The preclinical pharmacokinetic disposition of a series of perforin-inhibitors as potential immunosuppressive agents.

The cytolytic protein perforin is a key component of the immune response and is implicated in a number of human pathologies and therapy-induced conditions. A novel series of small molecule inhibitors of perforin function have been developed as potential immunosuppressive agents. The pharmacokinetics and metabolic stability of a series of 16 inhibitors of perforin was evaluated in male CD1 mice following intravenous administration. The compounds were well tolerated 6 h after dosing. After intravenous administration at 5 mg/kg, maximum plasma concentrations ranged from 532 ± 200 to 10,061 ± 12 ng/mL across the series. Plasma concentrations were greater than the concentrations required for in vitro inhibitory activity for 11 of the compounds. Following an initial rapid distribution phase, the elimination half-life values for the series ranged from 0.82 ± 0.25 to 4.38 ± 4.48 h. All compounds in the series were susceptible to oxidative biotransformation. Following incubations with microsomal preparations, a tenfold range in in vitro half-life was observed across the series. The data suggests that oxidative biotransformation was not singularly responsible for clearance of the compounds and no direct relationship between microsomal clearance and plasma clearance was observed. Structural modifications however, do provide some information as to the relative microsomal stability of the compounds, which may be useful for further drug development.

Unlocking the secrets of cytotoxic granule proteins.

Cytotoxic lymphocytes largely comprise CD8(+) cytotoxic T cells and natural killer cells and form the major defense of higher organisms against virus-infected and transformed cells. A key function of cytotoxic lymphocytes is to detect and eliminate potentially harmful cells by inducing them to undergo apoptosis. This is achieved through two principal pathways, both of which require direct but transient contact between the killer cell and its target. The first, involving ligation of TNF receptor-like molecules such as Fas/CD95 by their cognate ligands, results in mobilization of conventional, programmed cell-death pathways centered on activation of pro-apoptotic caspases. This review concentrates on the second pathway, in which the toxic contents of secretory vesicles of the cytotoxic lymphocyte are secreted toward the target cell, and some toxins penetrate into the target cell cytoplasm and nucleus. In addition to invoking a powerful stimulus to caspase activation, this "granule-exocytosis mechanism" provides a variety of additional strategies for overcoming inhibitors of the caspase cascade that may be elaborated by viruses. The key molecular players in this process are the pore-forming protein perforin and a family of granule-bound serine proteases or granzymes. The molecular functions of perforin and granzymes are under intense investigation in many laboratories including our own, and recent advances will be discussed. In addition, this review discusses the evidence pointing to the importance of perforin and granzyme function in pathophysiological situations as diverse as infection with intracellular pathogens, graft versus host disease, susceptibility to transplantable and spontaneous malignancies, lymphoid homeostasis, and the tendency to auto-immune diseases.

Initiation of apoptosis by granzyme B requires direct cleavage of bid, but not direct granzyme B-mediated caspase activation.

The essential upstream steps in granzyme B-mediated apoptosis remain undefined. Herein, we show that granzyme B triggers the mitochondrial apoptotic pathway through direct cleavage of Bid; however, cleavage of procaspases was stalled when mitochondrial disruption was blocked by Bcl-2. The sensitivity of granzyme B-resistant Bcl-2-overexpressing FDC-P1 cells was restored by coexpression of wild-type Bid, or Bid with a mutation of its caspase-8 cleavage site, and both types of Bid were cleaved. However, Bid with a mutated granzyme B cleavage site remained intact and did not restore apoptosis. Bid with a mutation preventing its interaction with Bcl-2 was cleaved but also failed to restore apoptosis. Rapid Bid cleavage by granzyme B (<2 min) was not delayed by Bcl-2 overexpression. These results clearly placed Bid cleavage upstream of mitochondrial Bcl-2. In granzyme B-treated Jurkat cells, endogenous Bid cleavage and loss of mitochondrial membrane depolarization occurred despite caspase inactivation with z-Val-Ala-Asp-fluoromethylketone or Asp-Glu-Val-Asp-fluoromethylketone. Initial partial processing of procaspase-3 and -8 was observed irrespective of Bcl-2 overexpression; however, later processing was completely abolished by Bcl-2. Overall, our results indicate that mitochondrial perturbation by Bid is necessary to achieve a lethal threshold of caspase activity and cell death due to granzyme B.

