involved in the development of salt-induced hypertension. Dahl salt-sensitive (Dahl-S) and salt-resistant (Dahl-R) rats were fed either a high salt (6.0% NaCl) or low salt (0.3% NaCl) diet for 4 weeks. The high salt diet caused the development of severe hypertension in Dahl-S animals and had no effect on blood pressure in Dahl-R animals. A tetranitroblue tetrazolium dye was used to detect superoxide radicals in microvessels of the mesentery. Light absorption measurements revealed enhanced staining along the endothelium of arterioles and venules in hypertensive Dahl-S animals, with significantly lower values in normotensive animals. In addition, a Clark electrochemical electrode was used to measure hydrogen peroxide levels in fresh plasma. Hypertensive Dahl-S animals had a higher plasma hydrogen peroxide concentration compared with their normotensive counterparts (2.81+/-0.43 versus 2.10+/-0.41 micromol/L), while no difference was detected between high- and low salt-treated Dahl-R animals (1.70+/-0.35 versus 1.56+/-0.51 micromol/L). The plasma hydrogen peroxide levels of all groups correlated with mean arterial pressure (r=.77). These findings demonstrate an enhanced production of oxygen free radicals in the microvasculature of hypertensive Dahl-S rats.

Microvascular tone in a skeletal muscle of spontaneously hypertensive rats.

We studied the degree of arteriolar smooth muscle constriction in the spinotrapezius muscle microcirculation of spontaneously hypertensive rats and their normotensive controls, Wistar-Kyoto rats. The constriction was expressed in the form of a nondimensional tone as the difference between steady state and dilated diameter (after papaverine treatment) divided by the dilated diameter. Both animal strains showed on average a progressive increase of tone toward the more distal arterioles, with a peak tone being reached in the transverse arterioles. Tone values in the hypertensive animals were consistently elevated. The number of arterioles that had more than 5% tone (so-called responder arterioles) was higher in the hypertensive animals. These studies suggest that, besides the anatomical adjustments documented earlier in our laboratory in the arteriolar network of this muscle, functional adjustments in the form of an elevated microvascular tone are associated with the elevated resistance in spontaneously hypertensive rats.

Leukocyte counts and activation in spontaneously hypertensive and normotensive rats.

The etiology for the progressive organ injury in hypertension is largely speculative. Recent studies have shown that leukocytes play a key role in several cardiovascular diseases. As an initial step toward investigating the role of leukocytes in hypertension, we measured leukocyte counts and spontaneous activation of granulocytes of freshly drawn unseparated blood samples in spontaneously hypertensive rats and in their normotensive counterpart, Wistar-Kyoto rats. The animals were derived from one breeder in the United States and from two breeders in Europe. Total leukocyte counts in young, mature, and old hypertensive rats were 50-100% above the controls. The number of granulocytes in mature and old spontaneously hypertensive rats in more than 100% elevated compared with control rats. In young hypertensive rats the mean granulocyte count was only slightly elevated. The number of spontaneously activated granulocytes, as detected by the nitroblue tetrazolium reduction, increases with age in both species; in mature spontaneously hypertensive rats, it is more than 300% above the values in the controls. Furthermore, in mature hypertensive rats the number of monocytes, activated monocytes, and the lymphocyte count are also significantly elevated over the values in the normotensive controls. It is proposed that these elevated leukocyte counts may constitute an enhanced risk for organ injury in the spontaneously hypertensive rat.

Impaired leukocyte-endothelial cell interaction in spontaneously hypertensive rats.

