Lipopolysaccharide reduces intercellular coupling in vitro and arteriolar conducted response in vivo.

Our recent in vitro study (Lidington et al. J Cell Physiol 185: 117-125, 2000) suggested that lipopolysaccharide (LPS) reduces communication along blood vessels. The present investigation extended this study to determine whether any effect of LPS and/or inflammatory cytokines [tumor necrosis factor-alpha, interleukin (IL)-1beta, and IL-6] on endothelial cell coupling in vitro could also be demonstrated for an arteriolar conducted response in vivo. Using an electrophysiological approach in monolayers of microvascular endothelial cells, we found that LPS (10 microg/ml) but not these cytokines reduced intercellular conductance (c(i)) (an index of cell communication) and that LPS together with these cytokines did not further reduce c(i). Also, c(i) was restored after LPS washout, and the LPS-induced reduction was prevented by protein tyrosine kinase (PTK) inhibitors (1.5 microM Tyr A9 and 10 nM PP-2). In our in vivo experiments in arterioles of the mouse cremaster muscle, local electrical stimulation evoked vasoconstriction that conducted along arterioles. LPS in the muscle superfusate did not alter local vasoconstriction but reduced the conducted response. Washout of LPS restored the conducted response, whereas PTK inhibitors prevented the effect of LPS. On the basis of a newly developed mathematical model, the LPS-induced reduction in conducted response was predicted to reduce the arteriolar ability to increase resistance to blood flow. We conclude that LPS can reduce communication in in vitro and in vivo systems comparably in a reversible and tyrosine kinase-dependent manner. Based on literature and present results, we suggest that LPS may compromise microvascular hemodynamics at both the arteriolar responsiveness and the conduction levels.

Ascorbate prevents microvascular dysfunction in the skeletal muscle of the septic rat.

Septic patients have low plasma ascorbate concentrations and compromised microvascular perfusion. The purpose of the present experiments was to determine whether ascorbate improves capillary function in volume-resuscitated sepsis. Cecal ligation and perforation (CLP) was performed on male Sprague-Dawley rats. The concentration of ascorbate in plasma and urine, mean arterial blood pressure, and density of continuously perfused capillaries in the extensor digitorum longus muscle were measured 24 h after surgery. CLP caused a 50% decrease (from 56 +/- 4 to 29 +/- 2 microM) in plasma ascorbate concentration, 1,000% increase (from 46 +/- 13 to 450 +/- 93 microM) in urine ascorbate concentration, 20% decrease (from 115 +/- 2 to 91 +/- 2 mmHg) in mean arterial pressure, and 30% decrease (from 24 +/- 1 to 17 +/- 1 capillaries/mm) in the density of perfused capillaries, compared with time-matched controls. A bolus of intravenous ascorbate (7.6 mg/100 g body wt) administered immediately after the CLP procedure increased plasma ascorbate concentration and restored both blood pressure and density of perfused capillaries to control levels. In vitro experiments showed that ascorbate (100 microM) inhibited replication of bacteria and prevented hydrogen peroxide injury to cultured microvascular endothelial cells. These results indicate that ascorbate is lost in the urine during sepsis and that a bolus of ascorbate can prevent microvascular dysfunction in the skeletal muscle of septic animals. Our study supports the view that ascorbate may be beneficial for patients with septic syndrome.

Structural and functional changes in the microvasculature of disused skeletal muscle.

