Modulation of Cell Death in Yeast by the Bcl-2 Family of Proteins*

(Received for publication, February 27, 1997)

Weikang Tao Dagger §, Cornelia Kurschner Dagger and James I. Morgan Dagger

From the Dagger  Department of Developmental Neurobiology, St. Jude Children's Research Hospital, Memphis, Tennessee 38105 and the § Department of Biochemistry and Molecular Biology, University of Medicine and Dentistry of New Jersey-Graduate School of Biochemical Sciences, Newark, New Jersey 07103

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCedURES
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES


ABSTRACT

Bcl-2 family members are regulators of cell death. The precise biochemical properties of these proteins are unclear although intrafamily protein-protein association is thought to be involved. To elucidate structure-activity relationships among Bcl-2 proteins and identify the pathways in which they act, an inducible death suppressor assay was developed in yeast. Only Bax and Bak killed yeast via a process that did not require interleukin-1beta -converting enzyme-like proteases. Bax/Bak lethality was suppressed by coexpression of Bcl-2 family members that are anti-apoptotic in vertebrates, namely Bcl-xL, Bcl-2, Mcl-1, and A1. Furthermore, Bcl-xL and Bcl-2 suppressed Bax toxicity by distinct mechanisms in yeast. Bad, Bcl-xS, and Ced-9 lacked suppressor activity. These inactive proteins bound to anti-apoptotic members of the Bcl-2 family but not to Bax or Bak. In contrast, most Bcl-2 family proteins that attenuated death bound to Bax and Bak. However, two mutants of Bcl-xL suppressed Bax-induced cell death while having no Bax binding activity. Therefore, Bcl-xL functions independently of Bax binding, perhaps by interacting with a common target or promoting a pathway that antagonizes Bax. Thus, the pathways downstream of Bax and Bcl-xL may be conserved between vertebrates and yeast. This suppressor assay could be used to isolate components of these pathways.


INTRODUCTION

Cell death is a highly regulated process involving interactions among extracellular molecules, intracellular signal transduction pathways, and resident suicide/rescue programs (1, 2). Studies in Caenorhabditis elegans have pointed to a cell suicide pathway that includes several molecules that have homologs in vertebrates (3). Central among these death-regulating proteins is Ced-9, which suppresses programmed cell death in C. elegans (4). Bcl-2, the vertebrate homolog of Ced-9, was identified independently through its translocation in many B cell follicular lymphomas in man (5, 6). Bcl-2 inhibits cell death in various circumstances in vertebrate cells and functionally substitutes for Ced-9 in C. elegans (7, 8). Subsequent investigations have identified a number of proteins in vertebrates that are structurally related to Bcl-2 (7). These proteins constitute a family, the members of which share a number of regions of homology, termed BH1 (Bcl-2 homology), BH2, and BH3 domains (9, 10). Some of these Bcl-2 related proteins, such as Bcl-xL, also prevent cell death, whereas others, such as Bax, provoke cell elimination. The biochemical and biophysical mechanisms that confer these properties on the Bcl-2 family of proteins remain enigmatic, although recent structural data suggest that they may be pore-forming proteins (11). However, Bcl-2 and many of its related proteins can participate in homo- and heteromeric complexes, and it has been suggested that the activity of pro-apoptotic members of the Bcl-2 family is neutralized by their association with anti-apoptotic members (12, 13).

There are a number of caveats in the interpretation of the role of Bcl-2 family members in the regulation of cell death in vertebrates. First, the effects of Bcl-2 family members are often assessed in models where cell death is triggered by an exogenous means such as growth factor withdrawal or addition of a toxin or virus to the culture medium. While this is more relevant to the physiological situation, it adds a level of ambiguity as to whether the effects are mediated through intrafamily interactions. Second, a given cell type may already express the gene of interest as well as other known and potentially unknown members of the Bcl-2 family. Thus, there is uncertainty as to precisely which proteins interact to produce the observed effect. Finally, Bcl-2 family members are differentially expressed, and bcl-2- and bcl-x-null mice have distinct phenotypes (14, 15). Together, these data imply that the various Bcl-2-like proteins have functional differences. Indeed, there are indications that Bcl-xL need not dimerize with Bax to suppress cell killing and that Bcl-2 and Bcl-xL have differential activities in some assays (14-18). Thus, from the mechanistic standpoint, there is a need for a model in which the role of Bcl-2 family members in cell death can be determined without the foregoing ambiguities.

