Thymocyte and peripheral blood T lymphocyte subpopulation changes in piglets following in utero infection with porcine reproductive and respiratory syndrome virus.

Piglets infected in utero with porcine reproductive and respiratory syndrome virus (PRRSV) are born severely immunocompromised. In this article we more closely examine the effects of in utero PRRSV infection on circulating and thymic T cell populations. Numbers of CD4+, CD8+, and dual-positive lymphocytes were quantitated in circulation and in the thymus during the 2 weeks following birth. At birth we found that the number of circulating lymphocytes was suppressed by 60%. Lymphocyte numbers were also suppressed by 42% at day 7, but by day 14 the number of lymphocytes had rebounded and was actually 47% greater than controls. At birth and day 7, a drop in the number of CD4+ cells could partially explain the suppression we observed, while the rebound in total lymphocyte numbers seen at day 14 was due to a nearly fourfold increase in the number of circulating CD8+ cells. As a result, the normal CD4+:CD8+ ratio of between 1.4 and 2.2 for neonatal pigs was reduced to 0.1-0.5. The thymuses of infected piglets were found to be 50% smaller than those of control pigs and were characterized by cortical involution and severe cortical depletion of thymocytes. Analysis of the population of thymocytes revealed that double-positive thymocytes were suppressed to a greater degree than either single positive subpopulation. In addition, we show that the number of thymocytes undergoing apoptosis was increased twofold in piglets infected with PRRSV. Taken together, these results help explain the dramatic immunosuppression observed in neonatal animals infected in utero with PRRSV.

In utero infection by porcine reproductive and respiratory syndrome virus is sufficient to increase susceptibility of piglets to challenge by Streptococcus suis type II.

Porcine reproductive and respiratory syndrome (PRRS) consistently elevates the frequency of disease and mortality in young pigs. Many different secondary bacterial diseases occur in PRRS virus (PRRSV)-infected pigs. However, to date, establishing a reproducible experimental model of PRRSV infection in weaned pigs, with subsequent clinical disease following secondary bacterial challenge, has been difficult. PRRSV is frequently isolated during outbreaks from weak-born piglets affected by secondary bacterial diseases. This study was performed to investigate the potential role of intrauterine PRRSV infection on piglet susceptibility to secondary bacterial infection. PRRSV-free pregnant sows were intranasally infected at 98 days of gestation with PRRSV strain SD 23983. All piglets born to the PRRSV-infected sows were viremic. Piglets were removed from the sows at birth and deprived of colostrum. Piglets from PRRSV-infected and noninfected sows were randomly assigned to Streptococcus suis challenge or control subgroups. At 5 days of age, piglets were challenged intranasally with strain MN 87555 of S. suis type II. Total and differential leukocyte counts were performed on blood samples collected at 3 days of age. The numbers of leukocytes, lymphocytes, and monocytes were significantly reduced in the PRRSV-infected piglets. Lesions were observed in bone marrow, brain, lung, heart, spleen, lymph node, tonsil, and thymus of PRRSV-infected piglets. Thymus/body weight ratios of in utero PRRSV-infected piglets were significantly reduced compared to those of non-PRRSV-infected piglets, and thymic lesions were characterized by severe cortical depletion of thymocytes. Lesions were not observed in piglets born to PRRSV-free sows. Overall, 20 out of 22 piglets in the PRRSV-S. suis dual-infection group died within 1 week after challenge with S. suis (10 of 11 in each of two trials). This contrasts with 1 of 18 piglets in the PRRSV-infection-only group and 5 of 23 piglets in the S. suis-challenge-only group (1 of 12 in trial 1 and 4 of 11 in trial 2). No piglets died in the uninfected control groups. Most of the piglets in the PRRSV-S. suis dual-infection group developed suppurative meningitis. S. suis type II was recovered from their brains and joints. These results indicate that in utero infection by PRRSV makes piglets more susceptible to infection and disease following challenge by S. suis type II. In utero infection by PRRSV may provide a useful model to study the interaction between PRRSV and bacterial coinfections in piglets.

Characterization of arachidonic acid-induced apoptosis.

