The bioenergetic and antioxidant status of neurons is controlled by continuous degradation of a key glycolytic enzyme by APC/C-Cdh1

The pentose-phosphate pathway in neuronal survival against nitrosative stress

Neurons are thought to be particularly vulnerable cells against reactive oxygen and nitrogen species (RONS) damage (nitrosative stress), due in part to their weak antioxidant defense and low ability to compensate energy homeostasis. Intriguingly, nitrosative stress efficiently stimulates the rate of the antioxidant pentose-phosphate pathway (PPP), which generates NADPH a necessary cofactor for the reduction of glutathione disulfide. In fact, inhibition of PPP sensitizes cultured neurons to glutathione oxidation and apoptotic death, whereas its stimulation confers resistance to nitrosative stress. Furthermore, we recently described that neurons can preferentially use glucose through the PPP by inhibiting glycolysis, which is achieved by continuously degrading the glycolytic positive-effector protein, 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase-3 (Pfkfb3) by the action of the E3 ubiquitine ligase anaphase-promoting complex/cyclosome (APC/C)(Cdh1). These results suggest that the antioxidant fragility of neurons may be compensated by the PPP at the expense of inhibiting bioenergetic glycolysis.

Fifteen years of APC/cyclosome: a short and impressive biography

The APC/C (anaphase-promoting complex/cyclosome) discovered exactly 15 years ago by Avram Heshko and Marc Kirschner is by far the most complex ubiquitin ligase discovered so far. The APC/C is composed of roughly a dozen subunits and measures a massive 1.5 MDa. This huge complex, as well as its multiple modes of regulation, boasts impressive evolutionary conservation. One of its most puzzling features is its split personality: regulation of mitotic exit events on the one hand, and its ongoing activity during G(1)-phase, G(0)-phase and in terminally differentiated cells. The present short review is intended to provide a basic description of our current understanding of the APC/C, focusing on recent findings concerning its role in G(1)-phase and in differentiated cells.

NAD(+) and metabolic regulation of age-related proteoxicity: A possible role for methylglyoxal?

A common biochemical characteristic of aging is proteotoxicity i.e. the accumulation of altered proteins. While many studies have shown that NAD(+) is important when lifespan is modulated by dietary means, it is uncertain whether or how NAD(+) affects either formation or elimination of altered proteins. It is suggested here that changes in NAD(+) availability can affect generation of methylglyoxal (MG) from glycolytic intermediates, which in turn can damage proteins, promote generation of reactive oxygen species and induce mitochondrial dysfunction. The proposal can also help to explain how, by altering NAD(+) regeneration from NADH, dietary supplementation with glycerol or glucose, which decreases lifespan in the nematode Caenorhabditis elegans, could cause MG generation to increase, whereas oxaloacetate supplementation, which increases lifespan, could lower the potential for MG formation. The proposal also suggests how upregulation of mitogenesis and mitochondrial activity, and increased aerobic activity, help to decrease the potential for MG formation and resultant proteotoxicity, with consequential beneficial effects with respect to aging.

Two views of brain function

Traditionally studies of brain function have focused on task-evoked responses. By their very nature, such experiments tacitly encourage a reflexive view of brain function. Although such an approach has been remarkably productive, it ignores the alternative possibility that brain functions are mainly intrinsic, involving information processing for interpreting, responding to and predicting environmental demands. Here I argue that the latter view best captures the essence of brain function, a position that accords well with the allocation of the brain's energy resources. Recognizing the importance of intrinsic activity will require integrating knowledge from cognitive and systems neuroscience with cellular and molecular neuroscience where ion channels, receptors, components of signal transduction and metabolic pathways are all in a constant state of flux.

