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First published online 15 July 2008
doi: 10.1242/jcs.026625

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Characterization of the mitochondrial protein LETM1, which maintains the mitochondrial tubular shapes and interacts with the AAA-ATPase BCS1L

¹ Department of Molecular Biology, Graduate School of Medical Science, Kyushu University, Fukuoka, Japan
² Laboratory of Zoology, Graduate School of Agriculture, Kyushu University, Fukuoka, Japan
³ Section of Functional Morphology, Faculty of Pharmaceuitical Science, Nagasaki International University, Nagasaki, Japan
⁴ Department of Physiology and Cell Biology, Tokyo Medical and Dental University, Tokyo, Japan
⁵ The Institute of Biological Sciences, University of Tsukuba, Ibaraki, Japan

^* Author for correspondence (e-mail: okat{at}cell.med.kyushu-u.ac.jp)

Accepted 19 May 2008

	Summary

Top Summary Introduction Results Discussion Materials and Methods References

 
LETM1 is located in the chromosomal region that is deleted in patients suffering Wolf-Hirschhorn syndrome; it encodes a homolog of the yeast protein Mdm38 that is involved in mitochondrial morphology. Here, we describe the LETM1-mediated regulation of the mitochondrial volume and its interaction with the mitochondrial AAA-ATPase BCS1L that is responsible for three different human disorders. LETM1 is a mitochondrial inner-membrane protein with a large domain extruding to the matrix. The LETM1 homolog LETM2 is a mitochondrial protein that is expressed preferentially in testis and sperm. LETM1 downregulation caused mitochondrial swelling and cristae disorganization, but seemed to have little effect on membrane fusion and fission. Formation of the respiratory-chain complex was impaired by LETM1 knockdown. Cells lacking mitochondrial DNA lost active respiratory chains but maintained mitochondrial tubular networks, indicating that mitochondrial swelling caused by LETM1 knockdown is not caused by the disassembly of the respiratory chains. LETM1 was co-precipitated with BCS1L and formation of the LETM1 complex depended on BCS1L levels, suggesting that BCS1L stimulates the assembly of the LETM1 complex. BCS1L knockdown caused disassembly of the respiratory chains as well as LETM1 downregulation and induced distinct changes in mitochondrial morphology.

Key words: BCS1L, LETM1, LETM2, Mitochondrial morphology, Respiratory chains

	Introduction

Top Summary Introduction Results Discussion Materials and Methods References

 
The leucine zipper EF-hand-containing transmembrane protein 1 (LETM1) gene was originally identified as one of the genes that are chromosomally deleted in patients with Wolf-Hirschhorn syndrome (WHS) (Endele et al., 1999). WHS is a congenital complex malformation syndrome characterized by growth delay, mental retardation, seizures, hypotonia and characteristic facial features, and is caused by the partial deletion of the distal short arm of chromosome 4 (Zollino et al., 2003). LETM1 protein is conserved between yeast and humans and is located in the mitochondria (Schlickum et al., 2004). The MDM38 gene, which encodes a yeast homolog of LETM1, was first identified by a mutation that caused enlarged mitochondria (Dimmer et al., 2002). The expression of LETM1 suppresses the growth defect of mdm38-deletion mutants on a non-fermentable carbon source, indicating that yeast Mdm38p is a functional counterpart of human LETM1 (Nowikovsky et al., 2004). The mdm38 mutation suppresses the growth deficiency caused by mutation in the MRS2 gene that encodes a mitochondrial membrane protein related to bacterial Mg²⁺ transporters (Waldherr et al., 1993; Gregan et al., 2001). Moreover, mitochondria isolated from the mdm38 mutant exhibit little potassium-acetate-induced swelling, suggesting that Mdm38p regulates mitochondrial K⁺/H⁺ exchange (Nowikovsky et al., 2004). However, Mdm38p binds to mitochondrial ribosomes, and a MDM38-gene deletion gives rise to impaired transport of mitochondrial proteins from the matrix, suggesting that Mdm38p has a critical role in protein export from the matrix (Frazier et al., 2006).

BCS1L is an AAA-ATPase that has a single hydrophobic segment, homologous to yeast Bcs1p. Mutations in the BCS1L gene cause three different human disorders: complex III deficiency, GRACILE syndrome and Björnstad syndrome. Complex III deficiencies are manifest in heterogeneous clinical presentations, such as neonatal proximal tubulopathy, hepatic involvement, and encephalopathy (de Lonlay et al., 2001). GRACILE syndrome is characterized by profound multisystem organ failure, including fetal growth retardation, lactic acidosis, aminoaciduria, cholestasis and abnormalities in iron metabolism (Visapää et al., 2002). Intriguingly, no defects in enzyme activity or oxygen consumption of the respiratory chains are found in patients with GRACILE syndrome. Björnstad syndrome is an autosomal recessive – but not lethal – disorder that is associated with sensorineural hearing loss and pili torti (Hinson et al., 2007). These various clinical presentations are consequences of different mutations in a single gene, BCS1L, suggesting that BCS1L functions in multiple cellular events through different downstream targets. In yeast, the bcs1 mutant was first identified as a respiratory-deficient mutant without spectroscopically discernible cytochrome b (Nobrega et al., 1992). Most subunits of the respiratory chains, which comprise five protein complexes (complex I to complex V), are encoded in the nucleus; only 13 subunits are encoded in mitochondrial DNA. The formation of stable complexes is coordinated by the insertion of subunits into the inner membrane, which is facilitated by several factors, including Oxa1p and chaperones (Tzagoloff, 1995; Yi and Dalbey, 2005). Yeast Bcs1p functions in loading the Rieske iron-sulfur (Fe-S) protein onto the subcomplex of complex III in an ATP-dependent manner (Cruciat et al., 1999). Despite the genetic relationship between BCS1L and human disorders with various characteristic features, the understanding of the molecular mechanisms of BCS1L is still insufficient to obtain an overview of its physiological roles.

