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3. Heparanase Stimulation of Physiologic Cardiac Hypertrophy Is Suppressed After Chronic Diabetes, Resulting in Cardiac Remodeling and Dysfunction.

Author

Lee, Chae Syng, Shang, Rui, Wang, Fulong, Khayambashi, Parisa, Wang, Hualin, Araujo, Gala, Puri, Karanjit, Vlodavsky, Israel, Hussein, Bahira, and Rodrigues, Brian

Subjects
CARDIAC hypertrophy, HEART cells, HEPARANASE, HEART diseases, VASCULAR endothelial growth factors, METABOLIC reprogramming
Abstract

In addition to controlling smooth muscle tone in coronary vessels, endothelial cells also influence subjacent cardiomyocyte growth. Because heparanase, with exclusive expression in endothelial cells, enables extracellular matrix remodeling, angiogenesis, metabolic reprogramming, and cell survival, it is conceivable that it could also encourage development of cardiac hypertrophy. Global heparanase overexpression resulted in physiologic cardiac hypertrophy, likely an outcome of HSPG clustering and activation of hypertrophic signaling. The heparanase autocrine effect of releasing neuregulin-1 could have also contributed to this overexpression. Hyperglycemia induced by streptozotocin-induced diabetes sensitized the heart to flow-induced release of heparanase and neuregulin-1. Despite this excess secretion, progression of diabetes caused significant gene expression changes related to mitochondrial metabolism and cell death that led to development of pathologic hypertrophy and heart dysfunction. Physiologic cardiac hypertrophy was also observed in rats with cardiomyocyte-specific vascular endothelial growth factor B overexpression. When perfused, hearts from these animals released significantly higher amounts of both heparanase and neuregulin-1. However, subjecting these animals to diabetes triggered robust transcriptome changes related to metabolism and a transition to pathologic hypertrophy. Our data suggest that in the absence of mechanisms that support cardiac energy generation and prevention of cell death, as seen after diabetes, there is a transition from physiologic to pathologic cardiac hypertrophy and a decline in cardiac function. Article Highlights: Endothelial cells have been implicated in physiologic cardiac hypertrophy. We examined the role of endothelial heparanase in this process and how diabetes affects heparanase function. Heparanase overexpression resulted in physiologic cardiac hypertrophy, an outcome of HSPG clustering and direct and indirect activation of hypertrophic signaling. Hyperglycemia sensitized the heart to flow-induced heparanase release, and progression of diabetes caused gene expression changes related to mitochondrial metabolism and apoptosis. With diabetes and its associated metabolic inflexibility and cell death, actions of heparanase are negated, leading to pathologic cardiac hypertrophy and heart dysfunction. These results can contribute to mechanism-directed therapeutics for diabetic cardiomyopathy. [ABSTRACT FROM AUTHOR]

Published
2024
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10. Human and mouse muscle transcriptomic analyses identify insulin receptor mRNA downregulation in hyperinsulinemia‐associated insulin resistance

Author

Cen, Haoning Howard, primary, Hussein, Bahira, additional, Botezelli, José Diego, additional, Wang, Su, additional, Zhang, Jiashuo Aaron, additional, Noursadeghi, Nilou, additional, Jessen, Niels, additional, Rodrigues, Brian, additional, Timmons, James A., additional, and Johnson, James D., additional

Published
2021
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11. Cardiac-specific VEGFB overexpression reduces lipoprotein lipase activity and improves insulin action in rat heart

Author

Shang, Rui, primary, Lal, Nathaniel, additional, Lee, Chae Syng, additional, Zhai, Yajie, additional, Puri, Karanjit, additional, Seira, Oscar, additional, Boushel, Robert C., additional, Sultan, Ibrahim, additional, Räsänen, Markus, additional, Alitalo, Kari, additional, Hussein, Bahira, additional, and Rodrigues, Brian, additional

Published
2021
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14. MK2‐Deficient Mice Are Bradycardic and Display Delayed Hypertrophic Remodeling in Response to a Chronic Increase in Afterload

Author

Ruiz, Matthieu, primary, Khairallah, Maya, additional, Dingar, Dharmendra, additional, Vaniotis, George, additional, Khairallah, Ramzi J., additional, Lauzier, Benjamin, additional, Thibault, Simon, additional, Trépanier, Joëlle, additional, Shi, Yanfen, additional, Douillette, Annie, additional, Hussein, Bahira, additional, Nawaito, Sherin Ali, additional, Sahadevan, Pramod, additional, Nguyen, Albert, additional, Sahmi, Fatiha, additional, Gillis, Marc‐Antoine, additional, Sirois, Martin G., additional, Gaestel, Matthias, additional, Stanley, William C., additional, Fiset, Céline, additional, Tardif, Jean‐Claude, additional, and Allen, Bruce G., additional

Published
2021
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15. MK2-deficient mice are bradycardic and display delayed hypertrophic remodelling in response to a chronic increase in afterload

Author

Ruiz, Matthieu, primary, Khairallah, Maya, additional, Dingar, Dharmendra, additional, Vaniotis, George, additional, Khairallah, Ramzi J., additional, Lauzier, Benjamin, additional, Thibault, Simon, additional, Trépanier, Joëlle, additional, Shi, Yanfen, additional, Douillette, Annie, additional, Hussein, Bahira, additional, Nawaito, Sherin Ali, additional, Sahadevan, Pramod, additional, Nguyen, Albert, additional, Gillis, Marc-Antoine, additional, Sirois, Martin G, additional, Gaestel, Matthias, additional, Stanley, William C, additional, Fiset, Céline, additional, Tardif, Jean-Claude, additional, and Allen, Bruce G, additional

Published
2020
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17. Human and mouse muscle transcriptomic analyses identify insulin receptor mRNA downregulation in hyperinsulinemia‐associated insulin resistance.

Author

Cen, Haoning Howard, Hussein, Bahira, Botezelli, José Diego, Wang, Su, Zhang, Jiashuo Aaron, Noursadeghi, Nilou, Jessen, Niels, Rodrigues, Brian, Timmons, James A., and Johnson, James D.

