Atugen AG, Robert-Rössle-Str.10, Otto-Warburg-Haus (80), 13125 Berlin, Germany
Author for correspondence (e-mail: santel{at}atugen.com)
Accepted 4 April 2005
![]() |
Summary |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Key words: Mitochondrial morphology, Mitofusin, Apoptosis, hFis1, Drp1, shRNA
![]() |
Introduction |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Evolutionary conserved cellular components of mitochondrial fusion and fission that maintain mitochondrial morphology have been identified and characterised in yeast, fly and mammals (Chen and Chan, 2004; Hales and Fuller, 1997
; Karbowski and Youle, 2003
; Mozdy and Shaw, 2003
; Scott et al., 2003
; Shaw and Nunnari, 2002
). A class of large GTPases controls the maintenance of mitochondrial morphology through antagonizing fusion and fission events in a GTPase-dependent manner. Mitochondrial mitofusin GTPases regulate controlled mitochondrial fusion. By contrast, the cytoplasmic GTPase dynamin 1-like protein (DNM1L, here referred to as Drp1) is recruited to the mitochondrial outer membrane to exert fission of mitochondria. In Caenorhabditis elegans, the assembly of Drp1 on mitochondria results in severing the outer membrane (Labrousse et al., 1999
). Similarly, genetic and biochemical studies in yeast uncovered a multi-step pathway for mitochondrial fission, whereby preassembled Drp1 structures, in concert with other mitochondrial outer membrane components, are sufficient to cut apart both mitochondrial membranes (Mozdy et al., 2000
; Sesaki and Jensen, 1999
; Shaw and Nunnari, 2002
; Tieu and Nunnari, 2000
; Tieu et al., 2002
). However, exactly how Drp1 is recruited to mitochondria and how the fission process is then executed is still not fully understood.
Like Drp1, the mitochondrial outer-membrane protein Fis1 appears to be a key player during mitochondrial fission. Human Fis1 [tetratricopeptide repeat protein 11 (TTC11), hereafter referred to as hFis1] is a highly conserved 17-kDa integral mitochondrial protein of the outer membrane. Recently, several reports have provided strong evidence that hFis1, like its yeast homologue Fis1p, is involved in mediating mitochondrial fission, presumably by setting up the fission complex on the cytoplasmic face of the outer membrane through (direct or indirect) recruitment of Drp1 (Frieden et al., 2004; James et al., 2003
; Stojanovski et al., 2004
; Suzuki et al., 2003
; Yoon et al., 2003
). In addition, hFis1 has been implicated in the control of Drp1-mediated fission during apoptosis. Mitochondrial fission and mitochondrial-membrane remodeling have been shown to be the initiating step of the apoptotic pathway (Bossy-Wetzel et al., 2003
; Fantin et al., 2002
; Frank et al., 2001
; Karbowski et al., 2002
; Scorrano et al., 2002
). Transient expression of hFis1 in mammalian cells leads to excessive mitochondrial fission. Consequently, cytochrome c is released from mitochondria and triggers the onset of programmed cell death, highlighting the direct link between mitochondrial function and apoptosis (James et al., 2003
). In addition to the proposed interaction of Drp1 with Fis1 during recruitment of Drp1 to the mitochondrial membrane, another report discusses Drp1 as a target for protein modification processes through interaction with modifying proteins such as Ubc9 (ubiquitin-conjugating enzyme 9) and Sumo1 (small ubiquitin-like modifier 1) (Harder et al., 2004
).
Furthermore, a few viral proteins have been reported to be actively involved in fragmentation of mitochondria after their expression in mammalian cells, however, with different effects on the apoptotic behavior of mitochondria (Karbowski and Youle, 2003). We have recently discovered another novel human mitochondrial protein, MTP18, that is implicated in the control of mitochondrial morphology (Tondera et al., 2004
).
In this study, we present further experimental evidence for MTP18's function in maintaining the balance of fission and fusion in mammalian cells. MTP18-induced mitochondrial fragmentation upon its overexpression can be inhibited by increasing counteracting mitochondrial fusion activity. Knockdown of MTP18 by RNA interference (RNAi) blocks hFis1-induced mitochondrial fission, therefore suggesting that MTP18 is required to facilitate the complete fission step.
![]() |
Materials and Methods |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
|
Cell culture and transfections
COS-7 and HeLa cells were cultured as described (Tondera et al., 2004). Transfection of MTP18-expression constructs using the Effectene transfection reagent (Qiagen) was carried out according to manufacturer's instructions. For transient coexpression of specific shRNAs and recombinant proteins, HeLa cells were first transfected with shRNA-expressing plasmids for 24 hours and then again with shRNA-expressing plasmids and overexpression plasmids (ratio 9:1) for another 24 hours.
