Endothelial cell-specific knockout of connexin 43 causes hypotension and bradycardia in mice

Connexin 43 (Cx43) is a protein expressed in a variety of mammalian tissues. However, the lack of specific blockers and the absence of known genetic mutants have hampered the investigation of the function of this protein. Cx43-null mice die shortly after birth, thus preventing functional studies in vivo. Here, we report the generation and characterization of a vascular endothelial cell-specific deletion of the Cx43 gene (VEC Cx43 KO) in mice by using the loxP/Cre system. Using homologous recombination, a mouse line was created carrying loxP sites flanking exon 2 of the Cx43 gene ("floxed" mice). To produce cell specific deletion of the Cx43 gene, these mice were crossed with animals from a line carrying the Tie 2-Cre transgene. The homozygous VEC Cx43 KO mice survived to maturity. However, they were hypotensive and bradycardic when compared with heterozygous VEC Cx43 KO mice, or to the floxed Cx43 gene mice. The hypotension was associated with marked elevation of plasma nitric oxide (NO) levels as well as elevated plasma angiotensin (Ang) I and II. We hypothesize that endothelial cell Cx43 plays a key role in the formation and/or action of NO, and that the elevation of Ang II is a secondary event. The specific cellular basis for the hypotension remains to be established, but our findings support the idea that endothelial Cx43 gap junctions are involved in maintaining normal vascular function; moreover, these animals provide the opportunity to determine more clearly the role of endothelial Cx43 in vascular development and homeostasis.

Possible cytotoxic effect of the expression of a connexin 43-LacZ fusion gene in cells of the vascular wall

Connexin 43 (Cx43) gap junctions are hypothesized to play a key role in many aspects of vascular function. In an effort to evaluate the importance of connexins in vascular function we took advantage of the fact that a Cx43-LacZ fusion protein has been reported to effectively reduce dye transfer in NIH 3T3 fibroblasts by acting as a dominant negative construct. We explored the use of this dominant negative construct in cultured vascular smooth muscle (VSM) cells and in transgenic mice. We examined the viability of cultured VSM cells expressing the Cx43-LacZ fusion protein under the control of a cytomegalovirus promoter. We also selectively expressed the dominant negative construct in the endothelial cells of transgenic mice under the control of a Tie 2 promoter. Transient transfection of cultured VSM cells led to good initial expression of the Cx43-LacZ fusion protein as evidenced by X-gal staining. Following 10 days of G418 selection, 300 cell clones were examined. None expressed the fusion protein, based on X-gal staining and Western blot analysis, but all contained the transgene, based on PCR analysis. The fusion protein was expressed in a few isolated cells, suggesting that cell division was inhibited by the fusion protein. In agreement with this finding was the fact that expression of the Cx43-LacZ fusion protein was not observed in any of seven Tie 2-Cx43-LacZ transgenic mouse lines. Moreover, a very low yield of mice carrying the transgene was observed (7/136; 5.1%). Analysis of 65 embryos at embryonic day 11.5 showed similar results. These data strongly suggest that the expression of the Cx43-LacZ fusion protein prevents the formation of both stable clones and transgenic animals. This may be due to a cytotoxic effect of the dominant negative construct or to the fact that successful cell propagation is not possible if gap junctional transmission is completely blocked.

TNF-alpha increases entry of macromolecules into luminal endothelial cell glycocalyx

The endothelial luminal glycocalyx has been largely ignored as a target in vascular pathophysiology even though it occupies a key location. As a model of the inflammatory response, we tested the hypothesis that tumor necrosis factor-alpha (TNF-alpha) can alter the properties of the endothelial apical glycocalyx. In the intact hamster cremaster microcirculation, fluorescein isothiocyanate (FITC)-labeled Dextrans 70, 580, and 2,000 kDa are excluded from a region extending from the endothelial surface almost 0.5 micrometer into the lumen. This exclusion zone defines the boundaries of the glycocalyx. Red blood cells (RBC) under normal flow conditions are excluded from a region extending even farther into the lumen. The cremaster microcirculation was pretreated with topical or intrascrotal applications of TNF-alpha. After infusion of FITC-dextran, FITC-albumin, or FITC-immunoglubulin G (IgG) via a femoral cannula, microvessels were observed with bright-field and fluorescence microscopy to obtain estimates of the anatomic diameters and the widths of fluorescent tracer columns and of the RBC columns (means +/- SE). After 2 h of intrascrotal TNF-alpha exposure, there was a significant increase in access of FITC-Dextrans 70 and 580 to the space bounded by the apical glycocalyx in arterioles, capillaries, and venules, but no significant change in access of FITC-Dextran 2,000. The effects of TNF-alpha could be observed as early as 20 min after the onset of topical application. TNF-alpha treatment also significantly increased the penetration rate of FITC-Dextran 40, FITC-albumin, and FITC-IgG into the glycocalyx and caused a significant increase in the intraluminal volume occupied by flowing RBC. White blood cell adhesion increased during TNF-alpha application, and we used the selectin antagonist fucoidan to attenuate leukocyte adhesion during TNF-alpha stimulation. This did not inhibit the TNF-alpha-mediated increase in permeation of the glycocalyx. These results show that proinflammatory cytokines can cause disruption of the endothelial apical glycocalyx, leading to an increased macromolecular permeation in the absence of an increase in leukocyte recruitment.

TNF-alpha modulates arteriolar reactivity secondary to a change in intimal permeability

OBJECTIVE

Inflammatory stimuli are often associated with marked changes in vascular reactivity. Tumor necrosis factor-alpha (TNF-alpha) is and important inflammatory cytokine with diverse effects including the ability to increase vascular endothelial cell permeability and to alter the structure of the endothelial cell glycocalyx. We have previously shown that arteriolar sensitivity to vasoactive materials is influenced by a barrier property of the arteriolar endothelium, and here we test the hypothesis that TNF-alpha might increase intimal permeability and thereby increase the access of circulating arginine-vasopressin (AVP) to vascular smooth muscle. Our objective in the current work was to show that TNF-alpha-mediated modulation of intimal cell permeability may produce both quantitative and qualitative alterations in vascular reactivity to arginine-vasopressin.

METHODS

Hamster cheek pouch arterioles (approximately 65 microm, i.d.) were double-cannulated and perfused. [Arg8]-vasopressin was applied selectively to either the luminal or the adventitial surface of isolated cannulated arterioles. The reactivity of the arterioles to vasopressin was determined in the presence and absence of TNF-alpha (0.625 microg/mL; 1 hour).

RESULTS

Adventially applied AVP induced a concentration-dependent vasoconstriction with a threshold of approximately 1 pM, and a maximal constriction at 10 nM. In contrast, luminally applied AVP induced a biphasic response, showing a modest vasodilation in the range of 1 to 100 pM, and constrictions at doses higher than 1 nM. Maximal constrictions were not obtained with luminal doses of AVP as high as 1 microM; (i.e., at doses 100-fold higher than those that produced maximal responses with adventitial application). Dilations induced by luminal application of AVP were significantly attenuated by 10 microM Nomega-nitro-L-arginine methyl ester (L-NAME), but were not altered by 10 microM indomethacin. After treatment with TNF-alpha, the concentration-response curve for luminally applied AVP showed a more pronounced constriction and the dilator component of the agonist was eliminated. There was no change in the reactivity to adventitially applied AVP or to adventitial applications of acetylcholine. Nonspecific increases in endothelial cell permeability induced by 3-[(3-chloroamino-dopropyl)-dimethylamino]-1-propanesulfonate (CHAPS) also eliminated the potency differences between luminal and adventitial drug application. Following TNF-alpha treatment and loss of the dilator component of the response to AVP, L-NAME was still capable of reducing the arteriolar sensitivity to ACh, thus showing that the endothelial cell machinery for NO production was intact following TNF-alpha treatment.

CONCLUSION

Our findings show that the reactivity of intact resistance vessels to agonists that have both endothelial-dependent and smooth muscle cell-dependent components will be complex. Reactivity is the summation of: 1) the relative sensitivities of smooth muscle and endothelial cells to AVP, 2) the release of nitric oxide or other mediators from endothelium, and 3) the restricted access of intraluminal AVP to arteriolar smooth muscle cells. Thus, cytokines, and perhaps other materials that regulate endothelial cell permeability, can modify arteriolar reactivity by altering transendothelial cell access of luminal stimuli to the smooth muscle cells, as well as by acting directly on smooth muscle or by influencing the production of endothelial cell-derived vasoactive materials. In the case of agonists that have an endothelial cell dilator component as well as a smooth muscle constrictor component, this may result in a qualitative change in response as is shown here with AVP.