Abstract

Hyperinsulinemia is commonly viewed as a compensatory response to insulin resistance, yet studies have demonstrated that chronically elevated insulin may also drive insulin resistance. The molecular mechanisms underpinning this potentially cyclic process remain poorly defined, especially on a transcriptome‐wide level. Transcriptomic meta‐analysis in >450 human samples demonstrated that fasting insulin reliably and negatively correlated with INSR mRNA in skeletal muscle. To establish causality and study the direct effects of prolonged exposure to excess insulin in muscle cells, we incubated C2C12 myotubes with elevated insulin for 16 h, followed by 6 h of serum starvation, and established that acute AKT and ERK signaling were attenuated in this model of in vitro hyperinsulinemia. Global RNA‐sequencing of cells both before and after nutrient withdrawal highlighted genes in the insulin receptor (INSR) signaling, FOXO signaling, and glucose metabolism pathways indicative of ‘hyperinsulinemia’ and ‘starvation’ programs. Consistently, we observed that hyperinsulinemia led to a substantial reduction in Insr gene expression, and subsequently a reduced surface INSR and total INSR protein, both in vitro and in vivo. Bioinformatic modeling combined with RNAi identified SIN3A as a negative regulator of Insr mRNA (and JUND, MAX, and MXI as positive regulators of Irs2 mRNA). Together, our analysis identifies mechanisms which may explain the cyclic processes underlying hyperinsulinemia‐induced insulin resistance in muscle, a process directly relevant to the etiology and disease progression of type 2 diabetes. [ABSTRACT FROM AUTHOR]

Published
2022
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18. Cardiac-specific VEGFB overexpression reduces lipoprotein lipase activity and improves insulin action in rat heart.

Author

Rui Shang, Lal, Nathaniel, Chae Syng Lee, Yajie Zhai, Puri, Karanjit, Seira, Oscar, Boushel, Robert C., Sultan, Ibrahim, Räsänen, Markus, Alitalo, Kari, Hussein, Bahira, and Rodrigues, Brian

Subjects
LIPOPROTEIN lipase, VASCULAR endothelial growth factors, INSULIN, MYOCARDIUM, HEART metabolism
Abstract

Cardiac muscle uses multiple sources of energy including glucose and fatty acid (FA). The heart cannot synthesize FA and relies on obtaining it from other sources, with lipoprotein lipase (LPL) breakdown of lipoproteins suggested to be a key source of FA for cardiac use. Recent work has indicated that cardiac vascular endothelial growth factor B (VEGFB) overexpression expands the coronary vasculature and facilitates metabolic reprogramming that favors glucose utilization. We wanted to explore whether this influence of VEGFB on cardiac metabolism involves regulation of LPL activity with consequent effects on lipotoxicity and insulin signaling. The transcriptomes of rats with and without cardiomyocyte-specific overexpression of human VEGFB were compared by using RNA sequencing. Isolated perfused hearts or cardiomyocytes incubated with heparin were used to enable measurement of LPL activity. Untargeted metabolomic analysis was performed for quantification of cardiac lipid metabolites. Cardiac insulin sensitivity was evaluated using fast-acting insulin. Isolated heart and cardiomyocytes were used to determine transgene-encoded VEGFB isoform secretion patterns and mitochondrial oxidative capacity using high-resolution respirometry and extracellular flux analysis. In vitro, transgenic cardiomyocytes incubated overnight and thus exposed to abundantly secreted VEGFB isoforms, in the absence of any in vivo confounding regulators of cardiac metabolism, demonstrated higher basal oxygen consumption. In the whole heart, VEGFB overexpression induced an angiogenic response that was accompanied by limited cardiac LPL activity through multiple mechanisms. This was associated with a lowered accumulation of lipid intermediates, diacylglycerols and lysophosphatidylcholine, that are known to influence insulin action. In response to exogenous insulin, transgenic hearts demonstrated increased insulin sensitivity. In conclusion, the interrogation of VEGFB function on cardiac metabolism uncovered an intriguing and previously unappreciated effect to lower LPL activity and prevent lipid metabolite accumulation to improve insulin action. VEGFB could be a potential cardioprotective therapy to treat metabolic disorders, for example, diabetes. [ABSTRACT FROM AUTHOR]

Published
2021
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20. MK5 haplodeficiency attenuates hypertrophy and preserves diastolic function during remodeling induced by chronic pressure overload in the mouse heart

Author

Nawaito, Sherin Ali, primary, Dingar, Dharmendra, additional, Sahadevan, Pramod, additional, Hussein, Bahira, additional, Sahmi, Fatiha, additional, Shi, Yanfen, additional, Gillis, Marc-Antoine, additional, Gaestel, Matthias, additional, Tardif, Jean-Claude, additional, and Allen, Bruce G., additional

Published
2017
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23. Heparanase Overexpression Induces Glucagon Resistance and Protects Animals From Chemically Induced Diabetes

Author

Zhang, Dahai, primary, Wang, Fulong, additional, Lal, Nathaniel, additional, Chiu, Amy Pei-Ling, additional, Wan, Andrea, additional, Jia, Jocelyn, additional, Bierende, Denise, additional, Flibotte, Stephane, additional, Sinha, Sunita, additional, Asadi, Ali, additional, Hu, Xiaoke, additional, Taghizadeh, Farnaz, additional, Pulinilkunnil, Thomas, additional, Nislow, Corey, additional, Vlodavsky, Israel, additional, Johnson, James D., additional, Kieffer, Timothy J., additional, Hussein, Bahira, additional, and Rodrigues, Brian, additional

Published
2016
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25. Dual effects of hyperglycemia on endothelial cells and cardiomyocytes to enhance coronary LPL activity.