Skeletal muscle and its microvasculature can exhibit remarkable plasticity in response to decreased functional demand (i.e., muscle disuse). Since the microvascular adaptation to disuse does seem to not depend solely on reduced demand, this review examines the various factors that may be responsible for the observed regression of microvascular structure and function during disuse. There are several animal models of muscle disuse; their common feature is that they are associated with a variety of confounding effects that make the interpretation of the "pure" disuse effect challenging. As well, in clinical studies, the effect of disuse can be difficult to separate from that of various pathologies. Regardless of methodological difficulties, degeneration of the capillary wall, capillary loss, arteriolar remodelling, reduced resting state blood flow, and reduced arteriolar responsiveness to acute vasodilative and vasoconstrictive stimuli have all been observed in disused muscles. The level, and presence/absence of these changes may depend on many factors including the duration of disuse, degree of muscle atrophy, residual muscle activity, microvascular blood flow, release of vasoactive agents from the degenerating muscle, muscle type, and the particular pathology associated with the muscle withering in humans. It is the present challenge to discover the presence/absence of key agents (possibly originating at the interface between the blood stream and the vascular wall, within the extracellular matrix, or the muscle fibres themselves) that alter the intra- and/or inter-cellular signalling to explain the mechanism of adaptation of the microvasculature to skeletal muscle disuse.

Nitric oxide attenuates but superoxide enhances iNOS expression in endotoxin- and IFNgamma-stimulated skeletal muscle endothelial cells.

OBJECTIVE: Endothelial cells (ECs) in septic skeletal muscle may be exposed to large amounts of NO and superoxide generated by the skeletal muscle cells. We tested the hypothesis that inducible nitric oxide synthase (iNOS) induction in ECs (i.e., one of the steps in the septic process) is modulated by extravascularly generated nitric oxide (NO) and superoxide. METHODS: To model sepsis in vitro, monolayers of microvascular ECs derived from rat skeletal muscle were incubated with a mixture of lipopolysaccharide (LPS) (25 ng/mL) and interferongamma (IFNgamma) (100 U/mL) for up to 24 hours. Next, a long-term release NO donor (DETA NONOate), a superoxide-generating mixture (xanthine oxidase/xanthine; XO/X), or DETA + XO/X were added to the LPS + IFNgamma mixture. The iNOS protein and activity, as well as intracellular oxidative stress, were measured at intervals up to 24 hours, whereas the activation of AP-1, IRF-1, and NFkappaB transcription factors was determined at 2 and 24 hours. RESULTS: LPS + IFNgamma caused time-dependent increases in iNOS protein and activity. Increasing concentrations of DETA (up to 500 microM) decreased, whereas XO/X (10 mU per mL/0.1 mM, respectively) markedly enhanced, iNOS expression and activity. DETA attenuated the enhancement by XO/X. Although intracellular oxidative stress was not altered by LPS + IFNgamma, modulations of iNOS expression by DETA, XO/X, and DETA + XO/X correlated with changes in oxidative stress. Among the three transcription factors, only IRF-1 and NFkappaB seemed to be involved in iNOS induction and its modulation by DETA and XO/X. CONCLUSIONS: LPS + IFNgamma can induce iNOS expression in microvascular ECs from rat skeletal muscle, whereas NO and superoxide modulate this expression. On the basis of these observations we suggest that NO and superoxide from the extravascular tissue may play a key role in the inflammatory response of septic ECs.

A new in vitro model for agonist-induced communication between microvascular endothelial cells.

Microvascular endothelial cells (MECs) grown in Matrigel form capillary-like structures. We hypothesized that these "capillaries" better mimic communication properties of microvessels than conventional cell monolayers. MECs were isolated from the rat hindlimb skeletal muscle. Functional communication was tested by visualizing the spread of microinjected 6-carboxyfluorescein (CF) dye and by measuring a conducted change of membrane potential after micropipette application of 500 mM KCl or 10 mM adenosine triphosphate (ATP) on the capillary and monolayer. MECs grown under both conditions were dye-coupled, as demonstrated by the spread of CF injected into a single cell. The membrane potential of cells grown in capillaries (-59 +/- 5 mV) was significantly greater than that of cells grown in monolayers (-24 +/- 2 mV). KCl and ATP caused local depolarization (18 +/- 3 mV) and hyperpolarization (21 +/- 3 mV) in capillaries that yielded conducted 13 +/- 3 mV depolarization and 15 +/- 5 mV hyperpolarization at a 300-microm distal site, respectively. In monolayers, local and distal responses to agonists were 3- to 6-fold and 9- to 10-fold less, respectively, than the corresponding responses in capillaries. Cells grown under both conditions expressed connexin 43, as demonstrated by immunohistochemistry and Western blotting. We conclude that cells grown in capillaries yield substantially larger local and communicated responses than cells in monolayers and thus offer a more sensitive model for mechanistic studies of MEC communication.

