Faculty Bibliography

Mitochondrial Apoptotic Channel inhibitors or iMACs are di-bromocarbazole derivatives with anti-apoptotic function which have been tested and validated in several mouse models of brain injury and neurodegeneration. Owing to the increased therapeutic potential of these compounds, we sought to expand our knowledge of their mechanism of action. We investigated the kinetics of MAC inhibition in mitochondria from wild type, Bak, and Bax knockout cell lines using patch clamp electrophysiology, fluorescence microscopy, ELISA, and semiquantitative western blot analyses. Our results show that iMACs work through at least two mechanisms: 1) by blocking relocation of the cytoplasmic Bax protein to mitochondria and 2) by disassembling Bax and Bak oligomers in the mitochondrial outer membrane. iMACs exert comparable effects on channel conductance of Bax or Bak and similarly affect cytochrome c release from Bax or Bak-containing mitochondria. Interestingly, wild type mitochondria were more susceptible to inhibition than the Bak or Bax knockouts. Western blot analysis showed that wild type mitochondria had lower steady state levels of Bak in the absence of apoptotic stimulation.

Calcium (Ca2+) plays diverse roles in all living organisms ranging from bacteria to humans. It is a structural element for bones, an essential mediator of excitation-contraction coupling, and a universal second messenger in the regulation of ion channel, enzyme and gene expression activities. In mitochondria, Ca2+ is crucial for the control of energy production and cellular responses to metabolic stress. Ca2+ uptake by the mitochondria occurs by the uniporter mechanism. The Mitochondrial Ca2+ Uniporter (MCU) protein has recently been identified as a core component responsible for mitochondrial Ca2+ uptake. MCU knockout (MCU KO) studies have identified a number of important roles played by this high capacity uptake pathway. Interestingly, this work has also shown that MCU-mediated Ca2+ uptake is not essential for vital cell functions such as muscle contraction, energy metabolism and neurotransmission. Although mitochondrial Ca2+ uptake was markedly reduced, MCU KO mitochondria still contained low but detectable levels of Ca2+. In view of the fundamental importance of Ca2+ for basic cell signalling, this finding suggests the existence of other currently unrecognized pathways for Ca2+ entry. We review the experimental evidence for the existence of alternative Ca2+ influx mechanisms and propose how these mechanisms may play an integral role in mitochondrial Ca2+ signalling.

Amyloid-beta peptides (Abeta), implicated in Alzheimer's disease (AD), interact with the cellular membrane and induce amyloid toxicity. The composition of cellular membranes changes in aging and AD. We designed multi-component lipid models to mimic healthy and diseased states of the neuronal membrane. Using atomic force microscopy (AFM), Kelvin probe force microscopy (KPFM) and black lipid membrane (BLM) techniques, we demonstrated that these model membranes differ in their nanoscale structure and physical properties, and interact differently with Abeta1-42. Based on our data, we propose a new hypothesis that changes in lipid membrane due to aging and AD may trigger amyloid toxicity through electrostatic mechanisms, similar to the accepted mechanism of antimicrobial peptide action. Understanding the role of the membrane changes as a key activating amyloid toxicity may aid in the development of a new avenue for the prevention and treatment of AD.

Background: It is now accepted that mitochondrial dysfunction is a key early event in the progression of neuronal and vascular degeneration in Alzheimer's disease (AD) and that therapies aimed at preventing mitochondrial failure may represent promising new strategies in the pursue of a cure for this devastating disease. Carbonic anhydrases (CAs) are a family of enzymes that catalyze the rapid interconversion of carbon dioxide and water to bicarbonate and protons (or vice versa), maintaining acid-base balance in blood and other tissues. CA isoforms are present in the mitochondria. CA inhibitors (CAIs), such as metazolamide (MTZ) and acetazolamide (ATZ) are clinically used for glaucoma, epilepsy (rarely), and high altitude sickness. Methods: We analyzed the effects of two main CAIs used in clinical settings (MTZ and ATZ) on the mechanism of mitochondrial damage and neurovascular degeneration induced by amyloid beta (Abeta), using cerebral vascular and neural cells as well as the TgSwDI (Swedish- Dutch-Iowa) transgenic mouse model of cerebral amyloidosis. Results: Both CAIs consistently prevented specific pathways of mitochondrial dysfunction induced by Abeta in cerebral microvascular endothelial, neuronal and glial cells, without affecting ATP production, pH, and Calcium flux. Increase of hydrogen peroxide, loss of mitochondrial membrane potential, release of Cytochrome C, caspase activation, and apoptotic cell death were inhibited by CAIs. ATZ was effective at concentrations lower than MTZ. Both drugs, given with diet, were able to ameliorate behavioral paradigms in relatively young TgSwDI mice. Conclusions: CAIs might represent a potentially successful strategy to prevent early mitochondrial dysfunction and neurovascular loss in AD. Further studies in animal models and clinical settings are needed to confirm our hypothesis

