By
From the * Children's Hospital Medical Center, Division of Critical Care, Cincinnati, Ohio 45229;
and Department of Biochemical Pharmacology, The William Harvey Research Institute, London
EC1M6BQ, United Kingdom
A cytotoxic cycle triggered by DNA single-strand breakage and poly (ADP-ribose) synthetase
activation has been shown to contribute to the cellular injury during various forms of oxidant
stress in vitro. The aim of this study was to investigate the role of poly (ADP-ribose) synthetase
(PARS) in the process of neutrophil recruitment and in development of local and systemic inflammation. In pharmacological studies, PARS was inhibited by 3-aminobenzamide (10-20
mg/kg) in rats and mice. In other sets of studies, inflammatory responses in PARS/
mice
were compared with the responses in corresponding wild-type controls. Inhibition of PARS
reduced neutrophil recruitment and reduced the extent of edema in zymosan- and carrageenan-triggered models of local inflammation. Moreover, inhibition of PARS prevented neutrophil recruitment, and reduced organ injury in rodent models of inflammation and multiple
organ failure elicited by intraperitoneal injection of zymosan. Inhibition of PARS also reduced
the extent of neutrophil emigration across murine mesenteric postcapillary venules. This reduction was due to an increased rate of adherent neutrophil detachment from the endothelium,
promoting their reentry into the circulation. Taken together, our results demonstrate that
PARS inhibition reduces local and systemic inflammation. Part of the antiinflammatory effects
of PARS inhibition is due to reduced neutrophil recruitment, which may be related to maintained endothelial integrity.
In vitro studies have demonstrated that oxidative injury in
various cell types is related in part to DNA single-strand
breakage and the consequent activation of the nuclear enzyme poly (ADP-ribose) synthetase (PARS).1 Massive ADP
ribosylation of nuclear proteins by PARS then results in cellular energy depletion and injury (1).
This present work was designed to elucidate (a) whether
inhibition of PARS exerts antiinflammatory effects in various
models of local and systemic inflammation, and (b) whether
inhibition of PARS affects neutrophil recruitment during
inflammation. In our studies we used 3-aminobenzamide, a
prototypical pharmacological inhibitor of PARS (1), and
genetically engineered mice lacking functional PARS enzyme (PARS Animals.
Male Swiss Albino mice (20-22 g; Interfauna,
Huntingdon, United Kingdom) were used for investigation of
the effect of 3-aminobenzamide in the zymosan peritonitis
model, and in leukocyte-endothelium interaction by intravital
microscopy.
/
) (8).
Zymosan-induced Peritonitis in Mice Treated with 3-aminobenzamide.
Peritonitis was induced by intraperitoneal injection of
zymosan (12.5 mg/kg) in 0.5 ml PBS (0.1 M, pH 7.4) (9). At 2 or 4 h, animals were killed by CO2 exposure, and peritoneal cavities were washed with 3 ml of PBS containing 3 mM EDTA. Aliquots of the lavage fluids were then stained with Turk's solution,
and differential counting was performed using a hematocytometer
and a light microscope. Data are reported as 106 PMN per mouse.
The large predominance (>98%) of neutrophils in the PMN population in 2- and 4-h lavage fluids was confirmed in cytospin
preparations stained with May-Grünwald and Giemsa. Lavage fluids were then centrifuged at 400 g for 10 min, and supernatants stored at 20°C before evaluation of
-glucuronidase activity, according to a published protocol (10).
PMN Adhesion and Emigration in Mice Treated with 3-aminobenzamide. Mice were fasted overnight before experimentation. Animals were injected intraperitoneally with 12.5 mg/kg zymosan (in 0.5 ml sterile saline) or saline (controls), and were left at liberty until the beginning of the experiment. 4 h later, mesenteries were prepared as described (11). Mice were anesthetized with diazepam (60 µl subcutaneously) and HypnormTM (30 µl intramuscularly; Janssen Pharmaceutical Ltd., Oxford, United Kingdom). A tracheotomy was performed to facilitate breathing. Cautery incisions were made along the abdominal region, and the mesenteric vascular bed was exteriorized and placed on a plexiglass stage for viewing. The preparation was then mounted on an Axioskop FS (Carl Zeiss, Inc., Welwyn Garden City, United Kingdom) with a water immersion objective lens (×40; Carl Zeiss, Inc.) to observe the microcirculation. The preparation was transilluminated with a 12-V, 100-W halogen light source. Images were displayed and recorded for subsequent offline analysis. Mesenteries were superfused with 37°C bicarbonate-buffered solution (g/liter: NaCl 7.71, KCl 0.25, MgSO4 0.14, NaHCO3 1.51, and CaCl2 0.22, pH 7.4, gassed with 5% CO2/95% N2). One to three randomly selected postcapillary venules (diameter between 20-40 µm, length of at least 100 µm) were observed for each mouse. Adhesion was monitored by counting, for each vessel, the number of adherent leukocytes in a 100-µm length. Leucocyte emigration from the microcirculation into the tissue was quantified by counting the number of cells that had emigrated out of the vessel up to 50 µm away from the vessel wall in parallel with the 100-µm vessel segment.
