|
|
|
|
|
|
|
||
© The Rockefeller University Press,
0021-9525/1998//153 $5.00
The Journal of Cell Biology, Volume 140, Number 1,
, 1998 153-158
Article |
A Role for Caspases in Lens Fiber Differentiation
Medical Research Council Laboratory for Molecular Cell Biology and Biology Department, University College London, London WC1E 6BT, United Kingdom
There is increasing evidence that programmed cell death (PCD) depends on a novel family of intracellular cysteine proteases, called caspases, that includes the Ced-3 protease in the nematode Caenorhabditis elegans and the interleukin-1β–converting enzyme (ICE)-like proteases in mammals. Some developing cells, including lens epithelial cells, erythroblasts, and keratinocytes, lose their nucleus and other organelles when they terminally differentiate, but it is not known whether the enzymatic machinery of PCD is involved in any of these normal differentiation events. We show here that at least one CPP32 (caspase-3)-like member of the caspase family becomes activated when rodent lens epithelial cells terminally differentiate into anucleate lens fibers in vivo, and that a peptide inhibitor of these proteases blocks the denucleation process in an in vitro model of lens fiber differentiation. These findings suggest that at least part of the machinery of PCD is involved in lens fiber differentiation.
Abbreviations used in this paper: bFGF, basic fibroblast growth factor; MTT, 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide; P, postnatal day; PCD, programmed cell death; PARP, poly(ADP-ribose) polymerase; STS, staurosporine; TUNEL, terminal deoxynucleotidyl transferase [Tdt]-mediated dUTP-biotin nick-end labeling.
PROGRAMMED cell death (PCD)1 eliminates unwanted cells in most animal tissues at some stage of their development (for reviews see Glucksmann, 1951; Ellis et al., 1991; Jacobson et al., 1997). It is thought to involve an intracellular proteolytic cascade, mediated by members of the Ced-3/interleukin-1β–converting enzyme (ICE) family of cysteine proteases, now called caspases, that cleave one another and various key intracellular target proteins to kill the cell neatly and quickly (Yuan et al., 1993; Martin and Green, 1995; Alnemri et al., 1996; Chinnaiyan et al., 1996). Some developing cells, such as lens epithelial cells, erythroblasts, and keratinocytes, lose their nucleus and other organelles when they terminally differentiate, and it seems possible that they use some elements of the caspase-based death program in doing so. Here we provide evidence that this is the case for lens cells.
Primary lens fibers develop from lens epithelial cells that form the posterior half of the early lens vesicle. Secondary lens fibers develop later from epithelial cells at the equatorial region of the lens, adding to the original primary fibers that remain as a core at the center of the lens (Goss, 1978; McAvoy, 1980). In the formation of both primary and secondary fibers, the cell nucleus and other organelles are lost as each lens fiber forms, but the intracellular mechanisms involved are unknown. There are conflicting reports about the nature of the nuclear loss, especially in the formation of secondary fibers. Modak and colleagues reported that the nuclear changes during terminal differentiation of chick secondary lens fiber cells resemble those seen in PCD: the nucleus becomes pyknotic and the DNA is degraded into low molecular weight fragments of discrete sizes (Modak and Perdue, 1970; Appleby and Modak, 1977). Kuwabara and Imaizumi, however, reported that the nucleus does not become pyknotic during secondary lens fiber cell differentiation, but instead just fades away (Kuwabara and Imaizumi, 1974). Moreover, several papers (Fromm et al., 1994; Morgenbesser et al., 1994; Pan and Griep, 1994; Robinson et al., 1995; Chow et al., 1995a) report that nuclei of differentiating secondary fiber cells in the mouse lens are not labeled by the in situ end-labeling TUNEL (terminal deoxynucleotidyl transferase [TdT]-mediated dUTP-biotin nick-end labeling) technique, which should label nuclei containing fragmented DNA (Gavrieli et al., 1992), although a recent study demonstrated DNA fragmentation in differentiating chick lens fiber cells by both the TUNEL technique and in situ electrophoresis (Bassnett and Mataic, 1997).
