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1. Dystrophin S3059 phosphorylation partially attenuates denervation atrophy in mouse tibialis anterior muscles

Author

Kristy Swiderski, Timur Naim, Jennifer Trieu, Annabel Chee, Marco J. Herold, Andrew J. Kueh, Craig A. Goodman, Paul Gregorevic, and Gordon S. Lynch

Subjects
denervation, dystrophin, muscle atrophy, phosphorylation, S3059, Physiology, QP1-981
Abstract

Abstract The dystrophin protein has well‐characterized roles in force transmission and maintaining membrane integrity during muscle contraction. Studies have reported decreased expression of dystrophin in atrophying muscles during wasting conditions, and that restoration of dystrophin can attenuate atrophy, suggesting a role in maintaining muscle mass. Phosphorylation of S3059 within the cysteine‐rich region of dystrophin enhances binding between dystrophin and β‐dystroglycan, and mimicking phosphorylation at this site by site‐directed mutagenesis attenuates myotube atrophy in vitro. To determine whether dystrophin phosphorylation can attenuate muscle wasting in vivo, CRISPR‐Cas9 was used to generate mice with whole body mutations of S3059 to either alanine (DmdS3059A) or glutamate (DmdS3059E), to mimic a loss of, or constitutive phosphorylation of S3059, on all endogenous dystrophin isoforms, respectively. Sciatic nerve transection was performed on these mice to determine whether phosphorylation of dystrophin S3059 could attenuate denervation atrophy. At 14 days post denervation, atrophy of tibialis anterior (TA) but not gastrocnemius or soleus muscles, was partially attenuated in DmdS3059E mice relative to WT mice. Attenuation of atrophy was associated with increased expression of β‐dystroglycan in TA muscles of DmdS3059E mice. Dystrophin S3059 phosphorylation can partially attenuate denervation‐induced atrophy, but may have more significant impact in less severe modes of muscle wasting.

Published
2024
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2. Class IIa HDACs inhibit cell death pathways and protect muscle integrity in response to lipotoxicity

Author

Sheree D. Martin, Timothy Connor, Andrew Sanigorski, Kevin A. McEwen, Darren C. Henstridge, Brunda Nijagal, David De Souza, Dedreia L. Tull, Peter J. Meikle, Greg M. Kowalski, Clinton R. Bruce, Paul Gregorevic, Mark A. Febbraio, Fiona M. Collier, Ken R. Walder, and Sean L. McGee

Subjects
Cytology, QH573-671
Abstract

Abstract Lipotoxicity, the accumulation of lipids in non-adipose tissues, alters the metabolic transcriptome and mitochondrial metabolism in skeletal muscle. The mechanisms involved remain poorly understood. Here we show that lipotoxicity increased histone deacetylase 4 (HDAC4) and histone deacetylase 5 (HDAC5), which reduced the expression of metabolic genes and oxidative metabolism in skeletal muscle, resulting in increased non-oxidative glucose metabolism. This metabolic reprogramming was also associated with impaired apoptosis and ferroptosis responses, and preserved muscle cell viability in response to lipotoxicity. Mechanistically, increased HDAC4 and 5 decreased acetylation of p53 at K120, a modification required for transcriptional activation of apoptosis. Redox drivers of ferroptosis derived from oxidative metabolism were also reduced. The relevance of this pathway was demonstrated by overexpression of loss-of-function HDAC4 and HDAC5 mutants in skeletal muscle of obese db/db mice, which enhanced oxidative metabolic capacity, increased apoptosis and ferroptosis and reduced muscle mass. This study identifies HDAC4 and HDAC5 as repressors of skeletal muscle oxidative metabolism, which is linked to inhibition of cell death pathways and preservation of muscle integrity in response to lipotoxicity.

Published
2023
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4. Decoupling FcRn and tumor contributions to elevated immune checkpoint inhibitor clearance in cancer cachexia

Author

Trang T. Vu, Kyeongmin Kim, Millennium Manna, Justin Thomas, Bryan C. Remaily, Emma J. Montgomery, Travis Costa, Lauren Granchie, Zhiliang Xie, Yizhen Guo, Min Chen, Alyssa Marie M. Castillo, Samuel K. Kulp, Xiaokui Mo, Sridhar Nimmagadda, Paul Gregorevic, Dwight H. Owen, Latha P. Ganesan, Thomas A. Mace, Christopher C. Coss, and Mitch A. Phelps

Subjects
Cachexia, Immune Checkpoint Inhibitor, Clearance, FcRn, LLC, MC38, Therapeutics. Pharmacology, RM1-950
Abstract

High baseline clearance of immune checkpoint inhibitors (ICIs), independent of dose or systemic exposure, is associated with cachexia and poor outcomes in cancer patients. Mechanisms linking ICI clearance, cachexia and ICI therapy failure are unknown. Here, we evaluate in four murine models and across multiple antibodies whether altered baseline catabolic clearance of administered antibody requires a tumor and/or cachexia and whether medical reversal of cachexia phenotype can alleviate altered clearance. Key findings include mild cachexia phenotype and lack of elevated pembrolizumab clearance in the MC38 tumor-bearing model. We also observed severe cachexia and decreased, instead of increased, baseline pembrolizumab clearance in the tumor-free cisplatin-induced cachexia model. Liver Fcgrt expression correlated with altered baseline catabolic clearance, though elevated clearance was still observed with antibodies having no (human IgA) or reduced (human H310Q IgG1) FcRn binding. We conclude cachexia phenotype coincides with altered antibody clearance, though tumor presence is neither sufficient nor necessary for altered clearance in immunocompetent mice. Magnitude and direction of clearance alteration correlated with hepatic Fcgrt, suggesting changes in FcRn expression and/or recycling function may be partially responsible, though factors beyond FcRn also contribute to altered clearance in cachexia.

