Cytochalasin D induces edema formation and lowering of interstitial fluid pressure in rat dermis

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Cytochalasin D induces edema formation and lowering of interstitial fluid pressure in rat dermis

Ansgar Berg¹, Kristofer Rubin², and Rolf K. Reed¹

¹ Department of Physiology, University of Bergen, N-5009 Bergen, Norway; and ² Department of Medical Biochemistry and Microbiology, University of Uppsala, S-751 23 Uppsala, Sweden

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The increased capillary fluid filtration required to create a rapid edema formation in acute inflammation can be generatedby lowering the interstitial fluid pressure (P_IF). The loweringof P_IF appears to involve dynamic $beta$ ₁-integrin-mediated interactionsbetween dermal cells and extracellular matrix fibers. The presentstudy specifically investigates the role of the cell cytoskeleton,i.e., the contractile apparatus of cells, in controlling P_IF inrat skin as the integrins are linked to both the cytoskeletonand the extracellular matrix. P_IF was measured using a micropuncturetechnique in the dorsal skin of the hind paw at a depth of 0.2-0.5mm and following the induction of circulatory arrest with theintravenous injection of KCl in pentobarbital anesthesia. Thisprocedure prevented the transcapillary flux of fluid and proteinleading to edema formation in acute inflammation, which in turncan increase the P_IF and therefore potentially mask a decreaseof P_IF. Control P_IF (n = 42) averaged $-$ 0.8 ± 0.5 (means ± SD)mmHg. In the first group of experiments, subdermal injection of2 µl cytochalasin D, a microfilament-disrupting drug, loweredP_IF to an average of $-$ 2.8 ± 0.7 mmHg within 40 min postinjection(P < 0.05 compared with control). Subdermal injection of vehicle(10% DMSO in PBS or PBS alone) did not change the P_IF (P > 0.05).Lowering of the P_IF was not observed after the injection of colchicineor nocodazole, which specifically disrupts microtubuli in culturedcells. In the second group of experiments, 2 µl of cytochalasinD injected subdermally into rats with intact circulation increasedthe total tissue water (TTW) and albumin extravasation rate (E_ALB)by 0.7 ± 0.2 and 0.4 ± 0.3 ml/g dry wt, respectively (P < 0.05compared with vehicle). Nocodazole and colchicine did not significantlyalter the TTW or E_ALB compared with the vehicle (P > 0.05). Takentogether, these findings strongly suggest that the connectivetissue cells can participate in control of P_IF via the actin filamentsystem. In addition, the observation that subdermal injectionof cytochalasin D lowered P_IF indicates that a dynamic assemblyand disassembly of actin filaments also occurs in the cells ofdermal tissues invivo.

acute inflammation; loose connective tissue; tissue fluid volume

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

EDEMA can occur within a few minutes after the onset of an acute inflammatory reaction in skin and develops when the capillaryfiltration rate exceeds the lymphatic drainage (3). The fluidflux across the capillary wall is determined by the transcapillarypressures; i.e., the interstitial fluid pressure (P_IF), the hydrostaticcapillary pressure (P_C), the colloid osmotic pressure in plasma(COP_P) and the interstitium (COP_IF). Under normal conditions,P_IF acts to maintain a constant tissue fluid volume and counteractsedema formation (3) because an increased transcapillary filtrationwill raise interstitial fluid volume (IFV) and thereby P_IF, whichin turn will act across the capillary to limit further filtrationas well as enhancing lymph drainage from the tissues (3).