Hypertension is associated with a progressive organ injury whose etiology remains largely speculative. An increasing database shows that activated leukocytes, while affording an important immune protection, may be a contributing factor to several of the pathogenetic features of the hypertension syndrome. The purpose of this study was to determine the extent to which the glucocorticoid pathway may be involved in the atypical kinetics of leukocytes in spontaneously hypertensive rats (SHR) compared with normotensive Wistar-Kyoto (WKY) rats. The typical venular leukocyte adhesion induced by histamine application was significantly lower in SHR, and a comparison of normalized leukocyte rolling velocity (VWBC/VRBC) showed the values to be significantly higher in SHR relative to WKY controls. This abnormal trend in adherent leukocyte numbers and in VWBC/VRBC values could be counteracted when SHR were pretreated with RU 486, a synthetic glucocorticoid inhibitor, and restored to the levels observed in WKY rats. Anti-P-selectin monoclonal antibody (PB1.3) attenuated in SHR and WKY rats the increment of adherent leukocyte numbers as well as the decrement of VWBC/VRBC value that developed under combined histamine and RU 486 superfusion. Furthermore, an anti-intercellular adhesion molecule-1 monoclonal antibody (1A29) served to attenuate the increment of adherent leukocyte number induced by a combination of histamine and RU 486 superfusion in WKY rats and SHR. The results indicate that the deficient leukocyte-endothelial cell interaction in SHR can be circumvented by a glucocorticoid inhibitor.

Control of oxidative stress in microcirculation of spontaneously hypertensive rats.

One mechanism for organ damage in individuals with arterial hypertension may be due to oxygen free radical production. This study was designed to localize free radicals in a microvascular network of mature spontaneously hypertensive rats (SHRs) and normotensive Wistar-Kyoto (WKY) rats. Because glucocorticoids play a role in pressure elevation of SHRs, we investigated their role in microvascular free radical formation. Oxygen radical production in mesentery was detected by tetranitroblue tetrazolium reduction to formazan aided by digital light-absorption measurements. Formazan deposits were observed in the endothelial cells and lumens of all microvessels and in lymphatic endothelia but were fewer in tissue parenchyma. The formazan distribution in younger (14-16 wk old) WKY rats and SHRs was heterogeneous with low values in capillaries and small arterioles/venules (<30 microm) but enhanced deposits in larger venules. Adrenalectomy served to reduce the formazan density in SHRs to the level of WKY rats, whereas dexamethasone supplementation of the adrenalectomized rats caused elevation in the larger venules of SHRs. In older (40 wk old) SHRs, formazan levels were elevated in all hierarchies of microvessels. After pressure reduction was employed with chronic hydralazine treatment, the formazan deposits were reduced in all locations of the microcirculation in both WKY rats and SHRs. Elevated formazan deposits were also found in lymphatic endothelium. These results suggest that oxygen free radical production is elevated in both high- and low-pressure regions of SHR microcirculation via a process that is controlled by glucocorticoids. Older SHRs have higher formazan levels than younger SHRs in all microvessels. Chronic hydralazine treatment, which serves to reduce arterial blood pressure, attenuates tetranitroblue tetrazolium reduction in WKY rats and SHRs even in venules of the microcirculation, which has no micropressure elevation. Free radical production may be a more global condition in SHRs and may not be limited to arteries and arterioles.

The microvasculature in skeletal muscle. VI. Adrenergic innervation of arterioles in normotensive and spontaneously hypertensive rats.

A microanatomical study of the adrenergic nerve plexus on the arterioles in the spinotrapezius muscle of normotensive and spontaneously hypertensive rats was carried out. The spinotrapezius muscle was selected since its microvasculature has been reconstructed in previous studies of this series. A modified glyoxylic acid amine densification technique was used to visualize the major portion of the microvascular nerve plexus. The nerve plexus density was quantified in the form of fiber length per unit area of vascular smooth muscle media. The adrenergic innervation was found to be limited to the arterial/arteriolar side of the microcirculation and positioned in close vicinity to vascular smooth muscle, in line with previous reports. Substantial variations of the nerve plexus density could be detected along the arterioles. Arcade arterioles show a significant reduction of the adrenergic innervation compared to that of the thoracodorsal supply artery. There was a significant elevation of the nerve plexus density at the origin of the transverse arterioles at the arcade arterioles, a site that in the past has been shown to exhibit the highest microvascular tonus in all arterioles of this organ. Distal to this site, transverse arterioles exhibit a progressive reduction of adrenergic plexus density toward their capillary endings, in line with the termination of vascular smooth muscle in these small branches. Sporadic fiber extensions were encountered leading from some of the transverse arterioles into the capillary network per se, but no regular innervation was detected in capillaries or in venules. These results suggest that the transverse arterioles may play a central role in nervous control of blood flow to the capillaries of muscle. Compared with the Wistar and Wistar-Kyoto strain, the spontaneously hypertensive rats exhibit qualitatively a similar pattern, but show quantitatively a significantly higher plexus density in the thoracodorsal artery and the arcade arterioles, a factor that may contribute to the elevated arteriolar tone.

