Faculty Bibliography

We studied the effect of complement on two life cycle stages of the protozoan parasite Trypanosoma cruzi: epimastigotes, found in the insect vector, and amastigotes, found in the mammalian host. We found that while both stages activate vigorously the alternative pathway, only epimastigotes are destroyed. The amounts of C3 and C5b-7 deposited on the amastigotes were similar to those bound to the much larger epimastigotes. Binding of C9 to amastigotes was four to six times less than binding to epimastigotes, resulting in a lower C9/C5b-7 ratio. Although a fairly large amount of C9 bound stably to amastigotes, no functional channels were formed as measured by release of incorporated 86Rb. The bound C9 had the characteristic properties of poly-C9, that is, it expressed a neo-antigen unique to poly-C9, and migrated in SDS-PAGE with an apparent Mr greater than 10(5). The poly-C9 was removed from the surface of amastigotes by treatment with trypsin, indicating that it was not inserted in the lipid bilayer. Modification of amastigote surface by pronase treatment rendered the parasites susceptible to complement attack. These results suggest that amastigotes have a surface protein that binds to the C5b-9 complex and inhibits membrane insertion, thus protecting the parasites from complement-mediated lysis

We have recently shown by dose-response analyses with resealed erythrocyte ghosts that the channel formed by complement is a monomer of C5b-9 of the composition C5b61C71C81C9n, in which n = 1 for channels permitting passage of sucrose (0.9 nm molecular diameter) and n = 2 for channels allowing transit of inulin (3 nm molecular diameter) (1). We have now continued these experiments and expanded them by including ribonuclease A (molecular diameter, 3.8 nm) as a marker to assess whether additional C9 molecules enlarge the functional C5b-9 channel. Our results show that formation of C5b-9 channels displays one-hit characteristics with respect to C5b6 when tested by transmembrane passage of inulin or ribonuclease A. By contrast, analysis of dose-response curves of C9 indicate that n = 2-3 for channels allowing transit of inulin and n = 4 for channels allowing transit of ribonuclease A. We have also performed sieving experiments with ghosts carrying C5b-7 and containing two small markers, inositol and sucrose. Dose-response curves for C8 were performed in the presence of excess C9 to ensure conversion of all C5b-8 to C5b-9 channels. The results indicate that small channels (approximately 0.8 nm effective diameter) are not formed at high C9 multiplicity, thus confirming the results obtained with the larger markers, i.e., increase of C9 input leads to formation of larger channels

We have developed a technique in which transglutaminase is used to measure the penetration of terminal complement proteins across the erythrocyte membrane into the cytoplasmic space. Penetration of a given terminal complement protein into the cytoplasmic space was assessed by labeling the protein of interest with radioactive iodine, forming the complement channel using the labeled protein, adding transglutaminase to only one side of the membrane, and allowing the enzyme to cross-link the susceptible proteins on that side of the membrane. Cross-linking was assessed by measuring the increase in molecular weight of the appropriate molecule on sodium dodecyl sulfate gels under reducing conditions. The results of these experiments indicate that C8 and C9 are rapidly cross-linked to high molecular weight from either the interior or the exterior of the membrane. In order to determine whether the cross-linking mediated by enzyme on the interior was occurring from within the ghosts and not via enzyme that had leaked into the extracellular medium, experiments were performed with dimethylcasein in the extracellular medium. In the presence of this protein, cross-linking of C8 and C9 from outside was negligible. Hence, if cross-linking occurs when transglutaminase is trapped inside the ghosts, it cannot be due to leakage of enzyme, but must be attributable to cross-linking from the inside. The results show that C9 definitely penetrated across the membrane into the intracellular space. With respect to C8, statistical evaluation indicates that C8 probably penetrated into the intracellular space

We have previously shown that lysis of a nucleated mammalian cell requires several complement channels unlike lysis of erythrocytes and that this difference is due primarily to rapid elimination of channels from the plasma membrane. We have now investigated this problem further by studying the rate of channel elimination at low temp, the osmotic fragility of the cells, and the effectiveness of the membrane-associated ion pumps. When complement channels were formed for 3 min at 37 degrees C, followed by prolonged incubation at 2 degrees C, the C6 lytic dose-response curves indicated that a single channel was required for lysis of a cell, whereas multiple channels were required when the entire process was carried out at 30 degrees C. The shift from multi- to one-hit lytic behavior can be explained by the drastic reduction in the rate of channel elimination at low temp. C6 lytic dose-response curves with puromycin-treated cells were also found to display one-hit behavior, but, in this case, the rate of channel elimination was reduced only about 35-40% (which would not suffice to explain the one-hit lytic characteristics). However, cell death was more extensive for puromycin-treated cells than normal cells after incubation in buffers of low ionic strength, suggesting that an increase in osmotic fragility may be a contributing factor in the shift from multi- to one-hit behavior. Blocking of the membrane-associated Na+/K+-ATPases with ouabain did not affect the multi-channel requirement. Presumably, this means that the ion pumping rate does not significantly influence the number of channels required for lysis

We have studied the release of radiolabeled small markers from nucleated cells carrying complement channels in order to determine the life-span of these channels at various temperatures. U937 cells, a human histiocytic cell line, were labeled with 14C-aminoisobutyric acid or 86RbCl, and treated with sublytic doses of C to form transmembrane channels. The cells were then incubated at various temperatures, and the persistence of channels was evaluated by measuring the release of the intracellular markers through the remaining channels. The results indicate that the life-span of the C channels in the plasma membranes of these cells varies markedly with temperature. Thus, at 2 degrees C, the half-life of the channels was about 2 hr, whereas at 37 degrees C, the half-life was estimated to be approximately 1 min. The rapid elimination of the transmembrane channels from the plasma membranes of these nucleated cells contrasts sharply with the long persistence of C channels in the membranes of erythrocytes or erythrocyte ghosts. It is likely that the multi-hit requirement recently reported for lysis of nucleated mammalian cells by C is due, at least in part, to the rapid disappearance of channels

We have performed double marker sieving experiments with molecules ranging from ca. 0.5-3 nm dia. in order to evaluate the size distribution of the channels formed by complement in resealed sheep erythrocyte ghosts. Evidence is presented that marker release through the channels reached equilibrium between the ghosts and the extracellular fluid in a period of 3 hr and that the channels are stable at 37 degrees C for this period of time. Under these experimental conditions we have observed a differential in the endpoint release of inositol and sucrose, which indicates that some of the ghosts carried channels measuring between 0.7 and 0.9 nm dia. No differential was observed between release of sucrose and raffinose (0.9 and 1.1 nm mol. dia., respectively). Comparisons between sucrose and inulin (0.9 and 3 nm mol. dia, respectively) showed a difference in marker release. Also, there was substantial release of inulin, indicating the presence of channels above 3 nm in dia. Hence, the present data indicate formation of channels in three size ranges, namely, 0.7-0.9 nm, 0.9-3 nm and greater than 3 nm