Contrary to this commonly accepted role for P_IF in maintaining constant IFV, we have observed a dramatic lowering of P_IF inthe initial phase of several acute inflammatory reactions (6,24, 25, 29, 37). The lowering of P_IF will increase thetranscapillary filtration pressure (39). This observation hasled to the development of the concept that the loose connectivetissues, via P_IF, can be "active" in transcapillary fluid exchangeas opposed to its commonly accepted role of being a "passive controller"in maintaining constant transcapillary fluid flux and therebyconstant IFV (35). The cellular events evolved in the loweringof P_IF appears to be related to the properties of the extracellularmatrix (ECM) macromolecules and the cell surface receptors towardECM components, the integrins. The rationale for linking ECM moleculesand interstitial cells to the lowering of P_IF and edema formationis primarily based on experiments in which cellular adhesion receptorstoward ECM components ( $beta$ ₁-integrins) are perturbed. Blockade ofthe $beta$ ₁-integrins in the rat skin by the subdermal injection ofanti- $beta$ ₁-integrin IgG causes a decrease of P_IF concomitant withedema formation (38, 41, 42), suggesting that the connectivetissue cells can actively exert control of P_IF via their collagen-binding $beta$ ₁-integrins (39). The control of P_IF is most likely achievedby a balance between the swelling properties of the hyaluronan-glycosaminoglycangel (30) and the ability of connective tissue cells to physicallyexert tension on the collagen and microfibril network that restrainthe swelling gel (30). According to this concept, the forcerequired to exert tension on the ECM fibers is generated by thecytoskeleton and is transmitted across the cell surface to theECM components. Integrins link ECM components with intracellularcytoskeletal components (9, 10, 22) and elicit intracellularsignaling when clustered or ligand occupied (11, 34, 53).Integrins transduce mechanical information between the extracellularenvironment and the cell interior (44, 47) coupling ECM fibersand cytoskeletal elements mechanically via integrins or integrin-directedmembrane complexes. It appears likely that alterations in cytoskeletalfunction should change the cellular tension on the ECM and therebythe P_IF according to the model presentedabove.

The aim of this study was twofold: 1) to investigate the effect on P_IF by selectively disrupting different parts of the cytoskeletalstructure in connective tissue cells of dermal tissue and 2) toevaluate whether the cytoskeleton is turned over continuouslyin vivo, because experimental data have demonstrated that thecytoskeleton in vitro is continuously regenerated (48). However,this has to our knowledge not been previously investigated invivo. The experiments were performed in two separate experimentalgroups by the investigation of the effect of the subdermal injectionof the microfilament and microtubule-disrupting drugs on P_IF oredemaformation.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Animals

Female Wistar Møller rats (Møllegaard, Denmark) weighing 200-250 g were housed, two per cage (20 × 45 cm), in a room withcontrolled temperature (22 ± 2°C) and light (12:12-h light-darkcycles), with free access to food and water. The rats were anesthetizedwith intraperitoneal injections of pentobarbital sodium (Mebumal,50 mg/kg body wt) and were kept on a servo-controlled heatingpad during anesthesia. In experiments for measurement of edemaformation and albumin extravasation, the rats were killed withan intravenous injection of 0.5 ml saturated potassium chlorideat the end of the experiment (see Total Tissue Water and AlbuminExtravasation). In experiments measuring P_IF, circulatory arrestwas induced during anesthesia by intravenous injection of 0.5ml of saturated potassium chloride after measurement of controlP_IF and before injection of the test substance in the paw (seeInterstitial fluid pressure). A PE-50 catheter was placed in theright external jugular vein and used for intravenous injections.The experimental protocols and procedures were approved by andperformed in accordance with regulations laid down by the NorwegianState Commission for LaboratoryAnimals.

Measurements

Interstitial fluid pressure. The measurement of P_IF has been described previously (5, 52). Briefly, P_IF was measured by a micropuncture techniquewith the use of micropipettes with tip diameters of 3-7 µm, whichwere connected to a servo-controlled counterpressure system (50,52). Punctures were performed on the dorsal side of the hindpaw through intact skin with the use of a micromanipulator (Leitz;Heerbrugg, Switzerland) and under the guidance of a stereomicroscope(Wild M5; Heerbrugg, Switzerland). Pressure measurements wererecorded in the following sequence: 1) with an intact circulation,and 2) for 90 min after circulatory arrest. In all experimentssubdermal injections of test substances were performed directlyafter circulatory arrest. An average was obtained for each ofthe following time periods: 0-10, 11-20, 21-30, 31-45, 46-60,and 61-90 min. The test drugs were deposited subdermally (2 µl)using a 5-µl chromatography syringe (Hamilton 800 Series; Sutton,UK) with a 34-gauge needle (38). Measurements of P_IF were performed0.2- to 0.5-mm below the skin surface and at the edge of the injectedvolume (5).

