Cytotoxic T lymphocyte-induced killing in the absence of granzymes A and B is unique and distinct from both apoptosis and perforin-dependent lysis

doi:10.1083/jcb.200510072

Published 10 April 2006. doi:10.1083/jcb.200510072
The Rockefeller University Press, 0021-9525 $8.00
JCB, Volume 173, Number 1, 133-144

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Cytotoxic T lymphocyte–induced killing in the absence of granzymes A and B is unique and distinct from both apoptosis and perforin-dependent lysis

Nigel J. Waterhouse¹^,2, Vivien R. Sutton¹, Karin A Sedelies¹, Annette Ciccone¹, Misty Jenkins³, Stephen J. Turner³, Phillip I. Bird⁴, and Joseph A. Trapani¹^,2^,3

¹ Cancer Cell Death Laboratory, Cancer Immunology Program, Peter MacCallum Cancer Centre, Melbourne, Victoria 8006, Australia
² Department of Pathology, Faculty of Medicine, and ³ Department of Microbiology and Immunology, University of Melbourne, Parkville, Melbourne, Victoria 3010, Australia
⁴ Department of Biochemistry and Molecular Biology, Monash University, Clayton 3600, Australia

Correspondence to Nigel J. Waterhouse: nigel.waterhouse{at}petermac.org

Top
Abstract
Introduction
Results
Discussion
Materials and methods
References

Cytotoxic T lymphocyte (CTL)–induced death triggered bythe granule exocytosis pathway involves the perforin-dependentdelivery of granzymes to the target cell. Gene targeting hasshown that perforin is essential for this process; however,CTL deficient in the key granzymes A and B maintain the abilityto kill their targets by granule exocytosis. It is not clearhow granzyme AB^–/– CTLs kill their targets, althoughit has been proposed that this occurs through perforin-inducedlysis. We found that purified granzyme B or CTLs from wild-typemice induced classic apoptotic cell death. Perforin-inducedlysis was far more rapid and involved the formation of largeplasma membrane protrusions. Cell death induced by granzymeAB^–/– CTLs shared similar kinetics and morphologicalcharacteristics to apoptosis but followed a distinct seriesof molecular events. Therefore, CTLs from granzyme AB^–/–mice induce target cell death by a unique mechanism that isdistinct from both perforin lysis and apoptosis.

Abbreviations used in this paper: CTL, cytotoxic T lymphocyte;PI, propidium iodide; PS, phosphatidylserine.

Introduction

Top
Abstract
Introduction
Results
Discussion
Materials and methods
References

Cytotoxic T lymphocytes (CTLs) form a major part of the body'sdefense against viral infection and cancer by seeking out andkilling infected or tumorigenic cells. CTLs kill their targetseither by ligation of death receptors on the target cell orby granule exocytosis (for review see Waterhouse et al., 2004).During granule-induced cell death, perforin and granule-specificserine proteases (granzymes) are delivered to the target cell,where they induce cell death by pathways that have yet to becompletely defined (Trapani and Smyth, 2002; Waterhouse and Trapani, 2002).Perforin is a key molecule in this process, as CTLs from perforin^–/–mice are inefficient in killing target cells in vitro, and perforin^–/–mice have a decreased ability to clear virus and diminishedtumor surveillance manifested as increased susceptibility tospontaneous B cell lymphoma (Kagi et al., 1994; van den Broek et al., 1996;Lin et al., 1998; Smyth et al., 2000; Street et al., 2002).The primary role attributed to perforin is to ensure the correcttrafficking of granzymes into the target cell (Peters et al., 1991;Browne et al., 1999); however, perforin has also been shownto induce direct lysis of the target cell (Ortaldo et al., 1992;Liu et al., 1995; Rochel and Cowan, 1997; Fraser et al., 2000;Wei et al., 2000; San Mateo et al., 2002).

Granzyme A has trypsinlike proteolytic specificity that inducescell death by cleaving a variety of substrates, including lamins,DNase within the SET complex, and PHAPII (for review see Lieberman and Fan, 2003).Granzyme B induces apoptotic cell death by cleaving the proapoptoticBcl-2 family member Bid (Sutton et al., 2000; Pinkoski et al., 2001;Waterhouse et al., 2005) and the regulatory prodomain of caspase-3(Martin et al., 1996; Sutton et al., 2003). Although somewhatless efficient than CTLs isolated from wild-type mice, CTLsfrom mice deficient in granzymes A and B (granzyme AB^–/–)maintain their ability to kill many target cells by granuleexocytosis (Simon et al., 1997; Mullbacher et al., 1999; Davis et al., 2001;Smyth et al., 2003), and, in contrast to perforin^–/–mice, granzyme AB^–/– mice develop normally, do notdevelop spontaneous malignancy, and clear many viruses normally.Granzymes C, K, and M have also been shown to induce cell deathwhen delivered by perforin in vitro (MacDonald et al., 1999;Johnson et al., 2003; Kelly et al., 2004). Therefore, deathinduced by CTLs from granzyme AB^–/– mice may becaused by perforin-mediated delivery of other death-inducinggranzymes. CTLs of mice deficient in granzyme B have been reportedto have reduced expression of granzyme C as a result of inadvertentsilencing of its gene (Pham et al., 1996), and granzyme M ispreferentially expressed by NK cells (Krenacs et al., 2003).Consistent with these observations, it has understandably beenproposed that cell death induced by granzyme AB^–/–CTLs occurs through direct perforin lysis (Simon et al., 1997).