Mitochondria are dynamic organelles that continuously divide and fuse, resulting in the maintenance of tubular network structures (Yaffe, 1999; Griparic and van der Bliek, 2001; Mozdy and Shaw, 2003). Extensive studies have led to the identification of several factors that directly regulate mitochondrial membrane fission and fusion (Yaffe, 1999; Jensen et al., 2000; Karbowski and Youle, 2003; Westermann, 2003; Zhang and Chan, 2007). Two of these factors, Drp1 (DNM1L) and OPA1, are dynamin-related proteins that control membrane fission and fusion, respectively (Frank et al., 2001; Olichon et al., 2003; Lee et al., 2004; Ishihara et al., 2006). Here, in HeLa cells, we demonstrated that LETM1 knockdown caused mitochondrial swelling and a reduction in the number of cristae structures. Interestingly, LETM1 downregulation had little influence on membrane fission and fusion machinery governed by Drp1 and OPA1. Moreover, LETM1 knockdown caused the disassembly of complexes I, III and IV of the respiratory chains, leading to decreased membrane potential. BCS1L interacted with LETM1, and its downregulation caused a deficiency in the formation of complexes I, III and IV (as in the LETM1 knockdown), suggesting that LETM1 and BCS1L cooperate in the biogenesis of respiratory chains. In addition, BCS1L has a distinct role in mitochondrial morphology. These findings provide crucial insight into the molecular mechanisms underlying human disorders caused by the loss of LETM1 and BCS1L.

View larger version (45K): [in this window] [in a new window]   Fig. 1. LETM1 is a mitochondrial inner-membrane protein. (A) Total cell lysates from HeLa cells transfected with vector (lane 1), LETM1 (lane 2) or LETM1-3HA expression plasmid (lane 3) were subjected to immunoblotting using anti-LETM1 antibody. Gray and black arrowheads indicate precursor and mature forms of LETM1, respectively. (B) HeLa cells were fixed, permeabilized and immunostained with antibody against LETM1 (a) and the mitochondrial matrix protein Hsp60 (b). Images were acquired using confocal microscopy. Scale bar, 10 µm. (C) Total lysate (T) from HeLa cells carrying the LETM2 expression plasmid was fractionated and separated into mitochondria-enriched (Mt), microsomal (Ms) and cytosolic (Cyto) fractions. These fractions were subjected to immunoblotting using antibodies against LETM1, LETM2, the mitochondrial outer-membrane protein Tom40, the mitochondrial inner-membrane protein Tim17, the ER protein Sec61β and the cytosolic protein H450. Gray and solid arrowheads indicate precursor and mature forms of LETM1, respectively. (D) The mitochondrial fraction prepared from HeLa cells was treated at 4°C for 30 minutes with trypsin at the indicated concentrations with (lanes 4, 8) or without 1% Triton X-100 (lanes 1-3, 5-7) under isotonic (Mitochondria) or hypotonic (Mitoplasts) conditions and analyzed by immunoblotting with antibodies against LETM1, Tim17, Hsp60 and the outer membrane protein Tom20.

	Results

Top Summary Introduction Results Discussion Materials and Methods References

By exogenously expressing LETM1 a slowly migrating band with a molecular mass of 83 kDa was detected in addition to the 70-kDa band (Fig. 1A, lane 2). When LETM1was expressed that had been C-terminally tagged with three hemagglutinin (HA) molecules (LETM1-3HA), two larger bands were also found (lane 3). On the basis of the deduced amino acid sequences, the molecular mass of LTEM1 was predicted to be 83,353. In subcellular fractionation, the 83-kDa band was detected only in the cytosolic fraction (Fig. 1C, gray arrowhead). These results suggest that LETM1 is synthesized as a cytosolic precursor with a presequence.

To examine the submitochondrial localization of LETM1, the mitochondrial fraction was treated with trypsin under either isotonic (mitochondria) or hypotonic (mitoplasts) conditions (Fig. 1D). An outer membrane protein, Tom20, was digested under both conditions, whereas the matrix protein Hsp60 was resistant to trypsin treatment even under the hypotonic condition. An inner-membrane protein, Tim17, was degraded only under the hypotonic condition. LETM1 was resistant to trypsin treatment under the isotonic condition, but was partially digested under the hypotonic condition (Fig. 1D, lane 7). All samples were degraded in the presence of Triton X-100 (Fig. 1D, lanes 4, 8), indicating that trypsin digests these proteins when the membrane integrity was lost. Together with the finding that LETM1 is resistant to alkaline extraction (data not shown), these results indicate that LETM1 is a mitochondrial inner-membrane protein. In addition, partial digestion of LETM1 under the hypotonic condition suggested LETM1 has a small and/or protease-resistant region exposed to the intermembrane space.

LETM1 downregulation causes mitochondrial swelling
To examine the roles of LETM1 in mitochondrial morphology, LETM1 gene expression was knocked down in RNA interference (RNAi) experiments. LETM1 was reduced by more than 90% after a single transfection with siRNA specifically targeting LETM1 (Fig. 2A). Because mitochondrial structures are fragile, cell fixation often induced mitochondrial fragmentation and subsequent aggregation, which is not easy to distinguish from swelling. To avoid technical problems, we used a HeLa cell line that stably expressed the mitochondria-targeted fluorescent protein Su9-DsRed, to visualize the morphology without requiring cell fixation (Taguchi et al., 2007). Mitochondria usually formed tubular network structures in control cells (Fig. 2Ba). With LETM1 knockdown, mitochondria became dot-like structures and lost their tubular networks (Fig. 2Bb). More than 80% of cells exhibited such dot-like structures after transfection with LETM1 siRNA (Fig. 2C). The tubular networks were partially restored by the introduction of LETM1 cDNA (Fig. 2Bc), but not by the introduction of the cDNA that encodes mitofilin, a mitochondrial inner-membrane protein (data not shown), which indicates that the dot-like structures of mitochondria are caused by LETM1 downregulation. Thus, LETM1 is crucial in the maintenance of mitochondrial tubular networks.