Published
2024
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5. Mechanisms of chemotherapy‐induced muscle wasting in mice with cancer cachexia

Author

Kate T. Murphy, Kristy Swiderski, James G. Ryall, Jonathan R. Davey, Hongwei Qian, Séverine Lamon, Victoria C. Foletta, Jennifer Trieu, Annabel Chee, Suzannah J. Read, Timur Naim, Paul Gregorevic, and Gordon S. Lynch

Subjects
ERK2, miR‐351, Chemotherapy, Cancer cachexia, Muscle wasting, Internal medicine, RC31-1245
Abstract

Abstract Background Cachexia is a debilitating complication of cancer characterized by progressive wasting and weakness of skeletal muscles that reduces quality of life and can compromise survival. Many anticancer treatments, such as chemotherapy, also cause muscle wasting, which impairs the response to treatment. Given that many cancer patients present with cachexia at the initiation of treatment, we investigated whether cachectic mice were susceptible to chemotherapy‐induced muscle wasting and to investigate contributing mechanisms, including the dysregulation of microRNAs (miRs). Methods Cachectic colon‐26 (C‐26) tumour‐bearing mice were given 5‐fluourouracil (5‐FU) chemotherapy or vehicle treatment and analysed for muscle mass, fibre size and composition, and miR expression. Mechanisms were validated in vitro using C2C12 cell culture and miR mimics and inhibitors and were confirmed in vivo by injecting muscles of 5‐FU‐treated cachectic mice with recombinant adeno‐associated viral (rAAV) vectors encoding a miR sponge. Results In cachectic tumour‐bearing mice, 5‐FU chemotherapy exacerbated the loss of skeletal muscle mass compared with vehicle treatment (by −12% to −20%, P

Published
2022
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6. Proteome-wide systems genetics identifies UFMylation as a regulator of skeletal muscle function

Author

Jeffrey Molendijk, Ronnie Blazev, Richard J Mills, Yaan-Kit Ng, Kevin I Watt, Daryn Chau, Paul Gregorevic, Peter J Crouch, James BW Hilton, Leszek Lisowski, Peixiang Zhang, Karen Reue, Aldons J Lusis, James E Hudson, David E James, Marcus M Seldin, and Benjamin L Parker

Subjects
skeletal muscle, systems genetics, proteomics, UFMylation, Medicine, Science, Biology (General), QH301-705.5
Abstract

Improving muscle function has great potential to improve the quality of life. To identify novel regulators of skeletal muscle metabolism and function, we performed a proteomic analysis of gastrocnemius muscle from 73 genetically distinct inbred mouse strains, and integrated the data with previously acquired genomics and >300 molecular/phenotypic traits via quantitative trait loci mapping and correlation network analysis. These data identified thousands of associations between protein abundance and phenotypes and can be accessed online (https://muscle.coffeeprot.com/) to identify regulators of muscle function. We used this resource to prioritize targets for a functional genomic screen in human bioengineered skeletal muscle. This identified several negative regulators of muscle function including UFC1, an E2 ligase for protein UFMylation. We show UFMylation is up-regulated in a mouse model of amyotrophic lateral sclerosis, a disease that involves muscle atrophy. Furthermore, in vivo knockdown of UFMylation increased contraction force, implicating its role as a negative regulator of skeletal muscle function.

Published
2022
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7. Mechanisms involved in follistatin‐induced hypertrophy and increased insulin action in skeletal muscle

Author

Xiuqing Han, Lisbeth Liliendal Valbjørn Møller, Estelle De Groote, Kirstine Nyvold Bojsen‐Møller, Jonathan Davey, Carlos Henríquez‐Olguin, Zhencheng Li, Jonas Roland Knudsen, Thomas Elbenhardt Jensen, Sten Madsbad, Paul Gregorevic, Erik Arne Richter, and Lykke Sylow

Subjects
Muscle wasting, Follistatin, TGF‐β, Glucose uptake, Insulin resistance, Glycaemic control, Diseases of the musculoskeletal system, RC925-935, Human anatomy, QM1-695
Abstract

Abstract Background Skeletal muscle wasting is often associated with insulin resistance. A major regulator of muscle mass is the transforming growth factor β (TGF‐β) superfamily, including activin A, which causes atrophy. TGF‐β superfamily ligands also negatively regulate insulin‐sensitive proteins, but whether this pathway contributes to insulin action remains to be determined. Methods To elucidate if TGF‐β superfamily ligands regulate insulin action, we used an adeno‐associated virus gene editing approach to overexpress an activin A inhibitor, follistatin (Fst288), in mouse muscle of lean and diet‐induced obese mice. We determined basal and insulin‐stimulated 2‐deoxy‐glucose uptake using isotopic tracers in vivo. Furthermore, to evaluate whether circulating Fst and activin A concentrations are associated with obesity, insulin resistance, and weight loss in humans, we analysed serum from morbidly obese subjects before, 1 week, and 1 year after Roux‐en‐Y gastric bypass (RYGB). Results Fst288 muscle overexpression markedly increased in vivo insulin‐stimulated (but not basal) glucose uptake (+75%, P < 0.05) and increased protein expression and intracellular insulin signalling of AKT, TBC1D4, PAK1, pyruvate dehydrogenase‐E1α, and p70S6K, while decreasing TBC1D1 signaling (P < 0.05). Fst288 increased both basal and insulin‐stimulated protein synthesis, but no correlation was observed between the Fst288‐driven hypertrophy and the increase in insulin‐stimulated glucose uptake. Importantly, Fst288 completely normalized muscle glucose uptake in insulin‐resistant diet‐induced obese mice. RYGB surgery doubled circulating Fst and reduced activin A (−24%, P < 0.05) concentration 1 week after surgery before any significant weight loss in morbidly obese normoglycemic patients, while major weight loss after 1 year did not further change the concentrations. Conclusions We here present evidence that Fst is a potent regulator of insulin action in muscle, and in addition to AKT and p70S6K, we identify TBC1D1, TBC1D4, pyruvate dehydrogenase‐E1α, and PAK1 as Fst targets. Circulating Fst more than doubled post‐RYGB surgery, a treatment that markedly improved insulin sensitivity, suggesting a role for Fst in regulating glycaemic control. These findings demonstrate the therapeutic potential of inhibiting TGF‐β superfamily ligands to improve insulin action and Fst's relevance to muscle wasting‐associated insulin‐resistant conditions in mice and humans.

