Abstract
Barth syndrome (BTHS) is a mitochondrial disorder that is caused by mutations in the tafazzin gene, which affects phospholipid composition. To determine whether this defect leads to alterations in the internal three-dimensional organization of mitochondrial membranes, we applied electron microscopic tomography to lymphoblast mitochondria from BTHS patients and controls. Tomograms were formed from 50 and 150 nm sections of chemically fixed lymphoblasts and the data were used to manually segment volumes of relevant structural details. Normal lymphoblast mitochondria contained well-aligned, lamellar cristae with slot-like junctions to the inner boundary membrane. In BTHS, mitochondrial size was more variable and the total mitochondrial volume per cell increased mainly due to clusters of fragmented mitochondria inside nuclear invaginations. However, mitochondria showed reduced cristae density, less cristae alignment, and inhomogeneous cristae distribution. Three-dimensional reconstruction of BTHS mitochondria revealed zones of adhesion of the opposing inner membranes, causing obliteration of the intracrista space. We found small isolated patches of adhesion as well as extended adhesion zones, resulting in sheets of collapsed cristae packaged in multiple concentric layers. We also found large tubular structures (diameter 30–150 nm) that appeared to be derivatives of the adhesion zones. The data suggest that mitochondrial abnormalities of BTHS involve adhesions of inner mitochondrial membranes with subsequent collapse of the intracristae space.
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Main
Barth syndrome (BTHS) is a mitochondrial disorder presenting with cardiomyopathy, skeletal muscle weakness, neutropenia, and growth retardation.1, 2, 3 This syndrome is caused by mutations in the tafazzin gene that has an X-linked recessive inheritance pattern.4 Although tafazzin is lacking a typical mitochondrial targeting signal, its mitochondrial localization has been demonstrated in yeast.5, 6, 7 The amino-acid sequence of tafazzin contains an acyltransferase motif, suggesting its involvement in lipid metabolism.8 Indeed, altered phospholipid composition was found in heart, skeletal muscle, platelets, lymphoblasts, and fibroblasts of BTHS patients.9, 10, 11 The phospholipid most affected by the disease is cardiolipin.
Cardiolipin is a phospholipid dimer with four fatty acids that is specifically localized in mitochondria. Cardiolipin is tightly bound to virtually all major proteins of the inner mitochondrial membrane, notably the solute carriers, the F0F1-ATPase, as well as respiratory complex III and IV (for a review, see Schlame et al).12 Only in the presence of cardiolipin are the respiratory complexes able to form stable oligomeric supercomplexes.13, 14 Thus, cardiolipin is thought to play an essential role in the supramolecular organization of the inner mitochondrial membrane. In most cardiolipin molecular species, only one or two types of fatty acids exist, which results in a high degree of molecular symmetry and structural uniformity.15 Cardiolipin molecules from patients with BTHS, however, lack these features; instead, they form multiple molecular species due to random attachment of fatty acids.15 BTHS patients also have a lower total concentration of cardiolipin. For instance, in lymphoblasts, cardiolipin decreases from 5.4 to 2.8% of total phospholipids.11
Given the role cardiolipin plays in the structural organization of the inner mitochondrial membrane, BTHS ought to have consequences for mitochondrial function and morphology. Indeed, tissue biopsies from BTHS patients have revealed mitochondria with pathologic cristae.1, 16, 17, 18, 19 Furthermore, a decrease in coupling efficiency between respiration and phosphorylation has been found.5, 20 In this study, we compare normal and BTHS lymphoblast mitochondria using electron microscopic tomography. This technique reveals aspects of the three-dimensional (3-D) mitochondrial structure, which remain unrecognized in conventional electron microscopy.21, 22, 23, 24
Materials and methods
Patients
Collection of blood samples was approved by institutional review boards of Johns Hopkins University and New York University Medical Center. The study was performed with four BTHS patients and four control subjects (age 1–9 years). Owing to the X-linked recessive nature of BTHS, all subjects were male. BTHS patients had a mutation in the tafazzin gene, which caused deletion of the protein. Patients presented with cardiomyopathy, and at least two of the noncardiac symptoms of BTHS, including skeletal myopathy, neutropenia, and growth retardation. Control subjects had a normal tafazzin gene and none of the symptoms of BTHS. They typically presented for work-up of unrelated neurologic conditions.
