COMMUNICATION
Nix and Nip3 Form a Subfamily of Pro-apoptotic Mitochondrial Proteins*

Gao Chen, Jeannick Cizeau, Christine Vande Velde, Jae Hoon Park, Gracjan Bozek, James Bolton, Lianfa Shi, Don Dubik, and Arnold GreenbergDagger

From the Manitoba Institute of Cell Biology, University of Manitoba, Winnipeg, Manitoba R3E 0V9, Canada

    ABSTRACT
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ABSTRACT
INTRODUCTION
REFERENCES

We have identified Nix, a homolog of the E1B 19K/Bcl-2 binding and pro-apoptotic protein Nip3. Human and murine Nix have a 56 and 53% amino acid identity to human and murine Nip3, respectively. The carboxyl terminus of Nix, including a transmembrane domain, is highly homologous to Nip3 but it bears a longer and distinct asparagine/proline-rich N terminus. Human Nip3 maps to chromosome 14q11.2-q12, whereas Nix/BNip3L was found on 8q21. Nix encodes a 23.8-kDa protein but it is expressed as a 48-kDa protein, suggesting that it homodimerizes similarly to Nip3. Following transfection, Nix protein undergoes progressive proteolysis to an 11-kDa C-terminal fragment, which is blocked by the proteasome inhibitor lactacystin. Nix colocalizes with the mitochondrial matrix protein HSP60, and removal of the putative transmembrane domain (TM) results in general cytoplasmic and nuclear expression. When transiently expressed, Nix and Nip3 but not TM deletion mutants rapidly activate apoptosis. Nix can overcome the suppressers Bcl-2 and Bcl-XL, although high levels of Bcl-XL expression will inhibit apoptosis. We propose that Nix and Nip3 form a new subfamily of pro-apoptotic mitochondrial proteins.

    INTRODUCTION
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ABSTRACT
INTRODUCTION
REFERENCES

Apoptosis is regulated by molecules that both activate and suppress cell death. The molecular regulators of developmental apoptosis in Caenorhabditis elegans include cell death inducers Ced-3 and -4 (1) which are conserved in mammals (2, 3). Ced-9 is the prototypical cell death suppresser protein, and Bcl-2 and Bcl-XL are the mammalian homologs (4). However, the Bcl-2 family of proteins also contains members that function to activate apoptosis such as Bax, Bad, Bak, Bik/Nbk, and Hrk (5-8).

We recently identified a new cell death-inducing protein named Nip3 (9) (also called BNip3 (10)), which was initially reported to physically interact with both adenovirus E1B 19K and Bcl-2 (11). Nip3 is a mitochondrial protein that induces apoptosis and can enhance the apoptosis induced by other cell death signals when transiently expressed (9, 10). Bcl-2 transiently suppresses Nip3-induced apoptosis although this resistance is rapidly overcome (9, 10). We report the cloning of Nix (Nip3-like protein X), which closely resembles Nip3 in both structure and function. We propose that Nix and Nip3 form a new structurally related pro-apoptotic family of mitochondrial proteins.

    MATERIALS AND METHODS

Cloning of Murine Nix (mNix), Human Nix (hNix), and Murine Nip3 (mNip3)-- Searches of the GenBank EST1 and TIGR (Institute for Genomic Research) data bank using the human Nip3 cDNA revealed related but novel human and mouse EST clones. Using primers within these EST sequences, we generated PCR fragments, which were cloned into pCRII vector (Invitrogen, San Diego, CA) and sequenced. The entire mNix and hNix cDNA were then polymerase chain reacted from mouse 17-day embryo Matchmaker cDNA library and human fetal liver 5'-stretch plus cDNA library (CLONTECH, Palo Alto, CA). Murine Nip3 cDNA was cloned from a lambda GT11 3T3 fibroblast cDNA library using human Nip3 as a probe. KpnI and EcoRI sites were introduced into the full-length cDNA by PCR and then subcloned into expression vector pcDNA3-T7, a modified pcDNA3 vector containing a C-terminal T7-tag (9). Transmembrane domain-deleted expression vector mNix (Delta TM) was generated by PCR using splice overlap extension (12). Human Nip3 and the Nip3163 transmembrane deletion mutant have been described previously (9).