Mechanisms of parenchymal cell death in-vivo after microvascular hemorrhage.

OBJECTIVE: In vitro studies suggest that microhemorrhages with escape of red cells into the tissue may be cytotoxic to parenchymal cells due to oxygen free radical formation. We examined in the rat mesentery the impact of microhemorrhages on parenchymal cell death, as detected by propidium iodide staining, using an intravital approach. METHODS AND RESULTS: Postcapillary venules were punctured with a closed-end micropipette, permitting escape of blood cells and plasma into the mesentery interstitium. Over a period of 2 h, no significant increase in parenchymal cell death was encountered in tissues with hemorrhagic sites compared with nonhemorrhagic control sites. Interstitial microinjections of plasma derived from whole blood incubated for several hours with and without a combination of sodium azide (2 mM) and hydrogen peroxide (1 mM) led to significantly increased levels of cell death compared to control experiments. Interventions against the hydroxyl radical with dimethylthiourea (DMTU, 2 mM) or 2,2'-dipyridyl (DPD, 2 mM), a lipid soluble iron chelator, provided no protective effect against the parenchymal cell death. DMTU slightly delayed tile cytotoxic reaction. CONCLUSIONS: These observations suggest that a newly formed microhemorrhage is not necessarily cytotoxic to parenchymal tissue cells. Interstitial microinjections of plasma, derived from whole blood after prolonged exposure to oxygen free radicals or just aging under in vitro conditions, may be cytotoxic to mesenteric parenchymal cells without effective blockade by interventions against the hydroxyl radical.

The leukocyte response to fluid stress.

Leukocyte migration from a hemopoietic pool across marrow endothelium requires active pseudopod formation and adhesion. Leukocytes rarely show pseudopod formation while in circulation. At question then is the mechanism that serves to minimize leukocyte pseudopod formation in the circulation. We tested the hypothesis that fluid shear stress acts to prevent pseudopod formation. When individual human leukocytes (neutrophils, monocytes) spreading on glass surfaces in vitro were subjected to fluid shear stress ( approximately 1 dyn/cm2), an instantaneous retraction of pseudopods was observed. Removal of the fluid shear stress in turn led to the return of pseudopod projection and cell spreading. When steady shear stress was prolonged over several minutes, leukocyte swelling occurs together with an enhanced random motion of cytoplasmic granules and a reduction of cytoplasmic stiffness. The response to shear stress could be suppressed by K+ channel blockers and chelation of external Ca2+. In rat mesentery microvessels after occlusion, circulating leukocytes project pseudopods in free suspension or when attached to the endothelium, even though immediately after occlusion only few pseudopods were present. When flow was restored, pseudopods on adhering leukocytes were retracted and then the cells began to roll and detach from the endothelium. In conclusion, plasma shear stress in the circulation serves to reduce pseudopod projection and adhesion of circulating leukocytes and vice versa reduction of shear stress leads to pseudopod projection and spreading of leukocytes on the endothelium.

Attenuation of oxygen free radical formation and tissue injury during experimental inflammation by P-selectin blockade.