In the first set of experiments, vehicle or 3-aminobenzamide was given intravenously immediately before intraperitoneal administration of zymosan. In a separate set of experiments, mesenteries were exposed 2 h after zymosan injection as described above, and vessels with a congruous number of adherent leukocytes (five to eight per branch) were chosen. Either PBS (100 µl) or 3-aminobenzamide (20 mg/kg) was given intravenously through the tail vein, and the fate of the adherent leukocytes was monitored for 10 min.Carrageenan-induced Paw Edema in Rats Treated with 3-aminobenzamide.
Rats received a subplantar injection 0.1 ml saline containing
1% -carrageenan into the right hind paw (12). The phlogogenic agent was given together with vehicle, with 3-aminobenzamide, or with the inactive structural analogue 3-aminobenzoic acid (25 µg/paw). The test agents were solubilized in saline solution, and
the injection volume was 0.1 ml. Control animals received the
same volume of vehicle. The volume of the paw was measured by a plethysmometer (Kent Laboratories, Kent, WA) (12).
Zymosan-induced Peritonitis and Multiple Organ Failure in Rats and Mice. Rats or mice were injected with 500 mg/kg zymosan i.p to induce multiple organ failure (14). 18 h after zymosan injection, animals were killed by CO2 exposure. Plasma samples were taken, and lactate dehydrogenase (LDH) levels and serum aspartate aminotransferase (AST) levels were determined by a clinical laboratory. The abdomen was carefully opened, and the peritoneal cavity was washed with 2 ml of saline solution with heparin (5 U/ml) and indomethacin (10 µg/ml).
Lavage fluids were then collected and measured, and exudate values were obtained after subtracting the volume injected. Differential cell counts were determined as described above. Lung, liver, and small intestinal MPO activities were determined as described for the paw tissues. For histopathological examination, tissues were fixed in 10% neutral-buffered formaldehyde for 5 d, embedded in paraffin, and sectioned. The sections were stained with hematoxylin and eosin. The above experiments were performed in rats and mice. In rats, responses in vehicle-pretreated animals and responses in animals pretreated with 3-aminobenzamide (10 mg/kg, 10 min before zymosan and every 6 h thereafter) were compared. In mice, responses in PARSData Analysis. All values in the figures and text are expressed as mean ± standard error of the mean of n observations, where n represents the number of animals studied. Data sets were examined by one- and two-way analysis of variance, and individual group means were compared with Student's unpaired t test. Nonparametric data were analyzed with the Fisher's exact test. A P value <0.05 was considered significant.
Zymosan injection into murine peritoneal cavities produced a time-dependent PMN
accumulation that was maximal at 4 h (15). Pretreatment of
animals with 3-aminobenzamide (10-20 mg/kg) resulted in
a significant reduction of PMN accumulation (Fig. 1 A).
The PARS inhibitor did not modify the extent of cell activation at the inflammatory site, assessed as -glucuronidase
activity in the lavage fluids. For instance,
-glucuronidase
activity was 66 ± 8 and 58 ± 17 U per 106 PMN in the
presence of PBS and 3-aminobenzamide (20 mg/kg) treatment, respectively (n = 6). The inhibitory action of 3-aminobenzamide on PMN elicitation was not the result of an
indirect effect on the number of circulating leukocytes,
since 3-aminobenzamide did not significantly alter the profile of circulating blood cells (Table 1). The inactive structural analog of 3-aminobenzamide, 3-aminobenzoic acid,
did not alter PMN recruitment (Fig. 1).