Published
2019
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8. Tissue-specific expression of Cas9 has no impact on whole-body metabolism in four transgenic mouse lines

Author

Simon T. Bond, Aowen Zhuang, Christine Yang, Eleanor A.M. Gould, Tim Sikora, Yingying Liu, Ying Fu, Kevin I. Watt, Yanie Tan, Helen Kiriazis, Graeme I. Lancaster, Paul Gregorevic, Darren C. Henstridge, Julie R. McMullen, Peter J. Meikle, Anna C. Calkin, and Brian G. Drew

Subjects
CRISPR, Cas9, Transgenic mice, Metabolism, Tissue specific, Phenotype, Internal medicine, RC31-1245
Abstract

Objective: CRISPR/Cas9 technology has revolutionized gene editing and fast tracked our capacity to manipulate genes of interest for the benefit of both research and therapeutic applications. Whilst many advances have, and continue to be made in this area, perhaps the most utilized technology to date has been the generation of knockout cells, tissues and animals. The advantages of this technology are many fold, however some questions still remain regarding the effects that long term expression of foreign proteins such as Cas9, have on mammalian cell function. Several studies have proposed that chronic overexpression of Cas9, with or without its accompanying guide RNAs, may have deleterious effects on cell function and health. This is of particular concern when applying this technology in vivo, where chronic expression of Cas9 in tissues of interest may promote disease-like phenotypes and thus confound the investigation of the effects of the gene of interest. Although these concerns remain valid, no study to our knowledge has yet to demonstrate this directly. Methods: In this study we used the lox-stop-lox (LSL) spCas9 ROSA26 transgenic (Tg) mouse line to generate four tissue-specific Cas9-Tg models that express Cas9 in the heart, liver, skeletal muscle or adipose tissue. We performed comprehensive phenotyping of these mice up to 20-weeks of age and subsequently performed molecular analysis of their organs. Results: We demonstrate that Cas9 expression in these tissues had no detrimental effect on whole body health of the animals, nor did it induce any tissue-specific effects on whole body energy metabolism, liver health, inflammation, fibrosis, heart function or muscle mass. Conclusions: Our data suggests that these models are suitable for studying the tissue specific effects of gene deletion using the LSL-Cas9-Tg model, and that phenotypes observed utilizing these models can be confidently interpreted as being gene specific, and not confounded by the chronic overexpression of Cas9.

Published
2021
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9. Bone Morphogenetic Protein 7 Gene Delivery Improves Cardiac Structure and Function in a Murine Model of Diabetic Cardiomyopathy

Author

Mitchel Tate, Nimna Perera, Darnel Prakoso, Andrew M. Willis, Minh Deo, Osezua Oseghale, Hongwei Qian, Daniel G Donner, Helen Kiriazis, Miles J. De Blasio, Paul Gregorevic, and Rebecca H. Ritchie

Subjects
bone morphogenetic protein 7, diabetic cardiomyopathy, adeno-associated virus, cardiac remodelling, gene therapy, Therapeutics. Pharmacology, RM1-950
Abstract

Diabetes is a major contributor to the increasing burden of heart failure prevalence globally, at least in part due to a disease process termed diabetic cardiomyopathy. Diabetic cardiomyopathy is characterised by cardiac structural changes that are caused by chronic exposure to the diabetic milieu. These structural changes are a major cause of left ventricular (LV) wall stiffness and the development of LV dysfunction. In the current study, we investigated the therapeutic potential of a cardiac-targeted bone morphogenetic protein 7 (BMP7) gene therapy, administered once diastolic dysfunction was present, mimicking the timeframe in which clinical management of the cardiomyopathy would likely be desired. Following 18 weeks of untreated diabetes, mice were administered with a single tail-vein injection of recombinant adeno-associated viral vector (AAV), containing the BMP7 gene, or null vector. Our data demonstrated, after 8 weeks of treatment, that rAAV6-BMP7 treatment exerted beneficial effects on LV functional and structural changes. Importantly, diabetes-induced LV dysfunction was significantly attenuated by a single administration of rAAV6-BMP7. This was associated with a reduction in cardiac fibrosis, cardiomyocyte hypertrophy and cardiomyocyte apoptosis. In conclusion, BMP7 gene therapy limited pathological remodelling in the diabetic heart, conferring an improvement in cardiac function. These findings provide insight for the potential development of treatment strategies urgently needed to delay or reverse LV pathological remodelling in the diabetic heart.

Published
2021
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10. Loss of the long non-coding RNA OIP5-AS1 exacerbates heart failure in a sex-specific manner

Author

Aowen Zhuang, Anna C. Calkin, Shannen Lau, Helen Kiriazis, Daniel G. Donner, Yingying Liu, Simon T. Bond, Sarah C. Moody, Eleanor A.M. Gould, Timothy D. Colgan, Sergio Ruiz Carmona, Michael Inouye, Thomas Q. de Aguiar Vallim, Elizabeth J. Tarling, Gregory A. Quaife-Ryan, James E. Hudson, Enzo R. Porrello, Paul Gregorevic, Xiao-Ming Gao, Xiao-Jun Du, Julie R. McMullen, and Brian G. Drew

Subjects
Cardiovascular medicine, Molecular physiology, Transcriptomics, Science
Abstract

Summary: Long non-coding RNAs (lncRNAs) have been demonstrated to influence numerous biological processes, being strongly implicated in the maintenance and physiological function of various tissues including the heart. The lncRNA OIP5-AS1 (1700020I14Rik/Cyrano) has been studied in several settings; however its role in cardiac pathologies remains mostly uncharacterized. Using a series of in vitro and ex vivo methods, we demonstrate that OIP5-AS1 is regulated during cardiac development in rodent and human models and in disease settings in mice. Using CRISPR, we engineered a global OIP5-AS1 knockout (KO) mouse and demonstrated that female KO mice develop exacerbated heart failure following cardiac pressure overload (transverse aortic constriction [TAC]) but male mice do not. RNA-sequencing of wild-type and KO hearts suggest that OIP5-AS1 regulates pathways that impact mitochondrial function. Thus, these findings highlight OIP5-AS1 as a gene of interest in sex-specific differences in mitochondrial function and development of heart failure.

Published
2021
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11. Bone Geometry Is Altered by Follistatin‐Induced Muscle Growth in Young Adult Male Mice

Author

Audrey S M Chan, Narelle E McGregor, Ingrid J Poulton, Justin P Hardee, Ellie H‐J Cho, T John Martin, Paul Gregorevic, Natalie A Sims, and Gordon S Lynch

Subjects
ANIMAL MODELS, BONE MODELING AND REMODELIN, BONE MORPHOGENETIC PROTEIN, BONE–MUSCLE INTERACTION, CELL/TISSUE SIGNALING—PARACRINE PATHWAYS, MOLECULAR PATHWAYS—REMODELING, Orthopedic surgery, RD701-811, Diseases of the musculoskeletal system, RC925-935
Abstract