OBJECTIVE: Neutrophilic leukocyte rolling on postcapillary endothelium requires membrane interaction between SLex-containing ligands on neutrophils and P-selectin on endothelial cells. The current sequence of studies was performed to explore the hypothesis that the leukocyte-endothelial rolling interaction not only precedes leukocyte migration but also is accompanied by oxygen free radical production and interstitial cell death in the rat mesentery. METHODS: The ratio of leukocyte rolling velocity on the endothelium of postcapillary venules and centerline red cell velocity was determined after topical application of platelet activating factor (PAF; 10(-8) mol/L). Superoxide formation was determined by an in situ nitroblue tetrazolium reduction to dark blue formazan crystals in the in situ mesentery preparation, and cell death was detected by nuclear staining with propidium iodide. RESULTS: Leukocyte rolling and subsequent adhesion was inhibited with a monoclonal antibody against P-selectin, PB1.3. Superoxide formation, as well as parenchymal cell death, was significantly enhanced in the mesentery after stimulation with platelet activating factor, and both could be significantly attenuated by reduction of the rolling leukocyte-endothelial interaction with PB1.3. CONCLUSIONS: These results provide direct evidence that the interaction of leukocytes and endothelium followed by migration of leukocytes into the interstitium is accompanied by enhanced oxidative stress and parenchymal cell death. Early interruption of the interaction provides significant protection even in the presence of a proinflammatory stimulus.

Microvascular adjustments during irreversible hemorrhagic shock in rat skeletal muscle.

A study was made of microvessel response to hemorrhagic hypotension and the subsequent restoration of blood volume. The experiments were conducted on anesthetized rats in which the cremaster muscle was exteriorized for intravital microscopy. Variables measured during hypotension (40 mm Hg for 60 min) and after blood restoration (120 min observation) included systemic blood pressure, heart rate, arteriolar and venular diameter, sensitivity to epinephrine, velocity and volumetric flow rate. These findings were correlated with 24-hr survival statistics. The response to hemorrhagic hypotension is a reflection of two separate adjustments, cardiac output and peripheral vascular behavior. In survivors, the microvascular sequelae following blood replacement was one of continuous improvement of muscle perfusion, whereas in nonsurvivors the picture was one of progressive deterioration. The consistent hallmark of irreversibility, arteriolar hyposensitivity, was associated with a continuous falling off in mean arterial pressure despite restoration of normal blood volume.

Wall structure of arteries and arterioles feeding the spinotrapezius muscle of normotensive and spontaneously hypertensive rats.

Vessel wall structure in feed arteries and their hierarchical ramifications were investigated in a rat skeletal muscle. Emphasis was placed on the transition of wall structure elements from the axillary and thoracodorsal arteries to the feeder arteries and the arcade and transverse arterioles forming the microcirculation of the spinotrapezius muscle. Semi-thin sections, prepared for light microscopy, and ultra-thin sections for electron microscopy were used to compare mature (15-20 week old) normotensive and hypertensive animals. The results demonstrate a gradual transition of the elastica intima and the smooth muscle from the central arteries towards the arterioles, accompanied by an attenuation of the adventitia. The elastica intima in 60-40 microns arcade arterioles is reduced from a continuous sheet in the central arteries to single fibers oriented parallel to the vessel axis. The multiple layers of smooth muscle cells at the level of the feeder arteries are reduced in the majority of arcade arterioles and in transverse arterioles to a single smooth muscle coat. Comparisons of the smooth muscle mass per unit length of vessel at selected sites of normotensive and spontaneously hypertensive rats show evidence for some degree of wall hypertrophy in the axillary artery, but no evidence for wall hypertrophy in arterioles of the microcirculation. There is no evidence of a pressure-mediated structural medial wall hypertrophy along this peripheral vascular pathway.

Penetration of the systemic blood pressure into the microvasculature of rat skeletal muscle.

A series of arterial micropressure measurements in different skeletal muscles of the Wistar-Kyoto and spontaneously hypertensive rat is presented. The micropunctures were carried out with minimal surgical intervention through small skin incisions and the micropressures were recorded simultaneously with femoral artery pressures. The measurement sites were located at the entry points into the muscles for the proximal and distal supply arteries and at the midpoint of the arteriolar arcade bridge which directly connects these two supply arteries in the center of the muscle parenchyma. In contrast to feed artery pressure values from exteriorized muscles, which in the past have been reported to be as low as 40 mm Hg, the current mean pressure values are substantially higher and in the range between 70 and 100 mm Hg, equivalent to 70 to 90% of the mean systemic pressure. Systolic and diastolic values exhibit comparable trends to the mean pressures and they are similar in muscles at different locations in the body. Although in spontaneously hypertensive rats the absolute pressures were significantly higher compared with their controls, the normalized pressures were virtually identical at the locations used in this study. These data indicate that the absolute pressure in the central arteries of spontaneously hypertensive animals is reduced to a greater degree than in Wistar-Kyoto rats, while in both strains the major pressure reduction in skeletal muscle still occurs in the microcirculation.