Author

Pei-Ling Chiu, Amy, Bierende, Denise, Lal, Nathaniel, Fulong Wang, Wan, Andrea, Vlodavsky, Israel, Hussein, Bahira, and Rodrigues, Brian

Subjects
HYPERGLYCEMIA, ENDOTHELIAL cells, LIPOPROTEIN lipase
Abstract

In the diabetic heart, there is excessive dependence on fatty acid (FA) utilization to generate ATP. Lipoprotein lipase (LPL)-mediated hydrolysis of circulating triglycerides is suggested to be the predominant source of FA for cardiac utilization during diabetes. In the heart, the majority of LPL is synthesized in cardiomyocytes and secreted onto cell surface heparan sulfate proteoglycan (HSPG), where an endothelial cell (EC)-releasable β-endoglycosidase, heparanase cleaves the side chains of HSPG to liberate LPL for its onward movement across the EC. EC glycosylphosphatidylinositol-anchored high-density lipoprotein-binding protein 1 (GPIHBP1) captures this released enzyme at its basolateral side and shuttles it across to its luminal side. We tested whether the diabetes-induced increase of transforming growth factor-β (TGF-β) can influence the myocyte and EC to help transfer LPL to the vascular lumen to generate triglyceride-FA. In response to high glucose and EC heparanase secretion, this endoglycosidase is taken up by the cardiomyocyte (Wang Y, Chiu AP, Neumaier K, Wang F, Zhang D, Hussein B, Lal N, Wan A, Liu G, Vlodavsky I, Rodrigues B. Diabetes 63: 2643-2655, 2014) to stimulate matrix metalloproteinase- 9 expression and the conversion of latent to active TGF-β. In the cardiomyocyte, TGF-β activation of RhoA enhances actin cytoskeleton rearrangement to promote LPL trafficking and secretion onto cell surface HSPG. In the EC, TGF-β signaling promotes mesodermal homeobox 2 translocation to the nucleus, which increases the expression of GPIHBP1, which facilitates movement of LPL to the vascular lumen. Collectively, our data suggest that in the diabetic heart, TGF-β actions on the cardiomyocyte promotes movement of LPL, whereas its action on the EC facilitates LPL shuttling. [ABSTRACT FROM AUTHOR]

Published
2018
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26. Heparanase Overexpression Induces Glucagon Resistance and Protects Animals From Chemically Induced Diabetes.

Author

Dahai Zhang, Fulong Wang, Lal, Nathaniel, Amy Pei-Ling Chiu, Andrea Wan, Jocelyn Jia, Bierende, Denise, Flibotte, Stephane, Sinha, Sunita, Asadi, Ali, Xiaoke Hu, Taghizadeh, Farnaz, Pulinilkunnil, Thomas, Nislow, Corey, Vlodavsky, Israel, Johnson, James D., Kieffer, Timothy J., Hussein, Bahira, Rodrigues, Brian, and Zhang, Dahai

Subjects
TREATMENT of diabetes, HEPARANASE, GENETIC overexpression, GLUCAGON, FIBROBLAST growth factors, GLUCAGON-like peptide 1, GLUCOSE metabolism, DIABETES prevention, HYPERGLYCEMIA prevention, ANIMALS, DIABETES, GLYCOSIDASES, GROWTH factors, HYPERGLYCEMIA, INSULIN, ISLANDS of Langerhans, MICE
Abstract

Heparanase, a protein with enzymatic and nonenzymatic properties, contributes toward disease progression and prevention. In the current study, a fortuitous observation in transgenic mice globally overexpressing heparanase (hep-tg) was the discovery of improved glucose homeostasis. We examined the mechanisms that contribute toward this improved glucose metabolism. Heparanase overexpression was associated with enhanced glucose-stimulated insulin secretion and hyperglucagonemia, in addition to changes in islet composition and structure. Strikingly, the pancreatic islet transcriptome was greatly altered in hep-tg mice, with >2,000 genes differentially expressed versus control. The upregulated genes were enriched for diverse functions including cell death regulation, extracellular matrix component synthesis, and pancreatic hormone production. The downregulated genes were tightly linked to regulation of the cell cycle. In response to multiple low-dose streptozotocin (STZ), hep-tg animals developed less severe hyperglycemia compared with wild-type, an effect likely related to their β-cells being more functionally efficient. In animals given a single high dose of STZ causing severe and rapid development of hyperglycemia related to the catastrophic loss of insulin, hep-tg mice continued to have significantly lower blood glucose. In these mice, protective pathways were uncovered for managing hyperglycemia and include augmentation of fibroblast growth factor 21 and glucagon-like peptide 1. This study uncovers the opportunity to use properties of heparanase in management of diabetes. [ABSTRACT FROM AUTHOR]

Published
2017
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27. High glucose facilitated endothelial heparanase transfer to the cardiomyocyte modifies its cell death signature.

Author

Fulong Wang, Jia, Jocelyn, Lal, Nathaniel, Dahai Zhang, Amy Pei-Ling Chiu, Wan, Andrea, Vlodavsky, Israel, Hussein, Bahira, and Rodrigues, Brian

Subjects
HEPARANASE, HEART cells, APOPTOSIS, GLUCOSE, LOW density lipoproteins
Abstract

Aims: The secretion of enzymatically active heparanase (HepA) has been implicated as an essential metabolic adaptation in the heart following diabetes. However, the regulation and function of the enzymatically inactive heparanase (HepL) remain poorly understood. We hypothesized that in response to high glucose (HG) and secretion of HepL from the endothelial cell (EC), HepL uptake and function can protect the cardiomyocyte by modifying its cell death signature. Methods and results: HG promoted both HepL and HepA secretion from microvascular (rat heart micro vessel endothelial cells, RHMEC) and macrovascular (rat aortic endothelial cells, RAOEC) EC. However, only RAOEC were capable of HepL reuptake. This occurred through a low-density lipoprotein receptor-related protein 1 (LRP1) dependent mechanism, as LRP1 inhibition using small interfering RNA (siRNA), receptor-associated protein, or an LRP1 neutralizing antibody significantly reduced uptake. In cardiomyocytes, which have a negligible amount of heparanase gene expression, LRP1 also participated in the uptake of HepL. Exogenous addition of HepL to rat cardiomyocytes produced a dramatically altered expression of apoptosis-related genes, and protection against HG and H2O2 induced cell death. Cardiomyocytes from acutely diabetic rats demonstrated a robust increase in LRP1 expression and levels of heparanase, a pro-survival gene signature, and limited evidence of cell death, observations that were not apparent following chronic and progressive diabetes. Conclusion: Our results highlight EC-to-cardiomyocyte transfer of heparanase to modulate the cardiomyocyte cell death signature. This mechanism was observed in the acutely diabetic heart, and its interruption following chronic diabetes may contribute towards the development of diabetic cardiomyopathy. [ABSTRACT FROM AUTHOR]

Published
2016
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31. Endothelial cells respond to hyperglycemia by increasing the LPL transporter GPIHBP1.