ABSTRACT The development of the musculoskeletal system and its maintenance depends on the reciprocal relationship between muscle and bone. The size of skeletal muscles and the forces generated during muscle contraction are potent sources of mechanical stress on the developing skeleton, and they shape bone structure during growth. This is particularly evident in hypermuscular global myostatin (Mstn)‐null mice, where larger muscles during development increase bone mass and alter bone shape. However, whether muscle hypertrophy can similarly influence the shape of bones after the embryonic and prepubertal period is unknown. To address this issue, bone structure was assessed after inducing muscle hypertrophy in the lower hindlimbs of young‐adult C57BL/6J male mice by administering intramuscular injections of recombinant adeno‐associated viral vectors expressing follistatin (FST), a potent antagonist of Mstn. Two FST isoforms were used: the full‐length 315 amino acid isoform (FST‐315) and a truncated 288 amino acid isoform (FST‐288). In both FST‐treated cohorts, muscle hypertrophy was observed, and the anterior crest of the tibia, adjacent to the tibialis anterior muscle, was lengthened. Hypertrophy of the muscles surrounding the tibia caused the adjacent cortical shell to recede inward toward the central axis: an event driven by bone resorption adjacent to the hypertrophic muscle. The findings reveal that inducing muscle hypertrophy in mice can confer changes in bone shape in early adulthood. © 2021 The Authors. JBMR Plus published by Wiley Periodicals LLC on behalf of American Society for Bone and Mineral Research.

Published
2021
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12. TMEPAI/PMEPA1 Is a Positive Regulator of Skeletal Muscle Mass

Author

Adam Hagg, Swati Kharoud, Georgia Goodchild, Craig A. Goodman, Justin L. Chen, Rachel E. Thomson, Hongwei Qian, Paul Gregorevic, Craig A. Harrison, and Kelly L. Walton

Subjects
Gdf11, myostatin, activin, cachexia, muscle, PMEPA1, Physiology, QP1-981
Abstract

Inhibition of myostatin- and activin-mediated SMAD2/3 signaling using ligand traps, such as soluble receptors, ligand-targeting propeptides and antibodies, or follistatin can increase skeletal muscle mass in healthy mice and ameliorate wasting in models of cancer cachexia and muscular dystrophy. However, clinical translation of these extracellular approaches targeting myostatin and activin has been hindered by the challenges of achieving efficacy without potential effects in other tissues. Toward the goal of developing tissue-specific myostatin/activin interventions, we explored the ability of transmembrane prostate androgen-induced (TMEPAI), an inhibitor of transforming growth factor-β (TGF-β1)-mediated SMAD2/3 signaling, to promote growth, and counter atrophy, in skeletal muscle. In this study, we show that TMEPAI can block activin A, activin B, myostatin and GDF-11 activity in vitro. To determine the physiological significance of TMEPAI, we employed Adeno-associated viral vector (AAV) delivery of a TMEPAI expression cassette to the muscles of healthy mice, which increased mass by as much as 30%, due to hypertrophy of muscle fibers. To demonstrate that TMEPAI mediates its effects via inhibition of the SMAD2/3 pathway, tibialis anterior (TA) muscles of mice were co-injected with AAV vectors expressing activin A and TMEPAI. In this setting, TMEPAI blocked skeletal muscle wasting driven by activin-induced phosphorylation of SMAD3. In a model of cancer cachexia associated with elevated circulating activin A, delivery of AAV:TMEPAI into TA muscles of mice bearing C26 colon tumors ameliorated the muscle atrophy normally associated with cancer progression. Collectively, the findings indicate that muscle-directed TMEPAI gene delivery can inactivate the activin/myostatin-SMAD3 pathway to positively regulate muscle mass in healthy settings and models of disease.

Published
2020
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13. Old Drug, New Trick: Tilorone, a Broad-Spectrum Antiviral Drug as a Potential Anti-Fibrotic Therapeutic for the Diseased Heart

Author

Duncan Horlock, David M. Kaye, Catherine E. Winbanks, Xiao-Ming Gao, Helen Kiriazis, Daniel G. Donner, Paul Gregorevic, Julie R. McMullen, and Bianca C. Bernardo

Subjects
heart failure, fibrosis, tilorone, pressure overload, fibroblast, treatment, Medicine, Pharmacy and materia medica, RS1-441
Abstract

Cardiac fibrosis is associated with most forms of cardiovascular disease. No reliable therapies targeting cardiac fibrosis are available, thus identifying novel drugs that can resolve or prevent fibrosis is needed. Tilorone, an antiviral agent, can prevent fibrosis in a mouse model of lung disease. We investigated the anti-fibrotic effects of tilorone in human cardiac fibroblasts in vitro by performing a radioisotopic assay for [3H]-proline incorporation as a proxy for collagen synthesis. Exploratory studies in human cardiac fibroblasts treated with tilorone (10 µM) showed a significant reduction in transforming growth factor-β induced collagen synthesis compared to untreated fibroblasts. To determine if this finding could be recapitulated in vivo, mice with established pathological remodelling due to four weeks of transverse aortic constriction (TAC) were administered tilorone (50 mg/kg, i.p) or saline every third day for eight weeks. Treatment with tilorone was associated with attenuation of fibrosis (assessed by Masson’s trichrome stain), a favourable cardiac gene expression profile and no further deterioration of cardiac systolic function determined by echocardiography compared to saline treated TAC mice. These data demonstrate that tilorone has anti-fibrotic actions in human cardiac fibroblasts and the adult mouse heart, and represents a potential novel therapy to treat fibrosis associated with heart failure.

Published
2021
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14. Glucose-6-phosphate dehydrogenase contributes to the regulation of glucose uptake in skeletal muscle

Author

Robert S. Lee-Young, Nolan J. Hoffman, Kate T. Murphy, Darren C. Henstridge, Dorit Samocha-Bonet, Andrew L. Siebel, Peter Iliades, Borivoj Zivanovic, Yet H. Hong, Timothy D. Colgan, Michael J. Kraakman, Clinton R. Bruce, Paul Gregorevic, Glenn K. McConell, Gordon S. Lynch, Grant R. Drummond, Bronwyn A. Kingwell, Jerry R. Greenfield, and Mark A. Febbraio