Total Tissue Water and Albumin Extravasation

Tissue samples. Tissue samples were obtained by removing the skin on the dorsal side of the hind paws. The samples were placed immediatelyin preweighed vials that were bottled and weighed as soon as possible.The wet weight of the tissue samples ranged from 0.1 to 0.2 g.Radioactivity was measured (see Albumin extravasation rate), andthe samples were dried at 65°C for 2-3 wk until they reached aconstant weight (usually 2-3 wk) to obtain the water content anddry tissueweight.

Total tissue water. Total tissue water (TTW) in the tissue samples was estimated as the water content per gram of dry tissue weight [(wet weight $-$ dry weight)/(dry weight)].

Albumin extravasation rate. Albumin extravasation rate (E_ALB) was measured as the 25-min extravascular space of ¹²⁵I-labeled human serum albumin (¹²⁵I-HSA) (Institute for Energy Technology; Kjeller, Norway) in thesame tissue samples that were used to obtain TTW. ¹²⁵I-HSA (0.05 MBq) in 0.3 ml of saline was administered intravenouslyimmediately after the subdermal injection (2 µl) of the test substances.After a period of 25 min, ¹³¹I-HSA (0.05 MBq) in 0.3 ml of saline was injected intravenously,and 5 min thereafter blood samples were collected by cardiac puncture.The rat was killed by an intravenous injection of saturated potassiumchloride. Tissue samples were obtained as described in Tissuesamples. Radioactivity in tissue and blood samples was determinedin a gamma-counting system (LKB Wallac 1285; Turku, Finland) withautomatic background subtraction and spillover correction. Distributionvolumes were calculated as plasma equivalent spaces (i.e., countsper minute per gram dry tissue weight divided by counts per milliliterplasma). E_ALB was calculated as the difference between the plasmaequivalent distribution volume of ¹²⁵I-HSA and that of ¹³¹I-HSA. All calculations were made per gram dry tissueweight.

Experimental Groups

Group 1: P_IF. P_IF was measured as described above. All test substances were injected subdermally in a volume of 2 µl. Experiments were carriedout using the following: 1) saline controls (n = 6): PBS; 2) DMSOcontrols (n = 6): 10% DMSO in PBS; 3) antimicrotubuli agents:colchicine at 3 mM (n = 6) or nocodazole at 0.33 mM (n = 6); and4) antimicrofilamental agents: cytochalasin D in concentrationsof 1.0 (n = 6), 0.4 (n = 6), or 0.12 mM (n =6).

Group 2: TTW and E_ALB. Test substance (2 µl) was injected into the right paw, and the left paw was given 2 µl of either sterile PBS or 10% DMSO inPBS as a control. Experiments were carried out using the following:1) saline controls (n = 6): 2 µl of 10% DMSO in PBS was injectedsubdermally into the right paw and 2 µl of PBS was injected intothe left paw as a control. 2) Antimicrotubuli agents: 2 µl ofcolchicine (3 mM) were injected subdermally (n = 8), with PBSused as the control in the left paw. In a separate series (n =5) 2 µl nocodazole (0.33 mM) were injected using 2 µl of 10% DMSOas a control in the left paw. 3) Antimicrofilamental agents: 2µl of cytochalasin D (1 mM) were injected (n = 6) with the useof 2 µl of 10% DMSO as a control in the leftpaw.

Test Substances

All drugs were purchased from Sigma (St. Louis, MO). Cytochalasin D and nocodazole were diluted in 10% DMSO diluted in sterilePBS. Colchicine was diluted in sterilePBS.

Statistical Methods

All values are means ± SD. The statistical analysis was performed using one-way analysis of variance with repeated measuresand subsequent Bonferroni and Student's t-test. P < 0.05 was consideredstatisticallysignificant.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Group 1: P_IF

Control P_IF averaged $-$ 0.8 ± 0.5 (means ± SD) mmHg (n = 42) after circulatory arrest had been induced and before injectionof test substances and was not different from the P_IF measuredwith an intact circulation ( $-$ 0.7 ± 0.4 mmHg, P > 0.05). Injectionof 2 µl of 10% DMSO in PBS or PBS alone did not change P_IF significantly(P > 0.05), compared with preinjection values (Fig. 1, Table 1).Injection of 2 µl cytochalasin D (1 mM) caused a significant loweringof the P_IF within 40 min to $-$ 2.8 ± 0.7 mmHg (P < 0.05, comparedwith its preinjection value and 10% DMSO control) (Fig. 1). Thelowering of P_IF was dose dependent (Fig. 1). Lowering of the P_IFwas not detected after injection of colchicine (3 mM) or nocodazole(0.33 mM) (P > 0.05 compared with the controls).