Integrated Ca(2+) signaling between smooth muscle and endothelium of resistance vessels

Cell-cell communication in the arteriolar wall was examined using the Ca(2+)-sensitive indicator fura-2 and the Ca(2+) buffer BAPTA as means of measuring and buffering cellular Ca(2+). The experiments focused on the role of endothelial cell [Ca(2+)](i) in modulating phenylephrine (PE)-induced contractions in in vitro arterioles of the hamster cremaster. Fura-2-AM and BAPTA-AM were applied intraluminally to accomplish endothelium-specific loading. PE was applied to short segments of arterioles using pressure-pulse ejection from a micropipette. Under control conditions at the site of stimulation, PE elicited a strong vasoconstriction preceded by an increase in endothelial cell [Ca(2+)](i). A very small biphasic conducted response was observed at sites upstream from the stimulation site. BAPTA sharply reduced the measured Ca(2+) response in the endothelium. This was associated with an enhanced local contractile response. In addition, the biphasic conducted response was converted into a strong conducted vasoconstriction. PE caused an initial rise in smooth muscle [Ca(2+)](i) at the stimulated site, which was followed by a rapid decrease below baseline. Endothelial cell loading of BAPTA had minimal effect on the initial [Ca(2+)](i) peak but eliminated the secondary decrease in smooth muscle [Ca(2+)](i). Intraluminal application of charybdotoxin plus apamin mimicked the change in vasomotor state induced by BAPTA. These data lead us to hypothesize that, after smooth muscle stimulation, intercellular Ca(2+) signaling between smooth muscle and endothelium causes a secondary rise in endothelial cell Ca(2+), which triggers a hyperpolarizing event and initiates a conducted vasodilation. We conclude that smooth muscle and endothelium operate as a functional unit in these vessels.

Blockade of connexin 43 expression by stable transfection of antisense cDNA in cultured vascular smooth muscle cells

Gap junctional communication is involved in embryogenesis, cell growth control, and coordinated contraction of cardiac myocytes. It has been hypothesized that gap junctions coordinate responses of vascular cells to constrictor or dilator stimulation. Three connexin (Cx) proteins, 37, 40, and 43, are found in the vasculature. Cx43 gap junctions are widely distributed along the vascular tree, although a precise physiologic role in vascular function is unknown because of a lack of specific functional inhibitors and of suitable animal models. To investigate the role of Cx43 in intercellular communication among vascular smooth muscle (VSM) cells, we selectively modified the expression of the Cx43 gene using antisense cDNA stable transfections in culture. Results show that in cells stably transfected with antisense Cx43 cDNA, gene expression of Cx43 could be reduced to 20% of that observed in vector-transfected cells. In spite of the mRNA and protein reduction, the antisense Cx43 cDNA-transfected cells did not show a significant reduction in dye transfer or a difference in cell growth rate as compared with control. These results suggest either that the residual amount of Cx43 protein is sufficient for dye transfer and growth control or that the dye transfer in these cells can be mediated by Cx40 or other connexin proteins. Therefore, more potent approaches, such as dominant negative and gene knockout, are required to fully block gap junctional communication in VSM cells.

Microvascular dilation in response to occlusion: a coordinating role for conducted vasomotor responses

In rat cremasteric microcirculation, mechanical occlusion of one branch of an arteriolar bifurcation causes an increase in flow and vasodilation of the unoccluded daughter branch. This dilation has been attributed to the operation of a shear stress-dependent mechanism in the microcirculation. Instead of or in addition to this, we hypothesized that the dilation observed during occlusion is the result of a conducted signal originating distal to the occlusion. To test this hypothesis, we blocked the ascending spread of conducted vasomotor responses by damaging the smooth muscle and endothelial cells in a 200-microm segment of second- or third-order arterioles. We found that a conduction blockade eliminated or diminished the occlusion-associated increase in flow through the unoccluded branch and abolished or strongly attenuated the vasodilatory response in both vessels at the branch. We also noted that vasodilations induced by ACh (10(-4) M, 0.6 s) spread to, but not beyond, the area of damage. Taken together, these data provide strong evidence that conducted vasomotor responses have an important role in coordinating blood flow in response to an arteriolar occlusion.

Activation of adenosine A2 alpha receptors inhibits mast cell degranulation and mast cell-dependent vasoconstriction

OBJECTIVE

Adenosine and inosine accumulate in tissue during periods of ischemia and both molecules have been shown to degranulate mast cells in the hamster cheek pouch via activation of an A3 receptor. An A2-mediated inhibitory action of adenosine on mast cell degranulation has also been reported (16), and the objective of this research was to investigate the role of adenosine A2 receptors in modulating inosine-induced mast cell degranulation and subsequent vasoconstriction of microvessels.

METHODS

Cheek pouches of the Golden hamster were prepared for in vivo microscopy. Adenosine, inosine, and other agents were applied either globally in the superfusion solution or to selected regions of the tissue by pipette.

RESULTS

Micropipette application of 10(-4) M inosine to periarteriolar mast cells caused a vasoconstriction and an associated mast cell degranulation in 71% of the arterioles tested. The average diameter reduction was 29 +/- 5%. To establish a modulatory role for the A2 receptor, low doses of adenosine (100 nM and 10 nM) were applied globally via the superfusion prior to inosine stimulation. This adenosine pretreatment resulted in a decrease in the incidence of the inosine-induced vasoconstriction (17% and 31%), as well as smaller constrictions (0.5 +/- 1% and 7 +/- 3%). Mast cell degranulation was also reduced by pretreatment with adenosine, as evidenced by a decreased number of mast cells exhibiting ruthenium red dye uptake. The inhibitory effect of adenosine could be eliminated by pretreatment with the nonselective A1/A2 antagonist 8-(p-sulfophenyl) theophylline, which restored the inosine-induced responses to control values. To demonstrate that the effect was A2 alpha-mediated, vessels were pretreated with the selective A2 alpha agonist 2-[4-(2-carboxyethyl) phenethylamino]-5'-N-ethylcarboxamidoadenosine (CGS21680). Following this treatment, constriction in response to microapplication of inosine (10(-4) M) occurred in only 11% of the vessels tested; the average constriction was reduced to 2 +/- 2% and no mast cell degranulation was observed.

CONCLUSIONS

We conclude that mast cell degranulation can be inhibited via activation of an adenosine A2 alpha receptor; which activation occurs at a lower concentration of adenosine than stimulatory A3 receptor activation. This finding may have implications for the pathology of ischemia.

Capillary endothelial surface layer selectively reduces plasma solute distribution volume

We previously reported that a 0.4- to 0.5-microm-thick endothelial surface layer confines Dextran 70 (70 kDa) to the central core of hamster cremaster muscle capillaries. In the present study we used a variety of plasma tracers to probe the barrier properties of the endothelial surface layer using combined fluorescence and brightfield intravital microscopy. No permeation of the endothelial surface layer was observed for either neutral or anionic dextrans >/=70 kDa, but a neutral Dextran 40 (40 kDa) and neutral free dye (rhodamine, 0.4 kDa) equilibrated with the endothelial surface layer within 1 min. In contrast, small anionic tracers of similar size (0. 4-40 kDa) permeated the endothelial surface layer relatively slowly with half-times (tau(50)) between 11 and 60 min, depending on tracer size. Furthermore, two plasma proteins, fibrinogen (340 kDa) and albumin (67 kDa), moved slowly into the endothelial surface layer at the same rates, despite greatly differing sizes (tau(50) approximately 40 min). Dextran 70, which did not enter the glycocalyx over the course of these experiments, entered at the same rate as free albumin when it was conjugated to albumin. These findings demonstrate that for anionic molecules size and charge have a profound effect on the penetration rate into the glycocalyx. The equal rates of penetration of the glycocalyx demonstrated by the different protein molecules suggests that multiple factors may influence the penetration of the barrier, including molecular size, charge, and structure.

