Mitochondrial redox systems as central hubs in plant metabolism and signaling

Plant mitochondria are indispensable for plant metabolism and are tightly integrated into cellular homeostasis. This review provides an update on the latest research concerning the organization and operation of plant mitochondrial redox systems, and how they affect cellular metabolism and signaling, plant development, and stress responses. New insights into the organization and operation of mitochondrial energy systems such as the tricarboxylic acid cycle and mitochondrial electron transport chain (mtETC) are discussed. The mtETC produces reactive oxygen and nitrogen species, which can act as signals or lead to cellular damage, and are thus efficiently removed by mitochondrial antioxidant systems, including Mn-superoxide dismutase, ascorbate–glutathione cycle, and thioredoxin-dependent peroxidases. Plant mitochondria are tightly connected with photosynthesis, photorespiration, and cytosolic metabolism, thereby providing redox-balancing. Mitochondrial proteins are targets of extensive post-translational modifications, but their functional significance and how they are added or removed remains unclear. To operate in sync with the whole cell, mitochondria can communicate their functional status via mitochondrial retrograde signaling to change nuclear gene expression, and several recent breakthroughs here are discussed. At a whole organism level, plant mitochondria thus play crucial roles from the first minutes after seed imbibition, supporting meristem activity, growth, and fertility, until senescence of darkened and aged tissue. Finally, plant mitochondria are tightly integrated with cellular and organismal responses to environmental challenges such as drought, salinity, heat, and submergence, but also threats posed by pathogens. Both the major recent advances and outstanding questions are reviewed, which may help future research efforts on plant mitochondria.

Plant mitochondria are key components of redox homeostasis and play vital roles in regulating cellular metabolism, thereby affecting development and stress tolerance at the whole plant level.

Advances

• Improved quantitative MS-based approaches have accelerated the study of mitochondrial protein abundance, turnover and PTMs.
• Mitochondrial enzymes and cellular compartments operate interactively and efficiently exchange substrates.
• Roles for mitochondrial retrograde signaling in plant growth, during physiologically relevant stress conditions and in interaction with other organelles such as the chloroplasts, have been clarified.
• Further insights into mitochondrial antioxidant and peroxidase systems and how they affect other redox systems, enzymes, and whole plant growth have been generated.
• Our understanding of how mitochondria help plants power development and cope with adversity has improved.

     

Mitochondrial redox system,dynamics, and dysfunction in lung inflammaging and COPD

Myriad forms of endogenous and environmental stress disrupt mitochondrial function by impacting critical processes in mitochondrial homeostasis, such as mitochondrial redox system, oxidative phosphorylation, biogenesis, and mitophagy. External stressors that interfere with the steady state activity of mitochondrial functions are generally associated with an increase in reactive oxygen species, inflammatory response, and induction of cellular senescence (inflammaging) potentially via mitochondrial damage associated molecular patterns (DAMPS). Many of these are the key events in the pathogenesis of chronic obstructive pulmonary disease (COPD) and its exacerbations. In this review, we highlight the primary mitochondrial quality control mechanisms that are influenced by oxidative stress/redox system, including role of mitochondria during inflammation and cellular senescence, and how mitochondrial dysfunction contributes to the pathogenesis of COPD and its exacerbations via pathogenic stimuli.     

Visfatin-induced lipid raft redox signaling platforms and dysfunction in glomerular endothelial cells

Adipokines have been reported to contribute to glomerular injury during obesity or diabetes mellitus. However, the mechanisms mediating the actions of various adipokines on the kidney remained elusive. The present study was performed to determine whether acid sphingomyelinase (ASM)-ceramide associated lipid raft (LR) clustering is involved in local oxidative stress in glomerular endothelial cells (GECs) induced by adipokines such as visfatin and adiponectin. Using confocal microscopy, visfatin but not adiponectin was found to increase LRs clustering in the membrane of GECs in a dose and time dependent manner. Upon visfatin stimulation ASMase activity was increased, and an aggregation of ASMase product, ceramide and NADPH oxidase subunits, gp91^phox and p47^phox was observed in the LR clusters, forming a LR redox signaling platform. The formation of this signaling platform was blocked by prior treatment with LR disruptor filipin, ASMase inhibitor amitriptyline, ASMase siRNA, gp91^phox siRNA and adiponectin. Corresponding to LR clustering and aggregation of NADPH subunits, superoxide (O₂^?) production was significantly increased (2.7 folds) upon visfatin stimulation, as measured by electron spin resonance (ESR) spectrometry. Functionally, visfatin significantly increased the permeability of GEC layer in culture and disrupted microtubular networks, which were blocked by inhibition of LR redox signaling platform formation. In conclusion, the injurious effect of visfatin, but not adiponectin on the glomerular endothelium is associated with the formation of LR redox signaling platforms via LR clustering, which produces local oxidative stress resulting in the disruption of microtubular networks in GECs and increases the glomerular permeability.     