Lymphoblast Cultures
Lymphoblast cell lines were established by Epstein–Barr virus transformation of leukocytes isolated from whole blood using Ficoll-Hypaque gradients. The cell lines were cultured in RPMI 1640 medium at 37°C, in the presence of 10% fetal bovine serum, 50 IU/ml penicillin, 0.05 mg/ml streptomycin, and 5% CO2. The serum was heat-inactivated at 56°C for 30 min prior to use. Lymphoblasts were seeded at a density of 3 × 105 cells/ml and cultures were expanded every 2–3 days.
Specimen Preparation
Lymphoblasts were pelleted using a bench-top centrifuge operated at 3000 r.p.m. The pellets were washed with 0.1 M sodium cacodylate buffer (pH 7.4) and fixed for 30 min in primary fixative (3% glutaraldehyde, 0.2% tannic acid in 0.1 M sodium cacodylate buffer, pH 7.4) at room temperature. Pellets were washed three times for 10 min in 0.1 M sodium cacodylate buffer and then incubated for 60 min on ice in the secondary fixative (1% OsO4 in 0.1 M sodium cacodylate buffer, pH 7.4). The cell pellets were washed again three times for 10 min in 0.1 M sodium cacodylate buffer and then rinsed with water. Pellets were further fixed and stained en bloc in 1% aqueous uranyl acetate for 60 min. After the samples were fully dehydrated with a graded ethanol series (from 10 to 100%) at progressively lower temperatures (from 20°C to −35°C), they were infiltrated with LX-12 resin over a period of 18 h, slowly increasing the resin content to 100%. Resin blocks were heat cured at 60°C for 48 h and then sectioned to a thickness of either 50 or 150 nm. Sections were collected on plastic-coated copper EM grids and stained for 10 min with 2% uranyl acetate in water and for 2 min with Sato Lead Solution. Colloidal gold (10 nm) was randomly spread across the sections after treatment with 0.02% poly-L-lysine for 10 min. The sections were washed with water, and finally coated with a thin layer of evaporated carbon. Cell lines from controls and BTHS patients were prepared in parallel using the same conditions at every step.
Electron Microscopic Tomography
Grids were mounted on a high tilt sample holder (Fischione, Export, PA, USA) and the samples were imaged at 13 000–16 000 nominal magnification, using a Tecnai TF20 electron microscope (FEI Corporation, Hillsboro, OR, USA) equipped with a 4k × 4k CCD camera (TVIPS, Gauting, Germany). Tilt series were collected from −70 to 70 degrees, in one- or two-degree increments along two perpendicular tilt axes at 1.0–1.5 μm defocus, using EMMENU (TVIPS). Images from the tilt series were used to calculate 3-D density maps using the IMOD tomography package.25 Colloidal gold particles were used for fiducial alignment of images within each tilt series. Independent tomograms were calculated with data from each of the two orthogonal tilt axes, which were then combined according to the standard IMOD practice. Final combined tomograms were viewed using the program AMIRA (Mercury Computer Systems, San Diego, CA, USA). Features of interest were manually labeled on tomogram slices using the segmentation module to create colored 3-D renderings.
Results
First we examined mitochondria in normal lymphoblasts. As reported previously,20 mitochondria were localized in two subcellular compartments: near the plasma membrane and inside the nuclear invagination that is typically present in lymphoblasts (Figure 1a). The size of mitochondrial cross-sections varied between 0.1 and 2 μm2 (average: 0.48 μm2). Mitochondria contained groups of parallel cristae, which often extended through the entire body of the organelle (Figure 1b and c). We constructed tomograms of 50 nm-thick sections through mitochondria for 3-D structural analysis. These tomograms showed that the cristae had a predominantly lamellar architecture (Figure 2a–c). Cristae connected to the inner boundary membrane via lamellar junctions. These junctions were slot-like segments that protruded from the main crista body (Figure 2b and c). In addition, lymphoblast mitochondria contained tubular elements, which appeared to be outgrowths of lamellar cristae (Figure 2c and d). Some of these tubules were at least 50 nm long, as they penetrated the entire depth of the reconstructed volume.