Author

Amy Pei-Ling Chiu, Fulong Wang, Lal, Nathaniel, Ying Wang, Dahai Zhang, Hussein, Bahira, Wan, Andrea, Vlodavsky, Israel, and Rodrigues, Brian

Subjects
ENDOTHELIAL cells, OXIDATION, TRIGLYCERIDES, DIABETES, PLATELET-derived growth factor
Abstract

In diabetes, when glucose uptake and oxidation are impaired, the heart is compelled to use fatty acid (FA) almost exclusively for ATP. The vascular content of lipoprotein lipase (LPL), the rate-limiting enzyme that determines circulating triglyceride clearance, is largely responsible for this FA delivery and increases following diabetes. Glycosylphosphatidylinositol- anchored high-density lipoprotein-binding protein [GPIHBP1; a protein expressed abundantly in the heart in endothelial cells (EC)] collects LPL from the interstitial space and transfers it across ECs onto the luminal binding sites of these cells, where the enzyme is functional. We tested whether ECs respond to hyperglycemia by increasing GPIHBP1. Streptozotocin diabetes increased cardiac LPL activity and GPIHBP1 gene and protein expression. The increased LPL and GPIHBP1 were located at the capillary lumen. In vitro, passaging EC caused a loss of GPIHBP1, which could be induced on exposure to increasing concentrations of glucose. The high-glucoseinduced GPIHBP1 increased LPL shuttling across EC monolayers. GPIHBP1 expression was linked to the EC content of heparanase. Moreover, active heparanase increased GPIHBP1 gene and protein expression. Both ECs and myocyte heparan sulfate proteoglycanbound platelet-derived growth factor (PDGF) released by heparanase caused augmentation of GPIHBP1. Overall, our data suggest that this protein "ensemble" (heparanase-PDGF-GPIHBP1) cooperates in the diabetic heart to regulate FA delivery and utilization by the cardiomyocytes. Interrupting this axis may be a novel therapeutic strategy to restore metabolic equilibrium, curb lipotoxicity, and help prevent or delay heart dysfunction that is characteristic of diabetes. [ABSTRACT FROM AUTHOR]

Published
2014
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32. G1/S Transcription Factor Orthologues Swi4p and Swi6p Are Important but Not Essential for Cell Proliferation and Influence Hyphal Development in the Fungal Pathogen Candida albicans

Author

Hussein, Bahira, Huang, Hao, Glory, Amandeep, Osmani, Amin, Kaminskyj, Susan, Nantel, Andre, and Bachewich, Catherine

Abstract

The G1/S transition is a critical control point for cell proliferation and involves essential transcription complexes termed SBF and MBF in Saccharomyces cerevisiae or MBF in Schizosaccharomyces pombe. In the fungal pathogen Candida albicans, G1/S regulation is not clear. To gain more insight into the G1/S circuitry, we characterized Swi6p, Swi4p and Mbp1p, the closest orthologues of SBF (Swi6p and Swi4p) and MBF (Swi6p and Mbp1p) components in S. cerevisiae. The mbp1Δ/Δ cells showed minor growth defects, whereas swi4Δ/Δ and swi6Δ/Δ yeast cells dramatically increased in size, suggesting a G1phase delay. Gene set enrichment analysis (GSEA) of transcription profiles revealed that genes associated with G1/S phase were significantly enriched in cells lacking Swi4p and Swi6p. These expression patterns suggested that Swi4p and Swi6p have repressing as well as activating activity. Intriguingly, swi4Δ/Δ swi6Δ/Δ and swi4Δ/Δ mbp1Δ/Δ strains were viable, in contrast to the situation in S. cerevisiae, and showed pleiotropic phenotypes that included multibudded yeast, pseudohyphae, and intriguingly, true hyphae. Consistently, GSEA identified strong enrichment of genes that are normally modulated during C. albicans-host cell interactions. Since Swi4p and Swi6p influence G1phase progression and SBF binding sites are lacking in the C. albicans genome, these factors may contribute to MBF activity. Overall, the data suggest that the putative G1/S regulatory machinery of C. albicans contains novel features and underscore the existence of a relationship between G1phase and morphogenetic switching, including hyphal development, in the pathogen.

Published
2010

33. G1/S Transcription Factor Orthologues Swi4p and Swi6p Are Important but Not Essential for Cell Proliferation and Influence Hyphal Development in the Fungal Pathogen Candida albicans

Author

Hussein, Bahira, Huang, Hao, Glory, Amandeep, Osmani, Amin, Kaminskyj, Susan, Nantel, Andre, and Bachewich, Catherine

Abstract

ABSTRACTThe G1/S transition is a critical control point for cell proliferation and involves essential transcription complexes termed SBF and MBF in Saccharomyces cerevisiaeor MBF in Schizosaccharomyces pombe. In the fungal pathogen Candida albicans, G1/S regulation is not clear. To gain more insight into the G1/S circuitry, we characterized Swi6p, Swi4p and Mbp1p, the closest orthologues of SBF (Swi6p and Swi4p) and MBF (Swi6p and Mbp1p) components in S. cerevisiae. The mbp1Δ/Δ cells showed minor growth defects, whereas swi4Δ/Δ and swi6Δ/Δ yeast cells dramatically increased in size, suggesting a G1phase delay. Gene set enrichment analysis (GSEA) of transcription profiles revealed that genes associated with G1/S phase were significantly enriched in cells lacking Swi4p and Swi6p. These expression patterns suggested that Swi4p and Swi6p have repressing as well as activating activity. Intriguingly, swi4Δ/Δ swi6Δ/Δ and swi4Δ/Δ mbp1Δ/Δ strains were viable, in contrast to the situation in S. cerevisiae, and showed pleiotropic phenotypes that included multibudded yeast, pseudohyphae, and intriguingly, true hyphae. Consistently, GSEA identified strong enrichment of genes that are normally modulated during C. albicans-host cell interactions. Since Swi4p and Swi6p influence G1phase progression and SBF binding sites are lacking in the C. albicansgenome, these factors may contribute to MBF activity. Overall, the data suggest that the putative G1/S regulatory machinery of C. albicans contains novel features and underscore the existence of a relationship between G1phase and morphogenetic switching, including hyphal development, in the pathogen.

