Your search keyword '"Heather, Lisa"' showing total 12 results

1. Cardiomyocyte tetrahydrobiopterin synthesis regulates fatty acid metabolism and susceptibility to ischaemia–reperfusion injury.

Author

Chu, Sandy M., Heather, Lisa C., Chuaiphichai, Surawee, Nicol, Thomas, Wright, Benjamin, Miossec, Matthieu, Bendall, Jennifer K., Douglas, Gillian, Crabtree, Mark J., and Channon, Keith M.

Subjects

*TETRAHYDROBIOPTERIN, *FATTY acids, *HEART metabolism, *FATTY acid oxidation, *GUANOSINE triphosphate, *NITRIC oxide

Abstract

New Findings: What is the central question of this study?What are the physiological roles of cardiomyocyte‐derived tetrahydrobiopterin (BH4) in cardiac metabolism and stress response?What is the main finding and its importance?Cardiomyocyte BH4 has a physiological role in cardiac metabolism. There was a shift of substrate preference from fatty acid to glucose in hearts with targeted deletion of BH4 synthesis. The changes in fatty‐acid metabolic profile were associated with a protective effect in response to ischaemia–reperfusion (IR) injury, and reduced infarct size. Manipulating fatty acid metabolism via BH4 availability could play a therapeutic role in limiting IR injury. Tetrahydrobiopterin (BH4) is an essential cofactor for nitric oxide (NO) synthases in which its production of NO is crucial for cardiac function. However, non‐canonical roles of BH4 have been discovered recently and the cell‐specific role of cardiomyocyte BH4 in cardiac function and metabolism remains to be elucidated. Therefore, we developed a novel mouse model of cardiomyocyte BH4 deficiency, by cardiomyocyte‐specific deletion of Gch1, which encodes guanosine triphosphate cyclohydrolase I, a required enzyme for de novo BH4 synthesis. Cardiomyocyte (cm)Gch1 mRNA expression and BH4 levels from cmGch1 KO mice were significantly reduced compared to Gch1flox/flox (WT) littermates. Transcriptomic analyses and protein assays revealed downregulation of genes involved in fatty acid oxidation in cmGch1 KO hearts compared with WT, accompanied by increased triacylglycerol concentration within the myocardium. Deletion of cardiomyocyte BH4 did not alter basal cardiac function. However, the recovery of left ventricle function was improved in cmGch1 KO hearts when subjected to ex vivo ischaemia–reperfusion (IR) injury, with reduced infarct size compared to WT hearts. Metabolomic analyses of cardiac tissue after IR revealed that long‐chain fatty acids were increased in cmGch1 KO hearts compared to WT, whereas at 5 min reperfusion (post‐35 min ischaemia) fatty acid metabolite levels were higher in WT compared to cmGch1 KO hearts. These results indicate a new role for BH4 in cardiomyocyte fatty acid metabolism, such that reduction of cardiomyocyte BH4 confers a protective effect in response to cardiac IR injury. Manipulating cardiac metabolism via BH4 could play a therapeutic role in limiting IR injury. [ABSTRACT FROM AUTHOR]

Published

2023

2. Rapid, B1‐insensitive, dual‐band quasi‐adiabatic saturation transfer with optimal control for complete quantification of myocardial ATP flux.

Author

Miller, Jack J., Valkovič, Ladislav, Kerr, Matthew, Timm, Kerstin N., Watson, William D., Lau, Justin Y. C., Tyler, Andrew, Rodgers, Christopher, Bottomley, Paul A., Heather, Lisa C., and Tyler, Damian J.