Pulmonary microvascular changes during sepsis: evaluation using intravital videomicroscopy.

A variety of pulmonary microvascular changes occur during sepsis. These include abnormal vascular reactivity, leukocyte sequestration, and leakage of protein into the alveoli. Based on intravital videomicroscopy we have developed a method to directly assess in vivo the changes that occur in the pulmonary microcirculation in a rat model of sepsis. Male Sprague-Dawley rats were assigned to control or sepsis groups. Sepsis was induced by cecal ligation and perforation. Twenty four hours later, rats were anesthetized, mechanically ventilated, and their lung prepared for intravital videomicroscopy. A specially designed transparent thoracic window was inserted into the chest wall. The dependent surface of the lung was superfused with saline solution and visualized with an inverted microscope. Vascular contractility, to phenylephrine, (PE) and hypoxia of small (15-25 microm in diameter) and medium (40-50 microm) arterioles was examined. Leukocyte traffic in the pulmonary microcirculation was studied after in vivo labeling of leukocytes with Rhodamine and visualized with fluorescence microscopy. Leak of albumin into the alveolar space was measured with FITC-labeled albumin and fluorescence microscopy. Both small and medium sized pulmonary arterioles in septic animals exhibited attenuated vascular contractility to phenylephrine, but only medium-sized arterioles displayed hypocontractility to hypoxia. Further, in septic animals there was an increase in both the number of stationary leukocytes in the pulmonary microcirculation and an increase in alveolar capillary protein leak. We conclude: (1) direct visualization of the pulmonary microvascular pressor response to hypoxia and PE in the rat is possible using this technique, (2) similar to previous in vitro studies with larger vessels, pulmonary arterioles have an attenuated contractile response to PE and hypoxia in sepsis, and (3) there is an increase in both the number of stationary leukocytes and protein leak into the alveolus in the lungs of septic animals.

Endotoxin increases intercellular resistance in microvascular endothelial cells by a tyrosine kinase pathway.

Gap junction communication between microvascular endothelial cells has been proposed to contribute to the coordination of microvascular function. Septic shock may attenuate microvascular cell-to-cell communication. We hypothesized that lipopolysaccharide (LPS) attenuates communication between microvascular endothelial cells derived from rat hindlimb skeletal muscle. Endothelial cells grown in monolayers expressed mRNA for connexin 37, 40, and 43. The expression of connexin 43 protein was confirmed, but connexin 40 protein was not detected by immunocytochemistry or immunoblot analysis. Intercellular resistance between cells of the monolayer, calculated using a Bessel function model, was increased from 3.3 to 5.3 MOmega by LPS. The effect was seen after 1 h of exposure and required a minimum concentration of 10 ng/ml. Intercellular resistance returned to normal 1 h following removal of LPS. Neither the response to LPS, nor its reversal, was blocked by the protein synthesis inhibitor cycloheximide (10 microg/ml). Pretreatment of monolayers with the tyrosine kinase inhibitors PP-2 (10 nM), lavendustin-C (1 microM), and geldanamycin (200 nM) prevented this LPS response; geldanamycin was also able to reverse the response. Inhibitors of MAP kinases, PD 98059 (5 microM) and SB 202190 (5 microM), and PKC (500 nM bisindolylmaleimide I) were unable to block the LPS response. We propose that LPS attenuates cell-to-cell communication through a signaling pathway that is tyrosine kinase dependent.

Nitric oxide produced via neuronal NOS may impair vasodilatation in septic rat skeletal muscle.