View larger version (50K): [in this window] [in a new window]   Fig. 2. LETM1 downregulation causes mitochondrial swelling. (A) Total-cell lysates from HeLa cells transfected once or twice with siRNA for either GFP (mock) or LETM1 were subjected to immunoblotting with antibodies to LETM1 and GAPDH as a loading control. (B) HeLa cells that stably expressed mitochondrion-targeted Su9-DsRed were transfected with siRNA targeting either GFP (a, control) or LETM1 (b). Then, the expression plasmid, which coexpressed LETM1 and nucleus-targeted GFP, was introduced into the cells transfected with the LETM1-targeting siRNA (c). Live images were obtained by confocal microscopy. Typical images were superimposed. Scale bar, 10 µm. (C) Cells transfected with siRNA (as described for B) were analyzed by immunofluorescence microscopy. Data represent the mean ± s.e. of three independent experiments; 100-200 individual cells were counted. (D) HeLa cells expressing Su9-DsRed were transfected with siRNAs targeting DRP1 (a), DRP1 and LETM1 (b), OPA1 (e), OPA1 and LETM1 (f), or LETM1 (panel d). After siRNA transfection, the plasmid expressing Drp1(K38A)-EGFP was transfected (c,d). Live images were collected by confocal microscopy. Arrowheads indicate large dot structures on the filaments, asterisks indicate cells expressing Drp1-EGFP. Scale bar, 10 µm. Data represent the mean ± s.e. of three independent experiments; 100-200 individual cells were counted. (E) HeLa cells transfected with siRNA targeting GFP (a-d) or LETM1 (e-h) were fixed, permeabilized and immunostained using antibodies against the inner membrane protein mitofilin and the matrix protein mtHsp70. Scale bar, 10 µm. (F) HeLa cells transfected with siRNA targeting either GFP (a, control) or LETM1 (b,c) were fixed and thin sections were visualized by electron microscopy. Arrowheads indicate swollen mitochondria. Scale bar, 950 nm. (G) Cells stably expressing Su9-DsRed were transfected with plasmid expressing LETM1-EGFP and analyzed by confocal microscopy. Inset, sigh-magnification image. Arrowhead indicates the cell overexpressing LETM1-EGFP. Scale bar, 10 µm.

To further examine whether LETM1 knockdown causes mitochondrial swelling, mitochondria were immunostained with antibodies against mitofilin and mtHsp70. If the dot-like structures were swollen mitochondria, mitofilin should be observed in the outline of these structures whereas mtHsp70 should be observed inside these structures. In control HeLa cells, both proteins clearly colocalized in the tubular networks. By contrast, mitofilin staining was observed at the outline of the large dot-like structures in LETM1-knockdown cells, whereas the interior of the large dots was immunostained with antibody against mtHsp70 (Fig. 2Ef; arrowhead), indicating that mitochondria are swollen in LETM1-knockdown cells. To further investigate these mitochondrial structures, LETM1-knockdown cells were analyzed using conventional electron microscopy. Mitochondria were larger and had fewer cristae in LETM1-knockdown cells compared with control cells (Fig. 2Fa,b). The few remaining cristae were not straight and were often twisted (Fig. 2Fc). Thus, LETM1 downregulation causes the disorganization of cristae structures, as well as mitochondrial swelling. In addition, the apoptotic release of cytochrome c was significantly stimulated by LETM1 knockdown (data not shown), supporting the theory that cristae formation is impaired by inactivation of LETM1.

Because LETM1 knockdown affected mitochondrial morphology, we examined the effects of LETM1 overproduction on mitochondrial morphology by introducing a LETM1-GFP fusion protein into HeLa cells stably expressing Su9-DsRed. In those cells that overexpress LETM1-GFP, mitochondria were clearly fragmented but were not swollen (Fig. 2Ga; superimposed). Thus, changes in LETM1 expression cause the loss of mitochondrial tubular networks.

LETM2 is a mitochondrial protein that is expressed specifically in testis and sperm
During cloning of the LETM1 cDNA, we found a rat chromosomal region that was homologous to human LETM1 cDNA. Similarly, a specific region in human chromosome 8 is reported to be homologous to the crucial WHS region that contains the LETM1 gene (Stec et al., 2001). Because the putative proteins encoded in the rat chromosomal region did not contain an ortholog of human LETM1, we attempted to clone a cDNA sequence that is homologous to the LETM1 gene. Using rat total RNA, we amplified a PCR product that contained a coding region for a 459 amino acid polypeptide with a single hydrophobic segment (Fig. 3A). The protein encoded by the cDNA exhibited 32% overall similarity to human LETM1 protein; higher similarity (53.6%) was found for the region between the hydrophobic segment and a putative leucine-zipper domain. The gene in human chromosome 8 has already been named LETM2, although the entire protein is still unidentified (Stec et al., 2001). Therefore, we named our cloned gene product rat LETM2 to avoid confusion in the nomenclature. We also cloned a cDNA for a splicing variant of LETM2 that lacked a 48 amino acid internal domain with a hydrophobic segment (Fig. 3A); this variant was named LETM2S.

View larger version (47K): [in this window] [in a new window]   Fig. 3. LETM2 is a mitochondrial protein that is expressed preferentially in testis and sperm. (A) Scheme of LETM1, LETM2, and LETM2S. Red, blue, orange and green boxes represent putative presequences, hydrophobic segments, leucine-zipper motifs and EF-hand motifs, respectively. (B) Poly(A) RNA from adult rat tissues was hybridized using a radioactive probe recognizing LETM2. The blot was also hybridized with a control probe recognizing β-actin. (C) Total-cell lysates from various rat tissues were subjected to immunoblotting using antibodies against LETM2, LETM1 and GAPDH. (D) Total cell lysates from the indicated cell lines were analyzed by immunoblotting using antibodies against LETM2, LETM1 and Hsp60. (E) Total-cell lysates from HeLa cells transfected with vector (lane 1), or with plasmid expressing LETM2 (lane 2) or LETM2S (lane 3), and rat testis homogenates (lane 4) were subjected to immunoblotting using anti-LETM2 antibody. Black and gray arrowheads indicate LETM2 and LETM2S, respectively. (F) HeLa cells transfected with LETM2 (a-c) or LETM2S expression plasmid (d-f) were fixed, permeabilized and immunostained with antibodies against LETM2 and cytochrome c. Images were collected using confocal microscopy. Scale bar, 10 µm.