In the present report we present three lines of evidence that lens fiber differentiation involves components of the machinery of PCD: (a) the nucleus in differentiating secondary lens fiber cells can be labeled by the TUNEL technique, suggesting that DNA fragmentation occurs during the differentiation process; (b) poly-(ADP-ribose) polymerase (PARP), a known substrate for caspase-3 and some caspase-3–like caspases (Lazebnik et al., 1994; Alnemri et al., 1995a,b; Nicholson et al., Tewari et al, 1995; Duan et al., 1996; Schlegel et al., 1996), is cleaved during lens development in a similar way to the cleavage that occurs in PCD, suggesting that caspase-3 or a related caspase is activated during the process; and (c) a peptide caspase inhibitor inhibits denucleation and PARP cleavage in differentiating lens cells in culture, suggesting that caspase activation is required for these processes.
 |
Materials and Methods |
|---|
 TopAbstract Materials and Methods ResultsDiscussionReferences |
|---|
Propidium Iodide or Bisbenzimide Staining
Lens explants, unfixed (for bisbenzimide staining) or fixed in 70% ethanol for 10 min at –20°C (for propidium iodide staining), were stained with either bisbenzimide (Hoechst 33342; Frankfurt, Germany; 40 µg/ml in DME/F-12), or propidium iodide (4 µg/ml in PBS containing 100 µg/ml DNase-free RNase A for 30 min at 37°C, and then examined in a fluorescence microscope (model BH2-FLPC; Olympus, Tokyo, Japan).
MTT Assay
MTT was dissolved in DME/F-12 at 5 mg/ml and sterilized by passage through a 0.22-µm filter (Millipore Corp., Waters Chromatography, Milford, MA). This stock solution was added (1:10 parts of medium) to each microwell of the Terasaki plate, and then the plate was incubated at 37°C for 1 h. Viable cells cleave the tetrazolium ring of the MTT into a visible dark blue formazan reaction product, whereas dead cells remain uncolored. The total numbers of live and dead cells were counted in an inverted microscope (model OMT2; Olympus). No proliferation of lens epithelial cells was observed 2 d after plating, even in the presence of FCS or bFGF plus insulin.
TUNEL Assay
A P11 rat lens was fixed in 4% paraformaldehyde, equilibrated in 30% sucrose, frozen in Tissue-Tek O.C.T. compound (Miles, Inc., West Haven, CT), and cut into 10-µm tangential sections with a cryostat (model Jung Frigocut 2800E; Leica, Inc., St. Gallen, Switzerland). The sections were collected onto gelatin-coated glass microscope slides, air dried, fixed again in 4% paraformaldehyde, permeabilized in 0.1% Triton X-100, and then treated with proteinase K (20 µg/ml) for 30 min at 37°C. After extensive washing, the sections were preincubated for 10 min at room temperature in the reaction buffer for TdT (Boehringer GmbH, Mannheim, Germany). The reaction was started by removing the preincubation buffer and adding the reaction mixture containing 500 U/ml TdT, 2.5 mM CoCl2, and 40 µM biotinylated dUTP. Control sections were incubated in the reaction mixture without TdT. After 2 h at 37°C, the reaction was terminated by the addition of 300 mM NaCl and 30 mM sodium citrate. The sections were incubated in 2% BSA in PBS for 10 min and then in streptavidin–fluorescein (diluted 1:100; Amersham Intl., Little Chalfont, UK) for 60 min in the dark. After extensive washing in PBS, the sections were mounted in Gel Mount (Biomeda Corp., Foster City, CA) and examined in a fluorescence microscope (model BH2-FLPC; Olympus). In some experiments, lens epithelial explants cultured for 10 d were processed in the same way as described above, but in these cases the sections were examined in a confocal laser scanning microscope (model MRC-1024; Bio-Rad Laboratories, Hercules, CA). Four fields were randomly selected in the sections of explants from each experimental group (control, bFGF plus insulin-treated, and bFGF plus insulin plus zVAD-fmk-treated), and the numbers of TUNEL-negative and -positive nuclei were counted (100–150 total nuclei were assessed in each field).