Impaired vascular responsiveness in sepsis may lead to maldistribution of blood flow in organs. We hypothesized that increased production of nitric oxide (NO) via inducible nitric oxide synthase (iNOS) mediates the impaired dilation to ACh in sepsis. Using a 24-h cecal ligation and perforation (CLP) model of sepsis, we measured changes in arteriolar diameter and in red blood cell velocity (V(RBC)) in a capillary fed by the arteriole, following application of ACh to terminal arterioles of rat hindlimb muscle. Sepsis attenuated both ACh-stimulated dilation and V(RBC) increase. In control rats, arteriolar pretreatment with the NO donors S-nitroso-N-acetylpenicillamine or sodium nitroprusside reduced diameter and V(RBC) responses to a level that mimicked sepsis. In septic rats, arteriolar pretreatment with the "selective" iNOS blockers aminoguanidine (AG) or S-methylisothiourea sulfate (SMT) restored the responses to the control level. The putative neuronal NOS (nNOS) inhibitor 7-nitroindazole also restored the response toward control. At 24-h post-CLP, muscles showed no reduction of endothelial NOS (eNOS), elevation of nNOS, and, surprisingly, no induction of iNOS protein; calcium-dependent constitutive NOS (eNOS+nNOS) enzyme activity was increased whereas calcium-independent iNOS activity was negligible. We conclude that 1) AG and SMT inhibit nNOS activity in septic skeletal muscle, 2) NO could impair vasodilative responses in control and septic rats, and 3) the source of increased endogenous NO in septic muscle is likely upregulated nNOS rather than iNOS. Thus agents released from the blood vessel milieu (e.g., NO produced by skeletal muscle nNOS) could affect vascular responsiveness.

Differential microvascular response to disuse in rat hindlimb skeletal muscles.

The aim of the study was to address discrepant findings in the literature regarding coupling between decreased functional demand during disuse and reduced capillarity. We previously reported [K. Tyml, O. Mathieu-Costello, and E. Noble. Microvasc. Res. 49: 17-32, 1995] that severe disuse of rat extensor digitorum longus (EDL) muscle caused by a 2-wk application of tetrodotoxin (TTX) on the sciatic nerve is not accompanied by capillary loss. Using the same animal model, the present study examined whether this absence of coupling could be explained in terms of 1) too short a duration of disuse and 2) muscle-specific response to disuse. Fischer 344 rats were exposed to either no treatment (control) or to 2- or 8-wk TTX applications. Fiber size, capillary density per fiber cross-sectional area, and capillary-to-fiber (C/F) ratio were determined by morphometry in the EDL muscle (control, 2- and 8-wk groups) and in the superficial portion of medial gastrocnemius (Gas) muscle (control, 2 wk). In both muscles, microvascular blood flow was evaluated by intravital microscopy [red blood cell velocity in capillaries (V(RBC))] and by laser Doppler flowmetry (LDF). Regardless of duration of TTX application or muscle type, TTX-induced disuse resulted in a significant reduction of fiber area (44-71%). However, capillary density increased in EDL muscle (both at 2 and 8 wk) but not in Gas muscle. C/F ratio decreased in EDL muscle at 8 wk (18%) and in Gas muscle (39%). This indicates that the effect on capillarity depended on duration of disuse and on muscle type. V(RBC) and LDF signal were significantly larger in EDL than in Gas muscle. Analysis of change in capillarity vs. V(RBC) suggested that the outcome of disuse may be modulated by blood flow. We conclude that the duration of skeletal muscle disuse per se does not dictate capillary loss, and we hypothesize that discrepant findings of coupling between functional demand and capillarity could be due to the presence/absence of flow-related angiogenesis superimposed on the capillary removal process during disuse.

Local L-NAME decreases blood flow and increases leukocyte adhesion via CD18.

