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1. Frequency of mononuclear diploid cardiomyocytes underlies natural variation in heart regeneration

Author

Patterson, Michaela, Barske, Lindsey, Van Handel, Ben, Rau, Christoph D, Gan, Peiheng, Sharma, Avneesh, Parikh, Shan, Denholtz, Matt, Huang, Ying, Yamaguchi, Yukiko, Shen, Hua, Allayee, Hooman, Crump, J Gage, Force, Thomas I, Lien, Ching-Ling, Makita, Takako, Lusis, Aldons J, Kumar, S Ram, and Sucov, Henry M

Subjects
Biological Sciences, Genetics, Cardiovascular, Regenerative Medicine, Heart Disease, Animals, Animals, Genetically Modified, Cells, Cultured, Diploidy, Gene Expression Profiling, Heart, Immunoblotting, In Situ Hybridization, Fluorescence, Mice, Inbred C57BL, Mice, Knockout, Mice, Transgenic, Microscopy, Confocal, Myocardium, Myocytes, Cardiac, Protein Kinases, Protein Serine-Threonine Kinases, Regeneration, Zebrafish, Medical and Health Sciences, Developmental Biology, Agricultural biotechnology, Bioinformatics and computational biology
Abstract

Adult mammalian cardiomyocyte regeneration after injury is thought to be minimal. Mononuclear diploid cardiomyocytes (MNDCMs), a relatively small subpopulation in the adult heart, may account for the observed degree of regeneration, but this has not been tested. We surveyed 120 inbred mouse strains and found that the frequency of adult mononuclear cardiomyocytes was surprisingly variable (>7-fold). Cardiomyocyte proliferation and heart functional recovery after coronary artery ligation both correlated with pre-injury MNDCM content. Using genome-wide association, we identified Tnni3k as one gene that influences variation in this composition and demonstrated that Tnni3k knockout resulted in elevated MNDCM content and increased cardiomyocyte proliferation after injury. Reciprocally, overexpression of Tnni3k in zebrafish promoted cardiomyocyte polyploidization and compromised heart regeneration. Our results corroborate the relevance of MNDCMs in heart regeneration. Moreover, they imply that intrinsic heart regeneration is not limited nor uniform in all individuals, but rather is a variable trait influenced by multiple genes.

Published
2017

3. 21st Century Cardio-Oncology: Identifying Cardiac Safety Signals in the Era of Personalized Medicine.

Author

Sheng, Calvin, Amiri-Kordestani, Laleh, Palmby, Todd, Force, Thomas, Hong, Charles, Wu, Joseph, Croce, Kevin, Kim, Geoffrey, and Moslehi, Javid

Subjects
cardio-oncology, cardiotoxicity, nonclinical/preclinical models
Abstract

Cardiotoxicity is a well-established complication of oncology therapies. Cardiomyopathy resulting from anthracyclines is a classic example. In the past decade, an explosion of novel cancer therapies, often targeted and more specific than traditional therapies, has revolutionized oncology therapy and dramatically changed cancer prognosis. However, some of these therapies have introduced an assortment of cardiovascular (CV) complications. At times, these devastating outcomes have only become apparent after drug approval and have limited the use of potent therapies. There is a growing need for better testing platforms, both for CV toxicity screening, as well as for elucidating mechanisms of cardiotoxicities of approved cancer therapies. This review discusses the utility of nonclinical models (in vitro, in vivo, & in silico) available and highlights recent advancements in modalities like human stem cell-derived cardiomyocytes for developing more comprehensive cardiotoxicity testing and new means of cardioprotection with targeted anticancer therapies.

Published
2016

11. Cardiomyocyte HIPK2 Maintains Basal Cardiac Function via ERK Signaling

Author

Guo, Yuanjun, Sui, Jennifer Y., Kim, Kyungsoo, Zhang, Zhentao, Qu, Xiaoyan A., Nam, Young-Jae, Willette, Robert N., Barnett, Joey V., Knollmann, Bjorn C., Force, Thomas, and Lal, Hind

Subjects
Heart Failure, Mice, Knockout, Mice, MAP Kinase Signaling System, Gene Expression Profiling, Myocardium, MAP Kinase Kinase 1, Animals, Protein Serine-Threonine Kinases, Article, Algorithms, Biomarkers, Oligonucleotide Array Sequence Analysis
Abstract