In lymphoblasts from BTHS patients, the total mitochondrial volume expanded, particularly inside the nuclear invagination (Figure 1d). This observation was consistent with our previously published data, which we interpreted as mitochondrial proliferation,20 but mitochondrial swelling (Figure 1d–f) also may have contributed to the expansion of the mitochondrial volume. Furthermore, the size of mitochondrial cross-sections was more heterogeneous (Figure 1e and f). For instance, we found that the proportion of lymphoblasts that contained 20 or more mitochondrial cross-sections increased from 6% in controls to 38% in BTHS patients. At the same time, the number of giant mitochondria (cross-sections larger than 3 μm2) rose from 11 per 100 cellular cross-sections in controls to 48 per 100 cellular cross-sections in BTHS.
A typical cluster of pathologic BTHS mitochondria is shown in Figure 3. These mitochondria have a distinct morphology with a striking lack of inner membranes and a very poor alignment of cristae. The remaining cristae were concentrated around the mitochondrial periphery (Figure 3a). 3-D reconstructions of these mitochondria showed that the cristae retained a lamellar shape, but they were much more interconnected than in normal mitochondria, and they contained segments that were swollen or collapsed. In the collapsed segments, the intracrista space was completely obliterated due to close adhesion of the opposing inner membranes (Figure 3b–d). Furthermore, the central cavity of mitochondria contained a distinct population of membranes that formed wide-open tubes with a diameter of 30–150 nm (orange structures in Figure 3). These membranes appeared to be connected to the collapsed cristae (Figure 3b–d).
As mentioned above, giant mitochondria were observed more frequently in BTHS lymphoblasts. Some giant mitochondria had an onion-shaped morphology, in which we identified two zones with distinct cristae architecture. The first zone contained lamellar cristae that wrapped around the core of the organelle in multiple layers. The second zone contained a web of interconnected cristae with honeycomb appearance, in which reversal of the inner membrane curvature forced the matrix into tubular shape (Figure 4a). Both zones typically coexisted in a single giant mitochondrion. Giant mitochondria also displayed evidence of inner membrane adhesion. We found small patches of crista membrane contact zones (Figure 4b and c) as well as extended regions of membrane adhesion (Figure 4d). Morphological details of collapsed cristae are depicted in a collage of tomogram slices in Figure 5. The slices show that normal crista segments alternate with collapsed crista segments and that the collapse results from close apposition of the two membranes.
We also constructed tomograms of 150 nm-thick sections in order to probe the structural depth of cristae junctions. In normal lymphoblast mitochondria, cristae are connected to the inner boundary membrane by slit-like openings. These slits had the same width as the cristae (20–35 nm) and a length of at least 50 nm, but often exceeding 100 nm (Figure 6a). The same features of cristae junctions were found in BTHS mitochondria (Figure 6b). Furthermore, the 150 nm sections showed that the large tubes of BTHS mitochondria were interconnected, enclosing a continuous cavity with varying diameter and multiple branches. The membrane surrounding this cavity originated from the cristae (Figure 6c).
Discussion
In this paper, we provide new insight into the ultrastructure of lymphoblast mitochondria from both normal individuals and patients with BTHS. By using electron microscopic tomography, we were able to generate 3-D views of portions of the intramitochondrial space. Although in our study, the reconstructed volumes were smaller than in previous tomography works,26, 27, 28 the 3-D images enhanced the clarity of the structural framework and revealed novel pathologic features of BTHS mitochondria.
