Intersection of mitochondrial fission and fusion machinery with apoptotic pathways: Role of Mcl‐1

Mitochondria actively contribute to apoptotic cell death through mechanisms including the loss of integrity of the outer mitochondrial membrane, the release of intermembrane space proteins, such as cytochrome c, in the cytosol and the caspase cascade activation. This process is the result of careful cooperation not only among members of the Bcl‐2 family but also dynamin‐related proteins. These events are often accompanied by fission of the organelle, thus linking mitochondrial dynamics to apoptosis. Emerging evidences are suggesting a fine regulation of mitochondrial morphology by Bcl‐2 family members and active participation of fission–fusion proteins in apoptosis. The debate whether in mitochondrial morphogenesis the role of Bcl‐2 family members is functionally distinct from their role in apoptosis is still open and, above all, which morphological changes are associated with cell death sensitisation. This review will cover the findings on how the mitochondrial fission and fusion machinery may intersect apoptotic pathways focusing on recent advances on the key role played by Mcl‐1.     

Viral modulators of cell death provide new links to old pathways

By observing how viruses facilitate their parasitic relationships with host cells, we gain insights into key regulatory pathways of the cell. Not only are mitochondria key players in the regulation of programmed cell death, but many viral regulators of cell death also alter mitochondrial functions either directly or indirectly. Although cytomegalovirus vMIA and Epstein-Barr virus BHRF1 seem to have opposite effects on mitochondrial morphology, they both inhibit cell death. Drosophila Reaper, a regulator of developmental cell death, acts on IAP (inhibitor of apoptosis) proteins to activate caspases, but can regulate mitochondrial permeability in vitro. Despite its pivotal role in Drosophila, homologues of Reaper in other species were not previously known. Recently, amino acid sequence similarity was recognized between Drosophila Reaper and a protein known to be important for the replication and virulence of mosquito-borne bunyaviruses that cause human encephalitis. Thus, viral mechanisms for regulating apoptosis are diverse and not fully elucidated but promise to provide new insights.     

Fzo1, a protein involved in mitochondrial fusion, inhibits apoptosis

Mitochondrial morphology and physiology are regulated by the processes of fusion and fission. Some forms of apoptosis are reported to be associated with mitochondrial fragmentation. We showed that overexpression of Fzo1A/B (rat) proteins involved in mitochondrial fusion, or silencing of Dnm1 (rat)/Drp1 (human) (a mitochondrial fission protein), increased elongated mitochondria in healthy cells. After apoptotic stimulation, these interventions inhibited mitochondrial fragmentation and cell death, suggesting that a process involved in mitochondrial fusion/fission might play a role in the regulation of apoptosis. Consistently, silencing of Fzo1A/B or Mfn1/2 (a human homolog of Fzo1A/B) led to an increase of shorter mitochondria and enhanced apoptotic death. Overexpression of Fzo1 inhibited cytochrome c release and activation of Bax/Bak, as assessed from conformational changes and oligomerization. Silencing of Mfn or Drp1 caused an increase or decrease of mitochondrial sensitivity to apoptotic stimulation, respectively. These results indicate that some of the proteins involved in mitochondrial fusion/fission modulate apoptotic cell death at the mitochondrial level.     

The mitochondrial fission regulator DRP3B does not regulate cell death in plants

BACKGROUND AND AIMS: Recent reports have described dramatic alterations in mitochondrial morphology during metazoan apoptosis. A dynamin-related protein (DRP) associated with mitochondrial outer membrane fission is known to be involved in the regulation of apoptosis. This study analysed the relationship between mitochondrial fission and regulation of plant cell death. METHODS: Transgenic plants were generated possessing Arabidopsis DRP3B (K56A), the dominant-negative form of Arabidopsis DRP, mitochondrial-targeted green fluorescent protein and mouse Bax. KEY RESULTS: Arabidopsis plants over-expressing DRP3B (K56A) exhibited long tubular mitochondria. In these plants, mitochondria appeared as a string-of-beads during cell death. This indicates that DRP3B (K56A) prevented mitochondrial fission during plant cell death. However, in contrast to results for mammalian cells and yeast, Bax-induced cell death was not inhibited in DRP3B (K56A)-expressing plant cells. Similarly, hydrogen peroxide-, menadione-, darkness- and salicylic acid-induced cell death was not inhibited by DRP3B (K56A) expression. CONCLUSIONS: These results indicate that the systems controlling cell death in animals and plants are not common in terms of mitochondrial fission.     

