Your search keyword '"Blackwood, Erik A."' showing total 5 results

1. The peroxisomal enzyme, FAR1, is induced during ER stress in an ATF6-dependent manner in cardiac myocytes.

Author

Marsh, Kayleigh G., Arrieta, Adrian, Thuerauf, Donna J., Blackwood, Erik A., MacDonnell, Lauren, and Glembotski, Christopher C.

Subjects

MUSCLE cells, TRANSCRIPTION factors, ENZYMES, PEROXISOMES, OXIDATIVE stress, DOBUTAMINE

Abstract

Although peroxisomes have been extensively studied in other cell types, their presence and function have gone virtually unexamined in cardiac myocytes. Here, in neonatal rat ventricular myocytes (NRVM) we showed that several known peroxisomal proteins co-localize to punctate structures with a morphology typical of peroxisomes. Surprisingly, we found that the peroxisomal protein, fatty acyl-CoA reductase 1 (FAR1), was upregulated by pharmacological and pathophysiological ER stress induced by tunicamycin (TM) and simulated ischemia-reperfusion (sI/R), respectively. Moreover, FAR1 induction in NRVM was mediated by the ER stress sensor, activating transcription factor 6 (ATF6). Functionally, FAR1 knockdown reduced myocyte death during oxidative stress induced by either sI/R or hydrogen peroxide (H2O2). Thus, Far1 is an ER stress-inducible gene, which encodes a protein that localizes to peroxisomes of cardiac myocytes, where it reduces myocyte viability during oxidative stress. Since FAR1 is critical for plasmalogen synthesis, these results imply that plasmalogens may exert maladaptive effects on the viability of myocytes exposed to oxidative stress. [ABSTRACT FROM AUTHOR]

Published

2021

2. ATF6 as a Nodal Regulator of Proteostasis in the Heart.

Author

Glembotski, Christopher C., Arrieta, Adrian, Blackwood, Erik A., and Stauffer, Winston T.

Subjects

MEMBRANE proteins, GREEN'S functions, TRANSCRIPTION factors, DENATURATION of proteins, ION channels, CARDIAC contraction, SMALL molecules

Abstract

Proteostasis encompasses a homeostatic cellular network in all cells that maintains the integrity of the proteome, which is critical for optimal cellular function. The components of the proteostasis network include protein synthesis, folding, trafficking, and degradation. Cardiac myocytes have a specialized endoplasmic reticulum (ER) called the sarcoplasmic reticulum that is well known for its role in contractile calcium handling. However, less studied is the proteostasis network associated with the ER, which is of particular importance in cardiac myocytes because it ensures the integrity of proteins that are critical for cardiac contraction, e.g., ion channels, as well as proteins necessary for maintaining myocyte viability and interaction with other cell types, e.g., secreted hormones and growth factors. A major aspect of the ER proteostasis network is the ER unfolded protein response (UPR), which is initiated when misfolded proteins in the ER activate a group of three ER transmembrane proteins, one of which is the transcription factor, ATF6. Prior to studies in the heart, ATF6 had been shown in model cell lines to be primarily adaptive, exerting protective effects by inducing genes that encode ER proteins that fortify protein-folding in this organelle, thus establishing the canonical role for ATF6. Subsequent studies in isolated cardiac myocytes and in the myocardium, in vivo , have expanded roles for ATF6 beyond the canonical functions to include the induction of genes that encode proteins outside of the ER that do not have known functions that are obviously related to ER protein-folding. The identification of such non-canonical roles for ATF6, as well as findings that the gene programs induced by ATF6 differ depending on the stimulus, have piqued interest in further research on ATF6 as an adaptive effector in cardiac myocytes, underscoring the therapeutic potential of activating ATF6 in the heart. Moreover, discoveries of small molecule activators of ATF6 that adaptively affect the heart, as well as other organs, in vivo , have expanded the potential for development of ATF6-based therapeutics. This review focuses on the ATF6 arm of the ER UPR and its effects on the proteostasis network in the myocardium. [ABSTRACT FROM AUTHOR]

Published

2020

3. Designing Novel Therapies to Mend Broken Hearts: ATF6 and Cardiac Proteostasis.

Author

Blackwood, Erik A., Bilal, Alina S., Stauffer, Winston T., Arrieta, Adrian, and Glembotski, Christopher C.