None of the cultured cell lines tested by us expressed LETM2. Therefore, LETM2 was exogenously expressed in HeLa cells to determine the intracellular localization. A 45-kDa band was detected in HeLa cells transfected with the LETM2-expression plasmid, but not in cells with the vector, and was the same molecular size as that found in rat testis (Fig. 3E). In addition to the 45-kDa band, a 50-kDa band was observed when exogenously expressing LETM2, suggesting that LETM2 is synthesized as a precursor. LETM2S was expressed as a 39-kDa band when the plasmid carrying LETM2S cDNA was introduced. Immunofluorescence microscopy showed that LETM2 colocalized with cytochrome c (Fig. 3F). In subcellular fractionation, LETM2 was recovered mainly in the mitochondrial fraction (Fig. 1C). Similar results were obtained for the intracellular distribution of LETM2S (data not shown). Thus, LETM2 and LETM2S that were exogenously expressed in HeLa cells both target the mitochondria.

To determine the cellular localization of endogenous LETM2, immunohistochemical analysis of frozen sections of rat testis was conducted using anti-LETM2 antibody. In the seminiferous tubules, immunostaining of LETM2 was detected in spermatocytes and elongating spermatids (Fig. 4Aa,e). No signal was obtained by immunostaining using pre-immune serum. Thus, LETM2 is expressed specifically in cells that undergo spermatogenesis and spermiogenesis. LETM2 was also found in middle pieces of purified spermatozoon (Fig. 4B). Immunoelectron microscopy revealed that LETM2 was observed in the mitochondria of spermatozoa (Fig. 4C). Together with the mitochondrial localization of LETM2 in HeLa cells, these results indicate that endogenous LETM2 is a mitochondrial protein that is expressed in the developmental stages from spermatocyte to spermatozoon.

View larger version (44K): [in this window] [in a new window]   Fig. 4. LETM2 is localized in spermatogenic cells and spermatozoa. (A) Frozen sections of rat testis were immunostained using anti-LETM2 antibody (a,b,e,f) and preimmune serum (c,d). Samples were also counterstained using SYTOX Green to visualize nuclear DNA (b,d,f). Scale bar, 30 µm. (B) Purified rat spermatozoa were immunostained using antibodies against LETM2 (a,b) and tubulin (b,d). Images containing the principle (P) and middle pieces (M) of spermatozoa are shown. Scale bar, 20 µm. (C) Vertical sections (a) and cross sections (b,c) of rat spermatozoa were immunogold-labeled using anti-LETM2 antibody and preimmune serum. Arrows indicate mitochondria. A, axoneme; ODF, outer dense fiber. Scale bar, 0.1 µm.

LETM1 is crucial for the assembly of supercomplexes of the respiratory chains
LETM1 downregulation caused a reduction in the number of, and morphological changes in, cristae. We therefore examined the effects of LETM1 knockdown on the mitochondrial membrane potential by using Mitotracker Red CMXRos, a membrane-potential-dependent mitochondrial vital dye (Fig. 5A). In control cells, staining with Mitotracker was clearly observed at concentrations ranging from 5-20 nM. By contrast, LETM1-knockdown cells were substantially stained with Mitotracker, only at a concentration of 20 nM. Treatment with 10 nM Mitotracker resulted in faint staining of mitochondria when LETM1 was repressed. Similar results were obtained using TMRM, another membrane-potential-dependent mitochondrial dye (supplementary material Fig. S2). Thus, the membrane potential in LETM1-siRNA-transfected cells is substantially lower than that in control cells, which is consistent with previous reports that isolated mitochondria from yeast mdm38 mutants that exhibit low membrane potential (Nowikovsky et al., 2004; Frazier et al., 2006).

View larger version (52K): [in this window] [in a new window]   Fig. 5. LETM1 is required for the assembly of the respiratory chain. (A) HeLa cells transfected with siRNA targeting GFP (control) or LETM1 were incubated for 60 minutes with Mitotracker Red CMXRos at the indicated concentrations, washed, fixed and analyzed by immunofluorescence microscopy with anti-mitofilin antibody. The uptake of Mitotracker Red CMXRos clearly decreased in the LETM1 knockdown cells. Fluorescent images were obtained by confocal microscopy. (B) Total cell lysates from cells transfected with siRNA targeting GFP (control) or LETM1 were subjected to SDS-PAGE and immunoblotted using antibodies to the indicated proteins. LETM1 knockdown caused reduction in the supercomplexes of the respiratory chains. (C) Mitochondrial fractions from cells transfected with siRNA targeting GFP (control) or LETM1 were digitonin-solubilized, centrifuged, subjected to Blue-Native gel electrophoresis and immunoblotted with antibodies against the indicated proteins. Arrowhead indicates the supercomplexes of complexes I, III and IV. Asterisk indicates a nonspecific band that was found even when BCS1L was repressed (see Fig. 8B). (D) Mitochondrial fractions from cells transfected with siRNA targeting GFP (control) or LETM1 were treated with alkaline buffers ranging in their pH values between 11.5 and 12.5, centrifuged for separation into supernatant (S) and pellet fractions (P), and immunoblotted with antibodies against the indicated proteins. The membrane association of core1 protein was affected by LETM1 downregulation.

The levels of the respiratory chain subunits tested were essentially normal, but the formation of complexes I, III and IV was clearly defective in LETM1-knockdown cells. Therefore, we examined the protein stability and membrane association of the subunits. Unfortunately, there were no differences in sensitivity to trypsin treatment between control and LETM1-knockdown cells for the subunits tested. The association with the inner membrane was thus analyzed carrying out alkaline extraction using buffers with pH ranges between 11.5 and 12.5 (Fig. 5D). As expected, complex IV subunit IV, a protein with a single transmembrane domain, was resistant to alkaline extraction, as was the integral membrane protein Tim17. By contrast, complex V -subunit, a peripheral protein, was mainly recovered in the supernatant fraction of the extractions. Although the core1 protein of complex III has no significant hydrophobic segment, it was resistant to alkaline extraction using buffer at pH 11.5. Extraction with buffer at pH 12.0 resulted in the recovery of half of the core1 protein in the supernatant fraction. By contrast, in LETM1-knockdown cells, most core1 protein was retained in the membrane fraction upon the same treatment. Core1 protein was eventually extracted with buffer at pH 12.5, even in LETM1-knockdown cells. The tested subunits of complex I and II were not affected by alkaline extraction (data not shown). Thus, LETM1 knockdown facilitates the tight association of at least core1 protein with the inner membrane, suggesting that this tight association interrupts the formation of complex III.