Fig. 1 B shows the effect of 3-aminobenzamide treatment (given 2 h after zymosan) on the number of cells recovered from the peritoneal cavities at the 4-h time point. In the period between 2 and 4 h, PMNs accumulated in response to zymosan with a high rate of influx (~3.5 × 106 cells/h), and administration of 3-aminobenzamide was highly effective in reducing cell recruitment. More than 70% reduction in PMN influx was seen with 10 or 20 mg/ kg 3-aminobenzamide, whereas the PARS inhibitor was inactive at 2 mg/kg (Fig. 1 B).
3-Aminobenzamide Inhibits PMN Emigration Across Mouse Mesenteric Postcapillary Venules Challenged with Zymosan.The effect of 3-aminobenzamide on leukocyte-endothelial
interaction was monitored by intravital microscopy. Zymosan injection induced high numbers of adherent and emigrated leukocytes in mouse mesenteric postcapillary venules
4 h after administration (Fig. 2). Treatment of mice with
3-aminobenzamide (20 mg/kg) immediately before zymosan did not modify the extent of cell adhesion (Fig. 2 A),
but significantly reduced the number of cells that emigrated outside the postcapillary venules (Fig. 2 B).
We then investigated the fate of the adherent leukocytes
in the presence or absence of pharmacological inhibition of
PARS in the mesenteries inflamed with zymosan. Postcapillary venules were visualized 2 h after zymosan injection.
Subsequently, vehicle or 3-aminobenzamide (20 mg/kg)
was given intravenously. While most of the adherent cells
emigrated through the endothelium of the postcapillary
venules in the vehicle-treated animals, a large majority detached from the endothelial surface after treatment with the
PARS inhibitor (Fig. 3 A). In vehicle treated-mice, only 25% of adherent cells detached after vehicle injection,
whereas most leukocytes emigrated (Fig. 3 B). In contrast,
in response to treatment with 3-aminobenzamide, cells
continued to detach and reenter the circulation. A total of
80% of adherent cells detached after administration of the
PARS inhibitor (Fig. 3 B).
Although 3-aminobenzamide did not apparently modify zymosan-induced cell adhesion at a fixed time point, it increased the rate of cell detachment from the postcapillary venule endothelium. In this protocol, only the fate of cells that were adherent before 3-aminobenzamide or vehicle intravenous challenge was followed, without considering newly adhered cells. The two processes (adhesion and detachment) equilibrated themselves, explaining why no difference in the degree of cell adhesion was seen at a single time point. Nonetheless, following the fate of adherent cells immediately after 3-aminobenzamide administration permitted identification of the process that was selectively affected by the drug. The net result is a diminished cell emigration across postcapillary venules and reduced PMN tissue infiltration.
3-Aminobenzamide Reduces Carrageenan-induced Rat Paw Edema.Based on the marked effects of 3-aminobenzamide
on neutrophil recruitment in the zymosan-induced models
of inflammation, we investigated the potential antiinflammatory effect of this PARS inhibitor in experimental models of inflammation where neutrophil recruitment plays a
crucial role. One of these processes is the carrageenan-induced local inflammation and tissue injury (16, 17). In
the carrageenan-induced rat paw edema model, pretreatment of the animals with 3-aminobenzamide (25 µg/paw)
caused a marked reduction in edema development (Fig. 4
A), and significantly reduced the increase in tissue levels of
myeloperoxidase, indicative of reduced neutrophil accumulation in the paw (Fig. 4 B). The degree of inhibition by
3-aminobenzamide of the paw edema was less pronounced (<50% inhibition) at 1-2 h, but it was more pronounced at
4 h (>75% inhibition). This difference in the degree of inhibition may be related to the nature of the various mediators involved in the pathogenesis of carrageenan-induced
paw edema. In the early stage, endogenous amines and
prostaglandins play an important role, while infiltrating
PMNs play a crucial role in the more delayed injury (3-4 h)
(12, 16). Nevertheless, peroxynitrite production, formed
by the reaction of superoxide with NO (the latter produced by constitutive NO synthase isoforms), is well established, even in the early phase of inflammation in this
model (19, 20). Similar to the results of the zymosan peritonitis studies, the inactive structural analog of 3-aminobenzamide, 3-aminobenzoic acid, did not alter the development
of paw edema (n = 5, data not shown).
