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2. Gap Junctions and Ageing

Author

Zeitz, Michael J., Smyth, James W., Harris, J. Robin, Series Editor, Kundu, Tapas K., Advisory Editor, Korolchuk, Viktor, Advisory Editor, Bolanos-Garcia, Victor, Advisory Editor, Marles-Wright, Jon, Advisory Editor, and Korolchuk, Viktor I., editor

Published
2023
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7. Acute Adenoviral Infection Elicits an Arrhythmogenic Substrate Prior to Myocarditis

Author

Padget, Rachel L., primary, Zeitz, Michael J., additional, Blair, Grace A., additional, Wu, Xiaobo, additional, North, Michael D., additional, Tanenbaum, Mira T., additional, Stanley, Kari E., additional, Phillips, Chelsea M., additional, King, D. Ryan, additional, Lamouille, Samy, additional, Gourdie, Robert G., additional, Hoeker, Gregory S., additional, Swanger, Sharon A., additional, Poelzing, Steven, additional, and Smyth, James W., additional

Published
2024
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9. Extracellular Perinexal Separation Is a Principal Determinant of Cardiac Conduction

Author

Adams, William P., primary, Raisch, Tristan B., additional, Zhao, Yajun, additional, Davalos, Rafael, additional, Barrett, Sarah, additional, King, D. Ryan, additional, Bain, Chandra B., additional, Colucci-Chang, Katrina, additional, Blair, Grace A., additional, Hanlon, Alexandra, additional, Lozano, Alicia, additional, Veeraraghavan, Rengasayee, additional, Wan, Xiaoping, additional, Deschenes, Isabelle, additional, Smyth, James W., additional, Hoeker, Gregory S., additional, Gourdie, Robert G., additional, and Poelzing, Steven, additional

Published
2023
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19. Additional file 1 of Folate regulates RNA m5C modification and translation in neural stem cells

Author

Xu, Xiguang, Johnson, Zachary, Wang, Amanda, Padget, Rachel L., Smyth, James W., and Xie, Hehuang

Abstract

Additional file 1: Figure S1. Quality control of total mRNA-seq datasets. (a, b, c) Scatter plot showing the Pearson correlation between two biological replicates in total mRNA-seq datasets in NSCs. (d) Principal component analysis of total mRNA-seq datasets. Figure S2. Validation of differentially expressed genes (DEGs). (a-g) RT-qPCR was performed to validate the expression of DEGs identified by RNA-seq. (*

Published
2022
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23. Virology

Author

Rai, Pallavi, Chuong, Christina, LeRoith, Tanya, Smyth, James W., Panov, Julia, Levi, Moshe, Kehn-Hall, Kylene, Duggal, Nisha K., and Weger-Lucarelli, James

Subjects
Male, viruses, Comorbidity, Replication-defective adenovirus, Mice, Virology, 07 Agricultural and Veterinary Sciences, Chlorocebus aethiops, Pathology, Animals, Humans, Obesity, Vero Cells, 11 Medical and Health Sciences, SYNDROME CORONAVIRUS INFECTION, SARS, Tissue, IMMUNE-RESPONSES, MORTALITY, Diet-induced obesity, COVID-19, hACE2, 06 Biological Sciences, Mice, Inbred C57BL, Disease Models, Animal, HEK293 Cells, Female, Morbidity, Life Sciences & Biomedicine, ACUTE RESPIRATORY SYNDROME
Abstract

The COVID-19 pandemic has paralyzed the global economy and resulted in millions of deaths globally. People with co-morbidities like obesity, diabetes and hypertension are at an increased risk for severe COVID-19 illness. This is of overwhelming concern because 42% of Americans are obese, 30% are pre-diabetic and 9.4% have clinical diabetes. Here, we investigated the effect of obesity on disease severity following SARS-CoV-2 infection using a well-established mouse model of diet-induced obesity. Diet-induced obese and lean control C57BL/6 N mice, transduced for ACE2 expression using replication-defective adenovirus, were infected with SARS-CoV-2, and monitored for lung pathology, viral titers, and cytokine expression. No significant differences in tissue pathology or viral replication was observed between AdV transduced lean and obese groups, infected with SARS-CoV-2, but certain cytokines were expressed more significantly in infected obese mice compared to the lean ones. Notably, significant weight loss was observed in obese mice treated with the adenovirus vector, independent of SARS-CoV-2 infection, suggesting an obesity-dependent morbidity induced by the vector. These data indicate that the adenovirus-transduced mouse model of SARS-CoV-2 infection, as described here and elsewhere, may be inappropriate for nutrition studies. Published version