The relationship between mitochondrial shape and function and the cytoskeleton

Mitochondria are crucial organelles for life and death of the cell. They are prominent players in energy conversion and integrated signaling pathways including regulation of Ca2+ signals and apoptosis. Their functional versatility is matched by their morphological plasticity and by their high mobility, allowing their transport at specialized cellular sites. This transport occurs by interactions with a variety of cytoskeletal proteins that also have the ability to influence shape and function of the organelle. A growing body of evidence suggests that mitochondria use cytoskeletal proteins as tracks for their movement; in turn, mitochondrial morphology and function is regulated via mostly uncharacterized pathways, by the cytoskeleton.     

The regulation of mitochondrial morphology: intricate mechanisms and dynamic machinery

Mitochondria typically form a reticular network radiating from the nucleus, creating an interconnected system that supplies the cell with essential energy and metabolites. These mitochondrial networks are regulated through the complex coordination of fission, fusion and distribution events. While a number of key mitochondrial morphology proteins have been identified, the precise mechanisms which govern their activity remain elusive. Moreover, post translational modifications including ubiquitination, phosphorylation and sumoylation of the core machinery are thought to regulate both fusion and division of the network. These proteins can undergo several different modifications depending on cellular signals, environment and energetic demands of the cell. Proteins involved in mitochondrial morphology may also have dual roles in both dynamics and apoptosis, with regulation of these proteins under tight control of the cell to ensure correct function. The absolute reliance of the cell on a functional mitochondrial network is highlighted in neurons, which are particularly vulnerable to any changes in organelle dynamics due to their unique biochemical requirements. Recent evidence suggests that defects in the shape or distribution of mitochondria correlate with the progression of neurodegenerative diseases such as Alzheimer's, Huntington's and Parkinson's disease. This review focuses on our current understanding of the mitochondrial morphology machinery in cell homeostasis, apoptosis and neurodegeneration, and the post translational modifications that regulate these processes.     

Regulation of the mitochondrial apoptosis-induced channel, MAC, by BCL-2 family proteins

Programmed cell death or apoptosis is central to many physiological processes and pathological conditions such as organogenesis, tissue homeostasis, cancer, and neurodegenerative diseases. Bcl-2 family proteins tightly control this cell death program by regulating the permeabilization of the mitochondrial outer membrane and, hence, the release of cytochrome c and other pro-apoptotic factors. Control of the formation of the mitochondrial apoptosis-induced channel, or MAC, is central to the regulation of apoptosis by Bcl-2 family proteins. MAC is detected early in apoptosis by patch clamping the mitochondrial outer membrane. The focus of this review is on the regulation of MAC activity by Bcl-2 family proteins. The role of MAC as the putative cytochrome c release channel during early apoptosis and insights concerning its molecular composition are also discussed.     

The role of mitochondrial factors in apoptosis: a Russian roulette with more than one bullet

Mitochondria are 'life-essential' organelles for the production of metabolic energy in the form of ATP. Paradoxically mitochondria also play a key role in controlling the pathways that lead to cell death. This latter role of mitochondria is more than just a 'loss of function' resulting in an energy deficit but is an active process involving different mitochondrial proteins. Cytochrome c was the first characterised mitochondrial factor shown to be released from the mitochondrial intermembrane space and to be actively implicated in apoptotic cell death. Since then, other mitochondrial proteins, such as AIF, Smac/DIABLO, endonuclease G and Omi/HtrA2, were found to undergo release during apoptosis and have been implicated in various aspects of the cell death process. Members of the Bcl-2 protein family control the integrity and response of mitochondria to apoptotic signals. The molecular mechanism by which mitochondrial intermembrane space proteins are released and the regulation of mitochondrial homeostasis by Bcl-2 proteins is still elusive. This review summarises and evaluates the current knowledge concerning the complex role of released mitochondrial proteins in the apoptotic process.     

