Proteases and lymphocyte cytotoxic killing mechanisms.

A subfamily of serine proteases is uniquely expressed by cytotoxic natural killer lymphocytes and T cells. Protease cleavage of different natural substrates is now implicated in the cytotoxic mechanisms of target cell membrane pore formation, DNA fragmentation and cytostasis.

Sulfonyl fluoride serine protease inhibitors inactivate RNK-16 lymphocyte granule proteases and reduce lysis by granule extracts and perforin.

Cytolytic granules purified from natural killer lymphocytes (NK) contain a pore-forming protein (perforin) and a number of serine proteases. When these proteases are inhibited by serine protease-specific isocoumarin reagents the serine proteases are inactivated and the cytolytic activity of the granules is decreased. Paradoxically, it has been found that the general serine protease inhibitor phenylmethylsulfonyl fluoride (PMSF) frequently cannot block killing even though it inhibits many of the serine proteases. At the same time it has been reported that "purified" perforin alone can lyze cells. To address these inconsistencies we first compared the ability of PMSF and four new sulfonyl fluoride serine protease inhibitors to inhibit proteases and cell lysis. We determined the effects on lysis and the second order inhibition rate constants for five granule protease activities: ly-tryptase, ly-chymase, Met-ase (methionine cleaving), Ser-ase (serine cleaving) and Asp-ase (aspartic acid cleaving). One compound, 2-(Z-NH(CH2)2CONH)C6SO2F, was a potent inhibitor of Met-ase activity (k(obsd)/[I] = 162 M-1 s-1), ly-chymase activity (k(obsd)/[I] = 147 M-1 s-1), and granule-mediated as well as perforin-mediated lysis. PMSF was a poor inhibitor of granule proteases (k(obsd)/[I]'s less than 7 M-1 s-1 for four activities and no inhibition of Ser-ase); the lack of reactivity is consistent with the failure of PMSF to block granule lytic activity. We also prepared enriched perforin by anion exchange chromatography and showed that a ly-chymase and a Met-ase associated with perforin. By inhibiting these proteases we also inhibited lytic activity.

Characterization, application and potential uses of biotin-tagged inhibitors for lymphocyte serine proteases (granzymes).

Cytotoxic lymphocytes and natural killer cells are able to kill their target cells in minutes. The death of the target cell occurs after the release of cytoplasmic granules from the effector cell. These granules contain the pore-forming protein perforin and serine proteases (granzymes). To date 10 genes encoding lymphocyte granzymes have been discovered; of these only four have been purified and characterized for their substrate specificity. Several are predicted to have a common chymase, like specificity which is found in the granule extracts. Others may need to be enriched as active enzymes before they can be evaluated for substrate hydrolysis. Due to the limitations of detection by substrate hydrolysis, a more sensitive method for the detection of dilute granules was needed. We report the differing reactivities of seven biotin (Bi)-tagged isocoumarin (IC) inhibitors for Asp-ase, chymase, tryptase and Met-ase granzymes. The inhibitors contained different substituents at their no. 3 position: methoxy (OMe), ethoxy (OEt), propoxy (OPr) or 2-phenylethoxy (OEtPh) groups. The OMe group conferred general reactivity, whereas the OEtPh group conferred selective reactivity with chymase granzymes. The inhibitors that contained the longest aminocaproyl (Aca) spacers between the biotin-tag and the isocoumarin ring mediated the most stable granzyme inactivation. These inhibitors were the most effective at blocking lysis of red blood cells by the granule extracts. The inhibitors were used in protein blotting experiments where the biotin was detected with an avidin-enzyme complex. Over 10 granzymes were labelled by the inhibitor Bi-Aca-Aca-IC-OMe. The inhibitors detected granzymes when they were not readily detected by substrate hydrolysis.

The -180 site of the IL-2 promoter is the target of CREB/CREM binding in T cell anergy.

Anergic T cells display a marked decrease in their ability to produce IL-2 even in the presence of optimal TCR and costimulatory signals. Using IL-2 enhancer/promoter-driven reporter constructs, we have previously identified a region that appears to be a target for cis transcriptional repression in anergy. This region of the promoter, which shares partial homology with a consensus AP-1-binding sequence, is located about -180 bp from the transcriptional start site. In the present study, we demonstrate that cAMP response element-binding protein/cAMP response element modulator (CREB/CREM), activating transcription factor-2/c-Jun, and Jun-Jun/Oct complexes bind to this site. However, the induction of anergy by prolonged stimulation through the TCR led to an increase in binding of only the CREB/CREM complex. Furthermore, the level of binding of this complex appeared to be up-regulated in both resting and restimulated anergic T cells. Finally, an IL-2 promoter-driven reporter construct that contained a mutation that specifically reduced the binding of the CREB/CREM complex displayed a decreased ability to be affected by anergy, while a construct that contained a mutation that decreased the binding of the Jun-Jun/Oct complex was still susceptible to anergy. These findings suggest that the -180 region of the IL-2 promoter is the target of a CREB/CREM transcriptional inhibitor that contributes to the repression of IL-2 production in T cell anergy.

P-4 and RNKP-7, new granzyme-like serine proteases expressed in activated rat lymphocytes.

Serine proteases (granzymes) in killer lymphocytes are required for lymphocyte cytotoxic granules to lyse target cells. Herein we report the development of a 3-step PCR cloning technique to amplify novel granzyme genes and two new rat granzymes are described. Degenerate oligonucleotide primers were designed based on sequence motifs selectively expressed in granzymes. These motifs flank "delta" regions that are unique for each granzyme. Total RNA of RNK-16 cells or activated splenocytes was amplified by reverse transcriptase-PCR to obtain cDNA fragments of several new granzymes. Gene-specific primers based on these delta regions were then used for 3'-RACE to obtain clones with the 3' gene ends. Reverse (antisense) delta-based or active site serine primers were used with a granzyme 5'-UTR primer to obtain clones extending to the 5' ends. Using this technique, two new cDNAs, RNKP-4 and RNKP-7, which encode granzymes of 248 and 241 amino acids, respectively, were cloned from activated lymphocytes. RNKP-4 is likely the rat equivalent of mouse granzyme C. RNKP-7 is most closely related to granzymes F and G. Modeling of the predicted proteins suggests large/polar P1 (Gln/Asn) specificity for RNKP-4 and large/hydrophobic P1 (e.g., Phe) specificity for RNKP-7. These specific protease activities were found in cytotoxic RNK-16 lymphocyte granules indicating that the two new genes may be translated and stored as active granzymes.