Tumor necrosis factor (TNF) can induce apoptosis in a number of different cell types. This response often depends on the activity of cytosolic phospholipase A2 (cPLA2), which catalyzes the release of arachidonic acid from the sn-2 position of membrane phospholipids. In this study, we investigate the ability of arachidonic acid itself to cause cell death. We show that in assays with 10% fetal bovine serum (FBS) arachidonic acid will not kill, nor does act synergistically with TNF. In contrast, by lowering the concentration of FBS to 2%, it is possible to use arachidonic acid to induce cell death. Arachidonic acid-induced cell death was judged to be apoptotic based on morphology and the cleavage of poly(ADP)ribose polymerase. Arachidonic acid was able to kill all cell lines tested including two human melanoma-derived cell lines, and susceptibility to arachidonic acid was not influenced by adenovirus gene products that control susceptibility to TNF. Finally, we show that arachidonic acid is unique among 20 carbon fatty acids for its ability to induce apoptosis and that several other unsaturated, but not saturated fatty acids can also induce apoptosis.

Sustained phosphorylation of cytosolic phospholipase A2 accompanies cycloheximide- and adenovirus-induced susceptibility to TNF.

In this report we examine the phosphorylation state of cytosolic phospholipase A2 (cPLA2) in C3HA fibroblasts that have been treated with TNF, cycloheximide (CHI), or a combination of both compounds. Our experiments show that TNF and CHI, when used independently, caused the rapid phosphorylation of cPLA2 (within 10 min). In both cases, cPLA2 was subsequently dephosphorylated to pretreatment levels by 40 min. In addition, under these conditions [3H]arachidonic acid was not released, and we could not detect a change in the activity of cPLA2 in vitro. In contrast, in cells treated with a combination of TNF and CHI, we found that the dephosphorylation of cPLA2 was inhibited, and cPLA2 remained phosphorylated for up to 2 h. In vitro we found that sustained phosphorylation of cPLA2 was accompanied by a 60 to 80% increase in the activity of cPLA2. The sustained phosphorylation of cPLA2 also occurred in cells infected with the adenovirus mutant dl309, suggesting that sustained phosphorylation may be a general requirement for the activation of cPLA2 in apoptotic cells. We also found that sustained phosphorylation of phosphoproteins is not a general consequence of apoptotic death, since the phosphorylation of p42 mitogen-activated protein kinase was not sustained. Finally, we show that the phosphatase inhibitor orthovanadate acts as does CHI to render cells susceptible to TNF, suggesting that resistance to TNF may depend on TNF's ability to induce the expression of tyrosine or dual specificity phosphatase(s).

The activity of cytosolic phospholipase A2 is required for the lysis of adenovirus-infected cells by tumor necrosis factor.

Most cell types are resistant to apoptosis induced by tumor necrosis factor (TNF) unless the cells are treated with a sensitizing agent. Inhibitors of transcription or translation act as sensitizing agents, as do adenoviruses lacking one or more resistance genes. We have reported recently that the activity of cytosolic phospholipase A2 (cPLA2) is necessary for the TNF-induced lysis of cells that are sensitized by inhibitors of transcription or translation (C. Voelkel-Johnson, T. E. Thorne, and S. M. Laster, J. Immunol. 156:201-207, 1996). In this report we have asked whether the lysis of cells infected by the adenovirus dl758 (which lacks the E3 14.7-kDa resistance gene product) also involves the activity of cPLA2. We report that a phosphorothioate-modified antisense oligonucleotide specific for cPLA2, but not the control oligonucleotide, inhibited the TNF-induced release of both [3H]arachidonic acid and 51Cr from infected cells. Arachidonyltrifluoromethyl ketone (AA COCF3), an inhibitor of cPLA2, also inhibited the release of 51Cr, and we found that the release of [3H]arachidonic acid was highly selective and was preferred over the release of [3H]palmitic acid. Taken together, these results suggest strongly that cPLA2 is indeed the phospholipase responsible for the release of [3H]arachidonic acid during the lysis of infected cells and that its activity is necessary for cell death. Finally, since arachidonic acid serves as the substrate for the synthesis of inflammatory lipids, our results suggest a possible link between the TNF-induced lysis of infected cells and inflammation. The E3 14.7-kDa resistance protein may, therefore, play two roles: preventing TNF-induced cell death and, as our results show, preventing the TNF-induced release of arachidonic acid.

Bleb formation and F-actin distribution during mitosis and tumor necrosis factor-induced apoptosis.