Permeation of the luminal capillary glycocalyx is determined by hyaluronan

The endothelial cell glycocalyx influences blood flow and presents a selective barrier to movement of macromolecules from plasma to the endothelial surface. In the hamster cremaster microcirculation, FITC-labeled Dextran 70 and larger molecules are excluded from a region extending almost 0.5 micrometer from the endothelial surface into the lumen. Red blood cells under normal flow conditions are excluded from a region extending even farther into the lumen. Examination of cultured endothelial cells has shown that the glycocalyx contains hyaluronan, a glycosaminoglycan which is known to create matrices with molecular sieving properties. To test the hypothesis that hyaluronan might be involved in establishing the permeation properties of the apical surface glycocalyx in vivo, hamster microvessels in the cremaster muscle were visualized using video microscopy. After infusion of one of several FITC-dextrans (70, 145, 580, and 2,000 kDa) via a femoral cannula, microvessels were observed with bright-field and fluorescence microscopy to obtain estimates of the anatomic diameters and the widths of fluorescent dextran columns and of red blood cell columns (means +/- SE). The widths of the red blood cell and dextran exclusion zones were calculated as one-half the difference between the bright-field anatomic diameter and the width of the red blood cell column or dextran column. After 1 h of treatment with active Streptomyces hyaluronidase, there was a significant increase in access of 70- and 145-kDa FITC-dextrans to the space bounded by the apical glycocalyx, but no increase in access of the red blood cells or in the anatomic diameter in capillaries, arterioles, and venules. Hyaluronidase had no effect on access of FITC-Dextrans 580 and 2,000. Infusion of a mixture of hyaluronan and chondroitin sulfate after enzyme treatment reconstituted the glycocalyx, although treatment with either molecule separately had no effect. These results suggest that cell surface hyaluronan plays a role in regulating or establishing permeation of the apical glycocalyx to macromolecules. This finding and our prior observations suggest that hyaluronan and other glycoconjugates are required for assembly of the matrix on the endothelial surface. We hypothesize that hyaluronidase creates a more open matrix, enabling smaller dextran molecules to penetrate deeper into the glycocalyx.

Capillaries and arterioles are electrically coupled in hamster cheek pouch

In this report we demonstrate electrical communication in the microcirculation between arterioles and capillary networks in situ. Microvessel networks in the hamster cheek pouch, which included capillaries and their feeding arterioles, were labeled with the voltage-sensitive dye di-8-ANEPPS by intraluminal perfusion through a micropipette. Pulses of 140 mM potassium solution were applied by pressure ejection from micropipettes positioned on arterioles several hundred micrometers upstream from capillaries. Potassium caused membrane potential changes of 3-11 mV in capillary segments up to 1,200 micrometers distal to the stimulation site, with time delays of <1 s. Capillary membrane potential changes were biphasic, with initial depolarizations followed by hyperpolarizations. The size of the response decreased exponentially with the distance between the arteriole and capillary, with a 1/e distance of 590 micrometers. The time to peak depolarization of both arteriolar and capillary segments was similar. The time to peak response was significantly faster than that for responses from direct stimulation of capillaries. Capillary responses were also obtained when blood flow was either blocked or directed toward sites of stimulation. Acetylcholine (10(-4) M) and phenylephrine (10(-5) M) applied to the arterioles by iontophoresis produced monophasic hyperpolarizing and depolarizing responses, respectively, in capillaries with <1-s delay between stimulus and onset of the membrane potential change. These results provide evidence in situ of a pathway for electrical communication between arteriolar and capillary levels of the microcirculation.

Capillaries demonstrate changes in membrane potential in response to pharmacological stimuli

It has been proposed that capillaries can detect changes in tissue metabolites and generate signals that are communicated upstream to resistance vessels. The mechanism for this communication may involve changes in capillary endothelial cell membrane potentials which are then conducted to upstream arterioles. We have tested the capacity of capillary endothelial cells in vivo to respond to pharmacological stimuli. In a hamster cheek pouch preparation, capillary endothelial cells were labeled with the voltage-sensitive dye di-8-ANEPPS. Fluorescence from capillary segments (75-150 microns long) was excited at 475 nm and recorded at 560 and 620 nm with a dual-wavelength photomultiplier system. KCl was applied using pressure injection, and acetylcholine (ACh) and phenylephrine (PE) were applied iontophoretically to these capillaries. Changes in the ratio of the fluorescence emission at two emission wavelengths were used to estimate changes in the capillary endothelial membrane potential. Application of KCl resulted in depolarization, whereas application of the vehicle did not. Application of ACh and PE resulted in hyperpolarization and depolarization, respectively. The capillary responses could be blocked by including a receptor antagonist (atropine or prazosin, respectively) in the superfusate. We conclude that the capillary membrane potential is capable of responding to pharmacological stimuli. We hypothesize that capillaries can respond to changes in the milieu of surrounding tissue via changes in endothelial membrane potential.

Patterns of excitation-contraction coupling in arterioles: dependence on time and concentration

We sought to understand the excitation-contraction coupling process in arterioles. KCl or phenylephrine (PE) was applied via the superfusion solution or by brief pulsatile ejections from a micropipette onto unpressurized arterioles (in vitro) from either the guinea pig small intestine or hamster cheek pouch. With either mode of application, KCl caused depolarizations that were tightly and predictably correlated with subsequent constrictions (electromechanical coupling). In contrast, the relationship between membrane potential and vasoconstriction in response to phenylephrine was dependent on both stimulus duration and agonist concentration. Application of short pulses of PE (< 1 s) produced mechanical responses that were dominated by pharmacomechanical coupling (i.e., they were not associated with changes in membrane potential). With longer PE stimuli, electromechanical coupling became more important and dominated microvessel responses. We conclude that adequate understanding of the signaling process in microvessels requires a consideration of both concentration and duration of application. Both the mode and duration of agonist application affect the relative degree of electromechanical or pharmacomechanical coupling in response to a vasomotor stimulus. These observations have important implications for intracellular and intercellular signaling.

Inosine binds to A3 adenosine receptors and stimulates mast cell degranulation

We investigated the mechanism by which inosine, a metabolite of adenosine that accumulates to > 1 mM levels in ischemic tissues, triggers mast cell degranulation. Inosine was found to do the following: (a) compete for [125I]N6-aminobenzyladenosine binding to recombinant rat A3 adenosine receptors (A3AR) with an IC50 of 25+/-6 microM; (b) not bind to A1 or A2A ARs; (c) bind to newly identified A3ARs in guinea pig lung (IC50 = 15+/-4 microM); (d) lower cyclic AMP in HEK-293 cells expressing rat A3ARs (ED50 = 12+/-5 microM); (e) stimulate RBL-2H3 rat mast-like cell degranulation (ED50 = 2.3+/-0.9 microM); and (f) cause mast cell-dependent constriction of hamster cheek pouch arterioles that is attenuated by A3AR blockade. Inosine differs from adenosine in not activating A2AARs that dilate vascular smooth muscle and inhibit mast cell degranulation. The A3 selectivity of inosine may explain why it elicits a monophasic arteriolar constrictor response distinct from the multiphasic dilator/constrictor response to adenosine. Nucleoside accumulation and an increase in the ratio of inosine to adenosine may provide a physiologic stimulus for mast cell degranulation in ischemic or inflamed tissues.

Elevation of intracellular calcium in smooth muscle causes endothelial cell generation of NO in arterioles

It is well known that vascular smooth muscle tone can be modulated by signals arising in the endothelium (e.g., endothelium-derived relaxing factor, endothelium-derived hyperpolarizing factor, and prostaglandins). Here we show that during vasoconstriction a signal can originate in smooth muscle cells and act on the endothelium to cause synthesis of endothelium-derived relaxing factor. We studied responses to two vasoconstrictors (phenylephrine and KCl) that act by initiating a rise in smooth muscle cell intracellular Ca2+ concentration ([Ca2+]i) and exert little or no direct effect on the endothelium. Fluo-3 was used as a Ca2+ indicator in either smooth muscle or endothelial cells of arterioles from the hamster cheek pouch. Phenylephrine and KCl caused the expected rise in smooth muscle cell [Ca2+]i that was accompanied by an elevation in endothelial cell [Ca2+]i. The rise in endothelial cell [Ca2+]i was followed by increased synthesis of NO, as evidenced by an enhancement of the vasoconstriction induced by both agents after blockade of NO synthesis. The molecule involved in signal transmission from smooth muscle to endothelium is as yet unknown. However, given that myoendothelial cell junctions are frequent in these vessels, we hypothesize that the rise in smooth muscle cell Ca2+ generates a diffusion gradient that drives Ca2+ through myoendothelial cell junctions and into the endothelial cells, thereby initiating the synthesis of NO.