BACKGROUND: Cardiac kinases play a critical role in the development of heart failure, and represent potential tractable therapeutic targets. However, only a very small fraction of the cardiac kinome has been investigated. To identify novel cardiac kinases involved in heart failure, we employed an integrated transcriptomics and bioinformatics analysis and identified Homeodomain-Interacting Protein Kinase 2 (HIPK2) as a novel candidate kinase. The role of HIPK2 in cardiac biology is unknown. METHODS: We used the Expression2Kinase algorithm for the screening of kinase targets. To determine the role of HIPK2 in the heart, we generated cardiomyocyte-specific HIPK2 knockout (CM-KO) and heterozygous (CM-Het) mice. Heart function was examined by echocardiography and related cellular and molecular mechanisms were examined. Adeno-associated virus serotype 9 (AAV9) carrying cardiac-specific constitutively active MEK1 (TnT-MEK1-CA) were administrated to rescue cardiac dysfunction in CM-KOs. RESULTS: To our knowledge, this is the first study to define the role of HIPK2 in cardiac biology. Using multiple HIPK2 loss-of-function mouse models, we demonstrated that reduction of HIPK2 in cardiomyocytes leads to cardiac dysfunction—suggesting a causal role in heart failure. Importantly, cardiac dysfunction in HIPK2 KOs developed with advancing age, but not during development. In addition, CM-KO and CM-Het exhibited a gene dose-response relationship of cardiomyocyte HIPK2 on heart function. HIPK2 expression in the heart was significantly reduced in human end-stage ischemic cardiomyopathy compared to non-failing myocardium, suggesting a clinical relevance of HIPK2 in cardiac biology. In vitro studies with neonatal rat ventricular cardiomyocytes corroborated the in vivo findings. Specifically, adenovirus-mediated overexpression of HIPK2 suppressed the expression of heart failure markers, NPPA and NPPB, at basal condition and abolished phenylephrine-induced pathological gene expression. An array of mechanistic studies revealed impaired ERK1/2 signaling in HIPK2 deficient hearts. In vivo rescue experiment with AAV9 TnT-MEK1-CA nearly abolished the detrimental phenotype of KOs suggesting that impaired ERK signaling mediated apoptosis as the key factor driving the detrimental phenotype in CM-KO hearts. CONCLUSIONS: Taken together, these findings suggest that cardiomyocyte HIPK2 is required to maintain normal cardiac function via ERK signaling.

Published
2019

16. Rab-GTPase binding effector protein 2 (RABEP2) is a primed substrate for Glycogen Synthase kinase-3 (GSK3)

Author

Logie, Lisa, Van Aalten, Lidy, Knebel, Axel, Force, Thomas, Hastie, C. James, MacLauchlan, Hilary, Campbell, David G., Gourlay, Robert, Prescott, Alan, Davidson, Jane, Fuller, Will, and Sutherland, Calum

Subjects
Male, animal structures, lcsh:R, Glycogen Synthase Kinases, Vesicular Transport Proteins, lcsh:Medicine, macromolecular substances, Article, Rats, Rats, Sprague-Dawley, HEK293 Cells, Animals, Humans, lcsh:Q, Phosphorylation, lcsh:Science, Protein Kinase Inhibitors, Biomarkers, Cells, Cultured, Protein Binding, rab5 GTP-Binding Proteins
Abstract

Glycogen synthase kinase-3 (GSK3) regulates many physiological processes through phosphorylation of a diverse array of substrates. Inhibitors of GSK3 have been generated as potential therapies in several diseases, however the vital role GSK3 plays in cell biology makes the clinical use of GSK3 inhibitors potentially problematic. A clearer understanding of true physiological and pathophysiological substrates of GSK3 should provide opportunities for more selective, disease specific, manipulation of GSK3. To identify kinetically favourable substrates we performed a GSK3 substrate screen in heart tissue. Rab-GTPase binding effector protein 2 (RABEP2) was identified as a novel GSK3 substrate and GSK3 phosphorylation of RABEP2 at Ser200 was enhanced by prior phosphorylation at Ser204, fitting the known consensus sequence for GSK3 substrates. Both residues are phosphorylated in cells while only Ser200 phosphorylation is reduced following inhibition of GSK3. RABEP2 function was originally identified as a Rab5 binding protein. We did not observe co-localisation of RABEP2 and Rab5 in cells, while ectopic expression of RABEP2 had no effect on endosomal recycling. The work presented identifies RABEP2 as a novel primed substrate of GSK3, and thus a potential biomarker for GSK3 activity, but understanding how phosphorylation regulates RABEP2 function requires more information on physiological roles of RABEP2.