Recently, several studies reported that the expression of Bax is lethal in the budding yeast, Saccharomyces cerevisiae (19-21). This is despite the fact that yeasts express no identifiable members of the Bcl-2 family and are not known to undergo programmed cell death. This afforded the opportunity to develop a suppressor assay in which the ability of Bcl-2 family members to attenuate Bax killing could be determined quantitatively. Moreover, since the model is in essence the same as a two-hybrid system, protein-protein association can be assessed simultaneously.

It is shown that Bcl-2, Bcl-xL, Mcl-1, and A1 can suppress death induced by Bax and Bak in yeast, whereas Ced-9, Bad, and Bcl-xS are inactive. Bcl-2 and Bcl-xL do not have identical structure-activity relationships for death suppression in yeast, indicating that they have distinct modes of action. Moreover, several Bcl-xL mutants suppressed Bax lethality without binding to Bax, indicating that Bcl-xL can function by a mechanism other than direct association with Bax. This implies that mechanisms downstream of Bcl-xL and Bax are conserved in yeast and that this system could be used to isolate these molecules.


EXPERIMENTAL PROCedURES

Yeast Strains, Growth, and Transformation

The S. cerevisiae strain S260 (ura3 trp1) contained a genomic LEXA-operator-LACZ fusion reporter gene and was described previously (22). Yeast growth, maintenance, and transformations were as described (23).

Yeast Expression Constructs

Fusion proteins with the LexA DNA binding domain were constructed in the yeast expression plasmid, Y.LexA (22), which carries the S. cerevisiae TRP1 gene as a selectable marker. Fusion proteins with the VP16 transcriptional activation domain were generated in pSD.10a, which harbors the URA3 selection marker (24). Constructs lacking heterologous fusion sequences were made in pSD.10a after deletion of the VP16 codons.

LexA and VP16 fusions of murine Bax, Bcl-2, and A1 were reported previously (22). cDNAs encoding murine Bcl-x, Bak, and Bad were obtained by reverse transcription polymerase chain reaction using mouse brain RNA and polymerase chain reaction primers based upon published sequences. Murine mcl-1 cDNA was isolated in a yeast two-hybrid screening for Bax-binding proteins.1 A Ced-9 cDNA was a gift from Dr. M. O. Hengartner, and plasmid p996 containing a crmA cDNA (25) was a gift from Dr. D. Pickup. Truncation and deletion mutants were generated by polymerase chain reaction. The sequences of all constructs were verified.

In Vitro Translation Constructs

For in vitro transcription/translation reactions, cDNAs encoding full-length Bcl-xL and two of its mutants (XF14 and XF15) were inserted into the vector pT7beta plink (24). A full-length murine bax cDNA was cloned in pT7beta plink-TagN (22). In this construct, an epitope tag derived from human c-MYC protein is fused to the N terminus of Bax. This epitope is recognized by the monoclonal antibody 9E10.

Coimmunoprecipitation

Proteins were translated in vitro as described (22). MYC-tagged Bax was translated in the absence of [35S]methionine (Amersham Life Science, Inc.), and untagged Bcl-xL and its mutants XF14 and XF15 were translated in the presence of [35S]methionine. For coimmunoprecipitations, 2 µl of the Bax-MYC translation reaction were mixed with 10 µl of the Bcl-xL, XF14, or XF15 translation reactions, respectively. Incubation and washing steps were performed as described (26) in NETgel buffer with 0.2% Nonidet P-40. The precipitating antibody was 9E10 (Santa Cruz Biotechnology, Inc.). Protein A-Sepharose CL-4B (Sigma) was used to precipitate the immune complexes.

Yeast Two-hybrid Analysis

S260 was transformed with two plasmids encoding a LexA fusion construct and a VP16 hybrid. Transformants were grown and assayed for beta -galactosidase activity as described (22). The development of blue color in the yeast colonies was monitored for 24 h.

Yeast Growth Assay

S260 was (co)transformed with expression plasmids encoding Bcl-2 family members. Selective media containing 2% glucose was inoculated with a single colony of transformants and incubated overnight at 30 °C. Subsequently, cells were washed three times with H2O. Typically, 20 ml of selective medium (with 2% galactose) was inoculated with 2.56 × 107 cells, and incubation was continued. Samples were taken at different time points, and cell density was measured by determining the OD at 660 nm. To compare results from different experiments, a growth index (GI)2 was devised. (OD660/22 h - OD660/0 h (cells containing Bax or Bak and the test protein))/(OD660/22 h - OD660/0 h (cells containing Bax or Bak and LexA or VP16)).