Local inhibition of nitric oxide (NO) synthesis with L-arginine analogs such as NG-nitro-L-arginine methyl ester (L-NAME) decreased red blood cell velocity (VRBC) in capillaries and increased leukocyte adhesion in postcapillary venules in rat skeletal muscle. The goal of the present study was to determine the mechanism of this response to L-NAME. Using intravital videomicroscopy, we examined blood flow in the surface microvasculature of rat extensor digitorum longus muscle. L-NAME (30 mM in the pipette) locally applied to capillaries (300 microns from feeding arteriole) reduced VRBC [control VRBC = 244 +/- 53 (SE) microns/s; delta VRBC = -52 +/- 8%] and increased leukocyte adhesion (from 0.2 +/- 0.01 to 1.3 +/- 0.3 cells/100 microns) in control animals. Systemic pretreatment with fucoidan (selectin binder), superoxide dismutase and catalase (extracellular antioxidants), dimethylthiourea (intracellular antioxidant), or ketotifen (mast cell stabilizer) did not alter this response. Pretreatment with CL26, an anti-CD18 antibody, abolished the L-NAME response. Our results suggest that L-NAME increased leukocyte-endothelial interactions via an effect on CD11/CD18 or its ligand, intercellular adhesion molecule.

Capillary and arteriolar responses to local vasodilators are impaired in a rat model of sepsis.

Although sepsis is known to affect vascular function, little is known about changes at the capillary level. We hypothesized that sepsis attenuates the "upstream" arteriolar response to vasoactive agents applied locally to capillaries. Sepsis in rats was induced by cecal ligation and perforation. After 24 h, extensor digitorum longus muscle was prepared for intravital microscopy. Phenylephrine (PE, 10 mM) and acetylcholine (ACh, 10 mM) were applied iontophoretically on terminal arterioles and on their downstream daughter capillaries (300 micron from arteriole). There was no significant difference between control and septic rats in baseline arteriolar diameters [8.0 +/- 0.6 vs. 9.8 +/- 0.8 (SE) micron- or baseline red blood cell velocity (VRBC) in perfused daughter capillaries (255 +/- 10 vs. 264 +/- 13 micron/s). Application of PE onto arterioles resulted in comparable constrictions (i.e., -22% diameter change) and VRBC reductions (-100%) in control and septic rats. In contrast, arteriolar diameter and VRBC increases after application of ACh were attenuated in sepsis (diameter: from 41 to 14%; VRBC: from 67 to 24%). Application of PE onto the capillary reduced VRBC to the same level (-100%) in both groups, whereas application of ACh increased VRBC less in septic than in control rats (20 vs. 73%). On the basis of arteriolar-capillary pair stimulations, sepsis affected VRBC responses to ACh more in the capillary than in the arteriole. When the adenosine analog 5'-N-ethylcarboxamidoadenosine (0.1 mM) was used instead of ACh, similar effects of sepsis were seen. To test for a possible involvement of inducible NO synthase (iNOS) in sepsis-induced attenuated ACh responses, arterioles and capillaries in septic animals were locally pretreated with the iNOS blocker aminoguanidine (10 mM). In both microvessels, aminoguanidine restored the ACh response to the control level. We conclude that impaired capillary VRBC and arteriolar diameter responses to vasodilators applied to capillaries in septic rat skeletal muscle were due to dysfunction at arteriolar and capillary levels. The study underscores the significant role iNOS/NO may play in sepsis-induced alteration of vascular reactivity in vivo.

Capillary adrenoceptors in rat skeletal muscle.