Western Blot Analysis
Lenses from developing BALB/c mice were sonicated in SDS sample buffer, run on 7.5% SDS-PAGE gels, transferred to nitrocellulose, incubated in the monoclonal anti-PARP antibody C-2-10 (Lamarre et al., 1988; donated by W. Earnshaw [University of Edinburgh, Edinburgh, Scotland] and G. Poirier [Laval University, Ste-Foy, Québec]), and visualized by enhanced chemiluminescence (Amersham Intl.). Lenses from adult (6-wk) mice were dissected (using a dissecting microscope [model Stemi 2000; Carl Zeiss, Jena, Germany]) into two parts—anterior epithelium and outer lens fibers—and each was processed as described above. As controls, Rat-1 cells were incubated in DME/F-12 containing 10% FCS in the absence or presence of STS (4 µM) for 8 h; the cells were then scraped off the culture dishes, sonicated in SDS sample buffer, and processed as above. Lens epithelial explants were sonicated in SDS sample buffer, run either on 7.5% SDS-PAGE gels (for PARP cleavage analysis) or on 15% SDS-PAGE gels (for crystallin analysis), transferred to nitrocellulose, incubated in the monoclonal anti-PARP antibody, or in either a rabbit anti–
-, or anti–β-crystallin antiserum (donated by J. McAvoy, University of Sydney, Sydney, Austrialia), and visualized by enhanced chemiluminescence. The protein concentration of each extract in SDS sample buffer was assayed after precipitation in trichloroacetic acid using a protein assay kit (Bio-Rad Laboratories; Bradford, 1976)
|
Results |
|---|
|
TopAbstractMaterials and MethodsResultsDiscussionReferences |
|---|
|
|
|
-crystallins. Transparent lens-like (lentoid) bodies begin to appear in the cultures after 
10 d (Peek et al., 1992). We observed the same sequence of events. Moreover, when examined after 10 d by the TUNEL technique, the proportion of TUNEL-positive nuclei was much greater in the explants treated with bFGF and insulin then in untreated explants (see below), and by 14 d lentoid bodies covered almost the complete surface of the treated explants (Fig. 4 D). By contrast, in untreated explants, the epithelial cells did not proliferate or change their shape, the explants remained as a monolayer, and lentoid bodies did not develop (Fig. 4 C). When we stained 14 d bFGF and insulin treated cultures with the fluorescent nuclear dye bisbenzimide, we found that all of the lentoid bodies, including the smallest ones, did not contain nuclei (Fig. 4 B), suggesting that they formed from differentiated fibers that had lost their nucleus.
|
-crystallin in the treated cultures compared to the controls, which is not surprising as -crystallin is expressed in undifferentiated lens epithelial cells, as well as in differentiated lens fibers (McAvoy, 1980; McAvoy et al., 1991). The formation of lentoid bodies in the bFGF- and insulin-treated cultures was almost completely suppressed by the addition of the caspase inhibitor zVAD-fmk (Fig. 4 E), whereas the addition of the chemically similar cathepsin B inhibitor zFA-fmk (Rasnick, 1985) had no effect (data not shown). Moreover, zVAD-fmk greatly decreased the amount of nuclear pyknosis seen in the cultures treated with bFGF and insulin (data not shown), and, when explants that had been cultured for 10 d were labeled by the TUNEL technique, the percentage of TUNEL-positive nuclei was greatly reduced by zVAD-fmk treatment (mean ± SD: untreated explants, 0.83 ± 0.31%; explants treated with bFGF plus insulin, 7.5 ± 2.67%; explants treated with bFGF plus insulin plus zVAD-fmk, 1.67 ± 0.69%). By contrast, neither the increased β-crystallin expression (Fig. 4 F) nor the increased cell proliferation (data not shown) seen in bFGF and insulin treated cultures was blocked by the addition of zVAD-fmk. When extracts of bFGF and insulin treated cultures (containing many lentoid bodies) were analyzed by Western blotting with anti-PARP antibody, PARP cleavage was readily detected, whereas PARP cleavage was not detected in cultures that were not stimulated with bFGF and insulin (Fig. 4 G). PARP cleavage in bFGF and insulin treated cultures was greatly reduced by the addition of zVAD-fmk (Fig. 4 G). These findings suggest that the activation of one or more caspases is required for denucleation to occur, at least in culture.