Published
2017

18. Correction: Analysis of Tyrosine Kinase Inhibitor-Mediated Decline in Contractile Force in Rat Engineered Heart Tissue

Author

Jacob, Fabian, primary, Yonis, Amina Y., additional, Cuello, Friederike, additional, Luther, Pradeep, additional, Schulze, Thomas, additional, Eder, Alexandra, additional, Streichert, Thomas, additional, Mannhardt, Ingra, additional, Hirt, Marc N., additional, Schaaf, Sebastian, additional, Stenzig, Justus, additional, Force, Thomas, additional, Eschenhagen, Thomas, additional, and Hansen, Arne, additional

Published
2018
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23. Activation of the Amino Acid Response Pathway Blunts the Effects of Cardiac Stress

Author

Qin, Pu, primary, Arabacilar, Pelin, additional, Bernard, Roberta E., additional, Bao, Weike, additional, Olzinski, Alan R., additional, Guo, Yuanjun, additional, Lal, Hind, additional, Eisennagel, Stephen H., additional, Platchek, Michael C., additional, Xie, Wensheng, additional, del Rosario, Julius, additional, Nayal, Mohamad, additional, Lu, Quinn, additional, Roethke, Theresa, additional, Schnackenberg, Christine G., additional, Wright, Fe, additional, Quaile, Michael P., additional, Halsey, Wendy S., additional, Hughes, Ashley M., additional, Sathe, Ganesh M., additional, Livi, George P., additional, Kirkpatrick, Robert B., additional, Qu, Xiaoyan A., additional, Rajpal, Deepak K., additional, Faelth Savitski, Maria, additional, Bantscheff, Marcus, additional, Joberty, Gerard, additional, Bergamini, Giovanna, additional, Force, Thomas L., additional, Gatto, Gregory J., additional, Hu, Erding, additional, and Willette, Robert N., additional

Published
2017
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24. A Novel Positron Emission Tomography (PET) Approach to Monitor Cardiac Metabolic Pathway Remodeling in Response to Sunitinib Malate

Author

O’Farrell, Alice C., primary, Evans, Rhys, additional, Silvola, Johanna M. U., additional, Miller, Ian S., additional, Conroy, Emer, additional, Hector, Suzanne, additional, Cary, Maurice, additional, Murray, David W., additional, Jarzabek, Monika A., additional, Maratha, Ashwini, additional, Alamanou, Marina, additional, Udupi, Girish Mallya, additional, Shiels, Liam, additional, Pallaud, Celine, additional, Saraste, Antti, additional, Liljenbäck, Heidi, additional, Jauhiainen, Matti, additional, Oikonen, Vesa, additional, Ducret, Axel, additional, Cutler, Paul, additional, McAuliffe, Fionnuala M., additional, Rousseau, Jacques A., additional, Lecomte, Roger, additional, Gascon, Suzanne, additional, Arany, Zoltan, additional, Ky, Bonnie, additional, Force, Thomas, additional, Knuuti, Juhani, additional, Gallagher, William M., additional, Roivainen, Anne, additional, and Byrne, Annette T., additional

Published
2017
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25. Targeted disruption of glycogen synthase kinase-3β in cardiomyocytes attenuates cardiac parasympathetic dysfunction in type 1 diabetic Akita mice.

Author

Yali Zhang, Welzig, Charles M., Haburcak, Marian, Bo Wang, Aronovitz, Mark, Blanton, Robert M., Ho-Jin Park, Force, Thomas, Noujaim, Sami, and Galper, Jonas B.