Published
2021

25. Folate regulates RNA m5C modification and translation in neural stem cells.

Author

Xu, Xiguang, Johnson, Zachary, Wang, Amanda, Padget, Rachel L., Smyth, James W., and Xie, Hehuang

Subjects
NEURAL stem cells, FOLIC acid, RNA modification & restriction, TRANSFER RNA, RNA methylation, DNA methylation, CELL proliferation
Abstract

Background: Folate is an essential B-group vitamin and a key methyl donor with important biological functions including DNA methylation regulation. Normal neurodevelopment and physiology are sensitive to the cellular folate levels. Either deficiency or excess of folate may lead to neurological disorders. Recently, folate has been linked to tRNA cytosine-5 methylation (m5C) and translation in mammalian mitochondria. However, the influence of folate intake on neuronal mRNA m5C modification and translation remains largely unknown. Here, we provide transcriptome-wide landscapes of m5C modification in poly(A)-enriched RNAs together with mRNA transcription and translation profiles for mouse neural stem cells (NSCs) cultured in three different concentrations of folate. Results: NSCs cultured in three different concentrations of folate showed distinct mRNA methylation profiles. Despite uncovering only a few differentially expressed genes, hundreds of differentially translated genes were identified in NSCs with folate deficiency or supplementation. The differentially translated genes induced by low folate are associated with cytoplasmic translation and mitochondrial function, while the differentially translated genes induced by high folate are associated with increased neural stem cell proliferation. Interestingly, compared to total mRNAs, polysome mRNAs contained high levels of m5C. Furthermore, an integrative analysis indicated a transcript-specific relationship between RNA m5C methylation and mRNA translation efficiency. Conclusions: Altogether, our study reports a transcriptome-wide influence of folate on mRNA m5C methylation and translation in NSCs and reveals a potential link between mRNA m5C methylation and mRNA translation. [ABSTRACT FROM AUTHOR]

Published
2022
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26. Adenovirus transduction to express human ACE2 causes obesity-specific morbidity in mice, impeding studies on the effect of host nutritional status on SARS-CoV-2 pathogenesis

Author

Rai, Pallavi, Chuong, Christina, LeRoith, Tanya, Smyth, James W., Panov, Julia, Levi, Moshe, Kehn-Hall, Kylene, Duggal, Nisha K., Weger-Lucarelli, James, Rai, Pallavi, Chuong, Christina, LeRoith, Tanya, Smyth, James W., Panov, Julia, Levi, Moshe, Kehn-Hall, Kylene, Duggal, Nisha K., and Weger-Lucarelli, James

Abstract

The COVID-19 pandemic has paralyzed the global economy and resulted in millions of deaths globally. People with co-morbidities like obesity, diabetes and hypertension are at an increased risk for severe COVID-19 illness. This is of overwhelming concern because 42% of Americans are obese, 30% are pre-diabetic and 9.4% have clinical diabetes. Here, we investigated the effect of obesity on disease severity following SARS-CoV-2 infection using a well-established mouse model of diet-induced obesity. Diet-induced obese and lean control C57BL/6 N mice, transduced for ACE2 expression using replication-defective adenovirus, were infected with SARS-CoV-2, and monitored for lung pathology, viral titers, and cytokine expression. No significant differences in tissue pathology or viral replication was observed between AdV transduced lean and obese groups, infected with SARS-CoV-2, but certain cytokines were expressed more significantly in infected obese mice compared to the lean ones. Notably, significant weight loss was observed in obese mice treated with the adenovirus vector, independent of SARS-CoV-2 infection, suggesting an obesity-dependent morbidity induced by the vector. These data indicate that the adenovirus-transduced mouse model of SARS-CoV-2 infection, as described here and elsewhere, may be inappropriate for nutrition studies.