Immunoblotting

Yeast cells were lysed mechanically as described (26). Proteins were separated on 15% SDS-polyacrylamide gels (30 µg/lane) and transferred to nitrocellulose membranes. Immunostaining was performed in Tris-buffered saline containing 1% fetal calf serum at room temperature. Membranes were incubated with a rabbit anti-murine Bax polyclonal antibody, 13686E (1:1000 dilution) (Pharmingen), followed by horseradish peroxidase-conjugated goat anti-rabbit immunoglobulin antiserum (1:1000) (Amersham), both for 2 h. Immunoblots were developed using diaminobenzidine as chromogen (27). For Bcl-xL immunostaining, the membrane was stripped of bound antibody, reprobed with a monoclonal anti-Bcl-x antibody, B22620 (1:250) (Transduction Laboratories). The immunoblots were developed using the enhanced chemiluminescence method (Amersham).


RESULTS

Identification of Members of the Bcl-2 Family That Are Lethal in Yeast

Since Bax kills yeast (19-21), additional members of the Bcl-2 family (Bcl-2, Bcl-xL, Bcl-xS, A1, Mcl-1, Bad, Bak, and Ced-9) were tested for this property. Besides Bax, only Bak was lethal, although it was consistently less potent (Table I). Moreover, like native Bax, the LexA and VP16 fusion proteins of Bax and Bak used in the two-hybrid assay were also lethal (Fig. 1, A and B, and Table I), making it possible to correlate binding activity with biological activity in subsequent studies.

Table I. Relationship between heterodimerization and suppression of cell death for Bcl-2 family members in yeast

S260 yeast were cotransformed with either VP16-fused Bax or Bak and one of the indicated Bcl-2 family members fused to LexA. Association between the proteins was determined by the two-hybrid assay. +, blue colony within 1 h; -, no blue colony after 24 h. The death-suppressive activities of the Bcl-2 family members were determined in the yeast growth assay. GI values are indicated. ND, not done; NA, not applicable. The data shown are representative of three independent experiments.

Y.LexA Bcl-2 Bcl-xL Bcl-xS A1 Mcl-1 Bad Ced-9 Bax Bak

Bax
  Binding  - + +  - + +  -  - + +
  Suppression 1.00  5.18  5.55 1.01  3.60  8.05 0.82 1.10 NA ND
Bak
  Binding  - + +  - + +  -  - + +
  Suppression 1.00 29.15 29.87 0.97 27.75 28.44 1.24 1.12 0.13 NA


Fig. 1. Bcl-xL suppresses Bax-induced lethality in yeast. A, yeasts were transformed with plasmids encoding LexA, LexA-Bax, LexA-Bax and Bcl-xL, or LexA-Bax and VP16. Cell density was determined at various time intervals by measuring OD660. B, yeasts were transformed with plasmids encoding VP16, Bax, Bax and LexA, or Bax and LexA-Bcl-xL. Growth was assessed at various times by measuring OD660. The data are representative curves that were repeated a minimum of three times.
[View Larger Version of this Image (18K GIF file)]

Suppression of Bax- and Bak-induced Lethality by Bcl-2 Family Members

To quantitatively determine the suppression of Bax/Bak toxicity in yeast, cDNAs encoding LexA or VP16 fusions of various Bcl-2 family members were coexpressed with either Bax or Bak. Coexpression of the Bcl-xL fusion proteins generated for the two-hybrid system inhibited Bax and Bak toxicity (Fig. 1A and Table I). In addition, LexA fusions of Bcl-2, Mcl-1, and A1 inhibited both Bax and Bak killing (Fig. 2 and Table I). Bcl-xS, Bad, and Ced-9 did not attenuate Bax or Bak lethality (Table I). To ensure that the results were not artifacts of LexA or VP16 fusion proteins, these data were confirmed using native (unfused) protein sequences. Both native Bcl-2 (GI, 7.4) and native Bcl-xL (GI, 8.0) suppressed the killing elicited by native Bax (GI, 1.0).