Subcellular fractionation and proteinase K treatment
Isolation of mitochondria was done as described (Tondera et al., 2004). For membrane protein analyses, mitochondrial pellets were resuspended in 400 µl of 0.1 M Na2CO3 or 0.5 M NaCl, vortexed and incubated on ice for 30 minutes. The insoluble membrane fractions were centrifuged at 100,000 g for 10 minutes, and the supernatant was precipitated with 10% (v/v) trichloroacetic acid (TCA). For proteinase K digestion, isolated mitochondria were suspended in isotonic mitochondrial buffer (MB; 250 mM sucrose, 10 mM HEPES, 10 mM KCl, 2 mM MgCl2, 1 mM EGTA pH 7.4) and incubated at room temperature with 5 µg/ml proteinase K for the times indicated. Digestion was terminated with 2 mM phenylmethylsulfonyl fluoride (final concentration). Mitochondrial proteins were separated by SDS-PAGE and proteins were detected by western blotting with anti-MTP18, anti-hFis1 and anti-Hsp60 antibodies.
Antibodies, dyes and immunoblotting
Rabbit polyclonal antiserum against MTP18 has been previously described (Tondera et al., 2004). Monoclonal anti-cytochrome c, anti-Hsp60 and anti-Drp1/DLP1 antibodies were purchased from BD Transduction Laboratories. The rabbit polyclonal anti-Mfn1 antibody was kindly provided by Minx Fuller (Santel et al., 2003
). Anti-hFis1 was obtained from Alexis Inc. (Portland, OR). Mouse- and rabbit-specific secondary antibodies coupled to Alexa fluor488, Alexa fluor596 or Alexa fluor633, as well as mitochondria-specific dye MitoTracker Red were purchased from Molecular Probes. Preparation of cell extracts and immunoblot analysis was carried out as described (Klippel et al., 1998
).
Immunofluorescence microscopy
Before fixation, cells were treated for 1 hour with 5 µM nocodazole (Figs 5, 6, and 7) and for 15 minutes with 1 µM MitoTracker Red at 37°C. For immunofluorescence, cells were fixed for 15 minutes at room temperature in 4% formaldehydephosphate-buffered saline. All subsequent steps for indirect immunofluorescence were carried out as previously described (Santel and Fuller, 2001). An LSM 510 META confocal microscope (Zeiss) was used for microscopy. Multitrack scanning mode was used to record double-labelled cells.
|
|
![]() |
Results |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
|
|
|
|
The C-terminus of MTP18 is crucial for localisation and function of MTP18
The transient expression of a truncated version of MTP18 lacking the C-terminus, affects proper mitochondrial localisation of MTP18 and blocks mitochondrial fission. Microscopic studies were carried out with COS-7 cells transfected with expression constructs for myc-tagged full-length MTP18, or truncated variants lacking the N-terminal half (1-90-MTP18-myc) or the C-terminal half (
91-166-MTP18-myc) (Fig. 3A). Transient expression of the full-length and the deletion constructs was confirmed with polyclonal anti-MTP18 antiserum in western blots (Fig. 3A). Transfected cells with high levels of recombinant MTP18-myc were discriminated from untransfected cells by immunofluorescence-staining with polyclonal anti-MTP18 antiserum. The MTP18 antibody detected recombinant MTP18-myc, but not low levels of endogenous MTP18 protein in mammalian cells. The full-length MTP18 protein and the N-terminally truncated variant localised to mitochondria as shown by counterstaining with an antibody against cytochrome c. Both variants caused fragmentation of mitochondria, demonstrating that the N-terminal half of the protein is not required for proper targeting and fragmentation (Fig. 3B). By contrast, when high levels of an MTP18 variant that lacks the C-terminal half of the protein (
91-166-MTP18-myc) were transiently expressed, it did not colocalise with cytochrome c, but instead showed a conspicuous cytoplasmic pattern. Moreover, the mitochondria did not appear fragmented but clustered (Fig. 3B), even when
91-166-MTP18-myc is transiently expressed at very high levels. By contrast, a more detailed analysis of transfected cells revealed that low levels of
91-166-MTP18-myc associated with mitochondria (Fig. 3C, arrow), but did not colocalise with Hsp60 (Fig. 3C, inset). Increasing amounts of this variant localised to the cytoplasm and nucleus in transfected cells as revealed by immunofluorescence staining with anti-MTP18 (Fig. 3C, double-arrow). Therefore, MTP18 might behave as an inner mitochondrial membrane protein containing more than one particular import signal (see Neupert, 1997
). Notably, mitochondria remained intact and did not become fragmented in cells with low levels of recombinant
91-166-MTP18-myc. Mis-localisation of
91-166-MTP18-myc presumably due to impaired import might affect the mitochondrial translocation machinery resulting in commonly observed perinuclear clustering of mitochondria upon transient protein expression (Santel and Fuller, 2001
). Taken together, the COOH-terminus of MTP18 bearing the predicted TM2 and TM3 regions contributes to the correct mitochondrial protein targeting and mitochondrial fragmentation activity.
