Cristae formation-linking ultrastructure and function of mitochondria

Mitochondria are double-membrane enclosed eukaryotic organelles with a central role in numerous cellular functions. The ultrastructure of mitochondria varies considerably between tissues, organisms, and the physiological state of cells. Alterations and remodeling of inner membrane structures are evident in numerous human disorders and during apoptosis. The inner membrane is composed of two subcompartments, the cristae membrane and the inner boundary membrane. Recent advances in electron tomography led to the current view that these membrane domains are connected by rather small tubular structures, termed crista junctions. They have been proposed to regulate the dynamic distribution of proteins and lipids as well as of soluble metabolites between individual mitochondrial subcompartments. One example is the release of cytochrome c upon induction of apoptosis. However, only little is known on the molecular mechanisms mediating the formation and maintenance of cristae and crista junctions. Here we review the current knowledge of the factors that determine cristae morphology and how the latter is linked to mitochondrial function. Further, we formulate several theoretical models which could account for the de novo formation of cristae as well as their propagation from existing cristae.     

Corn Mitochondrial Swelling and Contraction-an Alternate Interpretation

Mitochondria isolated from 3-day-old etiolated corn shoots (Zea mays L.) can be categorized into three separate groups, each group characteristic of the cell type from which the mitochondria were isolated. Phloem sieve tubes and some adjacent parenchyma cells contain mitochondria that have few cristae and little amorphous matrix. Mitochondria from meristematic and undifferentiated cells have more cristae and matrix. Vaculate and differentiated cells have mitochondria with well-developed cristae and abundant matrix. Each mitochondrial type exhibits typical in vitro spontaneous swelling and substrate-induced contraction responses. characterized by change or lack of change in cristae size and in density of amorphous material. For the second and third types of mitochondria, swelling and contraction are characterized by a change in degree of cristae size and in matrix density. The first type undergoes few changes upon swelling or contraction. Radical changes of the inner membrane, withdrawal and infolding, are associated with cell differentiation and not with swelling and contraction of isolated corn shoot mitochondria.     

The internal structure of mitochondria

Electron microscopic (EM) tomography is providing important new insights into the internal organization of mitochondria. The standard baffle model for cristae structure, called into question years ago, has now clearly been shown to be inaccurate. Depending on source and conformational state, cristae can vary from simple tubular structures to more complex lamellar structures merging with the inner boundary membrane through tubular structures 28 nm in diameter. The structural information provided by EM tomography has important implications for mitochondrial bioenergetics, biogenesis and the role of mitochondria in apoptosis. The structural paradigm defined by EM tomography is helping in the design of new experimental approaches to mitochondrial function.     

Insight into mitochondrial structure and function from electron tomography

In recent years, electron tomography has provided detailed three-dimensional models of mitochondria that have redefined our concept of mitochondrial structure. The models reveal an inner membrane consisting of two components, the inner boundary membrane (IBM) closely apposed to the outer membrane and the cristae membrane that projects into the matrix compartment. These two components are connected by tubular structures of relatively uniform size called crista junctions. The distribution of crista junction sizes and shapes is predicted by a thermodynamic model based upon the energy of membrane bending, but proteins likely also play a role in determining the conformation of the inner membrane. Results of structural studies of mitochondria during apoptosis demonstrate that cytochrome c is released without detectable disruption of the outer membrane or extensive swelling of the mitochondrial matrix, suggesting the formation of an outer membrane pore large enough to allow passage of holo-cytochrome c. The possible compartmentation of inner membrane function between the IBM and the cristae membrane is also discussed.     