Published
2010
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34. Reduction in Insulin Uncovers a Novel Effect of VEGFB on Cardiac Substrate Utilization.

Author

Shang R, Lee CS, Wang H, Dyer R, Noll C, Carpentier A, Sultan I, Alitalo K, Boushel R, Hussein B, and Rodrigues B

Subjects
Rats, Animals, Vascular Endothelial Growth Factor B genetics, Vascular Endothelial Growth Factor B metabolism, Rats, Wistar, Myocytes, Cardiac metabolism, Fatty Acids metabolism, Triglycerides metabolism, Lipoprotein Lipase metabolism, Myocardium metabolism, Insulin pharmacology, Diabetic Cardiomyopathies genetics, Diabetic Cardiomyopathies metabolism
Abstract

Background: The heart relies heavily on external fatty acid (FA) for energy production. VEGFB (vascular endothelial growth factor B) has been shown to promote endothelial FA uptake by upregulating FA transporters. However, its impact on LPL (lipoprotein lipase)-mediated lipolysis of lipoproteins, a major source of FA for cardiac use, is unknown., Methods: VEGFB transgenic (Tg) rats were generated by using the α-myosin heavy chain promoter to drive cardiomyocyte-specific overexpression. To measure coronary LPL activity, Langendorff hearts were perfused with heparin. In vivo positron emission tomography imaging with [ 18 F]-triglyceride-fluoro-6-thia-heptadecanoic acid and [ 11 C]-palmitate was used to determine cardiac FA uptake. Mitochondrial FA oxidation was evaluated by high-resolution respirometry. Streptozotocin was used to induce diabetes, and cardiac function was monitored using echocardiography., Results: In Tg hearts, the vectorial transfer of LPL to the vascular lumen is obstructed, resulting in LPL buildup within cardiomyocytes, an effect likely due to coronary vascular development with its associated augmentation of insulin action. With insulin insufficiency following fasting, VEGFB acted unimpeded to facilitate LPL movement and increase its activity at the coronary lumen. In vivo PET imaging following fasting confirmed that VEGFB induced a greater FA uptake to the heart from circulating lipoproteins as compared with plasma-free FAs. As this was associated with augmented mitochondrial oxidation, lipid accumulation in the heart was prevented. We further examined whether this property of VEGFB on cardiac metabolism could be useful following diabetes and its associated cardiac dysfunction, with attendant loss of metabolic flexibility. In Tg hearts, diabetes inhibited myocyte VEGFB gene expression and protein secretion together with its downstream receptor signaling, effects that could explain its lack of cardioprotection., Conclusions: Our study highlights the novel role of VEGFB in LPL-derived FA supply and utilization. In diabetes, loss of VEGFB action may contribute toward metabolic inflexibility, lipotoxicity, and development of diabetic cardiomyopathy., Competing Interests: Disclosures None.

Published
2024
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35. Cardiac-specific VEGFB overexpression reduces lipoprotein lipase activity and improves insulin action in rat heart.

Author

Shang R, Lal N, Lee CS, Zhai Y, Puri K, Seira O, Boushel RC, Sultan I, Räsänen M, Alitalo K, Hussein B, and Rodrigues B

Subjects
Animals, Cells, Cultured, Enzyme Activation genetics, Female, Heart physiology, Insulin metabolism, Male, Organ Specificity genetics, Rats, Rats, Sprague-Dawley, Rats, Transgenic, Up-Regulation genetics, Vascular Endothelial Growth Factor B metabolism, Insulin Resistance genetics, Lipoprotein Lipase metabolism, Myocardium metabolism, Vascular Endothelial Growth Factor B genetics
Abstract

Cardiac muscle uses multiple sources of energy including glucose and fatty acid (FA). The heart cannot synthesize FA and relies on obtaining it from other sources, with lipoprotein lipase (LPL) breakdown of lipoproteins suggested to be a key source of FA for cardiac use. Recent work has indicated that cardiac vascular endothelial growth factor B (VEGFB) overexpression expands the coronary vasculature and facilitates metabolic reprogramming that favors glucose utilization. We wanted to explore whether this influence of VEGFB on cardiac metabolism involves regulation of LPL activity with consequent effects on lipotoxicity and insulin signaling. The transcriptomes of rats with and without cardiomyocyte-specific overexpression of human VEGFB were compared by using RNA sequencing. Isolated perfused hearts or cardiomyocytes incubated with heparin were used to enable measurement of LPL activity. Untargeted metabolomic analysis was performed for quantification of cardiac lipid metabolites. Cardiac insulin sensitivity was evaluated using fast-acting insulin. Isolated heart and cardiomyocytes were used to determine transgene-encoded VEGFB isoform secretion patterns and mitochondrial oxidative capacity using high-resolution respirometry and extracellular flux analysis. In vitro, transgenic cardiomyocytes incubated overnight and thus exposed to abundantly secreted VEGFB isoforms, in the absence of any in vivo confounding regulators of cardiac metabolism, demonstrated higher basal oxygen consumption. In the whole heart, VEGFB overexpression induced an angiogenic response that was accompanied by limited cardiac LPL activity through multiple mechanisms. This was associated with a lowered accumulation of lipid intermediates, diacylglycerols and lysophosphatidylcholine, that are known to influence insulin action. In response to exogenous insulin, transgenic hearts demonstrated increased insulin sensitivity. In conclusion, the interrogation of VEGFB function on cardiac metabolism uncovered an intriguing and previously unappreciated effect to lower LPL activity and prevent lipid metabolite accumulation to improve insulin action. VEGFB could be a potential cardioprotective therapy to treat metabolic disorders, for example, diabetes. NEW & NOTEWORTHY In hearts overexpressing vascular endothelial growth factor B (VEGFB), besides its known angiogenic response, multiple regulatory mechanisms lowered coronary LPL. This was accompanied by limited cardiac lipid metabolite accumulation with an augmentation of cardiac insulin action. Our data for the first time links VEGFB to coronary LPL in regulation of cardiac metabolism. VEGFB may be cardioprotective in metabolic disorders like diabetes.