View larger version (50K): [in this window] [in a new window]   Fig. 8. BCS1L downregulation causes supercomplex disassembly and abnormal mitochondrial morphology. (A) Total cell lysates from cells transfected with siRNA targeting GFP (control) or BCS1L were immunoblotted with antibodies to the indicated proteins. BCS1L knockdown caused reduction in the supercomplexes of the respiratory chains. (B) Mitochondrial fractions from cells transfected with siRNA targeting GFP (control) or BCS1L were solubilized with digitonin, subjected to Blue-Native gel electrophoresis, and immunoblotted using antibodies against the indicated proteins. Arrowhead indicates supercomplexes of Complex I, III, and IV. Asterisk indicates a nonspecific band. (C) HeLa cells that stably expressed Su9-DsRed were transfected with siRNA for GFP (panel a), BCS1L (panels b,c,d), LETM1 (panel e), or BCS1L and LETM1 (panel f), and further transfected with plasmid co-expressing BCS1L and nucleus-targeted GFP (panel b). BCS1L knockdown induced abnormal mitochondrial morphology. Live images were acquired by confocal microscopy. Typical images are shown in insets at high magnification. Scale bar, 10 µm. (D) Cells transfected with BCS1L siRNA were analyzed by immunofluorescence microscopy. Data represent the mean ± s.e. of three independent experiments; 100-200 individual cells were counted. (E) Model of the functions of BCS1L and LETM1 in mitochondrial biogenesis. Blue arrows indicate functions reported here; gray arrow indicates the BCS1L function reported previously (Cruciat et al., 1999; de Lonlay et al., 2001).

View larger version (42K): [in this window] [in a new window]   Fig. 6. Mitochondrial tubular networks are maintained in 0 HeLa cells. (A) Total cell lysates from wild-type or 0 HeLa cells were analyzed by immunoblotting using antibodies targeting the indicated proteins. 0 HeLa cells completely lost the supercomplexes. (B) Mitochondrial fractions from wild-type or 0 HeLa cells were digitonin-solubilized, subjected to Blue-Native gel electrophoresis, and immunoblotted with antibodies against the indicated proteins. Arrowhead indicates the supercomplexes of complexes I, III and IV. (C) The 0 HeLa cells transfected with the plasmid carrying Su9-DsRed were analyzed by confocal microscopy. 0 HeLa cells maintain mitochondrial tubules, which are not expanded. Scale bar, 10 µm. (D) The 0 HeLa cells were fixed, and thin sections were visualized by electron microscopy. Arrowheads indicate mitochondria. Scale bar, 950 nm.

The AAA-ATPase BCS1L interacts with LETM1 and stimulates the formation of the LETM1 complex
In yeast, the AAA-ATPase Bcs1p has a role in the assembly of Rieske Fe-S protein into precomplexes of complex III in an ATP-dependent manner (Cruciat et al., 1999). In addition, mutations in the BCS1L gene cause three different human disorders (de Lonlay et al., 2001; Visapää et al., 2002; Hinson et al., 2007). Because BCS1L and LETM1 are mitochondrial inner-membrane proteins that are responsible for both human disorders and the assembly of respiratory chains, we examined the interaction of LETM1 with BCS1L. After transfection of plasmids that express C-terminal three-FLAG-tagged BCS1L (BCS1L-3FLAG) or the three-FLAG-tagged version of the inner-membrane protein AIF (AIF-3FLAG), immunoprecipitation using anti-FLAG antibody was carried out. Endogenous LETM1 was co-precipitated with BCS1L-3FLAG, but not AIF-3FLAG (Fig. 7A). By contrast, other inner membrane proteins, including the 39-kDa subunit of complex I, complex III core 1 protein and Tim44, were not co-precipitated with BCS1L. Thus, BCS1L interacts specifically with LETM1. Furthermore, the interaction with LETM1 was abolished by a BCS1L point mutation in which proline was substituted for argenine at position 155 (R155P; Fig. 7B); one of four mutations found in patients with complex-III deficiencies (de Lonlay et al., 2001). The ATPase-deficient mutant K236A (lysine substituted for argenine at position 236) of BCS1L was still able to pull down LETM1, suggesting that ATP hydrolysis is not required for the interaction between BCS1L and LETM1. Immunofluorescence microscopy showed that BCS1L-3FLAG was localized to the mitochondria, as was endogenous BCS1L (Fig. 7Ca,v). All BCS1L mutants were also targeted to the mitochondria (Fig. 7, panels d-u), although the expression of BCS1L(R155P)-3FLAG induced mitochondrial fragmentation and aggregation, indicating that these mutations have little influence on the mitochondrial localization of BCS1L.

View larger version (47K): [in this window] [in a new window]   Fig. 7. BCS1L interacts with LETM1 and stimulates the formation of the LETM1 complex. (A) Cell lysates from HeLa cells transfected with vector, BCS1L-3FLAG or AIF-3FALG expression plasmid were subjected to immunoprecipitation (Immppt) using anti-FLAG antibody. Precipitates were analyzed by immunoblotting using antibodies against the indicated proteins. HC, immunoglobulin heavy chains. LETM1 interacts with BCS1L. (B) Cell lysates from cells expressing wild-type BCS1L or the indicated BCS1L mutants were analyzed by immunoprecipitation (Immppt) using anti-FLAG antibody and immunoblotting. The mutation in BCS1L disrupted interaction with LETM1. (C) HeLa cells transfected with the expression plasmid carrying wild-type BCS1L or the indicated BCS1L mutants were fixed, permeabilized and immunostained using antibodies against FLAG (a,d,g,j,m,p,s) and the mitochondrial protein mtHsp70 (b,e,h,k,n,q,t). Untransfected HeLa cells were also analyzed by immunofluorescence microscopy using antibodies against BCS1L (v) and mtHsp70 (w). Scale bar, 10 µm. BCS1L mutations did not influence its mitochondrial localization. (D) HeLa cells transfected with BCS1L siRNA (lanes 1, 5, 9), GFP siRNA (lanes 2, 6, 10), or BCS1L expression plasmid (lanes 4, 8, 12) were analyzed by either SDS-PAGE (left panel) or Blue-Native gel electrophoresis (right panels) and immunoblotting using antibodies against LETM1, BCS1L and Tom40 as a loading control. Formation of the LETM1 complex was dependent on BCS1L.