Filamin (280-kDa actin-binding protein) is a caspase substrate and is also cleaved directly by the cytotoxic T lymphocyte protease granzyme B during apoptosis.

We used yeast two-hybrid screening to identify the cytoskeletal protein filamin as a ligand for the proapoptotic protease granzyme B, produced by cytotoxic T lymphocytes. Filamin was directly cleaved by granzyme B when target cells were exposed to granzyme B and the lytic protein perforin, but it was also cleaved in a caspase-dependent manner following the ligation of Fas receptors. A similar pattern of filamin cleavage to polypeptides of approximately 110 and 95 kDa was observed in Jurkat cells killed by either mechanism. However, filamin cleavage in response to granzyme B was not inhibited by the caspase inhibitor z-Val-Ala-Asp-fluoromethylketone at concentrations that abolished DNA fragmentation. Filamin staining was redistributed from the cell membrane into the cytoplasm of Jurkat cells exposed to granzyme B and perforin and following ligation of Fas receptors, coincident with the morphological changes of apoptosis. Filamin-deficient human melanoma cells were significantly (although not completely) protected from granzyme B-mediated death compared with isogenic filamin-expressing cells, both in clonogenic survival and (51)Cr release assays, whereas death from multiple other stimuli was not affected by filamin deficiency. Thus, filamin is a functionally important substrate for granzyme B, as its cleavage may account at least partly for caspase-independent cell death mediated by the granzyme.

Cytosolic delivery of granzyme B by bacterial toxins: evidence that endosomal disruption, in addition to transmembrane pore formation, is an important function of perforin.

Granule-mediated cell killing by cytotoxic lymphocytes requires the combined actions of a membranolytic protein, perforin, and granule-associated granzymes, but the mechanism by which they jointly kill cells is poorly understood. We have tested a series of membrane-disruptive agents including bacterial pore-forming toxins and hemolytic complement for their ability to replace perforin in facilitating granzyme B-mediated cell death. As with perforin, low concentrations of streptolysin O and pneumolysin (causing <10% (51)Cr release) permitted granzyme B-dependent apoptosis of Jurkat and Yac-1 cells, but staphylococcal alpha-toxin and complement were ineffective, regardless of concentration. The ensuing nuclear apoptotic damage was caspase dependent and included cleavage of poly(ADP-ribose) polymerase, suggesting a mode of action similar to that of perforin. The plasma membrane lesions formed at low dose by perforin, pneumolysin, and streptolysin did not permit diffusion of fluorescein-labeled proteins as small as 8 kDa into the cell, indicating that large membrane defects are not necessary for granzymes (32 to 65 kDa) to enter the cytosol and induce apoptosis. The endosomolytic toxin, listeriolysin O, also effected granzyme B-mediated cell death at concentrations which produced no appreciable cell membrane damage. Cells pretreated with inhibitors of endosomal trafficking such as brefeldin A took up granzyme B normally but demonstrated seriously impaired nuclear targeting of granzyme B when perforin was also added, indicating that an important role of perforin is to disrupt vesicular protein trafficking. Surprisingly, cells exposed to granzyme B with perforin concentrations that produced nearly maximal (51)Cr release (1,600 U/ml) also underwent apoptosis despite excluding a 8-kDa fluorescein-labeled protein marker. Only at concentrations of >4,000 U/ml were perforin pores demonstrably large enough to account for transmembrane diffusion of granzyme B. We conclude that pore formation may allow granzyme B direct cytosolic access only when perforin is delivered at very high concentrations, while perforin's ability to disrupt endosomal trafficking may be crucial when it is present at lower concentrations or in killing cells that efficiently repair perforin pores.

Anti-viral strategies of cytotoxic T lymphocytes are manifested through a variety of granule-bound pathways of apoptosis induction.

