Suppression of Ultraviolet Irradiation-induced Apoptosis by Overexpression of Focal Adhesion Kinase in Madin-Darby Canine Kidney Cells*

Focal adhesion kinase (FAK) has been implicated to play a role in suppression of apoptosis. In this study, we have demonstrated that UV irradiation induced cleavage of FAK and two of its interacting proteins Src and p130Cas in Madin-Darby canine kidney cells, concomitant with an increase in cell death. The cleavage of these proteins upon UV irradiation was completely inhibited by ZVAD-FMK, a broad range inhibitor of caspases, and apparently delayed by Bcl2 overexpression. To examine if FAK plays a role in suppressing UV-induced apoptosis, stable Madin-Darby canine kidney cell lines overexpressing FAK were established. Our results showed that a marked (30–40%) increase in cell survival upon UV irradiation was achieved by this strategy. In our efforts to determine the mechanism by which FAK transduces survival signals to the downstream, we found that a FAK mutant deficient in binding to phosphatidylinositol 3-kinase failed to promote cell survival. Moreover, the expression of the Src homology 3 domain of p130Cas, which competed with endogenous p130Cas for FAK binding, abrogated the FAK-promoted cell survival. Together, these results suggest that the integrity of FAK and its binding to phosphatidylinositol 3-kinase and p130Cas are required for FAK to exert its antiapoptotic function.

Focal adhesion kinase (FAK), 1 a 125-kDa cytoplasmic tyrosine kinase localized in focal adhesions, is a key component in integrin-mediated signal transduction pathways (1)(2)(3). So far, FAK has been implicated to play an important role in regulating at least three aspects of cellular functions, including cell migration (4,5), cell cycle progression (6), and cell survival (7)(8)(9)(10). The ability of FAK to transduce signals to the downstream is believed to be dependent on its ability to interact with several intracellular signaling molecules including Src family kinases (11,12), phosphatidylinositol 3-kinase (PI3K; Ref. 13), Grb2 (14), and p130 Cas (15). It has been shown recently that two simultaneous bindings of PI3K and p130 Cas are required for FAK to promote cell migration on extracellular matrix proteins (16,17). However, it is not clear if any of these molecules are responsible for the function of FAK in cell cycle or cell survival.
Tyr-397 has been identified as the major site of FAK autophosphorylation (18) and the binding site for the Src homology 2 (SH2) domains of Src (11,12) and PI3K (19). The binding site for the SH2 domain of Grb2 has been mapped to Tyr-925 (20). The proline-rich sequence region of FAK (residues 712-718) has been identified as the major binding site for the SH3 domain of p130 Cas (15,21). A substitution of Tyr-397 with Phe was found to abrogate the binding of FAK to both Src and PI3K (19). To directly analyze the effect of the loss of PI3K binding on FAK's functions, a FAK mutant deficient only in PI3K binding has recently been introduced by a substitution of Asp-395 with Ala (17).
Several lines of evidence have suggested that FAK may have a function in promoting cell survival. Inhibition of FAK in fibroblasts by microinjection with anti-FAK antibodies or with a peptide corresponding to a region of ␤ 1 integrin cytoplasmic domain thought to be required for FAK binding results in apoptosis (7). Similarly, attenuation of FAK expression by antisense oligonucleotides induces apoptosis in tumor cells (8). Recently, Ilic et al. (9) suggested that survival signals from extracellular matrix transduced by FAK may suppress p53mediated apoptosis and showed that expression of a FAK Cterminal construct, the focal adhesion targeting (FAT) domain, induces apoptosis in primary fibroblasts. Finally, expression of the constitutively activated form of FAK (CD2-FAK) by anchoring it to the plasma membrane prevents epithelial cells from apoptosis upon cell detachment (10).
In this report, we have demonstrated that FAK is a target of caspases during UV-induced apoptosis and that overexpression of the wild-type (WT) FAK is capable of suppressing cell death upon UV irradiation. Moreover, we have found that inhibition of the association of FAK with PI3K or p130 Cas abrogates the ability of FAK to promote cell survival. Taken together, these results strongly suggest that signals transmitted through the associations of FAK with PI3K and p130 Cas are important for cell survival.

