Induction of expression of cell-surface homologous restriction factor upon anti-CD3 stimulation of human peripheral lymphocytes

Relative contributions of decay accelerating factor (DAF), membrane cofactor protein (MCP) and CD59 in the protection of melanocytes from homologous complement

Complement regulatory molecules, membrane cofactor protein (MCP), decay accelerating factor (DAF) and CD59, protect body cells from autologous complement. They have wide tissue distribution but nothing is known about the expression of these molecules on human melanocytes. Since melanocytes are lysed in the lesional skin of patients with a depigmentary disorder vitiligo, it is important to compare the protection offered by complement regulatory molecules to melanocytes present in normal and vitiligo epidermis, against autologous complement. From this point of view, we investigated the differential expression of MCP, DAF and CD59 on normal cultured human melanocytes and assessed their individual contribution in the protection of these cells against complement-mediated damage. Flow cytometric analysis showed that MCP and DAF but not CD59 were expressed on cultured melanocytes. When heat inactivated sera of patients with vitiligo were used as a source of anti-melanocyte antibody to sensitize melanocytes, and guinea pig serum (GpS) or normal human serum (NHS) as a source of complement, GpS was found to be more effective in causing the lysis of melanocytes than NHS. When melanocytes were sensitized with autoantibody as well as F(ab')2 fragment of either anti-MCP or anti-DAF and subsequently incubated with NHS or GpS, both antibody fragments increased the killing of melanocytes by NHS as well as by GpS. F(ab')2 fragment of anti-DAF was much more effective in causing enhancement of lysis than that of anti-MCP. Thus, cultured normal human melanocytes express functionally active MCP and DAF but not CD59. Contribution of DAF in protecting melanocytes against complement attack was much more than that of MCP.

Perforin and lymphocyte-mediated cytolysis

We have discussed in the previous sections the recent progress made toward elucidating the regulatory mechanism of perforin gene transcription and the domain structure of the perforin molecule. It appears that the expression of perforin is, at least partially, controlled at the transcription level through the interaction between killer cell-specific cis- and trans- acting factors. One of such cognate pairs, NF-P motif (an EBS-homologous motif) and NF-P2 (a killer cell-specific DNA-binding protein), has been described. The regulatory mechanism of gene transcription, however, is likely to involve multiple factors which act in a coordinated fashion to bring about the most efficient expression of perforin limited strictly to activated killer lymphocytes. Through studies using synthetic peptides and recombinant perforins, it has been suggested that the N-terminal region of the perforin molecule is an important, though not the only, domain responsible for the lytic activity. Further studies are warranted to elucidate the role(s) of other potential amphiphilic structures located in the central portion of the perforin molecule in the overall pore-forming activity. The molecular basis underlying the resistance of killer lymphocytes to perforin-mediated lysis still remains an open question. Preliminary results, however, suggest that the surface protein(s) restricted to killer cells may account for their self-protection against perforin. Based on recent studies using perforin-deficient mice, the involvement of perforin in lymphocyte-mediated cytolysis both in vivo and in vitro has been confirmed. Two functional roles, a direct (lytic) and an indirect (endocytosis enhancer; conduit), both of which may contribute critically to the cell-killing event can be attributed to perforin. The fact that lymphocytes may also employ perforin-independent killing mechanism(s), e.g. Fas-dependent pathway, is beyond the scope of this review. There is, nevertheless, no doubt that these alternative cytolytic mechanisms may also play important roles in immune effector and/or regulatory responses associated with killer lymphocytes. Obviously, we are still a long way from concluding on the functional relevance of each individual cytolytic mechanism seen in different physiopathological situations. Suffice it to say, however, that a wealth of information on lymphocyte-mediated killing has already emerged through the multidisciplinary efforts conducted in our and other laboratories that promise to further dissect this complicated event in the years to come.

Functional heterogeneity among CD4+ T-cell clones from blood and skin lesions of leprosy patients. Identification of T-cell clones distinct from Th0, Th1 and Th2