Pioneering electron microscopic tomography studies have demonstrated that mitochondrial cristae form either lamellar26, 27, 28 or amorphous23, 29 compartments that connect to the mitochondrial periphery by cristae junctions. These junctions are often tubules that form circular or elliptical openings to the inner boundary membrane.24, 26, 27, 29, 30, 31, 32, 33 In several mammalian mitochondria, these openings have a rather uniform size of 20–30 nm.29, 30, 31 However, slot-like junctions with variable lateral extension have been observed in Neurospora mitochondria.28, 34 Also, the cristae openings of liver mitochondria are not always circular,35, 36 but may form elongated slits.37 Human lymphoblast mitochondria have primarily lamellar cristae with occasional tubular elements, and they have slot-like cristae junctions of variable dimensions (Figures 2, 6). The morphology of lymphoblast mitochondria is consistent with the general concept that only segments of the cristae connect to the inner boundary membrane (cristae junctions). However, the dimensions of these cristae junctions may be tissue-specific or depend on the status of the mitochondria.
Most importantly, we found abundant evidence of abnormal cristae architecture in BTHS. This may be directly related to the deficiency of cardiolipin, because this lipid is concentrated in the inner mitochondrial membrane. The tomograms suggest a specific mechanism of cristae reorganization, namely obliteration of the intracristae space by adhesion of the two opposing cristae membranes, which compromises the continuity of the intracrista space and its connection to the peripheral intermembrane space. As the intracrista space is important for the transfer of substrates in and out of mitochondria, the collapsed cristae may be metabolically inactive. Cristae collapse may also be the explanation for the bundles of stacked inner membrane sheets, which were seen in heart mitochondria from BTHS patients19 and in wing muscles from tafazzin-deficient Drosophila.38 Although the mitochondrial morphology in lymphoblasts is different from muscle and heart, the mechanism of cristae destruction may be similar, that is, obliteration of the intracristae space due to cristae membrane adhesion and stacking of the collapsed cristae. Perhaps, close apposition of membranes may be triggered by protein aggregation. In BTHS, deficiency of cardiolipin may predispose to protein aggregation because cardiolipin is essential for the correct supramolecular organization of protein complexes in the inner membrane.13, 14 Alternatively, the absence of tafazzin itself may cause membrane adhesion because tafazzin is associated with inner and outer membrane surfaces of the intermembrane space.39
We do not know whether the ultrastructural changes of BTHS mitochondria are specific for this disease or whether they reflect a general pattern of destruction in pathologic mitochondria. Bissler et al19 reported that mitochondrial abnormalities of BTHS presented with a specific morphology that can be differentiated from other dilated cardiomyopathies. However, certain morphologic features seem to repeat themselves in many mitochondrial diseases, for instance, segregated compartments, similar to the large tubular structures in Figure 3.21 Likewise, onion-shaped giant mitochondria have been observed in a variety of pathologic states, including ATP synthase deficiency,40 aging, hyperoxia,41 and others, although the exact morphology may not be identical in all instances. Onion-like structures likely reflect a lack of cristae junctions.42 BTHS mitochondria also show features that have previously been observed in association with apoptosis,36 such as matrix swelling and an apparent unfolding of the inner membrane (Figure 3) as well as an inversion of the cristae curvature (Figure 4).
In conclusion, we established that adhesions of the inner membranes are a dominant feature of pathologic mitochondria in BTHS lymphoblasts. Membrane adhesions occur in mitochondria of various sizes, including giant ones with onion-like appearance. More work is required to establish whether or not cristae collapse is a general phenomenon associated with mitochondrial diseases.
References
Barth PG, Scholte HR, Berden JA, et al. An X-linked mitochondrial disease affecting cardiac muscle, skeletal muscle and neutrophil leukocytes. J Neurol Sci 1983;62:327–355.
Kelley RI, Cheatham JP, Clark BJ, et al. X-linked dilated cardiomyopathy with neutropenia, growth retardation, and 3-methylglutaconic aciduria. J Pediatr 1991;119:738–747.
Barth PG, Wanders RJA, Vreken P, et al. X-linked cardioskeletal myopathy and neutropenia (Barth syndrome) (MIM 302060). J Inher Metab Dis 1999;22:555–567.
Bione S, D'Adamo P, Maestrini E, et al. A novel X-linked gene, G4.5, is responsible for Barth syndrome. Nat Genet 1996;12:385–389.