Abstract

Type 1 diabetic Akita mice develop severe cardiac parasympathetic dysfunction that we have previously demonstrated is due at least in part to an abnormality in the response of the end organ to parasympathetic stimulation. Specifically, we had shown that hypoinsulinemia in the diabetic heart results in attenuation of the G-protein coupled inward rectifying K channel (GIRK) which mediates the negative chronotropic response to parasympathetic stimulation due at least in part to decreased expression of the GIRK1 and GIRK4 subunits of the channel. We further demonstrated that the expression of GIRK1 and GIRK4 is under the control of the Sterol Regulatory element Binding Protein (SREBP-1), which is also decreased in response to hypoinsulinemia. Finally, given that hyperactivity of Glycogen Synthase Kinase (GSK)3β, had been demonstrated in the diabetic heart, we demonstrated that treatment of Akita mice with Li+, an inhibitor of GSK3β, increased parasympathetic responsiveness and SREBP-1 levels consistent with the conclusion that GSK3β might regulate IKACh via an effect on SREBP-1. However, inhibitor studies were complicated by lack of specificity for GSK3β. Here we generated an Akita mouse with cardiac specific inducible knockout of GSK3β. Using this mouse, we demonstrate that attenuation of GSK3β expression is associated with an increase in parasympathetic responsiveness measured as an increase in the heart rate response to atropine from 17.3 ± 3.5% (n = 8) prior to 41.2 ± 5.4% (n = 8, P = 0.017), an increase in the duration of carbamylcholine mediated bradycardia from 8.43 ± 1.60 min (n = 7) to 12.71 ± 2.26 min (n = 7, P = 0.028) and an increase in HRV as measured by an increase in the high frequency fraction from 40.78 ± 3.86% to 65.04 ± 5.64 (n = 10, P = 0.005). Furthermore, patch clamp measurements demonstrated a 3-fold increase in acetylcholine stimulated peak IKACh in atrial myocytes from GSK3β deficiency mice compared with control. Finally, western blot analysis of atrial extracts from knockout mice demonstrated increased levels of SREBP-1, GIRK1 and GIRK4 compared with control. Taken together with our prior observations, these data establish a role of increased GSK3β activity in the pathogenesis of parasympathetic dysfunction in type 1 diabetes via the regulation of IKACh and GIRK1/4 expression. [ABSTRACT FROM AUTHOR]

Published
2019
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26. Inhibition of GSK-3 to induce cardiomyocyte proliferation: a recipe for in situ cardiac regeneration.

Author

Singh, Anand Prakash, Umbarkar, Prachi, Guo, Yuanjun, Force, Thomas, Gupte, Manisha, and Lal, Hind

Abstract

With an estimated 38 million current patients, heart failure (HF) is a leading cause of morbidity and mortality worldwide. Although the aetiology differs, HF is largely a disease of cardiomyocyte (CM) death or dysfunction. Due to the famously limited amount of regenerative capacity of the myocardium, the only viable option for advanced HF patients is cardiac transplantation; however, donor's hearts are in very short supply. Thus, novel regenerative strategies are urgently needed to reconstitute the injured hearts. Emerging data from our lab and others have elucidated that CM-specific deletion of glycogen synthase kinase (GSK)-3 family of kinases induces CM proliferation, and the degree of proliferation is amplified in the setting of cardiac stress. If this proliferation is sufficiently robust, one could induce meaningful regeneration without the need for delivering exogenous cells to the injured myocardium (i.e. cardiac regeneration in situ). Herein, we will discuss the emerging role of the GSK-3s in CM proliferation and differentiation, including their potential implications in cardiac regeneration. The underlying molecular interactions and cross-talk among signalling pathways will be discussed. We will also review the specificity and limitations of the available small molecule inhibitors targeting GSK-3 and their potential applications to stimulate the endogenous cardiac regenerative responses to repair the injured heart. [ABSTRACT FROM AUTHOR]

Published
2019
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27. Analysis of Tyrosine Kinase Inhibitor-Mediated Decline in Contractile Force in Rat Engineered Heart Tissue

Author

Jacob, Fabian, Yonis, Amina Y., Cuello, Friederike, Luther, Pradeep, Schulze, Thomas, Eder, Alexandra, Streichert, Thomas, Mannhardt, Ingra, Hirt, Marc N., Schaaf, Sebastian, Stenzig, Justus, Force, Thomas, Eschenhagen, Thomas, Hansen, Arne, Jacob, Fabian, Yonis, Amina Y., Cuello, Friederike, Luther, Pradeep, Schulze, Thomas, Eder, Alexandra, Streichert, Thomas, Mannhardt, Ingra, Hirt, Marc N., Schaaf, Sebastian, Stenzig, Justus, Force, Thomas, Eschenhagen, Thomas, and Hansen, Arne