Mitochondrial fission caused by transient overexpression of MTP18 is blocked by dominant negative Drp1 (Drp1K38A)
Overexpression of MTP18 in cell culture induced fragmentation of mitochondria (Tondera et al., 2004), as shown by transient coexpression of MTP18-myc and the GFP-tagged mitochondrial marker protein ANT-GFP (adenosine nucleotide transporter (Fig. 4A) (Santel and Fuller, 2001
). Mitochondrial morphology is maintained by controlled fusion and fission events. Both events are controlled by two large GTPases the mitofusins (Mfn1 and Mfn 2) and Drp1. Whereas fission is executed by the Drp1 protein, mitochondrial fusion is mediated by the mitochondrial outer membrane GTPase Mfn1. To study the effect of these proteins on MTP18-induced mitochondrial fragmentation, the following expression constructs were used: myc-tagged MTP18, HA-tagged Drp1, a dominant negative variant of Drp1 (HA-Drp1K38A), GFP-tagged Mfn1 and GFP-tagged variant of the GTPase-defective mutant Mfn1 (GFP-Mfn1K88T) (Fig. 4B).
Transient coexpression of MTP18-myc with Drp1K38A interfered with unopposed mitochondrial fission. Drp1K38A carries a missense mutation in the predicted GTPase domain of Drp1 and acts as dominant negative by blocking mitochondrial fission and promoting fusion (Smirnova et al, 1998; Pitts et al., 1999
). By contrast, transiently overexpressed wild-type Drp1 has no effect on altering mitochondrial morphology (data not shown) (Pitts et al., 1999
; Smirnova et al., 1998
). After transient expression of Drp1K38A in COS-7 cells, 67% of the transfected cells showed highly interconnected mitochondria (Fig. 4C, upper row; Fig. 4E). Consequently, loss of fission activity resulted in uncontrolled mitochondrial fusion. When MTP18-myc was transiently coexpressed with Drp1K38A, mitochondria in 30% of doubly transfected cells appeared as a network of long and highly interconnected filaments that partially clustered around the nucleus and scattered throughout the cytoplasm. By contrast, of MTP18-myc transfected cells less than 5% exhibited this mitochondrial morphology (Fig. 4E). Notably, 50% of doubly transfected cells exhibited fragmented mitochondria like seen in transfected cells that overexpressing MTP18-myc alone (>95% showing fragmented mitochondria) (Fig. 4E). The appearance of mitochondrial networks indicates that Drp1K38A overexpression can partly suppress MTP18-mediated fission activity.
MTP18-mediated mitochondrial fragmentation is inhibited by opposed mitochondrial fusion
Whereas the transient expression of MTP18-myc alone resulted in mitochondrial fragmentation to be seen in more than 90% of transfected cells, 80% of COS-7 cells that co-expressed MTP18-myc and GFP-Mfn1 showed a perinuclear mitochondrial network (Fig. 4D middle row, Fig. 4E). The observed perinuclear mitochondrial network was reminiscent of Mfn1-induced (fused) `grape-like' mitochondrial clusters (93% in GFP-Mfn1 transfected cells, Fig. 4D upper row) (Santel et al., 2003). To prove that the change from fragmented to highly fused mitochondria in co-transfected cells depended on Mfn1-fusion activity, the mitochondrial morphology in COS-7 cells co-transfected with MTP18-myc and GTPase mutant and therefore fusion-incompetent Mfn1-variant Mfn1K88T (Santel et al., 2003
) were analysed by immunofluorescence microscopy. The majority (87%) of Mfn1K88TMTP18-myc-expressing cells exhibited clearly fragmented mitochondria reflecting the MTP18-overexpression phenotype (Fig. 4D, lower row; Fig. 4E). The characteristic morphology of grape-like mitochondria as shown for MTP18-Mfn1-expressing cells was not observed, when GTPase-mutant Mfn1 was transiently coexpressed with MTP18.
Knockdown of MTP18 results in mitochondrial fusion
The presented overexpression and coexpression studies demonstrated that MTP18 might participate in controlling mitochondrial morphology by modulating the balance of fission and fusion. We have previously shown that overexpression of MTP18 can mediate mitochondrial fragmentation (Tondera et al., 2004). To test whether mitochondrial fission depends on MTP18 action, we analysed the effect of MTP18 loss-of-function in mammalian cells by shRNA-mediated RNA interference (for a review, see Dorsett and Tuschl, 2004
; Shi, 2003
). For this purpose, we transiently transfected HeLa cells with an expression construct that gives rise to high levels of double-stranded RNA specifically designed to target MTP18 mRNA (shRNA-MTP18). In the same manner, we generated shRNA expression constructs to target Mfn1 (shRNA-Mfn1) and Drp1 (shRNA-Drp1) as controls to compare loss-of-function effects on mitochondrial morphology. An unrelated shRNA (PI 3-kinase subunit p110
) was used as negative control (Czauderna et al., 2003
). The 2-day-long transient expression of these shRNA-expressing constructs in HeLa cells resulted in a clear and target-specific reduction of target protein levels as assessed by western blot; Fig. 5A shows two representative examples. At the same time protein levels of a non-target control protein, hFis1, were not affected (Fig. 5A).