Published
2021
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36. Dual effects of hyperglycemia on endothelial cells and cardiomyocytes to enhance coronary LPL activity.

Author

Chiu AP, Bierende D, Lal N, Wang F, Wan A, Vlodavsky I, Hussein B, and Rodrigues B

Subjects
Animals, Cell Communication, Cells, Cultured, Diabetes Mellitus, Experimental blood, Diabetes Mellitus, Experimental physiopathology, Diabetic Cardiomyopathies blood, Diabetic Cardiomyopathies physiopathology, Glucuronidase metabolism, Homeodomain Proteins metabolism, Male, Matrix Metalloproteinase 9 metabolism, Muscle Proteins metabolism, Rats, Wistar, Receptors, Lipoprotein metabolism, Signal Transduction, Transforming Growth Factor beta metabolism, Blood Glucose metabolism, Diabetes Mellitus, Experimental enzymology, Diabetic Cardiomyopathies enzymology, Endothelial Cells enzymology, Energy Metabolism, Fatty Acids metabolism, Lipoprotein Lipase metabolism, Myocytes, Cardiac enzymology
Abstract

In the diabetic heart, there is excessive dependence on fatty acid (FA) utilization to generate ATP. Lipoprotein lipase (LPL)-mediated hydrolysis of circulating triglycerides is suggested to be the predominant source of FA for cardiac utilization during diabetes. In the heart, the majority of LPL is synthesized in cardiomyocytes and secreted onto cell surface heparan sulfate proteoglycan (HSPG), where an endothelial cell (EC)-releasable β-endoglycosidase, heparanase cleaves the side chains of HSPG to liberate LPL for its onward movement across the EC. EC glycosylphosphatidylinositol-anchored high-density lipoprotein-binding protein 1 (GPIHBP1) captures this released enzyme at its basolateral side and shuttles it across to its luminal side. We tested whether the diabetes-induced increase of transforming growth factor-β (TGF-β) can influence the myocyte and EC to help transfer LPL to the vascular lumen to generate triglyceride-FA. In response to high glucose and EC heparanase secretion, this endoglycosidase is taken up by the cardiomyocyte (Wang Y, Chiu AP, Neumaier K, Wang F, Zhang D, Hussein B, Lal N, Wan A, Liu G, Vlodavsky I, Rodrigues B. Diabetes 63: 2643-2655, 2014) to stimulate matrix metalloproteinase-9 expression and the conversion of latent to active TGF-β. In the cardiomyocyte, TGF-β activation of RhoA enhances actin cytoskeleton rearrangement to promote LPL trafficking and secretion onto cell surface HSPG. In the EC, TGF-β signaling promotes mesodermal homeobox 2 translocation to the nucleus, which increases the expression of GPIHBP1, which facilitates movement of LPL to the vascular lumen. Collectively, our data suggest that in the diabetic heart, TGF-β actions on the cardiomyocyte promotes movement of LPL, whereas its action on the EC facilitates LPL shuttling. NEW & NOTEWORTHY Endothelial cells, as first responders to hyperglycemia, release heparanase, whose subsequent uptake by cardiomyocytes amplifies matrix metalloproteinase-9 expression and activation of transforming growth factor-β. Transforming growth factor-β increases lipoprotein lipase secretion from cardiomyocytes and promotes mesodermal homeobox 2 to enhance glycosylphosphatidylinositol-anchored high-density lipoprotein-binding protein 1-dependent transfer of lipoprotein lipase across endothelial cells, mechanisms that accelerate fatty acid utilization by the diabetic heart.

Published
2018
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37. MK5 haplodeficiency attenuates hypertrophy and preserves diastolic function during remodeling induced by chronic pressure overload in the mouse heart.

Author

Nawaito SA, Dingar D, Sahadevan P, Hussein B, Sahmi F, Shi Y, Gillis MA, Gaestel M, Tardif JC, and Allen BG

Subjects
Animals, Haplotypes genetics, Hypertrophy, Left Ventricular etiology, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Myocardial Contraction, Stroke Volume, Ventricular Dysfunction, Left complications, Hypertrophy, Left Ventricular physiopathology, Intracellular Signaling Peptides and Proteins metabolism, Protein Serine-Threonine Kinases metabolism, Ventricular Dysfunction, Left physiopathology, Ventricular Remodeling physiology
Abstract

