ORCID Profile
0000-0002-8443-9365
Current Organisations
The University of Auckland
,
University of Auckland Auckland Bioengineering Institute
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Publisher: American Physiological Society
Date: 15-05-2015
DOI: 10.1152/AJPHEART.00002.2015
Abstract: An understanding of the role of autophagic processes in the management of cardiac metabolic stress responses is advancing rapidly and progressing beyond a conceptualization of the autophagosome as a simple cell recycling depot. The importance of autophagy dysregulation in diabetic cardiomyopathy and in ischemic heart disease - both conditions comprising the majority of cardiac disease burden - has now become apparent. New findings have revealed that specific autophagic processes may operate in the cardiomyocyte, specialized for selective recognition and management of mitochondria and glycogen particles in addition to protein macromolecular structures. Thus mitophagy, glycophagy, and macroautophagy regulatory pathways have become the focus of intensive experimental effort, and delineating the signaling pathways involved in these processes offers potential for targeted therapeutic intervention. Chronically elevated macroautophagic activity in the diabetic myocardium is generally observed in association with structural and functional cardiomyopathy yet there are also numerous reports of detrimental effect of autophagy suppression in diabetes. Autophagy induction has been identified as a key component of protective mechanisms that can be recruited to support the ischemic heart, but in this setting benefit may be mitigated by adverse downstream autophagic consequences. Recent report of glycophagy upregulation in diabetic cardiomyopathy opens up a novel area of investigation. Similarly, a role for glycogen management in ischemia protection through glycophagy initiation is an exciting prospect under investigation.
Publisher: Elsevier BV
Date: 03-2013
DOI: 10.1016/J.LFS.2012.03.042
Abstract: Existence of a diabetic cardiopathology, independent of vascular abnormalities, has been well reported. Diffuse interstitial fibrosis throughout the diabetic myocardium (even in the absence of an acute coronary event) suggests widespread cardiomyocyte attrition and cytokine activity. In addition to apoptotic and necrotic events, there is now good evidence that significant cardiomyocyte loss in the diabetic heart is driven by a different, non-apoptotic type of programmed cell death: autophagy. Although considered to be beneficial and pro-survival as a short term strategy to deal with acute stress, when chronically elevated or constitutive, excess autophagic activity has potential to be lethal. The insulin resistant myocardium exhibits various pro-autophagic characteristics: suppression of the PI3K(I)-Akt signaling pathway, oxidative stress and metabolic dysregulation, rendering the diabetic heart vulnerable to autophagic demise. There is compelling new evidence that in the diabetic myocardium cardiomyocyte attrition can be linked to autophagic upregulation.
Publisher: American Physiological Society
Date: 03-2009
DOI: 10.1152/AJPREGU.90919.2008
Abstract: The identification of genetic factors influencing cardiac growth independently of increased load is crucial to an understanding of the molecular and cellular basis of pathological cardiac hypertrophy. The central aim of this investigation was to determine how pathological hypertrophy in the adult can be linked with disturbances in cardiomyocyte growth and viability in early neonatal development. The hypertrophic heart rat (HHR) model is derived from the spontaneously hypertensive rat and exhibits marked cardiac hypertrophy, in the absence of a pressure load at maturity. Hearts were harvested from male HHR, and control strain normal heart rats (NHR), at different stages of postnatal development [neonatal (P2), 4 wk, 6 wk, 8 wk, 12 wk, 20 wk]. Isolated neonatal cardiomyocytes were prepared to evaluate cell size, number, and binucleation. At postnatal day 2, HHR hearts were considerably smaller than control NHR (4.3 ± 0.2 vs. 5.0 ± 0.1 mg/g, P 0.05). Cardiac growth restriction in the neonatal HHR was associated with reduced myocyte size (length and width) and an increased proportion of binucleated cardiomyocytes. Furthermore, the number of cardiomyocytes isolated from HHR neonatal hearts was significantly less (∼29%) than NHR. We also observe that growth stress in the neonate is associated with accentuated PI3K and suppressed MAPK activation, although these signaling pathways are normalized in the adult heart exhibiting established hypertrophy. Thus, using the HHR model, we identified novel molecular and cellular mechanisms involving premature exit from the cell cycle, reduced cardiomyocyte endowment, and dysregulated trophic signaling during early development, which are implicated in the etiology of heritable cardiac hypertrophy in the adult.
Publisher: American Physiological Society
Date: 15-09-2013
DOI: 10.1152/AJPHEART.00141.2013
Abstract: More than three decades ago, the Framingham study revealed that cardiovascular risk is elevated for all diabetics and that this jeopardy is substantially accentuated for women in particular. Numerous studies have subsequently documented worsened cardiac outcomes for women. Given that estrogen and insulin exert major regulatory effects through common intracellular signaling pathways prominent in maintenance of cardiomyocyte function, a sex-hormone:diabetic-disease interaction is plausible. Underlying aspects of female cardiovascular pathophysiology that exaggerate cardiovascular diabetic risk may be identified, including increased vulnerability to coronary microvascular disease, age-dependent impairment of insulin-sensitivity, and differential susceptibility to hyperglycemia. Since Framingham, considerable progress has been made in the development of experimental models of diabetic disease states, including a ersity of genetic rodent models. Ample evidence indicates that animal models of both type 1 and 2 diabetes variably recapitulate aspects of diabetic cardiomyopathy including diastolic and systolic dysfunction, and cardiac structural pathology including fibrosis, loss of compliance, and in some instances ventricular hypertrophy. Perplexingly, little of this work has explored the relevance and mechanisms of sexual dimorphism in diabetic cardiomyopathy. Only a small number of experimental studies have addressed this question, yet the prospects for gaining important mechanistic insights from further experimental enquiry are considerable. The case for experimental interrogation of sex differences, and of sex steroid influences in the aetiology of diabetic cardiomyopathy, is particularly compelling—providing incentive for future investigation with ultimate therapeutic potential.