Subjects
Internal medicine, RC31-1245
Abstract

Objective: The development of skeletal muscle insulin resistance is an early physiological defect, yet the intracellular mechanisms accounting for this metabolic defect remained unresolved. Here, we have examined the role of glucose-6-phosphate dehydrogenase (G6PDH) activity in the pathogenesis of insulin resistance in skeletal muscle. Methods: Multiple mouse disease states exhibiting insulin resistance and glucose intolerance, as well as obese humans defined as insulin-sensitive, insulin-resistant, or pre-diabetic, were examined. Results: We identified increased glucose-6-phosphate dehydrogenase (G6PDH) activity as a common intracellular adaptation that occurs in parallel with the induction of insulin resistance in skeletal muscle and is present across animal and human disease states with an underlying pathology of insulin resistance and glucose intolerance. We observed an inverse association between G6PDH activity and nitric oxide synthase (NOS) activity and show that increasing NOS activity via the skeletal muscle specific neuronal (n)NOSμ partially suppresses G6PDH activity in skeletal muscle cells. Furthermore, attenuation of G6PDH activity in skeletal muscle cells via (a) increased nNOSμ/NOS activity, (b) pharmacological G6PDH inhibition, or (c) genetic G6PDH inhibition increases insulin-independent glucose uptake. Conclusions: We have identified a novel, previously unrecognized role for G6PDH in the regulation of skeletal muscle glucose metabolism. Author Video: Author Video Watch what authors say about their articles Keywords: Glucose metabolism, Enzyme activity, Insulin sensitivity

Published
2016
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15. Disruption of the Class IIa HDAC Corepressor Complex Increases Energy Expenditure and Lipid Oxidation

Author

Vidhi Gaur, Timothy Connor, Andrew Sanigorski, Sheree D. Martin, Clinton R. Bruce, Darren C. Henstridge, Simon T. Bond, Kevin A. McEwen, Lyndal Kerr-Bayles, Trent D. Ashton, Cassandra Fleming, Min Wu, Lisa S. Pike Winer, Denise Chen, Gregg M. Hudson, John W.R. Schwabe, Keith Baar, Mark A. Febbraio, Paul Gregorevic, Frederick M. Pfeffer, Ken R. Walder, Mark Hargreaves, and Sean L. McGee

Subjects
Skeletal muscle, HDAC4, HDAC5, MEF2, Biology (General), QH301-705.5
Abstract

Drugs that recapitulate aspects of the exercise adaptive response have the potential to provide better treatment for diseases associated with physical inactivity. We previously observed reduced skeletal muscle class IIa HDAC (histone deacetylase) transcriptional repressive activity during exercise. Here, we find that exercise-like adaptations are induced by skeletal muscle expression of class IIa HDAC mutants that cannot form a corepressor complex. Adaptations include increased metabolic gene expression, mitochondrial capacity, and lipid oxidation. An existing HDAC inhibitor, Scriptaid, had similar phenotypic effects through disruption of the class IIa HDAC corepressor complex. Acute Scriptaid administration to mice increased the expression of metabolic genes, which required an intact class IIa HDAC corepressor complex. Chronic Scriptaid administration increased exercise capacity, whole-body energy expenditure and lipid oxidation, and reduced fasting blood lipids and glucose. Therefore, compounds that disrupt class IIa HDAC function could be used to enhance metabolic health in chronic diseases driven by physical inactivity.

Published
2016
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16. Generation of MicroRNA-34 Sponges and Tough Decoys for the Heart: Developments and Challenges

Author

Bianca C. Bernardo, Paul Gregorevic, Rebecca H. Ritchie, and Julie R. McMullen

Subjects
microRNAs, heart failure, tough decoy, microRNA sponge, antisense oligonucleotides, Therapeutics. Pharmacology, RM1-950
Abstract

Heart failure (HF) is a debilitating and deadly chronic disease, with almost 50% of patients with HF dying within 5 years of diagnosis. With limited effective therapies to treat or cure HF, new therapies are greatly needed. microRNAs (miRNAs) are small non-coding RNA molecules that are powerful regulators of gene expression and play a key role in almost every biological process. Disruptions in miRNA gene expression has been functionally linked to numerous diseases, including cardiovascular disease. Molecular tools for manipulating miRNA activity have been developed, and there is evidence from preclinical studies demonstrating the potential of miRNAs to be therapeutic targets for cardiovascular disease. For clinical application, miRNA sponges and tough decoys have been developed for more stable suppression and targeted delivery of the miRNA of choice. The aim of this study was to generate miRNA sponges and tough decoys to target miR-34 in the mouse heart. We present data to show that using both approaches we were unable to get significant knockdown of miR-34 or regulate miR-34 target genes in the heart in vivo. We also review recent applications of this method in the heart and discuss further considerations for optimisation in construct design and testing, and the obstacles to be overcome before they enter the clinic.

Published
2018
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17. Regulation of Tissue Growth by the Mammalian Hippo Signaling Pathway

Author

Kevin I. Watt, Kieran F. Harvey, and Paul Gregorevic

Subjects
hippo signaling pathway, YAP, TAZ, integrative physiology, cell signaling, Physiology, QP1-981
Abstract

The integrative control of diverse biological processes such as proliferation, differentiation, apoptosis and metabolism is essential to maintain cellular and tissue homeostasis. Disruption of these underlie the development of many disease states including cancer and diabetes, as well as many of the complications that arise as a consequence of aging. These biological outputs are governed by many cellular signaling networks that function independently, and in concert, to convert changes in hormonal, mechanical and metabolic stimuli into alterations in gene expression. First identified in Drosophila melanogaster as a powerful mediator of cell division and apoptosis, the Hippo signaling pathway is a highly conserved regulator of mammalian organ size and functional capacity in both healthy and diseased tissues. Recent studies have implicated the pathway as an effector of diverse physiological cues demonstrating an essential role for the Hippo pathway as an integrative component of cellular homeostasis. In this review, we will: (a) outline the critical signaling elements that constitute the mammalian Hippo pathway, and how they function to regulate Hippo pathway-dependent gene expression and tissue growth, (b) discuss evidence that shows this pathway functions as an effector of diverse physiological stimuli and (c) highlight key questions in this developing field.

Published
2017
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18. Silencing of miR-34a attenuates cardiac dysfunction in a setting of moderate, but not severe, hypertrophic cardiomyopathy.