The question of how CTLs kill their target cells in the absenceof granzymes A and B is likely to be physiologically importantin light of recent findings that individual activated lymphocyteswithin a population may express different combinations of perforinand granzymes or even no granzymes at all (Kelso et al., 2002).Indeed, in this study, up to 10% of perforin-positive lymphocytesdid not express either granzyme A or B at day 3 after IL-2 activation.In addition, it has been proposed that the mechanism of targetcell death (apoptosis or lysis) can subsequently influence thequality and quantity of the inflammatory response by modulatingantigen processing and presentation (for review see Pinkoski et al., 2006).

The mechanism of death induced by granzyme AB^–/–CTLs has been studied at a population level (Pardo et al., 2002,2004); however, using these assays, it has not been possibleto distinguish apoptosis from necrosis, lysis, or any alternatedeath mechanisms. Analysis of morphology remains one of themost decisive ways by which to distinguish the various formsof cell death. Time-lapse microscopy has previously been usedto investigate the subcellular organization of polarized CTLs(Ludford-Menting et al., 2005) and to measure the kinetics ofcell death induced by cytotoxic drugs (Goldstein et al., 2000a,b).Therefore, we have used time-lapse microscopy to study in realtime the morphological and molecular parameters of single cellsundergoing granule-induced death after attack by alloreactiveCTLs. We found that wild-type CTLs induced apoptosis, but theabsence of granzyme A and B resulted in a modified form of celldeath that was distinct from both apoptosis or perforin-mediatedlysis. These data show that death induced by CTLs from granzymeAB^–/– mice cannot simply be attributed to perforinlysis; rather, death is likely to be initiated by other granulecomponents. Furthermore, the unexpected resistance of the granzymeAB^–/– animals to a variety of viral pathogens cannotsimply be attributed to perforin.

Results

Top
Abstract
Introduction
Results
Discussion
Materials and methods
References

Purified granzyme B induces apoptosis, and purified perforin induces lysis
To characterize cell death induced by CTLs by time-lapse microscopy,it was first necessary to characterize cell death induced bypurified perforin alone or perforin together with granzyme B.During apoptosis induced by cytotoxic drugs, cells initiallyundergo a period of intense ruffling of the plasma membraneknown as blebbing, and phosphatidylserine (PS) becomes externalizedfrom the inner leaflet of the plasma membrane to the outer leaflet(Martin et al., 1995). Such a cell would normally be rapidlyphagocytosed in vivo; however, under typical cell culture conditions,the integrity of the plasma membrane is eventually lost, resultingin the rupture of the cell. PS externalization can be detectedby binding of annexin V, and the loss of plasma membrane integritycan later be detected by the passive uptake of propidium iodide(PI; Goldstein et al., 2000a,b). This process is in contrastto necrosis, which involves rapid cell swelling and ruptureof the plasma membrane in the absence of rounding and blebbingand results in simultaneous binding of annexin V and PI uptake.Cells undergoing early apoptosis stain with annexin V but excludePI (annexin V⁺PI^–), whereas necrotic cells or cells thathave undergone late apoptotic changes stain with annexin V andPI.

Granzyme B has been shown to induce apoptosis in a perforin-dependentmanner (Shi et al., 1992), and purified perforin is believedto induce cell lysis (Podack and Konigsberg, 1984; Young et al., 1986).However, little is known about the kinetics and morphologicalfeatures of death induced by these proteins. To investigatethe kinetics of granzyme B–induced cell death, we usedreal-time imaging to follow annexin V binding and PI uptakein MS9II cells treated with 10 nM perforin (a concentrationthat does not cause cell death when applied to cells alone)and 25 nM granzyme B. Under these conditions, the majority ofcells ( $~$ 70%) died within 4 h, and all showed typical signs ofapoptosis (example provided in Fig. 1 A). Individual cells showedthe initial morphological features of apoptosis (rounding/blebbing)in an asynchronous manner between 0.5 and 2 h and invariablyfollowed a distinct sequence of events: (1) rounding and blebbing(seen at 50 min in Fig. 1 A, c); (2) PS exposure as detectedby annexin V binding (at 1 h 20 min; Fig. 1 A, d); and (3) plasmamembrane rupture as detected by PI uptake (2 h 20 min; Fig. 1 A,f). By calculating the relative intensity of each fluorochromeas a function of time, we determined when individual cells becamepositive for annexin V staining and permeable to PI (Fig. 1 B).In the example shown, the individual frames shown in Fig. 1 Acorrespond to the arrows (a–g) shown in Fig. 1 B. By studyingmultiple target cells in the population, we determined thatthe mean time from cell rounding/blebbing until it became annexinV positive was $~$ 20 min, and the mean duration from annexin Vbinding to the loss of plasma membrane integrity (PI staining)was $~$ 70 min (Fig. 1 C). Therefore, the mean total time for celldeath, defined as commencing with the onset of morphologicalchanges (rounding/blebbing) and ending with PI staining, was $~$ 90 min. Inevitably, this estimate did not include the time takento achieve Bid cleavage, cytochrome c release, or caspase activation,as these parameters are known to occur extremely rapidly andprecede rounding (Sutton et al., 2000; Pinkoski et al., 2001).