Morphology favors an endothelial cell pathway for longitudinal conduction within arterioles

We examined the morphological parameters of arteriolar endothelial and smooth muscle cell dimensions and gap junctional surface areas to obtain an indication of the coupling capacity of each cell type. Silver nitrate staining was utilized to define cell borders of endothelial and smooth muscle cells in arterioles of several vascular beds from two species. From video images of silver-stained arterioles, the mean endothelial cell length of hamster cheek pouch arterioles (diameter 20 to 110 microns) was found to be 141 +/- 2 microns. Mean endothelial cell width was 7 +/- 0.2 microns in the same arterioles. Mean smooth muscle cell length in hamster cheek pouch arterioles of diameter 80 to 150 microns was 66 +/- 3 microns, with an average cell width of 8 +/- 0.2 microns. Dimensions of both endothelial and smooth muscle cells varied moderately with arteriole size and tissue type, but no general trends were seen. Based on the measured dimensions and the specific orientation of cell types within the arteriole, it was calculated that in hamster cheek pouch arterioles (60 microns diameter), 6 or 7 endothelial cell lengths would constitute a 1-mm segment of vessel, whereas approximately 140 smooth muscle cell widths would be required to span the same length. Estimates of connexin43 gap junctional plaque surface areas in each cell type suggest that endothelial cell junctional surface area is approximately eight times that of smooth muscle cells. Thus, combined measurement of cell dimensions and orientation with estimates of junctional plaque density leads to the conclusion that the endothelial cell layer forms a more permissive pathway for longitudinal conduction of signals through the blood vessel.

Acetylcholine induces conducted vasodilation by nitric oxide-dependent and -independent mechanisms

Conducted vasodilation has been proposed as an important component of local vascular control. Because conducted vasomotor responses have previously been studied only in response to short pulses (<500 ms) of agonist, this study examined conducted vasodilation in response to sustained stimuli. In addition, we examined the contribution of nitric oxide (NO) to initiation and maintenance of conducted responses induced by acetylcholine (ACh). Responses to 2-min applications of ACh, sodium nitroprusside, and 8-bromoguanosine 3',5'-cyclic monophosphate were obtained in cannulated, perfused hamster cheek pouch arterioles (approximately 60 microm in diameter). Changes of luminal diameter in response to pressure ejection of agonists from a micropipette placed close to the downstream end of the vessel were observed at the site of stimulation ("local") as well as 570 and 1,140 microm upstream. At the local site, ACh stimuli produced large changes in diameter (approximately 70% of the maximum response) that peaked within 45 s before declining slowly to levels of approximately 50% of the maximum response. A similar response pattern was observed at both upstream sites, with the conducted responses being maintained for the duration of the stimulus. Local responses of similar magnitude were found with sodium nitroprusside and 8-bromoguanosine 3',5'-cyclic monophosphate, but only minimal responses were observed at the conducted sites. In a separate set of arterioles, ACh responses were obtained before and during perfusion with 10 microM N(omega)-nitro-L-arginine. Inhibition of NO synthesis diminished the local response to ACh, but the initial phase of the conducted response was unaffected. Furthermore, the conducted responses faded more rapidly in the presence of N(omega)-nitro-L-arginine. We conclude from these results that local NO synthesis alone is insufficient to initiate conducted responses but that NO synthesis contributes to maintenance of sustained conducted responses.

A test of the role of flow-dependent dilation in arteriolar responses to occlusion

At an arteriolar bifurcation, occlusion of one of the branch arterioles has been reported to result in an increase in flow, shear stress, and vasodilation in the opposite unoccluded branch. This dilator response in the unoccluded branch, often referred to as the "parallel occlusion response," has been cited as evidence that flow-dependent dilation is a primary regulator of arteriolar diameter in the microcirculation. It has not been previously noted that, during this maneuver, flow through the feed arteriole would be expected to decrease and logically should cause that vessel to constrict. We tested this prediction in vivo by measuring red blood cell (RBC) velocity and diameter changes in response to arteriolar occlusion in the microcirculatory beds of three preparations: the hamster cheek pouch, the hamster cremaster, and the rat cremaster. In all preparations, a vasodilation was observed in the feed arteriole, despite a decrease in both flow and calculated wall shear stress through this vessel. Unexpectedly, we found that dilation occurred in the unoccluded branch arterioles even in those cases in which RBC velocity and shear stress did not increase in the unoccluded branch arterioles. All values returned to the baseline level after the removal of occlusion. The magnitude of the dilation of the feed and branch arterioles varied between species and tissues, but feed and branch arterioles within a given preparation always responded in a similar way to each other. We conclude from our experiments that mechanisms other than flow-dependent dilation are involved in the vasodilation observed in the microcirculation during occlusion of an arteriolar branch.

Vasoactive effects of basic and acidic fibroblast growth factors in hamster cheek pouch arterioles

Fibroblasts growth factors (FGFs) exhibit well-known angiogenic actions, but there is some controversy about whether they have vasoactive effects on blood vessels which might contribute to angiogenesis per se. To clarify this, changes in arteriolar diameter were recorded during observation by videomicroscopy of 3rd- and 4th (terminal)-order arterioles (resting diameters 22.5 +/- 0.5 microns and 14.4 +/- 0.3 microns, respectively) in the hamster cheek pouch in response to FGF application. Recombinant human bFGF (basic) and aFGF (acidic) were applied from micropipettes positioned 5-10 microns from the adventitial surface of vessels. Maximum vasodilator effects of adenosine (10(-4) M) applied in a similar way were also observed. Adenosine increased the diameters of 4th-order arterioles by 37.2 +/- 3.8% and those of 3rd-order arterioles by 38.7 +/- 2.7. bFGF produced vasodilatation (threshold dose 0.1 ng ml-1) in both classes of arterioles, while aFGF produced dose-dependent constriction (threshold dose 0.01 ng ml-1). A maximal dilator effect in 4th-order arterioles was obtained with 100 ng ml-1 bFGF, when diameters reached 82.6 +/- 2.4% of those with adenosine. Maximal constrictor effect (-48.2 +/- 5.6% of resting diameter) occurred with a dose of 100 ng ml-1 aFGF. Vehicle alone (MOPS or bicarbonate buffer used as solvents for FGFs) had no effect. As vasoconstrictors are known to stimulate growth of smooth muscle cells while dilators stimulate growth of endothelial cells, it is possible that the opposing vasoactivities demonstrated for aFGF and bFGF are linked with their selective mitogenicity for smooth muscle and endothelial cells, respectively, and contribute to their angiogenic actions.

Identification of distinct luminal domains for macromolecules, erythrocytes, and leukocytes within mammalian capillaries

A thick endothelial surface coat consisting of the glycocalyx and associated plasma proteins has been hypothesized to reduce functional capillary volume available for flowing plasma macromolecules and blood cells. The purpose of this study was to compare anatomic and functional capillary diameters available for macromolecules, RBCs, and WBCs in hamster cremaster muscle capillaries. Bright-field and fluorescence microscopy provided similar estimates (mean +/- SE) of the anatomic capillary diameter: 5.1 +/- 0.1 microns (bright field, 39 capillaries in 10 animals) and 5.1 +/- 0.2 microns (membrane dye PKH26, 18 capillaries in 2 animals). Estimates of functional diameters were obtained by measuring the width of RBCs and WBCs and the intracapillary distribution of systemically injected fluorescein isothiocyanate (FITC)-dextran 70. WBCs (5.1 +/- 0.2 microns) fully occupied the anatomic capillary cross section. In contrast, the widths of RBCs (3.9 +/- 0.2 microns, 21 capillaries in 8 animals) and FITC-dextran (4.3 +/- 0.2 microns, 21 capillaries in 8 animals) were significantly smaller than the anatomic capillary diameter. Continuous (1- to 5-minute) excitation of fluorochromes in the capillary lumen (light-dye treatment) increased the width of RBCs passing the treated site from 3.6 +/- 0.3 to 4.4 +/- 0.3 microns (6 capillaries in 4 animals) and the width of the FITC-dextran column from 4.1 +/- 0.2 to 4.6 +/- 0.3 microns (10 capillaries in 7 animals). Furthermore, light-dye treatment increased capillary tube hematocrit by 60% in 40-microns-long capillary segments compared with untreated sites in the same capillaries. It is concluded that the wall of skeletal muscle capillaries is decorated with a 0.4- to 0.5-microns-thick endothelial surface coat, which may represent the true active interface between blood and the capillary wall.

Ratiometric measurement of endothelial depolarization in arterioles with a potential-sensitive dye

A fluorescence ratio technique based on the voltage-sensitive dye 1-(3-sulfonatopropyl)-8-[beta-[2-di-n-butylamino)-6-naphythyl++ +]vinyl] pyridinium betaine (di-8-ANEPPS)has been developed for recording membrane potential changes during vascular responses of arterioles. Perfusion of hamster cheek pouch arterioles with the dye labeled the endothelial cell layer. voltage responses from the endothelium of intact arterioles were determined by analysis of voltage-induced shifts in fluorescence emission wavelengths from dye spectra imaged from the vessel wall. Membrane depolarization caused the dye spectrum to shift toward blue wavelengths, with maximal fluorescence changes near 560 and 620 nm. In isolated nonperfused arterioles, comparison of continuous dual-wavelength recordings with simultaneous microelectrode recordings showed that the ratio of fluorescence intensities (fluorescence at 620 nm to fluorescence at 560 nm) accurately followed changes in membrane potential (6-21 mV) during vasoconstriction. The dye response was linear with respect to potential changes from -56 to -6 mV, with a voltage sensitivity of 9.7% change in the ratio per 100 mV. Membrane potential responses from in vitro and in vivo arterioles after potassium stimulation consisted of rapid ( < 0.5 -s) depolarization followed by slow repolarization over several seconds. Potassium-induced depolarizations were conducted along arterioles, and the values of the electrical length constant for conducted depolarization determined by optical and microelectrode methods were in agreement. We conclude that ratio analysis of di-8-ANEPPS fluorescence emission can be used to accurately record membrane potential changes on the time scale of seconds during vasomotor activity from arterioles.