Published
2021
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27. Progression-Mediated Changes in Mitochondrial Morphology Promotes Adaptation to Hypoxic Peritoneal Conditions in Serous Ovarian Cancer

Author

Grieco, Joseph P., Allen, Mitchell E., Perry, Justin B., Wang, Yao, Song, Yipei, Rohani, Ali, Compton, Stephanie L. E., Smyth, James W., Swami, Nathan S., Brown, David A., Schmelz, Eva M., Grieco, Joseph P., Allen, Mitchell E., Perry, Justin B., Wang, Yao, Song, Yipei, Rohani, Ali, Compton, Stephanie L. E., Smyth, James W., Swami, Nathan S., Brown, David A., and Schmelz, Eva M.

Abstract

Ovarian cancer is the deadliest gynecological cancer in women, with a survival rate of less than 30% when the cancer has spread throughout the peritoneal cavity. Aggregation of cancer cells increases their viability and metastatic potential; however, there are limited studies that correlate these functional changes to specific phenotypic alterations. In this study, we investigated changes in mitochondrial morphology and dynamics during malignant transition using our MOSE cell model for progressive serous ovarian cancer. Mitochondrial morphology was changed with increasing malignancy from a filamentous network to single, enlarged organelles due to an imbalance of mitochondrial dynamic proteins (fusion: MFN1/OPA1, fission: DRP1/FIS1). These phenotypic alterations aided the adaptation to hypoxia through the promotion of autophagy and were accompanied by changes in the mitochondrial ultrastructure, mitochondrial membrane potential, and the regulation of reactive oxygen species (ROS) levels. The tumor-initiating cells increased mitochondrial fragmentation after aggregation and exposure to hypoxia that correlated well with our previously observed reduced growth and respiration in spheroids, suggesting that these alterations promote viability in non-permissive conditions. Our identification of such mitochondrial phenotypic changes in malignancy provides a model in which to identify targets for interventions aimed at suppressing metastases.

Published
2021
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28. Progression-Mediated Changes in Mitochondrial Morphology Promotes Adaptation to Hypoxic Peritoneal Conditions in Serous Ovarian Cancer

Author

Human Nutrition, Foods, and Exercise, Fralin Biomedical Research Institute, Biological Sciences, Virginia Tech Carilion School of Medicine, Grieco, Joseph P., Allen, Mitchell E., Perry, Justin B., Wang, Yao, Song, Yipei, Rohani, Ali, Compton, Stephanie L. E., Smyth, James W., Swami, Nathan S., Brown, David A., Schmelz, Eva M., Human Nutrition, Foods, and Exercise, Fralin Biomedical Research Institute, Biological Sciences, Virginia Tech Carilion School of Medicine, Grieco, Joseph P., Allen, Mitchell E., Perry, Justin B., Wang, Yao, Song, Yipei, Rohani, Ali, Compton, Stephanie L. E., Smyth, James W., Swami, Nathan S., Brown, David A., and Schmelz, Eva M.

Abstract

Ovarian cancer is the deadliest gynecological cancer in women, with a survival rate of less than 30% when the cancer has spread throughout the peritoneal cavity. Aggregation of cancer cells increases their viability and metastatic potential; however, there are limited studies that correlate these functional changes to specific phenotypic alterations. In this study, we investigated changes in mitochondrial morphology and dynamics during malignant transition using our MOSE cell model for progressive serous ovarian cancer. Mitochondrial morphology was changed with increasing malignancy from a filamentous network to single, enlarged organelles due to an imbalance of mitochondrial dynamic proteins (fusion: MFN1/OPA1, fission: DRP1/FIS1). These phenotypic alterations aided the adaptation to hypoxia through the promotion of autophagy and were accompanied by changes in the mitochondrial ultrastructure, mitochondrial membrane potential, and the regulation of reactive oxygen species (ROS) levels. The tumor-initiating cells increased mitochondrial fragmentation after aggregation and exposure to hypoxia that correlated well with our previously observed reduced growth and respiration in spheroids, suggesting that these alterations promote viability in non-permissive conditions. Our identification of such mitochondrial phenotypic changes in malignancy provides a model in which to identify targets for interventions aimed at suppressing metastases.

Published
2021

30. Translating Translation to Mechanisms of Cardiac Hypertrophy

Author

Zeitz, Michael J., Smyth, James W., Zeitz, Michael J., and Smyth, James W.

