Modular control analysis of effects of chronic hypoxia on mouse heart

Calmettes, Guillaume; Deschodt-Arsac, Véronique; Thiaudière, Eric; Müller, Bernard; Diolez, Philippe

doi:10.1152/ajpregu.90548.2008

Cited by 12 publications

(30 citation statements)

References 43 publications

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“…Despite the severe mitochondrial alteration after CH reported previously in the entire heart [6], MoCA evidenced an increased elasticity of the energy-producing processes (mainly mitochondria) in CH hearts leading to an improved response to an increase in energy demand [8]. The beneficial consequence of this surprising modification of mitochondrial regulation for integrative cardiac energetics is an unexpected decrease in the control exerted by energy-production on contraction which represents a clear positive adaptation of oxidative phosphorylation system to CH [8]. However, while this result strengthens the idea that mitochondrial energetics plays a crucial role in heart protection against chronic hypoxia, the direct relationship with CH-induced cardioprotection remains to be investigated.…”

Section: Introductioncontrasting

confidence: 52%

“…In parallel, a perturbation of calcium handling has been observed [7], leading to the decrease in calcium transients and therefore alteration of contractility [7]. Those modifications are concomitant with a decrease in phosphorylated metabolites concentrations in CH hearts, mainly phosphocreatine (PCr) [8], [9]. Altogether, these results evidence the development of a global heart failure in CH hearts [1], [10], [11].…”

Section: Introductionmentioning

confidence: 86%

“…Since recent evidence indicates that defects in communication between ATP-producing and ATP-consuming cellular sites are a major factor contributing to energetic deficiency in heart failure [23], tools such as MoCA, allowing study of the integrated cardiovascular function, are of particular interest [24]. Recently, we applied MoCA to study the effects of a 3-week CH on the energetics of contraction of intact perfused mouse hearts [8]. Despite the severe mitochondrial alteration after CH reported previously in the entire heart [6], MoCA evidenced an increased elasticity of the energy-producing processes (mainly mitochondria) in CH hearts leading to an improved response to an increase in energy demand [8].…”

Section: Introductionmentioning

confidence: 99%

“…Recently, we applied MoCA to study the effects of a 3-week CH on the energetics of contraction of intact perfused mouse hearts [8]. Despite the severe mitochondrial alteration after CH reported previously in the entire heart [6], MoCA evidenced an increased elasticity of the energy-producing processes (mainly mitochondria) in CH hearts leading to an improved response to an increase in energy demand [8]. The beneficial consequence of this surprising modification of mitochondrial regulation for integrative cardiac energetics is an unexpected decrease in the control exerted by energy-production on contraction which represents a clear positive adaptation of oxidative phosphorylation system to CH [8].…”

Section: Introductionmentioning

confidence: 99%

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Improved Energy Supply Regulation in Chronic Hypoxic Mouse Counteracts Hypoxia-Induced Altered Cardiac Energetics

et al. 2010

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BackgroundHypoxic states of the cardiovacular system are undoubtedly associated with the most frequent diseases of modern time. Therefore, understanding hypoxic resistance encountered after physiological adaptation such as chronic hypoxia, is crucial to better deal with hypoxic insult. In this study, we examine the role of energetic modifications induced by chronic hypoxia (CH) in the higher tolerance to oxygen deprivation.Methodology/Principal FindingsSwiss mice were exposed to a simulated altitude of 5500 m in a barochamber for 21 days. Isolated perfused hearts were used to study the effects of a decreased oxygen concentration in the perfusate on contractile performance (RPP) and phosphocreatine (PCr) concentration (assessed by 31P-NMR), and to describe the integrated changes in cardiac energetics regulation by using Modular Control Analysis (MoCA). Oxygen reduction induced a concomitant decrease in RPP (−46%) and in [PCr] (−23%) in Control hearts while CH hearts energetics was unchanged. MoCA demonstrated that this adaptation to hypoxia is the direct consequence of the higher responsiveness (elasticity) of ATP production of CH hearts compared with Controls (−1.88±0.38 vs −0.89±0.41, p<0.01) measured under low oxygen perfusion. This higher elasticity induces an improved response of energy supply to cellular energy demand. The result is the conservation of a healthy control pattern of contraction in CH hearts, whereas Control hearts are severely controlled by energy supply.Conclusions/SignificanceAs suggested by the present study, the mechanisms responsible for this increase in elasticity and the consequent improved ability of CH heart metabolism to respond to oxygen deprivation could participate to limit the damages induced by hypoxia.