Publisher: Public Library of Science (PLoS)
Date: 29-09-2011
Publisher: Elsevier BV
Date: 05-2015
DOI: 10.1016/J.LFS.2014.03.020
Abstract: Diabetes elicits cardiac metabolic stress involving impaired glucose uptake and metabolic substrate shifts. Diabetic cardiac pathology is well documented in human patients and experimental animal models to be characterized by diastolic dysfunction, but the underlying mechanisms are not well understood. Signaling disturbances involved in cardiac insulin resistance are linked to glucose handling abnormalities. Both reversible (e.g. O-GlcNAc) and irreversible (e.g. AGEs) glucose-modifications of cardiomyocyte extracellular and intracellular proteins are implicated in structural and functional alterations underlying pathology in the diabetic heart. This review highlights some aspects of the epigenetic roles played by glucose (and related hexose sugars) in mediating diabetic cardiac pathology with specific consideration for the mechanisms impinging on post-translational modifications which have key signaling and mechanical impacts.
Publisher: Springer Science and Business Media LLC
Date: 25-02-2014
Publisher: Elsevier BV
Date: 07-2010
DOI: 10.1016/J.NUT.2009.08.017
Abstract: Dietary fructose intake has increased considerably in recent decades and this has been paralleled by an increase in the incidence of insulin resistance, especially in children and adolescents. The impact of a high-fructose diet on the myocardium is not fully understood. The aims of this study were to characterize the murine metabolic and cardiac phenotypes associated with a high-fructose diet and to determine whether this diet imparts differential effects with age. Juvenile (4 wk) and adult (14 wk) C57Bl/6 mice were fed a 60% fructose diet or isoenergetic control (starch) diet for 6 wk. At completion of the dietary intervention (at ages 10 and 20 wk), fructose-fed mice were normotensive hyperinsulinemia and cardiac hypertrophy were not evident. Interestingly, fructose-fed mice exhibited lower blood glucose levels (10 wk: 4.81+/-0.28 versus 5.42+/-0.31 mmol/L 20 wk: 4.88+/-0.30 versus 5.96+/-0.42 mmol/L, P<0.05) compared with controls. Nicotinamide adenosine dinucleotide phosphate-driven myocardial superoxide production was significantly increased in fructose-fed mice at both ages (by approximately 29% of control at 10 wk of age and 16% at 20 wk, P<0.01). No increase in aortic superoxide production was observed. Fructose feeding did not alter gene expression of the antioxidant thioredoxin-2, suggesting an imbalance between myocardial reactive oxygen species generation and antioxidant induction. These findings indicate that increased myocardial superoxide production may represent an early and primary cardiac pathologic response to the metabolic challenge of excess dietary fructose in juveniles and adults that can be detected in the absence of cardiac hypertrophy and hypertension.
Publisher: Springer Science and Business Media LLC
Date: 05-02-2018
DOI: 10.1038/S41598-018-20703-8
Abstract: Diabetic cardiomyopathy is a distinct pathology characterized by early emergence of diastolic dysfunction. Increased cardiovascular risk associated with diabetes is more marked for women, but an understanding of the role of diastolic dysfunction in female susceptibility to diabetic cardiomyopathy is lacking. To investigate the sex-specific relationship between systemic diabetic status and in vivo occurrence of diastolic dysfunction, diabetes was induced in male and female mice by streptozotocin (5x daily i.p. 55 mg/kg). Echocardiography was performed at 7 weeks post-diabetes induction, cardiac collagen content assessed by picrosirius red staining, and gene expression measured using qPCR. The extent of diabetes-associated hyperglycemia was more marked in males than females (males: 25.8 ± 1.2 vs 9.1 ± 0.4 mM females: 13.5 ± 1.5 vs 8.4 ± 0.4 mM, p 0.05) yet in vivo diastolic dysfunction was evident in female (E/E′ 54% increase, p 0.05) but not male diabetic mice. Cardiac structural abnormalities (left ventricular wall thinning, collagen deposition) were similar in male and female diabetic mice. Female-specific gene expression changes in glucose metabolic and autophagy-related genes were evident. This study demonstrates that STZ-induced diabetic female mice exhibit a heightened susceptibility to diastolic dysfunction, despite exhibiting a lower extent of hyperglycemia than male mice. These findings highlight the importance of early echocardiographic screening of asymptomatic prediabetic at-risk patients.
