The Scale-Free Dynamics of Eukaryotic Cells

Aon, Miguel A.; Roussel, Marc R.; Cortassa, Sonia; O’Rourke, Brian; Murray, Douglas B.; Beckmann, Manfred; Lloyd, David

doi:10.1371/journal.pone.0003624

Cited by 72 publications

(119 citation statements)

References 68 publications

Supporting

Mentioning

111

Contrasting

Order By: Relevance

“…Recently, the application of network theory on mitochondrial networks has helped to understand the functional connectivity of mitochondria (23), especially the concept of scale-free mitochondrial networks (6,7,13,24). These studies have provided evidence that mitochondrial morphology is linked to function [e.g., in the case of coupling between mitochondria and the L-type Ca 2+ -channel (25)] and that changes in metabolic fluxes may occur by altering the structure of the mitochondrial network and/or the topology of the mitochondrial membranes, which may be structural organizing centers for several intracellular signaling pathways (reviewed in refs.…”

Section: Discussionmentioning

confidence: 99%

“…Aon et al (6) found that this global phase transition occurs at a percolation threshold of the mitochondrial network, and further demonstrated that this global behavior, under normal conditions, obeys fractal, self-similar dynamics (7,12,13), with no inherent characteristic frequency, but rather displays a broad range of frequencies occurring over multiple time scales.…”

mentioning

confidence: 99%

See 1 more Smart Citation

Spatio-temporal oscillations of individual mitochondria in cardiac myocytes reveal modulation of synchronized mitochondrial clusters

Kurz

Aon

O’Rourke

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

123

View full text Add to dashboard Cite

Mitochondrial networks in cardiac myocytes under oxidative stress show collective (cluster) behavior through synchronization of their inner membrane potentials (ΔΨ m ). However, it is unclear whether the oscillation frequency and coupling strength between individual mitochondria affect the size of the cluster and vice versa. We used the wavelet transform and developed advanced signal processing tools that allowed us to capture individual mitochondrial ΔΨ m oscillations in cardiac myocytes and examine their dynamic spatio-temporal properties. Heterogeneous frequency behavior prompted us to sort mitochondria according to their frequencies. Signal analysis of the mitochondrial network showed an inverse relationship between cluster size and cluster frequency as well as between cluster amplitude and cluster size. High cross-correlation coefficients between neighboring mitochondria clustered longitudinally along the myocyte striations, indicated anisotropic communication between mitochondria. Isochronal mapping of the onset of myocyte-wide ΔΨ m depolarization further exemplified heterogeneous ΔΨ m among mitochondria. Taken together, the results suggest that frequency and amplitude modulation of clusters of synchronized mitochondria arises by means of strong changes in local coupling between neighboring mitochondria.wavelets | frequency | amplitude | mitochondrial oscillator | mitochondrial coupling M itochondria in cardiac myocytes under the influence of substrate deprivation or oxidative stress have a fundamental role as determinants of cell life or death, with implications that scale to affect the function of the whole heart (1, 2). Cardiac mitochondria are organized in a highly ordered network consisting of intermyofibrillar, subcarcolemmal, and perinuclear (3) mitochondria whose coordinated function controls the energy metabolism of the myocyte (4).In cardiac myocytes, the localized perturbation of a few mitochondria within the overall mitochondrial network can trigger the transition from the physiological to the pathophysiological state by producing synchronized whole-myocyte oscillations of ΔΨ m that can be monitored with the fluorescent dye tetramethylrhodamine ethyl ester (TMRE) (5). The imbalance between reactive oxygen species (ROS) generation and ROS scavenging capacity in a significant proportion of the network (∼60%) (5) is thought to destabilize ΔΨ m beyond a critical point into a state of ROS-induced ROS release. Increased ROS overflow exceeding a threshold level results in the appearance of a spanning cluster of mitochondria oscillating in apparent synchrony throughout the cell as the mitochondrial network locks into a low-frequency, high-amplitude oscillatory mode (6, 7).In many disparate examples of physically and chemically coupled oscillators, synchronization of the system generally arises from an initial nucleus of (spontaneously) synchronized oscillators that integrate neighboring oscillators, thereby increasing the size and signal amplitude of the initial oscillatory nucleus (8-11).When the clus...