Author

Bianca C Bernardo, Xiao-Ming Gao, Yow Keat Tham, Helen Kiriazis, Catherine E Winbanks, Jenny Y Y Ooi, Esther J H Boey, Susanna Obad, Sakari Kauppinen, Paul Gregorevic, Xiao-Jun Du, Ruby C Y Lin, and Julie R McMullen

Subjects
Medicine, Science
Abstract

Therapeutic inhibition of the miR-34 family (miR-34a,-b,-c), or miR-34a alone, have emerged as promising strategies for the treatment of cardiac pathology. However, before advancing these approaches further for potential entry into the clinic, a more comprehensive assessment of the therapeutic potential of inhibiting miR-34a is required for two key reasons. First, miR-34a has ∼40% fewer predicted targets than the miR-34 family. Hence, in cardiac stress settings in which inhibition of miR-34a provides adequate protection, this approach is likely to result in less potential off-target effects. Secondly, silencing of miR-34a alone may be insufficient in settings of established cardiac pathology. We recently demonstrated that inhibition of the miR-34 family, but not miR-34a alone, provided benefit in a chronic model of myocardial infarction. Inhibition of miR-34 also attenuated cardiac remodeling and improved heart function following pressure overload, however, silencing of miR-34a alone was not examined. The aim of this study was to assess whether inhibition of miR-34a could attenuate cardiac remodeling in a mouse model with pre-existing pathological hypertrophy. Mice were subjected to pressure overload via constriction of the transverse aorta for four weeks and echocardiography was performed to confirm left ventricular hypertrophy and systolic dysfunction. After four weeks of pressure overload (before treatment), two distinct groups of animals became apparent: (1) mice with moderate pathology (fractional shortening decreased ∼20%) and (2) mice with severe pathology (fractional shortening decreased ∼37%). Mice were administered locked nucleic acid (LNA)-antimiR-34a or LNA-control with an eight week follow-up. Inhibition of miR-34a in mice with moderate cardiac pathology attenuated atrial enlargement and maintained cardiac function, but had no significant effect on fetal gene expression or cardiac fibrosis. Inhibition of miR-34a in mice with severe pathology provided no therapeutic benefit. Thus, therapies that inhibit miR-34a alone may have limited potential in settings of established cardiac pathology.

Published
2014
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19. Abnormal mitochondrial L-arginine transport contributes to the pathogenesis of heart failure and rexoygenation injury.

Author

David Williams, Kylie M Venardos, Melissa Byrne, Mandar Joshi, Duncan Horlock, Nicholas T Lam, Paul Gregorevic, Sean L McGee, and David M Kaye

Subjects
Medicine, Science
Abstract

BackgroundImpaired mitochondrial function is fundamental feature of heart failure (HF) and myocardial ischemia. In addition to the effects of heightened oxidative stress, altered nitric oxide (NO) metabolism, generated by a mitochondrial NO synthase, has also been proposed to impact upon mitochondrial function. However, the mechanism responsible for arginine transport into mitochondria and the effect of HF on such a process is unknown. We therefore aimed to characterize mitochondrial L-arginine transport and to investigate the hypothesis that impaired mitochondrial L-arginine transport plays a key role in the pathogenesis of heart failure and myocardial injury.Methods and resultsIn mitochondria isolated from failing hearts (sheep rapid pacing model and mouse Mst1 transgenic model) we demonstrated a marked reduction in L-arginine uptake (pConclusionThese data provide new insights into the role of L-arginine transport in mitochondrial biology and cardiovascular disease. Augmentation of mitochondrial L-arginine availability may be a novel therapeutic strategy for myocardial disorders involving mitochondrial stress such as heart failure and reperfusion injury.

Published
2014
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20. Functional β-adrenoceptors are important for early muscle regeneration in mice through effects on myoblast proliferation and differentiation.

Author

Jarrod E Church, Jennifer Trieu, Radhika Sheorey, Annabel Y-M Chee, Timur Naim, Dale M Baum, James G Ryall, Paul Gregorevic, and Gordon S Lynch

Subjects
Medicine, Science
Abstract

Muscles can be injured in different ways and the trauma and subsequent loss of function and physical capacity can impact significantly on the lives of patients through physical impairments and compromised quality of life. The relative success of muscle repair after injury will largely determine the extent of functional recovery. Unfortunately, regenerative processes are often slow and incomplete, and so developing novel strategies to enhance muscle regeneration is important. While the capacity to enhance muscle repair by stimulating β2-adrenoceptors (β-ARs) using β2-AR agonists (β2-agonists) has been demonstrated previously, the exact role β-ARs play in regulating the regenerative process remains unclear. To investigate β-AR-mediated signaling in muscle regeneration after myotoxic damage, we examined the regenerative capacity of tibialis anterior and extensor digitorum longus muscles from mice lacking either β1-AR (β1-KO) and/or β2-ARs (β2-KO), testing the hypothesis that muscles from mice lacking the β2-AR would exhibit impaired functional regeneration after damage compared with muscles from β1-KO or β1/β2-AR null (β1/β2-KO) KO mice. At 7 days post-injury, regenerating muscles from β1/β2-KO mice produced less force than those of controls but muscles from β1-KO or β2-KO mice did not exhibit any delay in functional restoration. Compared with controls, β1/β2-KO mice exhibited an enhanced inflammatory response to injury, which delayed early muscle regeneration, but an enhanced myoblast proliferation later during regeneration ensured a similar functional recovery (to controls) by 14 days post-injury. This apparent redundancy in the β-AR signaling pathway was unexpected and may have important implications for manipulating β-AR signaling to improve the rate, extent and efficacy of muscle regeneration to enhance functional recovery after injury.

Published
2014
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21. miR-206 represses hypertrophy of myogenic cells but not muscle fibers via inhibition of HDAC4.

Author

Catherine E Winbanks, Claudia Beyer, Adam Hagg, Hongwei Qian, Patricio V Sepulveda, and Paul Gregorevic

Subjects
Medicine, Science
Abstract

microRNAs regulate the development of myogenic progenitors, and the formation of skeletal muscle fibers. However, the role miRNAs play in controlling the growth and adaptation of post-mitotic musculature is less clear. Here, we show that inhibition of the established pro-myogenic regulator miR-206 can promote hypertrophy and increased protein synthesis in post-mitotic cells of the myogenic lineage. We have previously demonstrated that histone deacetylase 4 (HDAC4) is a target of miR-206 in the regulation of myogenic differentiation. We confirmed that inhibition of miR-206 de-repressed HDAC4 accumulation in cultured myotubes. Importantly, inhibition of HDAC4 activity by valproic acid or sodium butyrate prevented hypertrophy of myogenic cells otherwise induced by inhibition of miR-206. To test the significance of miRNA-206 as a regulator of skeletal muscle mass in vivo, we designed recombinant adeno-associated viral vectors (rAAV6 vectors) expressing miR-206, or a miR-206 "sponge," featuring repeats of a validated miR-206 target sequence. We observed that over-expression or inhibition of miR-206 in the muscles of mice decreased or increased endogenous HDAC4 levels respectively, but did not alter muscle mass or myofiber size. We subsequently manipulated miR-206 levels in muscles undergoing follistatin-induced hypertrophy or denervation-induced atrophy (models of muscle adaptation where endogenous miR-206 expression is altered). Vector-mediated manipulation of miR-206 activity in these models of cell growth and wasting did not alter gain or loss of muscle mass respectively. Our data demonstrate that although the miR-206/HDAC4 axis operates in skeletal muscle, the post-natal expression of miR-206 is not a key regulator of basal skeletal muscle mass or specific modes of muscle growth and wasting. These studies support a context-dependent role of miR-206 in regulating hypertrophy that may be dispensable for maintaining or modifying the adult skeletal muscle phenotype--an important consideration in relation to the development of therapeutics designed to manipulate microRNA activity in musculature.