Publisher: Elsevier BV
Date: 07-2022
Publisher: Springer Science and Business Media LLC
Date: 08-02-2021
DOI: 10.1038/S41387-021-00150-7
Abstract: Diabetes is associated with cardiac metabolic disturbances and increased heart failure risk. Plasma fructose levels are elevated in diabetic patients. A direct role for fructose involvement in diabetic heart pathology has not been investigated. The goals of this study were to clinically evaluate links between myocardial fructose and sorbitol (a polyol pathway fructose precursor) levels with evidence of cardiac dysfunction, and to experimentally assess the cardiomyocyte mechanisms involved in mediating the metabolic effects of elevated fructose. Fructose and sorbitol levels were increased in right atrial appendage tissues of type 2 diabetic patients (2.8- and 1.5-fold increase respectively). Elevated cardiac fructose levels were confirmed in type 2 diabetic rats. Diastolic dysfunction (increased E/e’, echocardiography) was significantly correlated with cardiac sorbitol levels. Elevated myocardial mRNA expression of the fructose-specific transporter, Glut5 (43% increase), and the key fructose-metabolizing enzyme, Fructokinase-A (50% increase) was observed in type 2 diabetic rats (Zucker diabetic fatty rat). In neonatal rat ventricular myocytes, fructose increased glycolytic capacity and cytosolic lipid inclusions (28% increase in lipid droplets/cell). This study provides the first evidence that elevated myocardial fructose and sorbitol are associated with diastolic dysfunction in diabetic patients. Experimental evidence suggests that fructose promotes the formation of cardiomyocyte cytosolic lipid inclusions, and may contribute to lipotoxicity in the diabetic heart.
Publisher: Elsevier BV
Date: 12-2016
Publisher: American Physiological Society
Date: 15-02-2012
DOI: 10.1152/AJPHEART.00797.2011
Abstract: High fructose intake has been linked to insulin resistance and cardiac pathology. Dietary fructose-induced myocardial signaling and morphological alterations have been described, but whether cardiomyocyte function is influenced by chronic high fructose intake is yet to be elucidated. The goal of this study was to evaluate the cardiomyocyte excitation-contraction coupling effects of high dietary fructose and determine the capacity for murine cardiomyocyte fructose transport. Male C57Bl/6J mice were fed a high fructose diet for 12 wk. Fructose- and control-fed mouse cardiomyocytes were isolated and loaded with the fura 2 Ca 2+ fluorescent dye for analysis of twitch and Ca 2+ transient characteristics (4 Hz stimulation, 37°C, 2 mM Ca 2+ ). Myocardial Ca 2+ -handling protein expression was determined by Western blot. Gene expression of the fructose-specific transporter, GLUT5, in adult mouse cardiomyocytes was detected by real-time and conventional RT-PCR techniques. Diastolic Ca 2+ and Ca 2+ transient litude were decreased in isolated cardiomyocytes from fructose-fed mice relative to control (16 and 42%, respectively), coincident with an increase in the time constant of Ca 2+ transient decay (24%). Dietary fructose increased the myofilament response to Ca 2+ (as evidenced by a left shift in the shortening-Ca 2+ phase loop). Protein expression of sarcoplasmic reticulum Ca 2+ -ATPase (SERCA2a), phosphorylated (P) phospholamban (Ser 16 ), and P-phospholamban (Thr 17 ) was reduced, and protein phosphatase 2A expression increased, in fructose-fed mouse hearts. Hypertension and cardiac hypertrophy were not evident. These findings demonstrate that fructose diet-associated myocardial insulin resistance induces profound disturbance of cardiomyocyte Ca 2+ handling and responsiveness in the absence of altered systemic loading conditions.
Publisher: The Endocrine Society
Date: 04-2015
DOI: 10.1210/EN.2014-1700
Abstract: The role of sex steroids in cardioprotection is contentious, with large clinical trials investigating hormone supplementation failing to deliver outcomes expected from observational studies. Mechanistic understanding of androgen/estrogen myocardial actions is lacking. Using a genetic model of aromatase tissue deficiency (ArKO) in female mice, the goal of this investigation was to evaluate the capacity of a shift in cardiac endogenous steroid conversion to influence ischemia-reperfusion resilience by optimizing cardiomyocyte Ca2+ handling responses. In isolated normoxic cardiomyocytes, basal Ca2+ transient litude and extent of shortening were greater in ArKO myocytes, with preservation of diastolic Ca2+ levels. Isolated ArKO cardiomyocytes exposed to a high Ca2+ load exhibited greater Ca2+ transient and contractile litudes, associated with a greater postrest spontaneous sarcoplasmic reticulum Ca2+ load-release. Microarray differential gene expression analysis of normoxic ventricular tissues from ArKO vs wild-type identified a significant influence of aromatase on genes involved in cardiac Ca2+ handling and signaling [including calmodulin dependent kinase II (CaMKII)-δ], myofilament structure and function, glucose uptake and signaling, and enzymes controlling phosphorylation-specific posttranslational modification status. CaMKII expression was not changed in ventricular tissues, although CaMKIIδ activation and phosphorylation of downstream targets was enhanced in ArKO hearts subjected to ischemia-reperfusion. Overall, this investigation shows that relative withdrawal of estrogen in favor of testosterone through genetically induced tissue aromatase deficiency in females modifies the gene expression profile to effect inotropic support via optimized Ca2+ handling in response to stress, with a modest impact on basal function. Consideration of aromatase inhibition, acutely or chronically, may have a role in cardioprotection, of particular relevance to women.