Abstract

Cardiac hypertrophy in response to chronic pathological stress is a common feature occurring with many forms of heart disease. This pathological hypertrophic growth increases the risk for arrhythmias and subsequent heart failure. While several factors promoting cardiac hypertrophy are known, the molecular mechanisms governing the progression to heart failure are incompletely understood. Recent studies on altered translational regulation during pathological cardiac hypertrophy are contributing to our understanding of disease progression. In this brief review, we describe how the translational machinery is modulated for enhanced global and transcript selective protein synthesis, and how alternative modes of translation contribute to the disease state. Attempts at controlling translational output through targeting of mTOR and its regulatory components are detailed, as well as recently emerging targets for pre-clinical investigation.

Published
2020
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31. Translating Translation to Mechanisms of Cardiac Hypertrophy

Author

Biological Sciences, Fralin Biomedical Research Institute, Virginia Tech Carilion School of Medicine, Zeitz, Michael J., Smyth, James W., Biological Sciences, Fralin Biomedical Research Institute, Virginia Tech Carilion School of Medicine, Zeitz, Michael J., and Smyth, James W.

Abstract

Cardiac hypertrophy in response to chronic pathological stress is a common feature occurring with many forms of heart disease. This pathological hypertrophic growth increases the risk for arrhythmias and subsequent heart failure. While several factors promoting cardiac hypertrophy are known, the molecular mechanisms governing the progression to heart failure are incompletely understood. Recent studies on altered translational regulation during pathological cardiac hypertrophy are contributing to our understanding of disease progression. In this brief review, we describe how the translational machinery is modulated for enhanced global and transcript selective protein synthesis, and how alternative modes of translation contribute to the disease state. Attempts at controlling translational output through targeting of mTOR and its regulatory components are detailed, as well as recently emerging targets for pre-clinical investigation.

Published
2020

32. Elevated perfusate [Na+] increases contractile dysfunction during ischemia and reperfusion

Author

Human Nutrition, Foods, and Exercise, Fralin Biomedical Research Institute, Virginia Tech Carilion School of Medicine, Biomedical Engineering and Mechanics, Biological Sciences, King, D. Ryan, Padget, Rachel L., Perry, Justin B., Hoeker, Gregory S., Smyth, James W., Brown, David A., Poelzing, Steven, Human Nutrition, Foods, and Exercise, Fralin Biomedical Research Institute, Virginia Tech Carilion School of Medicine, Biomedical Engineering and Mechanics, Biological Sciences, King, D. Ryan, Padget, Rachel L., Perry, Justin B., Hoeker, Gregory S., Smyth, James W., Brown, David A., and Poelzing, Steven

Abstract

Recent studies revealed that relatively small changes in perfusate sodium ([Na+](o)) composition significantly affect cardiac electrical conduction and stability in contraction arrested ex vivo Langendorff heart preparations before and during simulated ischemia. Additionally, [Na+](o) modulates cardiomyocyte contractility via a sodium-calcium exchanger (NCX) mediated pathway. It remains unknown, however, whether modest changes to [Na+](o) that promote electrophysiologic stability similarly improve mechanical function during baseline and ischemia-reperfusion conditions. The purpose of this study was to quantify cardiac mechanical function during ischemia-reperfusion with perfusates containing 145 or 155 mM Na+ in Langendorff perfused isolated rat heart preparations. Relative to 145 mM Na+, perfusion with 155 mM [Na+](o) decreased the amplitude of left-ventricular developed pressure (LVDP) at baseline and accelerated the onset of ischemic contracture. Inhibiting NCX with SEA0400 abolished LVDP depression caused by increasing [Na+](o) at baseline and reduced the time to peak ischemic contracture. Ischemia-reperfusion decreased LVDP in all hearts with return of intrinsic activity, and reperfusion with 155 mM [Na+](o) further depressed mechanical function. In summary, elevating [Na+](o) by as little as 10 mM can significantly modulate mechanical function under baseline conditions, as well as during ischemia and reperfusion. Importantly, clinical use of Normal Saline, which contains 155 mM [Na+](o), with cardiac ischemia may require further investigation.