The purpose of this study was to examine whether functional alpha- and beta-adrenoceptors exist on capillaries of rat skeletal muscle, and further to determine which subtype of these receptors predominates on these capillaries. Using intravital video microscopy, we measured red blood cell velocity (VRBC) responses in capillaries of rat extensor digitorum longus muscle (EDL) following a local application of these agonists: norepinephrine (NE; alpha 1, alpha 2; 10(-7) to 3 x 10(-3) M), phenylephrine (PE; alpha 1; 3 x 10(-4) to 10(-2) M), clonidine (CLO; alpha 2; 3 x 10(-3) to 10(-2) M), UK14304 (alpha 2; 3 x 10(-4) to 10(-2) M), and isoproterenol (IPR; beta 1, beta 2; 10(-7) to 3 x 10(-3) M). Responses to NE (10(-5) M) were also measured after a local pretreatment with prazosin (alpha 1 antagonist; 10(-5) to 10(-3) M) and rauwolscine (alpha 2 antagonist; 3 x 10(-4) to 3 x 10(-2) M), while responses to IPR (10(-5) M) were measured after local atenolol (ATE; beta 1 antagonist; 10(-3) to 10(-2) M) and butoxamine (BUT; beta 2 antagonist; 10(-3) to 10(-2) M) pretreatment. The overall control VRBC was 226 microns/sec. NE, PE, CLO, and UK14304 resulted in concentration-dependent decreases of VRBC (from -12 to -89%) from the control level, while IPR caused concentration-dependent increases (17 to 174%). PE reduced VRBC to a larger degree than CLO and UK14304. NE-induced VRBC responses tended to be attenuated more by prazosin than by rauwolscine. Both ATE (10(-2) M) and BUT (10(-3) and 10(-2) M) alone decreased VRBC. However, only ATE significantly attenuated the IPR-induced VRBC responses. These results suggest that the capillary of rat EDL muscle has alpha- and beta-adrenoceptors. From the two alpha-adrenoceptor subtypes, the capillary may be predominated by the alpha 1-adrenoceptors.

Evidence for K+ channels involvement in capillary sensing and for bidirectionality in capillary communication.

Although the capillary sensing and communication phenomenon has been characterized, its mechanism is not clear. It has been hypothesized that capillary sensing involves a membrane potential change in the capillary endothelium and/or pericyte and that communication represents an electrotonic spread of this change along the capillary. The goal of the present study was to address this hypothesis by examining the presence of K+ channels on the capillary and by determining bidirectionality of communication. Using intravital microscopy, we locally applied K+ (100 mM), acetylcholine (ACh; 3 mM), and norepinephrine (NE; 0.3 mM) on capillaries, 400-500 microns downstream from the arteriole, at the surface of the sartorius muscle in anesthetized frogs. Responses were measured in terms of red blood cell velocity (VRBC) changes in the stimulated capillary (control prestimulation VRBC ranged from 110 to 770 microns/sec). K+ and ACh caused significant 19 and 38% increases in VRBC, while NE caused a -46% decrease, respectively. The K+ response was blocked by local pretreatment with K+ channel blocker BaCl2 (1 microM) and by pretreatment with tetraethyl ammonium chloride (TEA; 5 mM). Responses to ACh and NE were attenuated by pretreatment with 1 microM BaCl2 (to 1%) and with 50 mM TEA (to -25%), respectively. In a separate experiment, NE (3 mM) application on the capillary 500 microns away from the draining venule (capillary occluded) caused a 19% venular constriction (i.e., similar to a reported 21% arteriolar constriction caused by the NE stimulus). We concluded that (i) K+ channels were present on the capillary and (ii) capillary communication was bidirectional. We interpreted these results to be consistent with the above hypothesis of membrane potential change and electrotonic spread.

Comparable effects of arteriolar and capillary stimuli on blood flow in rat skeletal muscle.

Although the capillary wall represents an active interface between blood and tissue, the potential role of the capillary in blood flow control has not been determined. The goals were (i) to establish the presence of the capillary sensing and communication phenomenon (Dietrich and Tyml, Microvasc. Res. 43, 87-99, 1992) in mammalian microvasculature and (ii) to determine the relative sensitivity of the capillary and the arteriole to locally applied vasoactive agents. Using intravital video microscopy, norepinephrine (NE; 10(-7)-3 x 10(-3) M), acetylcholine (ACh; 10(-4)-10(-2) M), or bradykinin (BK; 10(-9)-10(-3) M) was applied via micropipettes on capillaries (300 microm downstream from feeding arterioles) or on arterioles, at the surface of the extensor digitorum longus muscle of anesthetized rats. Red blood cell velocity (VRBC) in capillaries and arteriolar diameters was measured from video recordings. The overall control VRBC and control diameter were 190 microm/sec and 8.3 microm, respectively. NE applied on the capillary caused a dose-dependent reduction in VRBC (up to 100%, i.e., 0 microm/sec) via a constriction of the feeding arteriole. Both ACh and BK applied on the capillary caused a dose-dependent increase in VRBC (up to 115%) via arteriolar dilation. Based on two different approaches, these responses could not be explained in terms of diffusion of agents from capillary to the arteriole. When testing for the relative sensitivity of the arteriole and the capillary, application of NE and ACh on arterioles caused VRBC and diameter responses similar to those of capillary stimulations. When testing for the speed of response in these two microvessels, the time of noticeable VRBC change after NE (i.e., 10% from control) was also similar. We concluded that (i) the rat skeletal muscle capillary could respond to a variety of locally applied materials and (ii) the capillary could have as profound an effect on microvascular flow as the arteriole. Thus capillary could have the potential to participate in microvascular flow control.