For microscopic analysis, HeLa cells were transfected with the above mentioned shRNA expression constructs together with a GFP expression construct (to identify transfected cells) at the ratio 9:1. Transfected cell that showed reduced levels of Mfn1, Drp1 and MTP18 showed dramatic changes in mitochondrial morphology when compared with the non-related shRNA control sample (Fig. 5B). Reduction of the general mediator of mitochondrial fusion Mfn1 resulted in the fragmentation of mitochondria in approximately 80% of transfected GFP positive cells, whereas shRNA-Drp1-expressing cells (78%) displayed long interconnected filamentous mitochondrial network (Fig. 5B). For shRNA-Mfn1, the observed morphology resembled the phenotype described for mitochondria in Mfn1/ mouse embryonic fibroblast (MEFs) (Chen et al., 2003
) and cells transfected with synthetic siRNA molecules for RNAi (Eura et al., 2003
), whereas shRNA-Drp1 displayed the anticipated opposite effect of mitochondrial morphology.
Transient expression of shRNA-MTP18 gave rise to long mitochondrial filaments in approximately 90% of transfected cells, similar to the described effect for RNAi against Drp1 (Fig. 5B). The same result was confirmed with another shRNA-MTP18 sequence (data not shown). Therefore, we propose that RNAi-mediated MTP18 protein reduction results in uncontrolled fusion due to suppressed MTP18 fission activity. This observation is in agreement with our initial knockdown analysis of MTP18 in COS-7 cells using antisense molecules (Tondera et al., 2004). These RNAi data along with the overexpression results suggest that MTP18 is involved in mitochondrial fission.
hFis1 controlled mitochondrial fission appears to depend on MTP18
The level of MTP18 is crucial for hFis1-mediated mitochondrial fission. To study the influence of MTP18 on hFis1-mediated mitochondrial fission, we studied the knockdown effects of MTP18/hFis1 in combination with overexpression on mitochondrial morphology in transiently transfected HeLa cells (Fig. 6A). The mitochondrial hFis1 protein controls mitochondrial fission. Consequently, knockdown of hFis1 by shRNA-induced RNAi (Fig. 6A) resulted in the formation of long filamentous fused mitochondria (Fig. 6B upper row). By contrast, overexpression of hFis1 induced fragmented mitochondria in more than 90% of transfected cells (Fig. 6B, lower row). The fragmented mitochondria appeared round and swollen with an average size of 1.4 µm (s.d. 0.4 µm; n=60 mitochondria from two cells). Fragmented mitochondria in hFis1 transfected cells differed in size and morphology from those in MTP18 transfected cells giving rise to mitochondria with an average size of 0.7 µm (s.d. 0.1 µm; n=60). Notably, while overexpression of hFis1 finally led to cytochrome c release and apoptosis (data not shown) (James et al., 2003), overexpression of MTP18 had no effect on viability or apoptosis in transfected cells (Tondera et al., 2004
).
Transient overexpression of myc-tagged MTP18 in HeLa cells along with RNAi-mediated knockdown of hFis1 led to fragmentation in many of the transfected cells (50%). This result suggests that low levels of hFis1 are sufficient to facilitate MTP18-induced mitochondrial fission (Fig. 6C,E, red bars). By contrast, reduction of MTP18 opposed the hFis1-induced mitochondrial fission in cells that had been doubly transfected for the transient coexpression of shRNA-MTP18 and hFis1 protein (Fig. 6D,E, green bars). Compared with control cells and MTP18-shRNA-expressing HeLa cells that express endogenous hFis1 (Fig. 6C, arrows), elevated levels of hFis1 (Fig. 6C, double arrow; and Fig. 6A for western blot) had no effect on the highly filamentous morphology phenotype (
84% of hFis1-overexpressing cells with fused mitochondria and 4% with fragmented mitochondria in shRNA-MTP18/hFis1 doubly transfected cells) because of the suppressed MTP18 expression (Fig. 6E, green bars). Thus, the effect of hFis1 overexpression on mitochondrial morphology was suppressed by knockdown of MTP18. Based on these data, we conclude that reduced MTP18 expression abolished the mitochondrial fragmentation. Therefore, MTP18 appears to be required for the mitochondrial fission process.