Published
2020

33. Progression-Mediated Changes in Mitochondrial Morphology Promotes Adaptation to Hypoxic Peritoneal Conditions in Serous Ovarian Cancer

Author

Grieco, Joseph P., primary, Allen, Mitchell E., additional, Perry, Justin B., additional, Wang, Yao, additional, Song, Yipei, additional, Rohani, Ali, additional, Compton, Stephanie L. E., additional, Smyth, James W., additional, Swami, Nathan S., additional, Brown, David A., additional, and Schmelz, Eva M., additional

Published
2021
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38. Dynamic UTR Usage Regulates Alternative Translation to Modulate Gap Junction Formation during Stress and Aging

Author

Zeitz, Michael J., Calhoun, Patrick J., James, Carissa C., Taetzsch, Thomas, George, Kijana K., Robel, Stefanie, Valdez, Gregorio, and Smyth, James W.

Subjects
education, health care economics and organizations
Abstract

Connexin43 (Cx43; gene name GJA1) is the most ubiquitously expressed gap junction protein, and understanding of its regulation largely falls under transcription and post-translational modification. In addition to Cx43, Gja1 mRNA encodes internally translated isoforms regulating gap junction formation, whose expression is modulated by TGF-b. Here, using RLM-RACE, we identify distinct Gja1 transcripts differing only in 50 UTR length, of which two are upregulated during TGF-b exposure and hypoxia. Introduction of these transcripts into Gja1/ cells phenocopies the response of Gja1 to TGF-b with reduced internal translation initiation. Inhibiting pathways downstream of TGF-b selectively regulates levels of Gja1 transcript isoforms and translation products. Reporter assays reveal enhanced translation of fulllength Cx43 from shorter Gja1 50 UTR isoforms. We also observe a correlation among UTR selection, translation, and reduced gap junction formation in aged heart tissue. These data elucidate a relationship between transcript isoform expression and translation initiation regulating intercellular communication. This work was supported by an NIH NHLBI R01 grant (HL132236 to J.W.S.), NHLBI F31 grant (HL140909 to C.C.J.), NIA R01 grant (AG055545 to G.V.), NINDS R21 grant (NS106313 to G.V.), NINDS R01 grant (NS105807 to S.R.), NINDS R21 grant (NS107941 to S.R.), and the American Heart Association (18PRE33960573 to P.J.C.). Funding for open access charge: NIH.

Published
2019

39. Modulating cardiac conduction during metabolic ischemia with perfusate sodium and calcium in guinea pig hearts

Author

George, Sharon A, Hoeker, Gregory, Calhoun, Patrick J, Entz, Michael, Raisch, Tristan B, King, D Ryan, Khan, Momina, Baker, Chandra, Gourdie, Robert G, Smyth, James W, Nielsen, Morten S, Poelzing, Steven, George, Sharon A, Hoeker, Gregory, Calhoun, Patrick J, Entz, Michael, Raisch, Tristan B, King, D Ryan, Khan, Momina, Baker, Chandra, Gourdie, Robert G, Smyth, James W, Nielsen, Morten S, and Poelzing, Steven

Abstract

We previously demonstrated that altering extracellular sodium (Nao) and calcium (Cao) can modulate a form of electrical communication between cardiomyocytes termed "ephaptic coupling" (EpC), especially during loss of gap junction coupling. We hypothesized that altering Nao and Cao modulates conduction velocity (CV) and arrhythmic burden during ischemia. Electrophysiology was quantified by optically mapping Langendorff-perfused guinea pig ventricles with modified Nao (147 or 155 mM) and Cao (1.25 or 2.0 mM) during 30 min of simulated metabolic ischemia (pH 6.5, anoxia, aglycemia). Gap junction-adjacent perinexal width ( WP), a candidate cardiac ephapse, and connexin (Cx)43 protein expression and Cx43 phosphorylation at S368 were quantified by transmission electron microscopy and Western immunoblot analysis, respectively. Metabolic ischemia slowed CV in hearts perfused with 147 mM Nao and 2.0 mM Cao; however, theoretically increasing EpC with 155 mM Nao was arrhythmogenic, and CV could not be measured. Reducing Cao to 1.25 mM expanded WP, as expected during ischemia, consistent with reduced EpC, but attenuated CV slowing while delaying arrhythmia onset. These results were further supported by osmotically reducing WP with albumin, which exacerbated CV slowing and increased early arrhythmias during ischemia, whereas mannitol expanded WP, permitted conduction, and delayed the onset of arrhythmias. Cx43 expression patterns during the various interventions insufficiently correlated with observed CV changes and arrhythmic burden. In conclusion, decreasing perfusate calcium during metabolic ischemia enhances perinexal expansion, attenuates conduction slowing, and delays arrhythmias. Thus, perinexal expansion may be cardioprotective during metabolic ischemia. NEW & NOTEWORTHY This study demonstrates, for the first time, that modulating perfusate ion composition can alter cardiac electrophysiology during simulated metabolic ischemia.