3-Aminobenzamide and PARS
Intraperitoneal injection of a high dose of zymosan induces nonseptic shock and multiple organ failure, with
intensive PMN migration into various organs (14, 21).
In our experiments we chose the 18-h time point, and observed strong peritoneal inflammation (detected as exudation and leukocyte accumulation) and increased PMN infiltration into various organs (Fig. 5). In the wild-type (PARS+/+) control mice, zymosan injection increased serum AST and LDH levels to 170 ± 25 and 137 ± 24% of
control, respectively (P <0.05; n = 5). Treatment of rats
with 3-aminobenzamide (10 mg/kg), or the absence of
PARS in mice (animals with the PARS/
genotype) resulted in a pronounced reduction of exudate volumes and
leukocyte counts in the peritoneum, and significantly attenuated the zymosan-induced increase in the MPO activity in the organs studied (Fig. 5). There were no significant
increases in serum AST and LDH levels in the PARS
/
mice in response to zymosan injection (respective values
were 72 ± 20% and 97 ± 32% of control; n = 5). There
was also a marked reduction in the degree of histological
injury in the PARS
/
mice after zymosan injection when
compared with the response to zymosan in the PARS+/+
mice. The extent of zymosan-induced mononuclear cell
infiltration and the degree of the histological damage were
markedly reduced in the lung (Fig. 6) and liver (not shown)
of the PARS
/
mice when compared with the wild-type
PARS+/+ control mice.
The main finding of this study is that PARS inhibition (by a pharmacological approach or by the use of genetically engineered animals) reduces PMN recruitment
and accumulation into inflammatory tissue sites. Extravasated PMNs become activated once in the inflammatory sites, secreting a variety of substances such as growth factors, chemokines and cytokines, complement components,
proteases, NO, reactive oxygen metabolites, and peroxynitrite, all important mediators of tissue injury (24). Prevention of neutrophil-dependent inflammatory pathways is
likely to contribute to the reduced fluid extravasation and
improved histologic status after PARS inhibition. There
are recent reports from our laboratory and from other
groups showing the protective effect of PARS inhibitors in
experimental models of stroke (4, 27), endotoxic shock
(28), and ischemia-reperfusion injury (29). Because extensive activation of PARS due to massive oxidant-mediated
DNA injury can lead to pronounced NAD+ and ATP depletion in various tissues, it was generally assumed that the
mode of protection by inhibitors of PARS is directly related to improved metabolic status of the target tissues in these models (1, 27, 28). In fact, in in vitro studies, our
group and other investigators have observed that hydrogen peroxide, oxyradical- or peroxynitrite-induced cellular injury is ameliorated by pharmacological inhibition of PARS
(1, 27, 28), or in cells derived from the PARS/
mice,
when compared to corresponding wild-type controls (6, 30). Based on the data presented in this study, however, we propose that reduced neutrophil recruitment represents an
important additional mechanism for the antiinflammatory
effects provided by PARS inhibition.
Although PARS inhibition was effective in reducing PMN recruitment in all inflammatory models tested, paradoxically, the protective effects appeared to be more pronounced in more severe forms and more delayed stages of inflammation (compare, for example, the effects of 3-aminobenzamide on the delayed versus the early phase of zymosan peritonitis (Fig. 1) or carrageenan paw edema (Fig. 4). This effect may be related to the fact that PARS activation and related cellular alterations mainly occur under conditions of more severe oxidant stress.
It is likely that inhibition of PARS exerts antiinflammatory effects both independently of PMN accumulation and via inhibition of PMN influx into the tissues. An example for a PMN-independent protection is inhibition of paw edema development in the early phase of carrageenan edema; 1-2 h after carrageenan injection, only a small degree of PMN infiltration into the paw tissue can be detected (16). Such early protection by PARS inhibitors may be related to protection against early, PMN-independent oxidant injury. A likely species responsible for such effects is peroxynitrite, an oxidant produced by the reaction of NO and superoxide anion in this early stage of inflammation (19, 20). There is now good evidence that many cytotoxic effects of peroxynitrite (suppression of cellular metabolism, epithelial hyperpermeability, endothelial dysfunction) are at least in part due to PARS activation (1, 28, 31).