Fig. 2. Structure-activity relationships for Bcl-xL and Bcl-2 binding to Bax and suppression of Bax lethality in yeast. Panel A, yeasts were transformed with Bax and an additional plasmid encoding LexA, LexA-Bcl-xL, or a LexA fusion of a mutated Bcl-xL. Growth was assessed after 22 h by measuring cell density at OD660 and is expressed as Growth Index (see "Experimental Procedures" for details). The binding of the LexA fusion proteins to VP16-Bax was determined using the two-hybrid assay. Colonies that turned blue within 1 h were scored as positive (+), whereas those that were still white at 24 h were considered negative (-). Three mutants were negative at 1 h but weakly positive at 3 h when present as LexA fusions but were negative at 24 h when present as VP16 fusions. These clones were scored as having marginal Bax binding activity (±). The structures of the various Bcl-xL mutants are shown at the left. The major Bcl-2 homology (BH) domains as well as the transmembrane region (TM) are indicated by shaded boxes. The numbers over the constructs refer to the respective amino acids in the full-length Bcl-xL sequence that define particular mutants. In one mutant, XF15, amino acids 26-82 were deleted and replaced with the sequence AAAAVAAAA (amino acid single letter code) (A4VA4). The data shown are representative of three independent experiments. Panel B, the same series of VP16-Bax binding and suppression experiments were performed for Bcl-2 and a number of its mutants. Details of the growth and two-hybrid assays are as for panel A, as are domain nomenclature and amino acid numbering. In one Bcl-2 mutant, BF6, residues 32-87 were deleted and replaced with four alanines (A4).
[View Larger Version of this Image (18K GIF file)]

Relationship between the Anti-death Activity of Bcl-2 Family Members and Their Binding to Bax and Bak

In the yeast two-hybrid assay, Bcl-xL, Bcl-2, Mcl-1, and A1 all bound to Bax and Bak, whereas Bcl-xS, Bad, and Ced-9 did not (Table I). Therefore, anti-death activity was associated with the ability to bind to Bax or Bak. Proteins such as Ced-9, Bcl-xS, and Bad that did not bind to Bax/Bak did not inhibit killing, whereas proteins that could associate, such as Bcl-xL and Mcl-1, were inhibitory. Since the lack of death suppressor activity of Ced-9 was unexpected, its association with anti-apoptotic members of the Bcl-2 family was determined. LexA-Ced-9 (as well as LexA-Bcl-xS and LexA-Bad) bound to Bcl-xL, Bcl-2, and A1 (data not shown). Therefore, Ced-9 had the binding and activity profiles of proteins such as Bcl-xS rather than Bcl-2.

Mutations in Bcl-xL Dissociate Bax Binding from Death Suppressor Activity

To further pursue the relationship between heterodimerization and biological activity, a series of truncation and deletion mutations of Bcl-2 and Bcl-xL were made. When coexpressed with Bax, the majority of these mutants failed to bind to Bax and did not suppress death (Fig. 2, A and B). However, two Bcl-xL mutants, XF14 and XF15, were active in suppression of Bax toxicity but either bound weakly or not all in the two-hybrid assay (Fig. 2A).

To ensure that these data were not a product of the LexA sequences, unfused XF14 and XF15 were examined for their suppressive effects on native Bax toxicity and for coimmunoprecipitation with MYC-tagged Bax. Both unfused XF14 (GI, 8.7) and XF15 (GI, 8.8) were potent suppressors of Bax lethality (GI, 1.0). For coimmunoprecipitation, the proteins were in vitro translated in the presence of [35S]methionine, whereas a MYC epitope-tagged Bax (MYC-Bax) was translated in the absence of the radionuclide. After appropriate mixing and incubation, Bcl-xL was specifically immunoprecipitated with MYC-Bax but not the MYC epitope alone (Fig. 3). In contrast, neither XF14 nor XF15 was precipitated specifically with MYC-Bax and the anti-MYC monoclonal antibody (Fig. 3). XF15 showed no evidence of Bax binding. XF14 gave a relatively high background immunoprecipitation that was not augmented by the presence of MYC-Bax, indicating that it does not bind to Bax. This analysis confirms a prior report using these and similar constructs (28).