EXPERIMENTAL PROCEDURES
Expression Plasmids and Antibodies-The mammalian expression plasmid pKH3 encoding hemagglutinin (HA) epitope-tagged WT FAK or its mutants (D395A, Y397F, P712A/P715A, and Y925F) have been described previously (17). The plasmid pKH3-CasSH3 encoding the HA epitope-tagged SH3 domain of p130 Cas was kindly provided by Dr. J.-L. * This research was supported by National Health Research Institutes, Taiwan, Grant NHRI-GT-EX89S919C (to H.-C. C.) and National Science Council, Taiwan, Grant NSC88-2314-BO75A-016 (to C.-H. C.). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Cells and Transfections-MDCK cells, clone 3B5, were maintained in Dulbecco's modified Eagle's medium supplemented with 10% fetal bovine serum (Life Technologies, Inc.). To generate cells stably expressing HA epitope-tagged FAK, subconfluent MDCK cells grown on 60-mm dishes were co-transfected with 2 g of pKH3 plasmid encoding WT FAK or its mutant and 0.2 g of pSV2neo using 10 l of LipofectAMINE (Life Technologies, Inc.). Two days after transfection, cells were detached and replated on 100-mm dishes at an appropriate density in the medium containing 0.5 mg/ml of G418 (Calbiochem). After approximately 14 days, neomycin-resistant cell clones were picked using cloning cylinders and screened for exogenous FAK expression by immunoblotting using monoclonal antibody anti-HA. Multiple positive clones were obtained for further analysis for each FAK constructs. Stable MDCK cells overexpressing Bcl2 have been described previously (22) and were maintained in G418-containing medium.
To generate MDCK cells stably expressing both FAK and CasSH3, WT cells were transfected as described above using LipofectAMINE, 2 g of pKH3-CasSH3, and 0.2 g of pREP3. Clones were selected in growth medium containing 0.5 mg/ml G418 and 125 units/ml Hygromycin B (Calbiochem) and screened for FAK and CasSH3 expression by immunoblotting with anti-HA.
UV Irradiation, Treatment of Caspase Inhibitors, and Determinations of Cell Survival and Apoptotic Index-For UV irradiation, MDCK cells were plated at 10 6 per 60-mm culture dish in growth medium. After 12 h, the medium was reduced to 1 ml/dish, and culture dishes were uncovered in an UV cross-linker (model UVC-508, ULTRA-LUM Inc., Carson, CA). UV irradiation was carried out with 10 mJ/cm 2 for 1 min. Following irradiation, 2 ml of growth medium was added, and the cells were incubated at 37°C for the indicated times in a CO 2 incubator. For some experiments, cells were pretreated with 40 M caspase inhibitor ZVAD-FMK or DEVD-CHO (Takara Shuzo Co., Shiga, Japan) for 1 h. Following UV irradiation, cells were incubated in growth medium with freshly added caspase inhibitor for 12 h.
Cell viability was determined by trypan blue exclusion. Briefly, UVirradiated cells were collected and washed once with phosphate-buffered saline. Cell suspensions in phosphate-buffered saline were mixed with an equal volume of 0.4% trypan blue (Sigma), and cells excluding dye were counted with a hemocytometer. Cell survival was expressed as the percentage of live cells remaining after UV irradiation compared with the cell number at the time right before UV irradiation.
For nuclear staining, cells (10 4 ) were plated on glass coverslips for 16 h and then exposed to UV radiation. After 4 h, coverslips were washed with phosphate-buffered saline, fixed in 4% paraformaldehyde, and stained with 0.5 g/ml Hoechst 33258 (Sigma). Normal nuclei and apoptotic nuclei comprising those with fragmented nuclei and condensed chromatin in 10 randomly chosen fields were counted under a fluorescent microscope at ϫ 40 magnification. Apoptotic index was expressed as the percentage of apoptotic nuclei in total counted (200 -300) nuclei.