Publisher: Elsevier BV
Date: 05-2017
DOI: 10.1016/J.BBADIS.2017.10.035
Abstract: Diabetic cardiomyopathy is a distinct pathology independent of co-morbidities such as coronary artery disease and hypertension. Diminished glucose uptake due to impaired insulin signaling and decreased expression of glucose transporters is associated with a shift towards increased reliance on fatty acid oxidation and reduced cardiac efficiency in diabetic hearts. The cardiac metabolic profile in diabetes is influenced by disturbances in circulating glucose, insulin and fatty acids, and alterations in cardiomyocyte signaling. In this review, we focus on recent preclinical advances in understanding the molecular mechanisms of diabetic cardiomyopathy. Genetic manipulation of cardiomyocyte insulin signaling intermediates has demonstrated that partial cardiac functional rescue can be achieved by upregulation of the insulin signaling pathway in diabetic hearts. Inconsistent findings have been reported relating to the role of cardiac AMPK and β-adrenergic signaling in diabetes, and systemic administration of agents targeting these pathways appear to elicit some cardiac benefit, but whether these effects are related to direct cardiac actions is uncertain. Overload of cardiomyocyte fuel storage is evident in the diabetic heart, with accumulation of glycogen and lipid droplets. Cardiac metabolic dysregulation in diabetes has been linked with oxidative stress and autophagy disturbance, which may lead to cell death induction, fibrotic 'backfill' and cardiac dysfunction. This review examines the weight of evidence relating to the molecular mechanisms of diabetic cardiomyopathy, with a particular focus on metabolic and signaling pathways. Areas of uncertainty in the field are highlighted and important knowledge gaps for further investigation are identified. This article is part of a Special issue entitled Cardiac adaptations to obesity, diabetes and insulin resistance, edited by Professors Jan F.C. Glatz, Jason R.B. Dyck and Christine Des Rosiers.
Publisher: American Diabetes Association
Date: 12-11-2016
DOI: 10.2337/DB16-0682
Abstract: A link between excess dietary sugar and cardiac disease is clearly evident and has been largely attributed to systemic metabolic dysregulation. Now a new paradigm is emerging, and a compelling case can be made that fructose-associated heart injury may be attributed to the direct actions of fructose on cardiomyocytes. Plasma and cardiac fructose levels are elevated in patients with diabetes, and evidence suggests that some unique properties of fructose (vs. glucose) have specific cardiomyocyte consequences. Investigations to date have demonstrated that cardiomyocytes have the capacity to transport and utilize fructose and express all of the necessary proteins for fructose metabolism. When dietary fructose intake is elevated and myocardial glucose uptake compromised by insulin resistance, increased cardiomyocyte fructose flux represents a hazard involving unregulated glycolysis and oxidative stress. The high reactivity of fructose supports the contention that fructose accelerates subcellular hexose sugar-related protein modifications, such as O-GlcNAcylation and advanced glycation end product formation. Exciting recent discoveries link heart failure to induction of the specific high-affinity fructose-metabolizing enzyme, fructokinase, in an experimental setting. In this Perspective, we review key recent findings to synthesize a novel view of fructose as a cardiopathogenic agent in diabetes and to identify important knowledge gaps for urgent research focus.
Publisher: Wiley
Date: 09-06-2017
DOI: 10.1113/EP086293
Publisher: Wiley
Date: 21-09-2011
DOI: 10.1111/J.1440-1681.2011.05567.X
Abstract: 1. Important sex differences exist in ischaemic heart disease. Oestrogen has been conventionally regarded as providing a cardioprotective benefit and testosterone frequently perceived to exert a deleterious effect. However, there is accumulating evidence that argues against this simple dichotomy, suggesting that the influence of oestrogen and testosterone conferring benefit or detriment may be context specific. 2. Cardiomyocyte calcium (Ca(2+)) loading is recognized to be a major factor in acute ischaemia-reperfusion pathology, promoting cell death, contractile dysfunction and arrhythmogenic activity. Ca(2+)/calmodulin-dependent kinase II (CaMKII) is a mediator of many of the cardiomyocyte Ca(2+)-related pathologies in ischaemia-reperfusion. Cardiomyocyte Ca(2+)-handling processes have been shown to be modulated by the actions of oestrogen and testosterone. A role for these sex steroids in influencing CaMKII activation is argued. 3. Although many experimental studies of oestrogen manipulation can identify a cardioprotective role for this sex steroid, there are also numerous reports that fail to demonstrate sex differences in postischaemic recovery. Experimental studies report that testosterone can be protective in ischaemia-reperfusion in males and females in some settings. 4. Further studies of sex steroid influence in the ischaemic heart will allow the development of therapeutic interventions that are specifically targeted for male and female hearts.
Publisher: Elsevier BV
Date: 05-2015
Publisher: Springer Science and Business Media LLC
Date: 31-10-2018
DOI: 10.1038/S41598-018-33886-X
Abstract: Dynamic movements of the cardiac troponin complex are an important component of the cardiac cycle. Whether cardiac troponins are subjected to irreversible advanced glycation end-product (AGE) modification is unknown. This study interrogated human and rat cardiac troponin-C, troponin-I and troponin-T to identify endogenous AGE modifications using mass spectrometry (LC-MS/MS). AGE modifications were detected on two amino acid residues of human troponin-C (Lys 6 , Lys 39 ), thirteen troponin-I residues (Lys 36 , Lys 50 , Lys 58 , Arg 79 , Lys 117 , Lys 120 , Lys 131 , Arg 148 , Arg 162 , Lys 164 , Lys 183 , Lys 193 , Arg 204 ), and three troponin-T residues (Lys 107 , Lys 125 , Lys 227 ). AGE modifications of three corresponding troponin-I residues (Lys 58 , Lys 120 , Lys 194 ) and two corresponding troponin-T residues (Lys 107 , Lys 227 ) were confirmed in cardiac tissue extracts from an experimental rodent diabetic model. Additionally, novel human troponin-I phosphorylation sites were detected (Thr 119 , Thr 123 ). Accelerated AGE modification of troponin-C was evident in vitro with hexose sugar exposure. This study provides the first demonstration of the occurrence of cardiac troponin complex AGE-modifications. These irreversible AGE modifications are situated in regions of the troponin complex known to be important in myofilament relaxation, and may be of particular pathological importance in the pro-glycation environment of diabetic cardiomyopathy.