Fig. 3. Coimmunoprecipitation of Bcl-xL and Bcl-xL mutants with MYC-tagged Bax. Either unlabeled MYC-tagged Bax (MYC-Bax) or the MYC epitope (MYC) were incubated with [35S]methionine-labeled Bcl-xL, XF14, or XF15 (see "Experimental Procedures" for details). Subsequently, immunoprecipitation was carried out using the monoclonal anti-MYC antibody 9E10. Bcl-xL showed a low but detectable background precipitation with the MYC epitope alone. However, Bcl-xL showed markedly enhanced immunoprecipitation in the presence of MYC-Bax, indicating specific association between Bcl-xL and Bax. Mutant XF15 was not precipitated by either the MYC epitope or MYC-Bax, indicating a lack of association of this mutant with Bax. Mutant XF14 gave a relatively high background with MYC epitope alone, but unlike Bcl-xL, this signal was not augmented by MYC-Bax. Mr (K), molecular mass in kilodaltons.
[View Larger Version of this Image (45K GIF file)]

Bcl-xL and Bcl-xL Mutants Do Not Alter Bax Expression

To preclude the possibility that coexpression of Bcl-xL or the mutants either reduced the expression or promoted the degradation of Bax, steady-state protein levels were determined by immunoblotting. Fig. 4A shows the immunoblot analysis of Bax and Bcl-xL proteins in yeast. Cells were cotransformed with constructs encoding LexA-Bax and one of unfused Bcl-xL mutants, XF14 or XF15. An ~45-kDa LexA-Bax fusion protein accumulated to maximal levels within 12 h after galactose induction. Expression of ~26-kDa Bcl-xL, ~20-kDa XF14, and ~21-kDa XF15 immunoreactive bands were also detected 12 h after galactose induction. None of the anti-death proteins altered the levels or time course of LexA-Bax expression (Fig. 4A). Additional Bax-reactive proteins of lower molecular mass were also induced with similar kinetics to LexA-Bax. The levels of these proteins were also unaffected by Bcl-xL expression (Fig. 4A). It is unclear whether these bands are proteolytic fragments of LexA-Bax or incomplete transcription/translation products. No such proteins were observed when unfused Bax was expressed with Bcl-xL in yeast (Fig. 4B), suggesting that the additional bands do not represent selective processing of Bax sequences.


Fig. 4. Evaluation of the levels of Bcl-2 family members in yeast by immunoblotting. A, yeasts were cotransformed with LexA-Bax and a plasmid encoding VP16, Bcl-xL, XF14, or XF15. Transformants were switched to galactose medium, and the levels of the various proteins were determined by sequential immunoblotting as described under "Experimental Procedures." The position of full-length LexA-Bax is indicated. Several inducible lower molecular mass species are also evident. The upper panel shows the immunoblot of LexA-Bax, whereas the lower panel depicts the same blot reprobed for Bcl-xL or its two mutants. The positions of Bcl-xL, XF14, and XF15 are indicated at the right, and molecular mass is at the left. Coexpression of Bcl-xL or the two mutants did not affect the level or processing of any of the Bax-reactive bands. B, yeasts were cotransformed with VP16 and LexA, Bax and LexA-Bcl-xL, or Bax and LexA. Transformants were switched to galactose medium for 100 h, and extracts were immunoblotted for Bax as described under "Experimental Procedures." Unlike LexA-Bax, native Bax gave a single band at the appropriate molecular mass. Bax was only detectable in cultures that coexpressed Bax with LexA-Bcl-xL.
[View Larger Version of this Image (53K GIF file)]

Whereas expression of Bax is lethal, yeast transformed with the Bax plasmid did grow if cultured for longer periods (data not shown). This phenomenon is important in that it has implications for the use of this system as a suppressor screening assay. The growth effect could arise in a number of ways. First, a mutation in the vector could either inhibit expression of Bax or render it biologically inactive. Second, yeast may produce their own suppressor of Bax or lose a target of Bax. To test these possibilities, yeasts were cotransformed with Bax and Bcl-xL and subjected to immunoblot analysis after 100 h of culture. Fig. 4B shows that cells containing Bax and LexA plasmids no longer expressed immunoreactive Bax. However, an ~21-kDa Bax was still present in the cells containing Bax and LexA-Bcl-xL. Thus, mutations are selected for in Bax-expressing yeast that result in a loss of Bax expression. In the presence of Bcl-xL, this selective pressure is absent, and high (normally lethal) levels of full-length Bax are expressed. This effect must be considered when using this suppressor assay to identify proteins that functionally interact with Bax/Bak.

