Pedro M. Persechini

Perforin‐Dependent and ‐Independent Pathways of Cytotoxicity Mediated by Lymphocytes

There is little doubt at the present time that both perforin-dependent and -independent pathways are important in mediating the cytotoxicity associated with lymphocytes. The cell distribution of perforin, initially thought to include both CTL and NK cells, now must be viewed with caution because all previous biochemical studies on CTL have been conducted with cell lines propagated in long-term cultures in the presence of T cell growth factors (IL-2 and perhaps some still undefined factors). Under these conditions, CTL are known to assume a broader, NK-like specificity in target cell killing and may thus differ significantly from primary CTL generated in the body. Accordingly, perforin does not seem to be present in primary CTL activated directly through mixed lymphocyte reactions. It remains to be shown how primary CTL lyse target cells in vivo. Initial studies conducted in several laboratories have already provided some clues. It now seems that even in cultured, perforin-containing CTL, the perforin pathway is not an obligatory mechanism required for target cell killing. Other pathways, possibly involving TNF/lymphotoxin-like molecules, may play a direct role in this type of cytotoxicity. Other still unidentified factors now also need to be sought, including membrane polypeptides that may develop cytotoxicity directly upon cell contact and binding. Although from the studies reviewed here it is clear now that perforin has a more limited role in cell killing than originally proposed, it is still intriguing that it should share structural and functional homologies with complement proteins, drawing paradoxical analogies between two systems (the cellular and the humoral immune systems) which have evolved to become specialized to carry out separate immunological tasks. The cloning of the genes for perforin and for all the C proteins that comprise the MAC should reveal important information on how these genes originated and then diverged during evolution. The cellular distribution of other granule products, such as serine esterases, also must be viewed with caution. A serine esterase activity was initially thought to be CTL-specific. This information stimulated an intensive research activity in many laboratories that resulted in both the purification of a serine esterase family and the cloning of several serine esterase transcripts. It is becoming clear from recent evidence that this group of enzymes is not truly CTL-specific and therefore would not be expected to develop any function rendered absolutely necessary for cytolysis.(ABSTRACT TRUNCATED AT 400 WORDS)

The structure of the mouse lymphocyte pore-forming protein perforin

Purified murine lymphocyte pore-forming protein (PFP or perforin) was partially sequenced. Oligonucleotides synthesized on the basis of this sequence information were used to screen a murine cytotoxic T lymphocyte (CTL) cDNA library. Seven clones were obtained, two of which were sequenced, providing full-length sequence information on PFP. Murine PFP (534 a.a.) is 68% identical to human PFP. Hydropathic analysis revealed a predominantly hydrophilic protein with some hydrophobic domains, including a region (a.a. 191-251) that could contain putative membrane-spanning domains. PFP is approx. 20% identical to human C7, C8 and C9 within a region encompassing 270 a.a., confirming previous immunological cross-reactivity studies. Northern blot analysis showed that expression of PFP but not of a serine esterase transcript is enhanced in a CTL line by antigen receptor-stimulation. Southern blot analysis of mouse genomic DNA indicated that PFP is encoded as a single-copy gene with the coding region contained within 10 kilobases of genomic DNA.

The primary structure of the lymphocyte pore-forming protein perforin: partial amino acid sequencing and determination of isoelectric point.

The murine lymphocyte pore-forming protein (PFP) was purified to apparent homogeneity by successive steps of liquid chromatography. Monospecific antibodies were raised against purified PFP that detect only one protein band in murine CTL lines. 25% of the primary sequence of PFP (134 amino acids) was determined by amino terminal analysis of the purified protein and of some of its enzymatic cleavage products. These primary sequences were identical to sequences deduced by cDNA cloning. By isoelectric focusing, PFP was found to have a pI of 6.4. On the chromatofocusing column Mono P, however, PFP was found to elute at pH 4.7. This suggests a tertiary structure for monomeric PFP that is enriched in surface acidic amino acids.

Cytoplasts from cytotoxic t lymphocytes are resistant to perforin-mediated lysis

Cytotoxic T lymphocytes (CTL) contain a potent cytolytic pore-forming protein (PFP, perforin or cytolysin) localized in their cytoplasmic granules. In the presence of calcium, perforin lyses a variety of target cells (TC) non-specifically. CTL, however, are generally resistant to the lytic effect of perforin. In this work, cytoplasts from CTL and susceptible TC were made by centrifuging cells on a Ficoll density gradient in the presence of cytochalasin B. Characterization by electron microscopy and a serine esterase assay established that both CTL and TC cytoplasts were completely devoid of nuclei and CTL cytoplasts contained essentially no granules. CTL cytoplasts are just as resistant to perforin-mediated lysis as the intact CTL, and both TC and their corresponding cytoplasts are very sensitive to lysis. Furthermore, CTL cytoplasts are less effective than TC cytoplasts in inhibiting hemolysis, a property shared by the respective intact cells. These results indicate that soluble granular components do not confer resistance on CTL, and suggest that the protective agent(s) acts by impeding perforin binding to the CTL membrane.