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Figure 1. Time-lapse microscopy of granzyme B–induced cell death. MS9II cells were washed in HBSS and treated with 10 nM perforin and 25 nM granzyme B. (A) Images of morphology, annexin V, and PI were obtained every 5 min. The cell maintains a normal morphology until 40 min (b), is rounded up, and blebbing occurs by 50 min (c). Increased annexin V staining is clearly evident by 1 h 20 min (d). The plasma membrane integrity was maintained until 2 h 10 min (e) but was lost by 2 h 20 min (f). By f, the annexin V staining is seen around large cellular protrusions (airbags) that define the swollen plasma membrane. The full video is presented in Video 1 (available at http://www.jcb.org/cgi/content/full/jcb.200510072/DC1). DIC, differential interference contrast. (B) Fluorescence of annexin V binding and PI relative to maximum fluorescence is presented for the cell depicted in A. The times at which the frames in A were captured are indicated by arrows. (C) The duration from rounding to annexin V binding and annexin V binding to PI uptake was calculated for individual cells and is presented as means ± SEM (error bars; n = 25). AV, annexin V.

We also used the same methodology to investigate the characteristicsof perforin-induced cell lysis by assaying annexin V bindingand PI uptake in cells treated with sufficient purified perforinto induce direct lysis (80 nM) in the absence of granzyme B(Fig. 2). After perforin addition, the plasma membrane developedprotrusions that rapidly expanded, and the cells simultaneouslybecame permeable to PI and stained positive with annexin V (Fig. 2 A).Staining with each fluorochrome typically commenced 2–3min after perforin addition and reached maximal levels by 10min (Fig. 2 B). Interestingly, when the concentration of perforinwas progressively reduced so that only 10–50% of the cellsdied, the changes in cell morphology and staining did not varysignificantly (not depicted). In particular, the apoptotic changesseen in the presence of granzyme B were never observed; independentof the dosage used, purified perforin induced only cell lysis.

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Figure 2. Time-lapse microscopy of perforin-induced death in MS9II cells. MS9II cells were followed by time-lapse microscopy. (A) Images of morphology, annexin V, and PI were taken every 20 s. 80 nM perforin was added after the fifth frame (1 min 22 s). Plasma membrane protrusions are indicated by white arrows. Black arrow indicates the time of perforin addition. Asterisk indicates the cell analyzed in B. The full video is presented in Video 2 (available at http://www.jcb.org/cgi/content/full/jcb.200510072/DC1). (B) The fluorescence of annexin V and PI in the cell indicated by an asterisk in A was plotted as relative fluorescence compared with maximum fluorescence for that fluorochrome. Perforin addition is noted by the dashed arrow below the x axis. Arrows indicate the points at which the frames in A were recorded.

Intact wild-type CTLs induce apoptosis with similar kinetics to granzyme B
Using the aforementioned findings, we next turned to the questionof how intact CTLs induce target cell death in the presenceor absence of granzymes A and the B cluster (granzyme AB^–/–).We raised alloreactive CD8⁺ mouse CTLs (H-2^b anti–H-2^k)that killed MS9II fibroblasts (H-2^k) exclusively in a perforin-dependentmanner (Fig. 3). CTLs from wild-type mice efficiently killedMS9II in a 4-h assay as indicated by release of preloaded ⁵¹Cr(Fig. 3 A). The CTLs of granzyme AB^–/– mice weresomewhat less potent than wild-type CTLs over the 4-h time frame(Fig. 3 A), but these CTLs maintained significant killing ability.CTLs derived from perforin^–/– mice did not inducesignificant cell death (Fig. 3 A), and cytotoxicity was completelyblocked by chelating calcium with EGTA (not depicted), whichis consistent with a perforin-dependent cell death mechanism.Furthermore, the CTLs of gld mice that lack functional FasLwere as efficient as wild type (not depicted), confirming thatcell death in this assay was completely dependent on the granulepathway. Using RT-PCR, we showed that CTLs from granzyme AB^–/–mice expressed comparable levels of perforin and granzyme KmRNA to CTLs isolated from wild-type mice but, as expected,were completely deficient in message for both granzymes A andB (Fig. 3 B). Consistent with a previous study (Pham et al., 1996),CTLs from granzyme AB^–/– mice expressed mRNA forgranzyme C; however, this was $~$ 10-fold less than that of wild-typemice. Therefore, the CTLs of granzyme AB^–/– micewere capable of synthesizing both granzyme C and K as well asperforin.

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Figure 3. CTL-induced death of MS9II cells. Allogenic CTLs (H-2^b anti–H-2^k) were generated in a one-way mixed lymphocyte reaction from wild-type (WT), granzyme AB^–/–, and perforin^–/– mice. (A) MS9II cells preloaded with 100 µCi ⁵¹Cr were treated with CTLs from wild-type, granzyme AB^–/–, and perforin^–/– mice at the effector to target ratios indicated. The percentage of ⁵¹Cr released was assayed at 4 h. The data points shown are the means ± SD of data pooled from three independent assays each prepared in triplicate. (B) Real-time PCR for perforin and granzyme A, B, C, and K was performed on cDNA transcribed from mRNA isolated from WT and granzyme AB^–/– mice. Each cDNA sample was assayed in duplicate. Data presented is the mean fold increase in message (calculated from the means of duplicate samples) relative to the level of granzyme C in naive T cells from wild-type mice. Data represents message amplified from CTLs of three mice tested independently in each case ± SD (error bars).

