Contractile function and myoplasmic free Ca2+ (Cam) in coronary and mesenteric arteries of endotoxemic guinea pigs.

Endotoxin-induced vascular hyporesponsiveness could potentially involve alterations of vascular smooth muscle (VSM) myoplasmic free calcium (Ca(m)) mobilization mechanisms. Contractile function and Ca(m)(fura-2 microfluorometry) regulation were evaluated in vitro using coronary (COR) and mesenteric (MES) artery preparations (100-250 microm inner diameter) isolated from guinea pigs 16 h after intraperitoneal (i.p.) injection of either saline (control; CON) or Escherichia coli endotoxin lipopolysaccharide (LPS; 4 mg/kg). Concentration-response relationships to K+ (5-100 mM) were significantly enhanced in both COR and MES arteries isolated from LPS-treated animals. In contrast, contractile responses to prostaglandin F2alpha (PGF2alpha; 1-100 microM) were markedly impaired in COR and MES arteries from LPS-treated animals, while endothelin-1 (ET; 1-100 nM)-mediated contractile responses of these arteries were enhanced at the maximal dose (100 nM). In COR arteries, PGF2alpha (1-100 microM) and ET (1-100 nM) produced biphasic increases in Ca(m) in both CON and LPS groups. No significant differences were observed in either the initial transient peak or secondary sustained Ca(m) responses between groups, suggesting a lack of effect of LPS upon intracellular Ca2+ release or Ca2+ influx mechanisms in COR arteries. Exposure of MES arteries to PGF2alpha and ET produced concentration-dependent increases in Ca(m) in both groups. However, Ca(m) responses of MES arteries lacked initial peak responses, suggesting potential differences in Ca(m) mobilization between COR and MES arteries. Ca(m) responses to K+ (80 mM) and PGF2alpha (1-100 microM) were similar in MES arteries from both groups; however, ET-mediated increases in Ca(m) were significantly blunted in LPS compared with CON MES arteries. Thus, endotoxemia produced differential effects upon depolarization (K4) and receptor (PGF2alpha, ET)-mediated contractile responses in both COR and MES arteries. Reductions in VSM Ca(m) mobilization appear unlikely as a mechanism for LPS-induced impairment of contractile function of COR and MES arteries; other mechanisms (i.e., decreased Ca2+ sensitivity of contractile proteins) may be involved in effects of LPS upon VSM function of COR and MES arteries.