Inflammation in chronic venous insufficiency. Is the problem insurmountable?

One of the hallmarks of venous insufficiency is an elevated venous pressure. While a number of mechanisms have been proposed for vascular and parenchymal cell damage following venous pressure elevation, such as white cell infiltration, a key question remains as to what degree venous occlusion and flow interruption per se may constitute a risk factor in venous disease. To gain an insight into this mechanism, we examined the effect of venous occlusion followed by reperfusion. A draining venule (circa 50 micrometer) in the rat mesentery was occluded with a micropipette (1 h) followed by reperfusion (1 h). The procedure serves to raise the microvascular pressure to about 31 mm Hg during the occlusion while the flow is completely stopped in the local venous and capillary network. Parenchymal cell death in the mesentery was monitored by propidium iodide (PI) labeling. The number of PI-positive cells significantly increased predominantly during reperfusion. A 1-week treatment with a micronized purified flavonoid fraction (100 mg/kg/day) served to significantly reduce parenchymal cell death as well as leukocyte rolling, adhesion to postcapillary venule, and migration into the tissue both during occlusion and reperfusion. The results indicate, that even in an initially symptomless tissue, flow reduction combined with microvascular pressure elevation during venous occlusion results in tissue damage not only during reperfusion (as in arterial occlusion) but also during occlusion.

Life and death cell labeling in the microcirculation of the spontaneously hypertensive rat.

Spontaneously hypertensive rats (SHRs) have elevated numbers of apoptotic cells. However, the extent and pattern of cell death at the microvascular level is unexplored. We developed a technique to determine early forms of cell death in vivo in the mesentery by use of the life/death indicator ethidium bromide (EB). The mesenteric microvasculature was superfused with 5 microM EB for a period of 3 min, rinsed and immediately viewed by digital fluorescence microscopy. EB-positive cell structures were observed both in the wall of microvessels as well as in the tissue parenchyma. The microvessels had about 2--4 EB-positive cell structures per 100 microm of vessel length. Larger arterioles (>25 microm) in the SHR had an increased EB-positive structure density. After normalization of the blood pressure in the SHR with adrenalectomy, no significant differences remained between Wistar-Kyoto (WKY) rats and SHRs. After dexamethasone treatment, the adrenalectomized SHRs had a higher EB-positive cell density in the smaller class of microvessels than the WKY rats. In addition, EB-positive cell fragments (0.5--2 microm) were observed in the mesentery microvessel wall, and with TUNEL labeling, they were demonstrated to represent DNA fragments. The percentage of microvessels with EB-positive fragments was higher in the SHR arterioles and capillaries. Capillaries and larger venules (>30 microm) in the SHR had higher levels of cell fragments per vessel length. After adrenalectomy, no significant differences remained between WKY rats and SHRs in any of the microvessel categories. When adrenalectomized rats were treated with dexamethasone, a higher number of EB-positive fragments was detected in the wall of SHR capillaries. These results indicate that the mesentery microcirculation in both strains is subject to an early and nonuniform pattern of cell death, as detected by EB, but is enhanced in selected individual microvascular segments of the SHR by a glucocorticoid-driven mechanism.

Circulating leukocyte counts, activation, and degranulation in Dahl hypertensive rats.