To characterize the morphology of death, we coincubated CTLsfrom wild-type mice with MS9II cells at effector/target ratios(2:1) that easily permitted us to identify CTLs (motile andsmall) from MS9II cells (large, flat, and adherent). We thenfollowed the death by time-lapse microscopy (example presentedin Fig. 4 A). We found that MS9II cells underwent changes thatwere virtually identical to those of cells killed by purifiedperforin and granzyme B. After conjugation, the target cellsrapidly rounded and detached from the culture dish. The plasmamembrane then became ruffled (blebbed), and, after a furtherperiod of time, the cell began to swell. A clear increase inannexin V binding was observed during the blebbing phase ofdeath, but PI uptake was only observed when the cell had becomeswollen. The sequence of events (rounding, blebbing, annexinV binding, and PI uptake) was invariant for all of the cellsexamined. Using the same methodology described in Time-lapsemicroscopy to determine the relative fluorescence intensityof annexin V and PI, we could determine the specific timelineof events for MS9II cells killed by wild-type CTLs. For example,in the cell depicted in Fig. 4 (A and B), conjugation of theCTL was observed at 20 min, cell rounding was observed by 30min, and annexin V binding was detectable by $~$ 1 h. The cell remainedround and the plasma membrane remained intact until 1 h 45 min,after which the cell swelled and its outline became less distinct.PI uptake was detected at 1 h 50 min, which is coincident withcell swelling (Fig. 4, A and B). Pooled analysis of single cells(n = 33) revealed that the interval between rounding and annexinV binding was $~$ 30 min, whereas the duration between annexin Vbinding and PI uptake was $~$ 55 min (Fig. 4 C). Thus, the overalltime of death (rounding to PI) was $~$ 90 min.

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Figure 4. Time-lapse microscopy of death induced by wild-type CTLs. CTLs isolated from wild-type mice were incubated with MS9II cells. (A) Images of morphology, annexin V binding, and PI uptake were taken sequentially every 5 min. At 20 min (a), the CTL (indicated by #) forms a synapse with the target (indicated by asterisks). By 30 min (b), the target cell is blebbing and rounding, and, by 55 min (d), the target cell is still blebbing but remains annexin V negative. By 1 h 10 min (e), the cell becomes annexin V positive but maintains plasma membrane integrity until 1 h 45 min (f). Plasma membrane integrity is lost, and the cell becomes PI positive by 1 h 50 min. The full video is presented in Video 3 (available at http://www.jcb.org/cgi/content/full/jcb.200510072/DC1. Arrow indicates the swollen plasma membrane. DIC, differential interference contrast. (B) Fluorescence of annexin V binding and PI relative to maximum fluorescence is presented for the cell depicted by the asterisk in A. The point at which frames (a–g) were recorded in A are shown on the time line by arrows. (C) The duration from rounding to annexin V binding and annexin V binding to PI uptake was calculated for individual cells and is presented as means ± SEM (error bars; n = 33).

Granzyme AB^–/– CTL-induced cell death is distinct from classic apoptosis and perforin lysis
Similar to death induced by wild-type effector cells, CTLs fromgranzyme AB^–/– mice induced rapid rounding and blebbingof the MS9II target cells followed eventually by plasma membraneswelling and rupture (example presented in Fig. 5 A). In contrastto death induced by wild-type CTLs, the onset of annexin V stainingand PI uptake were virtually simultaneous during death inducedby granzyme AB^–/– CTLs (Fig. 5 B). In the examplepresented in Fig. 5 A, interaction between the CTL and targetcell was first observed at 1 h 42 min; however, annexin V bindingand PI uptake were not observed until 2 h 48 min (Fig. 5 B).When several target cells (n = 19) were analyzed in the sameway, the overall time from cell rounding to annexin V bindingwas $~$ 90 min, but, in contrast to wild-type CTLs, the durationfrom annexin V binding to PI uptake was <5 min.

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Figure 5. Death induced by CTLs from granzyme AB^–/– mice. CTLs isolated from granzyme AB^–/– mice were incubated with MS9II cells. (A) Images of morphology, annexin V binding, and PI uptake were taken sequentially every 6 min. Frame a (24 min) shows the unconjugated target cell (indicated by an asterisk). By 1 h 42 min (b), the CTL (indicated by #) formed a synapse with the target (indicated by asterisks). By 2 h 12 min, (c) the target cell was blebbing and rounding, and, by 2 h 24 min (d), the target cell is fully round and still blebbing but remains annexin V and PI negative until 2 h 42 min (e). By 2 h 48 min (f), annexin V staining and PI uptake is evident. The cell continues swelling until 3 h (g). Arrow indicates the swollen plasma membrane. A montage of morphology images for each frame is presented in Fig. S1, and a full time-lapse video is presented in Video 4 (available at http://www.jcb.org/cgi/content/full/jcb.200510072/DC1). DIC, differential interference contrast. (B) Fluorescence of annexin V binding and PI relative to maximum fluorescence is presented for the cell depicted by the asterisk in A. The point at which frames (a–g) were recorded in A are shown on the time line by arrows. (C) The duration from rounding to annexin V binding and annexin V binding to PI uptake was calculated for individual cells and is presented as means ± SEM (error bars; n = 19).