Publisher: American Physiological Society
Date: 15-04-2014
DOI: 10.1152/AJPHEART.00059.2014
Abstract: Disturbed systemic glycemic and insulinemic status elicits cardiomyocyte metabolic stress and altered glucose handling. In diabetes, pathological myocardial glycogen accumulation occurs. Recently, evidence of a specific myocardial autophagic degradation pathway for glycogen (“glycophagy”) has been reported, differentiated from the more well-characterized protein “macrophagy” pathway. The goal of this study was to identify potential mechanisms involved in cardiac glycogen accumulation, glycophagy, and macrophagy regulation using cultured neonatal rat ventricular myocytes (NRVMs). In NRVMs, insulin-induced Akt phosphorylation was evident with 5 mM-glucose conditions (∼2.3-fold increased). Under high-glucose (30 mM) conditions, insulin-augmented phosphorylation was not observed. Accumulation of glycogen was observed in response to insulin only in high-glucose conditions (∼2-fold increase). Increased expression of the glycophagy marker starch-binding domain-containing protein-1 (STBD1, 25% increase) was observed under high-glucose and insulin conditions. Expression levels of the macrophagy markers p62 and light chain protein 3BII:I were not increased by insulin at either glucose level. Preliminary results from hearts of streptozotocin-treated diabetic rats are supportive of the findings obtained in NRVMs, suggesting diabetes induced elevated expression of STBD1 and of an additional glycophagy marker GABA(A) receptor-associated protein-like 1. Confocal microscopy demonstrated that light chain protein 3B and STBD1 immunomarkers were not colocalized in NRVMs. These findings provide the first evidence that cardiomyocyte glycophagy induction occurs under the influence of insulin and is responsive to extracellular high glucose. This study suggests that the regulation of glycogen content and glycophagy induction in the cardiomyocyte may be linked, and it is speculated that glycogen pathology in diabetic cardiomyopathy has glycophagic involvement.
Publisher: Wiley
Date: 23-12-2013
DOI: 10.1111/J.1440-1681.2012.05738.X
Abstract: Clinical studies in humans strongly support a link between insulin resistance and non-ischaemic heart failure. The occurrence of a specific insulin-resistant cardiomyopathy, independent of vascular abnormalities, is now recognized. The progression of cardiac pathology linked with insulin resistance is poorly understood. Cardiac insulin resistance is characterized by reduced availability of sarcolemmal Glut-4 transporters and consequent lower glucose uptake. A shift away from glycolysis towards fatty acid oxidation for ATP supply is apparent and is associated with myocardial oxidative stress. Reliance of cardiomyocyte excitation-contraction coupling on glycolytically derived ATP supply potentially renders cardiac function vulnerable to the metabolic remodelling adaptations observed in diabetes development. Findings from Glut-4-knockout mice demonstrate that cardiomyocytes with extreme glucose uptake deficiency exhibit cardiac hypertrophy and marked excitation-contraction coupling abnormalities characterized by reduced sarcolemmal Ca(2+) influx and sarcoplasmic reticulum Ca(2+) uptake. The 'milder' phenotype fructose-fed mouse model of type 2 diabetes does not show evidence of cardiac hypertrophy, but cardiomyocyte loss linked with autophagic activation is evident. Fructose feeding induces a marked reduction in intracellular Ca(2+) availability with myofilament adaptation to preserve contractile function in this setting. The cardiac metabolic adaptations of two load-independent models of diabetes, namely the Glut-4-deficient mouse and the fructose-fed mouse are contrasted. The role of autophagy in diabetic cardiopathology is evaluated and anomalies of type 1 versus type 2 diabetic autophagic responses are highlighted.
Publisher: Springer Science and Business Media LLC
Date: 2014
Publisher: American Physiological Society
Date: 07-2022
DOI: 10.1152/AJPHEART.00058.2022
Abstract: Diabetes is a major risk factor for cardiovascular diseases, including diabetic cardiomyopathy, atherosclerosis, myocardial infarction, and heart failure. As cardiovascular disease represents the number one cause of death in people with diabetes, there has been a major emphasis on understanding the mechanisms by which diabetes promotes cardiovascular disease, and how antidiabetic therapies impact diabetic heart disease. With a wide array of models to study diabetes (both type 1 and type 2), the field has made major progress in answering these questions. However, each model has its own inherent limitations. Therefore, the purpose of this guidelines document is to provide the field with information on which aspects of cardiovascular disease in the human diabetic population are most accurately reproduced by the available models. This review aims to emphasize the advantages and disadvantages of each model, and to highlight the practical challenges and technical considerations involved. We will review the preclinical animal models of diabetes (based on their method of induction), appraise models of diabetes-related atherosclerosis and heart failure, and discuss in vitro models of diabetic heart disease. These guidelines will allow researchers to select the appropriate model of diabetic heart disease, depending on the specific research question being addressed.