|
Discussion |
|---|
|
TopAbstractMaterials and MethodsResultsDiscussionReferences |
|---|
The second line of evidence that components of the cell death program are involved in lens fiber differentiation is that PARP is cleaved in the developing lens. PARP cleavage is a widely used indicator of both PCD and the activation of caspase-3 and/or one or more of its close relatives such as caspase-7 (Alnemri et al., 1996). PARP is cleaved from a 116-kD form to an 85-kD fragment in many examples of PCD (Kaufmann, 1989; Kaufmann et al., 1993; Gu et al., 1995; Nicholson et al., 1995; Tewari et al., 1995), and it is cleaved in a similar way in the developing lens. This finding strongly suggests that caspase-3, and/or a closely related caspase, is activated during lens fiber differentiation, which in turn suggests that some parts of the machinery of PCD are used in normal lens development. It seems likely, for example, that caspase-6 becomes activated and cleaves one or more of the nuclear lamins (Fernandes- Alnemri et al., 1995a; Orth et al., 1996; Takahashi et al., 1996) to help remove the nuclear lamina when the nucleus degenerates in developing lens fibers.
The third line of evidence that lens fiber differentiation involves the machinery of PCD is that the caspase inhibitor zVAD-fmk, but not the chemically similar cathepsin B inhibitor zFA-fmk, inhibits both the formation of anucleate lentoid bodies and PARP cleavage in explant cultures of lens epithelial cells treated with bFGF and insulin. In this in vitro model of lens fiber differentiation, the production of β-crystallin increases, just as in vivo (Peek et al., 1992), and it is interesting that this increase is not suppressed by zVAD-fmk treatment. These findings suggest that, whereas PARP cleavage and the loss of the nucleus during lens fiber differentiation requires activated caspases, this is not the case for some other aspects of lens fiber differentiation, such as the increased expression of β-crystallin. Thus, lens fiber differentiation is not simply PCD, since the outcome is very different from that of classical PCD, where the cell usually shrinks, frequently fragments, and is rapidly phagocytosed and digested (Kerr et al., 1972; Wyllie et al., 1980); a lens fiber, by contrast, elongates, fills up with crystallins, and persists for the lifetime of the animal.
Taken together, our results provide strong evidence that the differentiation of a lens epithelial cell into a lens fiber involves components of the basic machinery of PCD. It was recently reported that mice in which the caspase-3 gene was deleted by targeted gene disruption die perinatally with an excess of cells in the central nervous system, apparently as a result of decreased PCD in neuroepithelial cells (Kuida et al., 1996). Although PCD was reported to occur normally in other organs, it appears to us that there is an abnormally large number of nuclei in the core of the lens of the caspase-3–deficient mouse shown in Fig. 3 in Kuida et al. (1996), which could reflect a failure of fiber cell denucleation. If so, this finding would provide further evidence that lens fiber differentiation requires components of the basic machinery of PCD.
In addition to lens cell differentiation, there are at least two other cases where mammalian cell differentiation is accompanied by the loss of the nucleus and other organelles—the development of erythrocytes and skin keratinocytes. It will be interesting to see if the differentiation in these cases is also caspase dependent. This seems likely in the case of keratinocytes, as overexpression of the PCD-suppressing gene bcl-2 has been reported to inhibit human keratinocyte differentiation in culture (Nataraj et al., 1994).
|
Acknowledgments |
|---|
- and anti–β-crystallin antisera, T. Himi (Tokyo Medical and Dental University, Tokyo, Japan) for help with frozen sections, and S. Sato (Kobe University, Kobe, Japan) for continuous encouragement. We thank the Medical Research Council and the Ministry of Education, Science, and Culture of Japan for support. This work was done as a UK–Japan Joint Research Project supported by the Japan Society for the Promotion of Science, the Royal Society, and the British Council.