Using cell rounding as a common reference point, it was possibleto compare the time course of CTL-induced cell death with apoptosisinduced by granzyme B that was delivered by sublytic concentrationsof purified perforin (Fig. 6). The execution phase (durationfrom rounding to PI uptake) of CTL-induced death (87.9 ±3.6 min for wild-type CTLs and 87.4 ± 3.2 min for granzymeAB^–/– CTLs) was very similar to that of purifiedperforin/granzyme B (94.6 ± 3.2 min). Therefore, in ourmodel system, we found that regardless of whether death wasinduced by purified granzyme B/perforin, wild-type CTLs, orgranzyme-deficient CTLs, the duration of death was $~$ 1.5 h ineach case. During death induced by wild-type CTLs or granzymeB/perforin, the target cells became annexin V positive $~$ 30 minafter rounding, and the cells remained annexin V positive butexcluded PI for the following $~$ 60 min. During death induced bygranzyme AB^–/– CTLs, annexin V binding was not evidentuntil $~$ 90 min and was almost concomitant with PI uptake. Themajor discrepancy between wild-type CTLs and granzyme AB^–/–CTLs was that annexin positivity was markedly delayed duringdeath induced by granzyme AB^–/– CTLs so that thetime during which the cells were annexin V⁺PI^– was reducedvirtually to zero. Because not all CTLs that came in contactwith targets killed that target and some targets were contactedby numerous CTLs (Fig. S2, available at http://www.jcb.org/cgi/content/full/jcb.200510072/DC1),it was not possible to get an accurate measure of the initiationphase of apoptosis (i.e., duration from conjugation to rounding).

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Figure 6. Comparison of the timing of molecular events during granzyme B and CTL-induced cell death. Data from Figs. 1 C, 4 C, and 5 C were collated and presented as a function of time. T = 0 indicates time when rounding/blebbing started. Gray bars indicate times when cells were round and blebbing but neither annexin V nor PI positive. Green bars indicate times when the cells were round/blebbing and annexin V positive but PI negative. Red and green-checkered bars indicate when cells were PI positive. Arrows of the corresponding color indicate the time at which each event started. Error bars represent SEM.

Although overall the morphology of cell death in response togranzyme AB^–/– CTLs was strikingly similar to apoptosis,simultaneous staining of annexin V and PI was reminiscent ofperforin lysis. Therefore, we considered that individual targetcells might be attacked, in turn, by several CTLs (Fig. S2)delivering consecutive sublytic doses of perforin so that theircumulative effects would eventually kill the cell. To modelthis, we added multiple sublytic doses (5 nM) of perforin at20-min intervals (Fig. 7). We found that at this concentration,a single addition of perforin induced death of <5% of cellsafter 4 h (Fig. 7 A). However, the same concentration plus granzymeB induced apoptosis in >80% of cells (Fig. 7 B). Two or threesequential doses of perforin every 20 min did not result inan increase in cell death, but four sequential doses induceddeath in $~$ 30% of cells. As three sequential doses of perforindid not induce more death than one single dose, the death observedafter four doses represented a cumulative effect similar towhat may occur if perforin was delivered by several CTLs. Incontrast to death induced by granzyme AB^–/– CTLs,the sequential addition of sublytic perforin did not resultin rounding and blebbing (Fig. 7 C). Rather, this death involvedformation of the very large membrane protrusions similar tothat induced by single lytic doses of perforin (Fig. 2). Thesedata indicated that death induced by granzyme AB^–/–CTLs does not reflect multiple hits of sublytic perforin andmore likely reflects the action of granule proteins deliveredby perforin.

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Figure 7. Sequential addition of perforin induces cell lysis. MS9II cells were treated with 5 nM perforin between one (1 dose) and four times (4 dose) sequentially every 20 min (A) or with 5 nM perforin and 25 nM granzyme B (B). Black arrows indicate the times at which perforin was added. Gray arrows (a–g) in A indicate the times at which the images in C were taken. (C) Images of morphology or PI fluorescence were taken every 5 min. DIC, differential interference contrast.

	Discussion

Top Abstract Introduction Results Discussion Materials and methods References

Much of our current knowledge of granule-mediated cell deathby intact CTLs is derived from population-based studies thatcannot easily distinguish between various death mechanisms (Sutton et al., 1997;Trapani et al., 1998; Davis et al., 2001). Therefore, relativelylittle is known about the nature of cell death induced by intactCTLs at a single cell level. Furthermore, the ability of CTLsfrom mice deficient in key granzymes A and B to kill targetcells through the granule pathway has been documented in severalexperimental systems (Simon et al., 1997; Davis et al., 2001;Pardo et al., 2002, 2004; Smyth et al., 2003). However, it hasnot been possible to determine how the target cells were killed.It has recently been shown that individual CTLs in wild-typemice may contain perforin but neither granzyme A or B (Kelso et al., 2002).The killing observed by the granzyme AB^–/– CTLsmay, therefore, be caused by a specific subset of cells thatare commonly present in populations of CTLs isolated from wild-typemice. As the nature of death (apoptosis, necrosis, lysis, oranother alternate programmed cell death) can influence how thedying cell is presented to the immune system (Henson et al., 2001),the mode of death induced by granzyme AB^–/– CTLsis likely to play a bona fide role in the immune response ofwild-type animals to pathogens or tumor cells.