The murine cell line C3HA has been used extensively in studies of the cytopathology that accompanies TNF-induced cytolysis. This cell line undergoes an apoptic form of cell death characterized by plasma membrane blebbing and cytoplasmic boiling. Since plasma membrane blebs also appear on C3HA cells during mitosis, in this report we have compared these blebs with those that appear during apoptosis to determine whether they represent related structures. Our results reveal several differences. During mitosis, the blebs that appear are smaller and more heterogeneous in size than are those that appear during apoptosis. In addition, during mitosis bleb formation is preceded by the appearance of microvilli on the cell surface. No microvilli are observed during apoptosis. The staining pattern with rhodamine phalloidin also differed between mitotic and apoptic blebs, indicating a difference in their content of f-actin. The blebs that form during mitosis stained in a bright, uniform manner, suggesting an association with f-actin. In contrast, apoptic blebs were stained only at their base, the bleb itself being devoid of f-actin-associated staining. This difference may help explain why mitotic blebs are reintegrated into the cell surface, while the blebs that form during apoptosis are not.

Susceptibility to TNF in the presence of inhibitors of transcription or translation is dependent on the activity of cytosolic phospholipase A2 in human melanoma tumor cells.

In this study, we have examined the relationship between the expression of the high molecular weight, cytosolic form of PLA2 (cPLA2) and ability of inhibitors of transcription or translation (ITT) to induce susceptibility to TNF. S Susceptibility to lysis was assayed by 51CR release, and the expression of cPLA2 was assayed by activity assay and by Western blot. The panel of cells that we examined included two murine cell lines, six human melanoma-derived cell lines, two samples of freshly explanted melanoma tumor tissue, and a culture of normal epidermal melanocytes. Our experiments revealed a near perfect correlation between the activity of cPLA2 per cell and susceptibility to TNF in the presence of either cycloheximide (CHI) or actinomycin D (r = 0.97). These results suggest that the activity of cPLA2 is both necessary and rate-limiting in this form of programmed cell death, conclusions that were confirmed in transfection experiments and in experiments with antisense oligonucleotides. Over-expression of cPLA2 in two melanoma-derived cell lines, WM793 and SK-MEL-131, led to enhanced susceptibility to TNF and CHI. Conversely, suppression of cPLA2 with antisense oligonucleotides dramatically decreased susceptibility to TNF and CHI in C3HA fibroblasts. These experiments also revealed a coupled, transformation-released change in the expression of cPLA2 and susceptibility to lysis. Normal melanocytes contained the lowest levels of cPLA2 and were completely resistant to sensitization with ITT. In contrast, all of the melanoma-derived cell lines and samples of melanoma tumor tissue we examined has higher levels of cPLA2 and could be killed, to some extent, by treatment with TNF and ITT.

Activation of intracellular proteases is an early event in TNF-induced apoptosis.

The serine protease inhibitor tosyl-argenine methyl ester inhibits TNF-induced apoptosis, suggesting that proteolysis is necessary for this response. To test this hypothesis, we asked whether protein fragmentation occurs during the death of C3HA fibroblasts, a 3T3-like cell that was rendered sensitive to TNF by cycloheximide. Our results show that the binding of fluorescamine, which binds primary amines, was increased in apoptotic cells by approximately 50%. We also found that 10-15% of the protein in apoptotic cells was no longer precipitable by TCA. Evidence for proteolysis was also revealed by SDS-PAGE analysis and from Western blots. We observed fragmentation and/or degradation of lamin B, topoisomerase I, histone H1, protein kinase C beta 1, and cPLA2, indicating that proteolysis during apoptosis is non-specific. We also found evidence of proteolysis in C3HA cells sensitized to TNF by the adenovirus dl758 (which lacks the E3 14.7-kDa resistance gene) suggesting that protease activation is common in TNF-induced apoptosis. In contrast, the adenovirus E3 14.7-kDa resistance gene prevented proteolysis suggesting that this protein acts at, or upstream of the proteases activated in this response. Finally, because tosyl-argenine methyl ester inhibits the release of [3H]arachidonic acid from apoptotic cells, we tested whether proteolysis of cPLA2 is necessary for enzyme activation. Our results failed, however, to reveal a common proteolytic fragment in different cell types, and when tested in vitro the cytosol from apoptotic cells had less cPLA2 activity. It is unlikely, therefore, that proteolysis is necessary for the activation of this enzyme during TNF-induced apoptosis.

Avian macrophages: contribution to cellular microenvironment and changes in effector functions following activation.