Cytotoxic T cells and natural killer cells together constitute a major defence against virus infection, through their ability to induce apoptotic death in infected cells. These cytolytic lymphocytes kill their targets through two principal mechanisms, and one of these, granule exocytosis, is essential for an effective in vivo immune response against many viruses. In recent years, the authors and other investigators have identified several distinct mechanisms that can induce death in a targeted cell. In the present article, it is postulated that the reason for this redundancy of lethal mechanisms is to deal with the array of anti-apoptotic molecules elaborated by viruses to extend the life of infected cells. The fate of such a cell therefore reflects the balance of pro-apoptotic (immune) and anti-apoptotic (viral) strategies that have developed over eons of evolutionary time.

Selective regulation of cytokine induction by adenoviral gene transfer of IkappaBalpha into human macrophages: lipopolysaccharide-induced, but not zymosan-induced, proinflammatory cytokines are inhibited, but IL-10 is nuclear factor-kappaB independent.

Macrophages are the major cytokine producers in chronic inflammatory diseases, but the biochemical pathways regulating cytokine production are poorly understood. This is because genetic tools to dissect signaling pathways cannot be used in macrophages because of difficulties in transfection. We have developed an adenoviral technique to achieve high efficiency gene delivery into macrophages and recently showed that spontaneous TNF-alpha production in rheumatoid arthritis joint cells, chiefly from macrophages, is 75% blocked by adenoviral transfer of IkappaBalpha. In this report we use the same adenovirus to investigate whether the production of a number of proinflammatory cytokines (e.g., TNF-alpha, IL-1beta, IL-6, and IL-8) from human macrophages depends on NF-kappaB. While the cytokine response to certain inducers, such as LPS, PMA, and UV light, is blocked by overexpression of IkappaBalpha, the response to zymosan is not. In contrast, anti-inflammatory mediators (IL-10 and IL-1 receptor antagonist) induced by LPS are only marginally inhibited by IkappaBalpha excess. These studies demonstrate several new points about macrophage cytokine production. First, there is heterogeneity of mechanisms regulating both the proinflammatory and anti-inflammatory cytokines within populations of a single cell type. In addition, the results confirm the utility of the adenoviral technique for functional analysis of cytokine induction. The results also confirm that there are autocrine and paracrine interactions regulating cytokine synthesis within a single cell type. The selectivity of NF-kappaB blockade for proinflammatory but not anti-inflammatory mediators indicates that in macrophages, NF-kappaB may be a good target for the treatment of chronic inflammatory diseases.

Efficient nuclear targeting of granzyme B and the nuclear consequences of apoptosis induced by granzyme B and perforin are caspase-dependent, but cell death is caspase-independent.

The secretory lysosomes of cytolytic lymphocytes house the principal apoptotic molecules for eliminating virus-infected cells: a membranolytic agent, perforin, and the serine protease, granzyme B. Perforin allows granzyme B access to cytosolic and nuclear substrates that, when cleaved, result in the characteristic apoptotic phenotype. Key among these substrates is a family of cytoplasmic caspases that mediate cell suicide. We have examined the caspase dependence of several nuclear and cytoplasmic parameters of apoptosis induced by purified perforin and granzyme B. Cell membrane leakage in response to perforin and granzyme B was independent of caspase activation; however, nuclear events such as DNA fragmentation and nuclear condensation and disintegration were abolished by the broad-acting caspase inhibitor, z-VAD-fmk. Despite being spared from nuclear damage, z-VAD-fmk-treated cells exposed to both cytotoxins uniformly died when they were re-cultured, while cells exposed to perforin or granzyme alone survived and proliferated as readily as untreated cells. Pretreatment of cells with z-VAD-fmk also resulted in reduced granzyme B nuclear uptake following addition of perforin; however, its uptake into the cytoplasm in the absence of perforin was unaffected. We conclude that cell death in response to perforin and granzyme B does not require caspase activation and still proceeds efficiently through non-nuclear pathways when nuclear substrate cleavage is inhibited.

Modelling quantitative structure-activity relationships between animal behaviour and environmental signal molecules.