Publisher: Wiley
Date: 19-01-2010
DOI: 10.1111/J.1440-1681.2009.05274.X
Abstract: 1. The prevalence of insulin resistance has increased markedly in the past decade and is known to be associated with cardiovascular risk. Evidence of an insulin-resistant cardiomyopathy, independent of pressure or volume loading influences, is now emerging. 2. Cardiac oxidative stress is often observed coincident with insulin resistance and there is accumulating evidence that reactive oxygen species (ROS) mediate deleterious effects in the insulin-resistant heart. It is established that ROS modification of signalling proteins can adversely modulate cellular processes, leading to cardiac growth remodelling and dysfunction. The mechanisms of ROS-induced damage in insulin-resistant cardiomyopathy are yet to be fully elucidated. 3. A number of different animal models have been used to study cardiac insulin resistance, including high-sugar dietary interventions, genetically modified diabetic mice and streptozotocin-induced diabetes. Mechanistic studies manipulating cardiac anti-oxidant levels, either endogenously or exogenously, in these models have demonstrated a role for ROS in the cardiac manifestations associated with insulin resistance. 4. The present review summarizes the cardiac-specific characteristics of insulin resistance, the features of cardiac metabolism relevant to ROS generation and ROS-mediated cardiomyocyte damage pathways. In vivo studies in which a combination of genetic and environmental variables have been manipulated are considered. These studies provide particular insights into the induction and suppression of insulin-resistant cardiomyopathy.
Publisher: Ovid Technologies (Wolters Kluwer Health)
Date: 05-06-2018
Abstract: Among the growing numbers of patients with heart failure, up to one half have heart failure with preserved ejection fraction ( HF p EF ). The lack of effective treatments for HF p EF is a substantial and escalating unmet clinical need—and the lack of HF p EF ‐specific animal models represents a major preclinical barrier in advancing understanding of HF p EF . As established treatments for heart failure with reduced ejection fraction ( HF r EF ) have proven ineffective for HF p EF , the contention that the intrinsic cardiomyocyte phenotype is distinct in these 2 conditions requires consideration. Our goal was to validate and characterize a new rodent model of HF p EF , undertaking longitudinal investigations to delineate the associated cardiac and cardiomyocyte pathophysiology. The selectively inbred Hypertrophic Heart Rat (HHR) strain exhibits adult cardiac enlargement (without hypertension) and premature death (40% mortality at 50 weeks) compared to its control strain, the normal heart rat. Hypertrophy was characterized in vivo by maintained systolic parameters (ejection fraction at 85%–90% control) with marked diastolic dysfunction (increased E/E′). Surprisingly, HHR cardiomyocytes were hypercontractile, exhibiting high Ca 2+ operational levels and markedly increased L‐type Ca 2+ channel current. In HHR , prominent regions of reparative fibrosis in the left ventricle free wall adjacent to the interventricular septum were observed. Thus, the cardiomyocyte remodeling process in the etiology of this HF p EF model contrasts dramatically with the suppressed Ca 2+ cycling state that typifies heart failure with reduced ejection fraction. These findings may explain clinical observations, that treatments considered appropriate for heart failure with reduced ejection fraction are of little benefit for HF p EF —and suggest a basis for new therapeutic strategies.
Publisher: Rockefeller University Press
Date: 28-06-2021
Abstract: Increased heart size is a major risk factor for heart failure and premature mortality. Although abnormal heart growth subsequent to hypertension often accompanies disturbances in mechano-energetics and cardiac efficiency, it remains uncertain whether hypertrophy is their primary driver. In this study, we aimed to investigate the direct association between cardiac hypertrophy and cardiac mechano-energetics using isolated left-ventricular trabeculae from a rat model of primary cardiac hypertrophy and its control. We evaluated energy expenditure (heat output) and mechanical performance (force length work production) simultaneously at a range of preloads and afterloads in a microcalorimeter, we determined energy expenditure related to cross-bridge cycling and Ca2+ cycling (activation heat), and we quantified energy efficiency. Rats with cardiac hypertrophy exhibited increased cardiomyocyte length and width. Their trabeculae showed mechanical impairment, evidenced by lower force production, extent and kinetics of shortening, and work output. Lower force was associated with lower energy expenditure related to Ca2+ cycling and to cross-bridge cycling. However, despite these changes, both mechanical and cross-bridge energy efficiency were unchanged. Our results show that cardiac hypertrophy is associated with impaired contractile performance and with preservation of energy efficiency. These findings provide direction for future investigations targeting metabolic and Ca2+ disturbances underlying cardiac mechanical and energetic impairment in primary cardiac hypertrophy.
Publisher: Wiley
Date: 27-03-2015
Abstract: Cardiac glycogen regulation involves a complex interplay between multiple signalling pathways, allosteric activation of enzymes, and sequestration for autophagic degradation. Signalling pathways appear to converge on glycogen regulatory enzymes via insulin (glycogen synthase kinase 3β, protein phosphatase 1, allosteric action of glucose-6-phosphate), β-adrenergic (phosphorylase kinase protein phosphatase 1 inhibitor), and 5' adenosine monophosphate-activated protein kinase (allosteric action of glucose-6-phosphate, direct glycogen binding, insulin receptor). While cytosolic glycogen synthesis and breakdown are relatively well understood, recent findings relating to phagic glycogen degradation highlight a new area of investigation in the heart. It has been recently demonstrated that a specific glycophagy pathway is operational in the myocardium. Proteins involved in recruiting glycogen to the forming phagosome have been identified. Starch-binding domain-containing protein 1 is involved in binding glycogen and mediating membrane anchorage via interaction with a homologue of the phagosomal protein light-chain 3. Specifically, it has been shown that starch-binding domain-containing protein 1 and light-chain 3 have discrete phagosomal immunolocalization patterns in cardiomyocytes, indicating that autophagic trafficking of glycogen and protein cargo in cardiomyocytes can occur via distinct pathways. There is strong evidence from glycogen storage diseases that phagic/lysosomal glycogen breakdown is important for maintaining normal cardiac glycogen levels and does not simply constitute a redundant 'alternative' breakdown route for glycogen. Advancing understanding of glycogen handling in the heart is an important priority with relevance not only to genetic glycogen storage diseases but also to cardiac metabolic stress disorders such as diabetes and ischaemia.