Reagents and Cell Lines-- Rat-1, Rat-1/Bcl-2, TC (10T1/2 parental cell line), TX5 and TX22 (Bcl-XL transfected clones), and MCF-7 cells were culture in alpha -minimal essential medium (Life Technologies, Inc.) supplemented with 10% fetal bovine serum (Life Technologies, Inc.). Murine monoclonal anti-T7 antibody was purchased from Novagen (Madison, WI). Rabbit anti-HSP60 antibody was donated by Dr. Radhey Gupta (McMaster University). FITC-conjugated goat anti-rabbit IgG (Sigma Chemical Co.) and Cy3-conjugated goat anti-mouse IgG (BioCan Ltd., Mississauga) were used for fluorescence studies. Lactacystin was purchased from Calbiochem-Novabiochem (Cambridge, MA).

Northern Analysis-- Total RNA (30 µg) was fractionated on a formaldehyde denaturing gel and then transferred and hybridized with nick-translated human or mouse Nix cDNA corresponding to the coding region as described (9).

In Vitro Transcription-- 35S-labeled Nix proteins were prepared by in vitro transcription and translation of cDNA cloned in pcDNA3 vector using TnT coupled reticulocyte lysate system (Promega, Madison, WI).

Western Blotting-- Aliquots of 5 × 104 cells transfected with Nix-T7 were separated by an SDS-PAGE method using Tris-Tricine buffer and polyvinylidene difluoride membrane that is suitable for detecting small molecular weight peptides (13). Western blots were probed with mouse monoclonal anti-T7 antibody using an ECL detection kit (Amersham Pharmacia Biotech, UK).

Transient Transfection and Apoptosis Assays-- Cells were transfected with Nix using LipofectAMINE Reagent (Life Technologies, Inc.). Aliquots of 5 × 104 cells were Western blotted as described above. For apoptosis experiments, Nix-expressing cells were detected with mouse anti-T7 antibody and FITC-conjugated rabbit anti-mouse IgG antibody. Apoptotic cells, exhibiting altered DNA morphology following Hoechst dye staining, were enumerated manually counting as described previously (9). Fluorescence was visualized using a Zeiss Axiophot microscope equipped with a cooled CCD camera.

For beta -galactosidase apoptosis assays evaluating the effect of removing the transmembrane domain on Nix and Nip3 apoptosis, 293T cells were cotransfected with 0.2 µg of pcDNA3-beta -galactosidase plus 0.75 µg of the expression plasmid in triplicate using LipofectAMINE. Cells were fixed, stained, and evaluated 21 h later as described previously (14).

    RESULTS AND DISCUSSION

The cloning of hNix, mNix, and mNip3 was as follows. Using the human Nip3 cDNA as a probe, we screened a lambda GT11 mouse fibroblast cDNA library for clones related to Nip3. The clone containing the longest insert of 1311 bp was found to contain the entire mouse Nip3 coding region of 187 amino acids (GenBank accession number AF041054). The cDNA had overall identity with human Nip3 of 90.2% (Fig. 1).


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Fig. 1.   Alignment of predicted murine and human Nip3 and Nix proteins. Regions of identity with hNix are shaded. The predicted transmembrane domains are underlined.

Human and murine ESTs related to but different from Nip3 were used for PCR to clone, as described under "Materials and Methods," a human 1337-bp and murine 1351-bp cDNA containing a large open reading frame of 219 and 218 amino acids, respectively. The protein was named Nix. The predicted human Nix (hNix) (GenBank accession number AF067396) and mouse Nix (mNix) (AF067395) proteins share 56 and 53% identity, respectively, with Nip3 of the same species, and are 97% identical to each other (Fig. 1). The highest regions of homology between the four proteins resides in the C terminus. Nix proteins bear a single hydrophobic alpha -helical sequence at the extreme carboxyl terminus, corresponding to the location of the TM domain of Nip3 (2) (Fig. 1). Nix has a significantly longer N terminus that contains an unusual five asparagines in sequence and is proline-rich. N-terminal amino acids 1-59 of hNix and 1-32 of hNip3 are the most divergent. Another region from amino acids 97-120 of hNix is also distinct from hNip3, whereas the remainder is over 85% homologous with large blocks of identical sequences in both species.