Abstract

Introduction Left ventricular dysfunction is a frequent and potentially severe side effect of many tyrosine kinase inhibitors (TKI). The mode of toxicity is not identified, but may include impairment of mitochondrial or sarcomeric function, autophagy or angiogenesis, either as an on-target or off-target mechanism. Methods and Results We studied concentration-response curves and time courses for nine TKIs in three-dimensional, force generating engineered heart tissue (EHT) from neonatal rat heart cells. We detected a concentration-and time-dependent decline in contractile force for gefitinib, lapatinib, sunitinib, imatinib, sorafenib, vandetanib and lestaurtinib and no decline in contractile force for erlotinib and dasatinib after 96 hours of incubation. The decline in contractile force was associated with an impairment of autophagy (LC3 Western blot) and appearance of autophagolysosomes (transmission electron microscopy). Conclusion This study demonstrates the feasibility to study TKI-mediated force effects in EHTs and identifies an association between a decline in contractility and inhibition of autophagic flux.

Published
2016

32. Loss of Adult Cardiac Myocyte GSK-3 Leads to Mitotic Catastrophe Resulting in Fatal Dilated Cardiomyopathy

Author

Zhou, Jibin, primary, Ahmad, Firdos, additional, Parikh, Shan, additional, Hoffman, Nichole E., additional, Rajan, Sudarsan, additional, Verma, Vipin K., additional, Song, Jianliang, additional, Yuan, Ancai, additional, Shanmughapriya, Santhanam, additional, Guo, Yuanjun, additional, Gao, Erhe, additional, Koch, Walter, additional, Woodgett, James R., additional, Madesh, Muniswamy, additional, Kishore, Raj, additional, Lal, Hind, additional, and Force, Thomas, additional

Published
2016
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33. Analysis of Tyrosine Kinase Inhibitor-Mediated Decline in Contractile Force in Rat Engineered Heart Tissue

Author

Jacob, Fabian, primary, Yonis, Amina Y., additional, Cuello, Friederike, additional, Luther, Pradeep, additional, Schulze, Thomas, additional, Eder, Alexandra, additional, Streichert, Thomas, additional, Mannhardt, Ingra, additional, Hirt, Marc N., additional, Schaaf, Sebastian, additional, Stenzig, Justus, additional, Force, Thomas, additional, Eschenhagen, Thomas, additional, and Hansen, Arne, additional

Published
2016
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34. Introducing JACC: Basic to Translational Science

Author

Mann, Douglas L., primary, Annex, Brian H., additional, Bishopric, Nanette H., additional, Force, Thomas, additional, Kelly, Daniel P., additional, Libby, Peter, additional, Roberts, Robert, additional, van Rooij, Eva, additional, Tomaselli, Gordon, additional, and Newby, L. Kristin, additional

Published
2016
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35. Cardio-Oncology

Author

Bellinger, Andrew M., primary, Arteaga, Carlos L., additional, Force, Thomas, additional, Humphreys, Benjamin D., additional, Demetri, George D., additional, Druker, Brian J., additional, and Moslehi, Javid J., additional

Published
2015
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36. Colaboradores