Persistent mitochondrial damage by nitric oxide and its derivatives: neuropathological implications

Approximately 15 years ago we reported that cytochrome c oxidase (CcO) was persistently inhibited as a consequence of endogenous induction and activation of nitric oxide (^•NO) synthase-2 (NOS2) in astrocytes. Furthermore, the reactive nitrogen species implicated was peroxynitrite. In contrast to the reversible inhibition by ^•NO, which occurs rapidly, in competition with O₂, and has signaling regulatory implications, the irreversible CcO damage by peroxynitrite is progressive in nature and follows and/or is accompanied by damage to other key mitochondrial bioenergetic targets. In purified CcO it has been reported that the irreversible inhibition occurs through a mechanism involving damage of the heme a₃-Cu_B binuclear center leading to an increase in the K_m for oxygen. Astrocyte survival, as a consequence of peroxynitrite exposure, is preserved due to their robust bioenergetic and antioxidant defense mechanisms. However, by releasing peroxynitrite to the neighboring neurons, whose antioxidant defense can, under certain conditions, be fragile, activated astrocytes trigger bioenergetic stress leading to neuronal cell death. Thus, such irreversible inhibition of CcO by peroxynitrite may be a plausible mechanism for the neuronal death associated with neurodegenerative diseases, in which the activation of astrocytes plays a crucial role.

The anaphase-promoting complex/cyclosome (APC/C): cell-cycle-dependent and -independent functions

The APC/C (anaphase-promoting complex/cyclosome) is an E3 ubiquitin ligase that targets specific substrates for degradation by the 26S proteasome. APC/C activity depends on two cofactors, namely Cdc20 (cell division cycle 20) and Cdh1, which select the appropriate targets for ubiquitination. It is well established that APC/C is a target of the SAC (spindle assembly checkpoint) during mitosis and has critical roles in controlling the protein levels of major regulators of mitosis and DNA replication. In addition, recent studies have suggested new cell-cycle-independent functions of APC/C in non-mitotic cells and specifically in neuronal structure and function. Given the relevant functions of APC/C in cell proliferation and neuronal physiology, modulating APC/C activity may have beneficial effects in the clinic.

The dynamic ubiquitin ligase duo: Cdh1-APC and Cdc20-APC regulate neuronal morphogenesis and connectivity

The proper development and patterning of axons, dendrites, and synapses is essential for the establishment of accurate neuronal circuits in the brain. A major goal in neurobiology is to identify the mechanisms and principles that govern these fundamental developmental events of neuronal circuit formation. In recent years, exciting new studies have suggested that ubiquitin signaling pathways may play crucial roles in the control of neuronal connectivity. Among E3 ubiquitin ligases, Cdh1-anaphase promoting complex (Cdh1-APC) and Cdc20-APC have emerged as key regulators of diverse aspects of neuronal connectivity, from axon and dendrite morphogenesis to synapse differentiation and remodeling.

E3 ubiquitin ligase APC/C-Cdh1 accounts for the Warburg effect by linking glycolysis to cell proliferation

Cell proliferation is known to be accompanied by activation of glycolysis. We have recently discovered that the glycolysis-promoting enzyme 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase, isoform 3 (PFKFB3), is degraded by the E3 ubiquitin ligase APC/C-Cdh1, which also degrades cell-cycle proteins. We now show in two different cell types (neoplastic and nonneoplastic) that both proliferation and aerobic glycolysis are prevented by overexpression of Cdh1 and enhanced by its silencing. Furthermore, we have coexpressed Cdh1 with PFKFB3--either wild-type or a mutant form resistant to ubiquitylation by APC/C-Cdh1--or with the glycolytic enzyme 6-phosphofructo-1-kinase and demonstrated that whereas glycolysis is essential for cell proliferation, its initiation in the presence of active Cdh1 does not result in proliferation. Our experiments indicate that the proliferative response, regardless of whether it occurs in normal or neoplastic cells, is dependent on a decrease in the activity of APC/C-Cdh1, which activates both proliferation and glycolysis. These observations have implications for cell proliferation, neoplastic transformation, and the prevention and treatment of cancer.

Glycolysis: a bioenergetic or a survival pathway?