Ascorbate uptake by microvascular endothelial cells of rat skeletal muscle.

OBJECTIVE: In several systems, exogenous ascorbate (reduced vitamin C) has been shown to protect against microvascular injury induced by reactive oxygen species. Since skeletal muscle is relatively resistant to oxidative injury, it is possible that under physiological conditions endogenous ascorbate in the muscle microvasculature affords such protection. To examine the ability of microvascular endothelium to accumulate ascorbate, we aimed (1) to develop an in vitro model of microvascular endothelial cells derived from rat hindlimb skeletal muscles and (2) to investigate the uptake and steady-state concentration of ascorbate in these cells. METHODS: Microvascular cells were enzymatically dissociated, isolated on a density gradient, and grown in serum-supplemented medium. After passaging, they were tested for formation of tube-like structures, coagulation factor VIII antigen expression, Griffonia simplicifolia lectin I-isolectin B4 binding, and acetylated low-density lipoprotein (LDL) uptake. Concentrations of reduced ascorbate were measured by high-performance liquid chromatography (HPLC) with electrochemical detection. Transport activity was assessed on the basis of the initial rate [14C]ascorbate uptake. RESULTS: The cultured cells tested positively for factor VIII antigen expression, lectin binding, LDL uptake, and tube formation. Although these cells did not synthesize ascorbate de novo, they accumulated reduced vitamin C when it was added to the culture medium. The initial rate of [14C]ascorbate uptake was 0.9 mumol/g cell protein 10 min when cells were incubated with 10 microM of the radiolabeled vitamin. This uptake was Na+-dependent and was blocked by the organic anion transport inhibitor sulfinpyrazone, but was not acutely affected by glucose. Following incubation with a physiological concentration of vitamin C (100 microM L-ascorbate), cells accumulated a high concentration of ascorbate within 6 h (approximately 16 mM at steady-state). Steady-state cellular ascorbate concentration was also dependent on extracellular Na+ and sensitive to sulfinpyrazone. CONCLUSIONS: Microvascular cells derived from rat hindlimb muscles demonstrated endothelial characteristics. These cells accumulated reduced vitamin C by means of Na+-dependent ascorbate transporters, which are distinct from hexose carriers. The high endothelial ascorbate concentration at steady-state is consistent with the role of ascorbate as a major antioxidant in the skeletal muscle microvasculature.

Nitric oxide release in rat skeletal muscle capillary.