The missing link between hydrogenosomes and mitochondria

Mitochondria typically respire oxygen and possess a small DNA genome. But among various groups of oxygen-shunning eukaryotes, typical mitochondria are often lacking, organelles called hydrogenosomes being found instead. Like mitochondria, hydrogenosomes are surrounded by a double-membrane, produce ATP and sometimes even have cristae. In contrast to mitochondria, hydrogenosomes produce molecular hydrogen through fermentations, lack cytochromes and usually lack DNA. Hydrogenosomes do not fit into the conceptual mold cast by the classical endosymbiont hypothesis about the nature of mitochondria. Accordingly, ideas about their evolutionary origins have focussed on the differences between the two organelles instead of their commonalities. Are hydrogenosomes fundamentally different from mitochondria, the result of a different endosymbiosis? Or are our concepts about the mitochondrial archetype simply too narrow? A new report has uncovered DNA in the hydrogenosomes of anaerobic ciliates. The sequences show that these hydrogenosomes are, without a doubt, mitochondria in the evolutionary sense, even though they differ from typical mitochondria in various biochemical properties. The new findings are a benchmark for our understanding of hydrogenosome origins.     

Protective action of l-carnitine on cardiac mitochondrial function and structure against fatty acid stress

Cardiovascular risks are frequently accompanied by high serum fatty acid levels. Although recent studies have shown that fatty acids affect mitochondrial function and induce cell apoptosis, l-carnitine is essential for the uptake of fatty acids by mitochondria, and may attenuate the mitochondrial dysfunction and apoptosis of cardiocytes. This study aimed to elucidate the activity of l-carnitine in the prevention on fatty acid-induced mitochondrial membrane permeability transition and cytochrome c release using isolated cardiac mitochondria from rats. Palmitoyl-CoA-induced mitochondrial respiration that was observed with l-carnitine was inhibited with oligomycin. The palmitoyl-CoA-induced mitochondrial membrane depolarization and swelling were greatly inhibited by the presence of l-carnitine. In ultrastructural observations, terminally swollen and ruptured mitochondria with little or no distinguishable cristae structures were induced by treatment with palmitoyl-CoA. However, the severe morphological damage in cardiac mitochondria was dramatically inhibited by pretreatment with l-carnitine. Treatment with l-carnitine also attenuated 4-hydroxy-l-phenylglycine- and rotenone-induced mitochondrial swelling even when the l-carnitine could not protect against the decrease in oxygen consumption associated with these inhibitors. Furthermore, l-carnitine completely inhibited palmitoyl-CoA-induced cytochrome c release. We concluded that l-carnitine is essential for cardiac mitochondria to attenuate the membrane permeability transition, and to maintain the ultrastructure and membrane stabilization, in the presence of high fatty acid β-oxidation. Consequently, the cells may be protected against apoptosis by l-carnitine through inhibition of the fatty acid-induced cytochrome c release.     

Detection of new two-membrane structures in native mitochondria by the method of small-angle scattering of neutrons

The structure of mitochondrial cristas has been studied for the first time by the method of small-angle scattering of thermal neutrons. Experiments were performed on intact functioning rat liver mitochondria. Mitochondrial cristas are usually considered as folds of the internal membrane with arbitrary nonfixed intermembrane distances. It was shown that, under particular conditions, during low-amplitude swelling of mitochondria, cristas are transformed to bimembrane structures, with the distance between the central planes of membranes of 190 E. It was found that the formation of bimembrane structures and their structural parameters do not depend on the method of induction of swelling, by placing the mitochondria into a hypotonic medium or by the opening of nonspecific pores.     

Role of mitochondrial swelling in the energetic effectiveness of intact myocardial cells (according to electron microscopy data)]

The myocardium of the left and the right cardiac ventricles was studied at various seasons on 20 rabbits. There was found a distinct seasonal dynamics of a number of quantitative indices of electronograms. In particular, there was found a relationship between the coefficients of energy efficacy of the mitochondria (integral value--calculated by multiplying the mitochondrial area by the number of mitochondrial cristae) and the mitochondrial area. With increase of the latter to 0,85 mc2 this relationship is positive and linear. With further swelling of the mitochondria this relationship disappears, however.     