线粒体形态学改变与细胞凋亡

近年来,对于线粒体形态学以及其在凋亡过程中的改变和作用的研究打破了传统的观点。正常情况下,线粒体在细胞内相互连接成管网状结构,并发生着频繁的融合与分裂。融合和分裂由一系列蛋白质介导,二者之间的动态平衡维持着线粒体的形态和功能。在细胞凋亡的早期,线粒体融合和分裂失平衡,导致线粒体管网状结构碎裂和嵴的重构,这些改变对线粒体随后的变化以及凋亡的发生具有重要的意义。融合和分裂的蛋白质不仅调控线粒体形态和细胞凋亡过程,也和某些凋亡相关疾病有关。此外,促凋亡的Bcl-2蛋白可能通过改变线粒体的构形来调控凋亡过程。     

Mcl-1 rescues a glitch in the matrix

Bcl-2 family proteins are known to control cell death and influence mitochondrial function. The function of Mcl-1, an anti-apoptotic Bcl-2 protein, is now shown to depend on its subcellular localization. Mcl-1 at the mitochondrial outer membrane inhibits mitochondrial permeabilization to block apoptosis. However, a cleaved form of Mcl-1 localizes to the mitochondrial matrix and controls inner mitochondrial morphology and oxidative phosphorylation, without directly modulating apoptosis.     

Role of Bcl-2 family of proteins in mediating apoptotic death of PC12 cells exposed to oxygen and glucose deprivation

Apoptotic cell death has been observed in many in vivo and in vitro models of ischemia. However, the molecular pathways involved in ischemia-induced apoptosis remain unclear. We have examined the role of Bcl-2 family of proteins in mediating apoptosis of PC12 cells exposed to the conditions of oxygen and glucose deprivation (OGD) or OGD followed by restoration of oxygen and glucose (OGD-restoration, OGD-R). OGD decreased mitochondrial membrane potential and induced necrosis of PC12 cells, which were both prevented by the overexpression of Bcl-2 proteins. OGD-R caused apoptotic cell death, induced cytochrome C release from mitochondria and caspase-3 activation, decreased mitochondrial membrane potential, and increased levels of pro-apoptotic Bax translocated to the mitochondrial membrane, all of which were reversed by overexpression of Bcl-2. These results demonstrate that the cell death induced by OGD and OGD-R in PC12 cells is potentially mediated through the regulation of mitochondrial membrane potential by the Bcl-2 family of proteins. It also reveals the importance of developing therapeutic strategies for maintaining the mitochondrial membrane potential as a possible way of reducing necrotic and apoptotic cell death that occurs following an ischemic insult.     

Mitochondrial regulation of apoptotic cell death

Mitochondria play a decisive role in the regulation of both apoptotic and necrotic cell death. Permeabilization of the outer mitochondrial membrane and subsequent release of intermembrane space proteins are important features of both models of cell death. The mechanisms by which these proteins are released depend presumably on cell type and the nature of stimuli. Of the mechanisms involved, mitochondrial permeability transition appears to be associated mainly with necrosis, whereas the release of caspase activating proteins during early apoptosis is regulated primarily by the Bcl-2 family of proteins. However, there is increasing evidence for interaction and co-operation between these two mechanisms. The multiple mechanisms of mitochondrial permeabilization may explain diversities in the response of mitochondria to numerous apoptotic stimuli in different types of cells.     

Depletion of mitochondrial fission factor DRP1 causes increased apoptosis in human colon cancer cells

Mitochondria play a critical role in regulation of apoptosis, a form of programmed cell death, by releasing apoptogenic factors including cytochrome c. Growing evidence suggests that dynamic changes in mitochondrial morphology are involved in cellular apoptotic response. However, whether DRP1-mediated mitochondrial fission is required for induction of apoptosis remains speculative. Here, we show that siRNA-mediated DRP1 knockdown promoted accumulation of elongated mitochondria in HCT116 and SW480 human colon cancer cells. Surprisingly, DRP1 down-regulation led to decreased proliferation and increased apoptosis of these cells. A higher rate of cytochrome c release and reductions in mitochondrial membrane potential were also revealed in DRP1-depleted cells. Taken together, our present findings suggest that mitochondrial fission factor DRP1 inhibits colon cancer cell apoptosis through the regulation of cytochrome c release and mitochondrial membrane integrity.     

Mitochondrial dynamics during apoptosis

Mitochondria exist as dynamic networks that often change shape and subcellular distribution. The morphology of mitochondria within a cell is controlled by precisely regulated rates of organelle fusion and fission. Several reports have described dramatic alterations in mitochondrial morphology during the early stages of apoptosis: a fragmentation of the network and the cristae remodeling. However, whether this mitochondrial fragmentation is a required step for apoptosis is highly debated. In this review the recent progress in understanding the mechanisms governing mitochondrial morphology during apoptosis and the latest advances connecting the regulation of mitochondrial morphology with apoptosis are discussed.     