Author

Aaronson, Keith D., Abraham, William T., Acker, Michael A., Ackerman, Michael J., Antman, Elliott M., Baddour, Larry M., Baggish, Aaron, Noel Bairey Merz, C., Balady, Gary J., Beckman, Joshua A., Bers, Donald M., Bettman, Michael A., Bhatt, Deepak L., Boden, William E., Bonow, Robert O., Braunwald, Eugene, Braverman, Alan C., Douglas Bremner, J., Buring, Julie E., Calkins, Hugh G., Cannon, Christopher P., Canty, John M., Jr., Carroll, John D., Castellanos, Augustin, Chen, Ming Hui, Cooper, Leslie T., Jr., Creager, Mark A., Davidson, Charles J., Devries, Stephen, Dickert, Neal W., Dilsizian, Vasken, Duncker, Dirk J., Emanuel, Ezekiel J., Falk, Rodney H., Fang, James C., Michael Felker, G., Fisher, Stacy D., Fleisher, Lee A., Force, Thomas, Freeman, William K., Michael Gaziano, J., Gaziano, Thomas A., Genest, Jacques, Gerszten, Robert E., Gillam, Linda, Ginsburg, Geoffrey S., Giugliano, Robert P., Goldberger, Ary L., Goldhaber, Samuel Z., Goldstein, Larry B., Goodlin, Sarah J., Groh, William J., Gulati, Martha, Hajjar, Roger J., Hare, Joshua M., Hasenfuss, Gerd, Hershberger, Ray E., David Hillis, L., Hopkins, William E., Humbert, Marc, Januzzi, James L., Jr., Jessup, Mariell, Kathiresan, Sekar, Kinlay, Scott, Klein, Irwin, Knowlton, Kirk U., Krumholz, Harlan M., Kwong, Raymond Y., Lange, Richard A., Lee, Thomas H., Lenihan, Daniel J., LeWinter, Martin M., Libby, Peter, Lipshultz, Steven E., Little, William C., Mann, Douglas L., Maron, Barry J., Mason, Justin C., Masoudi, Frederick A., Mattox, Kenneth L., Mauri, Laura, Mayosi, Bongani M., McCullough, Peter A., McGuire, Darren K., McLaughlin, Vallerie V., Mega, Jessica L., Miller, John M., Mirvis, David M., Morady, Fred, Morise, Anthony P., Morrow, David A., Mozaffarian, Dariush, Musunuru, Kiran, Myerburg, Robert J., O’Gara, Patrick T., Olgin, Jeffrey E., Olivotto, Iacopo, Opie, Lionel H., Otto, Catherine M., Pagani, Francis D., Piña, Ileana L., Popma, Jeffrey J., Prabhakaran, Dorairaj, Redington, Andrew N., Ridker, Paul M, Roden, Dan M., Rubart, Michael, Rumsfeld, John S., Sabatine, Marc S., Schwartz, Janice B., Scirica, Benjamin M., Smallhorn, Jeffrey F., Solomon, Scott D., Somers, Virend K., Suri, Rakesh M., Swerdlow, Charles D., Taylor, Allen J., Taylor, Anne L., Teerlink, John R., Tester, David J., Therrien, Judith, Thompson, Paul D., Tsai, Peter I., Udelson, James E., Vaccarino, Viola, Victor, Ronald G., Wall, Matthew J., Jr., Wang, Paul J., Warnes, Carole A., Webb, Gary D., Webb, John G., Weitz, Jeffrey I., Wilson, Walter R., Wright, Jackson T., Yusuf, Syed Wamique, Wiviott, Stephen D., Wu, Justina, Zile, Michael R., and Zipes, Douglas P.