Quantitative structure-activity relationships (QSARs) between the physicochemical properties of environmental signal molecules and animal behaviour have been determined. Past work has shown that oyster and barnacle larval settlement and mud crab abdominal pumping (for larval dispersal) are stimulated by small peptide cues. In all the peptides examined that were active at ecologically relevant concentrations, arginine or lysine was found at the carboxy terminus, but the amino acids found at preceding positions were highly variable. We used the multivariate partial least squares algorithm to relate composite properties for the hydrophilicity, size and charge of each amino acid and the sequence position to oyster, barnacle and crab behaviour patterns. From the information in these QSAR models, the apparent variability in amino acid sequences eliciting behavioural responses was explained in each case, and more potent peptide analogues are hypothesized on the basis of untested amino acid sequences. Remarkably, these peptide signals are all structurally related to the carboxy-terminal sequence of mammalian C5a anaphylatoxin, a potent white blood cell chemoattractant. Even more striking is the fact that these different animal species should rely on apparently similar environmental signal molecules when residing within a common habitat (southeastern US estuaries). Through the physicochemical properties of amino acids, the current QSAR models clearly differentiate between the optimal sequences for eliciting oyster, barnacle and mud crab behaviour. Thus, QSARs provide a novel and powerful method not only for relating the physicochemical properties of molecules to animal behaviour but also for differentiating responses to chemicals by individuals of different species.

Reduction of serum matrix metalloproteinase 1 and matrix metalloproteinase 3 in rheumatoid arthritis patients following anti-tumour necrosis factor-alpha (cA2) therapy.

Matrix metalloproteinase (MMP)-1 and MMP-3 levels were measured in serum samples from rheumatoid arthritis (RA) patients undergoing a double-blinded placebo-controlled trial with the chimaeric anti-tumour necrosis factor (TNF)-alpha antibody cA2. Both MMP-1 (P < 0.015), but to a larger extent MMP-3 (P < 0.001) levels were elevated in all RA patients prior to the commencement of the trial compared with normal control sera. Following cA2 therapy, MMP-1 and MMP-3 levels were assessed in the placebo, and 1 and 10 mg/kg cA2-treated groups at 7, 14, 21 and 28 days. In both the 1 and the 10 mg/kg cA2-treated groups, a significant decrease in serum MMP-3 levels at all time points was observed, reducing maximally to 41% of pre-infusion values at day 7. MMP-1 levels were also reduced, but less dramatically than MMP-3, to 85% of pre-infusion values after 14 days in the 10 mg/kg cA2 treated group. In a separate non-placebo-controlled study, we also evaluated the tissue inhibitor of metalloproteinase (TIMP)-1 levels in plasma following cA2 infusion. Pre-infusion TIMP-1 levels were above the normal control range, but were significantly reduced (P < 0.035) 14 days after infusion to 72% of pre-infusion values. This study confirms previous reports that MMP-3 levels are elevated and correlate with measures of inflammation in RA, and furthermore demonstrate that serum MMP-3 and MMP-1 levels are downmodulated following anti-TNF-alpha antibody therapy. Whilst serum MMP-3 levels correlated with C-reactive protein (CRP) both prior to and following anti-TNF-alpha antibody therapy, it remains to be demonstrated that serum MMP-3 and/or MMP-1 levels reflect the cartilage and bone resorptive processes which are evident in this disease.

Localization of granzyme B in the nucleus. A putative role in the mechanism of cytotoxic lymphocyte-mediated apoptosis.