Published
2013
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22. Transduction of skeletal muscles with common reporter genes can promote muscle fiber degeneration and inflammation.

Author

Catherine E Winbanks, Claudia Beyer, Hongwei Qian, and Paul Gregorevic

Subjects
Medicine, Science
Abstract

Recombinant adeno-associated viral vectors (rAAV vectors) are promising tools for delivering transgenes to skeletal muscle, in order to study the mechanisms that control the muscle phenotype, and to ameliorate diseases that perturb muscle homeostasis. Many studies have employed rAAV vectors carrying reporter genes encoding for β-galactosidase (β-gal), human placental alkaline phosphatase (hPLAP), and green fluorescent protein (GFP) as experimental controls when studying the effects of manipulating other genes. However, it is not clear to what extent these reporter genes can influence signaling and gene expression signatures in skeletal muscle, which may confound the interpretation of results obtained in experimentally manipulated muscles. Herein, we report a strong pro-inflammatory effect of expressing reporter genes in skeletal muscle. Specifically, we show that the administration of rAAV6:hPLAP vectors to the hind limb muscles of mice is associated with dose- and time-dependent macrophage recruitment, and skeletal muscle damage. Dose-dependent expression of hPLAP also led to marked activity of established pro-inflammatory IL-6/Stat3, TNFα, IKKβ and JNK signaling in lysates obtained from homogenized muscles. These effects were independent of promoter type, as expression cassettes featuring hPLAP under the control of constitutive CMV and muscle-specific CK6 promoters both drove cellular responses when matched for vector dose. Importantly, the administration of rAAV6:GFP vectors did not induce muscle damage or inflammation except at the highest doses we examined, and administration of a transgene-null vector (rAAV6:MCS) did not cause damage or inflammation at any of the doses tested, demonstrating that GFP-expressing, or transgene-null vectors may be more suitable as experimental controls. The studies highlight the importance of considering the potential effects of reporter genes when designing experiments that examine gene manipulation in vivo.

Published
2012
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23. Functional deficits in nNOSmu-deficient skeletal muscle: myopathy in nNOS knockout mice.

Author

Justin M Percival, Kendra N E Anderson, Paul Gregorevic, Jeffrey S Chamberlain, and Stanley C Froehner

Subjects
Medicine, Science
Abstract

Skeletal muscle nNOSmu (neuronal nitric oxide synthase mu) localizes to the sarcolemma through interaction with the dystrophin-associated glycoprotein (DAG) complex, where it synthesizes nitric oxide (NO). Disruption of the DAG complex occurs in dystrophinopathies and sarcoglycanopathies, two genetically distinct classes of muscular dystrophy characterized by progressive loss of muscle mass, muscle weakness and increased fatigability. DAG complex instability leads to mislocalization and downregulation of nNOSmu; but this is thought to play a minor role in disease pathogenesis. This view persists without knowledge of the role of nNOS in skeletal muscle contractile function in vivo and has influenced gene therapy approaches to dystrophinopathy, the majority of which do not restore sarcolemmal nNOSmu. We address this knowledge gap by evaluating skeletal muscle function in nNOS knockout (KN1) mice using an in situ approach, in which the muscle is maintained in its normal physiological environment. nNOS-deficiency caused reductions in skeletal muscle bulk and maximum tetanic force production in male mice only. Furthermore, nNOS-deficient muscles from both male and female mice exhibited increased susceptibility to contraction-induced fatigue. These data suggest that aberrant nNOSmu signaling can negatively impact three important clinical features of dystrophinopathies and sarcoglycanopathies: maintenance of muscle bulk, force generation and fatigability. Our study suggests that restoration of sarcolemmal nNOSmu expression in dystrophic muscles may be more important than previously appreciated and that it should be a feature of any fully effective gene therapy-based intervention.

Published
2008
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24. Liver-Secreted Hexosaminidase A Regulates Insulin-Like Growth Factor Signaling and Glucose Transport in Skeletal Muscle

Author

Magdalene K. Montgomery, Jacqueline Bayliss, Shuai Nie, William de Nardo, Stacey N. Keenan, Marziyeh Anari, Amanuiel Z. Taddese, Nicholas A. Williamson, Geraldine J. Ooi, Wendy A. Brown, Paul R. Burton, Paul Gregorevic, Craig A. Goodman, Kevin I. Watt, and Matthew J. Watt

Subjects
Endocrinology, Diabetes and Metabolism, Internal Medicine
Abstract

Non-alcoholic fatty liver disease (NAFLD) and impaired glycaemic control are closely linked, however, the pathophysiological mechanisms underpinning this bidirectional relationship remain unresolved. The high secretory capacity of the liver and impairments in protein secretion in NAFLD suggest that endocrine changes in the liver are likely to contribute to glycaemic defects. We identify hexosaminidase A (HEXA) as a NAFLD-induced hepatokine in both mice and humans. HEXA regulates sphingolipid metabolism, converting GM2 to GM3 gangliosides; sphingolipids that are primarily localized to cell surface lipid rafts. Using recombinant murine HEXA protein, an enzymatically inactive HEXA(R178H) mutant, or adeno-associated viral vectors to induce hepatocyte-specific overexpression of HEXA, we show that HEXA improves blood glucose control by increasing skeletal muscle glucose uptake in mouse models of insulin resistance and type 2 diabetes, with these effects being dependent on HEXA’s enzymatic action. Mechanistically, HEXA remodels muscle lipid raft ganglioside composition, thereby increasing insulin-like growth factor 1 signalling and glucose transporter 4 localization to the cell surface. Disrupting lipid rafts reverses these HEXA-mediated effects. Together, this study identifies a novel pathway for inter-tissue communication between liver and skeletal muscle in the regulation of systemic glycaemic control.