Mitochondrial redox biology and homeostasis in plants

Mitochondria are key players in plant cell redox homeostasis and signalling. Earlier concepts that regarded mitochondria as secondary to chloroplasts as the powerhouses of photosynthetic cells, with roles in cell proliferation, death and ageing described largely by analogy to animal paradigms, have been replaced by the new philosophy of integrated cellular energy and redox metabolism involving mitochondria and chloroplasts. Thanks to oxygenic photosynthesis, plant mitochondria often operate in an oxygen- and carbohydrate-rich environment. This rather unique environment necessitates extensive flexibility in electron transport pathways and associated NAD(P)-linked enzymes. In this review, mitochondrial redox metabolism is discussed in relation to the integrated cellular energy and redox function that controls plant cell biology and fate.     

Mitochondrial dysfunction in epilepsy

Mitochondrial dysfunction has been identified as one potential cause of epileptic seizures. Impaired mitochondrial function has been reported for the seizure focus of patients with temporal lobe epilepsy and Ammon's horn sclerosis and of adult and immature animal models of epilepsy. Since mitochondrial oxidative phosphorylation provides the major source of ATP in neurons and mitochondria participate in cellular Ca(2+) homeostasis and generation of reactive oxygen species, their dysfunction strongly affects neuronal excitability and synaptic transmission. Therefore, mitochondrial dysfunction is proposed to be highly relevant for seizure generation. Additionally, mitochondrial dysfunction is known to trigger neuronal cell death, which is a prominent feature of therapy-resistant epilepsy. For this reason mitochondria have to be considered as promising targets for neuroprotective strategies in epilepsy.     

Mitochondrial dysfunction in cancer

Nearly a century of scientific research has revealed a number of notable differences in the structure and function of mitochondria between normal and cancer cells, including differences in metabolic activity, molecular composition, and mtDNA sequence. This article reviews several of these differences and discusses their clinical implications, especially with regard to the use of mitochondria as biomarkers for early detection of cancer, or as unique cellular targets for novel and selective anti-cancer agents.     

Mitochondrial dysfunction in osteoarthritis

In osteoarthritis (OA) a time or age dependent process leads to aberrant cartilage structure which is characterized by reduced number of chondrocytes, loss of existing cartilage extracellular matrix, the production of matrix with abnormal composition and pathologic matrix calcification. Because chondrocyte matrix synthesis and mineralization are modulated by the balance between ATP generation and consumption, the mechanism by which chondrocytes generate energy have been a topic of interest. The analysis of mitochondrial respiratory chain (MRC) activity in OA chondrocytes shows a significant decrease in complexes II and III compared to normal chondrocytes. On the other hand, mitochondrial mass is increased in OA, as demonstrated by a significant rise in CS activity. Furthermore, OA cells show a reduction in the mitochondrial membrane potential (deltapsim) as demonstrated by using the fluorescent probe JC-1. OA cartilage contains high number of apoptotic chondrocytes, and mitochondria play a key role in apoptosis. Interestingly, OA cartilages show markedly elevated Bcl-2 and caspasa-3 expression. This expression is also correlated with chondrocyte apoptosis and OA lesions. The pathogenesis of OA includes elaboration of increased amounts of NO as a consequence of up-regulation of chondrocyte-inducible NO synthase induced by IL-1, TNF-alpha and other factors. NO reduces chondrocyte survival and induces cell death with morphologic changes characteristic of chondrocyte apoptosis. NO reduces the activity of complex IV and decreases the deltapsim as measured as the ratio of red/green fluorescence. Furthermore, NO induces the mRNA expression of caspase-3 and -7, and it reduces the expression of mRNA bcl-2 and the bcl-2 protein synthesis. Some studies suggest that the chondrocyte mitochondria are specialized for calcium transport and are important in the calcification of the extracellular matrix. Mineral formation has been demonstrated in matrix vesicles (MV) and within mitochondria. Direct suppression of mitochondrial respiration promoted MV-mediated mineralization in chondrocytes. Regulation of MRC may be one of the signaling pathways by which NO modulates articular cartilage matrix biosynthesis and pathologic mineralization. After age 40, the incidence of OA in humans increases progressively with increasing age. Studies show a trend to statistic significance between the age and the reduction of complex I activity of human normal chondrocytes. However, the study of relation between age and deltapsim in normal chondrocytes do not demonstrate any significant correlation. It has been reported that as the number of population doublings increased, mitochondrial DNA was degraded and the number of mitochondria per chondrocyte decline. One approach for determining the role of mitochondria in OA is to determine the effects of the MRC inhibition and to compare them with the findings in OA. Inhibition of MRC with antimycin prevents the normal ability of TGFbeta to increase excretion of Pi, thereby worsening deposition of pathologic HA crystals. In chondrocytes, the inhibition of complex IV with NaN3 modified both the deltapsim and the survival of cells inducing apoptosis. Inhibition of complex I with rotenone increases the expression and synthesis of Bcl-2 and Cox-2, both effects are similar effects to produced by IL-1 in human chondrocytes.     

