Effects of Mannheimia haemolytica leukotoxin on apoptosis and oncosis of bovine neutrophils.

OBJECTIVE: To investigate the concentration-dependent effects of Mannheimia haemolytica (formerly Pasteurella haemolytica) leukotoxin (LKT) on apoptosis and oncosis in bovine neutrophils and to examine the role of calcium ions (Ca2+) in LKT-induced apoptosis. SAMPLE POPULATION: Neutrophils isolated from blood samples obtained from healthy calves. PROCEDURE: Neutrophil suspensions were exposed to lytic or sublytic dilutions of LKT and then examined by use of transmission electron microscopy (TEM) or gel electrophoresis. Contribution of extracellular Ca2+ to LKT-induced apoptosis was investigated by incubating neutrophils with LKT or control solutions in buffer containing 1 mM CaCl2 or in Ca2+-free buffer containing 1 mM ethylene glycol-bis (b-aminoethyl ether)-N,N-tetraacetic acid (EGTA) prior to diphenyl amine analysis. RESULTS: Examination by TEM revealed that bovine neutrophils exposed to lytic dilutions of LKT had changes consistent with oncosis, whereas neutrophils exposed to sublytic dilutions of LKT and staurosporin, an inducer of apoptosis, had changes consistent with apoptosis. Effects of sublytic dilutions of LKT on apoptosis were confirmed by gel electrophoresis. Replacement of extracellular Ca2+ with EGTA, a Ca2+ chelator, reduced apoptosis attributable to the calcium ionophore A23187, but it did not have significant effects on apoptosis induced by LKT or staurosporin. CONCLUSIONS AND CLINICAL RELEVANCE: The ability of LKT to cause apoptosis instead of oncosis is concentration-dependent, suggesting that both processes of cell death contribute to an ineffective host-defense response, depending on the LKT concentration in pneumonic lesions. Furthermore, although Ca2+ promotes A23187-induced apoptosis, it is apparently not an essential second messenger for LKT-induced apoptosis.

Intravenous pharmacokinetics of penicillin G and antipyrine in ostriches (Struthio camelus) and emus (Dromaius novaehollandiae).

Penicillin G and antipyrine, which served as model drugs to assess the relative capacities of renal and hepatic elimination pathways, respectively, were each administered intravenously to six ostriches (Struthio camelus) and to six emus (Dromaius novaehollandiae). Drug concentrations in blood samples collected over a period of 12 hr after administration were assayed, and elimination half-life, mean residence time, clearance, and steady-state volume of distribution were calculated. Mean values for elimination half-life and mean residence time of penicillin G were significantly higher in emus than in ostriches; no significant differences in antipyrine pharmacokinetics between species were demonstrated.

Correlation of Pasteurella haemolytica leukotoxin binding with susceptibility to intoxication of lymphoid cells from various species.

Pasteurella haemolytica, the causative agent of shipping fever pneumonia in cattle, produces a leukotoxin (LKT) which lyses ruminant leukocytes with high efficiency but is reputed to not affect leukocytes from nonruminant species. In this study, we tested the supposition that LKT binding correlates positively with susceptibility to intoxication of susceptible isolated bovine lymphocytes and lymphoma tissue culture cells (BL3 cells) and negatively with reputed nonsusceptible equine, porcine, and canine lymphocytes and human lymphoid tissue culture cells (Raji cells). Bovine lymphocytes and BL3 cells were highly susceptible to LKT intoxication, exhibiting both substantial increase in intracellular Ca(2+) concentration and marked leukolysis. Exposure of reputed LKT-nonsusceptible porcine lymphocytes and Raji cells to LKT caused a slightly increased intracellular Ca(2+) concentration but no leukolysis. No LKT effect was detected for equine and canine lymphocytes. LKT bound to lymphoid cells from all species tested. Intact 102-kDa LKT was recovered from exposed isolated lymphoid cell membranes. Pro-LKT acylation was not required for LKT binding to BL3 cells. LKT binding was rapid, with maximal binding occurring by 3 min, and was proportional to the LKT concentration in the range 0.04 to 4.0 microg/ml. For this LKT concentration range, BL3 cells bound more LKT than did porcine lymphocytes or Raji cells, suggesting that LKT binds to BL3 cells with higher affinity than to porcine lymphocytes or Raji cells. Above 4.0 microg/ml, LKT demonstrated saturable binding to BL3 cells. Neutralizing anti-LKT monoclonal antibody (MAb) MM601 diminished LKT binding to BL3 by 36% while decreasing leukolysis by 81%. In contrast, MM601 did not diminish LKT binding to Raji cells. Pretreatment of target cells with 120 microg of protease K per ml diminished LKT binding to BL3 cells by 75%, with only a 25% decrease in leukolysis. However, pretreatment with 150 microg of protease K per ml abolished the remaining 25% of LKT binding and 75% leukolysis. Therefore, P. haemolytica LKT binds rapidly to susceptible and to reputed nonsusceptible lymphoid cells. LKT binding resulting in species-specific leukolysis was characterized by high affinity, inhibition by MAb MM601, and relative resistance to protease K pretreatment of lymphoid cells. Two types of LKT binding to lymphoid cells are proposed. High-affinity binding leads to efficient leukolysis. In some lymphoid cells from reputed LKT-nonsusceptible species, low-affinity LKT binding may cause a low-efficiency increase in the intracellular Ca(2+) concentration without leading to leukolysis.

Pharmacokinetics and toxicity of tolonium chloride in sheep.

The pharmacokinetic disposition, urinary excretion and toxicity of tolonium chloride were determined after i.v. administration to sheep. Pretreatment with sodium nitrite significantly decreased the volume of the central compartment, apparent volume of distribution, area under the concentration-time curve, and total body clearance of tolonium chloride. Urinary excretion of tolonium chloride and its metabolite, leucotolonium chloride, together accounted for less than 15% of the administered dose in sheep receiving sodium nitrite and less than 10% of the administered dose in control sheep. The LD50 of tolonium chloride was 10 mg/kg with a 95% confidence interval of 7.35-13.60 mg/kg. Comparison with previously published data describing the pharmacokinetics and toxicity of a related compound, methylene blue, indicated that tolonium chloride has a higher volume of distribution and a narrower therapeutic index.