Previous evidence has shown that rats with spontaneous hypertension have on average about twice as many circulating leukocytes in comparison with their normotensive counterparts, the Wistar-Kyoto rats. Since such high levels of leukocytes may increase the risk for vascular complications for hypertensive animals, it is useful to ascertain whether a comparable derangement is present in other forms of hypertension. The present study deals with the properties of the circulating leukocytes in rats exhibiting another form of experimental hypertension; Dahl salt-sensitive (Dahl-S) hypertensive rats were compared with Dahl salt-resistant (Dahl-R) control rats. Measurements were performed to determine the following: circulating hematocrit levels, leukocyte counts, differential counts, number of activated leukocytes (by means of nitro blue tetrazolium [NBT] reduction), leukocyte adhesion in vitro and neutrophil CD-18 expression, alkaline phosphatase activity in individual neutrophils and in the plasma, and myeloperoxidase activity in neutrophils. The experimental cohort consisted of Dahl-S and Dahl-R rats maintained for a 6-week period on a 6% NaCl diet. The results show a highly significant elevation in the number of total leukocytes, neutrophil and monocyte counts, and NBT-positive neutrophils and monocytes in Dahl-S but not Dahl-R rats. There was a significant loss of alkaline phosphatase and myeloperoxidase activity in the neutrophils of the salt-treated Dahl-S rats but not in the neutrophils of the untreated Dahl-S or Dahl-R rats. No significant differences were found in neutrophil adhesion under in vitro test conditions between the two strains maintained on the salt diet.(ABSTRACT TRUNCATED AT 250 WORDS)

A mechanism of oxygen free radical production in the Dahl hypertensive rat.

OBJECTIVE: To determine if oxygen free radicals derived from xanthine oxidase are involved in the development of salt-induced hypertension. Enhanced production of oxygen free radicals may play a role in hypertension by affecting vascular smooth muscle contraction and provide a mechanism for lesion formation. METHODS: Dahl salt-sensitive (Dahl-S) and salt-resistant (Dahl-R) rats were fed either a low-salt, high-salt or high-salt + tungsten diet for 4 wk. In vivo production of superoxide (O2-) was detected by the reduction of a tetranitroblue tetrazolium (TNBT) dye in the rat mesentery, while plasma hydrogen peroxide (H2O2) production levels were determined using a modified electrochemical electrode technique. RESULTS: The tungsten diet lowered the blood pressure of Dahl-S rats compared to high-salt-treated Dahl-S rats, but had no effect on blood pressure in Dahl-R rats. Light absorption of formazan deposits revealed that tungsten-treated Dahl-S rats had reduced TNBT staining along the endothelium of arterioles and venules compared to hypertensive, high-salt-treated Dahl-S rats. In addition, tungsten-treated Dahl-S rats had a lower plasma H2O2 concentration compared to hypertensive, high-salt-treated Dahl-S rats. CONCLUSIONS: These findings indicate that xanthine oxidase-derived oxygen free radicals are involved in the pathogenesis of salt-induced hypertension.

Mechanisms of cell injury in rat mesentery and cremaster muscle.

The events responsible for cell injury after a tissue stimulation are only incompletely understood. The purpose of this study was to examine mechanisms of cell injury in two tissues, rat mesentery and cremaster muscle, after tissue stimulation with N-formylmethionyl-leucyl-phenylalanine (FMLP) and platelet-activating factor (PAF). The response was studied in the same animal in random order using normal and leukopenic rats. The tissues were exteriorized after pentobarbital anesthesia. Five to six vascularized areas were chosen in each tissue, and cell injury and hydroperoxide production were assessed visually by continuous superfusion with 1 microM propidium iodide and 5 microM dichlorofluorescin diacetate (DCFH), respectively. FMLP (1 x 10(-8) M) and then PAF (1 x 10(-8) M) were added to the superfusate, and measurements were made at several time points. The second tissue was then examined using the same protocol. In the cremaster, there was little hydroperoxide production, and the tissue injury was eliminated after leukopenia. Leukopenia had no effect on tissue injury in the mesentery. Although hydroperoxide production was observed, there was no correlation between it and the tissue injury. The level of preactivation showed no correlation with either tissue injury or hydroperoxide production. In light of these results, mast cell degranulation may be an important mechanism of tissue injury in the mesentery.