Adenosine-induced vasoconstriction in vivo. Role of the mast cell and A3 adenosine receptor

Adenosine, a vasodilator metabolite, is often produced in tissues where the demand for oxygen exceeds the supply. We have recently demonstrated in isolated cannulated arterioles that adenosine and its metabolite, inosine, can also cause vasoconstriction by stimulation of mast cells. Secondary release of histamine and thromboxane is responsible for the inosine-induced constriction in vivo. In the present study, we explored the vasomotor effects of adenosine in vivo and investigated the role of the A3 adenosine receptor in mediating vasoconstriction. In vivo, local application of adenosine (10-6 to 10-4 mol/L) to arterioles consistently caused dose-dependent vasodilation. A fraction of arterioles, however, exhibited a biphasic response, with constriction following dilation. This, too, was dose dependent; 37% of arterioles constricted by 12.7 +/- 4.3% of the initial diameter in response to 10-4 mol/L adenosine. In the presence of 8-(p-sulfophenyl)theophylline (8-SPT), an antagonist of A1 and A2 adenosine receptors, dilation in response to the same dose of adenosine was reduced, and constriction was enhanced; 85% of the tested arterioles constricted by -44.3 +/- 6.0% of the initial diameter. The A3 adenosine receptor has been shown to facilitate mediator release from mast cells, and its role was also examined. N6-(3-Iodo-4-aminobenzyl)adenosine (I-ABA), an agonist of A1 and A3 adenosine receptors, produced dose-dependent vasoconstriction. 1,3-Dipropyl-8-(4-acrylate)phenylxanthine (BW-A1433), an antagonist of A1, A2, and A3 receptors, significantly reduced the vasoconstrictor response to adenosine, which was unmasked during treatment with 8-SPT. In addition, both adenosine and I-ABA stimulated mast cell uptake of ruthenium red, indicating degranulation. The I-ABA-induced constriction was abolished by combined histamine and thromboxane receptor antagonists. We conclude that adenosine can cause vasoconstriction in vivo, which is often masked by A2 receptor-mediated vasodilation. Mast cells are stimulated in the course of the response, and the A3 adenosine receptor is involved in mediating constriction.

Inosine-induced vasoconstriction is mediated by histamine and thromboxane derived from mast cells

Mast cell degranulation has been shown to release products that cause arteriolar constriction. We previously reported that two nucleosides, adenosine and inosine, cause vasoconstriction of isolated hamster cheek pouch arterioles by stimulating degranulation of periarteriolar mast cells. The objectives of the present study were to characterize the nucleoside-dependent vasoconstriction in vivo and to determine the mediator or mediators responsible. We examined the vasomotor effect of inosine on arterioles in the cheek pouches of anesthetized hamsters (70 mg/kg pentobarbital sodium) in the control situation and in the presence of receptor antagonists for histamine (H1), thromboxane A2 (Tx), and leukotrienes (LT). Most experiments were carried out using inosine applied once locally via micropipette to arterioles and observing the subsequent response. Over a range of inosine concentrations from 10(-5) to 10(-3) M in the pipette, we observed a dose-dependent increase in the incidence and magnitude of constriction. In addition, mast cell staining with ruthenium red was observed after stimulation with inosine, an indication of mast cell degranulation. Neither the H1, Tx, nor LT antagonist alone had a significant effect on the vasomotor response to inosine. However, combined H1 and Tx blockade significantly reduced the incidence and magnitude of inosine-induced constriction. These data establish that inosine-induced constriction occurs in vivo and support the role of mast cells in this response. Furthermore they suggest that multiple mediators, primarily histamine and thromboxane, are responsible for the observed constriction.

Electromechanical coupling and the conducted vasomotor response

Conducted vasomotor responses are viewed as one mechanism that functionally integrates the microvasculature. It is hypothesized that the conducted vasomotor response is the result of an electrical current and its passive electrotonic spread along the length of a microvessel. We tested this hypothesis in isolated, unpressurized arterioles from the hamster cheek pouch using conventional intracellular membrane potential recording techniques. The mean resting membrane potential (RMP) was -67 mV. KCl and phenylephrine (PE) pulse-stimulation applied through micropipettes could both induce transient depolarizations and vasoconstrictions at the site of stimulation (local) and at conducted (560 microns) sites. It was noted, however, that the conducted vasomotor response could not be induced until the conducted electrical response exceeded a threshold of -45 mV for a minimum amount of time. The relationship between the amplitude of constriction and the amplitude-time area of depolarization above -45 mV was the same for local and conducted KCl and for conducted PE but was significantly different from that for local PE. Nifedipine greatly reduced the local and conducted mechanical but not electrical responses. Our results indicate that the conducted vasomotor responses are the result of the generation and subsequent conduction of electrical signals along the vessel but that the corresponding mechanical response occurs only when the electrical response exceeds a threshold level.

Use of Ruthenium Red staining to detect mast cell degranulation in vivo

OBJECTIVE

To establish a method of detecting mast cell degranulation in tissues during in vivo microscopy.

METHODS

Hamster tissues were prepared for intravital microscopy. Ruthenium red (RR) was superfused over the cheek pouch at concentrations of 0.0001-0.01% to determine the optimal concentration. Mast cells were stimulated with compound 48/80, as well as with vasoactive agents not known to be stimulatory to mast cells, following which, mast cell staining was observed. Mesenteries were stained with Toluidine Blue (TB) or RR and mast cell degranulation was assessed during treatment with compound 48/80, or control.

RESULTS

During superfusion with varying concentrations of RR, a dose dependence for background staining of unstimulated cells was observed. A RR concentration of 0.001% was optimal for in vivo detection of mast cell degranulation. Mast cells exposed to 0.001% RR were stained following stimulation with compound 48/80 but not after treatment with KCl or acetylcholine. The latter agents are not known to stimulate mast cells. Thus, arteriolar vasomotor responses, per se, did not appear to play a role in mast cell RR uptake. Comparable results were obtained with RR versus TB in control or 48/80-treated mesenteries.

CONCLUSIONS

This RR technique facilitates rapid detection of mast cell degranulation in vivo and provides an opportunity to assess both mast cell and microvascular function simultaneously.

Cellular pathways of the conducted electrical response in arterioles of hamster cheek pouch in vitro

We have previously shown that conducted vasomotor responses follow patterns that are consistent with a passive spread of electrical current along the length of the arterioles [(Xia and Duling, Am. J. Physiol. 269 (Heart Circ. Physiol. 38): H2022-H2030, 1995]. In this study, we define the cells through which the current flows. Isolated arterioles of hamster cheek pouch were used. The mean resting membrane potential (RMP) for randomly sampled arteriolar cells was -67 mV. When cell types were identified by dye injection, the RMPs were -68 and -67 mV for smooth muscle (SM) and endothelium (EC), respectively. Pulses of KCl induced transient, monophasic depolarizations at the site of stimulation (local), which were conducted decrementally along the length of the arteriole over several millimeters. During electrical conduction, three patterns of responses could be observed, but identical patterns of the conducted electrical responses were always observed in SM and EC. Phenylephrine stimulation also caused transient local and conducted depolarizations in both SM and EC. As with KCl stimuli, shapes of conducted electrical responses were identical in records made in both cell types. The results suggest that SM and EC are electrically coupled both homocellularly and heterocellularly.