Submitted: 5 June 1997
Revised: 9 October 1997
Address all correspondence to Martin C. Raff, Medical Research Council Laboratory for Molecular Cell Biology and Biology Department, University College London, London WC1E 6BT, United Kingdom. Tel.: (44) 171.380.7016. Fax: (44) 171.380.7805. E-mail: m.raff{at}ucl.ac.uk
|
References |
|---|
|
TopAbstractMaterials and MethodsResultsDiscussionReferences |
|---|
Alnemri ES, Livingston DJ, Nicholson DW, Salvesen G, Thornberry NA, Wong WW & Yuan J. Human ICE/CED3 protease nomenclature, Cell, 1996, 87, 171, .[Medline]
Appleby DW & Modak SP. DNA degradation in terminally differentiating lens fiber cells from chick embryos, Proc Natl Acad Sci USA, 1977, 74, 5579–5583.
Bassnett S & Mataic D. Chromatin degradation in differentiating fiber cells of the eye lens, J Cell Biol, 1997, 137, 37–49.
Bradford MM. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding, Anal Biochem, 1976, 72, 248–254.[Medline]
Chinnaiyan AM, Orth K, O'Rourke K, Duan H, Poirier GG & Dixit VM. Molecular ordering of the cell death pathway: Bcl-2 and Bcl-xL function upstream of the CED-3-like apoptotic proteases, J Biol Chem, 1996, 271, 4573–4576.
Chow RL, Roux GD, Roghani M, Palmer MA, Rifkin DB, Moscatelli DA & Lang RA. FGF suppresses apoptosis and induces differentiation of fiber cells in the mouse lens, Development (Camb), 1995a, 121, 4383–4393.[Abstract]
Chow SC, Weis M, Kass GE, Holmstrom TH, Eriksson JE & Orrenius S. Involvement of multiple proteases during Fas-mediated apoptosis in T lymphocytes, FEBS (Fed Eur Biochem Soc) Lett, 1995b, 364, 134–138.
Duan H, Orth K, Chinnaiyan A, Poirier G, Froelich C, He W & Dixit V. ICE-LAP6, a novel member of the ICE/Ced-3 gene family, is activated by the cytotoxic T-cell protease granzyme-B, J Biol Chem, 1996, 271, 16720–16724.
Ellis RE, Yuan JY & Horvitz HR. Mechanisms and functions of cell death, Annu Rev Cell Biol, 1991, 7, 663–698.
Fernandes-Alnemri T, Litwack G & Alnemri ES. Mch2, a new member of the apoptotic Ced-3/Ice cysteine protease gene family, Cancer Res, 1995a, 55, 2737–2742.
Fernandes-Alnemri T, Takahashi A, Armstrong R, Krebs J, Fritz L, Tomaselli K, Wang L, Yu Z, Croce C, Salveson G et al.. Mch3, a novel human apoptotic cysteine protease highly related to cpp32, Cancer Res, 1995b, 55, 6045–6052.
Fromm L, Shawlot W, Gunning K, Butel JS & Overbeek PA. The retinoblastoma protein-binding region of simian virus 40 large T antigen alters cell cycle regulation in lenses of transgenic mice, Mol Cell Biol, 1994, 14, 6743–6754.
Gavrieli Y, Sherman Y, Ben SA & Sasson. Identification of programmed cell death in situ via specific labeling of nuclear DNA fragmentation, J Cell Biol, 1992, 119, 493–501.
Glucksmann A. Cell deaths in normal vertebrate ontogeny, Biol Rev, 1951, 26, 59–86.
