Network dynamics: quantitative analysis of complex behavior in metabolism, organelles, and cells, from experiments to models and back

Kurz, Felix T.; Kembro, Jackelyn Melissa; Flesia, Ana Georgina; Armoundas, Antonis A.; Cortassa, Sonia; Aon, Miguel A.; Lloyd, David

doi:10.1002/wsbm.1352

Cited by 35 publications

(34 citation statements)

References 196 publications

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“…Furthermore, the mean frequency in diabetic cells was lower with 18.3 ± 7.6 mHz (Figure 2E) than in control cells. This result indicates the presence of large clusters with predominant low-frequency, high-amplitude oscillations, likely resulting from relatively slow rate-controlling steps in the synchronization process (Kurz et al, 2010b(Kurz et al, , 2017. Interestingly, insulin treatment restores the frequency distribution to almost control levels, exhibiting a frequency bandwidth of (26.4 ± 10.4) mHz (Figure 2F).…”

Section: Wavelet Analysis Of Mitochondrial Network Dynamicsmentioning

confidence: 92%

“…To further examine and characterize the spatiotemporal dynamic behavior of the mitochondrial networks, we utilized grid-based wavelet analysis of cell fluorescence obtained by imaging with two-photon laser scanning microscopy. The grid-based wavelet approach enables monitoring of the time-dependent evolution of m oscillatory frequencies from mitochondria at both single and population levels, without the need to assume stationarity of the time series ( Supplementary Figures S2-S4; for Sham, STZ, and STZ + Ins, respectively) (Kurz et al, 2010a(Kurz et al, , 2017. Using an average TMRM-fluorescence image of the cell as a template (Supplementary Figure S2A, center), we created a hand-drawn grid (Supplementary Figure S2B, center).…”

Section: Wavelet Analysis Of Mitochondrial Network Dynamicsmentioning

confidence: 99%

“…The largest group of mitochondria with similar frequencies for a specific point in time constitutes a cluster exhibiting highly correlated and coherent m signal, involved in the macroscopic, cell-wide oscillations (Kurz et al, 2017). The size of the cluster influences synchronization; large clusters take longer to synchronize, thus their common frequency is lower compared to smaller clusters (Kurz et al, 2017).…”

Section: Wavelet Analysis Of Mitochondrial Network Dynamicsmentioning

confidence: 99%

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Diabetes Increases the Vulnerability of the Cardiac Mitochondrial Network to Criticality

et al. 2020

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Mitochondrial criticality describes a state in which the mitochondrial cardiac network under intense oxidative stress becomes very sensitive to small perturbations, leading from local to cell-wide depolarization and synchronized oscillations that may escalate to the myocardial syncytium generating arrhythmias. Herein, we describe the occurrence of mitochondrial criticality in the chronic setting of a metabolic disorder, type 1 diabetes (T1DM), using a streptozotocin (STZ)-treated guinea pig (GP) animal model. Using wavelet analysis of mitochondrial networks from two-photon microscopy imaging of cardiac myocytes loaded with a fluorescent probe of the mitochondrial membrane potential, we show that cardiomyocytes from T1DM GPs are closer to criticality, making them more vulnerable to cell-wide mitochondrial oscillations as can be judged by the latency period to trigger oscillations after a laser flash perturbation, and their propensity to oscillate. Insulin treatment of T1DM GPs rescued cardiac myocytes to sham control levels of susceptibility, a protective condition that could also be attained with interventions leading to improvement of the cellular redox environment such as preincubation of diabetic cardiac myocytes with the lipid palmitate or a cell-permeable form of glutathione, in the presence of glucose.

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Section: Wavelet Analysis Of Mitochondrial Network Dynamicsmentioning

confidence: 92%

Section: Wavelet Analysis Of Mitochondrial Network Dynamicsmentioning

confidence: 99%

Section: Wavelet Analysis Of Mitochondrial Network Dynamicsmentioning

confidence: 99%

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Diabetes Increases the Vulnerability of the Cardiac Mitochondrial Network to Criticality

et al. 2020

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“…Systems biology computational methods have been pivotal to addressing the integrated functional dynamics of metabolic, organelle and cellular networks (Kurz et al . ). Metabolic disorders, cancer and caloric restriction, which have an impact on lifespan (Mitchell et al .…”

Section: Introductionmentioning

confidence: 99%

“…Systems biology computational methods have been pivotal to addressing the integrated functional dynamics of metabolic, organelle and cellular networks (Kurz et al 2017). Metabolic disorders, cancer and caloric restriction, which have an impact on lifespan (Mitchell et al 2016), together with pharmacological interventions able to modulate redox metabolism and healthspan (Mitchell et al 2018), are conspicuous examples of data-driven research that can directly benefit from quantitative knowledge of physiological and molecular mechanisms underlying their respective systemic states.…”

Section: Introductionmentioning

confidence: 99%

Metabolic remodelling of glucose, fatty acid and redox pathways in the heart of type 2 diabetic mice