Subjects

MAGNETIZATION transfer, BLOCH equations, FLUX (Energy), CREATINE kinase, NONLINEAR analysis

Abstract

Purpose: Phosphorus saturation‐transfer experiments can quantify metabolic fluxes noninvasively. Typically, the forward flux through the creatine kinase reaction is investigated by observing the decrease in phosphocreatine (PCr) after saturation of γ‐ATP. The quantification of total ATP utilization is currently underexplored, as it requires simultaneous saturation of inorganic phosphate (Pi) and PCr. This is challenging, as currently available saturation pulses reduce the already‐low γ‐ATP signal present. Methods: Using a hybrid optimal‐control and Shinnar‐Le Roux method, a quasi‐adiabatic RF pulse was designed for the dual saturation of PCr and Pi to enable determination of total ATP utilization. The pulses were evaluated in Bloch equation simulations, compared with a conventional hard‐cosine DANTE saturation sequence, before being applied to perfused rat hearts at 11.7 T. Results: The quasi‐adiabatic pulse was insensitive to a >2.5‐fold variation in B1, producing equivalent saturation with a 53% reduction in delivered pulse power and a 33‐fold reduction in spillover at the minimum effective B1. This enabled the complete quantification of the synthesis and degradation fluxes for ATP in 30‐45 minutes in the perfused rat heart. While the net synthesis flux (4.24 ± 0.8 mM/s, SEM) was not significantly different from degradation flux (6.88 ± 2 mM/s, P =.06) and both measures are consistent with prior work, nonlinear error analysis highlights uncertainties in the Pi‐to‐ATP measurement that may explain a trend suggesting a possible imbalance. Conclusions: This work demonstrates a novel quasi‐adiabatic dual‐saturation RF pulse with significantly improved performance that can be used to measure ATP turnover in the heart in vivo. [ABSTRACT FROM AUTHOR]

Published

2021

3. Hyperpolarized magnetic resonance shows that the anti‐ischemic drug meldonium leads to increased flux through pyruvate dehydrogenase in vivo resulting in improved post‐ischemic function in the diabetic heart.

Author

Savic, Dragana, Ball, Vicky, Holzner, Lorenz, Hauton, David, Timm, Kerstin N., Curtis, M. Kate, Heather, Lisa C., and Tyler, Damian J.

Subjects

MAGNETIC resonance, GLYCEMIC control, HEART metabolism, TYPE 1 diabetes, LABORATORY rats

Abstract

The diabetic heart has a decreased ability to metabolize glucose. The anti‐ischemic drug meldonium may provide a route to counteract this by reducing l‐carnitine levels, resulting in improved cardiac glucose utilization. Therefore, the aim of this study was to use the novel technique of hyperpolarized magnetic resonance to investigate the in vivo effects of treatment with meldonium on cardiac metabolism and function in control and diabetic rats. Thirty‐six male Wistar rats were injected either with vehicle, or with streptozotocin (55 mg/kg) to induce a model of type 1 diabetes. Daily treatment with either saline or meldonium (100 mg/kg/day) was undertaken for three weeks. in vivo cardiac function and metabolism were assessed with CINE MRI and hyperpolarized magnetic resonance respectively. Isolated perfused hearts were challenged with low‐flow ischemia/reperfusion to assess the impact of meldonium on post‐ischemic recovery. Meldonium had no significant effect on blood glucose concentrations or on baseline cardiac function. However, hyperpolarized magnetic resonance revealed that meldonium treatment elevated pyruvate dehydrogenase flux by 3.1‐fold and 1.2‐fold in diabetic and control animals, respectively, suggesting an increase in cardiac glucose oxidation. Hyperpolarized magnetic resonance further demonstrated that meldonium reduced the normalized acetylcarnitine signal by 2.1‐fold in both diabetic and control animals. The increase in pyruvate dehydrogenase flux in vivo was accompanied by an improvement in post‐ischemic function ex vivo, as meldonium elevated the rate pressure product by 1.3‐fold and 1.5‐fold in the control and diabetic animals, respectively. In conclusion, meldonium improves in vivo pyruvate dehydrogenase flux in the diabetic heart, contributing to improved cardiac recovery after ischemia. [ABSTRACT FROM AUTHOR]

Published

2021

4. Simultaneous in vivo assessment of cardiac and hepatic metabolism in the diabetic rat using hyperpolarized MRS.

Author

Le Page, Lydia M., Ball, Daniel R., Ball, Vicky, Dodd, Michael S., Miller, Jack J., Heather, Lisa C., and Tyler, Damian J.

