Your search keyword '"Aaron Renberg"' showing total 5 results

1. Retrograde mitochondrial signaling governs the identity and maturity of metabolic tissues

Author

Gemma L. Pearson, Emily M. Walker, Nathan Lawlor, Anne Lietzke, Vaibhav Sidarala, Jie Zhu, Tracy Stromer, Emma C. Reck, Jin Li, Aaron Renberg, Kawthar Mohamed, Vishal S. Parekh, Irina X. Zhang, Benjamin Thompson, Deqiang Zhang, Sarah A. Ware, Leena Haataja, Stephen C.J. Parker, Peter Arvan, Lei Yin, Brett A. Kaufman, Leslie S. Satin, Lori Sussel, Michael L. Stitzel, and Scott A. Soleimanpour

Abstract

Mitochondrial dysfunction is a hallmark of metabolic diseases, including diabetes, yet the consequences of mitochondrial damage in metabolic tissues are often unclear. Here, we report that mitochondrial dysfunction engages a retrograde (mitonuclear) signaling program that impairs cellular identity and maturity across many metabolic tissues. Surprisingly, we demonstrate that impairments in the mitochondrial quality control machinery, which we observe in pancreatic β cells of humans with diabetes, cause reductions of β cell mass due to dedifferentiation, rather than apoptosis. Utilizing transcriptomic profiling, lineage tracing, and assessments of chromatin accessibility, we find that targeted defects anywhere in the mitochondrial quality control pathway (e.g., genome integrity, dynamics, or turnover) activate the mitochondrial integrated stress response and promote cellular immaturity in β cells, hepatocytes, and brown adipocytes. Intriguingly, pharmacologic blockade of mitochondrial retrograde signaling in vivo restores β cell mass and identity to ameliorate hyperglycemia following mitochondrial damage. Thus, we observe that a shared mitochondrial retrograde response controls cellular identity across metabolic tissues and may be a promising target to treat or prevent metabolic diseases.

Published

2022

2. An intrinsically disordered protein region encoded by the human disease gene

Author

Morgan A, Gingerich, Xueying, Liu, Biaoxin, Chai, Gemma L, Pearson, Michael P, Vincent, Tracy, Stromer, Jie, Zhu, Vaibhav, Sidarala, Aaron, Renberg, Debashish, Sahu, Daniel J, Klionsky, Santiago, Schnell, and Scott A, Soleimanpour

Subjects

Research Paper

Abstract

CLEC16A regulates mitochondrial health through mitophagy and is associated with over 20 human diseases. However, the key structural and functional regions of CLEC16A, and their relevance for human disease, remain unknown. Here, we report that a disease-associated CLEC16A variant lacks a C-terminal intrinsically disordered protein region (IDPR) that is critical for mitochondrial quality control. IDPRs comprise nearly half of the human proteome, yet their mechanistic roles in human disease are poorly understood. Using carbon detect NMR, we find that the CLEC16A C terminus lacks secondary structure, validating the presence of an IDPR. Loss of the CLEC16A C-terminal IDPR in vivo impairs mitophagy, mitochondrial function, and glucose-stimulated insulin secretion, ultimately causing glucose intolerance. Deletion of the CLEC16A C-terminal IDPR increases CLEC16A ubiquitination and degradation, thus impairing assembly of the mitophagy regulatory machinery. Importantly, CLEC16A stability is dependent on proline bias within the C-terminal IDPR, but not amino acid sequence order or charge. Together, we elucidate how an IDPR in CLEC16A regulates mitophagy and implicate pathogenic human gene variants that disrupt IDPRs as novel contributors to diabetes and other CLEC16A-associated diseases. Abbreviations : CAS: carbon-detect amino-acid specific; IDPR: intrinsically disordered protein region; MEFs: mouse embryonic fibroblasts; NMR: nuclear magnetic resonance.

Published

2022

3. An intrinsically disordered protein region encoded by the human disease gene CLEC16A regulates mitophagy

Author

Morgan A. Gingerich, Xueying Liu, Biaoxin Chai, Gemma L. Pearson, Michael P. Vincent, Tracy Stromer, Jie Zhu, Vaibhav Sidarala, Aaron Renberg, Debashish Sahu, Daniel J. Klionsky, Santiago Schnell, and Scott A. Soleimanpour

Subjects

Cell Biology, Molecular Biology

Abstract

CLEC16A regulates mitochondrial health through mitophagy and is associated with over 20 human diseases. However, the key structural and functional regions of CLEC16A, and their relevance for human disease, remain unknown. Here, we report that a disease-associated CLEC16A variant lacks a C-terminal intrinsically disordered protein region (IDPR) that is critical for mitochondrial quality control. IDPRs comprise nearly half of the human proteome, yet their mechanistic roles in human disease are poorly understood. Using carbon detect NMR, we find that the CLEC16A C terminus lacks secondary structure, validating the presence of an IDPR. Loss of the CLEC16A C-terminal IDPR in vivo impairs mitophagy, mitochondrial function, and glucose-stimulated insulin secretion, ultimately causing glucose intolerance. Deletion of the CLEC16A C-terminal IDPR increases CLEC16A ubiquitination and degradation, thus impairing assembly of the mitophagy regulatory machinery. Importantly, CLEC16A stability is dependent on proline bias within the C-terminal IDPR, but not amino acid sequence order or charge. Together, we elucidate how an IDPR in CLEC16A regulates mitophagy and implicate pathogenic human gene variants that disrupt IDPRs as novel contributors to diabetes and other CLEC16A-associated diseases. Abbreviations : CAS: carbon-detect amino-acid specific; IDPR: intrinsically disordered protein region; MEFs: mouse embryonic fibroblasts; NMR: nuclear magnetic resonance.