MTP18 as a novel intramitochondrial component for mitochondrial fission
Drp1 is responsible for mitochondrial fission. As shown above, dominant negative activity of Drp1K38A can partially block MTP18 induced mitochondrial fission. Overexpression of MTP18 in HeLa cells with reduced Drp1 levels (as assessed by western blot see Fig. 7A) revealed fused mitochondrial networks. Owing to loss of Drp1 function, fusion of mitochondria occurred (Fig. 7B, double arrow) but could not be disrupted by additional levels of MTP18 fission activity (Fig. 7B, arrow indicates MTP18-myc expressing cells). This result emphasises the requirement of Drp1 for carrying out the fission steps. MTP18-induced fission relies on Drp1, but apparently not on hFis1 in the employed transient assay system. In summary, our biochemical as well as RNAi and overexpression studies suggest that MTP18 is a novel intramitochondrial component contributing to the mitochondrial fission process.
![]() |
Discussion |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
We propose that MTP18 is a novel mitochondrial protein component involved in the maintenance of mitochondrial morphology by contributing to the control of mitochondrial fission. Changes in the expression levels of MTP18 by either overexpression or RNAi-mediated knockdown in mammalian cells affect mitochondrial morphology. The changes most probably interfere with the balance of mitochondrial fission and fusion. The effects on mitochondrial morphology caused by different levels of MTP18 are reminiscent of mitochondrial fission proteins: loss of MTP18 results in pronounced mitochondrial fusion due to the block of fission and consequently unopposed mitochondrial fusion. By contrast, high levels of MTP18 stimulate frequent mitochondrial fission, which results in a high number of fragmented mitochondria by overriding endogenous fusion processes. Furthermore, an increase of mitochondrial fusion activity, by either overexpressing the main mitochondrial fusion protein Mfn1 or the dominant negative form of the fission protein Drp1, antagonises MTP18-induced mitochondrial fission. These results indicate a functional role of MTP18 in controlling the balance of fission and fusion processes. Our applied transient assays in mammalian cells proves the contribution of MTP18 to the maintenance of mitochondrial morphology and resembles the genetic system in yeast used to study novel regulatory components of the mitochondrial morphology machinery. In addition, by using RNAi (shRNA-MTP18) together with protein overexpression (hFis1), we were able to show that MTP18 might be required for the mitochondrial fission process (Fig. 5). Nevertheless, RNAi only allows to assess the effect of protein reduction (knockdown), in contrast to `real' loss-of-function effects caused by null mutations in the endogenous gene. Therefore, further genetic analysis (e.g. gene knockout) is needed to confirm the hFis1-independent requirement of MTP18 in regulating mitochondrial fission.
Our biochemical and microscopic data imply that MTP18 is an integral protein residing inside mitochondria. MTP18 acts most probably as a component of the inner membrane (IM) facing the inner membrane space (IMS), but it is also conceivable that MTP18 is anchored to the mitochondrial outer membrane (OM) from the inner leaflet and exposed to the IMS. Since the number of predicted TM domains has not been fully determined, the exact localisation and TM topology of MTP18 remains to be clarified. Thus, it remains unclear, in which mitochondrial compartment the N-terminus and C-terminus reside. Since the antibody used in this study was raised against the entire protein, the exact localisation of the protein cannot be resolved in detail. A putative association of MTP18 as a bipartite TM protein of the outer membrane with both protein termini facing the intermembrane space is conceivable, if cytoplasmic portions of MTP18 were protected by peripheral outer membrane proteins from proteinase K digestion. Nevertheless, our results indicate that MTP18 does not act like Mfn1 as a `common' outer membrane protein in the proteinase-protection experiment (Fig. 2C). Furthermore, we observed that GFP-tagged MTP18 fusion protein appeared to be processed upon transient overexpression in mammalian cell culture (D.T., unpublished observation). This preliminary result points to the possibility that MTP18 might become processed during import or maturation inside the mitochondrion, which raises the possibility for differential sublocalisation inside the IMS compartment as reported for OPA1 (Satoh et al., 2003). The mitochondrial fusion protein OPA1/Mgm1 (Delettre et al., 2000
; Griparic et al., 2004
; Olichon et al., 2003
; Olichon et al., 2002
; Wong et al., 2000
; Wong et al., 2003
) has recently been discovered to be a target of the Rhomboid-like protease Rbd1/Pcp1 in yeast implying the occurrence of proteolytic cleavage mechanisms for the control of mitochondrial morphology (Herlan et al., 2003
; McQuibban et al., 2003
). An in-depth analysis with epitope-specific antibodies for MTP18 together with in-vitro import studies will clarify putative processing steps and reveal the exact topology of endogenous MTP18.