Similar to Nip3 (9, 11), Nix contains PEST sequences comprised of high frequency stretches of Pro, Glu, Ser, Thr, and Asp, flanked by charged amino acids His, Arg, or Lys. PEST sequences are associated with proteins having high turnover rates (15) whose degradation is controlled by the proteasome. hNix and mNix are expressed as 4.5- and 1.4-kilobase mRNA transcripts, respectively (not shown). The smaller transcript corresponds to the size of the cDNAs reported above and is likely the complete sequence. The larger transcript has not been identified; however, some cDNA clones were found that bear a distinct 5'-UTR suggesting alternate splicing of the Nix mRNA, and may represent a larger transcript.

Following in vitro transcription and translation and Western blotting (Fig. 2A), mNix and hNix run as proteins of 48,000 relative molecular weight under reducing and non-reducing conditions using the Tris-Tricine SDS-PAGE method (13). hNip3 has a 40,000 relative molecular weight in Tris-Tricine-buffered SDS-PAGE (Fig. 2A). In contrast, using the Laemmli method, Nix runs as an 80-kDa protein (not shown) and Nip3 at 60 kDa (9). The reason for the difference in mobility in the two buffers is not clear; however Nip3, which forms a homodimer that does not dissociate under reducing conditions (9), runs at its predicted molecular weight of 40,000 in the Tris-Tricine SDS-PAGE. Nix is also unaffected by reduction and is about double its 23.8 kDa predicted mass (Fig. 2A), suggesting that it may also be a homodimer.


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Fig. 2.   A, in vitro transcription and translation of Nix and Nip3. 35S-labeled mNix (lanes 1 and 2), hNix (lanes 3 and 4), and mNip3 (lanes 5 and 6) were electrophoresed on Tris-Tricine SDS-PAGE under reducing (R) (lanes 2, 4, and 6) and non-reducing (NR) (lanes 1, 3, and 5) conditions as described under "Materials and Methods." B, mNix expression in vivo. Rat-1 cells were transfected with C-terminal T7-tagged mNix (left) and then lysates were electrophoresed in Tris-Tricine buffer (see "Materials and Methods") and Western blotted with anti-T7 antibody. Rat-1 cells treated with the proteasome inhibitor lactacystin were transfected with mNix-T7 in parallel (right).

Western blotting of lysates from Rat-1 cells transiently transfected with expression vector Nix-T7 reveals a 48-kDa protein that is progressively degraded over 42 h (Fig. 2B). We examined both N- and C-terminal T7-tagged Nix and found that a residual 11-kDa fragment was detected only with the C-terminal tag (Fig. 2B). Nix with an N-terminal tag showed a similar degradation pattern of the 48-kDa band but no smaller fragments were detected (not shown). Intermediate fragments were also visible on some transfections at earlier time points or after prolonged development of the blots but only with the C-terminal tag. A similar pattern of degradation was found following transfection with Nip3 in which an 11-kDa fragment was detected using a C- but not an N-terminal tag. The 11-kDa residual Nip3 fragment was only detectable using the Tris-Tricine-buffered SDS-PAGE, which is optimized for the detection of small peptides. The proteolytic degradation is dependent on an active proteasome. Nix remains as a 48-kDa protein when cells were first treated with lactacystin, the proteasome threonine protease inhibitor (Fig. 2B). Nip3 is also degraded rapidly following transfection (9), and as with Nix, Nip3 degradation is also inhibited in lactacystin-treated cells (not shown).