MAPK-activated protein kinase-5 (MK5) is a protein serine/threonine kinase that is activated by p38 MAPK and the atypical MAPKs ERK3 and ERK4. The physiological function(s) of MK5 remains unknown. Here, we examined the effect of MK5 haplodeficiency on cardiac function and myocardial remodeling. At 12 wk of age, MK5 haplodeficient mice (MK5 +/- ) were smaller than age-matched wild-type littermates (MK5 +/+ ), with similar diastolic function but reduced systolic function. Transverse aortic constriction (TAC) was used to induce chronic pressure overload in 12-wk-old male MK5 +/- and MK5 +/+ mice. Two weeks post-TAC, heart weight-to-tibia length ratios were similarly increased in MK5 +/- and MK5 +/+ hearts, as was the abundance of B-type natriuretic peptide and β-myosin heavy chain mRNA. Left ventricular ejection fraction was reduced in both MK5 +/+ and MK5 +/- mice, whereas regional peak systolic tissue velocities were reduced and isovolumetric relaxation time was prolonged in MK5 +/+ hearts but not in MK5 +/- hearts. The TAC-induced increase in collagen type 1-α 1 mRNA observed in MK5 +/+ hearts was markedly attenuated in MK5 +/- hearts. Eight weeks post-TAC, systolic function was equally impaired in MK5 +/+ and MK5 +/- mice. In contrast, the increase in E wave deceleration rate and progression of hypertrophy observed in TAC MK5 +/+ mice were attenuated in TAC MK5 +/- mice. MK5 immunoreactivity was detected in adult fibroblasts but not in myocytes. MK5 +/+ , MK5 +/- , and MK5 -/- fibroblasts all expressed α-smooth muscle actin in culture. Hence, reduced MK5 expression in cardiac fibroblasts was associated with the attenuation of both hypertrophy and development of a restrictive filling pattern during myocardial remodeling in response to chronic pressure overload. NEW & NOTEWORTHY MAPK-activated protein kinase-5 (MK5)/p38-regulated/activated protein kinase is a protein serine/threonine kinase activated by p38 MAPK and/or the atypical MAPKs ERK3 and ERK4. MK5 immunoreactivity was detected in adult ventricular fibroblasts but not in myocytes. MK5 haplodeficiency attenuated the progression of hypertrophy, reduced collagen type 1 mRNA, and protected diastolic function in response to chronic pressure overload., (Copyright © 2017 the American Physiological Society.)

Published
2017
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38. Loss of VEGFB and its signaling in the diabetic heart is associated with increased cell death signaling.

Author

Lal N, Chiu AP, Wang F, Zhang D, Jia J, Wan A, Vlodavsky I, Hussein B, and Rodrigues B

Subjects
Animals, Apoptosis Regulatory Proteins genetics, Apoptosis Regulatory Proteins metabolism, Autocrine Communication, Cells, Cultured, Diabetes Mellitus, Experimental chemically induced, Diabetic Cardiomyopathies chemically induced, Diabetic Cardiomyopathies genetics, Diabetic Cardiomyopathies pathology, Endothelial Cells enzymology, Glucuronidase metabolism, Male, Myocardium pathology, Paracrine Communication, Rats, Wistar, Streptozocin, Vascular Endothelial Growth Factor B genetics, Vascular Endothelial Growth Factor Receptor-1 genetics, Vascular Endothelial Growth Factor Receptor-1 metabolism, Apoptosis, Diabetic Cardiomyopathies metabolism, Myocardium metabolism, Signal Transduction, Vascular Endothelial Growth Factor B metabolism
Abstract

Vascular endothelial growth factor B (VEGFB) is highly expressed in metabolically active tissues, such as the heart and skeletal muscle, suggesting a function in maintaining oxidative metabolic and contractile function in these tissues. Multiple models of heart failure have indicated a significant drop in VEGFB. However, whether there is a role for decreased VEGFB in diabetic cardiomyopathy is currently unknown. Of the VEGFB located in cardiomyocytes, there is a substantial and readily releasable pool localized on the cell surface. The immediate response to high glucose and the secretion of endothelial heparanase is the release of this surface-bound VEGFB, which triggers signaling pathways and gene expression to influence endothelial cell (autocrine action) and cardiomyocyte (paracrine effects) survival. Under conditions of hyperglycemia, when VEGFB production is impaired, a robust increase in vascular endothelial growth factor receptor (VEGFR)-1 expression ensues as a possible mechanism to enhance or maintain VEGFB signaling. However, even with an increase in VEGFR1 after diabetes, cardiomyocytes are unable to respond to VEGFB. In addition to the loss of VEGFB production and signaling, evaluation of latent heparanase, the protein responsible for VEGFB release, also showed a significant decline in expression in whole hearts from animals with chronic or acute diabetes. Defects in these numerous VEGFB pathways were associated with an increased cell death signature in our models of diabetes. Through this bidirectional interaction between endothelial cells (which secrete heparanase) and cardiomyocytes (which release VEGFB), this growth factor could provide the diabetic heart protection against cell death and may be a critical tool to delay or prevent cardiomyopathy. NEW & NOTEWORTHY We discovered a bidirectional interaction between endothelial cells (which secrete heparanase) and cardiomyocytes [which release vascular endothelial growth factor B (VEGFB)]. VEGFB promoted cell survival through ERK and cell death gene expression. Loss of VEGFB and its downstream signaling is an early event following hyperglycemia, is sustained with disease progression, and could explain diabetic cardiomyopathy., (Copyright © 2017 the American Physiological Society.)

Published
2017
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39. Heparanase Overexpression Induces Glucagon Resistance and Protects Animals From Chemically Induced Diabetes.

Author

Zhang D, Wang F, Lal N, Chiu AP, Wan A, Jia J, Bierende D, Flibotte S, Sinha S, Asadi A, Hu X, Taghizadeh F, Pulinilkunnil T, Nislow C, Vlodavsky I, Johnson JD, Kieffer TJ, Hussein B, and Rodrigues B

Subjects
Animals, Diabetes Mellitus, Experimental genetics, Diabetes Mellitus, Experimental metabolism, Diabetes Mellitus, Experimental prevention & control, Fibroblast Growth Factors metabolism, Glucagon-Like Peptide 1 metabolism, Glucuronidase genetics, Hyperglycemia blood, Hyperglycemia metabolism, Hyperglycemia prevention & control, Insulin metabolism, Islets of Langerhans drug effects, Islets of Langerhans metabolism, Male, Mice, Mice, Inbred C57BL, Mice, Transgenic, Streptozocin toxicity, Glucagon metabolism, Glucuronidase metabolism
Abstract