Mitochondrial dysfunction in reproduction

The mitochondrial genome passes from one generation to the next by way of the egg's cytoplasm, so ordinarily an individual's mitochondrial DNA (mtDNA) is entirely derived from his or her mother. A potential mother has a finite number of eggs, or oocytes, all of which were formed when she herself was still a fetus, many years before she can conceive. The eggs are progressively depleted through childhood and her reproductive years at a much faster rate than is accounted for by ovulation. Up to a decade before the ultimate depletion of ovarian follicles (and hence oocytes) at or soon after menopause, cytoplasmic senility of the remaining eggs leads to physiological sterility; a phenomenon that is suspected of being mitochondrially based and has been termed the oopause. When ovulation and conception occur, oxidative phosphorylation and other mitochondrial functions of the fertilized oocyte are thought to be essential to the early embryo well before it implants in the uterus. The competition between follicles to deliver the oocyte that will be fertilized and which will found a new generation could also be mitochondrially based, but the mechanism remains to be elucidated. Increasing experience with the culture of human embryos in vitro is highlighting the importance of mitochondrial metabolism generally, and the avoidance of excessive generation of reactive oxygen species in particular. Paradoxes abound in the experimental data, however. Although natural selection operates on mitochondria only in females (and in extreme cases through the survival of their offspring), reproductive disturbance from mitochondrial mutations is most obvious in males, who typically have reduced sperm motility. mtDNA point mutations such as T8993G, which is serious enough to cause the death of infants from Leigh disease in the first few years of life, can carry through the female germ line apparently unhindered; yet mtDNA deletions that cause a less severe phenotype, and which typically manifest at a later age, are effectively blocked from transmission to offspring--a phenomenon in accord with early experimental observations that deleted mtDNA species are less common in cleaving embryos than in unselected preovulatory oocytes. A mitochondrial basis for ooplasmic aging has not been convincingly established, but the novel IVF-based practice of micro-aspiration and transfer of ooplasm from younger eggs to older eggs, which includes the transfer of mitochondria, appears in preliminary studies to have some clinical efficacy in rejuvenating fertility in older women.     

Mitochondrial dysfunction and lipotoxicity

Mitochondrial dysfunction in skeletal muscle has been suggested to underlie the development of insulin resistance and type 2 diabetes mellitus. Reduced mitochondrial capacity will contribute to the accumulation of lipid intermediates, desensitizing insulin signaling and leading to insulin resistance. Why mitochondrial function is reduced in the (pre-)diabetic state is, however, so far unknown. Although it is tempting to suggest that skeletal muscle insulin resistance may result from an inherited or acquired reduction in mitochondrial function in the pre-diabetic state, it cannot be excluded that mitochondrial dysfunction may in fact be the consequence of the insulin-resistant/diabetic state. Lipotoxicity, the deleterious effects of accumulating fatty acids in skeletal muscle cells, may lie at the basis of mitochondrial dysfunction: next to producing energy, mitochondria are also the major source of reactive oxygen species (ROS). Fatty acids accumulating in the vicinity of mitochondria are vulnerable to ROS-induced lipid peroxidation. Subsequently, these lipid peroxides could have lipotoxic effects on mtDNA, RNA and proteins of the mitochondrial machinery, leading to mitochondrial dysfunction. Indeed, increased lipid peroxidation has been reported in insulin resistant skeletal muscle and the mitochondrial uncoupling protein-3, which has been suggested to prevent lipid-induced mitochondrial damage, is reduced in subjects with an impaired glucose tolerance and in type 2 diabetic patients. These findings support the hypothesis that fat accumulation in skeletal muscle may precede the reduction in mitochondrial function that is observed in type 2 diabetes mellitus.     