Ma L, Vaz FM, Gu Z, et al. The human TAZ gene complements mitochondrial dysfunction in the yeast taz1Δ mutant. Implications for Barth syndrome. J Biol Chem 2004;279:44394–44399.
Testet E, Laroche-Traineau J, Noubhani A, et al. Ypr140wp, the yeast tafazzin, displays a mitochondrial lysophosphatidylcholine (lyso-PC) acyltransferase activity related to triacylglycerol and mitochondrial lipid synthesis. Biochem J 2005;387:617–626.
Brandner K, Mick DU, Frazier AE, et al. Taz1, an outer mitochondrial membrane protein, affects stability and assembly of inner membrane protein complexes—implications for Barth syndrome. Mol Biol Cell 2005;16:5202–5214.
Neuwald AF . Barth syndrome may be due to an acyltransferase deficiency. Curr Biol 1997;7:R465–R466.
Vreken P, Valianpour F, Nijtmans LG, et al. Defective remodeling of cardiolipin and phosphatidylglycerol in Barth syndrome. Biochem Biophys Res Comm 2000;279:378–382.
Schlame M, Towbin JA, Heerdt PM, et al. Deficiency of tetralinoleoyl-cardiolipin in Barth syndrome. Ann Neurol 2002;51:634–637.
Schlame M, Kelley RI, Feigenbaum A, et al. Phospholipid abnormalities in children with Barth syndrome. J Am Coll Cardiol 2003;42:1994–1999.
Schlame M, Rua D, Greenberg ML . The biosynthesis and functional role of cardiolipin. Progr Lipid Res 2000;39:257–288.
Zhang M, Mileykovskaya E, Dowhan W . Gluing the respiratory chain together. Cardiolipin is required for supercomplex formation in the inner mitochondrial membrane. J Biol Chem 2002;277:43553–43556.
Pfeiffer K, Gohil V, Stuart RA, et al. Cardiolipin stabilizes respiratory chain supercomplexes. J Biol Chem 2003;278:52873–52880.
Schlame M, Ren M, Xu Y, et al. Molecular symmetry in mitochondrial cardiolipins. Chem Phys Lipids 2005;138:38–49.
Neustein HB, Lurie PR, Dahms B, et al. An X-linked recessive cardiomyopathy with abnormal mitochondria. Pediatrics 1979;64:24–29.
Hug G, Schwartz DC, Tuuri D . Sex-linked dilated cardiomyopathy, characteristic mitochondrial ultrastructure in liver, heart and muscle, effect of carnitine treatment. Pediatr Res 1990;27:20–28.
Christodoulou J, McInnes RR, Jay V, et al. Barth syndrome: clinical observation and genetic linkage studies. Am J Med Genet 1994;50:255–264.
Bissler JJ, Tsoras M, Goring HHH, et al. Infantile dilated X-linked cardiomyopathy, G4.5 mutations, altered lipids, and ultrastructural malformations of mitochondria in heart, liver, and skeletal muscle. Lab Invest 2002;82:335–344.
Xu Y, Sutachan JJ, Plesken H, et al. Characterization of lymphoblast mitochondria from patients with Barth syndrome. Lab Invest 2005;85:823–830.
Frey TG, Mannella CA . The internal structure of mitochondria. Trends Biochem Sci 2000;25:319–324.
Mannella CA . Introduction: our changing views of mitochondria. J Bioenerg Biomembr 2000;32:1–4.
Mannella CA, Pfeiffer DR, Bradshaw PC, et al. Topology of the mitochondrial inner membrane: dynamics and bioenergetic implications. IUBMB Life 2001;52:93–100.
Frey TG, Renken CW, Perkins GA . Insight into mitochondrial structure and functions from electron tomography. Biochim Biophys Acta 2002;1555:196–203.
Kremer JR, Mastronarde DN, McIntosh JR . Computer visualization of three-dimensional image data using IMOD. J Struct Biol 1996;116:71–76.