Subjects

*PROTEIN folding, *SMALL molecules, *PROTEOLYSIS, *CARDIAC hypertrophy, *PROTEIN synthesis

Abstract

The heart exhibits incredible plasticity in response to both environmental and genetic alterations that affect workload. Over the course of development, or in response to physiological or pathological stimuli, the heart responds to fluctuations in workload by hypertrophic growth primarily by individual cardiac myocytes growing in size. Cardiac hypertrophy is associated with an increase in protein synthesis, which must coordinate with protein folding and degradation to allow for homeostatic growth without affecting the functional integrity of cardiac myocytes (i.e., proteostasis). This increase in the protein folding demand in the growing cardiac myocyte activates the transcription factor, ATF6 (activating transcription factor 6α, an inducer of genes that restore proteostasis. Previously, ATF6 has been shown to induce ER-targeted proteins functioning primarily to enhance ER protein folding and degradation. More recent studies, however, have illuminated adaptive roles for ATF6 functioning outside of the ER by inducing non-canonical targets in a stimulus-specific manner. This unique ability of ATF6 to act as an initial adaptive responder has bolstered an enthusiasm for identifying small molecule activators of ATF6 and similar proteostasis-based therapeutics. [ABSTRACT FROM AUTHOR]

Published

2020

4. The ER Unfolded Protein Response Effector, ATF6, Reduces Cardiac Fibrosis and Decreases Activation of Cardiac Fibroblasts.

Author

Stauffer, Winston T., Blackwood, Erik A., Azizi, Khalid, Kaufman, Randal J., and Glembotski, Christopher C.

Subjects

*MYOFIBROBLASTS, *HEART fibrosis, *DENATURATION of proteins, *FIBROBLASTS, *TRANSFORMING growth factors, *ENDOPLASMIC reticulum, *SMOOTH muscle

Abstract

Activating transcription factor-6 α (ATF6) is one of the three main sensors and effectors of the endoplasmic reticulum (ER) stress response and, as such, it is critical for protecting the heart and other tissues from a variety of environmental insults and disease states. In the heart, ATF6 has been shown to protect cardiac myocytes. However, its roles in other cell types in the heart are unknown. Here we show that ATF6 decreases the activation of cardiac fibroblasts in response to the cytokine, transforming growth factor β (TGFβ), which can induce fibroblast trans-differentiation into a myofibroblast phenotype through signaling via the TGFβ–Smad pathway. ATF6 activation suppressed fibroblast contraction and the induction of α smooth muscle actin (αSMA). Conversely, fibroblasts were hyperactivated when ATF6 was silenced or deleted. ATF6 thus represents a novel inhibitor of the TGFβ–Smad axis of cardiac fibroblast activation. [ABSTRACT FROM AUTHOR]

Published

2020

5. ATF6 protects against protein misfolding during cardiac hypertrophy.

Author

Hofmann, Christoph, Aghajani, Marjan, Alcock, Cecily D., Blackwood, Erik A., Sandmann, Clara, Herzog, Nicole, Groß, Julia, Plate, Lars, Wiseman, R. Luke, Kaufman, Randal J., Katus, Hugo A., Jakobi, Tobias, Völkers, Mirko, Glembotski, Christopher C., and Doroudgar, Shirin

Subjects

*CARDIAC hypertrophy, *UNFOLDED protein response, *PROTEIN folding, *TRANSCRIPTION factors, *PROTEINS

Abstract

Cardiomyocytes activate the unfolded protein response (UPR) transcription factor ATF6 during pressure overload-induced hypertrophic growth. The UPR is thought to increase ER protein folding capacity and maintain proteostasis. ATF6 deficiency during pressure overload leads to heart failure, suggesting that ATF6 protects against myocardial dysfunction by preventing protein misfolding. However, conclusive evidence that ATF6 prevents toxic protein misfolding during cardiac hypertrophy is still pending. Here, we found that activation of the UPR, including ATF6, is a common response to pathological cardiac hypertrophy in mice. ATF6 KO mice failed to induce sufficient levels of UPR target genes in response to chronic isoproterenol infusion or transverse aortic constriction (TAC), resulting in impaired cardiac growth. To investigate the effects of ATF6 on protein folding, the accumulation of poly-ubiquitinated proteins as well as soluble amyloid oligomers were directly quantified in hypertrophied hearts of WT and ATF6 KO mice. Whereas only low levels of protein misfolding was observed in WT hearts after TAC, ATF6 KO mice accumulated increased quantities of misfolded protein, which was associated with impaired myocardial function. Collectively, the data suggest that ATF6 plays a critical adaptive role during cardiac hypertrophy by protecting against protein misfolding. [Display omitted] • Cardiac pressure overload and sustained adrenergic stimulation activate the UPR. • Regulation of a specific subset of UPR target genes controling proteostasis during cardiac hypertrophy. • Growth control of ATF6 is mediated by its transcriptional gene program. • ATF6 is necessary to induce adaptive UPR genes in response to pressure overload. • ATF6 deficiency causes protein misfolding in mouse myocardium after TAC surgery. [ABSTRACT FROM AUTHOR]

Published

2024