Published

2022

4. The human disease gene CLEC16A encodes an intrinsically disordered protein region required for mitochondrial quality control

Author

Jie Zhu, Xueying Liu, Gemma L. Pearson, Aaron Renberg, Scott A. Soleimanpour, Vaibhav Sidarala, Debashish Sahu, Morgan A. Gingerich, Daniel J. Klionsky, Biaoxin Chai, Michael S. Vincent, Santiago Schnell, and Tracy Stromer

Subjects

Chemistry, C-terminus, Mitophagy, CLEC16A, Proline, Protein secondary structure, Peptide sequence, Gene, Function (biology), Cell biology

Abstract

CLEC16A regulates mitochondrial health through mitophagy and is associated with over 20 human diseases. While CLEC16A has ubiquitin ligase activity, the key structural and functional regions of CLEC16A, and their relevance for human disease, remain unknown. Here, we report that a disease-associated CLEC16A variant lacks a C-terminal intrinsically disordered protein region (IDPR) that is critical for mitochondrial quality control. Using carbon detect NMR, we find that the CLEC16A C terminus lacks secondary structure, validating the presence of an IDPR. Loss of the CLEC16A C-terminal IDPR in vivo impairs pancreatic β-cell mitophagy, mitochondrial function, and glucose-stimulated insulin secretion, ultimately causing glucose intolerance. Deletion of the CLEC16A C-terminal IDPR increases its self-ubiquitination and destabilizes CLEC16A, thus impairing formation of a critical CLEC16A-dependent mitophagy complex. Importantly, CLEC16A stability is dependent on proline bias within the C-terminal IDPR, but not amino acid sequence order or charge. Together, we clarify how an IDPR in CLEC16A prevents diabetes, thus implicating the disruption of IDPRs as novel pathological contributors to diabetes and other CLEC16A-associated diseases.

Published

2021

5. The E3 ubiquitin ligase parkin is dispensable for metabolic homeostasis in murine pancreatic β cells and adipocytes

Author

Gemma L. Pearson, Aaron Renberg, Ormond A. MacDougald, Tracy D. Vozheiko, Callie A.S. Corsa, Scott A. Soleimanpour, and Matthew M. Askar

Subjects

0301 basic medicine, Male, Mitochondrial Turnover, Ubiquitin-Protein Ligases, Mitochondrion, Biochemistry, Parkin, 03 medical and health sciences, chemistry.chemical_compound, Mice, Insulin resistance, Adipocyte, Insulin-Secreting Cells, Mitophagy, medicine, Adipocytes, Glucose homeostasis, Animals, Homeostasis, Molecular Biology, Adiposity, 030102 biochemistry & molecular biology, biology, Chemistry, Body Weight, Cell Differentiation, Cell Biology, Glucose Tolerance Test, medicine.disease, Ubiquitin ligase, Cell biology, nervous system diseases, Mitochondria, 030104 developmental biology, Metabolism, Diabetes Mellitus, Type 2, biology.protein, Female, Insulin Resistance, Energy Metabolism, Oxidation-Reduction

Abstract

The E3 ubiquitin ligase parkin is a critical regulator of mitophagy and has been identified as a susceptibility gene for type 2 diabetes (T2D). However, its role in metabolically active tissues that precipitate T2D development is unknown. Specifically, pancreatic β cells and adipocytes both rely heavily on mitochondrial function in the regulation of optimal glycemic control to prevent T2D, but parkin's role in preserving quality control of β cell or adipocyte mitochondria is unclear. Although parkin has been reported previously to control mitophagy, here we show that, surprisingly, parkin is dispensable for glucose homeostasis in both β cells and adipocytes during diet-induced insulin resistance in mice. We observed that insulin secretion, β cell formation, and islet architecture were preserved in parkin-deficient β cells and islets, suggesting that parkin is not necessary for control of β cell function and islet compensation for diet-induced obesity. Although transient parkin deficiency mildly impaired mitochondrial turnover in β cell lines, parkin deletion in primary β cells yielded no deficits in mitochondrial clearance. In adipocyte-specific deletion models, lipid uptake and β-oxidation were increased in cultured cells, whereas adipose tissue morphology, glucose homeostasis, and beige-to-white adipocyte transition were unaffected in vivo. In key metabolic tissues where mitochondrial dysfunction has been implicated in T2D development, our experiments unexpectedly revealed that parkin is not an essential regulator of glucose tolerance, whole-body energy metabolism, or mitochondrial quality control. These findings highlight that parkin-independent processes maintain β cell and adipocyte mitochondrial quality control in diet-induced obesity.

Published

2019