Immunoprecipitations, Immunoblotting, and in Vitro Kinase Assays-To analyze protein cleavage, UV-irradiated cells were collected and lysed in 1% Nonidet P-40 lysis buffer containing protease inhibitors as described previously (23). An equal amount (50 g) of lysates was resolved by SDS-polyacrylamide gel electrophoresis and analyzed by immunoblotting with anti-FAK, anti-p130 Cas , anti-Src, anti-p85, or anti-HA using the Amersham Pharmacia Biotech chemiluminescence system for detection.
To measure the PI3K activity associated with ectopically expressed FAK proteins in MDCK cells, epitope-tagged FAK proteins were immunoprecipitated with anti-HA from MDCK cell lysates (700 g) and subjected to an in vitro PI3K assay as described previously (13).
To detect the association of epitope-tagged FAK with endogenous p130 Cas in MDCK cells, lysates (500 g) were incubated with polyclonal anti-p130 Cas . The immunocomplexes were washed with 1% Nonidet P-40 lysis buffer and analyzed by immunoblotting with anti-HA.

RESULTS
A proteolytic cleavage of FAK has been observed during apoptosis induced by serum deprivation (24), the addition of Fas ligand/Apo-2L (25), overexpression of c-Myc (26), and treatment of certain chemicals such as staurosporine (27). In this report, we have examined if FAK cleavage also occurs during UV-induced apoptosis. Similar to other apoptotic stimuli as described above, UV irradiation induced a sequential cleavage of FAK into two fragments in MDCK cells, which was concomitant with a decrease in cell survival (Fig. 1). The first cleavage product of the 85-kDa fragment was detected as early as 6 h after UV irradiation, and the second cleavage product of 77-kDa fragment was detected 3 h later. Twenty-four hours after UV irradiation, dead cells accounted for more than 95% of the total cell population in which the intact FAK was not detected, and only the 77-kDa fragment remained. In addition to FAK, we also examined if other cellular proteins that are known to interact with FAK undergo cleavage during UV-induced apoptosis ( Fig. 1). Among these proteins, we found that the amount of p130 Cas was gradually decreased 6 h after UV irradiation, presumably due to a proteolytic cleavage, and finally disappeared at 24 h. In addition, the cleavage of Src upon UV irradiation was found to generate an approximately 50-kDa fragment. Interestingly, a significant amount of Src remained intact 24 h after UV irradiation, indicating that Src was only partially cleaved during the apoptotic response. In contrast, the level of four other FAK-interacting proteins including the p85 subunit of PI3K (Fig. 1), Grb2, paxillin, and talin had no detectable change during UV-induced apoptosis (data not shown).
To examine if caspases are involved in the cleavage of FAK, p130 Cas , and Src during UV-induced apoptosis, UV-exposed MDCK cells were incubated with tetrapeptide caspase inhibitors, ZVAD-FMK or DEVD-CHO ( Fig. 2A). ZVAD-FMK, a general inhibitor of cysteine proteases, completely blocked cleavage of FAK, p130 Cas , and Src, and significantly (ϳ30%) increased cell survival upon UV irradiation. DEVD-CHO, a specific inhibitor of caspase-3, at a concentration of 40 M was able to completely block Src cleavage but only partially inhibit the cleavage of FAK and p130 Cas . These results suggest that the cleavage of FAK and p130 Cas is likely to be mediated by FIG. 1. Cleavage of FAK and its interacting proteins during UV-induced apoptosis. MDCK cells were exposed to UV radiation with 10 mJ/cm 2 for 1 min. After various times as indicated, live cells were determined by trypan blue exclusion. Cell survival is expressed as the percentage of live cells remaining compared with the cell number at the time right before UV irradiation (0 h), which is defined as 100%.
Values are the average of three independent experiments. To examine protein cleavage, an equal amount (50 g) of lysates prepared from UV-irradiated cells was analyzed by immunoblotting with anti-FAK, anti-p130 Cas , anti-Src, or anti-p85. more than one member of caspase family during UV irradiation-induced apoptosis.