Perkins GA, Renken CW, Martone M, et al. Electron tomography of neuronal mitochondria: 3D structure and organization of cristae and membrane contacts. J Struct Biol 1997;119:260–272.
Perkins GA, Song JY, Tarsa L, et al. Electron tomography of mitochondria from brown adipocytes reveals crista junctions. J Bioenerg Biomembr 1998;30:431–442.
Nicastro D, Frangakis AS, Typke D, et al. Cryo-electron tomography of Neurospora mitochondria. J Struct Biol 2000;129:48–56.
He L, Perkins GA, Poblenz AT, et al. Bcl-XL overexpression blocks bax-mediated mitochondrial contact site formation and apoptosis in rod photoreceptors of led-exposed mice. Proc Natl Acad Sci USA 2003;100:1022–1027.
Perkins GA, Renken CW, Frey TG, et al. Membrane architecture of mitochondria in neurons of the central nervous system. J Neurosci Res 2001;66:857–865.
Prince FP, Buttle KF . Mitochondrial structure in steroid-producing cells: three-dimensional reconstruction of human Leydig cell mitochondria by electron microscopic tomography. Anat Record 2004;2278A:454–461.
Perkins GA, Ellisman MH, Fox DA . The structure–function correlates of mammalian rod and cone photoreceptor mitochondria: observations and unanswered questions. Mitochondrion 2004;4:695–703.
Perkins GA, Ellisman MH, Fox DA . Three-dimensional analysis of mouse rod and cone mitochondrial cristae architecture: bioenergetic and functional implications. Mol Vision 2003;9:60–73.
Perkins GA, Renken CW, van der Klei IJ, et al. Electron tomography of mitochondria after the arrest of protein import associated with Tom19 depletion. Eur J Cell Biol 2001;80:139–150.
Mootha VK, Wei MC, Buttle KF, et al. A reversible component of mitochondrial respiratory dysfunction in apoptosis can be rescued by exogenous cytochrome c. EMBO J 2001;20:661–671.
Scorrano L, Ashiya M, Buttle K, et al. A distinct pathway remodels mitochondrial cristae and mobilizes cytochrome c during apoptosis. Dev Cell 2002;2:55–67.
Hsieh C-E, Leith A, Mannella CA, et al. Towards high-resolution three-dimensional imaging of native mammalian tissue: electron tomography of frozen-hydrated rat liver sections. J Struct Biol 2006;153:1–13.
Xu Y, Condell M, Plesken H, et al. A Drosophila model of Barth syndrome. Proc Natl Acad Sci USA 2006;103:11584–11588.
Claypool SM, McCaffery JM, Koehler CM . Mitochondrial mislocalization and altered assembly of a cluster of Barth syndrome mutant tafazzins. J Cell Biol 2006;174:379–390.
Paumard P, Vaillier J, Coulary B, et al. The ATP synthase is involved in generating mitochondrial cristae morphology. EMBO J 2002;21:221–230.
Walker DW, Benzer S . Mitochondrial ‘swirls’ induced by oxygen stress and in the Drosophila mutant hyperswirl. Proc Natl Acad Sci USA 2004;101:10290–10295.
Mannella CA . Structure and dynamics of the mitochondrial inner membrane cristae. Biochim Biophys Acta 2006;1763:542–548.
Acknowledgements
We are grateful to Dr Richard I Kelley (Kennedy Krieger Institute, Baltimore, MD, USA) for providing cultured lymphoblasts and for critically reading the manuscript. We are also grateful to Dr Carmen A Mannella (Wadsworth Center, Albany, NY, USA) for a critical discussion on our data. This work was supported by the National Institute of Health (1 R01 HL078788-01A1), the American Heart Association (grant-in-aid 0350126N) and the Barth Syndrome Foundation.
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Acehan, D., Xu, Y., Stokes, D. et al. Comparison of lymphoblast mitochondria from normal subjects and patients with Barth syndrome using electron microscopic tomography. Lab Invest 87, 40–48 (2007). https://doi.org/10.1038/labinvest.3700480
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DOI: https://doi.org/10.1038/labinvest.3700480
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