Nitric oxide (NO) has been shown to be a potent vasodilator released from endothelial cells (EC) in large blood vessels, but NO release has not been examined in the capillary bed. Because the capillary bed represents the largest source of EC, it may be the largest source of vascular NO. In the present study, we used intravital microscopy to examine the effect of the NO synthase inhibitor, NG-nitro-L-arginine methyl ester (L-NAME), on the microvasculature of the rat extensor digitorum longus muscle. L-NAME (30 mM) applied locally to a capillary (300 micron(s) from the feeding arteriole) reduced red blood cell (RBC) velocity [VRBC; control VRBC = 238 +/- 58 (SE) micron/s; delta VRBC = -76 +/- 8%] and RBC flux (4.4 +/- 0.7 to 2.8 +/- 0.7 RBC/s) significantly in the capillary, but did not change feeding arteriole diameter (Dcon = 6.3 +/- 0.7 micron, delta D = 5 +/- 7%) or draining venule diameter (Dcon = 10.1 +/- 0.6 micron, delta D = 4 +/- 2%). Because of the VRBC change, the flux reduction was equivalent to an increased local hemoconcentration from 1.8 to 5 RBCs per 100 micron capillary length. L-NAME also caused an increase in the number of adhering leukocytes in the venule from 0.29 to 1.43 cells/100 micron. L-NAME (30 mM) applied either to arterioles or to venules did not change capillary VRBC. Bradykinin (BK) locally applied to the capillary caused significant increases in VRBC (delta VRBC = 111 +/- 23%) and in arteriolar diameter (delta D = 40 +/- 5%). This BK response was blocked by capillary pretreatment with 30 mM L-NAME (delta VRBC = -4 +/- 27%; delta D = 5 +/- 9% after BK). We concluded that NO may be released from capillary EC both basally and in response to the vasodilator BK. We hypothesize that 1) low basal levels of NO affect capillary blood flow by modulating local hemoconcentration and leukocyte adhesion, and 2) higher levels of NO (stimulated by BK) may cause a remote vasodilation to increase microvascular blood flow.

Capillary ultrastructure and functional capillary density.

We briefly summarize our findings on alterations in capillary structure in skeletal muscle and heart in response to up to 30 min of ischemia. In frog sartorius muscle, reactive hyperemia was absent in atrophy. Increased spatial heterogeneity of red cell velocity in individual capillaries was observed, as were increases in the percentage of capillaries with damaged endothelium and white cell volume density in capillaries. Examination of the effect of aging on the response of the vascular bed to 30 min ischemia in extensor digitorum longus muscle of Fisher 344 rats suggested that the lack of postischemic hyperemia and structural alterations in frog muscle were related to disuse rather than aging per se. However, the specific study of disuse in rat extensor digitorum longus muscle after chronic application of tetrodotoxin revealed both capillary damage and a postischemic hyperemic response. It suggested an effect of the degree of tissue deterioration on the hyperemic response after short-term disuse in rat muscle, compared to longer-term atrophy in frog. Morphometric data in isolated rabbit heart suggested a link between microvascular compression as a result of tissue edema and decreased perfusion after 30 min total ischemia.

Heterogeneity of red blood cell velocity in skeletal muscle decreases with increased flow.

OBJECTIVE: Effective material exchange between blood and tissue depends on the heterogeneity of microvascular flow. The objective was to address inconsistencies between intravital studies regarding this dependency. We tested the hypothesis that heterogeneity of red blood cell velocity (VRBC) in capillary beds varies with the strength of metabolic stimulus and with capillary bed geometry. METHODS: We used videomicroscopy to measure VRBC in a bed of 10-24 capillaries at the surface of extensor digitorum longus (EDL) muscle in anesthetized rats. The coefficient of variation (CV = standard deviation/mean; an index of spatial heterogeneity) was computed in the same bed before and after (i) 1, 2, 4, or 8 Hz supramaximal muscle contraction or (ii) adenosine superfusion (10(-7)-10(-3) M). Beds with or without arteriolar-venular capillary shunts were used. RESULTS: Although control VRBC differed between beds (shunt: 232 microns/s; no shunt: 130 microns/s), the percentage increases in postcontraction VRBC did not (range: 111-326%). In both beds, control CV varied greatly (overall range: 28-117%) and 2-8 Hz muscle contractions reduced CV significantly by 25%. Similar results were obtained for adenosine. In confirmatory experiments using the rat cremaster muscle, contractions (4 Hz) and adenosine (10(-4) M) also reduced CV. Based on all data, CV = 63-0.022 VRBC (r = 0.82, P < 0.001). CONCLUSIONS: The heterogeneity of VRBC decreased with metabolic stress, regardless of capillary bed geometry. We propose that both the large variability in control CV and the relatively shallow dependence of CV on velocity could be responsible for the present inconsistencies between intravital studies.