Publisher: Mary Ann Liebert Inc
Date: 20-08-2019
Publisher: American Physiological Society
Date: 10-2022
Publisher: American Physiological Society
Date: 09-2016
DOI: 10.1152/AJPHEART.00690.2015
Abstract: A definitive understanding of the role of dietary lipids in determining cardioprotection (or cardiodetriment) has been elusive. Randomized trial findings have been variable and sex specificity of dietary interventions has not been determined. In this investigation the sex-selective cardiac functional effects of three diets enriched by omega-3 or omega-6 polyunsaturated fatty acids (PUFA) or enriched to an equivalent extent in saturated fatty acid components were examined in rats after an 8-wk treatment period. In females the myocardial membrane omega-6:omega-3 PUFA ratio was twofold higher than males in the omega-6 diet replacement group. In diets specified to be high in omega-3 PUFA or in saturated fat, this sex difference was not apparent. Isolated cardiomyocyte and heart Langendorff perfusion experiments were performed, and molecular measures of cell viability were assessed. Under basal conditions the contractile performance of omega-6 fed female cardiomyocytes and hearts was reduced compared with males. Omega-6 fed females exhibited impaired systolic resilience after ischemic insult. This response was associated with increased postischemia necrotic cell damage evaluated by coronary lactate dehydrogenase during reperfusion in omega-6 fed females. Cardiac and myocyte functional parameters were not different between omega-3 and saturated fat dietary groups and within these groups there were no discernible sex differences. Our data provide evidence at both the cardiac and cardiomyocyte levels that dietary saturated fatty acid intake replacement with an omega-6 (but not omega-3) enriched diet has selective adverse cardiac effect in females. This finding has potential relevance in relation to women, cardiac risk, and dietary management.
Publisher: Informa UK Limited
Date: 10-2011
Abstract: The prominent occurrence of autophagy in fetal/neonatal myocardial tissue has been recognized for more than three decades as a key process in managing the period of perinatal nutrient deprivation. Fasting-induced autophagy has similarly been characterized as an expedient short-term cardiomyocyte response to nutrient restriction. Discerning how autophagy operates in the heart in disease contexts of substrate dysregulation is proving to be a much more complex challenge. Recent studies relating to insulin signaling and cardiac autophagy activation have provided new insights-and generated new contradictions. We highlight several anomalies and pose a number of questions, which emerge from these studies. How can myocardial autophagy induction be associated with both PtdIns3K-Akt activation (in ischemia) and suppression (in insulin resistance)? What is the explanation for the contrasting findings that myocardial autophagy is elevated in a murine model of type 2 diabetes, yet suppressed in the type 1 diabetic state? And finally, in the type 1 diabetic setting, what could be the basis for downregulated cardiac AMP-activated protein kinase (AMPK)-driven autophagic activity, when activation of this 'energy stress' kinase is usually integral to the cellular response to glucose deficit? We summarize and discuss these interesting ambiguities of myocardial autophagy regulation.
Publisher: Wiley
Date: 06-2017
DOI: 10.1113/JP274174
Publisher: The Endocrine Society
Date: 25-10-2011
DOI: 10.1210/EN.2011-1212
Abstract: The conventional view is that estrogen confers female cardioprotection. Estrogen synthesis depends on androgen availability, with aromatase regulating conversion of testosterone to estradiol. Extragonadal aromatase expression mediates estrogen production in some tissues, but a role for local steroid conversion has not yet been demonstrated in the heart. This study's goal was to investigate how aromatase deficiency influences myocardial function and ischemic resilience. RT-PCR analysis of C57Bl/6 mouse hearts confirmed cardiac-specific aromatase expression in adult females. Functional performance of isolated hearts from female aromatase knockout (ArKO) and aromatase wild-type mice were compared. Left ventricular developed pressures were similar in aerobic perfusion, but the maximal rate of rise of ventricular pressure was modestly reduced in ArKO hearts (3725 ± 144 vs. 4272 ± 154 mm Hg/sec, P & 0.05). After 25 min of ischemia, the recovery of left ventricular developed pressure was substantially improved in ArKO (percentage of basal at 60 min of reperfusion, 62 ± 8 vs. 30 ± 6% P & 0.05). Hypercontracture was attenuated (end diastolic pressure, 25 ± 5 vs. 51 ± 1 mm Hg P & 0.05), and lactate dehydrogenase content of coronary effluent was reduced throughout reperfusion in ArKO hearts. This was associated with a hyperphosphorylation of phospholamban and a reduction in phosphorylated Akt. Immediately after reperfusion, ArKO hearts exhibited increased incidence of ventricular premature beats (194 ± 70 vs. 46 ± 6, P & 0.05). These observations indicate more robust functional recovery, reduced cellular injury, and modified cardiomyocyte Ca2+ handling in aromatase-deficient hearts. Our findings indicate that androgen-to-estrogen conversion may be of pathophysiologic importance to the heart and challenge the notion that estrogen deficiency is deleterious. These studies suggest the possibility that aromatase suppression may offer inotropic benefit in the acute ischemia/reperfusion setting with appropriate arrhythmia management.