One mechanism used by cytotoxic T cells and natural killer cells to kill target cells involves synergy between the pore-forming protein, perforin, and a serine protease termed granzyme B, both constituents of the cytoplasmic granules of cytolytic lymphocytes. Exposing susceptible cells to perforin and granzyme B results in apoptosis, the morphological consequences of which are most clearly seen in the nucleus. It is conventionally accepted that perforin acts by perforating the target cell membrane; however, the site and mode of action of granzyme B are unknown. We have addressed this issue using Western blotting, proteolytic assays, and confocal laser scanning microscopy to demonstrate that purified human granzyme B can be taken up in large amounts and bound within nuclei. By contrast, perforin and nongranzyme serine proteases did not undergo nuclear uptake. Both unglycosylated human granzyme B (26 kDa) and that bearing high mannose glycosylation (32 kDa) were internalized and bound within nuclei, but forms greater than 32 kDa with complex carbohydrate addition were excluded. The uptake of granzymes was not dependent on net charge, as nuclei absorbed similar quantities of granzyme B at neutral pH and through a range of basic pHs but did not take up other very basic serine proteases such as the mouse mast cell protease 5. Confocal laser scanning microscopy indicated nuclear and nucleolar accumulation of fluoresceinated granzyme B by isolated nuclei. Measurement of the kinetics of nuclear import using an in vitro nuclear transport assay indicated maximal levels of nuclear accumulation of granzyme about 2.5-fold above those in the cytoplasm and nucleolar accumulation a further 3-4-fold higher. Nuclear and nucleolar accumulation were exceedingly rapid, reaching half-maximal levels within 3.3 and 7.5 min, respectively, implying that nuclear accumulation probably occurs prior to transport to the nucleolus. Our observations may provide a mechanism explaining how aspartate-specific cell death proteases access the nuclear substrate poly(ADP-ribose) polymerase, the cleavage of which is an early event in apoptosis.

The peptide loop consisting of amino acids 139-157 of human granzyme B (fragmentin 2) contains an immunodominant epitope recognized by the mouse.

Granzyme B (also termed fragmentin 2) is a prototypic member of a subfamily of serine proteases expressed in the cytoplasmic granules of cytotoxic T lymphocytes and natural killer cells, and has been implicated in the destruction of targeted cells. Studies on the role of all granzymes in the cytolytic response would be greatly facilitated by the availability of specific anti-granzyme antisera. Three synthetic peptides corresponding to amino acid residues 1-17, 92-109 and 139-157 of human granzyme B were predicted to be immunogenic in the mouse, based on their hydrophilicity, accessibility to solvent, polymorphism with respect to mouse granzyme B and by comparison with X-ray crystallographic models of the rat mast cell protease II. Each peptide was conjugated to keyhole limpet hemocyanin and used to produce monoclonal antibodies in BALB/c mice. The monoclonal antibodies produced generally exhibited strong and specific reactivity with the respective immunizing peptide. However, only those antibodies detecting the peptide corresponding to residues 139-157 were able to detect native or denatured granzyme B, in direct binding studies with purified granzyme B or by immunoblotting. As an alternative approach for antiserum production, mice were immunized with whole, proteolytically active granzyme B isolated by immuno-affinity purification from NK tumour cell lysates, using one of the monoclonal antibodies generated. Despite the overall structural similarities between the various human granzymes, these mouse antisera surprisingly reacted only with granzyme B. Indeed, the reactivity of these polyclonal antisera was specifically abrogated by preincubation with the peptide corresponding to amino acid residues 139-157. This peptide stretch therefore represents an immunodominant portion of the granzyme B molecule in the mouse. Given the analogous structures of serine protease families expressed in leukocytes, these findings have implications for the production of monospecific antisera to granzymes and related proteases.

Binding studies of cationic thymidyl deoxyribonucleic guanidine to RNA homopolynucleotides.

Deoxyribonucleic guanidine is a potential antisense agent that is generated via the replacement of the negative phosphodiester linkages of DNA [--O--(PO2-)--O--] with positively-charged guanidinium (g) linkages [--NH--C(==NH2+)--NH--]. A pentameric thymidyl deoxyribonucleic guanidine molecule [d(Tg)4T-azido] has been shown to base pair specifically to poly(rA) with an unprecedented affinity. Both double and triple strands consisting of one and two equivalents of d(Tg)4T-azido paired with one equivalent of poly(rA) are indicated by thermal denaturation experiments. At an ionic strength of 0.22, the five bases of d(Tg)4T-azido are estimated to dissociate from a double helix with poly(rA) at > 100 degrees C! The effect of ionic strength on thermal denaturation is very pronounced, with stability greatest at low ionic strengths. The method of continuous variation indicates that there is an equilibrium complex with a molar ratio of d(Tg) to r(Ap) or d(Ap) of 2:1. Based on this evidence, models of the structures of d(Tg)9T-azido bound to r(Ap)9A are proposed.