Abstract

Understanding and assessing diabetic metabolism is vital for monitoring disease progression and improving treatment of patients. In vivo assessments , using MRI and MRS, provide non-invasive and accurate measurements, and the development of hyperpolarized 13C spectroscopy in particular has been demonstrated to provide valuable metabolic data in real time. Until now, studies have focussed on individual organs. However, diabetes is a systemic disease affecting multiple tissues in the body. Therefore, we have developed a technique to simultaneously measure metabolism in both the heart and liver during a single acquisition. A hyperpolarized 13C MRS protocol was developed to allow acquisition of metabolic data from the heart and liver during a single scan. This protocol was subsequently used to assess metabolism in the heart and liver of seven control male Wistar rats and seven diabetic rats (diabetes was induced by three weeks of high-fat feeding and a 30 mg/kg injection of streptozotocin). Using our new acquisition, we observed decreased cardiac and hepatic pyruvate dehydrogenase flux in our diabetic rat model. These diabetic rats also had increased blood glucose levels, decreased insulin, and increased hepatic triglycerides. Decreased production of hepatic [1-13C]alanine was observed in the diabetic group, but this change was not present in the hearts of the same diabetic animals. We have demonstrated the ability to measure cardiac and hepatic metabolism simultaneously, with sufficient sensitivity to detect metabolic alterations in both organs. Further, we have non-invasively observed the different reactions of the heart and liver to the metabolic challenge of diabetes. [ABSTRACT FROM AUTHOR]

Published

2016

5. On the pivotal role of PPARa in adaptation of the heart to hypoxia and why fat in the diet increases hypoxic injury.

Author

Cole, Mark A., Jamil, Amira H. Abd, Heather, Lisa C., Murray, Andrew J., Sutton, Elizabeth R., Slingo, Mary, Sebag-Montefiore, Liam, Suat Cheng Tan, Aksentijević, Dunja, Gildea, Ottilie S., Stuckey, Daniel J., Kar Kheng Yeoh, Carr, Carolyn A., Evans, Rhys D., Aasum, Ellen, Schofield, Christopher J., Ratcliffe, Peter J., Neubauer, Stefan, Robbins, Peter A., and Clarke, Kieran

Published

2016

6. Increased oxidative metabolism following hypoxia in the type 2 diabetic heart, despite normal hypoxia signalling and metabolic adaptation.

Author

Mansor, Latt S., Mehta, Keshavi, Aksentijevic, Dunja, Carr, Carolyn A., Lund, Trine, Cole, Mark A., Page, Lydia Le, Sousa Fialho, Maria da Luz, Shattock, Michael J., Aasum, Ellen, Clarke, Kieran, Tyler, Damian J, and Heather, Lisa C.

Subjects

HYPOXEMIA, TYPE 2 diabetes, MUSCLE metabolism, MYOCARDIUM, HEART metabolism, PHYSIOLOGY