Publisher: Springer Science and Business Media LLC
Date: 31-03-2017
Publisher: Canadian Science Publishing
Date: 05-2010
DOI: 10.1139/Y10-005
Abstract: A dramatic rise in the prevalence of insulin resistance has been paralleled by increasing dietary consumption of sugar. The use of added sweeteners containing fructose (sucrose and high-fructose corn syrup) has increased by 25% over the past 3 decades. High fructose intake has the potential to adversely influence systemic and cellular metabolism via insulin resistance and glycolytic dysregulation. As a tissue that is both insulin sensitive and glycolysis dependent, the heart may be especially vulnerable to fructose over-consumption. In this review, experimental studies of elevated dietary sugar intake are evaluated, including sucrose and fructose dietary manipulation models. The possible role of the GLUT5 transporter as a mediator of cardiomyocyte fructose uptake is considered. The impact of dietary sucrose and fructose on cardiac insulin-dependent signaling in the context of perturbed systemic metabolic response is detailed. Myocardial dysfunction, modified growth, and oxidative stress responses associated with high dietary sugar intake are discussed. Finally, the involvement of the renin–angiotensin system in mediating fructose cardiopathology is considered. This review highlights the importance of obtaining new mechanistic data that can contribute to a more developed understanding of how high sugar intake directly contributes to structural and functional cardiomyopathy.
Publisher: Elsevier BV
Date: 12-2013
DOI: 10.1016/J.YJMCC.2013.09.014
Abstract: Cardiac metabolic stress is a hallmark of many cardiac pathologies, including diabetes. Cardiac glycogen mis-handling is a frequent manifestation of various cardiopathologies. Diabetic females have a higher risk of heart disease than males, yet sex disparities in cardiac metabolic stress settings are not well understood. Oestrogen acts on key glycogen regulatory proteins. The goal of this study was to evaluate sex-specific metabolic stress-triggered cardiac glycogen handling responses. Male and female adult C57Bl/6J mice were fasted for 48h. Cardiac glycogen content, particle size, regulatory enzymes, signalling intermediates and autophagic processes were evaluated. Female hearts exhibited 51% lower basal glycogen content than males associated with lower AMP-activated-kinase (AMPK) activity (35% decrease in pAMPK:AMPK). With fasting, glycogen accumulated in female hearts linked with decreased particle size and upregulation of Akt and AMPK signalling, activation of glycogen synthase and inactivation of glycogen phosphorylase. Fasting did not alter glycogen content or regulatory proteins in male hearts. Expression of glycogen autophagy marker, starch-binding-protein-domain-1 (STBD1), was 63% lower in female hearts than males and increased by 69% with fasting in females only. Macro-autophagy markers, p62 and LC3BII:I ratio, increased with fasting in male and female hearts. This study identifies glycogen autophagy ('glycophagy') as a potentially important component of the response to cardiac metabolic stress. Glycogen autophagy occurs in association with a marked and selective accumulation of glycogen in the female myocardium. Our findings suggest that sex-specific differences in glycogen handling may have cardiopathologic consequences in various settings, including diabetic cardiomyopathy.
Publisher: Elsevier BV
Date: 06-2011
DOI: 10.1016/J.YJMCC.2011.03.002
Abstract: Fructose intake is linked with the increasing prevalence of insulin resistance and there is now evidence for a specific insulin-resistant cardiomyopathy. The aim of this study was to determine the cardiac-specific myocardial remodeling effects of high fructose dietary intake. Given the links between insulin signaling, reactive oxygen species generation and autophagy induction, we hypothesized that autophagy contributes to pathologic remodeling in the insulin-resistant heart, and in particular may be a feature of high fructose diet-induced cardiac phenotype. Male C57Bl/6 mice were fed a high fructose (60%) diet or nutrient-matched control diet for 12 weeks. Systemic and myocardial insulin-resistant status was characterized. Superoxide production (lucigenin) and cellular growth and death signaling pathways were examined in myocardial tissue. Myocardial structural remodeling was evaluated by measurement of heart weight indices and histological analysis of collagen deposition (picrosirius red). Fructose-fed mice exhibited hyperglycemia and glucose intolerance, but plasma insulin and blood pressure were unchanged. High fructose intake suppressed the myocardial Akt cell survival signaling coincident with increased cardiac superoxide generation (21% increase, p<0.05). Fructose feeding induced elevated autophagy (LC3B-II: LC3B-I ratio: 46% increase, p<0.05) but not apoptosis signaling (unchanged Bax-1:Bcl-2 ratio). Despite a 28% increase in interstitial fibrosis, no difference in heart weight was observed in fructose-fed mice. We provide the first evidence that myocardial autophagy activation is associated with systemic insulin resistance, and that high level fructose intake inflicts direct cardiac damage. Upregulated autophagy is associated with elevated cardiac superoxide production, suppressed cell survival signaling and fibrotic infiltration in fructose-fed mice. The novel finding that autophagy contributes to cardiac pathology in insulin resistance identifies a new therapeutic target for diabetic cardiomyopathy.
Publisher: Rockefeller University Press
Date: 03-10-2023
Location: New Zealand
No related grants have been discovered for Kimberley Mellor.