In the present study we examined the functional properties of T-cell clones reactive with Mycobacterium leprae and other mycobacterial antigens. Clones isolated from the skin lesions and blood of leprosy patients across the spectrum were exclusively CD4+CD8- and expressed the alpha beta T-cell receptor. Substantial heterogeneity in the production of cytokines, in particular interleukin-4 (IL-4), was observed, although no striking correlation with clinical status was apparent. A variety of patterns of cytokine secretion distinct from those of T-helper type-1 (Th1) Th2 or Th0, as defined in murine studies, was evident. Most noteworthy was a large number of clones from skin which secreted neither IL-2 nor IL-4, but large amounts of tumour necrosis factor (TNF) and interferon-gamma (IFN-gamma). Clones isolated from the blood of leprosy patients had a more restricted cytokine secretion profile, and appeared to resemble more closely previously described patterns, including those of high level production of IL-2 and/or IL-4. Virtually all clones, from either skin or blood, produced high levels of IFN-gamma, and thus many clones were IL-4 and IFN-gamma co-producers. The pattern of cytokine production by skin-derived T-cell clones was significantly affected by the in vitro activation status of the cells. Cells enriched in activated blasts tended to produce more IL-4 than small resting cells. In addition, the production of IFN-gamma by skin T-cell clones after < or = 10 weeks of culture was strikingly distinct from that of these clones after 5 months of culture. IL-4 and IFN-gamma co-producing clones shifted to a Th2-like pattern with much less IFN-gamma secretion, whereas non-IL-4-producing clones secreted much higher levels of IFN-gamma after prolonged culture, and became much more Th1-like. However, there was still no correlation between clinical status and pattern of cytokines produced. These results imply that a high fraction of T cells exists in leprosy lesions that is distinct from or that has not yet fully matured into Th1 or Th2 cells.

Complement membrane attack on nucleated cells: resistance, recovery and non-lethal effects

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Resistance of cytolytic lymphocytes to perforin-mediated killing. Induction of resistance correlates with increase in cytotoxicity

CTL and NK cells cultured in vitro are known to produce a cytolytic pore-forming protein (PFP, perforin) localized in their cytoplasmic granules. Using purified perforin, we showed here that both cloned CTL and primary killer cell populations, including allospecific CTL, NK/lymphokine-activated killer cells, and MHC-non-restricted CTL, were more resistant to perforin-mediated killing than other lymphocyte populations and cell types. Similar results were obtained with both murine and human cytolytic lymphocyte populations. Resistance of killer cells to perforin correlated in general with their cytolytic capability. Thus, cells that have acquired competence to kill after stimulation with Con A, IL-2, or leukocyte-conditioned medium, were also the more resistant cells. IL-2-independent CTL lines and hybridomas derived in our laboratories could be triggered to become cytotoxic and perforin resistant by short-term stimulation with various cytokines, indicating that the acquisition of resistance to perforin-mediated lysis was independent of cell proliferation. Activation of one IL-2-independent CTL line with IL-2 also resulted in enhanced production of perforin and in enhanced serine esterase activity. The acquisition of cell resistance to perforin by these IL-2-independent cell lines after activation with stimulatory reagents was independent of protein and RNA neosynthesis: emetine, cycloheximide, and actinomycin D, while effectively blocking the incorporation of [35S]methionine into cell proteins, did not affect the induced increase in perforin resistance.

Mechanisms of lymphocyte-mediated lysis

Cytotoxic T lymphocytes (CTLs) and natural killer (NK) cells use multiple mechanisms to destroy their target cells. Pore formation resulting in osmotic lysis of the target is one mechanism; the pore-forming protein (perforin) responsible for this activity has been purified. Antigenically and functionally it resembles proteins of the membrane attack complex of complement. The other known mediators of cytotoxicity appear to be closely interrelated. Tumor necrosis factor (TNF), lymphotoxin (LT), and leukalexin are the three members of this group that have been purified, although their mechanisms of action are still unknown. CTLs fragment the DNA of target cells, as do TNF, LT, and leukalexin; this may be one of the mechanisms of action of these mediators. CTLs and NK cells do not self lyse. The basis of this phenomenon is unclear, although recent advances have shed some light on the problem.

Absence of homologous restriction factor does not affect CTL-mediated cytolysis

Homologous restriction factor (HRF) is a membrane protein of erythrocytes and leukocytes that inhibits the complement (C5b-9)-mediated lysis in a species-restricting manner. HRF has also been reported to inhibit perforin-mediated cytolysis and postulated to play a role in cytotoxic T lymphocyte (CTL) self-protection. We show that paroxysmal nocturnal hemoglobinuria (PNH) erythrocytes, lacking HRF, are no more sensitive to Ca2+-dependent human CTL-mediated lysis than normal erythrocytes. Furthermore, mouse and normal human erythrocytes, as well as PNH erythrocytes, are similarly lysed by isolated murine perforin-containing granules. We conclude that HRF does not inhibit perforin-mediated lysis and therefore is not likely to play a role in CTL self-protection.