To determine whether Nix is localized to mitochondria, the primary site of Nip3 expression (9, 10), mNix-T7 was transiently transfected into Rat-1 cells and stained with both monoclonal anti-T7 and rabbit anti-HSP60 antibodies. Secondary antibodies, FITC-labeled goat anti-mouse IgG and Cy3-labeled goat anti-rabbit IgG, were then used to visualize the localization of Nix and HSP60, respectively, within the cells after immunofluorescence and confocal microscopy. HSP60 is primarily located in mitochondria (16), and our results showed that Nix colocalizes with HSP60 (Fig. 3A). Because Nip3 requires the TM domain to localize to mitochondria, we prepared a mutant Nix without the putative TM domain (Nix Delta TM). Nix Delta TM is expressed evenly throughout the cytoplasm and is not localized to any organelle-like structure (Fig. 3B). Unlike Nip3 Delta TM (9), the Nix mutant was detected in the nucleus in higher levels than in the cytoplasm. Because Nip3 induces apoptosis when transiently transfected, we examined the effects of Nix expression in Rat-1 and MCF-7 cells over time. Nix-expressing cells undergo apoptosis (Fig. 3C). This was quantitated over a 48-h period, and a progressive increase in the percent of cells that were apoptotic was observed (Fig. 4A) and at about the same rate as that in Nip3 (Fig. 4B). Removal of the transmembrane domain of Nix prevented the induction of cell death similar to that of transmembrane deficient mutant of Nip3 (Fig. 4C).


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Fig. 3.   Subcellular localization of Nix and the mitochondrial matrix protein HSP60. MCF-7 cells transiently transfected with mNix-T7 were stained with mouse monoclonal anti-T7 antibody and FITC-labeled rabbit anti-mouse IgG (A) and rabbit anti-HSP60 antibody followed by Cy3-conjugated donkey anti-rabbit IgG antibody (B) 12 h later. N, nucleus. MCF-7 cells transfected with the Nix Delta TM mutant were stained with anti-T7 antibody (C) or Hoechst dye (D). Shown are Nix-expressing cells undergoing apoptosis 30 h post-transfection. mNix-transfected cells stained with anti-T7 antibody (E) and Hoechst dye (F). Note the condensed chromatin in the nucleus in the mNix expressing cells (arrows).


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Fig. 4.   Time course of induction of apoptosis following mNix-T7 (A) or hNip3 (B) transient transfection of MCF-7 (black-square, ) and Rat-1 (bullet , open circle ) cells. Each tumor cell was transfected in three independent experiments, and apoptotic cells were quantitated at the times indicated by counting the percentage with apoptotic nuclear morphology by Hoechst staining of Nix or Nip3 expressing cells. Cells transfected with mNix or hNip3 (black-square, bullet ) were identified by immunofluorescent staining of anti-T7 antibody. Apoptosis of non-transfected cells (, open circle ) was also enumerated. The data from three independent experiments were expressed as the mean ± S.E. for each time point. C, removal of the transmembrane domain abolishes apoptosis by mNix and hNip3. mNix Delta TM (Nix-TM) and the transmembrane and C-terminal deletion mutant Nip3163 (Nip3-TM) were inactive when evaluated in a beta -galactosidase assay. The data represent triplicate independent transfections and were repeated with identical results.

Nip3-induced apoptosis is only partially suppressed in Bcl-2 expressing cell lines (9, 10). Inhibition is detected early in the time course but is overcome at later time points (9). Examining the apoptosis rate over a 48-h period following mNix transfection, we found that there was no significant difference between Rat-1 and Rat-1/Bcl-2 cell lines (Fig. 5A), the latter being highly resistant to other apoptotic signals such as granzyme B (9). At decreasing doses of Nix plasmid from 1.0 to 0.1 µg, the transfection efficiency decreased progressively but the apoptosis rate in transfected cells remained constant between the two cell lines (not shown). Examining Nix apoptosis in Bcl-XL expressing cell lines TX22 and TX5, we find that only the higher Bcl-XL expressing cell line TX5 was effective at blocking Nix although both lines were resistant to staurosporine-induced apoptosis when compared with the parental line TC (Fig. 5,B and C).