BACKGROUND: Calcium signaling plays a key role in the regulation of multiple processes in mammalian mitochondria, from cellular bioenergetics to the induction of stress-induced cell death. While the total concentration of calcium inside the mitochondria can increase by several orders of magnitude, the concentration of bioavailable free calcium in mitochondria is maintained within the micromolar range by the mitochondrial calcium buffering system. This calcium buffering system involves the participation of inorganic phosphate. However, the mechanisms of its function are not yet understood. Specifically, it is not clear how calcium-orthophosphate interactions, which normally lead to formation of insoluble precipitates, are capable to dynamically regulate free calcium concentration. Here we test the hypothesis that inorganic polyphosphate, which is a polymerized form of orthophosphate, is capable to from soluble complexes with calcium, playing a significant role in the regulation of the mitochondrial free calcium concentration. METHODS: We used confocal fluorescence microscopy to measure the relative levels of mitochondrial free calcium in cultured hepatoma cells (HepG2) with variable levels of inorganic polyphosphate (polyP). RESULTS: The depletion of polyP leads to the significantly lower levels of mitochondrial free calcium concentration under conditions of pathological calcium overload. These results are coherent with previous observations showing that inorganic polyphosphate (polyP) can inhibit calcium-phosphate precipitation and, thus, increase the amount of free calcium. CONCLUSIONS: Inorganic polyphosphate plays an important role in the regulation of mitochondrial free calcium, leading to its significant increase. GENERAL SIGNIFICANCE: Inorganic polyphosphate is a previously unrecognized integral component of the mitochondrial calcium buffering system.

Aggregation of alpha-synuclein leads to the formation of oligomeric intermediates that can interact with membranes to form pores. However it is unknown how this leads to cell toxicity in Parkinson's disease. We investigated the species-specific effects of alpha-synuclein on calcium signalling in primary neurons and astrocytes using live neuronal imaging and electrophysiology on artificial membranes. We demonstrate that alpha-synuclein induces an increase in basal intracellular calcium in its unfolded monomeric state as well as in its oligomeric state. Electrophysiology of artificial membranes demonstrated that alpha-synuclein monomers induce irregular ionic currents, while alpha-synuclein oligomers induce rare discrete channel formation. Despite the ability for monomeric alpha-synuclein to affect calcium signalling, it is only the oligomeric form of alpha-synuclein that induces cell death. Oligomer-induced cell death was abolished by the exclusion of extracellular calcium, which prevented the alpha-synuclein induced calcium dysregulation. The findings of this study confirm that alpha-synuclein interacts with membranes to affect calcium signalling in a structure-specific manner and the oligomeric beta sheet rich alpha-synuclein species ultimately leads to calcium dysregulation and calcium dependent cell death.

Mitochondrial permeability transition pore (mPTP) is a large channel located in the mitochondrial inner membrane. The opening of mPTP during pathological calcium overload leads to the membrane depolarization and disruption of ATP production. mPTP activation has been implicated as a central event during the process of stress-induced cell death. mPTP is a supramolecular complex composed of many proteins. Recent studies suggest that mitochondrial ATPase plays the central role in the formation of mPTP. However, the structure of the central conducting pore part of mPTP (mPTPore) remains elusive. Here we review current models proposed for the mPTPore and involvement of polyP in its formation and regulation. We discuss the underestimated role of polyP as an effector and a putative structural component of the mPTPore. We propose the hypothesis that inclusion of polyP can explain such properties of mPTP activity as calcium activation, selectivity and voltage-dependence.