The expression of Bcl2 has been shown to suppress apoptosis by inhibiting the activation of caspases (28,29). To determine whether Bcl2 blocks FAK cleavage in response to UV irradiation, stable MDCK cell lines overexpressing Bcl2 were established (22). The expression level of ectopic Bcl2 in MDCK cells was at least 10-fold higher than endogenous Bcl2 (data not shown). The Bcl2-overexpressed (Bcl2) cells and control (Neo) cells were exposed to UV radiation and then analyzed for FAK cleavage after various time intervals. The results showed that overexpression of Bcl2 in MDCK cells apparently delayed FAK cleavage upon UV irradiation (Fig. 2B). The first FAK cleavage product of the 85-kDa fragment appeared at 12 h after UV irradiation in Bcl2-overexpressed cells, which was an approximately 6-h delay compared with control cells. Consistent with the results from parental MDCK cells (Fig. 1), no intact FAK could be detected in Neo control cells 24 h after UV irradiation.
Notably, at this time point, a significant amount of intact FAK still remained in Bcl2-overexpressed cells.
To examine if FAK plays a role in preventing UV-induced cell death, stable MDCK cell lines overexpressing HA-tagged FAK (WT) were established. The expression level of ectopic FAK in MDCK cells was approximately 2.5-fold of endogenous FAK (Fig. 3A). Cells from three WT clones and a control (Neo) clone were exposed to UV radiation, and their survival rates were determined after various time intervals. The results showed that, 9, 12, or 24 h after UV irradiation, the survival rate of WT cells was significantly (30 -40%) higher than that of control cells (Fig. 3B). To further confirm the antiapoptotic effect of FAK in this system, other apoptotic characteristics were analyzed. The Hoechst staining showed that, 4 h after UV irradiation, control cells contained a higher number of apoptotic nuclei, manifested by shrunken and fragmented nuclear morphology and condensed chromatin, than WT cells (Fig. 3C). The DNA laddering assays indicated that control cells also exhibited a more severe DNA fragmentation than WT cells upon UV irradiation (data not shown). Together, these data indicate that overexpression of FAK is able to suppress UV-induced apoptosis. A simple explanation for WT cells being more resistant to UV irradiation is that more intact FAK proteins retained in WT  Fig. 1. Survival of cells without UV irradiation and inhibitor treatment is defined as 100%. Values are the average of two independent experiments. B, an equal amount (50 g) of lysates prepared from a control (Neo) clone or a MDCK cell clone overexpressing Bcl2 were exposed to UV radiation. After indicated times, the cleavage of FAK was analyzed as described in the legend to Fig. 1.   FIG. 3. Suppression of UV irradiation-induced apoptosis by FAK overexpression. A, an equal amount (50 g) of lysates prepared from a control (Neo) clone or three independent MDCK cell clones overexpressing HA-tagged WT FAK (designated WT-1, WT-2, and WT-3) was analyzed by immunoblotting with anti-HA or anti-FAK. B, control and WT cells were exposed to UV radiation, and cell survivals were measured as described in the legend to Fig. 1. Data (means Ϯ S.E.) are from five independent experiments. C, control and WT cells were exposed to UV and then visualized with Hoechst 33258 dye for nucleus 4 h after UV irradiation, as described under "Experimental Procedures." Apoptotic nuclei comprising those with fragmented nuclei (arrows) and condensed chromatin (arrowheads) were counted. The apoptotic index is expressed as the percentage of apoptotic nuclei in total counted nuclei. Values are the average of two independent experiments. D, control and WT cells were exposed to UV radiation and then analyzed for FAK cleavage 9 h afterwards, as described in the legend to Fig. 1. cells than in Neo cells within a period of time after UV irradiation. To examine this, the cleavage of FAK in WT and Neo cells were analyzed 9 h after UV irradiation (Fig. 3D). The result clearly supports our assumption and suggests that the ability of FAK to exert its antiapoptotic function may first rely on its intact structure.