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Fig. 1. Effect of subdermal injection of cytochalasin D on interstitial fluid pressure (P_IF) in rat paw at decreasing concentrations. Also shown is DMSO control. Values are means ± SD. *P < 0.05 compared with DMSO control at same time points.

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Table 1. Interstitial fluid pressure in control and from 31 to 45 min after subdermal injection of different test substances

Group 2: TTW and E_ALB

TTW in the paw injected with cytochalasin D (1 mM) was 0.74 ± 0.21 ml/g dry wt (n = 8) above that in the paw injected with10% DMSO solution after 30 min (Table 2) (P < 0.05). The transcapillaryE_ALB was about eight times higher after injection of cytochalasinD compared with the DMSO control solution (P < 0.05) (Table 2).There was no significant difference in TTW and E_alb in the pawreceiving colchicine (3 mM) or nocodazole (0.33 mM) compared withtheir respective controls (P > 0.05) (Table 2).

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Table 2. E_ALB and TTW in rat paw skin following subdermal injection of different test substances

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The cytochalasins constitute a group of fungal metabolites that readily permeate cell membranes in vivo and exert profoundeffects on cell shape, disrupt actin organization, and inhibitcell movements (16, 49). In vitro, these compounds inhibitactin polymerization by binding to the rapidly growing (barbed)end of F-actin filaments and block all association and dissociationreactions at these filament ends (7, 8, 12, 16). Inthis study we show that subdermal injections of cytochalasin D,but not nocodazole or colchicine, lead to a decrease of P_IF andrapid edema formation in rat pawskin.

Subdermal injections of cytochalasin D lowered P_IF. This is an effect that most likely relates to a specific action of actin.However, in our model, targets other than actin cannot be totallyexcluded. The following observations argue for specificity. First,the measured effect on P_IF is dose dependent. Second, the effectis rapid and is seen within 10-15 min after administration ofthe drug. Finally, the time required to obtain a measurable responseon P_IF after cytochalasin D administration is in agreement withthe in vitro observations where alterations in cellular processescan be observed within seconds or minutes after the drugchallenge.

Colchicine and nocodazole are important drugs in the study of microtubule function. In vitro, the microtubuli display dynamicinstability and undergo continual cycles of assembly and disassemblyas a result of tubulin polymerization (31). Most microtubulihave half-lives in the order of minutes in most cell types studied.Colchicine inhibits tubulin polymerization into microtubules (1a),whereas nocodazole depolymerizes microtubuli (13). These twodrugs inhibit the dynamic functions of the microtubule system.Microtubule-disrupting agents have been reported to increase theisometric tension exerted by fibroblasts cultured in a three-dimensionalcollagen lattice (26, 27). Although both nocodazole and colchicineinhibit cell elongation, these drugs do not inhibit formationand the extension of pseudopodia by fibroblasts cultured in collagengels (46). As discussed below, connective tissue cells likelyparticipate in the control of P_IF by exerting a tension on a collagen-microfibrilnetwork. According to this model for the control of P_IF, as wellas taking into account the effects of microtubule-disrupting drugson the tension exerted by cultured fibroblasts, one would expectthat P_IF should increase after injection of colchicine and nocodazolein rat dermis. The finding that neither of these drugs had aneffect on P_IF suggests that the connective tissue cell tensionin rat dermis was not dependent primarily on the microtubule function.Furthermore, our data demonstrate that albumin extravasation andtotal tissue water content are not affected by colchicine andnocaodazole, suggesting that the endothelial barrier is not dependenton microtubuleintegrity.