Mitochondrial F1F0-ATP synthase and organellar internal architecture

The mitochondrial F₁F₀-ATP synthase adopts supramolecular structures. The interaction domains between monomers involve components belonging to the F₀ domains. In Saccharomyces cerevisiae, alteration of these components destabilizes the oligomeric structures, leading concomitantly to the appearance of monomeric species of ATP synthase and anomalous mitochondrial morphologies in the form of onion-like structures. The mitochondrial ultrastructure at the cristae level is thus modified. Electron microscopy on cross-sections of wild type mitochondria display many short cristae with narrowed intra-cristae space, whereas yeast mutants defected in supramolecular ATP synthases assembly present a low number of large lamellar cristae of constant thickness and traversing the whole organelle. The growth of these internal structures leads finally to mitochondria with sphere-like structures with a mean diameter of 1 μm that are easily identified by epifluorescence microscopy. As a result, ATP synthase is an actor of the mitochondrial ultrastructure in yeast. This paper reviews the ATP synthase components whose modifications lead to anomalous mitochondrial morphology and also provides a schema showing the formation of the so-called onion-like structures.     

Trial comparison of mitochondrial cristae craters images obtained by the freeze-fracturing and ultrathin sections method

In two-folded lamina of the mitochondrial cristae occurs in mitochondria of spermatocytes large areas of the inner and outer halves in freeze-fracturing technique morphological observations suggest that in mitochondrial membrane there exist "crater-like' structures with internal diameter of approximately 18 nm. A question has come up why no mention has so far been found in the literature of the appearance of similar structure in mitochondrial cristae in specimens in transmission electron microscope (TEM) observed. Thus comparison of our findings obtained by the freeze-fracturing (FF) method with those achieved by TEM was made.     

The inner membrane protein Mdm33 controls mitochondrial morphology in yeast

Mitochondrial distribution and morphology depend on MDM33, a Saccharomyces cerevisiae gene encoding a novel protein of the mitochondrial inner membrane. Cells lacking Mdm33 contain ring-shaped, mostly interconnected mitochondria, which are able to form large hollow spheres. On the ultrastructural level, these aberrant organelles display extremely elongated stretches of outer and inner membranes enclosing a very narrow matrix space. Dilated parts of Delta mdm33 mitochondria contain well-developed cristae. Overexpression of Mdm33 leads to growth arrest, aggregation of mitochondria, and generation of aberrant inner membrane structures, including septa, inner membrane fragments, and loss of inner membrane cristae. The MDM33 gene is required for the formation of net-like mitochondria in mutants lacking components of the outer membrane fission machinery, and mitochondrial fusion is required for the formation of extended ring-like mitochondria in cells lacking the MDM33 gene. The Mdm33 protein assembles into an oligomeric complex in the inner membrane where it performs homotypic protein-protein interactions. Our results indicate that Mdm33 plays a distinct role in the mitochondrial inner membrane to control mitochondrial morphology. We propose that Mdm33 is involved in fission of the mitochondrial inner membrane.     

Osmotically-induced alterations in volume and ultrastructure of mitochondria isolated from rat liver and bovine heart

Detailed studies correlating changes in mitochondrial optical density, packed volume, and ultrastructure associated with osmotically-induced swelling were performed. Various swelling states were established by incubating mitochondria (isolated in 0.25 M sucrose) at 0°C for 5 min in series of KCl and sucrose solutions ranging in tonicity from 250 to 3 milliosmols. Reversibility of swelling was determined by examining mitochondria exposed to 250 milliosmols media after they had been induced to swell. Swelling induced by lowering the ambient tonicity to approximately 130 (liver mitochondria) and 90 (heart mitochondria) milliosmols involves primarily swelling of the inner compartment within the intact outer membrane. Decreasing the ambient tonicity beyond this level results in rupture of the outer membrane and expansion of the inner compartment through the break. The maximum extent of swelling, corresponding with complete unfolding of the cristae and an increase in over-all mitochondrial volume of approximately 6-fold (liver mitochondria) and 11-fold (heart mitochondria), is reached at approximately 15 (liver mitochondria) and 3 (heart mitochondria) milliosmols. Exposure of liver mitochondria to media of lower tonicity results in irreversibility of inner compartment swelling and escape of matrix material. These changes appear to result from increased inner membrane permeability, possibly due to stretching.     