Resistance of cytolytic lymphocytes to perforin-mediated killing. Lack of correlation with complement-associated homologous species restriction

CTL and NK cells resist self-mediated killing and lysis by their own pore-forming protein (PFP; perforin). Perforin, like C, lyses RBC. Efficient C-mediated lysis of RBC occurs when both C and RBC are from different species (homologous species restriction). A protective surface protein (C8-binding protein, homologous restriction factor) has been reported to mediate both homologous species restriction in C-dependent cytolysis and protection of some target cells against perforin-induced lysis. We show here that perforin, unlike C, lyses target cells across a variety of species, including the homologous one, while the same target cell populations resist the attack by homologous C. Perforin-containing extracts of CTL and LAK/NK cells from three species (rat, mouse, and human) and purified mouse perforin were tested against RBC from 10 different species, several nucleated target cell lines, and one primary cell population (thymocytes). While resisting lysis by homologous C, most of these cell types were lysed effectively by perforin without any homologous restriction pattern. CTL and NK cells, like other nucleated targets, are resistant to lysis by homologous but not heterologous C; however, these cell types are resistant to both homologous and heterologous perforin. Together, our results suggest that the protective mechanisms associated with C- and perforin-mediated lysis are distinct.

Structure and function of human perforin

Perforin (P1) is a cytolytic protein with similarity to complement component C9. P1 has been described as a unique component of murine cytolytic T-cell and rat natural killer cell granules Previous studies indicated that human granules and P1 differed from murine granules and P1 in that they appeared to be cytolytically less active and lacked the haemolytic activity characteristic of P1. It has been suggested that P1, like C9, is under the control of the homologous restriction factor. Here we determine the primary structure of human P1, re-examine its functional properties, and address the question of homologous restriction.

Self-protection of cytotoxic lymphocytes: a soluble form of homologous restriction factor in cytoplasmic granules

A soluble form of homologous restriction factor (HRF) has been isolated from the cytoplasmic granules of human large granular lymphocytes that were cultured in the presence of recombinant interleukin 2 for 2-3 weeks. The granule-derived protein (approximately 65 kDa) is soluble in detergent-free solution and reacts with antibody produced to membrane HRF. HRF was first described as a 65-kDa membrane protein of human erythrocytes capable of inhibiting the formation of transmembrane channels by the membrane attack complex of complement. It has also been isolated from activated human lymphocytes and shown to confer upon these cells relative resistance to lysis by the membrane attack complex and by the complement component C9-related protein of human cytotoxic lymphocytes. The soluble HRF of lymphocyte granules inhibits reactive lysis of erythrocytes by the membrane attack complex of human complement. It was also found to be a potent inhibitor of (i) the cytolytic activity of the C9-related protein of human cytotoxic lymphocytes, (ii) human large granular lymphocyte cytotoxicity, and (iii) the cytotoxic activity of human CD8+ lymphocytes obtained by cell sorting from recombinant interleukin 2-activated peripheral blood mononuclear cells. It is proposed that granule-derived soluble HRF and cell surface-membrane-bound HRF are involved in the mechanism of self-protection of killer lymphocytes.

The molecular basis of target cell killing by human lymphocytes and of killer cell self-protection

The cytolytic protein (C9RP) of human cytotoxic lymphocytes was isolated from large granular lymphocytes (LGL) and anti-CD3 activated cytotoxic T cells (CTL). It is immunochemically related to the channel-forming proteins of complement. Whereas LGL constitutively contain C9RP, peripheral resting CTL do not. C9RP synthesis is induced, however, in CD8+ cells upon stimulation of the T cell antigen receptor-CD3 structure. Comparison of cellular cytotoxicity and C9RP content at various times during anti-CD3 activation of CTL yielded a coefficient of correlation, r = 0.92. Isolated C9RP (Mr approximately 70,000) readily lysed a large variety of metabolically active cells tested. Certain monoclonal antibodies to C9RP inhibited target cell killing by LGL or activated CD8+ lymphocytes. Homologous restriction factor (HRF) is a normal membrane protein of blood cells that inhibits transmembrane channel formation by the membrane attack complex of complement. It has recently been found that isolated HRF (Mr approximately 65,000), bound to sheep erythrocytes, inhibited their lysis mediated by the antibody-dependent cellular cytotoxicity reaction or by isolated C9RP. Further, stimulation of resting peripheral lymphocytes with anti-CD3 resulted in increased expression of cell surface HRF. Acquisition of HRF expression conferred upon CTL relative resistance to lysis by C9RP. A soluble form of HRF (Mr approximately 65,000) was isolated from the cytoplasmic granules of LGL, which also contain C9RP, and shown to inhibit cytotoxicity of LGL and CTL. It is conceivable that HRF is opertive in self-protection of cytotoxic lymphocytes.