The intramitochondrial localisation of MTP18 suggests the following function during mitochondrial fission: it is conceivable that MTP18 is actively involved in setting up the fission complex inside the mitochondrion to allow division of both membranes. The RNAi experiments indicate that MTP18 is required to allow hFis1-induced fission, even if elevated levels of hFis1 are present. This result suggests that hFis1 function is not sufficient in setting up the division complex on the surface of the outer membrane, if MTP18 was lacking. In this scenario, a hypothesised mitochondrial division machinery that lacks the intramitochondrially localised MTP18-containing part cannot execute the fission step for both membranes. In other words, it is conceivable that MTP18 completes the set-up of a fission complex inside the mitochondrion by bridging division complexes of the outer membrane with intramitochondrial division components. Conversely, lack of the inner mitochondrial fission machinery abrogates complete fission and might only result in partial division of the mitochondrial outer membrane. This idea is in agreement with the observation, that overexpression of hFis1, in contrast to MTP18, results in the formation of differently appearing fragmented mitochondria, which finally release cytochrome c. For this reason, we speculate that MTP18 action might be the limiting step during the fission process. When overexpressed, MTP18 possibly promotes the assembly of complete fission machineries that are responsible for faithful mitochondrial division. Consequently, release of cytochrome c does not occur. Interestingly, overexpression of Drp1 itself does not increase mitochondrial fission, presumably owing to the lack of sufficient mitochondrial division components such as hFis1 for the outer membrane and MTP18 for the inner mitochondrial membrane/intramitochondrial compartment. This proposed mode of MTP18 action is reminiscent of MDM33, the yeast mitochondrial inner membrane protein. MDM33 was proposed to be involved in controlling the fission of the mitochondrial inner membrane by homotypic interaction, resulting in the constriction of the inner membrane (Messerschmitt et al., 2003). However, to date no homologue or orthologue of MDM33 is known in higher eukaryotes. The elucidation of the topology of MTP18 inside mitochondria and the identification of interacting proteins will help to clarify contribution of MTP18 to the fission process.
![]() |
Acknowledgments |
---|
![]() |
Footnotes |
---|
Present address: Serono Reproductive Biology Institute, Rockland, MA 02370, USA
![]() |
References |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Alexander, C., Votruba, M., Pesch, U. E., Thiselton, D. L., Mayer, S., Moore, A., Rodriguez, M., Kellner, U., Leo-Kottler, B., Auburger, G. et al. (2000). OPA1, encoding a dynamin-related GTPase, is mutated in autosomal dominant optic atrophy linked to chromosome 3q28. Nat. Genet. 26, 211-215.[CrossRef][Medline]
Bossy-Wetzel, E., Barsoum, M. J., Godzik, A., Schwarzenbacher, R. and Lipton, S. A. (2003). Mitochondrial fission in apoptosis, neurodegeneration and aging. Curr. Opin. Cell Biol. 15, 706-716.[CrossRef][Medline]
Chen, H. and Chan, D. C. (2004). Mitochondrial dynamics in mammals. Curr. Top. Dev. Biol. 59, 119-144.[Medline]
Chen, H., Detmer, S. A., Ewald, A. J., Griffin, E. E., Fraser, S. E. and Chan, D. C. (2003). Mitofusins Mfn1 and Mfn2 coordinately regulate mitochondrial fusion and are essential for embryonic development. J. Cell Biol. 160, 189-200.
Czauderna, F., Fechtner, M., Aygun, H., Arnold, W., Klippel, A., Giese, K. and Kaufmann, J. (2003). Functional studies of the PI(3)-kinase signalling pathway employing synthetic and expressed siRNA. Nucleic Acids Res. 31, 670-682.
Delettre, C., Lenaers, G., Griffoin, J. M., Gigarel, N., Lorenzo, C., Belenguer, P., Pelloquin, L., Grosgeorge, J., Turc-Carel, C., Perret, E. et al. (2000). Nuclear gene OPA1, encoding a mitochondrial dynamin-related protein, is mutated in dominant optic atrophy. Nat. Genet. 26, 207-210.[CrossRef][Medline]
Dorsett, Y. and Tuschl, T. (2004). siRNAs: applications in functional genomics and potential as therapeutics. Nat. Rev. Drug Discov. 3, 318-329.[CrossRef][Medline]
Eura, Y., Ishihara, N., Yokota, S. and Mihara, K. (2003). Two mitofusin proteins, mammalian homologues of FZO, with distinct functions are both required for mitochondrial fusion. J. Biochem. 134, 333-344.
Fantin, V. R., Berardi, M. J., Scorrano, L., Korsmeyer, S. J. and Leder, P. (2002). A novel mitochondriotoxic small molecule that selectively inhibits tumor cell growth. Cancer Cell 2, 29-42.[CrossRef][Medline]
Frank, S., Gaume, B., Bergmann-Leitner, E. S., Leitner, W. W., Robert, E. G., Catez, F., Smith, C. L. and Youle, R. J. (2001). The role of dynamin-related protein 1, a mediator of mitochondrial fission, in apoptosis. Dev. Cell 1, 515-525.[CrossRef][Medline]
Frieden, M., James, D., Castelbou, C., Danckaert, A., Martinou, J. C. and Demaurex, N. (2004). Ca(2+) homeostasis during mitochondrial fragmentation and perinuclear clustering induced by hFis1. J. Biol. Chem. 279, 22704-22714.