Published
2018

39. Colaboradores

Author

Aaronson, Keith D., Abraham, William T., Acker, Michael A., Ackerman, Michael J., Antman, Elliott M., Baddour, Larry M., Baggish, Aaron, Bairey Merz, C. Noel, Balady, Gary J., Beckman, Joshua A., Bers, Donald M., Bettman, Michael A., Bhatt, Deepak L., Boden, William E., Bonow, Robert O., Braunwald, Eugene, Braverman, Alan C., Bremner, J. Douglas, Buring, Julie E., Calkins, Hugh G., Cannon, Christopher P., Canty, John M., Jr., Carroll, John D., Castellanos, Augustin, Chen, Ming Hui, Cooper, Leslie T., Jr., Creager, Mark A., Davidson, Charles J., Devries, Stephen, Dickert, Neal W., Dilsizian, Vasken, Duncker, Dirk J., Emanuel, Ezekiel J., Falk, Rodney H., Fang, James C., Felker, G. Michael, Fisher, Stacy D., Fleisher, Lee A., Force, Thomas, Freeman, William K., Gaziano, J. Michael, Gaziano, Thomas A., Genest, Jacques, Gerszten, Robert E., Gillam, Linda, Ginsburg, Geoffrey S., Giugliano, Robert P., Goldberger, Ary L., Goldhaber, Samuel Z., Goldstein, Larry B., Goodlin, Sarah J., Groh, William J., Gulati, Martha, Hajjar, Roger J., Hare, Joshua M., Hasenfuss, Gerd, Hershberger, Ray E., Hillis, L. David, Hopkins, William E., Humbert, Marc, Januzzi, James L., Jr., Jessup, Mariell, Kathiresan, Sekar, Kinlay, Scott, Klein, Irwin, Knowlton, Kirk U., Krumholz, Harlan M., Kwong, Raymond Y., Lange, Richard A., Lee, Thomas H., Lenihan, Daniel J., LeWinter, Martin M., Libby, Peter, Lipshultz, Steven E., Little, William C., Mann, Douglas L., Maron, Barry J., Mason, Justin C., Masoudi, Frederick A., Mattox, Kenneth L., Mauri, Laura, Mayosi, Bongani M., McCullough, Peter A., McGuire, Darren K., McLaughlin, Vallerie V., Mega, Jessica L., Miller, John M., Mirvis, David M., Morady, Fred, Morise, Anthony P., Morrow, David A., Mozaffarian, Dariush, Musunuru, Kiran, Myerburg, Robert J., O’Gara, Patrick T., Olgin, Jeffrey E., Olivotto, Iacopo, Opie, Lionel H., Otto, Catherine M., Pagani, Francis D., Piña, Ileana L., Popma, Jeffrey J., Prabhakaran, Dorairaj, Redington, Andrew N., Ridker, Paul M., Roden, Dan M., Rubart, Michael, Rumsfeld, John S., Sabatine, Marc S., Schwartz, Janice B., Scirica, Benjamin M., Smallhorn, Jeffrey F., Solomon, Scott D., Somers, Virend K., Suri, Rakesh M., Swerdlow, Charles D., Taylor, Allen J., Taylor, Anne L., Teerlink, John R., Tester, David J., Therrien, Judith, Thompson, Paul D., Tsai, Peter I., Udelson, James E., Vaccarino, Viola, Victor, Ronald G., Wall, Matthew J., Jr., Wang, Paul J., Warnes, Carole A., Webb, Gary D., Webb, John G., Weitz, Jeffrey I., Wilson, Walter R., Wright, Jackson T., Wamique Yusuf, Syed, Wiviott, Stephen D., Wu, Justina, Zile, Michael R., and Zipes, Douglas P.

Published
2016
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42. Group IVA Cytosolic Phospholipase A2 Regulates the G2-to-M Transition by Modulating the Activity of Tumor Suppressor SIRT2.

Author

Naini, Said Movahedi, Sheridan, Alice M., Force, Thomas, Shah, Jagesh V., and Bonventre, Joseph V.

Subjects
TUMOR suppressor proteins, TUMOR suppressor genes, PHOSPHOLIPASES, CYCLIN genetics, CENTROSOMES, OXIDATIVE phosphorylation
Abstract

The G2-to-M transition (or prophase) checkpoint of the cell cycle is a critical regulator of mitotic entry. SIRT2, a tumor suppressor gene, contributes to the control of this checkpoint by blocking mitotic entry under cellular stress. However, the mechanism underlying both SIRT2 activation and regulation of the G2-to-M transition remains largely unknown. Here, we report the formation of a multiprotein complex at the G2-to-M transition in vitro and in vivo. Group IVA cytosolic phospholipase A2 (cPLA2α) acts as a bridge in this complex to promote binding of SIRT2 to cyclin A-Cdk2. Cyclin A-Cdk2 then phosphorylates SIRT2 at Ser331. This phosphorylation reduces SIRT2 catalytic activity and its binding affinity to centrosomes and mitotic spindles, promoting G2-to-M transition. We show that the inhibitory effect of cPLA2α on SIRT2 activity impacts various cellular processes, including cellular levels of histone H4 acetylated at K16 (Ac-H4K16) and Ac-α-tubulin. This regulatory effect of cPLA2α on SIRT2 defines a novel function of cPLA2α independent of its phospholipase activity and may have implications for the impact of SIRT2-related effects on tumorigenesis and age-related diseases. [ABSTRACT FROM AUTHOR]

Published
2015
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44. Rab-GTPase binding effector protein 2 (RABEP2) is a primed substrate for Glycogen Synthase kinase-3 (GSK3).