The capacity of macrophages to generate metabolites and monokines having effector and regulatory functions can result in a major impact on their cellular microenvironment. Macrophage products synthesized in response to bacterial lipopolysaccharide stimulation include reactive oxygen and nitrogen intermediates as well as tumor necrosis factor (TNF). These secreted products of macrophages exhibit bioactivity either locally or systemically. Although the mechanism of action of avian monokines such as TNF-like factor may be similar to their mammalian counterparts, chicken TNF seems to lyse cells of chicken origin and not of mammalian origin. Furthermore, the generation and activity of products such as TNF is directly influenced by environmental stressors such as heat and toxins.

The adenovirus E3 region 14.7 kDa protein, heat and sodium arsenite inhibit the TNF-induced release of arachidonic acid.

In this report we show that the adenovirus E3 region 14.7 kDa protein, heat and sodium arsenite, which have been defined previously as inhibitors of cytolysis, inhibit the tumor necrosis factor-alpha (TNF)-induced release of 3H-arachidonic acid from cycloheximide-sensitized C3HA fibroblasts. Since the A23187-induced release of 3H-a.a. was unaffected, our results suggest that these inhibitors provide resistance to lysis by selectively interfering with the lytic response pathway. Our results also show that heat and sodium arsenite can themselves induce the release of 3H-arachidonic acid. These results raise the possibility that stressor-induced resistance to TNF results from the selective desensitization of phospholipase A2.

Both tumor necrosis factor and nitric oxide participate in lysis of simian virus 40-transformed cells by activated macrophages.

SV40 transformation of rodent fibroblasts generally produces cells that are highly sensitive to killing by activated macrophages. The cell line SV-COL-E8 (E8) is typical of SV40-transformed mouse fibroblasts in that it is readily lysed when exposed to activated macrophages. This killing is not due solely to TNF, because soluble TNF alone is incapable of lysing these cells. TNF is, however, necessary for lysis since antibodies to TNF will prevent macrophage-mediated lysis. Similarly, E8 is not sensitive to nitric oxide (NO); however, NO is also necessary for lysis since inhibition of NO generation (by coincubation with the arginine analogue NG-monomethyl-1-arginine) with Fe(II)) blocks lysis of E8 by activated macrophages. Cytolysis by macrophages is contact dependent, suggesting that the cell-associated TNF precursor may be involved in mediating cytolysis. However, transfected cell lines bearing cell-associated TNF precursor do not mediate killing of E8. Thus, killing of E8 either involves both TNF and NO in addition to a third, as yet unidentified, lytic mechanism, or killing requires the contact-dependent delivery of TNF and NO from the macrophage to its target.

Inhibitors of transcription and translation act synergistically with tumor necrosis factor to cause the activation of phospholipase A2.

In this report we have examined the ability of tumor necrosis factor-alpha (TNF) to induce the activity of phospholipase A2 (PLA2) in the cell line C3HA, a murine 3T3-like cell line which is normally resistant to TNF-induced cytolysis but can be sensitized with inhibitors of transcription and translation. Our results show that TNF is normally unable to induce the activity of PLA2 in this cell, as measured by the release of [3H]arachidonic acid. We find, however, that in the presence of either actinomycin D (Act D) or cycloheximide (CHI), TNF is indeed able to induce phospholipase activity and that the TNF-induced activation of PLA2 occurs 2-4 h before the onset of 51Cr release. The release of [3H]arachidonic acid was inhibited by 40-50% by pretreatment with 1 microM dexamethasone. Treatment with dexamethasone also inhibited cytolysis by 40-50% indicating that the CHI-dependent, TNF-induced activation of PLA2 is a cause, not an effect of cytolysis. The ability of TNF to induce the activity of PLA2 was also tested in two other cell types which are resistant to TNF except in the presence of Act D or CHI: SK-MEL-28, a human melanoma-derived cell line, and pVBETK-1cl15.2, an SV40-transformed murine L cell line. Our results were the same, treatment with a combination of Act D and TNF or CHI and TNF was required to cause activation of PLA2.

A defect in the sterol:steryl ester interconversion in a mutant of the yeast, Saccharomyces cerevisiae.

A culture cycle dependent interconversion of sterols and steryl esters is disturbed in a mutant of Saccharomyces cerevisiae. Independent extragenic suppressors to this mutant return the mutant's pleiotropic phenotype to that of the parental wild type. Concomitant with the alterations in interconversion, modifications were found in the yeast proteins that antigenically react with antibodies elicited against mammalian apolipoproteins. Suppressor mutations returned the aberrant immunoblot banding pattern of the mutant to that of the wild type in apolipoprotein B.

Sensitivity to tumour necrosis factor-mediated cytolysis is unrelated to manganous superoxide dismutase messenger RNA levels among transformed mouse fibroblasts.