To investigate the mechanisms by which FAK transmits survival signals downstream, stable MDCK cell lines overexpressing FAK mutants including D395A, Y397F, P712A/ P715A, and Y925F, deficient in binding to PI3K, Src, p130 Cas , and Grb2, respectively, were established. The expression levels of these FAK mutants were comparable with WT FAK (Fig. 4B, top) and all localized in focal contacts (data not shown). Interestingly, all of these FAK mutants failed to promote cell survival upon UV irradiation (Fig. 4A). To examine if these ectopically expressed FAK proteins had a similar rate in their decay, presumably caused by caspase-mediated cleavage, these stable MDCK cell lines were exposed to UV radiation and lysed 4 or 6 h afterwards. Surprisingly, the decay rates of FAK Y397F, P712A/P715A, and Y925F mutants were much faster than those in both WT FAK and D395A mutant, which were similar in their rates of decay (Fig. 4B). Six hours after UV irradiation, HA-tagged FAK proteins were markedly lowered in Y397F, P712A/P715A, and Y925F cells. Conversely, a substantial amount of HA-tagged FAK proteins still remained intact in WT FAK and D395A cells at this time point. Thus, it is possible that the failure of FAK Y397F, P712A/P715A, and Y925F mutants in promoting cell survival is because of their fast decay rates rather than deficiency in particular protein binding. Nevertheless, the result showing FAK D395A failed to promote cell survival suggested that PI3K binding might be required for FAK to promote cell survival (see below).
Consistent with our previous result (17), FAK D395A mutant expressed in MDCK cells was able to bind Src and p130 Cas and exhibited a level of tyrosine phosphorylation and in vitro autophosphorylation similar to WT FAK (data not shown). These results indicated that the amino acid substitution in D395A mutant did not cause a change in its conformation. Moreover, because D395A mutant has been shown to be deficient in binding to PI3K in vitro and in Chinese hamster cells (17), our results here strongly suggest that the direct binding of PI3K to FAK may be required for FAK to promote cell survival. To confirm this, the association of endogenous PI3K with WT FAK and D395A mutant upon UV irradiation in MDCK cells was examined (Fig. 4C). The level of PI3K activity associated with WT FAK was higher (ϳ7-fold) than that associated with D395A mutant in MDCK cells. Although some residual binding of PI3K to FAK D395A mutant was detected, it was apparently not sufficient for promoting cell survival in this system.
It has previously been shown that associations of PI3K and p130 Cas are required for FAK to promote cell migration (16,17). To examine if direct association of p130 Cas with FAK is also critical for FAK to suppress cell death induced by UV irradiation, the HA-tagged SH3 domain of p130 Cas (CasSH3) was stably expressed in MDCK cells that had already expressed HA-tagged FAK. CasSH3 was expected to function as a dominant-negative version of p130 Cas by competing with endogenous p130 Cas for FAK binding. The expression level of HAtagged FAK in cells (WT/CasSH3) expressing both FAK and CasSH3 was similar to that in WT cells (Fig. 5A). Next, we examined the effect of CasSH3 expression on FAK associations with p130 Cas and PI3K. The results showed that the association of endogenous p130 Cas with HA-tagged FAK was significantly reduced in WT/CasSH3 cells (Fig. 5B). Conversely, the association of PI3K with HA-tagged FAK was not affected by CasSH3 expression (data not shown). Importantly, we found that WT/CasSH3 clones exhibited a lower cell survival rate than WT cells upon UV irradiation (Fig. 5C), indicating that, in addition to PI3K, p130 Cas binding may be also required for FAK to promote cell survival. DISCUSSION In this report, first we showed a sequential cleavage of FAK during UV-induced apoptosis. Because FAK cleavage is also triggered by other apoptotic stimuli in various cell types (24 -27), it is possible that this proteolytic event is a general phenomenon in apoptosis and plays an important role in the execution of the suicide pathway. The cleavage of FAK during UV-induced apoptosis was completely inhibited by a general caspase inhibitor ZVAD-FMK and apparently delayed by Bcl2 expression, suggesting an involvement of caspases in this event. In fact, several members of the caspase family have been shown to directly cleave FAK in vitro (25,27). Notably, the patterns of FAK cleavage in various cell types undergoing apoptosis induced by UV irradiation (Fig. 1) or other stimuli (24 -27) were very similar, indicating that a similar, if not the same, set of caspases may be responsible for FAK cleavage in response to various apoptotic stimuli.