Published
2019

40. Contributors

Author

Abrams, Dominic, Abriel, Hugues, Adkisson, Wayne O., Ajijola, Olujimi A., Alvarado, Francisco J., Amin, Ahmad S., André, Clémentine, Anter, Elad, Antzelevitch, Charles, Ariga, Rina, Arora, Rishi, Arya, Arash, Asirvatham, Samuel, Atienza, Felipe, Atluri, Pavan, Balse, Elise, Basso, Cristina, Benditt, David G., Bennett, Richard, Berenfeld, Omer, Berruezo, Antonio, Bers, Donald M., Bhaskaran, Ashwin, Bogun, Frank, Bose, Rupan, Botzer, Lior, Boyle, Patrick M., Bradfield, Jason S., Brini, Marisa, Brugada, Pedro, Caldwell, Jessica L., Calkins, Hugh, Poindexter, Catherine Ellen, Callans, David J., Carafoli, Ernesto, Catterall, William A., Cerrone, Marina, Chandler, Stephanie, Chauvel, Remi, Chen, Lan S., Chen, Peng-Sheng, Cheniti, Ghassen, Cheung, Christopher C., Chiamvimonvat, Nipavan, Chiang, David Y., Chorin, Ehud, Christini, David J., Christoffels, Vincent M., Christoph, Jan, Clancy, Colleen E., Climent, Andreu M., Cochet, Hubert, Coetzee, William A., Crossley, George H., Crotti, Lia, Cuculich, Phillip S., Curtis, Anne B., Dagradi, Federica, Damiano, Ralph J., Jr, Darbar, Dawood, Das, Mithilesh K., Delmar, Mario, Delpón, Eva, Derval, Nicolas, Deshmukh, Abhishek, Dherange, Parinita, Dickfeld, Timm M., Dierckx, Hans, Dinov, Borislav, Divakaran, Sanjay, Dixit, Sanjay, Dubois, Rémi, Duchateau, Josselin, Edwards, Andrew G., Ellenbogen, Kenneth A., Ellinor, Patrick T., Ellis, Christopher R., Enriquez, Andres, Estes III, N.A. Mark, Etheridge, Susan P., Everett, Thomas H., Fedorov, Vadim V., Filgueiras-Rama, David, Fishbein, Michael, Fishman, Glenn I., Fradley, Michael, Gami, Apoor S., Gando, Ivan, Garabelli, Paul James, Garcia, Fermin, George, Alfred L., Jr, Gerstenfeld, Edward P., Goldberger, Jeffrey J., Gourdie, Robert G., Grace, Andrew, Grubb, Blair P., Guerrier, Karine, Guillem, María S., Györke, Sándor, Haines, David E., Halperin, Henry R., Hatem, Stéphane, Haïssaguerre, Michel, Herron, Todd J., Hindricks, Gerhard, Hocini, Mélèze, Hoffman, Jacob, Hund, Thomas J., Hutchinson, Mathew D., Iliceto, Sabino, Ilkhanoff, Leonard, Ingles, Jodie, Ip, James E., Jackman, Warren M., Jalife, Jose, Jaïs, Pierre, Jhun, Bong Sook, Restrepo, Alejandro Jimenez, John, Roy M., Johnson, Jason, Jongbloed, Monique, Jáuregui, Beatriz, Kalman, Jonathan M., Kalyanasundaram, Anuradha, Kamp, Timothy J., Kanagasundram, Arvindh N., Kang, Po Wei, Kanj, Mohamed H., Kapa, Suraj, Kapur, Sunil, Karabin, Beverly, Kernik, Divya C., Klein, George J., Kléber, André G., Knight, Bradley P., Koenig, Sara N., Kohl, Peter, Konecny, Thomas, Koneru, Jayanthi N., Krahn, Andrew D., Krishnappa, Darshan, Krogh-Madsen, Trine, Kumar, Saurabh, Kusayama, Takashi, Kushnir, Alexander, Kwak, Brenda R., Lador, Adi, Lakatta, Edward G., Laksman, Zachary W.M., Latchamsetty, Rakesh, Lau, Dennis H., Lee, Byron K., Lenaeus, Michael J., Lerman, Bruce B., Li, Ning, Lin, Shien-Fong, Link, Mark S., Liu, Bin, Liu, Christopher F., Lockwood, Deborah