It has been proposed that the default pathway adopted by CTLsin the absence of most of the proapoptotic granzymes is perforin-inducedlysis (Simon et al., 1997). In contrast, granzymes C, K, andM have been shown to induce the death of target cells when deliveredby perforin. Therefore, death induced in the absence of granzymesA and B may be caused by various other death-inducing granzymes.We found that death induced by lytic concentrations of perforinwas virtually immediate (plasma membrane rupture within 2–3min and complete by $~$ 10 min) and involved the progressive swellingof plasma membrane protrusions followed within a few minutesby the loss of plasma membrane integrity. Cell rounding anddetachment from the culture flask were notably absent. Thisis consistent with a recent study that also showed that perforininduced large "airbaglike" protrusions of the plasma membranefollowed by plasma membrane rupture (Keefe et al., 2005). Theseprotrusions were reported to be reversible when perforin wasdelivered at sublytic concentrations, probably as a result ofplasma membrane repair by lysosomes (Keefe et al., 2005). Inour model, we never observed large plasma membrane protrusionswhen we used sublytic concentrations of perforin alone or incombination with granzyme B. This may reflect cell type differencesor may suggest that the formation of plasma membrane protrusionsis not required for granzyme uptake. In contrast to perforinlysis, MS9II cells killed by granzyme B added with sublyticconcentrations of perforin or by wild-type or granzyme AB^–/–CTLs underwent more gradual death (taking $~$ 90 min), which wascharacterized by rapid rounding followed by a discrete periodof plasma membrane blebbing before the eventual loss of plasmamembrane integrity. Our thorough kinetic analysis of cell deathat a single cell level has revealed that the morphology of deathinduced by either wild-type CTLs or CTLs from granzyme AB^–/–mice was quite clearly distinct from cell lysis induced by purifiedperforin.

The rapidity of cell death induced by CTLs or perforin/granzymeB probably reflects the essential need to kill virus-infectedcells as efficiently as possible to limit viral replicationand spread. But strikingly, although the duration of targetcell death induced by intact CTLs was $~$ 1.5 h in the presenceor absence of granzyme A and the B cluster, the timing of specificmolecular events differed somewhat. During apoptosis inducedby granzyme B/perforin or the CTLs of wild-type mice, PS exposureoccurred shortly after the target cell rounded up, and the cellmaintained plasma membrane integrity over the following 45–60min. In contrast, PS exposure was not evident shortly afterrounding during death induced by granzyme AB^–/–CTLs, and binding of annexin V to PS was only evident virtuallyat the same time as it lost plasma membrane integrity. Underour experimental conditions, it is not clear whether PS everbecomes exposed on the outer leaflet of the plasma membraneor whether the dying cell becomes permeable to annexin V. Regardlessof the nature of annexin V binding, these data indicate thatgranzyme B and wild-type CTLs induce classic apoptosis, whereasgranzyme AB^–/– mice induce a novel form of programmedcell death that shares similar features with but is distinctfrom apoptosis. These findings are consistent with our previousstudy that showed that caspase-dependent DNA fragmentation,a classic hallmark of apoptotic cell death, was detected incells killed by wild-type CTLs but was not detected in cellskilled by granzyme AB^–/– CTLs (Davis et al., 2001).

The physiological consequences of killing a target cell by apoptosisor by nonapoptotic cell death are unclear. It has been proposedthat cells undergoing apoptosis are packaged and cleared byphagocytosis before plasma membrane rupture, avoiding the leakageof potentially toxic cytoplasmic material into the cellularmilieu and reducing bystander cell damage. It has also beensuggested that apoptotic cells may be presented to antigen-presentingcells in a different way than necrotic cells and that this maymodulate the resultant immune response (for review see Henson et al., 2001).PS exposure is an important event in the phagocytosis of apoptoticcells, as macrophages deficient in PS receptor bind but do notingest dying cells. As cells killed by granzyme AB^–/–CTLs do not expose PS before plasma membrane rupture, it ispossible that these cells would not be efficiently engulfedby macrophages and, thus, may be perceived by the immune systemas having undergone necrosis. If the target cell under attackcontains potentially viable virions, the outcome for the hostmight differ significantly. First, if viral particles were releasedextracellularly, the opportunity for spread to neighboring cellsor for systemic infection is heightened. Second, the efficiencyof viral uptake into antigen-presenting cells might well influencesubsequent antigen presentation, chemotaxis, and the qualityof the local inflammatory reaction. On the basis of our findings,we can speculate that one reason a virus might express a specificinhibitor of intrinsic apoptosis (e.g., IAPs) or granzyme B(e.g., the L4 100-kD protein of adenovirus) might be to influencethe mechanism of cell death, thereby reducing the likelihoodof phagocytosis and encouraging viral spread rather than significantlyprolonging the life of the infected cell. It must be noted thatit has not been determined whether cells killed by granzymeAB^–/– CTLs can be recognized and cleared by phagocyticcells through a PS-independent mechanism.

