We evaluated in vitro the functional role of mucoid exopolysaccharide (MEP) of Pseudomonas aeruginosa in blocking antibiotic-induced and polymorphonuclear leukocyte (PMN)-mediated pseudomonal killing. The serum-resistant P. aeruginosa isolates used were mucoid strain 144MR and its nonmucoid revertant, strain 144NM. By timed kill curves, early bactericidal effects of-amikacin against mucoid strain 144MR were substantially less than those observed with nonmucoid strain 144NM; this effect was reversible with enzymatic hydrolysis of MEP of strain 144MR by alginase. Also, early tobramycin uptake (15 to 30 min) by mucoid 144MR cells was less than that seen with nonmucoid strain 144NM; pretreatment of 144MR cells with alginase substantially enhanced early tobramycin uptake compared with untreated 144MR cells (P = 0.08). In strain 144NM (but not in strain 114MR) there was a notable postantibiotic leukocidal enhancement effect manifested by increased nonopsonic killing following brief exposure of these cells to supra-MIC amikacin; pretreatment of strain 144MR with alginase rendered these cells more susceptible to amikacin-induced postantibiotic leukocidal enhancement. Similarly, direct PMN-mediated nonopsonic killing of mucoid strain 144MR was significantly less than that observed with strain 144NM (P < 0.05); pretreatment of 144MR cells with alginase rendered this strain equal to strain 144NM in susceptibility to nonopsonic killing. In addition, exogenous sodium alginate or extracted MEP of strain 144MR interfered with effective nonopsonic killing of strain 144NM by PMNs. Studies also indicated that mucoid strain 144MR was phagocytosed significantly less well than its nonmucoid mate (P < 0.00001), an effect reversed by pretreatment of the mucoid cells with alginase. These data confirm that P. aeruginosa MEPs functionally decrease the uptake and early bactericidal effect of aminoglycosides in vitro and interfere with effective PMN-mediated nonopsonic phagocytosis and killing of mucoid strains.
The exopolysaccharide (alginate) of mucoid strains ofPseudomonas aeruginosa is believed to be an important virulence factor. The ability of an alginate-depolymerizing enzyme (alginase) to modify the polymorphonuclear leukocyte (PMN)-directed and antibiotic-mediated phagocytosis and killing of mucoid P. aeruginosa was studied both in vitro and in vivo. In vitro, pretreatment of a mucoid P. aeruginosa strain (144MR) resulted in a significant enhancement of PMN phagocytosis and killing of the organism (P < 0.05), to levels similar to that observed with its nonmucoid mate, strain 144NM. Moreover, alginase treatment of the mucoid strain 144MR caused a substantial removal of bacterial cell surface alginate as assessed by immunofluorescence staining with a murine monoclonal antialginate antibody. The experimental endocarditis model was used to evaluate the in vivo effect of alginase in modifying the course of a deep-seated pseudomonal infection caused by mucoid strain 144MR. In right-sided endocarditis, in which PMNs normally mediate spontaneous clearance of the organism from cardiac vegetations (Chemotherapy 35:278-288, 1989), the presence of the alginate exopolysaccharide on strain 144MR was associated with an inability to reduce intravegetation pseudomonal counts over a 13-day postinfection period; in contrast, right-sided vegetations infected with the nonmucoid strain 144NM underwent significant reductions in bacterial densities over this same time (P < 0.05). Administration of alginase intravenously (i.v.) (750 enzyme units per day for 7 days) to animals with right-sided endocarditis caused by the mucoid strain 144MR was associated with a significant reduction in intravegetation pseudomonal counts (P < 0.05), to levels similar to that seen with endocarditis caused by the nonmucoid strain. In left-sided endocarditis caused by mucoid strain 144MR, animals received either no therapy, amikacin (20 or 40 mg/kg twice a day for 7 or 14 days), or amikacin plus alginase (750 U/day [i.v.]). The coadministration of alginase for 14 days with the higher-dose amikacin regimen rendered more left-sided vegetations culture negative than those in animals receiving the antibiotic alone for 7 or 14 days (P = 0.001 and 0.056, respectively). These salutary effects of alginase in vivo were paralleled by the ability of the enzyme to remove the exopolysaccharide from the surface of mucoid pseudomonal cells within cardiac vegetations, as assessed by transmission electron microscopy. Collectively these data indicate that the alginate exopolysaccharide was an important factor in inhibiting clearance of mucoid pseudomonal organisms from vegetations by both PMN-directed and antibiotic-mediated processes; the coadministration of alginase in vivo enhanced the clearances of mucoid pseudomonal strains from such infection foci.
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