Among known FAK-interacting proteins, we found that Src and p130 Cas were cleaved during UV-induced apoptosis. The cleavage of Src could be completely blocked by a caspase-3 FIG. 4. Requirement of PI3K binding for FAK to promote cell survival. A, control (Neo) cells or MDCK cells overexpressing HAtagged WT FAK, D395A, P712A/P715A, or Y925F were exposed to UV radiation, and their survival rates were determined 9 h afterwards. Data (means Ϯ S.E.) are from at least nine independent experiments using three independent cell clones for each FAK construct. B, the cells as described in A were exposed UV radiation and lysed 4 or 6 h afterwards. An equal amount of lysates was then analyzed by immunoblotting with anti-HA. C, an aliquot (700 g) of lysates from Neo, WT, or D395A cells that were lysed 6 h after UV irradiation was incubated with anti-HA. The immunocomplexes were then subjected to an in vitro assay for PI3K activity, as described under "Experimental Procedures." The locations of the origin (Ori) and phosphatidylinositol 3-phosphate (PIP) are indicated at the right.
inhibitor DEVD-CHO at 40 M, which could only partially inhibit cleavage of FAK and p130 Cas (Fig. 2). These results suggest that only caspase-3-like caspase(s) may be responsible for Src cleavage during UV-induced apoptosis. Moreover, our results showed that a substantial amount of Src remained intact 24 h (Fig. 1) or even 36 h (data not shown) after UV irradiation, indicating that Src cleavage occurred only in part of its fractions. Src is mainly a membrane protein, anchored via an N-terminal myristic acid and neighboring positively charged amino acids (30). To examine if membrane association protects Src from caspase-mediated cleavage, we carried out subcellular fractionation for UV-irradiated MDCK cells. Our preliminary results showed that Src cleavage was observed in cytosol fractions, but not in membrane fractions (data not shown). These results raise an intriguing possibility that, in addition to the presence of specific motifs in substrates for caspase recognition, subcellular localization and/or membrane anchorage of caspase substrates may have some impact on the execution of the proteolysis.
In this study, we have established stable MDCK cell lines overexpressing FAK or its mutants deficient in binding to PI3K, Src, p130 Cas , or Grb2. Surprisingly, these ectopically expressed FAK proteins exhibited different rates in their decay during UV-induced apoptosis (Fig. 4), presumably due to a caspase-mediated cleavage. It appeared that Y397F, P712A/ P715A, and Y925F mutants had a faster decay rate than both WT FAK and D395A mutant, which were similar in their rates of decay. Although the reason for this is unclear at present, it is possible that protein-protein interactions may lead to a mask of caspase recognition motifs on FAK or block the access of caspase to FAK, thereby tentatively protecting FAK from cleavage. Alternatively, the amino acid substitutions in FAK mutants Y397F, P712A/P715A, or Y925F may cause a change in protein conformation, leading to protein less stable regardless of UV irradiation. The latter possibility was excluded by our observation that all FAK mutants used in this study had a turnover rate similar to WT without UV irradiation (data not shown). It is noteworthy that, like WT, all FAK mutants described in this report targeted to focal adhesions (data not shown), rendering it unlikely that a faster decay rate for certain FAK mutants is due to an incorrect subcellular localization.
Despite the fact that expression of the constitutively activated form of FAK rescues MDCK cells from apoptosis induced by the disruption of cell-matrix interactions (10), here we show the first time that expression of WT FAK can significantly (30 -40%) promote cell survival upon UV irradiation (Fig. 3). In addition to UV irradiation, these FAK-overexpressed cells were also found to be more resistant to some tested apoptotic stimuli, such as treatment of cyclohexamide and loss of cell-matrix adhesion (data not shown). Using this system, we further showed that a PI3K binding-deficient mutant (D395A) that had a decay rate similar to WT FAK upon UV irradiation failed to promote cell survival (Fig. 4). Because, except for deficiency in PI3K binding, no other changes could be detected for the D395A mutant, including the ability to bind other FAK-interacting proteins and the level of tyrosine phosphorylation and in vitro kinase activity, our results strongly suggest that PI3K binding is required for FAK to promote cell survival. In fact, an increased association of FAK with PI3K and a subsequent activation of Akt have been observed in hydrogen peroxideinduced apoptosis in human glioblastoma cells (31). This and our results are consistent with other work showing the importance of PI3K in promoting cell survival (32)(33)(34).