Following inhibition of mitochondrial respiration neurons die rapidly, whereas astrocytes utilize glycolytically-generated ATP to increase their mitochondrial membrane potential, thus becoming more resistant to pro-apoptotic stimuli. Neurons are unable to increase glycolysis due to the lack of activity of the glycolysis-promoting enzyme 6-phosphofructo-2-kinase/fructose 2,6-bisphosphatase, isoform 3 (PFKFB3). In neurons, PFKFB3 is degraded constantly via the E3 ubiquitin ligase anaphase-promoting complex/cyclosome (APC/C)- CDH1. Glucose metabolism in neurons is directed mainly to the pentose phosphate pathway, leading to regeneration of reduced glutathione. In addition to their relevance to brain physiology and pathophysiology, these observations suggest that APC/C-CDH1 might link activation of glycolysis and cell proliferation as it is also involved in the regulation of cell cycle proteins.

p53 regulation of metabolic pathways

During the course of tumorigenesis, cells acquire a number of alterations that contribute to the acquisition of the malignant phenotype, allowing them to survive and flourish in increasingly hostile environments. Cancer cells can be characterized by perturbations in the control of cell proliferation and growth, resistance to death, and alterations in their interactions with the microenvironment. Underpinning many of these changes are shifts in metabolism that allow cancer cells to use alternative pathways for energy production and building the macromolecules necessary for growth, as well as regulating the generation of signaling molecules such as reactive oxygen species (ROS). In the past few years, it became clear that p53, the most studied, if not most important, tumor suppressor protein, can also directly control metabolic traits of cells.

Glucose and lactate supply to the synapse

The main source of energy for the mammalian brain is glucose, and the main sink of energy in the mammalian brain is the neuron, so the conventional view of brain energy metabolism is that glucose is consumed preferentially in neurons. But between glucose and the production of energy are several steps that do not necessarily take place in the same cell. An alternative model has been proposed that states that glucose preferentially taken by astrocytes, is degraded to lactate and then exported into neurons to be oxidized. Short of definitive data, opinions about the relative merits of these competing models are divided, making it a very exciting field of research. Furthermore, growing evidence suggests that lactate acts as a signaling molecule, involved in Na(+) sensing, glucosensing, and in coupling neuronal and glial activity to the modulation of vascular tone. In the present review, we discuss possible dynamics of glucose and lactate in excitatory synaptic regions, focusing on the transporters that catalyze the movement of these molecules.

Glucose metabolism and programmed cell death: an evolutionary and mechanistic perspective

Over the last decade, cellular glucose metabolism has emerged as a central player in the mechanisms of programmed cell death (PCD). We examined the metabolic foundations of apoptosis from a Darwinian context and suggest that PCD has evolved from the cellular response to metabolic stress, most notably in relation to glucose metabolism. Whilst apoptosis and other forms of PCD are essential to the development, maintenance and survival of multicellular organisms, it is now evident that controlled and selective cell death confers fitness advantages in unicellular organisms. All species may thus harbour a fundamental relationship between the availability of basic nutrients and life/death decisions. This evolutionary perspective may inform our understanding of PCD in its many guises.

Bilirubin selectively inhibits cytochrome c oxidase activity and induces apoptosis in immature cortical neurons: assessment of the protective effects of glycoursodeoxycholic acid

High levels of unconjugated bilirubin (UCB) may initiate encephalopathy in neonatal life, mainly in pre-mature infants. The molecular mechanisms of this bilirubin-induced neurologic dysfunction (BIND) are not yet clarified and no neuroprotective strategy is currently worldwide accepted. Here, we show that UCB, at conditions mimicking those of hyperbilirubinemic newborns (50 microM UCB in the presence of 100 muM human serum albumin), rapidly (within 1 h) inhibited cytochrome c oxidase activity and ascorbate-driven oxygen consumption in 3 days in vitro rat cortical neurons. This was accompanied by a bioenergetic and oxidative crisis, and apoptotic cell death, as judged by the collapse of the inner-mitochondrial membrane potential, increased glycolytic activity, superoxide anion radical production, and ATP release, as well as disruption of glutathione redox status. Furthermore, the antioxidant compound glycoursodeoxycholic acid (GUDCA) fully abrogated UCB-induced cytochrome c oxidase inhibition and significantly prevented oxidative stress, metabolic alterations, and cell demise. These results suggest that the neurotoxicity associated with neonatal bilirubin-induced encephalopathy occur through a dysregulation of energy metabolism, and supports the notion that GUDCA may be useful in the treatment of BIND.