Heparanase, a protein with enzymatic and nonenzymatic properties, contributes toward disease progression and prevention. In the current study, a fortuitous observation in transgenic mice globally overexpressing heparanase (hep-tg) was the discovery of improved glucose homeostasis. We examined the mechanisms that contribute toward this improved glucose metabolism. Heparanase overexpression was associated with enhanced glucose-stimulated insulin secretion and hyperglucagonemia, in addition to changes in islet composition and structure. Strikingly, the pancreatic islet transcriptome was greatly altered in hep-tg mice, with >2,000 genes differentially expressed versus control. The upregulated genes were enriched for diverse functions including cell death regulation, extracellular matrix component synthesis, and pancreatic hormone production. The downregulated genes were tightly linked to regulation of the cell cycle. In response to multiple low-dose streptozotocin (STZ), hep-tg animals developed less severe hyperglycemia compared with wild-type, an effect likely related to their β-cells being more functionally efficient. In animals given a single high dose of STZ causing severe and rapid development of hyperglycemia related to the catastrophic loss of insulin, hep-tg mice continued to have significantly lower blood glucose. In these mice, protective pathways were uncovered for managing hyperglycemia and include augmentation of fibroblast growth factor 21 and glucagon-like peptide 1. This study uncovers the opportunity to use properties of heparanase in management of diabetes., (© 2017 by the American Diabetes Association.)

Published
2017
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40. Endothelial cells respond to hyperglycemia by increasing the LPL transporter GPIHBP1.

Author

Pei-Ling Chiu A, Wang F, Lal N, Wang Y, Zhang D, Hussein B, Wan A, Vlodavsky I, and Rodrigues B

Subjects
Animals, Biological Transport, Active physiology, Blotting, Western, Cattle, Coculture Techniques, Cytokines biosynthesis, Diabetes Mellitus, Experimental metabolism, Fluorescent Antibody Technique, Glucose pharmacology, Glucuronidase metabolism, Lipolysis physiology, Male, Monocytes metabolism, Myocytes, Cardiac metabolism, Platelet-Derived Growth Factor metabolism, RNA, Messenger biosynthesis, RNA, Messenger genetics, Rats, Rats, Wistar, Real-Time Polymerase Chain Reaction, Endothelial Cells metabolism, Hyperglycemia metabolism, Lipoprotein Lipase biosynthesis, Receptors, Lipoprotein biosynthesis
Abstract

In diabetes, when glucose uptake and oxidation are impaired, the heart is compelled to use fatty acid (FA) almost exclusively for ATP. The vascular content of lipoprotein lipase (LPL), the rate-limiting enzyme that determines circulating triglyceride clearance, is largely responsible for this FA delivery and increases following diabetes. Glycosylphosphatidylinositol-anchored high-density lipoprotein-binding protein [GPIHBP1; a protein expressed abundantly in the heart in endothelial cells (EC)] collects LPL from the interstitial space and transfers it across ECs onto the luminal binding sites of these cells, where the enzyme is functional. We tested whether ECs respond to hyperglycemia by increasing GPIHBP1. Streptozotocin diabetes increased cardiac LPL activity and GPIHBP1 gene and protein expression. The increased LPL and GPIHBP1 were located at the capillary lumen. In vitro, passaging EC caused a loss of GPIHBP1, which could be induced on exposure to increasing concentrations of glucose. The high-glucose-induced GPIHBP1 increased LPL shuttling across EC monolayers. GPIHBP1 expression was linked to the EC content of heparanase. Moreover, active heparanase increased GPIHBP1 gene and protein expression. Both ECs and myocyte heparan sulfate proteoglycan-bound platelet-derived growth factor (PDGF) released by heparanase caused augmentation of GPIHBP1. Overall, our data suggest that this protein "ensemble" (heparanase-PDGF-GPIHBP1) cooperates in the diabetic heart to regulate FA delivery and utilization by the cardiomyocytes. Interrupting this axis may be a novel therapeutic strategy to restore metabolic equilibrium, curb lipotoxicity, and help prevent or delay heart dysfunction that is characteristic of diabetes., (Copyright © 2014 the American Physiological Society.)

Published
2014
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41. G1/S transcription factor orthologues Swi4p and Swi6p are important but not essential for cell proliferation and influence hyphal development in the fungal pathogen Candida albicans.

Author

Hussein B, Huang H, Glory A, Osmani A, Kaminskyj S, Nantel A, and Bachewich C

Subjects
Candida albicans cytology, Candida albicans genetics, Candida albicans growth & development, Fungal Proteins genetics, Hyphae genetics, Hyphae metabolism, Transcription Factors genetics, Candida albicans metabolism, Cell Proliferation, Fungal Proteins metabolism, G1 Phase, Hyphae growth & development, S Phase, Transcription Factors metabolism
Abstract

The G(1)/S transition is a critical control point for cell proliferation and involves essential transcription complexes termed SBF and MBF in Saccharomyces cerevisiae or MBF in Schizosaccharomyces pombe. In the fungal pathogen Candida albicans, G(1)/S regulation is not clear. To gain more insight into the G(1)/S circuitry, we characterized Swi6p, Swi4p and Mbp1p, the closest orthologues of SBF (Swi6p and Swi4p) and MBF (Swi6p and Mbp1p) components in S. cerevisiae. The mbp1Δ/Δ cells showed minor growth defects, whereas swi4Δ/Δ and swi6Δ/Δ yeast cells dramatically increased in size, suggesting a G(1) phase delay. Gene set enrichment analysis (GSEA) of transcription profiles revealed that genes associated with G(1)/S phase were significantly enriched in cells lacking Swi4p and Swi6p. These expression patterns suggested that Swi4p and Swi6p have repressing as well as activating activity. Intriguingly, swi4Δ/Δ swi6Δ/Δ and swi4Δ/Δ mbp1Δ/Δ strains were viable, in contrast to the situation in S. cerevisiae, and showed pleiotropic phenotypes that included multibudded yeast, pseudohyphae, and intriguingly, true hyphae. Consistently, GSEA identified strong enrichment of genes that are normally modulated during C. albicans-host cell interactions. Since Swi4p and Swi6p influence G(1) phase progression and SBF binding sites are lacking in the C. albicans genome, these factors may contribute to MBF activity. Overall, the data suggest that the putative G(1)/S regulatory machinery of C. albicans contains novel features and underscore the existence of a relationship between G(1) phase and morphogenetic switching, including hyphal development, in the pathogen.

Published
2011
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