The antineutrophil and antiinflammatory effects of 3-aminobenzamide were likely to be related to PARS inhibition,
rather than some other pharmacological action of this agent,
since (a) the inactive analog of 3-aminobenzamide (3-aminobenzoic acid) did not affect neutrophil recruitment or
edema formation, and (b) the antiinflammatory effects of
3-aminobenzamide were also reproducible in the PARS/
animals in the zymosan model of multiple organ failure.
With regards to 3-aminobenzoic acid, it is noteworthy that
in contrast to 3-aminobenzamide, 3-aminobenzoic acid does
not protect endothelial cells against oxidant injury (6), or
tissues against reperfusion injury (29).
What, then, is the mechanism of protection against PMN recruitment provided by PARS inhibition? The data presented in this study provide evidence that the effects of PARS inhibition are mainly due to interference with PMN postadhesion phenomena. The strongest indication for this conclusion derives from our experiments using intravital microscopy, which allows characterization of temporally related processes such as rolling, adhesion, and emigration (32). In our model, zymosan challenge produced a significant degree of cell adhesion and emigration in the mouse mesenteric microcirculation. Treatment of mice with 3-aminobenzamide did not modify zymosan-induced cell adhesion to any extent, but the drug suppressed the degree of cell emigration. This result clearly indicated that 3-aminobenzamide was affecting postadhesion phenomena such that only the number of emigrated cells was altered when analysis was done at a fixed time point (4 h). To further investigate this phenomenon, an appropriate protocol was set up to monitor the adherent leukocytes in real time. Inflammation in the mouse mesentery was induced by zymosan, and postcapillary venules with a congruous number of adherent cells were selected, such that their fate could be monitored after intravenous challenge with 3-aminobenzamide or vehicle. Under these conditions, the PARS inhibitor produced a marked phenomenon of detachment. A similar, higher incidence of leukocyte detachment has been described in response to dexamethasone (33).
The mechanisms regulating leukocyte emigration through the gap formed between adjacent endothelial cells in inflammatory conditions are incompletely understood. In this respect, adhesion molecules such as leukocyte integrins, as well as endothelial intercellular adhesion molecule-1 and platelet-endothelial cell adhesion molecule-1, have been shown to play an important role (32, 34). Since PARS regulates the expression of various genes (36), the possibility that PARS may alter the expression of adhesion receptors involved in postadhesion/emigration processes may be proposed. The immediate course (within minutes) of the leukocyte detachment seen after 3-aminobenzamide administration, however, would argue against a mechanism related to altered expression of adhesion molecules, at least in this experimental setting. Endothelial-derived NO inhibits PMN infiltration into the inflammatory tissue sites. In this respect, there are a number of reports demonstrating that oxidant injury to the vascular endothelium, triggered by oxyradicals or by peroxynitrite, is in part mediated by PARS activation (6, 39). Inhibition of PARS has been shown to improve the morphology, metabolic status, and function of the vascular endothelium under oxidant stress (6, 39). Thus, PARS may modulate PMN emigration by altering the metabolic/functional status of the vascular endothelium.
These data, coupled with a number of recent observations, suggest that PARS activation plays a role in oxidant injury in various forms of inflammation and reperfusion injury. These data emphasize the importance of neutrophil recruitment blockade for the protection provided by PARS inhibition. This effect, coupled with a direct cytoprotective effect of PARS inhibition against oxidant injury (1, 28, 30, 39), may explain the antiinflammatory effects seen with PARS inhibition. Based on these data, we propose that pharmacological inhibition of PARS represents a novel strategy for antiinflammatory therapy.
Address correspondence to Dr. Csaba Szabó, Children's Hospital Medical Center, Division of Critical Care, 3333 Burnet Avenue, Cincinnati, OH 45229. Phone: 513-636-8714; FAX: 513-636-4892.
Received for publication 23 May 1997 and in revised form 29 July 1997.
1 Abbreviations used in this paper: AST, aspartate aminotransferase; LDH, lactate dehydrogenase; MPO, myeloperoxidase; PARS, poly (ADP-ribose) synthetase.This work was supported by a grant from the National Institutes of Health (R29GM54773) to C. Szabó. R.J. Flower is a Principal Research Fellow of the Wellcome Trust, whereas M. Perretti is a postdoctoral fellow of the Arthritis & Rheumatism Council (United Kingdom).
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