Griparic, L., van der Wel, N. N., Orozco, I. J., Peters, P. J. and van der Bliek, A. M. (2004). Loss of the intermembrane space protein Mgm1/OPA1 induces swelling and localized constrictions along the lengths of mitochondria. J. Biol. Chem. 279, 18792-18798.
Hales, K. G. and Fuller, M. T. (1997). Developmentally regulated mitochondrial fusion mediated by a conserved, novel, predicted GTPase. Cell 90, 121-129.[CrossRef][Medline]
Harder, Z., Zunino, R. and McBride, H. (2004). Sumo1 conjugates mitochondrial substrates and participates in mitochondrial fission. Curr. Biol. 14, 340-345.[CrossRef][Medline]
Herlan, M., Vogel, F., Bornhovd, C., Neupert, W. and Reichert, A. S. (2003). Processing of Mgm1 by the rhomboid-type protease Pcp1 is required for maintenance of mitochondrial morphology and of mitochondrial DNA. J. Biol. Chem. 278, 27781-27788.
James, D. I., Parone, P. A., Mattenberger, Y. and Martinou, J. C. (2003). hFis1, a novel component of the mammalian mitochondrial fission machinery. J. Biol. Chem. 278, 36373-36379.
Karbowski, M. and Youle, R. J. (2003). Dynamics of mitochondrial morphology in healthy cells and during apoptosis. Cell Death Differ. 10, 870-880.[CrossRef][Medline]
Karbowski, M., Lee, Y. J., Gaume, B., Jeong, S. Y., Frank, S., Nechushtan, A., Santel, A., Fuller, M., Smith, C. L. and Youle, R. J. (2002). Spatial and temporal association of Bax with mitochondrial fission sites, Drp1, and Mfn2 during apoptosis. J. Cell Biol. 159, 931-938.
Klippel, A., Escobedo, M. A., Wachowicz, M. S., Apell, G., Brown, T. W., Giedlin, M. A., Kavanaugh, W. M. and Williams, L. T. (1998). Activation of phosphatidylinositol 3-kinase is sufficient for cell cycle entry and promotes cellular changes characteristic of oncogenic transformation. Mol. Cell. Biol. 18, 5699-5711.
Labrousse, A. M., Zappaterra, M. D., Rube, D. A. and van der Bliek, A. M. (1999). C. elegans dynamin-related protein DRP-1 controls severing of the mitochondrial outer membrane. Mol. Cell 4, 815-826.[CrossRef][Medline]
McQuibban, G. A., Saurya, S. and Freeman, M. (2003). Mitochondrial membrane remodelling regulated by a conserved rhomboid protease. Nature 423, 537-541.[CrossRef][Medline]
Messerschmitt, M., Jakobs, S., Vogel, F., Fritz, S., Dimmer, K. S., Neupert, W. and Westermann, B. (2003). The inner membrane protein Mdm33 controls mitochondrial morphology in yeast. J. Cell Biol. 160, 553-564.
Mozdy, A. D. and Shaw, J. M. (2003). A fuzzy mitochondrial fusion apparatus comes into focus. Nat. Rev. Mol. Cell Biol. 4, 468-478.[CrossRef][Medline]
Mozdy, A. D., McCaffery, J. M. and Shaw, J. M. (2000). Dnm1p GTPase-mediated mitochondrial fission is a multi-step process requiring the novel integral membrane component Fis1p. J. Cell Biol. 151, 367-380.
Neupert, W. (1997). Protein import into mitochondria. Annu. Rev. Biochem. 66, 863-917.[CrossRef][Medline]
Olichon, A., Emorine, L. J., Descoins, E., Pelloquin, L., Brichese, L., Gas, N., Guillou, E., Delettre, C., Valette, A., Hamel, C. P. et al. (2002). The human dynamin-related protein OPA1 is anchored to the mitochondrial inner membrane facing the inter-membrane space. FEBS Lett. 523, 171-176.[CrossRef][Medline]
Olichon, A., Baricault, L., Gas, N., Guillou, E., Valette, A., Belenguer, P. and Lenaers, G. (2003). Loss of OPA1 perturbates the mitochondrial inner membrane structure and integrity, leading to cytochrome c release and apoptosis. J. Biol. Chem. 278, 7743-7746.
Pitts, K. R., Yoon, Y., Krueger, E. W. and McNiven, M. A. (1999). The dynamin-like protein DLP1 is essential for normal distribution and morphology of the endoplasmic reticulum and mitochondria in mammalian cells. Mol. Biol. Cell 10, 4403-4417.
Santel, A. and Fuller, M. T. (2001). Control of mitochondrial morphology by a human mitofusin. J. Cell Sci. 114, 867-874.