LETM1 formed the major (300 kDa) and minor (500-600 kDa) complexes (Fig. 5C). The overexpression of BCS1L-3FLAG stimulated the formation of the major complex, but the amount of LETM1 was essentially unaffected (Fig. 7D, lanes 4 and 8). Conversely, BCS1L knockdown caused decreases (50%) in both the amount of LETM1 and the formation of LETM1 major complex (Fig. 7D, lanes 1 and 4). Pulse chase experiment also indicated the instability of LETM1 in BCS1L-knockdown cells (supplementary material Fig. S3). Thus, the formation of the LETM1 major complex depends on the BCS1L level. Although BCS1L formed a 500-600-kDa complex on Blue-Native gel electrophoresis, LETM1 knockdown had little effect on the formation of the BCS1L complex (Fig. 5C), suggesting that in the native gel most BCS1L is not stably associated with LETM1 as a protein complex. These results indicate that BCS1L stimulates the assembly of the LETM1 complex.

BCS1L downregulation causes the disassembly of the supercomplexes and abnormal mitochondrial morphology
As expected from studies in yeast, BCS1L downregulation dramatically affected the assembly of the respiratory chains. Immunoblotting showed that the Rieske Fe-S protein of complex III and the complex-II 70-kDa subunit were significantly reduced; however, the other subunits tested, as well as Tom40, were unaffected by RNAi targeting BCS1L (Fig. 8A). The formation of the supercomplexes clearly decreased upon BCS1L knockdown, whereas the Tom complex, and complexes II and V were formed as usual (Fig. 8B). Interestingly, the amount of the 70-kDa subunit incorporated into complex II was not affected, although the total amount was reduced by BCS1L downregulation. Rieske Fe-S protein was hardly detected in any complexes corresponding to Complex III upon BCS1L knockdown (Fig. 8B). In the yeast bcs1 deletion mutants, non-assembled Rieske Fe-S protein is detected as monomer (Cruciat et al., 1999). Monomeric forms of the Rieske Fe-S protein, however, were undetectable in the BCS1L-knockdown cells. In addition, BCS1L downregulation did not influence amounts of the Rieske Fe-S protein recovered in the digitonin-insoluble fraction (supplementary material Fig. S4), suggesting that formation of aggregates including the Rieske Fe-S protein is not stimulated by BCS1L inactivation. Compared with the LETM1-knockdown cells (Fig. 5C), the decrease in the Rieske Fe-S protein of the supercomplexes was more severe in the BCS1L-knockdown cells (Fig. 8B). Thus, BCS1L downregulation causes the disassembly of the supercomplexes as does LETM1 knockdown, but the effects on the formation of the individual complexes differ. In particular, LETM1 might be responsible for the steps after loading of the Rieske Fe-S protein before formation of the supercomplexes.

The effects of BCS1L knockdown on mitochondrial morphology were analyzed using a HeLa cell line that stably expressed Su9-DsRed. When BCS1L was knocked down, more than 70% of mitochondria lost their network structures but did not swell, resulting in the formation of short, lumpy filaments with few branches (Fig. 8Cc,D). In addition, ring structures were frequently observed (Fig. 8Cd; inset). These mitochondrial morphologies were clearly different from those caused by LETM1 knockdown. Exogenous expression of BCS1L partially suppressed the morphological defects in the BCS1L-knockdown cells (Fig. 8Cb). Thus, BCS1L has a distinct role in the maintenance of mitochondrial morphology that is separate from the LETM1 function. Furthermore, the simultaneous knockdown of LETM1 and BCS1L resulted in a phenocopy with both features, i.e. short filaments associated with large dots at their edges (Fig. 8Cf), supporting that BCS1L and LETM1 function in different processes in the formation of tubular network structures, although BCS1L helps LETM1 in the formation of protein complexes.

	Discussion

Top Summary Introduction Results Discussion Materials and Methods References

 
In this study, we showed that LETM1 is a mitochondrial inner-membrane protein with a pre-sequence, which is consistent with recent reports (Dimmer et al., 2007; Hasegawa and van der Bliek, 2007). LETM1 downregulation caused mitochondrial swelling and the loss of tubular networks. The simultaneous knockdown of LETM1 and OPA1 showed that membrane fission is a dominant event, rather than swelling, even when most LETM1 protein had disappeared. Moreover, elongated mitochondria were maintained upon the downregulation of both LETM1 and Drp1, indicating that membrane fusion occurs independently of the loss of LETM1 function. These results strongly suggest that LETM1 is not involved directly in mitochondrial membrane fusion and fission, and imply that the disappearance of the tubular networks in LETM1-knockdown cells is caused by the expansion of the tubular structures. Recent study reported that the silencing together of Drp1 and LETM1 caused the loss of tubular networks, similar to the phenocopy caused by LETM1 knockdown (Dimmer et al., 2007), which is inconsistent with our findings. Under our conditions, Drp1 and LETM1 virtually disappeared (supplementary material Fig. S1) and more than 60% of cells had elongated mitochondria with large elongated mitochondria that had dilated tubules in part (Fig. 2D). The differences may be explained by the extent to which Drp1 was knocked down.