It is intriguing to speculate on the molecular mechanisms responsiblefor the cell death induced by granzyme AB^–/– CTLs.Several granzymes have been identified in mice in addition togranzymes A and B, including C, D, E, F, G, J, K, M, and N,of which granzyme C, K, and M have been shown to induce celldeath when delivered by perforin (Trapani and Smyth, 1993; MacDonald et al., 1999;Johnson et al., 2003; Kelly et al., 2004). Granzyme M expressionis restricted to natural killer cells (Trapani and Smyth, 1993;Sedelies et al., 2004). As our data is generated from CD8⁺ Tcells, granzyme M is unlikely to be responsible for the deathin our model. Granzyme AB^–/– mice were generatedby crossing granzyme A^–/– mice with granzyme B^–/–mice (Simon et al., 1997). As disrupting the granzyme B genealso resulted in the reduction in expression of multiple genes,including granzymes C, D, E, F, and G (Pham et al., 1996), weconsidered the possibility that granzyme C might be excludedas a cause of cell death. However, we found significant levelsof granzyme C mRNA expressed in our alloreactive CTLs (10,000times higher than that detected in naive T cells from wild-typemice). So, although granzyme C expression may be reduced ingranzyme AB^–/– mice, it cannot be excluded as causingthe death of MS9II target cells in our model. We further showedthat message for granzyme K is expressed at comparable levelsin CTLs from granzyme AB^–/– and wild-type mice.Therefore, the death induced by CTLs from granzyme AB^–/–mice may be caused by either granzyme C, K, or other granuleproteins for which a death-inducing ability has not been described.

The distinct specificity, alternate regulation, cell-specificexpression profile, and species-to-species variation of granzymessuggest that each of the granzymes may play a very specificrole in an immune response while collaborating to thwart mosttypes of viral infection or cells undergoing oncogenic transformation.Understanding the mechanism by which granzyme AB^–/–CTLs kill their targets will be important in developing ourknowledge of how CTL-induced target cell killing helps preventinfection and may unmask the key granule constituents involvedin maintaining the relatively healthy immune status of granzymeAB^–/– mice compared with perforin-deficient mice.

Materials and methods

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Abstract
Introduction
Results
Discussion
Materials and methods
References

Materials
⁵¹Cr (as sodium dichromate) was purchased from GE Healthcare.Annexin V–FLUOS was obtained from Roche. Cell culturereagents were purchased from Invitrogen, and PI and all otherchemicals were obtained from Sigma-Aldrich. Mouse perforin expressedin baculovirus-infected insect cells was purified essentiallyaccording to Liu et al. (1994). Human granzyme B was expressedand purified from Pichia pastoris as described previously (Sun et al., 1999).

Cell culture
The adherent mouse fibroblast cell line MS9II (derived fromthe C3H strain H-2^k) was obtained from W. Sly (Washington University,St. Louis, MO) and cultured at 37°C in a humidified CO₂incubator in RPMI medium supplemented with 2 mM glutamine, 10%FBS, and 1 mM sodium pyruvate.

Isolation and culture of allogenic CTLs
C3H/J (H-2^k) mice and C57BL/6 (H-2^b) mice were maintained inspecific pathogen-free conditions at The Walter and Eliza HallInstitute (Melbourne, Australia). Mice deficient in granzymeA and the granzyme B cluster (granzyme AB^–/–; Simon et al., 1997;Mullbacher et al., 1999; Davis et al., 2001; Pardo et al., 2004)were obtained from M. Simon (Max-Planck-Institut für Immunbiologie,Freiburg, Germany; Simon et al., 1997) and maintained at thePeter MacCallum Cancer Centre (Melbourne, Australia). The micewere generated by backcrossing granzyme B cluster–deficientmice (generated on strain 129 embryonic stem cells; H-2^b; Ebnet et al., 1995)for six generations with C57BL/6 mice and for a further twogenerations with granzyme A–deficient mice (generatedfrom C57BL/6 embryonic stem cells; Heusel et al., 1994). Thus,the granzyme AB^–/– mice were backcrossed a totalof eight generations to C57BL/6.

Allogeneic CTLs were generated in a one-way mixed lymphocytereaction in which splenocytes isolated from C57BL/6 or granzymeAB^–/– mice were cocultured for 7 d in RPMI containing10% FBS, 2 mM glutamine, 50 µM ß-mercaptoethanol,100 µM nonessential amino acids, 100 U/ml penicillin,100 µg/ml streptomycin, 1 mM sodiun pyruvate, and 50 U/mlrIL-2 with a similar number of lethally irradiated stimulatorsplenocytes from C3H/J mice (H-2^k). In some experiments, theactivated lymphocytes were restimulated with C3H/J splenocytesand cultured for a further 3–4 d. Phenotypic analysisby FACS demonstrated that the responder cells were >90% CD3⁺CD8⁺T cells. The activation markers CD25, CD44, and CD69 did notvary significantly between the responder cell populations.