Synthesis of a thymidyl pentamer of deoxyribonucleic guanidine and binding studies with DNA homopolynucleotides.

Replacement of the phosphodiester linkages of the polyanion DNA with guanidine linkers provides the polycation deoxynucleic guanidine (DNG). The synthesis of pentameric thymidyl DNA is provided. This polycationic DNG species binds with unprecedented affinity and with base-pair specificity to negatively charged poly(dA) to provide both double and triple helices. The dramatic stability of these hybrid structures is shown by their denaturation temperatures (Tm). For example, the double helix of the pentameric thymidyl DNG and poly(dA) does not dissociate in boiling water (ionic strength = 0.12), whereas the Tm for pentameric thymidyl DNA associated with poly(dA) is approximately 13 degrees C (ionic strength = 0.12). The effect of ionic strength on Tm for DNG complexes with DNA shows an opposite correlation compared with double-stranded DNA and is much more dramatic than for double-stranded DNA.

NMR structure of d(CGCA3T3GCG)2:tren-microgonotropen-b:Zn(II) complex and solution studies of metal ion complexes of tren-microgonotropen-b interacting with DNA.

The solution structure of a 1:1 complex of zinc tren-microgonotropen-b [6b:Zn(II)] with d(CGCAAATTTGCG)2 has been determined by 2D nuclear Overhauser effect 1H NMR spectroscopy and restrained molecular modeling. The exchangeable and nonexchangeable proton resonances of d(CGCA3T3GCG)2:6b:Zn(II) indicate that the Zn(II) is interacting in the A+T-rich region of the dsDNA and the tren region of 6b, while 31P NMR shows interaction of the Zn(II) with the phosphate backbone. Proton chemical shift differences between d(CGCA3T3GCG)2:6b:Zn(II) and d(CGCA3T3GCG)2:6b are in agreement with the polyamino substituent of 6b [-(CH2)4N(CH2CH2)N-(CH2CH2NH2)2] forming a four-coordinated Zn(II) complex similar to that found in the X-ray structure of 'tren-chloride':Zn(II). The P9 and P10 phosphate oxygens that are held by hydrogen bonding to the tren substituent of 6b in the DNA:6b complex become ligands to the tren-complexed Zn(II) in DNA:6b:Zn(II). To do so there is a 2 A decrease in the adjacent phosphate-to-phosphate distance at the Zn(II) binding site. This motion brings about an increased bend of 14.6 degrees in the helical axis of d(CGCA3T3GCG)2:6b:Zn(II) compared to that found in d(CGCA3T3GCG)2:6b. Single stranded cleavage of linear DNA fragments was not observed in the presence of 6b and Fe(II), Co(II), Ni(II), Cu(II), Zn(II), La(III) or Ce(III); this is likely due to the metal ion being sequestered as in the structure of d(CGCA3T3GCG)2:6b:Zn(II) complex. Supercoiled DNA was susceptible to cleavage by 6b:Cu(II) in the presence of O2 and a reducing agent.

A novel minor groove binding reagent designed to serve as a "truck" to carry DNA modifying moieties into the major groove.

A site selective DNA minor groove binding tripyrrole peptide has been synthesized as a "truck" to place chemical functionalities into the major groove which are capable of physically modifying DNA, acting as catalysts to hydrolyze DNA, or effectively protecting DNA from various DNA modifying enzymes. The equilibrium dissociation constants for the binding of this peptide to an A3T3 dsDNA binding site have been determined to be nanomolar, and they are compared to the constants for other minor groove binding agents.

Distinct granzyme expression in human CD3- CD56+ large granular- and CD3- CD56+ small high density-lymphocytes displaying non-MHC-restricted cytolytic activity.