LETM1 downregulation induced a reduction in the number of cristae structures and the disassembly of respiratory chains. In particular, complexes I, III and IV failed to form supercomplexes. MDM38 gene deletion also causes defects in the formation of complexes III and IV; together with the association with mitochondrial ribosomes, it is proposed that Mdm38 functions in protein export from the matrix (Frazier et al., 2006). However, knockdown of OXA1L (the human ortholog of yeast Oxa1p), which is a central component of the protein export machinery, induced the severe disassembly of complex V and a moderate reduction in complex I (Stiburek et al., 2007), suggesting that LETM1 does not function in an OXA1L-mediated pathway of the export machinery. The ⁰ HeLa cells completely lost several respiratory chain complexes, but the mitochondrial tubular shapes were maintained, indicating that mitochondrial swelling caused by LETM1 knockdown is not caused by the failure of respiratory-chain assembly. Furthermore, we found that the disassembly of the respiratory chains proceeded slowly, rather than changes in mitochondrial morphology, with increasing LETM1 inactivation (supplementary material Fig. S5). When transfected once with the LETM1 siRNA, half of the cells had swollen mitochondria but the supercomplexes were normally assembled. In addition, the mitochondrial morphology is altered in the cells, with a 60% reduction in the amount of LETM1, but respiratory chain activity is unaffected (Dimmer et al., 2007). Thus, it is that the disassembly of the respiratory chains is likely to be a secondary effect of changes in mitochondrial morphology, especially in cristae structure. However, we cannot rule out that LETM1 is implicated directly in the assembly of respiratory chain because prolonged respiratory-chain stability may conceal the early effects of LETM1 downregulation.

Although mitochondrial swelling was induced by RNAi targeting LETM1, the molecular mechanisms of how LETM1 regulates mitochondrial volume still remains unclear. The addition of nigericin, an electroneutral ionophore, cancels mitochondrial swelling caused by the loss of yeast Mdm38 function in vivo and in vitro (Nowikovsky et al., 2004; Nowikovsky et al., 2007). In HeLa cells, treatment with nigericin also prevented mitochondrial swelling caused by LETM1 knockdown (supplementary material Fig. S6) (Dimmer et al., 2007). However, the addition of nigericin to mitochondria produced short filaments even in wild-type HeLa cells (supplementary material Fig. S6), suggesting that nigericin works on multiple aspects of mitochondrial morphology in HeLa cells. Furthermore, the simultaneous knockdown of DRP1 and LETM1 caused mitochondria to become elongated and partially swollen (Fig. 2D). Such mitochondrial morphology cannot be simply explained by increasing osmotic pressure in the matrix caused by impaired K⁺/H⁺-exchange activity. Our findings indicate that LETM1 is required for the maintenance of the tubular shape, cristae organization and assembly of the respiratory chain, leading to the possibility that LETM1 functions as a structural protein to maintain normal cristae structure. For example, lamins and lamin-associated proteins act as structural proteins in the nucleus and have scaffolding functions in the regulation of high-order chromatin (Vlcek and Foisner, 2007). LETM1 might fold the inner membranes by interacting with other factors and might scaffold the respiratory chains. As a consequence of LETM1 downregulation, the unfolding of cristae might induce the expansion of the tubular structures.

LETM2 is a mitochondrial protein that is expressed preferentially in spermatocytes and spermatozoa. On the basis of the deduced amino acid sequences, LETM2 is predicted to have a single hydrophobic segment. Analyses of alkaline extraction and protease protection indicated that, similar to LETM1, LETM2 is an inner-membrane protein (our unpublished data). Although LETM2 and LETM1 share common features (e.g. being a mitochondrial inner membrane protein, containing a leucine-zipper motif), mitochondrial swelling caused by LETM1 knockdown was not suppressed by the expression of LETM2 (our unpublished data), indicating that LETM2 cannot be replaced by LETM1. This is consistent with the observation that LETM1 is also expressed in testis (Fig. 3C). Why mitochondrial functions in testis and sperm require LETM2 still remains unclear. Mitochondrial morphology changes dramatically in rat germ cells; the mitochondria become rounded with the dilated intra-cristal spaces and inner space that contains a dense matrix, and are known as condensed mitochondria (De Martino et al., 1979). LETM2 might contribute to the reorganization of the inner and cristae membranes during spermatogenesis.

BCS1L was involved in the assembly of three respiratory-chain complexes (I, III and IV), as well as the LETM1 (major) complex. The clinical characterization of WHS patients strongly suggests a correlation between LETM1 and epileptic seizures (Rauch et al., 2001; South et al., 2007). Certain patients with GRACILE syndrome also exhibit neurological symptoms such as seizure (Visapää et al., 2002). These common features strongly suggest a functional relationship between BCS1L and LETM1. Indeed, LETM1 co-precipitated with BCS1L, and the interaction was abolished by the R155P mutation in BCS1L. Furthermore, the formation of the LETM1 complex depended on the level of BCS1L, whereas the amount of BCS1L was less affected by LETM1 knockdown, indicating that BCS1L stimulates the assembly of the LETM1 complex. Because LETM1 has been reported to interact with itself in vitro (Hasegawa and van der Bliek, 2007), BCS1L might induce the homo-oligomerization of LETM1. However, BCS1L downregulation caused changes in mitochondrial morphology that were different from those in LETM1-knockdown cells. In addition, the simultaneous knockdown of LETM1 and BCS1L produced distinct mitochondrial morphology comprising both features, which suggests that BCS1L contributes to the maintenance of mitochondrial tubular networks separately from an LETM1-dependent pathway.

We hypothesize a working model of the function of BCS1L and LETM1 in mitochondrial biogenesis (Fig. 8E). Because BCS1L is an AAA-ATPase, the following three functions are downstream targets: (1) respiratory chain assembly, (2) mitochondrial morphology maintenance and, (3) LETM1 complex formation. BCS1L functions directly in the formation of mitochondrial tubular networks, in addition to the assembly of the supercomplexes. LETM1 has a distinct role in maintenance of mitochondrial volume and shapes, which helps – in concert with BCS1L – to achieve the efficient assembly of the respiratory chains. Further investigation of LETM1-associated proteins is necessary to elucidate the physiological relations between the roles in mitochondrial biogenesis and the clinical presentation of human disorders.