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Section: Introductioncontrasting

confidence: 52%

Section: Introductionmentioning

confidence: 86%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Improved Energy Supply Regulation in Chronic Hypoxic Mouse Counteracts Hypoxia-Induced Altered Cardiac Energetics

et al. 2010

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“…supply, demand and metabolite changes, by which the effect(s) of a drug/hormone [3,4] or a pathology [5,6] are transmitted. In particular, the study of inotropic drugs/action permits the qualitative and quantitative description of the activation of heart contraction.…”

Section: Introductionmentioning

confidence: 99%

System analysis of the effect of various drugs on cardiac contraction energetics

Deschodt-Arsac

Calmettes

Gouspillou

et al. 2010

Biochemical Society Transactions

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We used MoCA (Modular Control and Regulation Analysis) to demonstrate in intact beating rat heart that physiological activation of contraction by adrenaline involves the almost perfect parallel activation of both mitochondria and myofibrils by intracellular Ca(2+). This explains the perfect homoeostasis of the energetic intermediate PCr (phosphocreatine) in heart. When using drugs specifically stimulating either supply or demand activities, MoCA helped reveal the very specific mode of regulation of heart contraction energetics. Only activation of myofibrils activity (demand), either by increasing intracellular Ca(2+) concentration or myofibrils sensitivity to Ca(2+), triggers activation of contractile activity. In contrast, the activation of mitochondrial activity (supply) has strictly no effect on contraction, either directly or through PCr changes (intermediate).

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4D retrospective black blood trueFISP imaging of mouse heart

Miraux

Calmettes

Massot

et al. 2009

Magnetic Resonance in Med

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The purpose of this study was to demonstrate the feasibility of steady-state True fast imaging with steady precession (True-FISP) four-dimensional imaging of mouse heart at high resolution and its efficiency for cardiac volumetry. Three-dimensional cine-imaging of control and hypoxic mice was carried out at 4.7 T without magnetization preparation or ECG-triggering. The k-space lines were acquired with the TrueFISP sequence (pulse repetition time/echo time ‫؍‬ 4/2 ms) in a repeated sequential manner. Retrospective reordering of raw data allowed the reconstruction of 10 three-dimensional images per cardiac cycle. The acquisition scheme used an alternating radiofrequency phase and sum-of-square reconstruction method. Black-blood three-dimensional images at around 200 m resolution were produced without banding artifact throughout the cardiac cycle. High contrast to noise made it possible to estimate cavity volumes during diastole and systole. Right and left ventricular stroke volume was significantly higher in hypoxic mice vs controls (20.2 ؎ 2 vs 15.1 ؎ 2; P < 0.05, 24.9 ؎ 2 vs 20.4 ؎ 2; P < 0.05, respectively). Owing to the many possibilities offered by transgenic and surgical approaches, numerous models of cardiovascular diseases have been developed in mouse. This provides not only a better understanding of physiology but is also of great use in preclinical trials, e.g., gene therapy or pharmacological treatment.MRI has become a reference noninvasive tool to characterize variations in structure and function of mouse heart. Until now, most of the MR studies on mouse models were performed with two-dimensional white-blood cine-imaging combined with cardiac triggering for MR acquisition synchronization (1-4). Parameters like end-systolic and end-diastolic volumes can be measured in order to evaluate both stroke volume and ejection fraction. Nevertheless, routine MRI techniques suffer from many drawbacks. First of all, two-dimensional imaging results in a limited spatial resolution in the slice dimension. In fact, typical out-ofplane resolutions are in the range of 1 mm, whereas mouse heart does not exceed 10 mm in the long axis. This could result in measurement errors due to a partial volume effect.To overcome this issue, some authors have shown interest in performing four-dimensional (4D) (three-dimensional [3D]-cine) imaging (5-7). Feintuch et al. (6) demonstrated the feasibility of 4D mouse imaging with an isotropic spatial resolution of 200 m. Nevertheless, scan times were very long (between 80 and 120 min) for bright blood imaging. More recently, Bucholz et al. (7) presented impressive images with exceptional resolution (80 m), but injection of a nonconventional liposomal gadolinium contrast agent was required. The other drawback of such experiments is that, in many cases, images are acquired with a bright blood contrast. It is now widely accepted that MR sequences with suppression of the blood signal (black or dark blood sequence) are more appropriate to reduce interobserver variability in the drawing of epicar...

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Modular control analysis of effects of chronic hypoxia on mouse heart

Cited by 12 publications

References 43 publications

Improved Energy Supply Regulation in Chronic Hypoxic Mouse Counteracts Hypoxia-Induced Altered Cardiac Energetics

Improved Energy Supply Regulation in Chronic Hypoxic Mouse Counteracts Hypoxia-Induced Altered Cardiac Energetics

System analysis of the effect of various drugs on cardiac contraction energetics

4D retrospective black blood trueFISP imaging of mouse heart

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