Method to create small photo-bleached volumes to monitor blood plasma flow in capillaries

A method has been developed to examine the movement of plasma in capillaries using intravital microscopy. Spatial transients in fluorescence properties are instantaneously induced by laser photo-bleach pulses after which the convective recovery can be monitored. The plasma is tagged with fluorescent dyes coupled to bovine serum albumin, which is injected well before the measurements and circulates with the blood stream. A laser beam from an argon laser source, set to emit light with a wavelength of 488 nm, is focused on the illumination field diaphragm and creates a spot in the object plane of the microscope. At low laser power, the laser spot is aimed at a blood plasma gap between red blood cells in a capillary segment, using a steerable mirror. Light sensors, coupled to photo-multipliers in the secondary image plane of the microscope, record the light intensity of the moving plasma/dye while the preparation is continuously illuminated with a xenon epi-illuminating set-up. The laser photo-bleach spot is then used to bleach the dye complex within a 5.4 microns segment of the capillary for less than 20 ms. The movement of the bleached plasma bolus is tracked by the photo-sensors, placed sequentially along the capillary. Both dye and red blood cell passage can be detected in the photo-multiplier signals, and the relative velocities of the two blood components can be measured. Measurements reveal that the ratio of transit times between blood plasma and red blood cells is 1.23 (SD = 0.22, N = 18), which is in good agreement with measurements by other techniques.

Dye tracers define differential endothelial and smooth muscle coupling patterns within the arteriolar wall

Dye tracers were chosen, based on net charge, chemical structure, and reactive groups, to test for the existence of and to provide novel insight into channel selectivities of junctional pathways connecting smooth muscle and endothelial cells of the arteriolar wall. Dyes were injected into individual smooth muscle or endothelial cells of hamster cheek pouch arterioles using microiontophoresis. Coupling, independent of tracer net charge, was seen both within and between cell layers. Endothelial cells were well coupled by all of the tested dyes. Smooth muscle junctions appeared less effective in dye transfer than endothelial junctions. Lucifer yellow was confirmed to be a poor tracer of smooth muscle gap junctions, and remarkably this dye and other related sulfate-containing molecules interfered with dye movement through smooth muscle but not endothelial junctions. Myoendothelial junctions showed a striking polarity of dye movement, with dye transfer from endothelial to smooth muscle cells but little or no transfer in the reverse direction. Because the dyes have size and charge characteristics similar to those of known cellular second messengers, these findings have important implications for cell-cell signaling in the vessel wall.

Connexin 43 and connexin 40 gap junctional proteins are present in arteriolar smooth muscle and endothelium in vivo

The distributions of connexin 43 (Cx43) and connexin 40 (Cx40) in smooth muscle and endothelium of resistance vessels were examined using indirect immunofluorescence techniques coupled with confocal microscopy. Cx43 and Cx40 were found in smooth muscle and endothelium. Similar staining patterns were found in microvessel samples from brain and cremaster of the rat and from arterioles of the hamster cheek pouch. Double-labeling studies showed a high degree of colocalization of Cx40 with Cx43, suggesting the presence of multiple connexins within a single junctional plaque. Quantitative comparisons were made of the fluorescent patterns in the endothelium and smooth muscle of rat brain arterioles. Cx43 and Cx40 plaque diameters were 0.9 +/- 0.1 and 0.8 +/- 0.1 (SE) microns, respectively, in the endothelial layer and 0.5 +/- 0.1 and 0.5 +/- 0.1 microns, respectively, in the smooth muscle. There was no difference between mean plaque diameters of Cx43 and Cx40 in endothelium or smooth muscle. However, plaques were significantly larger in endothelium than in smooth muscle (P < 0.05). These findings demonstrate the potential for cell-cell communication in both cell types of the wall of arterioles from three different tissues. The data also suggest a greater level of coupling within the endothelium.

Vulnerability of conducted vasomotor response to ischemia

Many vasoactive substances induce two responses, a direct effect at the site of application and a conducted response that spreads along the vessel length. In the microcirculation, we find that these two components of the vasomotor response display quite different sensitivities to occlusion and/or ischemia. Conducted vasomotor responses were induced in arterioles of the hamster cheek pouch by micropipette application of two test agents: phenylephrine (PE), which causes a receptor-mediated vasomotor response, and KCl, which causes an alteration in the membrane potential by a simple change in the K+ gradient. Ischemia was produced either by total occlusion of the vascular supply, which resulted in a complete cessation of flow in all vessels, or by venous occlusion, which was achieved by gradually inflating a pressurized cuff positioned across the pedicle of the pouch until venous return from the pouch was arrested while the feed arterioles remained patent. Both types of occlusion produced ischemia, the former with low intravascular pressure, the latter with high intravascular pressure. During both types of occlusion, arterioles were initially maximally dilated and unresponsive to both agonists, but over a subsequent 3- to 5-min period, resting arteriolar tone and local responses to both agonists returned. With total occlusion, the conducted response to KCl returned in parallel with the local response, whereas the conducted response to PE was diminished or absent. With venous occlusion, the local responses recovered as with total occlusion, but the conducted responses to both PE and KCl recovered as well.(ABSTRACT TRUNCATED AT 250 WORDS)

Determination of capillary tube hematocrit during arteriolar microperfusion

Intracapillary hematocrit is known to be substantially lower than arterial hematocrit. We hypothesized that capillary hematocrit might be influenced by interactions between plasma macromolecules and the endothelial cell surface. Microvessel perfusion pipettes were inserted in second- or third-order vessels, and capillaries were perfused with three different artificial bloods composed of 50% red cells plus the following suspension media: fetal calf serum (group I), serum albumin plus serum globulins (fractions II and III; group II), and bovine serum albumin plus dextran (group III). The mean hematocrits of the pipette-perfused capillaries averaged close to 50% of the systemic value with all perfusion fluids and were not different from the hematocrits of the capillaries perfused by the animal. These data suggest that bifurcations proximal to the pipette location did not contribute to the reduction in mean tube hematocrit normally seen in the animal. Furthermore, interactions between the plasma macromolecules and the endothelial cell surface do not appear to contribute to the low intracapillary hematocrit. Analysis of the data indicate that the capillary Fåhraeus effect, the network Fåhraeus effect in terminal vessels of the arterial tree, and intracapillary events all contribute to the reduction in intracapillary hematocrit.

Nucleoside-induced arteriolar constriction: a mast cell-dependent response

Adenosine (Ado) is a potent vasodilator that has occasionally been shown to cause vasoconstriction. Constrictor responses are generally attributed to A1-receptor stimulation or interactions with the renin-angiotensin system. We describe a previously unreported vasoconstrictor action of Ado and inosine (Ino) in hamster cheek pouch arterioles and examine the mechanism by which these nucleosides induce constriction. Arterioles were dissected from male Golden hamster cheek pouches, transferred to a 37 degrees C tissue chamber, and cannulated at both ends. Changes of luminal diameter in response to Ado were measured to generate cumulative concentration-response curves. The concentration-response curves were biphasic: 10(-6) M Ado elicited an intense, transient constriction, and higher concentrations induced dilator responses. Pretreatment with 8(p-sulfophenyl)theophylline, an Ado receptor antagonist, inhibited the dilator responses but did not alter the constriction. Inhibition of Ado uptake with S-(4-nitrobenzyl)-6-thio-inosine eliminated the constrictor response without altering dilator responses. Similar effects were found after pretreatment with an Ado deaminase inhibitor erythro-9-(2-hydroxy-3-nonyl)adenine hydrochloride. Finally, Ino, a metabolite of Ado, induced constrictions of similar magnitude to those seen with Ado, but at higher concentrations. The constrictor response was focal in nature, suggesting discrete sites of action of Ado. Methylene blue staining after Ado application revealed degranulated mast cells closely associated with the vessel wall, indicating a possible role for mast cell degranulation in the constrictor response. Supporting this idea were the observations that inhibition of degranulation by 10 microM cromolyn blocked the constrictor response, and compound 48/80 (a mast cell secretagogue) caused constriction similar to that elicited by Ado.(ABSTRACT TRUNCATED AT 250 WORDS)

A technique for the estimation of plasma flow in single capillaries using photobleached dyes

In order to estimate plasma flow in single capillaries, an "indicator bolus" was optically inserted into individual microvessels of the hamster cremaster muscle. This was accomplished using short-duration (200 msec), argon laser pulses to photobleach a 5-microns segment of fluorochrome circulating with the plasma. The subsequent motion of the bleached plasma bolus was then tracked using photomultipliers positioned at three sites along the capillary. The transient passage of the dye appeared as a steep fall in light intensity as the downstream edge of the bleached area entered the sensor field, followed by a steep rise in light intensity as trailing unbleached plasma flowed under the sensor. The behavior of light intensity as the photobleached bolus flowed past a sensor was analyzed using a theoretical model developed to predict the behavior of this type of plasma flow indicator in single capillaries. The characteristic time, tau, which equals the capillary segment volume divided by the plasma flow, was taken as an estimate of plasma flow. The model predicts that, for this system, tau of the capillary corresponds closely to the time at which 50% of the full sensor response to the bolus is attained, that is, the t50. The ratio between the t50 and the characteristic time is found to be a function of the relative sensor width and the flow velocity profile. A procedure is also described to assess the flow velocity profile from in vivo measurements. Using this technique, the ratio of the velocity of the red cell compared to that of plasma is found to be about 1.3.