Cortassa

Caceres

Tocchetti

et al. 2018

The Journal of Physiology

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Key points Hearts from type 2 diabetic animals display perturbations in excitation–contraction coupling, impairing myocyte contractility and delaying relaxation, along with altered substrate consumption patterns. Under high glucose and β‐adrenergic stimulation conditions, palmitate can, at least in part, offset left ventricle (LV) dysfunction in hearts from diabetic mice, improving contractility and relaxation while restoring coronary perfusion pressure. Fluxome calculations of central catabolism in diabetic hearts show that, in the presence of palmitate, there is a metabolic remodelling involving tricarboxylic acid cycle, polyol and pentose phosphate pathways, leading to improved redox balance in cytoplasmic and mitochondrial compartments. Under high glucose and increased energy demand, the metabolic/fluxomic redirection leading to restored redox balance imparted by palmitate helps explain maintained LV function and may contribute to designing novel therapeutic approaches to prevent cardiac dysfunction in diabetic patients. Abstract Type‐2 diabetes (T2DM) leads to reduced myocardial performance, and eventually heart failure. Excessive accumulation of lipids and glucose is central to T2DM cardiomyopathy. Previous data showed that palmitate (Palm) or glutathione preserved heart mitochondrial energy/redox balance under excess glucose, rescuing β‐adrenergic‐stimulated cardiac excitation–contraction coupling. However, the mechanisms underlying the accompanying improved contractile performance have been largely ignored. Herein we explore in intact heart under substrate excess the metabolic remodelling associated with cardiac function in diabetic db/db mice subjected to stress given by β‐adrenergic stimulation with isoproterenol and high glucose compared to their non‐diabetic controls (+/+, WT) under euglycaemic conditions. When perfused with Palm, T2DM hearts exhibited improved contractility/relaxation compared to WT, accompanied by extensive metabolic remodelling as demonstrated by metabolomics–fluxomics combined with bioinformatics and computational modelling. The T2DM heart metabolome showed significant differences in the abundance of metabolites in pathways related to glucose, lipids and redox metabolism. Using a validated computational model of heart's central catabolism, comprising glucose and fatty acid (FA) oxidation in cytoplasmic and mitochondrial compartments, we estimated that fluxes through glucose degradation pathways are ∼2‐fold lower in heart from T2DM vs. WT under all conditions studied. Palm addition elicits improvement of the redox status via enhanced β‐oxidation and decreased glucose uptake, leading to flux‐redirection away from redox‐consuming pathways (e.g. polyol) while maintaining the flux through redox‐generating pathways together with glucose–FA ‘shared fuelling’ of oxidative phosphorylation. Thus, available FAs such as Palm may help improve function via enhanced redox balance in T2DM hearts during peaks of hyperglycaemia and increased workload.

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An appreciation of the prescience of Don Gilbert (1930–2011): master of the theory and experimental unravelling of biochemical and cellular oscillatory dynamics

Gilbert

Hammond²,

Brodsky

et al. 2020

Cell Biology International

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We review Don Gilbert's pioneering seminal contributions that both detailed the mathematical principles and the experimental demonstration of several of the key dynamic characteristics of life. Long before it became evident to the wider biochemical community, Gilbert proposed that cellular growth and replication necessitate autodynamic occurrence of cycles of oscillations that initiate, coordinate and terminate the processes of growth, during which all components are duplicated and become spatially re‐organised in the progeny. Initiation and suppression of replication exhibit switch‐like characteristics, that is, bifurcations in the values of parameters that separate static and autodynamic behaviour. His limit cycle solutions present models developed in a series of papers reported between 1974 and 1984, and these showed that most or even all of the major facets of the cell division cycle could be accommodated. That the cell division cycle may be timed by a multiple of shorter period (ultradian) rhythms, gave further credence to the central importance of oscillatory phenomena and homeodynamics as evident on multiple time scales (seconds to hours). Further application of the concepts inherent in limit cycle operation as hypothesised by Gilbert more than 50 years ago are now validated as being applicable to oscillatory transcript, metabolite and enzyme levels, cellular differentiation, senescence, cancerous states and cell death. Now, we reiterate especially for students and young colleagues, that these early achievements were even more exceptional, as his own lifetime's work on modelling was continued with experimental work in parallel with his predictions of the major current enterprises of biological research.

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Network dynamics: quantitative analysis of complex behavior in metabolism, organelles, and cells, from experiments to models and back

Cited by 35 publications

References 196 publications

Diabetes Increases the Vulnerability of the Cardiac Mitochondrial Network to Criticality

Diabetes Increases the Vulnerability of the Cardiac Mitochondrial Network to Criticality

Metabolic remodelling of glucose, fatty acid and redox pathways in the heart of type 2 diabetic mice

An appreciation of the prescience of Don Gilbert (1930–2011): master of the theory and experimental unravelling of biochemical and cellular oscillatory dynamics

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