Abstract

Key points Adaptation to hypoxia makes the heart more oxygen efficient, by metabolising more glucose. In contrast, type 2 diabetes makes the heart metabolise more fatty acids., Diabetes increases the chances of the heart being exposed to hypoxia, but whether the diabetic heart can adapt and respond is unknown., In this study we show that diabetic hearts retain the ability to adapt their metabolism in response to hypoxia, with functional hypoxia signalling pathways., However, the hypoxia-induced changes in metabolism are additive to abnormal baseline metabolism, resulting in hypoxic diabetic hearts metabolising more fat and less glucose than controls. This stops the diabetic heart being able to recover its function when stressed., These results demonstrate that the diabetic heart retains metabolic flexibility to adapt to hypoxia, but is hindered by the baseline effects of the disease. This increases our understanding of how the diabetic heart is affected by hypoxia-associated complications of the disease., Abstract Hypoxia activates the hypoxia-inducible factor (HIF), promoting glycolysis and suppressing mitochondrial respiration. In the type 2 diabetic heart, glycolysis is suppressed whereas fatty acid metabolism is promoted. The diabetic heart experiences chronic hypoxia as a consequence of increased obstructive sleep apnoea and cardiovascular disease. Given the opposing metabolic effects of hypoxia and diabetes, we questioned whether diabetes affects cardiac metabolic adaptation to hypoxia. Control and type 2 diabetic rats were housed for 3 weeks in normoxia or 11% oxygen. Metabolism and function were measured in the isolated perfused heart using radiolabelled substrates. Following chronic hypoxia, both control and diabetic hearts upregulated glycolysis, lactate efflux and glycogen content and decreased fatty acid oxidation rates, with similar activation of HIF signalling pathways. However, hypoxia-induced changes were superimposed on diabetic hearts that were metabolically abnormal in normoxia, resulting in glycolytic rates 30% lower, and fatty acid oxidation 36% higher, in hypoxic diabetic hearts than hypoxic controls. Peroxisome proliferator-activated receptor α target proteins were suppressed by hypoxia, but activated by diabetes. Mitochondrial respiration in diabetic hearts was divergently activated following hypoxia compared with controls. These differences in metabolism were associated with decreased contractile recovery of the hypoxic diabetic heart following an acute hypoxic insult. In conclusion, type 2 diabetic hearts retain metabolic flexibility to adapt to hypoxia, with normal HIF signalling pathways. However, they are more dependent on oxidative metabolism following hypoxia due to abnormal normoxic metabolism, which was associated with a functional deficit in response to stress. [ABSTRACT FROM AUTHOR]

Published

2016

7. Dietary nitrate increases arginine availability and protects mitochondrial complex I and energetics in the hypoxic rat heart.

Author

Ashmore, Tom, Fernandez, Bernadette O., Branco‐Price, Cristina, West, James A., Cowburn, Andrew S., Heather, Lisa C., Griffin, Julian L., Johnson, Randall S., Feelisch, Martin, and Murray, Andrew J.

Subjects

MITOCHONDRIA, ADENOSINE triphosphate, REACTIVE oxygen species, DIETARY supplements, BLOOD flow measurement

Abstract

Hypoxic exposure is associated with impaired cardiac energetics in humans and altered mitochondrial function, with suppressed complex I-supported respiration, in rat heart. This response might limit reactive oxygen species generation, but at the cost of impaired electron transport chain (ETC) activity. Dietary nitrate supplementation improves mitochondrial efficiency and can promote tissue oxygenation by enhancing blood flow. We therefore hypothesised that ETC dysfunction, impaired energetics and oxidative damage in the hearts of rats exposed to chronic hypoxia could be alleviated by sustained administration of a moderate dose of dietary nitrate. Male Wistar rats (n = 40) were given water supplemented with 0.7 mmol l-1 NaCl (as control) or 0.7 mmol l-1 NaNO3, elevating plasma nitrate levels by 80%, and were exposed to 13% O2 (hypoxia) or normoxia (n = 10 per group) for 14 days. Respiration rates, ETC protein levels, mitochondrial density, ATP content and protein carbonylation were measured in cardiacmuscle. Complex I respiration rates and protein levels were 33% lower in hypoxic/NaCl rats compared with normoxic/NaCl controls. Protein carbonylation was 65% higher in hearts of hypoxic rats compared with controls, indicating increased oxidative stress, whilst ATP levels were 62% lower. Respiration rates, complex I protein and activity, protein carbonylation and ATP levels were all fully protected in the hearts of nitrate-supplemented hypoxic rats. Both in normoxia and hypoxia, dietary nitrate suppressed cardiac arginase expression and activity and markedly elevated cardiac L-arginine concentrations, unmasking a novel mechanism of action by which nitrate enhances tissue NO bioavailability. Dietary nitrate therefore alleviates metabolic abnormalities in the hypoxic heart, improving myocardial energetics. [ABSTRACT FROM AUTHOR]

Published

2014

8. Determining the in vivo regulation of cardiac pyruvate dehydrogenase based on label flux from hyperpolarised [1-13C]pyruvate.

Author

Schroeder, Marie A., Atherton, Helen J., Heather, Lisa C., Griffin, Julian L., Clarke, Kieran, Radda, George K., and Tyler, Damian J.