A light-emitting diode light standard for photo- and videomicroscopy

A light calibration system consisting of a compact light-emitting diode (LED) source with feedback control of intensity is described. The source is positioned in the focal plane of the microscope objective and produces flat-field illumination of up to 31 microW. The source can be easily used to determine the performance of microscope optics and camera response. It can also be used as a standard light source for calibration of experimental systems. Selectable light intensities are produced by controlling the LED input power via a feedback circuit consisting of a photodiode that detects output light intensity. Spectral coverage extends between 550 and 670 nm using green, yellow and red LEDs mounted side by side, which are selected individually. The LED chips are encapsulated in plastic diffusers which homogenize the light, and a flat field of illumination is obtained through a thin 1-mm-diameter aperture positioned directly over each chip. Provision is made for insertion of Ronchi rulings over the aperture to enable measurements of contrast modulation in a uniform field. The light may be pulse-modulated to assess camera response times and the device can be synchronized with video frames. Narrow bandpass interference filters can be placed between the objective lens and the LED source to produce monochromatic light without affecting the spacing of controlled light intensities since emission spectra do not shift appreciably over the range of LED powers chosen in this design. Results of tests using controlled light intensity and uniform illumination are presented.

Modification of vascular reactivity by alteration of intimal permeability: effect of TNF-alpha

We investigated the effects of alterations in intimal permeability on microvascular reactivity to small hydrophilic agents in isolated, cannulated, perfused arterioles (65 +/- 6 microns ID) from hamster cheek pouches. Arterioles are 300-fold less responsive to the hydrophilic alpha 1-agonist, phenylephrine, applied to the lumen than when applied to the adventitia. Luminal treatment with tumor necrosis factor-alpha (TNF-alpha, 0.625 micrograms/ml, 1-2 h) potentiated reactivity to luminally applied phenylephrine, but the treatment did not change reactivity to adventitially applied phenylephrine. Similar results were obtained with a brief treatment with the detergent, 3-[(3-cholamidopropyl)dimethylammonio]-1- propanesulfonate (CHAPS; 0.3%, < 30 s). To confirm that a change in permeability had occurred, we measured the movement across the arteriolar wall of a low-molecular-weight hydrophilic fluorescent molecule, fluorescein, before and after luminal treatment with TNF-alpha or CHAPS. Either TNF-alpha or CHAPS significantly increased the rate of movement of fluorescein across the arteriolar wall. These data suggest that one element in the pathophysiology of TNF-alpha is an increase in arteriolar permeability to small, water-soluble agents, which may modify reactivity to circulating vasoactive substances.

Comparison of conduit vessel and resistance vessel reactivity: influence of intimal permeability

Arterioles of hamster cheek pouches are less reactive to luminal application of small hydrophilic agents than to adventitial application. To explore possible longitudinal variations in response sidedness, we compared reactivity of isolated vessels from carotid arteries to first-order arterioles. Concentration-response curves for luminally or adventitially applied phenylephrine (PE) were constructed. Arterioles were 274-fold less responsive when PE was in luminal vs. adventitial responsiveness decreased as vessel diameters increased, from 24-fold in inferior saccular arteries to 18-fold in external maxillary arteries and, finally, to 3-fold in common carotid arteries. Differences in response to luminal or adventitial application of PE could be eliminated in arterioles by perfusion with 3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonate (CHAPS), which disrupts membrane integrity. Treatment with CHAPS also increased the transmural movement of sodium fluorescein across arteriolar vessel walls. We conclude that a diffusion barrier exists in arterial walls, that there is a longitudinal variation in this barrier as expressed by the differences in movement of small hydrophilic molecules from lumen to smooth muscle cell layers, and that the site of the barrier is likely to be at the endothelial cell membrane.

A micropipette which allows in situ perfusion of arterioles and capillaries

In order to investigate capillary physiology, a glass micropipette system was developed that allowed in situ perfusion of microvessels as well as rapid changes of perfusion solutions. Theta tube (WPI, Inc.; 1.5-mm o.d. glass stock capillary tubing which is divided into two hemicylindrical sides by a central glass septum) was pulled to a smaller diameter of approx 300-600 microns and inserted into the shank of a sharpened cannulating micropipette tip constructed from large-bore glass stock (1.6 mm i.d.). The resulting dead volume between the end of the Theta supply tube and the tip of the outer cannulating tip was approximately 90 nl. The perfusate was driven in a circuit from a pressurized feed reservoir down one side of the Theta supply tube pipette and back through the second side into a reservoir maintained at a lower pressure. The pressure gradient between the two reservoirs established a high-volume flow rate and subsequently a short perfusate transit time from the feed to the collection reservoir. The average pressure in the two reservoirs determined the pressure which drove the perfusate from the cannulating tip. At normal pressures and flows, the time required to change perfusion fluid composition at the pipette tip was less than 1 min, and discharge hematocrit of a red blood cell suspension was indistinguishable from the hematocrit measured in the feed reservoir.(ABSTRACT TRUNCATED AT 250 WORDS)

Access of blood-borne vasoconstrictors to the arteriolar smooth muscle

In vitro experiments have shown that luminally applied water-soluble vasoactive materials have limited access to arteriolar smooth muscle cells, and as a result, the responses to such agents applied luminally are less than the responses to those applied adventitially. To determine the extent to which this 'compartmentation' influences arteriolar responsiveness to blood-borne water-soluble vasoconstrictors in vivo, we applied phenylephrine, vasopressin and angiotension II to arterioles in the hamster cheek pouch both by luminal perfusion, and by topical application to the arteriolar smooth muscle via micropipettes. The arterioles were about 2 orders of magnitude more sensitive to these water-soluble vasoconstrictors when they were applied topically than when they were applied luminally. In contrast, the arterioles were almost equally sensitive to the lipid-soluble alpha 1-adrenoceptor agonist SKF 89748-A applied by either route. The venular wall appears to be much less effective as a barrier than the arteriolar endothelium. Phenylephrine and vasopressin both elicited large arteriolar constrictions when perfused through venules in close proximity to the arteriole, and these constrictions were larger than those observed when the drug was applied to the arteriole's own lumen. Our observations confirm that the arteriolar endothelium can inhibit the direct access of water-soluble blood-borne agents to the arteriolar smooth muscle in vivo, and they suggest that the capillaries and venules could be the primary routes of access for water-soluble agents from the blood to the arteriolar smooth muscle.

Arteriolar endothelial cell barrier separates two populations of muscarinic receptors

The endothelium of arterioles can function as a barrier to diffusion of hydrophilic molecules when studied in vitro. Thus a substance applied to one side of the arteriole is relatively ineffective in reaching receptors on the opposite side of the vessel wall unless it is lipid soluble. To study the receptor populations on the two sides of the arteriolar endothelium, we used micropipettes to apply methacholine (MCh; 1.0 microM), either luminally or adventitially, for 5 s to the arterioles of the cheek pouch of pentobarbital-anesthetized hamsters. MCh equally dilated the arterioles regardless of the side of application. That different populations of receptors are located on either side of the arteriole was shown by the fact that adventitially applied hydrophilic methscopolamine was ineffective in blocking the effects of the luminally applied MCh but completely blocked the effects of abluminally applied MCh. In contrast, the luminal population of receptors was easily blocked by adventially applied scopolamine, which is lipophilic. Separate and independent populations of receptors in the vessel wall suggests the potential for differential control between humoral and adventitial sources of vasoactive metabolites.

Microcirculatory dysfunction following perfusion with hyperkalemic, hypothermic, cardioplegic solutions and blood reperfusion. Effects of adenosine

BACKGROUND

Cardioplegic solutions have been used to enhance myocardial preservation during cardiac surgery. The benefits derived from preventing myocardial ischemia with cardioplegic solutions may, however, be countered by tissue damage that occurs when the myocardium is reperfused with oxygenated blood. Furthermore, cardioplegia-induced endothelial dysfunction may contribute to depressed myocardial function postoperatively. The endothelium of coronary arteries and vein grafts is damaged by crystalloid cardioplegic solutions. There is less known about the effects of cardioplegic solutions on the microvasculature.