Mitochondrial compartmentalization of redox processes

Knowledge of location and intracellular subcompartmentalization is essential for the understanding of redox processes, because oxidants, owing to their reactive nature, must be generated close to the molecules modified in both signaling and damaging processes. Here we discuss known redox characteristics of various mitochondrial microenvironments. Points covered are the locations of mitochondrial oxidant generation, characteristics of antioxidant systems in various mitochondrial compartments, and diffusion characteristics of oxidants in mitochondria. We also review techniques used to measure redox state in mitochondrial subcompartments, antioxidants targeted to mitochondrial subcompartments, and methodological concerns that must be addressed when using these tools.     

Mitochondrial energy metabolism and redox state in dyslipidemias

Changes in mitochondrial function are intimately associated with metabolic diseases. Here, we review recent evidence relating alterations in mitochondrial energy metabolism, ion transport and redox state in hypercholesterolemia and hypertriglyceridemia. We focus mainly on changes in mitochondrial respiration, K(+) and Ca(2+) transport, reactive oxygen species generation and susceptibility to mitochondrial permeability transition.     

Mitochondrial function and redox state in mammalian embryos

Mitochondria play a central and multifaceted role in the mammalian egg and early embryo, contributing to many different aspects of early development. While the contribution of mitochondria to energy production is fundamental, other roles for mitochondria are starting to emerge. Mitochondria are central to intracellular redox metabolism as they produce reactive oxygen species (ROS, the mediators of oxidative stress) and they can generate TCA cycle intermediates and reducing equivalents that are used in antioxidant defence. A high cytosolic lactate dehydrogenase activity coupled with dynamic levels of cytosolic pyruvate is responsible for a very dynamic intracellular redox state in the oocyte and embryo. Mammalian embryos have a low glucose metabolism during the earliest stages of development, as both glycolysis and the pentose phosphate pathway are suppressed. The mitochondrial TCA cycle is therefore the major source of reducing equivalents in the cytosol so that any change in mitochondrial function in the embryo will be reflected in changes in the intracellular redox state. In the mouse, the metabolic substrates used by the oocyte and early embryo each have a different impact on the intracellular redox state. Pyruvate which oxidises the cytosolic redox state, acts as an energetic and redox substrate whereas lactate, which reduces the cytosolic redox state, acts only as a redox substrate. Mammalian early embryos are very sensitive to oxidative stress which can cause permanent developmental arrest before zygotic genome activation and apoptosis in the blastocyst. The oocyte stockpiles antioxidant defence for the early embryo to cope with exogenous and endogenous oxidant insults arising during early development. Mitochondria provide ATP for glutathione (GSH) production during oocyte maturation and also participate in the regeneration of NADPH and GSH during early development. Finally, a number of pathological conditions or environmental insults impair early development by altering mitochondrial function, illustrating the centrality of mitochondrial function in embryo development.     

N-acetyltyrosine-induced redox signaling in hormesis

A suite of adaptations allows insects to survive in hostile terrestrial environments for long periods of time. Temperature represents a key environmental factor for most ectothermic insects, and they rapidly acclimate to high and low temperatures. Vast amounts of data in this research field support the idea that an insect's ability to tolerate fluctuating temperatures can be regarded as a biphasic hormetic dose response. Observation indicates that their thermal hormetic response represents a conservative estimate of their intrinsic capacity for rapid adaptation to environmental changes in nature because they naturally experience diel or seasonal temperature fluctuations. It is therefore reasonable to suppose that the hormetic response in insects reflects a surplus physiological capacity to deal with temperature changes that they would experience naturally. Although it has been unknown how thermal acclimation is induced, a stress-dependent increase in N-acetyltyrosine (NAT) was recently found to occur in insect larvae who had endured high temperatures. NAT treatment was demonstrated to induce thermotolerance in several tested insect species. NAT was also identified in the serum of humans as well as mice, and its concentration in mice was shown to be increased by heat and restraint stress, with NAT pretreatment lowering the concentrations of corticosterone and peroxidized lipids in stressed mice. These recent findings may give us some hints about how long a hormetic response lasts. Here, I will discuss recent findings underlying hormetic responses induced by an intrinsic factor, NAT, and how the hormetic response may begin and end.     