J., Loeys, Bart, Lubitz, Steven A., Prof-Dr, Stefan Luther, Lyon, Aurore, MacGregor, Robert M., MacRae, Calum A., Maher, Timothy, Maltsev, Victor, Man, Joyce C.K., Marchlinski, Francis E., Markowitz, Steven M., Maron, Barry J., Maron, Martin S., Marra, Martina Perazzolo, Marx, Steven O., Mazzanti, Andrea, McCulloch, Andrew D., Mehta, Nishaki K., Melby, Spencer J., Mellor, Greg, Michaud, Gregory F., Miles, William M., Miller, Jennifer C., Miller, John M., Mitrani, Raul D., Mohler, Peter J., Montgomery, Jay A., Moreno, Jonathan D., Murray, Katherine T., Myerburg, Robert J., Nakagawa, Hiroshi, Naksuk, Niyada, Nalliah, Chrishan Joseph, Napolitano, Carlo, Narayan, Sanjiv M., Nazarian, Saman, Nerbonne, Jeanne M., Nery, Pablo B., Nguyen, Thao P., Nichols, Colin G., Nielsen, Morten S., Nogami, Akihiko, Noujaim, Sami F., Nubret, Karine, O-Uchi, Jin, Olgin, Jeffrey E., Olshansky, Brian, Ozcan, Cevher, Pambrun, Thomas, Panfilov, Alexander V., Pang, Paul D., Park, David S., Parlitz, Ulrich, Patocskai, Bence, Pauziene, Neringa, Pauža, Dainius H., Penela, Diego, Peyronnet, Rémi, Pfenniger, Anna, Phillips, S. Tyler, Picard, François, Ploux, Sylvain, Po, Sunny S., Poelzing, Steven, Polina, Iuliia, Porta-Sánchez, Andreu, Prasad, Abhiram, Priori, Silvia G., Pérez-Hernández, Marta, Qian, Pierre C., Quintanilla, MScEng, Jorge G., Radwański, Przemysław B., Ramirez, F. Daniel, Rappel, Wouter-Jan, Richardson, Travis D., Ripplinger, Crystal M., Robinson, Clifford G., Roden, Dan M., Rodrigo, Miguel, Rodriguez, Blanca, Rosso, Raphael, Rowin, Ethan J., Rudy, Yoram, Rysevaite-Kyguoliene, Kristina, Sacher, Frédéric, Sadek, Mouhannad M., Sanders, Prashanthan, Satin, Jonathan, Sauer, William H., Saxon, Leslie A., Schalij, Martin Jan, Schepers, Dorien, Scherlag, Benjamin J., Schleifer, J. William, Schmidt, Ehud J., Schröder-Schetelig, Johannes, Schuessler, Richard B., Schwartz, Peter J., Semsarian, Christopher, Shaw, Robin M., Shen, Win-Kuang, Sheu, Shey-Shing, Shivkumar, Kalyanam, Sieliwonczyk, Ewa, Silva, Jonathan R., Skanes, Allan C., Smyth, James W., Sobie, Eric A., Soejima, Kyoko, Somers, Virend K., Sorajja, Dan, Sroubek, Jakub, Stavrakis, Stavros, Steinberg, Christian, Stevenson, William G., Supple, Gregory E., Swerdlow, Charles, Tandri, Harikrishna, Tedrow, Usha, Thai, Phung N., Thiene, Gaetano, Tixier, Romain, Tomaselli, Gordon F., Towbin, Jeffrey A., Trayanova, Natalia A., Tristani-Firouzi, Martin, Tseng, Zian H., Tung, Roderick, Ueda, Akiko, Upadhyay, Gaurav A., Valderrábano, Miguel, Valdivia, Héctor H., van den Brink, Jonas, van der Werf, Christian, van Opbergen, Chantal J.M., Vaseghi, Marmar, Vautier, R. Ashton, Vera Pedrosa, Maria Linarejos, Verma, Nishant, Vermij, Sarah H., Virk, Sohaib, Viskin, Sami, Vlachos, Konstantinos, Walsh, Edward P., Wang, Paul J., Welte, Nicolas, Wilde, Arthur A.M., Wilkoff, Bruce L., Wu, Joseph C., Yang, Hua-Qian, Yee, Raymond, Zaman, Junaid A.B., Zeppenfeld, Katja, Zghaib, Tarek, Zhang, Jianhua, Zhang, Xiao-Dong, and Zimetbaum, Peter