Abstract

Pyruvate dehydrogenase (PDH) is a key regulator of cardiac substrate selection and is regulated by both pyruvate dehydrogenase kinase (PDK)-mediated phosphorylation and feedback inhibition. The extent to which chronic upregulation of PDK protein levels, acutely increased PDK activity and acute feedback inhibition limit PDH flux remains unclear because existing in vitro assessment methods inherently disrupt the regulation of the enzyme complex. We have demonstrated previously that hyperpolarised 13C-labelled metabolic tracers coupled with MRS can monitor flux through PDH in vivo. The aim of this study was to determine the relative contributions of acute and chronic changes in PDK and PDH activities to in vivo myocardial PDH flux. We examined both fed and fasted rats with either hyperpolarised [1-13C]pyruvate alone or hyperpolarised [1-13C]pyruvate co-infused with malate [to modulate mitochondrial nicotinamide adenine dinucleotide (NADH/NAD+) and acetyl-coenzyme A (acetyl-CoA)/CoA ratios, which alter both PDH activity and flux]. To confirm the metabolic fate of infused malate, we performed in vitro 1H NMR spectroscopy on cardiac tissue extracts. We observed that, in fed rats, where PDH activity was high, the presence of malate increased PDH flux by 27%, whereas, in the fasted state, malate infusion had no effect on PDH flux. These observations suggest that pyruvate oxidation is limited by feedback inhibition from acetyl-CoA only when PDH activity is high. Therefore, in the case of PDH, and potentially other enzymes, hyperpolarised 13C MRI can be used to assess noninvasively enzymatic regulation. Copyright © 2011 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published

2011

9. Normobaric hypoxia impairs human cardiac energetics.

Author

Holloway, Cameron, Cochlin, Lowri, Codreanu, Ion, Bloch, Edward, Fatemian, Marzieh, Szmigielski, Cezary, Atherton, Helen, Heather, Lisa, Francis, Jane, Neubauer, Stefan, Robbins, Peter, Montgomery, Hugh, and Clarke, Kieran

Subjects

HYPOXEMIA, HEART, ENERGY metabolism, DIASTOLE (Cardiac cycle), INFLUENCE of altitude

Abstract

Hypoxia causes left ventricular dysfunction in the human heart, but the biochemical mechanism is poorly understood. Here, we tested whether short-term normobaric hypoxia leads to changes in cardiac energetics and early cardiac dysfunction. Healthy male volunteers (m=12, age 24±2 yr) were exposed to normobaric hypoxia in a purpose-built hypoxic chamber. The partial pressure of oxygen during end-tidal expiration (PETo2) was kept between 50 and 60 mmHg, and peripheral oxygen saturation (SaO2) was kept above 80%. Cardiac morphology and function were assessed using magnetic resonance imaging and echocardiography, both before and after 20 h of hypoxic exposure, and high-energy phosphate metabolism [measured as the phosphocreatine (PCr)/ATP ratio] was measured using 31P magnetic resonance spectroscopy. During hypoxia, PETO2 and SaO2 averaged 55 ± 1 mmHg and 83.6 ± 0.4%, respectively. Hypoxia caused a 15% reduction in cardiac PCr/ATP (from 2.0±0.1 to 1.7±0.1, P<0.01) and reduced diastolic function (measured as E/E', rising from 6.1 ±0.4 to 7.5±0.7, P<0.01). Normobaric hypoxia causes a rapid decrease in high-energy phosphate metabolism in the human cardiac left ventricle, which may lead to a decline in diastolic function. These findings are important in understanding the response of normal individuals to environmental hypoxia, and to situations in which disease reduces cardiac oxygen delivery. [ABSTRACT FROM AUTHOR]

Published

2011

10. Validation of the in vivo assessment of pyruvate dehydrogenase activity using hyperpolarised.

Author

Atherton, Helen J., Schroeder, Marie A., Dodd, Michael S., Heather, Lisa C., Carter, Emma E., Cochlin, Lowri E., Nagel, Simon, Sibson, Nicola R., Radda, George K., Clarke, Kieran, and Tyler, Damian J.