Author

Logie L, Van Aalten L, Knebel A, Force T, Hastie CJ, MacLauchlan H, Campbell DG, Gourlay R, Prescott A, Davidson J, Fuller W, and Sutherland C

Subjects
Animals, Biomarkers metabolism, Cells, Cultured, HEK293 Cells, Humans, Male, Phosphorylation drug effects, Protein Binding drug effects, Protein Kinase Inhibitors pharmacology, Rats, Rats, Sprague-Dawley, rab5 GTP-Binding Proteins metabolism, Glycogen Synthase Kinases metabolism, Vesicular Transport Proteins metabolism
Abstract

Glycogen synthase kinase-3 (GSK3) regulates many physiological processes through phosphorylation of a diverse array of substrates. Inhibitors of GSK3 have been generated as potential therapies in several diseases, however the vital role GSK3 plays in cell biology makes the clinical use of GSK3 inhibitors potentially problematic. A clearer understanding of true physiological and pathophysiological substrates of GSK3 should provide opportunities for more selective, disease specific, manipulation of GSK3. To identify kinetically favourable substrates we performed a GSK3 substrate screen in heart tissue. Rab-GTPase binding effector protein 2 (RABEP2) was identified as a novel GSK3 substrate and GSK3 phosphorylation of RABEP2 at Ser200 was enhanced by prior phosphorylation at Ser204, fitting the known consensus sequence for GSK3 substrates. Both residues are phosphorylated in cells while only Ser200 phosphorylation is reduced following inhibition of GSK3. RABEP2 function was originally identified as a Rab5 binding protein. We did not observe co-localisation of RABEP2 and Rab5 in cells, while ectopic expression of RABEP2 had no effect on endosomal recycling. The work presented identifies RABEP2 as a novel primed substrate of GSK3, and thus a potential biomarker for GSK3 activity, but understanding how phosphorylation regulates RABEP2 function requires more information on physiological roles of RABEP2.

Published
2017
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45. A Novel Positron Emission Tomography (PET) Approach to Monitor Cardiac Metabolic Pathway Remodeling in Response to Sunitinib Malate.

Author

O'Farrell AC, Evans R, Silvola JM, Miller IS, Conroy E, Hector S, Cary M, Murray DW, Jarzabek MA, Maratha A, Alamanou M, Udupi GM, Shiels L, Pallaud C, Saraste A, Liljenbäck H, Jauhiainen M, Oikonen V, Ducret A, Cutler P, McAuliffe FM, Rousseau JA, Lecomte R, Gascon S, Arany Z, Ky B, Force T, Knuuti J, Gallagher WM, Roivainen A, and Byrne AT

Subjects
Animals, Fluorodeoxyglucose F18 therapeutic use, Heart drug effects, Humans, Indoles administration & dosage, Male, Myocardium metabolism, Myocardium pathology, Proteomics, Pyrroles administration & dosage, Rats, Rats, Sprague-Dawley, Sunitinib, Ventricular Function, Left drug effects, Heart diagnostic imaging, Indoles adverse effects, Metabolic Networks and Pathways drug effects, Positron-Emission Tomography, Pyrroles adverse effects
Abstract

Sunitinib is a tyrosine kinase inhibitor approved for the treatment of multiple solid tumors. However, cardiotoxicity is of increasing concern, with a need to develop rational mechanism driven approaches for the early detection of cardiac dysfunction. We sought to interrogate changes in cardiac energy substrate usage during sunitinib treatment, hypothesising that these changes could represent a strategy for the early detection of cardiotoxicity. Balb/CJ mice or Sprague-Dawley rats were treated orally for 4 weeks with 40 or 20 mg/kg/day sunitinib. Cardiac positron emission tomography (PET) was implemented to investigate alterations in myocardial glucose and oxidative metabolism. Following treatment, blood pressure increased, and left ventricular ejection fraction decreased. Cardiac [18F]-fluorodeoxyglucose (FDG)-PET revealed increased glucose uptake after 48 hours. [11C]Acetate-PET showed decreased myocardial perfusion following treatment. Electron microscopy revealed significant lipid accumulation in the myocardium. Proteomic analyses indicated that oxidative metabolism, fatty acid β-oxidation and mitochondrial dysfunction were among the top myocardial signalling pathways perturbed. Sunitinib treatment results in an increased reliance on glycolysis, increased myocardial lipid deposition and perturbed mitochondrial function, indicative of a fundamental energy crisis resulting in compromised myocardial energy metabolism and function. Our findings suggest that a cardiac PET strategy may represent a rational approach to non-invasively monitor metabolic pathway remodeling following sunitinib treatment., Competing Interests: There are no competing interests associated with the publication of this manuscript and the commercial affiliations do not alter our adherence to PLOS ONE policies on sharing data and materials.

Published
2017
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