⁵¹Cr release assays for cytotoxicity
10⁶ target cells were incubated with 75 µCi ⁵¹Cr in 100µl of culture medium for 1 h at 37°C. Cells were washedthree times in culture medium to remove the unincorporated ⁵¹Crand resuspended at 2 x 10⁵ cells/ml. CD8⁺ CTLs were incubatedwith the target cells at the ratios indicated, and the supernatantwas harvested using a Skatron supernatant collection system(Molecular Devices). ⁵¹Cr released into the supernatant wasdetected using an automatic ${gamma}$ counter (Wallac Wizard 1470; PerkinElmer).In each case, the spontaneous release of radiolabel over thetime of the assay was no higher than 10% of the total incorporatedradioactivity. The percentage of ⁵¹Cr release was calculatedby the following equation: [(cpm of ⁵¹Cr released from sample– cpm of ⁵¹Cr released from untreated cells/cpm of ⁵¹Crreleased from cells treated with 1 M HCl – cpm releasedfrom untreated cells) x 100].

Time-lapse microscopy
MS9II cells were plated in 96-well culture plates and incubatedovernight at 37°C in a humidified CO₂ incubator. The plateswere transferred to a temperature-controlled stage (Prior Proscan;GT Vision) maintained at 37°C on a microscope (IX-81; Olympus).PI was added to the cultures at 50 ng/ml, and annexin V–FLUOSwas added at 2 µg/ml. Cells were exposed to an equal numberof activated CD8⁺ CTLs and viewed using a 20x LCplanFL NA 0.40lens (Olympus) for the times indicated. Images were capturedat specified intervals using a CCD camera (model ORCA-ER; Hamamatsu)controlled by MetaMorph software (Universal Imaging Corp.).As the fluorescence intensities of annexin V–FLUOS andPI were significantly different, we used MetaMorph and Excelsoftware (Microsoft) to plot the fluorescence reading for eachframe relative to the maximum for that fluorochrome over thecourse of the experiment after subtraction of the backgroundfluorescence reading from each. The maximum fluorescence plottedfor each fluorophore was 1.0, and baseline fluorescence waszero.

RNA extraction, cDNA synthesis, and real-time PCR analysis
Splenic lymphocytes from a 7-d mixed lymphocyte reaction (>95%CD8⁺ T cells) were pelleted and resuspended in 1 ml TRIzol reagent(Invitrogen). RNA was extracted with 200 µl chloroformand precipitated with isopropanol. The RNA pellet was washedwith 70% ethanol, resuspended in 40 µL RNA Storage Solutionbuffer (Ambion), and incubated at 60°C for 5 min. cDNA wassynthesized using an Omniscript kit (QIAGEN) according to themanufacturer's instructions. In brief, cDNA mix (0.2 U/µLOmniscript reverse transcriptase [QIAGEN], 1x cDNA buffer, 0.5mM each deoxynucleotide triphosphate, 1 µM oligo-dT [Promega],and 0.5 U/µL RNAsin [Invitrogen]) was added to 100 ngRNA and heated at 37°C for 1 h. cDNA encoding granzymesA, B, C, K, and perforin were quantified using real-time analysis,which was performed using an Assays-on-Demand TaqMan Gene ExpressionAssay kit (Applied Biosystems), and singleplex PCR was performedusing TaqMan (FAM dye labeled) minor groove-binder probes. cDNAencoding the mitochondrial ribosomal protein L32 was quantifiedas an internal standard to provide a reference point for comparingmRNA levels for granzyme with perforin in naive and activatedlymphocytes. Real-time PCR was performed using a thermocycler(ABI PRISM 7700; Applied Biosystems) with denaturation at 95°Cfor 2 min followed by 40 cycles of denaturation at 95°Cfor 10 s and synthesis for 30 s at 60°C.

Online supplemental material
Video 1 is a time-lapse video of the death of an MS9II cellinduced by 10 nM perforin and 25 nM granzyme B as describedin Fig. 1. Video 2 is a time-lapse video of the death of anMS9II cell induced by 80 nM perforin as described in Fig. 2.Video 3 is a time-lapse video of the death of an MS9II cellinduced by a wild-type CTL as described in Fig. 4. Video 4 isa time-lapse video of the death of an MS9II cell induced bya granzyme AB^–/– CTL as described in Fig. 5. Fig.S1 is a montage of a target cell killed by granzyme AB^–/–CTLs as described in Fig. 5, and Fig. S2 is a montage of a targetcell killed by granzyme AB^–/– CTLs in which thetarget cell depicted is touched by several lymphocytes beforerounding. Online supplemental material is available at http://www.jcb.org/cgi/content/full/jcb.200510072/DC1.

Acknowledgments

We thank Sarah Ellis (Peter MacCallum Cancer Centre, Melbourne,Australia) for technical help.

This work was supported by grant funding from the National Healthand Medical Research Council (NHMRC) of Australia to V.R. Suttonand J.A. Trapani. J.A. Trapani is a Senior Principal ResearchFellow, and N.J. Waterhouse is the recipient of an RD WrightCareer Award from NHMRC.

Submitted: 13 October 2005

Accepted: 8 March 2006

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