P_IF was measured after circulatory arrest had been induced to eliminate the potential vascular effects caused by the differentdrugs that thereby limited transcapillary fluid filtration andprevented edema formation. This procedure did not affect P_IF forup to 90 min compared with control situations with intact circulation(52). Different drugs were injected subdermally, and P_IF wasmeasured by micropipettes at the edge of the injected volume;i.e., about 2 mm from the center of the injection site (5).This implies that the different test substances become dilutedas they diffuse into the surrounding tissue, which leaves someuncertainty about the effective concentration of the drugs inthe area of measurement. This would explain the relatively highconcentration of cytochalasin D (100-1,000 µM), which was requiredto give a measurable effect on the P_IF in our model system; i.e.,around 100-fold higher than necessary to alter cellular processesin tissue culture systems (4, 19, 32, 46). A sphere witha volume of 2 µl has a radius of about 0.8 mm and doubling ofthe radius will raise the volume in the sphere eight times whilethe concentration in the sphere falls correspondingly, i.e., eighttimes. Because the measurements of P_IF were made approximately2 mm from the center of injection, this will cause a dilutionto <10% of that in the injectate. The same phenomenon has beenobserved with several other test substances, where the lowesteffective concentration in vivo has been between 10 and 100 timeslarger than in cell culture experiments (5, 40, 42).

Under normal conditions P_IF acts to maintain normal interstitial volume and to counteract edema formation (3). An increasedfluid flux large enough to increase interstitial fluid volumewill, depending on the tissue compliance, eventually raise P_IFand thereby restrict further fluid filtration to the tissue. Thismechanism is known to be one of the "safety factors" against edemaformation. Contrary to this commonly accepted role for P_IF inthe normal control of interstitial volume, our observations oflowering of P_IF concomitant with edema formation during acuteinflammations demonstrate that the tissue can "actively" enhancecapillary filtration and eventually cause edema formation. Thelowering of P_IF will provide a driving force only for the initialand rapid part of the edema formation, because once the inflammatoryedema is sufficiently large, P_IF will become positive, as a functionof the tissue compliance, and counteract further fluid filtration.Maintenance of the edema formation will thereafter be due to otherfactors like increased capillary permeability together with increasedhydrostaticpressure.

Several series of experiments suggest that the final events resulting in the lowering of the P_IF involve connective tissuecells and structural components of the connective tissue (39).The evidence for involvement of structural components as wellas participation of the connective tissue cells is based on invivo studies of P_IF and edema formation in dermal tissue and fibroblastscultured in vitro. Experiments by Meyer (30) showed that piecesof isolated loose connective tissue placed into an isotonic bufferhad a tendency to swell. This swelling phenomenon has been attributedto the tissue content of hyaluronan (30). Our previous findings(38, 42) that subdermal injection of anti- $beta$ ₁ integrin IgGinduces edema formation concomitant with lowering of P_IF, togetherwith observations of the ability of fibroblasts to compact a three-dimensionalcollagen lattice in vitro, form the basis for proposing a mechanicalmodel for the cellular control of the P_IF by connective tissuecells (43). Platelet-derived growth factor (42) and phosphatidylinositol-3'kinase (1) have been shown to be involved in the control ofP_IF as well as influence the collagen gel contraction, which providesfurther evidence for the cellular control of P_IF and thereby tissuefluid homeostasis. According to this model, the lowering of P_IFoccurs after connective tissue cells loosen their attachment oneither a collagen or a microfibril network, which constrains ahyaluronan-proteoglycan gel with an intrinsic tendency to swell(30). When the restraining force is released in vivo, the tissuewill swell, but the initial lack of excess fluid will restrictswelling, and P_IF will decrease until the tissue expansion isbalanced by the negative P_IF and the stress in the fiber networks.Our observation of a decrease of P_IF following subdermal injectionsof cytochalasin D further substantiates this hypothesis in thatthis substance disrupts the actin filaments of the cytoskeletonand thereby limits the ability of the cells to generate enoughforce to exert a tension on the extracellular fiber network. Inanalogy with the effect of cytochalasin D to lower of P_IF in skinis that this substance also inhibits collagen gel contractionin vitro (19).

The control of P_IF in vivo shares characteristics with fibroblast-mediated collagen contraction in vitro (35, 43). Fibroblastscultured in three-dimensional collagen gels send out long extensionsand generate traction forces on the collagen fibers within thegel leading to the compaction of the latter (15, 18, 20).The actin-based microfilament system is highly dynamic, and thesending out of cell extensions is dependent on this turnover ofactin filaments (21). The fact that cytochalasin D induces alowering of P_IF indicates that a dynamic assembly and disassemblyof actin filaments also take place in dermal cells in vivo. Thisphenomenon has to the best of our knowledge not been reportedbefore. Our data support the concept that connective tissue cellsgenerate traction forces, which are important for normal tissueintegrity.