	Materials and Methods

Top Summary Introduction Results Discussion Materials and Methods References

 
Cell culture and DNA transfection
HeLa cells and a Su9-DsRed-expressing cell line were maintained at 37°C in Dulbecco's modified Eagle's medium supplemented with 10% fetal bovine serum (FBS) and 4.5 mg/ml glucose. The ⁰ HeLa cells (EB8) (Hayashi et al., 1992) were cultured in RPMI160 supplemented with 10% FBS, 4.5 mg/ml glucose, 0.1 mg/ml pyruvate, and 50 µg/ml uridine. DNA transfection was carried out using FuGENE6 (Roche Diagnostics) according to the manufacturer's instructions.

cDNA cloning and plasmid construction of human LETM1, rat LETM2 and human BCS1L
A 2.2-kb DNA fragment containing the LETM1 coding region was amplified using a human EST clone (IMAGE 4126510; Invitrogen) as template and primers with the sequences 5'-CCGCGCCCGAATTCATGGCGTCC-3' and 5'-CCAGGCCAGTGCTCGAGGCTCTTCACCT-3'. The fragment was then cloned into pEGFP-N1 (Clontech) for the expression of LETM1-GFP fusion protein and pEF1-3HA in which the inserted gene was expressed as a three-tandem HA-tagged protein by the EF1 promoter. LETM1 cDNA was also cloned into pNucScrIII, a vector containing humanized Renilla green fluorescent protein (hrGFP; Stratagene) with three tandem SV40 nuclear-localization signals downstream of the internal ribosomal entry site (IRES) sequence, to co-express both hrGFP and LETM1. A 1.4-kb cDNA containing an LETM2 open reading frame was obtained by amplification using total RNA from rat testis, using the primers 5'-AAATATGGCCTTCTACAGTTATAATTCA-3' and 5'-TTAGGCTCCTTTTGAATTAGCCTTGCTG-3', and cloned into pBluescript II (Stratagene). After DNA sequence analysis, the coding regions for LETM2 and LETM2S were subcloned to yield constructs pEF1-LETM2 and pEF1-LETM2S, respectively. The nucleotide sequence data were deposited in the nucleotide sequence databases with the following accession numbers: rat LETM2, AB296367; rat LETM2S, AB296368. A 1.3-kb RT-PCR product encoding human BCS1L was obtained using total RNA from HeLa cells and cloned into p3FLAG-CMV14 (Sigma-Aldrich).

Preparation of antibodies
GST-LETM1 or GST-LETM2S-fusion protein were expressed in Escherichia coli BL21 (DE3) cells carrying pET41-LETM1 or pET41-LETM2S, and purified by SDS gel electrophoresis, electrically eluted from the gels, and used to immunize rabbits to generate antibodies. The antisera were affinity-purified by incubation with nitrocellulose membrane strips to which the antigen bound and were elution with 0.1 M glycine (pH 2.0).

Immunoblotting and immunofluorescence microscopy
Immunoblotting was performed as described previously (Oka et al., 2004).

Immunofluorescence microscopy was carried out essentially as described previously (Ungar et al., 2002), with the following modification: cells grown on glass coverslips were fixed at room temperature for 25 minutes with 4% paraformaldehyde, permeabilized by incubation with 0.1% Triton TX-100 for 10 minutes, and incubated with primary antibodies. After incubation with Alexa-conjugated secondary antibodies (Invitrogen), images were acquired using a confocal microscope Radiance 2000 (Bio Rad).

Subcellular localization
Subcellular fractionation was performed as described previously (Horie et al., 2002). To determine the intramitochondrial localization, the isolated mitochondria fraction was treated at 4°C for 30 minutes with 0, 50 or 150 µg/ml trypsin in the presence or absence of 1% Triton X-100 under isotonic and hypotonic conditions. After termination by the addition of 10% TCA, the precipitates were analyzed using SDS-PAGE and immunoblotting.

siRNA transfection
The following siRNA duplexes were transfected into HeLa cells using Lipofectamine 2000 (Invitrogen) according to the manufacturer's instructions: LETM1 (sense, 5'-CCAGCAAUGAGGAAAUCAUGCGUUU-3'; antisense, 5'-AAACGCAUGAUUUCCUCAUUGCUGG-3'), BCS1L (sense, 5'-GAGUGGACCUGAAGGAGUATT-3'; antisense, 5'-UACUCCUUCAGGUCCACUCTT-3'), OPA1 (Ishihara et al., 2006), and Drp1 (Taguchi et al., 2007). After incubation for 48 hours, the cells were harvested and used for immunoblotting. For Blue-Native gel electrophoresis and morphological analysis cells were transfected with siRNA at least twice.

Immunoprecipitation
Cells were harvested, solubilized at 4°C for 60 minutes with 1% digitonin in buffer A (20 mM HEPES-KOH, pH 7.4, 150 mM NaCl, and 10% glycerol), and centrifuged to remove insoluble materials. The resultant supernatant was incubated at 4°C for 120 minutes with anti-FLAG (M2) antibody, washed twice with 0.25% digitonin in buffer A, and rinsed with buffer A. The immunoprecipitates were analyzed by SDS-PAGE and immunoblotting.

Blue-Native gel electrophoresis
Blue-Native gel electrophoresis was carried out essentially as described previously (Schägger and von Jagow, 1991). Isolated mitochondria (1 mg/ml) were solubilized at 4°C for 60 minutes with 1% digitonin in buffer A, centrifuged at 100,000 g for 15 minutes, and subjected to electrophoresis on 3-12% gradient gels with 0.02% SERVA Blue G. After incubating at 60°C for 15 minutes with denaturing buffer (20 mM Tris-HCl, pH 6.8, 1% SDS, and 100 mM β-mercaptoethanol), the proteins were electrically transferred to PVDF membranes and analyzed by immunoblotting.

Northern blots
Northern blotting was carried out using multiple tissue blots (Clontech) as described previously (Oka et al., 2001). A 506-bp probe was prepared from LETM2 cDNA (between +875 and +1380 bp, numbering from the first letter of the initiation codon) and used for radioactive labeling.

Electron microcopy
Electron microscopy was carried out as described previously (Eura et al., 2003).

Immunohistochemistry and immunoelectron microscopy
Immunohistochemistry of rat testis and immunoelectron microscopy of spermatozoa were performed as reported previously (Doiguchi et al., 2002).

	Acknowledgments

 
We thank Hidenori Otera for helpful comments and discussion. This work was supported by grants from the Ministry of Education, Science and Culture of Japan, the Naito Foundation, and the Takeda Science Foundation.

	Footnotes

 
Supplementary material available online at http://jcs.biologists.org/cgi/content/full/121/15/2588/DC1

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