The ability of cells to resist the cytolytic actions of tumour necrosis factor (TNF) has been shown to require TNF-induced gene expression. It has been shown in some human cells that the gene encoding manganese superoxide dismutase (MnSOD), a TNF-induced gene, can provide resistance to TNF killing. Variation in the sensitivity to TNF was observed during subcloning of mouse SV40-transformed cell lines. This variation fell into three phenotypic classes. Cells were found that were either always resistant to TNF, always sensitive to TNF, and sensitive to TNF if inhibitors of transcription or translation were present. To determine if the regulation of MnSOD was responsible for the TNF sensitivity, Northern blot analysis was carried out. These experiments showed no correlation between expression and/or induction of the MnSOD mRNA and sensitivity or resistance to TNF. These data suggest that other pathways and gene products must therefore play a role for cells to resist TNF-mediated cellular lysis.

Evidence that a target-derived soluble factor is necessary for the selective lysis of SV40-transformed fibroblasts by activated mouse macrophages.

Our laboratory is investigating the basis for the selective recognition of transformed cells by activated mouse macrophages. As targets we are using a panel of SV40-transformed, C3H.OL fibroblast cell lines (SV-COL) that display widely different levels of sensitivity to lysis, from highly sensitive to completely resistant. Our results show that adding conditioned medium from the macrophage-sensitive target SV-COL-E8 (CM(E8] to a cytolysis assay with the macrophage-resistant target SV-COL-F5f causes the macrophages to kill the resistant targets in a contact dependent fashion. We have termed this activity "macrophage cell lysis factor" (MCLF). MCLF activity was not detected in conditioned media from cells not killed by activated macrophages (i.e., 3T3-like cell lines or embryo fibroblasts) but was present in conditioned media from six other SV-COL cell lines at levels that were directly proportional to the sensitivity of those targets (r = 0.98). These data suggest that MCLF plays a key role in determining the lytic sensitivity of SV40-transformed fibroblasts. Finally, to ask whether the production of MCLF is sufficient to explain the selective recognition of SV40-transformed fibroblasts by activated macrophages we have tested whether CM(E8) will cause macrophages to kill normal cells. Our results show that in the presence of CM(E8) macrophages will kill immortalized, 3T3-like fibroblasts but will not kill normal embryo fibroblasts. These results suggest that the production of MCLF, or a similar activity, is necessary but not sufficient for macrophage cytolysis to occur and that a change in target cell phenotype that occurs during the process of immortalization is also required.

Inhibition of target cell mitochondrial electron transfer by tumor necrosis factor.

Using digitonin permeabilization to assay mitochondrial electron transfer, we have found that respiratory activity (succinoxidase and cytochrome oxidase) in three mouse fibroblast lines is completely eliminated by incubation with human recombinant tumor necrosis factor-alpha (hrTNF). As with cytotoxicity, hrTNF-induced mitochondrial dysfunction occurs in resistant cells upon inhibition of protein synthesis, whereas sensitive cells exhibit spontaneous respiratory inhibition. In C3HA cells, inhibition is detectable 1.5-2 h after hrTNF addition, preceding cell lysis by at least 5 h (as measured by dye exclusion), and is approximately coincidental with morphological changes we have previously reported for this cell line. LM cells also exhibit inhibition of electron transfer, coincidental with morphological changes. These results suggest that bioenergetic dysfunction may be involved in the cytotoxic mechanism of TNF.

Evidence against expression of an endogenous murine leukemia virus causing cellular resistance to lysis by activated macrophages.

In previous studies we observed that resistance of murine SV40-transformed fibroblast cell lines to cytolysis by activated macrophages was frequently associated with cellular expression of the gp70 of an endogenous ecotropic murine leukemia virus (MuLV). The work described here was initiated to test directly for a causative relationship between MuLV expression and resistance to lysis by macrophages. Northern blot analysis revealed that macrophage-resistant cells contain full length retroviral RNA. A panel of mAb which distinguish among host-range classes of MuLV detected only a non-recombinant ecotropic gp70 in these cells. The ecotropic MuLV from two independently derived macrophage resistant cells were isolated by limiting dilution cloning on Mus dunii fibroblasts. These viruses were then used to infect macrophage-sensitive cell lines and the resultant MuLV-positive cells tested for sensitivity to macrophage cytolysis. The MuLV-infected lines remained highly sensitive to macrophage lysis despite their high levels of cell surface gp70 and release of infectious MuLV. Thus, although we cannot rule out the possibility that MuLV or a product thereof is necessary for development of macrophage resistance in transformed cells, expression of MuLV per se is not sufficient to create the resistant phenotype.