大鼠心肌线粒体缺血再灌损伤及SOD抗缺血再灌损伤作用的形态计量研究

研究了在体大鼠心肌缺血再灌模型心肌线粒体再灌损伤和SOD抗缺血再灌损伤的作用。实验分为:A组(缺血再灌组)B组(SOD组)和C组(假手术组)。电镜见A组线粒体高度肿胀、外膜缺损、嵴断裂溶解,出现无定形致密体、四膜嵴和杆状嵴等改变。B组线粒体轻度或中度肿胀、少数有轻度嵴溶解。个别线粒体内出现无定形致密体。三组线粒体超微结构立体计量数据比较,A组线粒体密度、线粒体体密度与肌原纤维体密度比率增高((P<0.01),线粒体比表面和比膜面降低(P<0.01)。自身动图像分析仪检测SDH反应灰度值A组呈强损伤反应,B组反应较轻,二者差别有显著性(P<0.05)。结果表明,心肌缺血再灌可致线粒体发生不可逆性损伤,SOD能减轻线粒体缺血再灌性损伤。     

泥螺卵黄发生过程中线粒体的变化

利用透射电镜（TEM）技术研究了泥螺卵黄发生过程中线粒体的形态结构的变化特点,结果表明,从卵黄发生早期到晚期,卵母细胞内线粒体经历了从外部形态到内部结构的一系列变化。卵黄合成初期的卵母细胞内,线粒体多,结构典型,仅部分线粒体外膜破裂,嵴 和内膜逐渐消失,卵黄发生中期,线粒体基质空泡化,嵴和内膜消失,腔内充满颗粒状物质,最后演变成卵黄颗粒,随着卵母细胞的发育,卵黄颗粒的数量和直径逐渐增加,卵黄发生后期,卵质中胞器不发达,细胞质中充满卵黄颗粒,在卵黄颗粒之间仅有少量线粒体存在,提供细胞代谢所需的能量,此外,对线粒体在卵黄形成中的功能,去向及行为变化等 进行了讨论。     

Ultrastructure and function of mitochondria in gametocytic stage of Plasmodium falciparum

Morphological properties of the mitochondrial organelles in the asexual and sexual gametocytic stages of Plasmodium falciparum have been analyzed and found to be markedly different. From in vitro cultures of both stages in human erythrocytes, it has been demonstrated that the asexual stages contained a defined double-membrane organelle having a few tubular-like cristae. The numbers of mitochondria in the gametocytes were found to be approximately 6 organelles per parasite, and they showed a greater density of the cristae than that of the asexual stage parasite. The organelles of the gametocytes were successfully purified by differential centrifugation following Percoll density gradient separation with the results of approximately 7% yields and approximately 5 folds. The gametocytic organelles contained much more activities of mitochondrial electron transporting enzymes (i.e., cytochrome c reductase, cytochrome c oxidase) than the asexual stage organelles. Mitochondrial function as measured by oxygen consumption were found to be different between these two stages organelles. Their rates of oxygen consumption were relatively low, as compared to those of human leukocyte and mouse liver mitochondria. In contrast to the coupled mammalian mitochondria, the gametocytic organelles were in the uncoupling state between oxidation and phosphorylation reactions during their respiration. However, they were sensitive to inhibitors of the electron transport system, e.g., antimycin A, cyanide. Our results suggest that the mitochondria of the gametocytic stages are metabolically active and still underdeveloped, although their inner membranes are extensively folded. The biochemical significance of the unique structure of the mitochondria in these developing stages in host erythrocytes remains to be elucidated.     