show abstract

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Spatio-temporal oscillations of individual mitochondria in cardiac myocytes reveal modulation of synchronized mitochondrial clusters

Kurz

Aon

O’Rourke

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

123

View full text Add to dashboard Cite

show abstract

“…However, the elusive pacemaker may prove to be a red herring. The rich literature concerning biological oscillators covers cycles as diverse as Canadian lynx/hare relationships (Krebs et al, 1995), fungal mycelia nutrient allocation (Tlalka et al, 2007), cardiac cell energetics (Aon et al, 2003(Aon et al, , 2008a(Aon et al, , 2008b, yeast energetics (Ghosh and Chance, 1964;Aon et al, 2003Aon et al, , 2008aAon et al, , 2008bXu and Tsurugi, 2007), and of course circadian rhythms (Hastings et al, 2008;Johnson et al, 2008). It has become clear that in many of these systems a central pacemaker does not govern oscillations.…”

Section: Nad(p)h/nad(p)mentioning

confidence: 99%

Oscillatory Growth in Lily Pollen Tubes Does Not Require Aerobic Energy Metabolism

et al. 2009

View full text Add to dashboard Cite

Oscillatory tip growth in pollen tubes depends on prodigious amounts of energy. We have tested the hypothesis that oscillations in the electron transport chain lead to growth oscillations in lily (Lilium formosanum). Using three respiratory inhibitors, oligomycin, antimycin A, and cyanide, we find that pollen tube growth is much less sensitive to respiratory inhibition than respiration is. All three block respiration at concentrations severalfold lower than necessary to inhibit growth. Mitochondrial NAD(P)H and potentiometric JC-1 fluorescence, employed as markers for electron transport chain activity, rise rapidly in response to oligomycin, as expected. Pollen tube growth stops for several minutes before resuming. Subsequent growth has a lower mean rate, but continues to oscillate, albeit with a longer period. NAD(P)H fluorescence no longer exhibits coherent oscillations, and mitochondria no longer congregate directly behind the apex: they distribute evenly throughout the cell. Postinhibition growth relies on aerobic fermentation for energy production as revealed by an increase in ethanol in the media. These data suggest that oscillatory growth depends not on a single oscillatory pacemaker but rather is an emergent property arising from a number of stable limit cycles.

show abstract

“…Several periods of 13 h, 40 min and 4 min were detected in the O2 and CO2 time series obtained by mass spectrometry. Further analysis of these time series revealed that the broad range of temporal scales among multi-oscillatory states exhibit self-similar scaling, described by an inverse power law [59].…”

Section: Prediction Control and Modulation Of Complex Dynamic Behaviormentioning

confidence: 99%

Systems Biology of the Fluxome

Aon

Cortassa

2015

Processes

Self Cite

View full text Add to dashboard Cite

Abstract:The advent of high throughput -omics has made the accumulation of comprehensive data sets possible, consisting of changes in genes, transcripts, proteins and metabolites. Systems biology-inspired computational methods for translating metabolomics data into fluxomics provide a direct functional, dynamic readout of metabolic networks. When combined with appropriate experimental design, these methods deliver insightful knowledge about cellular function under diverse conditions. The use of computational models accounting for detailed kinetics and regulatory mechanisms allow us to unravel the control and regulatory properties of the fluxome under steady and time-dependent behaviors. This approach extends the analysis of complex systems from description to prediction, including control of complex dynamic behavior ranging from biological rhythms to catastrophic lethal arrhythmias. The powerful quantitative metabolomics-fluxomics approach will help our ability to engineer unicellular and multicellular organisms evolve from trial-and-error to a more predictable process, and from cells to organ and organisms.

show abstract

The Scale-Free Dynamics of Eukaryotic Cells

Cited by 72 publications

References 68 publications

Spatio-temporal oscillations of individual mitochondria in cardiac myocytes reveal modulation of synchronized mitochondrial clusters

Spatio-temporal oscillations of individual mitochondria in cardiac myocytes reveal modulation of synchronized mitochondrial clusters

Oscillatory Growth in Lily Pollen Tubes Does Not Require Aerobic Energy Metabolism

Systems Biology of the Fluxome

Contact Info

Product

Resources

About