Goss, R.J. 1978. The Physiology of Growth. Academic Press, New York. pp. 210–223.
Gu Y, Sarnecki C, Aldape RA, Livingston DJ & Su MS. Cleavage of poly(ADP-ribose) polymerase by interleukin-1 beta converting enzyme and its homologs TX and Nedd-2, J Biol Chem, 1995, 270, 18715–18718.
Ishizaki Y, Voyvodic JT, Burne JF & Raff MC. Control of lens epithelial cell survival, J Cell Biol, 1993, 121, 899–908.
Ishizaki Y, Cheng L, Mudge AW & Raff MC. Programmed cell death by default in embryonic cells, fibroblasts, and cancer cells, Mol Biol Cell, 1995, 6, 1443–1458.[Abstract]
Jacobson MD, Weil M & Raff MC. Role of Ced-3/ICE-family proteases in staurosporine-induced programmed cell death, J Cell Biol, 1996, 133, 1041–1051.[Abstract]
Jacobson MD, Weil M & Raff MC. Programmed cell death in animal development, Cell, 1997, 88, 347–354.[Medline]
Kaufmann SH. Induction of endonucleolytic DNA cleavage in human acute myelogenous leukemia cells by etoposide, camptothecin, and other cytotoxic anticancer drugs: a cautionary note, Cancer Res, 1989, 49, 5870–5878.
Kaufmann SH, Desnoyers S, Ottaviano Y, Davidson NE & Poirier GG. Specific proteolytic cleavage of poly(ADP-ribose) polymerase: an early marker of chemotherapy-induced apoptosis, Cancer Res, 1993, 53, 3976–3985.
Kerr JFR, Wyllie AH & Currie AR. Apoptosis: a basic biological phenomenon with wide-ranging implication in tissue kinetics, Br J Cancer, 1972, 26, 239–257.[Medline]
Kuida K, Zheng TS, Na S, Kuan C-Y, Yang D, Karasuyama H, Rakic P & Flavell RA. Decreased apoptosis in the brain and premature lethality in CPP32-deficient mice, Nature, 1996, 384, 368–372.[Medline]
Kuwabara T & Imaizumi M. Denucleation process of the lens, Invest Ophthalmol, 1974, 13, 973–981.
Lamarre D, Talbot B, de Murcia G, Laplante C, Leduc Y, Mazen A & Poirier GG. Structural and functional analysis of poly(ADP ribose) polymerase: an immunological study, Biochim Biophys Acta, 1988, 950, 147–160.[Medline]
Lazebnik YA, Kaufmann SH, Desnoyers S, Poirier GG & Earnshaw WC. Cleavage of poly(ADP-ribose) polymerase by a proteinase with properties like ICE, Nature, 1994, 371, 346–347.[Medline]
Martin SJ & Green DR. Protease activation during apoptosis: death by a thousand cuts? , Cell, 1995, 82, 349–352.[Medline]
McAvoy JW. Induction of the eye lens, Differentiation, 1980, 17, 137–149.[Medline]
McAvoy JW & Richardson NA. Nuclear pyknosis during lens fiber differentiation in epithelial explants, Curr Eye Res, 1986, 5, 711–715.[Medline]
McAvoy JW, Chamberlain CG, de Iongh RU, Richardson NA & Lovicu FJ. The role of fibroblast growth factor in eye lens development, Annu NY Acad Sci, 1991, 638, 256–274.[Medline]
Modak SP & Perdue SW. Terminal lens cell differentiation. I. Histological and microspectrophotometric analysis of nuclear degeneration, Exp Cell Res, 1970, 59, 43–56.[Medline]
Morgenbesser SD, Williams BO, Jacks T & DePinho RA. p53- dependent apoptosis produced by Rb-deficiency in the developing mouse lens, Nature, 1994, 371, 72–74.[Medline]
Mosmann T. A rapid colorimetric assay for cellular growth and survival: application to proliferation and cytotoxicity assays, J Immunol Methods, 1983, 65, 55–63.[Medline]
Nataraj A, Pathak S, Hopwood V, McDonnell T & Ananthaswamy H. bcl-2 oncogene blocks differentiation and extends viability but does not immortalize normal human keratinocytes, Int J Oncology, 1994, 4, 1211–1218.