BIOGENESIS OF MITOCHONDRIA : XIII. The Isolation of Mitochondrial Structures from Anaerobically Grown Saccharomyces cerevisiae

Morphologically intact structures have been isolated from anaerobically grown yeast cells which have many of the properties of yeast mitochondria. The structures are about 0.5 µ in diameter and contain malate dehydrogenase, succinate dehydrogenase, oligomycin-sensitive ATPase, and DNA of buoyant density 1.683 g/cc, characteristic of yeast mitochondria. The morphology of the structures is critically dependent on their lipid composition. When isolated from cells grown anaerobically in the presence of supplements of unsaturated fatty acid and ergosterol, their unsaturated fatty acid content is similar to that of mitochondria from aerobically grown cells. These lipid-complete structures consist pre-dominantly of double-membrane vesicles enclosing a dense matrix which contains a folded inner membrane system bordering electron-transparent regions which are somewhat different from the cristae of functional mitochondria. In contrast, the structures from cells grown without lipid supplements are much simpler in morphology; they have a dense granular matrix surrounded by a double membrane but have no obvious folded inner membrane system within the matrix. The lipid-depleted structures are very fragile and are only isolated in intact form from protoplasts that have been prefixed with glutaraldehyde     

镉对长江华溪蟹心肌细胞超微结构的影响

应用透射电镜方法,研究了镉在24h内对长江华溪触心肌细胞超微结构的影响。结果表明：注射镉后0.5h,心肌细胞超微结构即出现变化,且随着时间的延长,变化渐趋明显,主要表现在细胞核和线粒体。细胞核核膜肿胀、弥散、最后解体。线粒体嵴部分解体、直至全部解体;线粒体内室部分肿胀、明显肿胀、直至高度肿胀。此外,溶酶体的数量和类型随镉处理时间的延长而增多,肌原纤维出现断裂。     

QSAR modeling and transmission electron microscopy stereology of altered mitochondrial ultrastructure of white blood cells in patients diagnosed as schizophrenic and treated with antipsychotic drugs.

Treatment of patients diagnosed as schizophrenic with antipsychotic drugs (neuroleptics) is known to cause occasional unexplained depletion of white blood cells, especially neutrophil granulocytes. It has been known for many years that neuroleptics can interfere with the mitochondrial respiratory chain in vitro. Because there has been a growing interest recently in mitochondrial targeting of drugs, and since a quantitative structure-activity relationship (QSAR) model that predicts mitochondrial accumulation of neuroleptics has been published, we investigated the effects of neuroleptics on white blood cell mitochondria. Venous blood samples were collected from both patients undergoing treatment with neuroleptics and healthy volunteers. The samples were processed for transmission electron microscopy. The resulting images of white blood cells were analyzed using stereology to compare quantitatively mitochondrial morphology in the patient and control groups. We found that in patients, but not in controls, there was swelling of mitochondria and fragmentation of the mitochondrial cristae. There also were fewer mitochondria in patients than in controls, although due to the swelling of the organelles, the volume density of mitochondria in the two groups was not significantly different. Such changes are typical of a toxic insult. Consequently, it seems plausible that, since schizophrenia is not a disease considered to affect white blood cells per se, these changes probably are due to the medication.     

QSAR modeling and transmission electron microscopy stereology of altered mitochondrial ultrastructure of white blood cells in patients diagnosed as schizophrenic and treated with antipsychotic drugs.

Treatment of patients diagnosed as schizophrenic with antipsychotic drugs (neuroleptics) is known to cause occasional unexplained depletion of white blood cells, especially neutrophil granulocytes. It has been known for many years that neuroleptics can interfere with the mitochondrial respiratory chain in vitro. Because there has been a growing interest recently in mitochondrial targeting of drugs, and since a quantitative structure-activity relationship (QSAR) model that predicts mitochondrial accumulation of neuroleptics has been published, we investigated the effects of neuroleptics on white blood cell mitochondria. Venous blood samples were collected from both patients undergoing treatment with neuroleptics and healthy volunteers. The samples were processed for transmission electron microscopy. The resulting images of white blood cells were analyzed using stereology to compare quantitatively mitochondrial morphology in the patient and control groups. We found that in patients, but not in controls, there was swelling of mitochondria and fragmentation of the mitochondrial cristae. There also were fewer mitochondria in patients than in controls, although due to the swelling of the organelles, the volume density of mitochondria in the two groups was not significantly different. Such changes are typical of a toxic insult. Consequently, it seems plausible that, since schizophrenia is not a disease considered to affect white blood cells per se, these changes probably are due to the medication.