Bax Toxicity May Not Be Mediated by ICE-like Proteases

Since Bax and Bcl-xL may function independently, the mechanisms that mediate Bax toxicity were investigated. Another study has established that Bax lethality in yeast is not associated with DNA laddering (21), although it may involve proteolysis. Indeed, proteases belonging to the interleukin-1beta -converting enzyme (ICE) subfamily (recently termed caspases) have been implicated in cell death in phylogenetically disparate species (2). A search of the yeast genome for the consensus active site of ICE proteases (QACRG) yielded no hits, suggesting that these enzymes could not mediate death in yeast. To further examine this point, yeasts were cotransformed with Bax and CrmA, an inhibitor of ICE proteases that is derived from cowpox virus (25). CrmA did not rescue Bax toxicity and alone had no effect upon yeast growth (data not shown). Together, the data indicate that ICE-like proteases do not mediate Bax lethality in yeast.

Bcl-2 and Bcl-xL Have Distinct Structure-Activity Relationships in Yeast

Several studies have suggested that Bcl-2 and Bcl-xL have distinct properties (15, 17, 18). Therefore, the structure-activity relationships for Bax dimerization and suppression were determined for the two molecules in yeast. Two regions of Bcl-2 and Bcl-xL distinguished the biological properties of the two proteins. We confirm that the transmembrane (TM) domain of Bcl-2 is not essential for suppression of Bax toxicity in yeast and its elimination does not affect Bax binding (see mutant BF3 in Fig. 2B) (21). However, elimination of the TM domain in Bcl-xL leads to both the loss of Bax binding and suppressor activity (see mutant XF3 in Fig. 2A). As shown above, deletion of the putative loop region in Bcl-xL (mutants XF14 and XF15) (11) results in a loss of Bax binding but retention of Bax suppressor activity (Fig. 2A). Whereas an equivalent mutation in Bcl-2 (BF6) retained suppressor activity, it still bound well to Bax (Fig. 2B). These data suggest that the loop region may be important for the interaction of Bcl-xL with Bax, whereas the equivalent domain in Bcl-2 is not. Together, the results indicate that whereas Bcl-2 and Bcl-xL, both, can suppress Bax toxicity in yeast, they may not do so in an identical manner.


DISCUSSION

As in vertebrate cell death models, members of the Bcl-2 family can be grouped into three functional classes in yeast. The first group comprises proteins, such as Bax and Bak, which are lethal per se. The second group includes Bcl-2, Bcl-xL, Mcl-1, and A1, which bind to and suppress Bax and Bak lethality. The third group bind to anti- but not pro-apoptotic members of the Bcl-2 family. These proteins, which include Bad, Bcl-xS, and the C. elegans Ced-9, are functionally inactive in terms of direct killing or death suppression. In vertebrates, proteins such as Bad and Bcl-xS are not considered to be lethal per se but rather are thought to potentiate killing by binding to anti-apoptotic members of the Bcl-2 family (29, 30). Thus, mammalian Bcl-2 family members have the same spectrum of biological activities in yeast as they do in vertebrate cells.

One unexpected result was that whereas Ced-9 did bind to anti-apoptotic members of the Bcl-2 family, it did not bind to Bax and did not suppress Bax/Bak killing. Although we can find no study that has used Ced-9 to rescue death in a vertebrate cell, it is the presumed homolog of Bcl-2 (8) and was expected to suppress killing. However, the properties of Ced-9 are more akin to those of Bcl-xS than they are to Bcl-2. It is conceivable that Ced-9 binds specifically to a C. elegans homolog of Bax, although no such gene has been identified. However, the possibility exists that family members such as Ced-9 and Bcl-xS might exert their functions through mechanisms other than intrafamily binding.

Genetic analysis in C. elegans has shown that Ced-9 acts via Ced-4, a protein of unknown function, and Ced-3, an ICE-like cysteine protease (4). It is possible that Ced-9, and by implication Bcl-xS and Bad, might act by binding to Ced-4 or related proteins in vertebrates. However, whereas many studies have implicated cysteine proteases in cell death in vertebrates (2), it is unlikely that ICE-like proteases mediate Bcl-2 family effects in yeast. First, Bax lethality is not inhibited by coexpression of the ICE protease inhibitor, CrmA. Second, no consensus sequence for the active site of ICE proteases has been found in the yeast genome. Therefore, Bax lethality may not involve the activation of ICE-like proteases in yeast. Indeed, Bax killing has been shown to be independent of this class of proteases in at least one vertebrate model (31).