METHODS AND RESULTS

The hypothesis that microvascular damage occurs following perfusion with hyperkalemic, crystalloid, cardioplegic solutions and blood reperfusion, leading to decreased blood flow and increased neutrophil accumulation, was tested in a model system. Intravital microscopic observations were performed during a 20-minute perfusion of the hamster cremaster muscle with cardioplegic solutions (10 degrees C) via the femoral artery with the iliac occluded and during a subsequent 2-hour blood reperfusion period (iliac open). Arteriolar vasoconstriction (27% decrease in diameter, p less than 0.05) and a 25% decrease in the density of perfused capillaries (p less than 0.05) occurred during reperfusion in hamsters receiving crystalloid cardioplegic solution (16 meq K+) compared to control hamsters (no cardioplegic solution given). Neutrophils accumulated on venular endothelium in treated animals (250% increase, p less than 0.05) and extravascularly (myeloperoxidase levels 2.0 +/- 0.4 U/g versus 1.3 +/- 0.3 U/g in control, p less than 0.05). The addition of adenosine (10(-4) M) and albumin (2 g%) to the cardioplegic perfusate, accompanied by the administration of adenosine (10(-4) M) during reperfusion, produced arteriolar vasodilation (34% diameter increase, p less than 0.05) and inhibited extravascular neutrophil accumulation (myeloperoxidase level of 1.5 +/- 0.2 U/g, p greater than 0.05 versus control). Capillary perfusion, however, was still significantly diminished (28% decrease, p less than 0.05.)

CONCLUSIONS

We conclude that injury manifest by decreased microvascular blood flow and increased neutrophil accumulation in tissues occurs after perfusion with hypothermic, hyperkalemic, crystalloid cardioplegic solutions and blood reperfusion. Adenosine seems to partially attenuate this injury by dilating arterioles and decreasing extravascular neutrophil accumulation.

Heterogeneity in conducted arteriolar vasomotor response is agonist dependent

Microiontophoresis of acetylcholine onto cheek pouch arterioles of the pentobarbital-anesthetized hamster results in both a local response at the pipette tip and a conducted dilator response. The conducted response is not dependent on blood flow, and its magnitude decays with distance from the site of stimulation. In an attempt to define the mechanism responsible for activation of arteriolar conduction, vasoactive agonists directed toward different vascular wall cell types, receptor types, and second messengers were applied to arterioles by pressure-pulse microejection. As expected, microapplication caused a consistent arteriolar response at the site of application with each of the agonists tested (local response). However, a high degree of variability was observed among agonists in their ability to produce conducted responses. Acetylcholine, muscarine, and phenylephrine, invariably induced both local and conducted responses. In contrast, bradykinin, substance P, papaverine, isoproterenol, and adenosine, though consistently inducing local responses, displayed a highly variable ability to induce the conducted responses. When conduction was observed, the arteriolar response was similar regardless of the agonist used to induce the response. Microejection of sodium nitroprusside or arginine vasopressin produced local arteriolar responses with no evidence of a conducted response regardless of the dose. These studies reveal previously undetected heterogeneity among microvessel responses and may reflect variations in the coupling mechanisms linking the local vasomotor response to the conducted response.

Ca2+ sensitivity of isolated arterioles from the hamster cheek pouch

When isolated from the hamster cheek pouch, cannulated, and perfused, 60- to 90-microns arterioles spontaneously contracted to 67 +/- 4% of maximum diameter. Vessel sensitivity to variations in extracellular Ca2+ was then evaluated. Tone, regardless of its source, was highly dependent on the concentration of Ca2+ in the bathing solution. The magnitude of responses to changing Ca2+ depended upon which vessel surface (luminal or abluminal) the change was made. For K(+)-induced tone the Ca2+ concentration-response curve was right shifted 60-fold for luminal vs. abluminal changes. These results suggest that restricted diffusion of Ca2+ from lumen to smooth muscle dramatically reduces smooth muscle Ca2+ concentration and that under standard in vitro conditions the smooth muscle layer is effectively isolated from luminal contents. Both the cytosolic and stored Ca2+ in these microvessels were dependent on the Ca2+ concentration in the bathing solution. Abrupt removal of Ca2+ from bath produced a rapid maximal dilation with a mean time to half-maximal response (t1/2 max) of 14 +/- 4 s. Ca2+ replacement induced a return to the previous level of tone with a mean t1/2 max of 8 +/- 3 s. The magnitude of transient responses to caffeine (10 mM) was inversely related to the time of exposure to zero Ca2+ with a rapid decay in magnitude (t1/2 max = 2.7 +/- 0.8 min). These data suggest that the smooth muscle cells of arterioles have a particularly rapid transmembrane Ca2+ flux that is tightly controlled by an intracellular regulatory mechanism, which may explain the generally increased dependence of smaller vessels on extracellular Ca2+.

Arteriolar reactivity in vivo is influenced by an intramural diffusion barrier

The endothelium of the hamster cheek pouch arteriole in vitro is able to greatly reduce the potency of luminally applied water-soluble drugs by acting as a barrier to diffusion from the lumen to the smooth muscle [Lew, Rivers, and Duling. Am. J. Physiol. 257 (Heart Circ. Physiol. 26): H10-H16, 1989]. Lipid-soluble drugs appear unaffected by the diffusion barrier, presumably because their ability to cross cell membranes allows them to freely cross the endothelium. We compared the effects of two alpha 1-adrenoceptor agonists, phenylephrine (water soluble) and SKF 89748A (lipid soluble), on systemic blood pressure and the arterioles of the hamster cheek pouch in vivo. Both agonists were able to activate the arterioles when applied topically to the outside of the arterioles (extraluminal application). The agonists were also injected as a brief bolus into the aortic arch at doses chosen to elicit similar peak pressor responses. At all levels of pressor response, the arteriolar responses to phenylephrine were smaller than those to SKF 89748A. In the cremasteric vasculature SKF 89748A was similarly found to be more effective in activating the arterioles after intravascular administration than was phenylephrine. We conclude that an intramural diffusion barrier exists in the arteriolar wall in vivo and that it can influence vascular reactivity.

Heparinase treatment suggests a role for the endothelial cell glycocalyx in regulation of capillary hematocrit

Physiological stimuli induce rapid and unexplained increases in the number of red blood cells within capillaries of skeletal muscle. We hypothesized that such alterations in intracapillary red cell numbers might be due to an undefined interaction between one or more components of blood and the luminal surface of the capillary. This proposition was tested by in situ microperfusion of capillaries with enzymes directed against macromolecules likely to be expressed on the surface of endothelial cells. The instantaneous fractional volume of red blood cells within a capillary (tube hematocrit) was used as an index of a capillary's response to enzyme microperfusion. Five to 8 min of perfusion with enzyme vehicle (0.25% albumin-Ringer solution) produced no significant alteration in capillary tube hematocrit. Perfusion with solutions containing heparinase raised the tube hematocrit at least twofold (P less than 0.05) without a significant change in red cell velocity. Heat-denatured heparinase and other enzymes such as neuraminidase, hyaluronidase, papain, pronase E, and clostripain had no detectable effect on the tube hematocrit (P greater than 0.05). After enzyme treatment, application of adenosine (10(-4) M) or oxygen caused brisk vasomotor responses in arterioles feeding perfused capillary units, but the usual changes in the tube hematocrit were not observed. Thus heparinase treatment results in a sustained elevation in the capillary tube hematocrit and a dissociation of the typical relationship between vasomotor changes and red cell distribution in capillaries. These findings suggest that physiological stimuli which alter the number of red blood cells within capillaries may operate by modifying interactions between plasma and one or more components on the luminal surface of capillaries.

Microcirculatory responses to exogenous endothelial cell-derived relaxing factor

Endothelium-derived relaxing factor (EDRF) plays an important role in the vasodilatory responses of large blood vessels. However, such a role has yet to be conclusively shown for the microvasculature. In this study we tested the sensitivity of arterioles in the cheek pouch of pentobarbital-anesthetized hamsters to the EDRF-dependent agonists bradykinin and A23187, as well as to exogenous EDRF from cultured bovine aortic endothelial cells. The pouch superfusion fluid was arranged to first pass through a column containing endothelial cells and then on to the tissue. Bradykinin (10-30 nM) or A23187 (0.3 microM) was introduced either upstream or downstream to the endothelial cells, and the resultant responses were measured with video microscopy. Bradykinin and A23187 both caused a dose-dependent release of a microvessel dilator from cultured endothelial cells. We take this dilator to be EDRF based on the characteristics of the responses to the stimuli. Indomethacin (7.7 microM) was present in the superfusate to eliminate the production of cyclooxygenase products from the endothelial cells, and the magnitude of the response was diminished if the superfusate was first passed through a 3-min delay coil before arrival at the pouch. The arterioles dilated to the direct application of bradykinin in a dose-dependent fashion. They did not respond however to the direct application of A23187. These studies demonstrate that arteriolar smooth muscle is able to respond to exogenous EDRF and support the premise that EDRF may play an active role in the regulation of blood flow in the microcirculation.