Sphingolipid signaling and redox regulation

Sphingolipids including ceramide and its derivatives such as ceramide-1-phosphate, glycosyl-ceramide, and sphinogosine (-1-phosphate) are now recognized as novel intracellular signal mediators for regulation of inflammation, apoptosis, proliferation, and differentiation. One of the important and regulated steps in these events is the generation of these sphingolipids via hydrolysis of sphingomyelin through the action of sphingomyelinases (SMase). Several lines of evidence suggest that reactive oxygen species (ROS; O2-, H2O2, and OH-,) and reactive nitrogen species (RNS; NO, and ONOO-) and cellular redox potential, which is mainly regulated by cellular glutathione (GSH), are tightly linked to the regulation of SMase activation. On the other hand, sphingolipids are also known to play an important role in maintaining cellular redox homeostasis through regulation of NADPH oxidase, mitochondrial integrity, and antioxidant enzymes. Therefore, this paper reviews the relationship between cellular redox and sphingolipid metabolism and its biological significance.     

Mitochondrial dysfunction in friedreich's ataxia

Friedreich ataxia (FRDA) is an autosomal recessive degenerative disorder caused in the vast majority of cases by a GAA triplet expansion in the FRDA gene on chromosome 9q13. The FRDA gene product, frataxin, is a widely expressed mitochondrial protein which is severely reduced in FRDA patients. Loss of the homologue of frataxin in yeast is associated with mitochondrial iron overload, increased sensitivity to oxidative stress and profound deficit of oxidative phosphorylation. The demonstration that the human pathology of FRDA is also characterised by mitochondrial iron accumulation, deficit of respiratory chain complex activities and in vivo deficit of tissue energy metabolism establishes FRDA as a 'new' nuclear encoded mitochondrial disease.     

Mitochondrial dysfunction in metabolic syndrome

Metabolic syndrome is co-occurrence of obesity, insulin resistance, atherogenic dyslipidemia (high triglyceride, low high density lipoprotein cholesterol), and hypertension. It is a global health problem. An estimated 20%–30% of adults of the world have metabolic syndrome. Metabolic syndrome is associated with increased risk of type 2 diabetes mellitus, nonalcoholic fatty liver disease, myocardial infarction, and stroke. Thus, it is a major cause of morbidity and mortality worldwide. However, molecular pathogenesis of metabolic syndrome is not well known. Recently, there has been interest in the role of mitochondria in pathogenesis of metabolic problems such as obesity, metabolic syndrome, and type 2 diabetes mellitus. Mitochondrial dysfunction contributes to the oxidative stress and systemic inflammation seen in metabolic syndrome. Role of mitochondria in the pathogenesis of metabolic syndrome is intriguing but far from completely understood. However, a better understanding will be very rewarding as it may lead to novel approaches to control this major public health problem. This brief review explores pathogenesis of metabolic syndrome from a mitochondrial perspective.     

Mitochondrial dysfunction in cardiovascular disease

Whereas the pathogenesis of atherosclerosis has been intensively studied and described, the underlying events that initiate cardiovascular disease are not yet fully understood. A substantial number of studies suggest that altered levels of oxidative and nitrosoxidative stress within the cardiovascular environment are essential in the development of cardiovascular disease; however, the impact of such changes on the subcellular or organellar components and their functions that are relevant to cardiovascular disease inception are less understood. In this regard, studies are beginning to show that mitochondria not only appear susceptible to damage mediated by increased oxidative and nitrosoxidative stress, but also play significant roles in the regulation of cardiovascular cell function. In addition, accumulating evidence suggests that a common theme among cardiovascular disease development and cardiovascular disease risk factors is increased mitochondrial damage and dysfunction. This review discusses aspects relating mitochondrial damage and function to cardiovascular disease risk factors and disease development.