The edema-generating effect of subdermal injections of the different drugs, acting on the cytoskeleton, were tested in animalswith an intact circulation. Cytochalasin D injected subdermallywas the only drug that induced edema. Edema occurs when transcapillaryfluid filtration exceeds lymph drainage (3). In rat skin visibleedema requires IFV to increase by 50-100% above that of the control(51). Transcapillary fluid filtration flux (J_V) is the productof capillary hydraulic conductivity (CFC) and the net filtrationpressure across the capillary ( $Delta$ P) (3). Under steady-stateconditions $Delta$ P has been calculated to be ~0.5 mmHg in peripheraltissues (3). Because IFV in the rat skin is turned over in12-24 h (36), the appearance of edema in 10-15 min requiresthat J_V be increased by 50-100 times above control. During acuteinflammatory conditions, CFC increases two to three times abovethat of the control, even in severe tissue injuries such as burninjuries (2, 14, 33) and is therefore not sufficient toexplain the rapid edema formation under these conditions. Thelowering of P_IF by 2.0 mmHg, within 20 min after injection ofcytochalasin D, adds directly to a $Delta$ P of 0.5 mmHg (3) and increasesthe net filtration pressure by a factor of four above the control.Cytochalasin D also appears to raise the capillary permeabilityto macromolecules as protein accumulation (E_alb) increased significantlyfrom 0.05 in control to 0.40 ml/g dry wt. Capillary permeabilityis quantitatively described by the osmotic reflection coefficient( $sigma$ ) and the permeability-surface area product PS (45). The reflectioncoefficient is estimated at high transcapillary fluxes when diffusionbecomes negligible as $sigma$ = 1 $-$ C_L/C_P (17) where C is proteinconcentration in lymph (L) and plasma (P). However, if this requirementis not fulfilled, another estimate can be obtained from the ratioof C_L/C_P; i.e., the ratio of albumin accumulated divided by thefluid accumulated (increase in TTW). From the data in Table 1,C_L/C_P after cytochalasin D is 0.35/0.73 = 0.48 when E_ALB increasessevenfold; i.e., from 0.05 to 0.40 ml/g dry wt in 25 min. However,C_L/C_P is normally 0.5 (3, 45), and after cytochalasin D,the unchanged value at seven times water flux increase clearlyattests to an increased capillary protein permeability. The reflectioncoefficient also contributes to transcapillary fluid flux becausethe effective osmotic pressure across the capillary wall is aproduct of $sigma$ and colloid osmotic pressure differences. By assumingthat the transcapillary fluid flux is increased to an extent wherediffusion is negligible, $sigma$ equals 0.51 and raises the net filtrationpressure by 4 mmHg, assuming a transcapillary oncotic pressureof 10 mmHg. The reduction of $sigma$ is in agreement with experimentswhere cytochalasin D was given intravenously and produced a correspondingdecrease in $sigma$ (28). This suggests that the edema formation inducedby cytochalasin D is related in part to an increased microvascularpermeability (28). Thus the initial edema formation seen aftersubdermal injection of cytochalasin D is both due to a loweringof P_IF and an increased microvascular permeability. However, asedema develops and IFV increases, P_IF will eventually rise andcounteract further edema formation, and maintenance of edema mustrely on increased capillary pressure and permeability (3).

In summary, the present findings are important for two reasons. The observation that cytochalasin D induces lowering of P_IFin the dermal skin provides important and new information on thestate of the cytoskeleton in vivo by demonstrating that actinmonomers both associate and dissociate from the ends of actinfilaments in vivo. These experiments also provide additional supportto the hypothesis that interstitial matrix components in dermaltissue are normally held under tension by connective tissue cells(23), and that this tension must be generated by the contractileapparatus in thecells.

	ACKNOWLEDGEMENTS

The authors thank Dr. Alison Reith for valuable discussions and comments on the paper. The technical assistance of Gerd SigneSalvesen isappreciated.

	FOOTNOTES

This study was supported by grants from the Norwegian Research Counsil and the Swedish CancerSociety.

Address for reprint requests and other correspondence: A. Berg, Dept. of Pediatrics, Haukeland Univ. Hospital, N-5021 Bergen,Norway (E-mail: ansgar.berg{at}haukeland.no).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

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DISCUSSION
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