Santel, A., Frank, S., Gaume, B., Herrler, M., Youle, R. J. and Fuller, M. T. (2003). Mitofusin-1 protein is a generally expressed mediator of mitochondrial fusion in mammalian cells. J. Cell Sci. 116, 2763-2774.
Satoh, M., Hamamoto, T., Seo, N., Kagawa, Y. and Endo, H. (2003). Differential sublocalization of the dynamin-related protein OPA1 isoforms in mitochondria. Biochem. Biophys. Res. Com. 300, 482-493.[CrossRef][Medline]
Scorrano, L., Ashiya, M., Buttle, K., Weiler, S., Oakes, S. A., Mannella, C. A. and Korsmeyer, S. J. (2002). A distinct pathway remodels mitochondrial cristae and mobilizes cytochrome c during apoptosis. Dev. Cell 2, 55-67.[CrossRef][Medline]
Scott, S. V., Cassidy-Stone, A., Meeusen, S. L. and Nunnari, J. (2003). Staying in aerobic shape: how the structural integrity of mitochondria and mitochondrial DNA is maintained. Curr. Opin. Cell Biol. 15, 482-488.[CrossRef][Medline]
Sesaki, H. and Jensen, R. E. (1999). Division versus fusion: Dnm1p and Fzo1p antagonistically regulate mitochondrial shape. J. Cell Biol. 147, 699-706.
Shaw, J. M. and Nunnari, J. (2002). Mitochondrial dynamics and division in budding yeast. Trends Cell Biol. 12, 178-184.[CrossRef][Medline]
Shi, Y. (2003). Mammalian RNAi for the masses. Trends Genet. 19, 9-12.[CrossRef][Medline]
Smirnova, E., Shurland, D. L., Ryazantsev, S. N. and van der Bliek, A. M. (1998). A human dynamin-related protein controls the distribution of mitochondria. J. Cell Biol. 143, 351-358.
Smirnova, E., Griparic, L., Shurland, D. L. and van der Bliek, A. M. (2001). Dynamin-related protein Drp1 is required for mitochondrial division in mammalian cells. Mol. Biol. Cell 12, 2245-2256.
Stojanovski, D., Koutsopoulos, O. S., Okamoto, K. and Ryan, M. T. (2004). Levels of human Fis1 at the mitochondrial outer membrane regulate mitochondrial morphology. J. Cell Sci. 117, 1201-1210.
Suzuki, M., Jeong, S. Y., Karbowski, M., Youle, R. J. and Tjandra, N. (2003). The solution structure of human mitochondria fission protein Fis1 reveals a novel TPR-like helix bundle. J. Mol. Biol. 334, 445-458.[CrossRef][Medline]
Tieu, Q. and Nunnari, J. (2000). Mdv1p is a WD repeat protein that interacts with the dynamin-related GTPase, Dnm1p, to trigger mitochondrial division. J. Cell Biol. 151, 353-366.
Tieu, Q., Okreglak, V., Naylor, K. and Nunnari, J. (2002). The WD repeat protein, Mdv1p, functions as a molecular adaptor by interacting with Dnm1p and Fis1p during mitochondrial fission. J. Cell Biol. 158, 445-452.
Tondera, D., Santel, A., Schwarzer, R., Dames, S., Giese, K., Klippel, A. and Kaufmann, J. (2004). Knockdown of MTP18, a novel phosphatidylinositol 3-kinase-dependent protein, affects mitochondrial morphology and induces apoptosis. J. Biol. Chem. 279, 31544-31555.
Wong, E. D., Wagner, J. A., Gorsich, S. W., McCaffery, J. M., Shaw, J. M. and Nunnari, J. (2000). The dynamin-related GTPase, Mgm1p, is an intermembrane space protein required for maintenance of fusion competent mitochondria. J. Cell Biol. 151, 341-352.
Wong, E. D., Wagner, J. A., Scott, S. V., Okreglak, V., Holewinske, T. J., Cassidy-Stone, A. and Nunnari, J. (2003). The intramitochondrial dynamin-related GTPase, Mgm1p, is a component of a protein complex that mediates mitochondrial fusion. J. Cell Biol. 160, 303-311.
Yoon, Y., Krueger, E. W., Oswald, B. J. and McNiven, M. A. (2003). The mitochondrial protein hFis1 regulates mitochondrial fission in mammalian cells through an interaction with the dynamin-like protein DLP1. Mol. Cell. Biol. 23, 5409-5420.
Zuchner, S., Mersiyanova, I. V., Muglia, M., Bissar-Tadmouri, N., Rochelle, J., Dadali, E. L., Zappia, M., Nelis, E., Patitucci, A., Senderek, J. et al. (2004). Mutations in the mitochondrial GTPase mitofusin 2 cause Charcot-Marie-Tooth neuropathy type 2A. Nat. Genet. 36, 449-451.[CrossRef][Medline]
|