Published
2022
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44. Modulating cardiac conduction during metabolic ischemia with perfusate sodium and calcium in guinea pig hearts

Author

George, Sharon A., primary, Hoeker, Gregory, additional, Calhoun, Patrick J., additional, Entz, Michael, additional, Raisch, Tristan B., additional, King, D. Ryan, additional, Khan, Momina, additional, Baker, Chandra, additional, Gourdie, Robert G., additional, Smyth, James W., additional, Nielsen, Morten S., additional, and Poelzing, Steven, additional

Published
2019
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45. Altered translation initiation of Gja1 limits gap junction formation during epithelial–mesenchymal transition

Author

James, Carissa C., Zeitz, Michael J., Calhoun, Patrick J., Lamouille, Samy, Smyth, James W., James, Carissa C., Zeitz, Michael J., Calhoun, Patrick J., Lamouille, Samy, and Smyth, James W.

Abstract

Epithelial–mesenchymal transition (EMT) is activated during development, wound healing, and pathologies including fibrosis and cancer metastasis. Hallmarks of EMT are remodeling of intercellular junctions and adhesion proteins, including gap junctions. The GJA1 mRNA transcript encoding the gap junction protein connexin43 (Cx43) has been demonstrated to undergo internal translation initiation, yielding truncated isoforms that modulate gap junctions. The PI3K/Akt/mTOR pathway is central to translation regulation and is activated during EMT, leading us to hypothesize that altered translation initiation would contribute to gap junction loss. Using TGF-β–induced EMT as a model, we find reductions in Cx43 gap junctions despite increased transcription and stabilization of Cx43 protein. Biochemical experiments reveal suppression of the internally translated Cx43 isoform, GJA1-20k in a Smad3 and ERK-dependent manner. Ectopic expression of GJA1-20k does not halt EMT, but is sufficient to rescue gap junction formation. GJA1-20k localizes to the Golgi apparatus, and using superresolution localization microscopy we find retention of GJA1-43k at the Golgi in mesenchymal cells lacking GJA1-20k. NativePAGE demonstrates that levels of GJA1-20k regulate GJA1-43k hexamer oligomerization, a limiting step in Cx43 trafficking. These findings reveal alterations in translation initiation as an unexplored mechanism by which the cell regulates Cx43 gap junction formation during EMT.

Published
2018
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47. The adhesion function of the sodium channel beta subunit (β1) contributes to cardiac action potential propagation

Author

Veeraraghavan, Rengasayee, primary, Hoeker, Gregory S, additional, Alvarez-Laviada, Anita, additional, Hoagland, Daniel, additional, Wan, Xiaoping, additional, King, D Ryan, additional, Sanchez-Alonso, Jose, additional, Chen, Chunling, additional, Jourdan, Jane, additional, Isom, Lori L, additional, Deschenes, Isabelle, additional, Smyth, James W, additional, Gorelik, Julia, additional, Poelzing, Steven, additional, and Gourdie, Robert G, additional

Published
2018
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48. Author response: The adhesion function of the sodium channel beta subunit (β1) contributes to cardiac action potential propagation

Author

Veeraraghavan, Rengasayee, primary, Hoeker, Gregory S, additional, Alvarez-Laviada, Anita, additional, Hoagland, Daniel, additional, Wan, Xiaoping, additional, King, D Ryan, additional, Sanchez-Alonso, Jose, additional, Chen, Chunling, additional, Jourdan, Jane, additional, Isom, Lori L, additional, Deschenes, Isabelle, additional, Smyth, James W, additional, Gorelik, Julia, additional, Poelzing, Steven, additional, and Gourdie, Robert G, additional

Published
2018
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