Analysis of the structural requirements of Bcl-xL for suppression of Bax toxicity in yeast revealed that deletions at both the N and C termini eliminated biological activity. In one mutant, XF3, deletion of the last 22 amino acids, which included the TM domain, resulted in loss of suppressor activity. This result suggests that membrane targeting is essential for the protective effect of Bcl-xL in yeast. However, the equivalent domain in Bcl-2 is not required for rescue (19), indicating that these two related proteins may have divergent mechanisms of action. Such a notion is underscored by the distinct phenotypes of mice that lack functional bcl-2 or bcl-x alleles and by the unique protective effects of Bcl-xL in some cell death models (14, 15, 17, 18). Whereas the TM domain is thought to be necessary for the activity of Bcl-xL in vertebrate cells, the situation for Bcl-2 is controversial (12, 32, 33). However, the recent demonstration that Bcl-xL has structural similarities to the pore-forming subunit of diphtheria toxin suggests that its biological function may occur at or within cellular membranes (11). Therefore it is conceivable that there are proteins in yeast that can dock Bcl-2, but not Bcl-xL, to membranes thereby obviating the requirement for a TM domain. Bcl-2 and Bcl-xL can also be discriminated by their structure-activity relationship for binding to Bax. Mutants of Bcl-xL that had the putative loop domain deleted (XF14 and XF15) did not bind Bax, whereas an equivalent deletion in Bcl-2 (BF6) did bind in the two-hybrid assay. Since the loop regions of Bcl-2 and Bcl-xL are not conserved, these data may be an indication that these domains can selectively modify dimerization, although they may not be part of the dimerization interface.

Dimerization between Bcl-2 family members is considered central to their biological activity. Indeed, in one model it is the stoichiometry of various pro- to anti-apoptotic Bcl-2 family members that is supposed to determine cell fate (34). However, the view that dimerization is the sole determinant of activity has been questioned. For example, some Bcl-xL mutants that failed to associate with Bax still rescued 70-80% of Sindbis virus-induced cell death (16). However, it could be argued that Sindbis virus-triggered cell death may not be mediated by Bax. Indeed, there is evidence of Bax-independent cell death pathways in bax-null mice (35). Recently, some Bcl-xL mutations were described that had reduced, or no, binding activity to Bax but that rescued vertebrate cells from death triggered by IL-3 deprivation (11, 28). Therefore we compared the activity of these deletions with other Bcl-xL and Bcl-2 mutants as suppressors of Bax toxicity in yeast. All full-length Bcl-2 family members and mutants that bound to Bax inhibited killing, whereas those that did not bind were inactive. However, the two internal deletion mutants of Bcl-xL, XF14 and XF15, that did not bind to Bax were potent suppressors. This indicates that dimerization is not essential for Bcl-xL to suppress Bax lethality in yeast.

The observation that Bcl-xL can antagonize Bax killing in yeast independent of heterodimerization has several important implications. First, it argues against the effects of Bax in yeast as being nonspecific toxicity that can be attenuated by any Bax-binding protein. Second, it suggests that Bax and Bcl-xL either interact with, or compete for, a common downstream target or pathway in yeast. Alternatively, they could influence antagonistic mechanisms. Third, the data suggest that Bax and Bcl-xL act upon mechanisms that have been conserved from yeast to mammals, although these processes may only have been adapted for the control of cell elimination in multicellular organisms. The assay described here can be used as a genetic suppressor screen to identify potential components of this pathway in yeast and vertebrates.


FOOTNOTES

*   This work was supported in part by National Institutes of Health Cancer Support CORE Grant P30 CA21765 and by the American Lebanese Syrian Associated Charities.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
   To whom correspondence should be addressed: Dept. of Developmental Neurobiology, St. Jude Children's Research Hospital, 332 N. Lauderdale, Memphis, TN 38105. Tel.: 901-495-2256; Fax: 901-495-3143; E-mail: jim.morgan{at}stjude.org.
1   C. Kurschner and J. I. Morgan, unpublished data.
2   The abbreviations used are: GI, growth index; ICE, interleukin-1beta -converting enzyme; TM, transmembrane.

ACKNOWLEDGEMENTS

We thank Dr. Craig B. Thompson for helpful discussions and Dr. Steven Dalton for providing the yeast expression plasmids pSD.10a and Y.LexA, in vitro translation plasmids, and the S. cerevisiae reporter strain S260.


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