The lymphocyte pore-forming protein perforin is associated with granules by a pH-dependent mechanism

A pore-forming protein (PFP, perforin or cytolysin) has been found in the cytoplasmic granules of cytotoxic T lymphocytes (CTL) and natural killer (NK) cells. Extraction of granules with high-salt buffers or by freezing-and-thawing results in the release of perforin, which occurs only when the buffer pH is above 7.0. While high-salt extraction and freezing-and-thawing of granules at low pH (below 7.0) do not result in perforin release, these treatments render granules susceptible to a subsequent incubation with low-salt buffers (pH 7-8) that then solubilizes perforin completely. Granules may thus have been made leaky by high-salt extraction or freezing-and-thawing that may occur regardless of the buffer pH, while dissociation of perforin from granules may be exquisitely pH-sensitive. Freezing-and-thawing intact CTL and NK cells in physiological buffers with pH in the range of 7-8 (but not below 7) also causes release of perforin activity to the cell supernatant, thus providing a simple procedure by which perforin activity can be quantitated in small cell samples. Our results suggest that during lymphocyte-mediated killing, the extracellularly released perforin may rapidly dissociate from granules as a result of pH change and, in the process, become cytolytically active.

Differential susceptibility of type III erythrocytes of paroxysmal nocturnal hemoglobinuria to lysis mediated by complement and perforin

Previous reports have suggested that a 65 kDa membrane protein, termed homologous restriction factor (HRF), in addition to protecting erythrocytes (E) against lysis by homologous complement (C), may also be involved in protecting cytolytic lymphocytes against lysis mediated by a pore-forming protein (PFP/perforin), one of their own lytic mediators. Here, we used HRF-deficient type III E of patients with paroxysmal nocturnal hemoglobinuria (PNH) to study their susceptibility to lysis mediated by homologous C and perforin, and compared it with lysis of HRF-bearing control or PNH type I E. We show that type III E of PNH patients are indeed more susceptible to lysis mediated by homologous C than control or type I E, but they are as susceptible to perforin-mediated lysis as type I E. In addition, all human E (type I or III) tested here are equally susceptible to lysis mediated by either human (homologous) or murine (heterologous) perforin. By immunoblot analysis, we confirm that type III E, in contrast to type I E, were deficient in the 65 kDa HRF. These results support the notion that homologous species restriction is seen in the C- but not in the lymphocyte perforin-system and argue against an active participation of HRF in protecting cells from perforin-mediated lysis.

THE DISTRIBUTION OF PERFORIN IN NORMAL TISSUES

We describe the production of monoclonal antibodies to murine and human forms of the lymphocyte pore-forming protein (perforin, PFP, or cytolysin), a major granule-localized cytolytic mediator of CTL and NK cells. Antibodies were raised against both murine perforin purified from a CTL line, and human perforin expressed in bacteria as a fusion protein with the Escherichia coli TrpE protein. Antibodies raised against either immunogen inhibited the hemolytic activity of murine perforin, and thus may enable us to identify the pore-forming or self-associative domain of perforin. One mAb, MP1, was used to study the distribution of perforin in murine tissues under physiological conditions. We found that perforin was expressed in the granular metrial gland (GMG) cells of the pregnant murine uterus, but not in other tissues examined. These results further support the view that perforin is induced only in activated cytolytic lymphocytes, and raise the question whether perforin-containing GMG cells represent an effector of a maternal immune response to the fetus.

Resistance to the pore forming protein of cytotoxic T cells: comparison of target cell membrane rigidity

Cytotoxic T lymphocytes (CTL) release from their granules a 70 kDa protein, called PFP, perforin or cytolysin, which inserts into the target cell plasma membrane in its monomeric form. Here it polymerizes into a macromolecular complex forming pores as large as 20 nm. Although purified PFP/perforin can effectively lyze all target cells tested. CTL are refractory to lysis. The mechanism underlying the resistance of CTL is currently unknown. This study represents a search for membrane structural properties that could confer resistance to CTL against PFP/perforin-mediated lysis. The fluorescent dye merocyanine 540 was used to measure the lipid head group packing of CTL and several target cells, and 1-[4-(trimethylamine)phenyl]-6-phenylhexa-1,3,5-triene was used to estimate the fluidity of the membrane hydrocarbon region. The resistance against PFP/perforin-mediated lysis was determined by the 51Cr release assay. A comparison of the membrane rigidity with cell resistance led to the conclusion that the membrane lipid structure cannot account for the unusually high resistance of CTL. In particular, the resistant CTL line CTLL-2 has a lipid head group packing that is looser than that of Yac-1, and the sensitive target cells Jy-25 and EL-4 have membrane acyl chains that are less fluid than those of the effector CTLL-R8.

Heterogeneity of granules of murine cytolytic T lymphocytes isolation of a homogeneous population of dense granules

A separation procedure based on Percoll gradient centrifugation is described here that allows enrichment for two main populations of granules, with average densities of 1.05 and 1.1 g/ml. The heavy-density granules, which comprise 5-20% of the total amount of membrane-lytic activity, are morphologically and biochemically more homogeneous than the light-density granules, which are contaminated with other subcellular organelles. A trypsin-like serine esterase activity, used in the past as a granule marker, was mainly found in the free cytosol and in the light-density fractions, while a small portion of this activity was associated with the heavy-density fractions. This enzyme marker is therefore not exclusively associated with granules and should not be used as the only granule marker.