Although a FAK mutant (P712A/P715A) deficient in p130 Cas binding failed to promote cell survival upon UV irradiation, we could not conclude that p130 Cas binding is required for FAK to promote cell survival because of the fast decay rate of this mutant during UV-induced apoptosis (Fig. 4). Thus, we employed another strategy to examine the potential role of p130 Cas in FAK-promoted cell survival. We showed that expression of the SH3 domain of p130 Cas was able to interfere with FAK-p130 Cas association and to suppress cell survival promoted by FAK overexpression (Fig. 5). These results suggest that, in addition to PI3K, p130 Cas binding is also required for FAK to promote cell survival. Ilic et al. (9) showed that two FAK C-terminal constructs, FAK-related nonkinase and the FAT domain, were localized in focal adhesions and displaced endogenous FAK from these sites, but only the FAT domain was able to abrogate the function of FAK to transduce survival signals from fibronectin. These results suggest that FAK-related nonkinase, but not the FAT domain, may contain sequences required for FAK to promote cell survival. A comparison between these two constructs revealed that an N-terminal region of FAK-related nonkinase comprising a proline-rich sequence for p130 Cas binding was not present in the FAT domain, supporting the notion that p130 Cas binding is required for FAK to promote cell survival. In fact, it has been proposed that the initial cleavage of FAK at Asp-772 by caspase-3-like proteases may generate a FAK C-terminal fragment corresponding to the , an equal amount (500 g) of lysates from the cells as described in A was incubated with anti-p130 Cas . The immunocomplexes were analyzed by immunoblotting with anti-HA or anti-p130 Cas . C, survival rates of the cells as described in A were determined 9 h after UV irradiation, as described in the legend to Fig. 1. FAT domain, which may act as a competitive inhibitor for the remaining intact FAK during apoptosis (27).
The adaptor protein p130 Cas was originally identified as a major tyrosine-phosphorylated protein in cells transformed by either v-src (35)(36)(37) or v-crk (38 -40). Its association with another adaptor protein Crk has been shown to play an important role in promoting cell migration (41). Our results in this report imply that p130 Cas may also have a function in regulating cell survival. It has recently been shown that p130 Cas -Crk association further leads to activation of c-Jun N-terminal kinase via small GTP-binding protein Rac (42,43). It will be of interest to determine the potential connection between the c-Jun N-terminal kinase activation and p130 Cas -mediated cell migration and/or cell survival.
Because the effect of FAK on the suppression of UV-induced apoptosis is limited (ϳ30%), apparently other survival factors against UV-induced apoptosis are present. In fact, the first cellular response detectable in UV-irradiated cells is the tyrosine phosphorylation of different cell membrane growth factor receptors (44). It has been shown that UV rapidly induces activation of Ras, Src, and other molecules located at or near the plasma membrane (45,46) and inhibition of tyrosine phosphatases (47), leading to signaling and to transcription of UVresponsive genes. Recently, the atypical protein kinase C (PKC) isoforms, PKC and PKC/, have been suggested to play a protective role in UV-induced apoptosis (48,49). It was found that overexpression of PKC and PKC/ inhibited UV-induced cell death, whereas exposure of cells to UV radiation leads to a dramatic reduction of PKC activity (48). Furthermore, it is known that UV irradiation potently activates c-Jun N-terminal kinase (50). The UV-induced c-Jun N-terminal kinase activation has also been suggested to trigger a protective response through the activation of genes coding for protective proteins (45,50,51). Therefore, the signaling cascades induced by UV radiation appear to be complex and involve many different molecules. Some of them promote survival, whereas others promote cell death. The relationship between FAK and other survival factors in UV-induced apoptosis remains to be investigated.