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Fig. 5.   Effect of Bcl-2 or Bcl-XL overexpression on mNix. A, time course of Nix-induced apoptosis in Bcl-2 expressing Rat-1 cells. Rat-1 cells (bullet ) or Rat-1 cells overexpressing Bcl-2 (black-triangle) were transfected with mNix and apoptotic cells counted as above. B, transfection of mNix into two cell lines TX5 and TX22 overexpressing Bcl-XL compared with the parental 10T1/2 cell line TC. At different times following transfection, Nix expressing cells (TC-Nix, TX22-Nix, TX5-Nix) undergoing apoptosis were quantitated as described above. Cells not expressing Nix (TC-Con, TX22-Con, TX5-Con) were also counted for apoptotic morphology. C, apoptosis of the TC, TX5, and TX22 cell lines following staurosporine treatment at the doses indicated for 5 h. Experiments were repeated three times, and the mean ± S.E. is shown.

The suppressive action of Bcl-2 can be reversed by heterodimerization with pro-apoptotic members of the Bcl-2 family through the BH3 (Bcl-2 homology-3) domain (8, 17, 18). Nip3 protein appears to have a region that bears some structural similarity to the BH3 domain of the Bcl-2 family (9, 10), which may partially function to promote Nip3 cell death (10). However, it is also clear that Nip3 and Nix are more structurally related to each other than to pro-apoptotic members of the Bcl-2 family.

A recent report identified a human cDNA called BNip3L that is homologous to hNip3 and maps to chromosome 8p21 (19). The protein encoded by the BNip3L cDNA is identical to the human Nix. For comparison, we have now mapped the chromosomal location of human Nip3 and, using a radiation hybrid panel, we find it is on chromosome 14; 4.08 centi-Ray from the marker WI-6506. Using the Whitehead Institute/MIT YAC map of chromosome 14, the CEPH YAC 951d6 was positive, placing the gene slightly centromeric to WI-6506 at the band 14q11.2-q12. The distinct mapping location of the two genes warrants a unique name for Nix rather than BNip3L because Nix is not a long form of Nip3.

Expression of BNip3L in cervical cancer cell lines reduced their colony-forming ability and suggested to the authors that the protein may have growth-suppressive function. Because we find that both hNix and mNix are pro-apoptotic when overexpressed in tumor cell lines, induction of apoptosis can account for the observed growth suppression and poor colony formation in the BNip3L-transfected carcinoma cells.

In conclusion, we have described Nix, a homolog of the Nip3 protein, which shares the ability to induce apoptosis, localize to mitochondria, and undergo proteasome-dependent degradation when overexpressed. Nip3 and Nix form a new subfamily of mitochondrial cell death proteins.

    ACKNOWLEDGEMENTS

We thank Dr. Brian Fristensky for analyzing the Nix and Nip3 proteins and Dr. Radhey Gupta for the anti-HSP60 antibody. We also thank the Medical Research Council Genome Resource Facility at The Hospital for Sick Children, Toronto, for radiation and YAC mapping.

    FOOTNOTES

* This work was supported by the National Cancer Institute of Canada and Medical Research Council of Canada.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.

The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) AF041054, AF067396, and AF067395.

Dagger Terry Fox Cancer Research Scientist. To whom correspondence should be addressed: 100 Olivia St., Manitoba Institute of Cell Biology, University of Manitoba, Winnipeg, MB R3E 0V9, Canada. Tel.: 204-787-2112; Fax: 204-787-2190; E-mail: agreenb{at}cc.umanitoba.ca.

    ABBREVIATIONS

The abbreviations used are: EST, expressed sequence tag; PCR, polymerase chain reaction; TM, transmembrane; FITC, fluorescein isothiocyanate; PAGE, polyacrylamide gel electrophoresis; Tricine, N-[2-hydroxy-1,1-bis(hydroxymethyl)ethyl]glycine; bp, base pair(s)..

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