The role of mitochondria in apoptosis

Apoptosis (programmed cell death) is a cellular self-destruction mechanism that is essential for a variety of biological events, such as developmental sculpturing, tissue homeostasis, and the removal of unwanted cells. Mitochondria play a crucial role in regulating cell death. Ca2+ has long been recognized as a participant in apoptotic pathways. Mitochondria are known to modulate and synchronize Ca2+ signaling. Massive accumulation of Ca2+ in the mitochondria leads to apoptosis. The Ca2+ dynamics of ER and mitochondria appear to be modulated by the Bcl-2 family proteins, key factors involved in apoptosis. The number and morphology of mitochondria are precisely controlled through mitochondrial fusion and fission process by numerous mitochondria-shaping proteins. Mitochondrial fission accompanies apoptotic cell death and appears to be important for progression of the apoptotic pathway. Here, we highlight and discuss the role of mitochondrial calcium handling and mitochondrial fusion and fission machinery in apoptosis.     

The role of the Bcl-2 family in the regulation of outer mitochondrial membrane permeability

Mitochondria are well known as sites of electron transport and generators of cellular ATP. Mitochondria also appear to be sites of cell survival regulation. In the process of programmed cell death, mediators of apoptosis can be released from mitochondria through disruptions in the outer mitochondrial membrane; these mediators then participate in the activation of caspases and of DNA degradation. Thus the regulation of outer mitochondrial membrane integrity is an important control point for apoptosis. The Bcl-2 family is made up of outer mitochondrial membrane proteins that can regulate cell survival, but the mechanisms by which Bcl-2 family proteins act remain controversial. Most metabolites are permeant to the outer membrane through the voltage dependent anion channel (VDAC), and Bcl-2 family proteins appear to be able to regulate VDAC function. In addition, many Bcl-2 family proteins can form channels in vitro, and some pro-apoptotic members may form multimeric channels large enough to release apoptosis promoting proteins from the intermembrane space. Alternatively, Bcl-2 family proteins have been hypothesized to coordinate the permeability of both the outer and inner mitochondrial membranes through the permeability transition (PT) pore. Increasing evidence suggests that alterations in cellular metabolism can lead to pro-apoptotic changes, including changes in intracellular pH, redox potential and ion transport. By regulating mitochondrial membrane physiology, Bcl-2 proteins also affect mitochondrial energy generation, and thus influence cellular bioenergetics. Cell Death and Differentiation (2000) 7, 1182 - 1191     

Apoptotic-like regulation of programmed cell death in plants

In plants, apoptotic-like programmed cell death (PCD) can be distinguished from other forms of plant cell death by protoplast condensation that results in a morphologically distinct cell corpse. In addition, there is a central regulatory role for the mitochondria and the degradation of the cell and its contents by PCD associated proteases. These distinguishing features are shared with animal apoptosis as it is probable that plant and animal cell death programmes arose in a shared unicellular ancestor. However, animal and plant cell death pathways are not completely conserved. The cell death programmes may have been further modified after the divergence of plant and animal lineages leading to converged, or indeed unique, features of their respective cell death programmes. In this review we will examine the features of apoptotic-like PCD in plants and examine the probable conserved components such as mitochondrial regulation through the release of apoptogenic proteins from the mitochondrial intermembrane space, the possible conserved or converged features such as “caspase-like” molecules which drive cellular destruction and the emerging unique features of plant PCD such as chloroplast involvement in cell death regulation.     

Bcl-2 proteins: regulators of apoptosis or of mitochondrial homeostasis?

Programmed cell death (apoptosis) is used by multicellular organisms during development and to maintain homeostasis within mature tissues. One of the first genes shown to regulate apoptosis was bcl-2. Subsequently, a number of Bcl-2-related proteins have been identified. Despite overwhelming evidence that Bcl-2 proteins are evolutionarily conserved regulators of apoptosis, their precise biochemical function remains controversial. Three biochemical properties of Bcl-2 proteins have been identified: their ability to localize constitutively and/or inducibly to the outer mitochondrial, outer nuclear and endoplasmic reticular membranes, their ability to form heterodimers with proteins bearing an amphipathic helical BH3 domain, and their ability to form ion-conducting channels in synthetic membranes. The discovery that mitochondria can play a key part in the induction of apoptosis has focused attention on the role that Bcl-2 proteins may have in regulating either mitochondrial physiology or mitochondria-dependent caspase activation. Here we attempt to synthesize our current understanding of the part played by mitochondria in apoptosis with a consideration of how Bcl-2 proteins might control cell death through an ability to regulate mitochondrial physiology.