Cultured natural killer (NK) cells derived from CD3- CD56+ high-density small lymphocytes (HDLs) exhibit similar morphology and high levels of non-major histocompatibility complex-restricted (NK) cytotoxicity equivalent to those of cultured NK cells from CD3- CD56+ low-density large granular lymphocytes (LGLs). To examine the similarities and differences between NK cells from HDLs and NK cells from LGLs, we investigated the expression of three distinct members of the granule serine protease (granzyme) family within cultured CD3- CD56+ LGLs and HDLs. CD3- subpopulations of nonadherent peripheral blood mononuclear cells, LGLs (density < 1.063 g/ml), and HDLs (density > 1.063 g/ml) were stimulated to proliferate in culture. The cultured cells from each population were entirely CD3- CD56+ and were indistinguishable in terms of their increased granularity and size once activated. All cultured CD3- CD56+ LGLs and HDLs displayed cytolytic activity against K562 and immunoglobulin-coated P815. Western analysis detected perforin in both cultured LGL and HDL populations. Cultured HDLs and LGLs both expressed BLT-esterase activity and human granzyme A mRNA. Granzyme B mRNA and protein and Asp-ase activity were detected in unstimulated and cultured LGLs and cultured HDLs. By contrast, unstimulated HDLs did not express significant levels of granzyme B. High levels of Hu-Met-1 granzyme mRNA and Met-ase activity were detected only in cultured LGLs. Thus, despite the development of large granular morphology during proliferation, interleukin-2 cultured CD3- CD56+ HDLs display a different pattern of granzyme expression from CD3- CD56+ LGLs. These data also further suggest an unusually restricted expression of the Hu-Met-1 granzyme in LGLs.

Granule serine proteases are normal nuclear constituents of natural killer cells.

One mechanism by which cytotoxic T lymphocytes and natural killer cells inflict target cell death depends upon secreting the contents of their specialized cytoplasmic granules, containing a pore-forming protein, perforin, and a family of homologous serine proteases ("granzymes") with various enzyme activities. We used a granzyme B-specific mouse anti-human monoclonal antibody 2C5 and Western blotting to demonstrate that nuclear extracts of human interleukin-2-stimulated peripheral blood mononuclear cells, the human NK leukemia cell line YT, and the rat NK leukemia cell line RNK-16 contain abundant granzyme B. In interleukin-2-activated peripheral blood mononuclear cells, more than 50% of the total cellular granzyme B was present in the nuclear lysate. Nuclear granzyme B had an apparent molecular mass of approximately 32 kDa in human cells and approximately 30 kDa in RNK-16 and was eluted from immobilized heparin at the same NaCl concentration as granzyme B from cytoplasmic granules. Granzyme B that was affinity-purified with 2C5 from the nuclei of YT or human LAK cells was capable of efficiently cleaving synthetic peptide thiobenzyl ester substrates with the same specificity (peptide cleavage after aspartic acid) as granule-localized granzyme B. By contrast perforin, which colocalizes with granzymes in cytotoxic granules, was not detectable in nuclear lysates. Granzyme B was also demonstrated to be present in the nucleus and cytoplasmic granules of YT by immunohistochemical staining with monospecific anti-granzyme B antisera. Other protease activities (tryptase and peptide cleavage after methionine) were also readily detectable in nuclear and cytoplasmic lysates of YT, RNK-16, and LAK cells, as determined by the cleavage of the synthetic substrates N alpha-benzyloxycarbonyl-L-lysine thiobenzyl ester (BLT) and Boc-Ala-Ala-Met-S-benzyl, except that BLT-esterase activity was absent from the nucleus of YT. The localization of serine proteases in the nucleus was restricted to lymphocytes with cytotoxic capacity, as non-cytotoxic cell lines expressed high levels of peptide cleavage after methionine and tryptase activities in their cytoplasm, but possessed no nuclear serine protease activity. Furthermore, non-cytotoxic monkey kidney COS-7 cells transfected with an SV40-driven expression plasmid incorporating full-length human granzyme B cDNA contained abundant cytoplasmic granzyme B, but demonstrated minimal nuclear granzyme B accumulation. We conclude that serine proteases of NK cells are not restricted to cytolytic granules and, further, that their capacity to access the nucleus may have implications for the role of these enzymes in eliciting target cell death.