Nicholson DW, Ali A, Thornberry NA, Vaillancourt JP, Ding CK, Gallant M, Gareau Y, Griffin PR, Labelle M, Lazebnik YA et al.. Identification and inhibition of the ICE/CED-3 protease necessary for mammalian apoptosis, Nature, 1995, 376, 37–43.[Medline]
Orth K, Chinnaiyan AM, Garg M, Froelich CJ & Dixit VM. The CED-3/ICE-like protease Mch2 is activated during apoptosis and cleaves the death substrate lamin A, J Biol Chem, 1996, 271, 16443–16446.
Pan H & Griep AE. Altered cell cycle regulation in the lens of HPV-16 E6 or E7 transgenic mice: implications for tumor suppressor gene function in development, Genes Dev, 1994, 8, 1285–1299.
Peek R, McAvoy JW, Lubsen NH & Schoenmakers JG. Rise and fall of crystallin gene messenger levels during fibroblast growth factor induced terminal differentiation of lens cells, Dev Biol, 1992, 152, 152–160.[Medline]
Rasnick D. Synthesis of peptide fluoromethyl ketones and the inhibition of human cathepsin B, Anal Biochem, 1985, 149, 461–465.[Medline]
Robinson ML, MacMillan-Crow LA, Thompson JA & Overbeek PA. Expression of a truncated FGF receptor results in defective lens development in transgenic mice, Development (Camb), 1995, 121, 3959–3967.[Abstract]
Schlegel J, Peters I, Orrenius S, Miller DK, Thornberry NA, Yamin TT & Nicholson DW. CPP32/apopain is a key interleukin 1 beta converting enzyme-like protease involved in Fas-mediated apoptosis, J Biol Chem, 1996, 271, 1841–1844.
Takahashi A, Alnemri ES, Lazebnik YA, Fernandes-Alnemri T, Litwack G, Moir RD, Goldman RD, Poirier GG, Kaufmann SH & Earnshaw WC. Cleavage of lamin A by Mch2 alpha but not CPP32: multiple interleukin 1 beta-converting enzyme-related proteases with distinct substrate recognition properties are active in apoptosis, Proc Natl Acad Sci USA, 1996, 93, 8395–8400.
Tewari M, Quan LT, O'Rourke K, Desnoyers S, Zeng Z, Beidler DR, Poirier GG, Salvesen GS & Dixit VM. Yama/CPP32 beta, a mammalian homolog of CED-3, is a CrmA-inhibitable protease that cleaves the death substrate poly(ADP-ribose) polymerase, Cell, 1995, 81, 801–809.[Medline]
Weil M, Jacobson MD, Coles HSR, Davies TJ, Gardener RL, Raff KD & Raff MC. Constitutive expression of the machinery for programmed cell death, J Cell Biol, 1996, 133, 1053–1059.
Wyllie AH, Kerr JFR & Currie AR. Cell death: the significance of apoptosis, Int Rev Cytol, 1980, 68, 251–306.[Medline]
Yuan J, Shaham S, Ledoux S, Ellis HM & Horvitz HR. The C. eleganscell death gene ced-3 encodes a protein similar to mammalian interleukin-1 beta-converting enzyme, Cell, 1993, 75, 641–652.[Medline]
Zhu H, Fearnhead HO & Cohen GM. An ICE-like protease is a common mediator of apoptosis induced by diverse stimuli in human monocytic THP.1 cells, FEBS (Fed Eur Biochem Soc) Lett, 1995, 374, 303–308.
CiteULike 
Complore 
Connotea 
Del.icio.us 
Digg 
Facebook 
Reddit 
Technorati 
Twitter What's this?
This article has been cited by other articles:
| |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
|
|