Published

2011

11. Real-time assessment of Krebs cycle metabolism using hyperpolarized 13C magnetic resonance spectroscopy.

Author

Schroeder, Marie A., Atherton, Helen J., Ball, Daniel R., Cole, Mark A., Heather, Lisa C., Griffin, Julian L., Clarke, Kieran, Radda, George K., and Tyler, Damian J.

Subjects

KREBS cycle, METABOLISM, HEART diseases, MAGNETIC resonance, PYRUVATES, LABORATORY rats

Abstract

The Krebs cycle plays a fundamental role in cardiac energy production and is often implicated in the energetic imbalance characteristic of heart disease. In this study, we measured Krebs cycle flux in real time in perfused rat hearts using hyperpolarized magnetic resonance spectroscopy (MRS). [2-13C]Pyruvate was hyperpolarized and infused into isolated perfused hearts in both healthy and postischemic metabolic states. We followed the enzymatic conversion of pyruvate to lactate, acetylcarnitine, citrate, and glutamate with 1 s temporal resolution. The appearance of 13C-labeled glutamate was delayed compared with that of other metabolites, indicating that Krebs cycle flux can be measured directly. The production of 13C-labeled citrate and glutamate was decreased postischemia, as opposed to lactate, which was significantly elevated. These results showed that the control and fluxes of the Krebs cycle in heart disease can be studied using hyperpolarized [2-13C] pyruvate. [ABSTRACT FROM AUTHOR]

Published

2009

12. Assessing the effect of hypoxia on cardiac metabolism using hyperpolarized 13C magnetic resonance spectroscopy.

Author

Le Page, Lydia M., Rider, Oliver J., Lewis, Andrew J., Noden, Victoria, Kerr, Matthew, Giles, Lucia, Ambrose, Lucy J.A., Ball, Vicky, Mansor, Latt, Heather, Lisa C., and Tyler, Damian J.

Subjects

NUCLEAR magnetic resonance spectroscopy, HEART metabolism, HYPOXEMIA, LACTATE dehydrogenase

Abstract

Hypoxia plays a role in many diseases and can have a wide range of effects on cardiac metabolism depending on the extent of the hypoxic insult. Noninvasive imaging methods could shed valuable light on the metabolic effects of hypoxia on the heart in vivo. Hyperpolarized carbon‐13 magnetic resonance spectroscopy (HP 13C MRS) in particular is an exciting technique for imaging metabolism that could provide such information. The aim of our work was, therefore, to establish whether hyperpolarized 13C MRS can be used to assess the in vivo heart's metabolism of pyruvate in response to systemic acute and chronic hypoxic exposure. Groups of healthy male Wistar rats were exposed to either acute (30 minutes), 1 week or 3 weeks of hypoxia. In vivo MRS of hyperpolarized [1‐13C] pyruvate was carried out along with assessments of physiological parameters and ejection fraction. Hematocrit was elevated after 1 week and 3 weeks of hypoxia. 30 minutes of hypoxia resulted in a significant reduction in pyruvate dehydrogenase (PDH) flux, whereas 1 or 3 weeks of hypoxia resulted in a PDH flux that was not different to normoxic animals. Conversion of hyperpolarized [1‐13C] pyruvate into [1‐13C] lactate was elevated following acute hypoxia, suggestive of enhanced anaerobic glycolysis. Elevated HP pyruvate to lactate conversion was also seen at the one week timepoint, in concert with an increase in lactate dehydrogenase (LDH) expression. Following three weeks of hypoxic exposure, cardiac metabolism of pyruvate was comparable with that observed in normoxia. We have successfully visualized the effects of systemic hypoxia on cardiac metabolism of pyruvate using hyperpolarized 13C MRS, with differences observed following 30 minutes and 1 week of hypoxia. This demonstrates the potential of in vivo hyperpolarized 13C MRS data for assessing the cardiometabolic effects of hypoxia in disease. [ABSTRACT FROM AUTHOR]

Published

2019