Cytolysis by tumor necrosis factor is preceded by a rapid and specific dissolution of microfilaments.

Tumor necrosis factor (TNF) is cytotoxic to certain transformed cells, whereas normal cells are resistant to its effects. The resistance of normal cells can often be overcome by treatment with inhibitors of transcription or translation such as actinomycin D or cycloheximide (CHI), suggesting that normal cells produce a protein(s) that protects them from TNF-induced cytolysis. In this report, we examine the mechanism of cytolysis in a 3T3-like mouse cell line, C3HA, which was sensitized to TNF by treatment with CHI. We found that an early change in TNF/CHI-treated cells was a significant loss of stress fibers in perinuclear areas of the cytoplasm. The disruption of microfilaments, which was observed within 15 min of treatment, was not seen in untreated cells or in cells treated with either TNF or CHI alone. The dissolution of microfilaments spread peripherally over time and preceded other TNF/CHI-induced effects such as cytoplasmic "boiling," decrease in cell volume, and lysis of the plasma membrane. The breakdown of stress fibers occurred without a change in microtubules or intermediate filaments. Cytochalasin E, which disrupts microfilaments, induced cytolysis of TNF-treated cells even in the absence of CHI; however, demecolcine, which depolymerizes microtubules, did not sensitize cells to TNF. We propose that the TNF-induced cytolysis of certain cell types is preceded by a selective disruption of the microfilament lattice.

Tumor necrosis factor can induce both apoptic and necrotic forms of cell lysis.

TNF is a protein toxin which is secreted by activated macrophages and monocytes. Although the cytotoxic activity of TNF has been well documented, the mechanism of TNF-induced lysis is not well understood. The goal of this investigation was to determine whether TNF caused one of the classic forms of cell death, i.e., apoptosis, which is characterized by nuclear disintegration and cytoplasmic "boiling," or necrosis, which is characterized by the formation of a "balloon-like" plasma membrane and a lack of nuclear disintegration. Therefore, to distinguish apoptosis from necrosis, we have used time-lapse video microscopy to observe the death of several TNF-sensitive target cell lines while measuring the release of Na2(51)CrO4 and [3H]TdR from cytoplasmic and nuclear compartments, respectively. As targets we selected two spontaneously sensitive cell lines, F17 and L-M, and one resistant cell line, C3HA, which was sensitized by treatment with cycloheximide or by infection with the adeno-SV40 hybrid virus Ad2+ND2. We find that the type of cell death observed depends on the cell being tested. For example, in F17 cells we found that TNF treatment induced a classical form of apoptosis. In contrast, TNF induced a necrotic form of cell death in L-M cells, similar to the lysis induced by antibody and C. Finally, we found that sensitized C3HA cells displayed a novel cytolytic phenotype which resembled apoptosis but did not include DNA fragmentation. These results emphasize the complex nature of the TNF-induced cytotoxic response.

Target-induced changes in macrophage migration may explain differences in lytic sensitivity among simian virus 40-transformed fibroblasts.

Time-lapse video microscopy has been used to study macrophage movement in the presence of SV40-transformed fibroblasts. In all, five different SV40-transformed cell lines (an uncloned line and four clones derived from it) were tested for their affects on the movement of LPS-activated macrophages (AM). Conditions for video microscope recording were designed to simulate, as best as possible, the conditions used in a 51Cr-release cytotoxicity assay. Our analysis shows that these targets had a range of effects on macrophage migration, from stimulation to complete inhibition of movement. Two of the targets we tested (SV-COL and SV-COL-E8) both highly sensitive to lysis, stimulated macrophage movement, inducing an "agitated" response. Two other targets (SV-COL-F11 and SV-COL-H5), both of intermediate sensitivity had, for the most part, a suppressive effect on macrophage movement. Finally, we found that one target, clone SV-COL-F5, which is completely resistant to lysis by AM, was able to completely inhibit macrophage movement. This inhibitory effect was accompanied by a "pathologic" change in the structure of the macrophage cytoplasm suggesting that this target escapes lysis in vitro by secreting a factor that incapacitates the effector cell. Overall, these observations suggest that target cell products that can affect the behavior of the AM may be important in determining the lytic sensitivity of transformed target cells.