Published
2022

25. Statins activate the NLRP3 inflammasome and inhibit the Hippo pathway to promote myopathy

Author

Nazli Robin, Nicole Barra, Danish Patoli, Kevin Watt, Khang Nguyen, Kevin Foley, Yujin Li, Akhilesh Tamrakar, Irena Rebalka, Michael Huang, Rhianna Davis, Darryl Chan, Brittany Duggan, Brandyn Henriksbo, Paul Gregorevic, Gary Sweeney, Thomas Hawke, Benedicte Py, and Jonathan Schertzer

Subjects
Physiology
Abstract

High blood cholesterol affects ~30% of adult Canadians and doubles the risk of cardiac events. Statins are widely used for lowering cholesterol levels, but statins have pleiotropic effects that can be mediated by lowering protein prenylation. The most prevalent side effect of statin therapy is myopathy. Overt myotoxicity and rhabdomyolysis are rare (S127A) in C2C12 mitigated statin-mediated increases in atrogin-1 and lower myotube diameter compared to vector/vehicle controls in LPS primed myotubes. Statins also promoted the nuclear accumulation of FOXO1 and decreased levels of phosphorylated FOXO1/3a. Restoring protein prenylation and blocking the NLRP3 inflammasome prevented statin-induced nuclear accumulation of FOXO1 and mitigated decreased levels of p-FOXO1/3a. These results showed that prenylation and activation of NLRP3 inflammasome are both upstream of the FOXO activation. Our results demonstrated that activation of YAP in the presence of statins mitigated measures of statin-induced myopathy and that NLRP3 activation is upstream of FOXO activation, which is a known regulator of Atrogin-1. Further investigation to characterize the mechanism of statin-induced myopathy can lead to an enhanced understanding of statin-induced myopathy and the establishment of next-generation statin therapies without muscular side effects. Natural Sciences and Engineering Research Council (NSERC) of Canada This is the full abstract presented at the American Physiology Summit 2023 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Published
2023

27. Data from Differential Effects of IL6 and Activin A in the Development of Cancer-Associated Cachexia

Author

Paul Gregorevic, Craig A. Harrison, Matthew J. Watt, Adam Hagg, Timothy D. Colgan, Hongwei Qian, Kelly L. Walton, and Justin L. Chen

Abstract

Cachexia is a life-threatening wasting syndrome lacking effective treatment, which arises in many cancer patients. Although ostensibly induced by multiple tumor-produced cytokines (tumorkines), their functional contribution to initiation and progression of this syndrome has proven difficult to determine. In this study, we used adeno-associated viral vectors to elevate circulating levels of the tumorkines IL6 and/or activin A in animals in the absence of tumors as a tactic to evaluate hypothesized roles in cachexia development. Mice with elevated levels of IL6 exhibited 8.1% weight loss after 9 weeks, whereas mice with elevated levels of activin A lost 11% of their body weight. Co-elevation of both tumorkines to levels approximating those observed in cancer cachexia models induced a more rapid and profound body weight loss of 15.4%. Analysis of body composition revealed that activin A primarily triggered loss of lean mass, whereas IL6 was a major mediator of fat loss. Histologic and transcriptional analysis of affected organs/tissues (skeletal muscle, fat, and liver) identified interactions between the activin A and IL6 signaling pathways. For example, IL6 exacerbated the detrimental effects of activin A in skeletal muscle, whereas activin A curbed the IL6-induced acute-phase response in liver. This study presents a useful model to deconstruct cachexia, opening a pathway to determining which tumorkines are best targeted to slow/reverse this devastating condition in cancer patients. Cancer Res; 76(18); 5372–82. ©2016 AACR.

Published
2023

32. Supplementary figure 6 from Differential Effects of IL6 and Activin A in the Development of Cancer-Associated Cachexia

Author

Paul Gregorevic, Craig A. Harrison, Matthew J. Watt, Adam Hagg, Timothy D. Colgan, Hongwei Qian, Kelly L. Walton, and Justin L. Chen

Abstract

In mice injected with rAAV6:activin A and/or rAAV6:IL-6, the mRNA expression of E3 ubiquitin ligases was determined in quadriceps muscles. In addition, skeletal muscle, epididymal WAT and BAT depots were probed for IL-6 target genes or genes involved in lipolysis and browning.

Published
2023

33. Supplementary figure 1 from Differential Effects of IL6 and Activin A in the Development of Cancer-Associated Cachexia

Author

Paul Gregorevic, Craig A. Harrison, Matthew J. Watt, Adam Hagg, Timothy D. Colgan, Hongwei Qian, Kelly L. Walton, and Justin L. Chen

Abstract

Mice bearing colon-26 tumors rapidly lose lean and fat mass, together with significant wasting of muscle groups. These losses correlate with increases in the phosphorylation of the transcription factors, Stat3 and Smad3, which are activated by IL-6 and activin A, respectively. Smad3 target genes are also altered in cachectic mice.

Published
2023

37. Class IIa HDACs inhibit cell death pathways and protect muscle integrity in response to lipotoxicity

Author

Sheree D. Martin, Timothy Connor, Andrew Sanigorski, Kevin A. McEwen, Darren C. Henstridge, Brunda Nijagal, David De Souza, Dedreia L. Tull, Peter J. Meikle, Greg M. Kowalski, Clinton R. Bruce, Paul Gregorevic, Mark A. Febbraio, Fiona M. Collier, Ken R. Walder, and Sean L. McGee

Abstract

Lipotoxicity, the accumulation of lipids in non-adipose tissues, alters the metabolic transcriptome and mitochondrial metabolism in skeletal muscle. The mechanisms involved remain poorly understood. Here we show that lipotoxicity increased histone deacetylase 4 (HDAC4) and histone deacetylase 5 (HDAC5), which reduced the expression of metabolic genes and oxidative metabolism in skeletal muscle. This metabolic reprogramming was linked with reduced expression of p53 pathway genes that mediate apoptosis and ferroptosis, as well as preserved muscle cell viability in response to lipotoxicity. Mechanistically, increased HDAC4 and 5 decreased acetylation of p53 at K120, a modification required for transcriptional activation of apoptosis, while metabolically sensitive redox drivers of ferroptosis were also reduced. Overexpression of loss-of-function HDAC4 and HDAC5 mutants in skeletal muscle of obesedb/dbmice enhanced oxidative capacity, increased apoptosis and ferroptosis and reduced muscle mass. This study identifies HDAC4 and HDAC5 as repressors of the oxidative state of skeletal muscle, which is linked to inhibition of cell death pathways and preservation of muscle integrity in response to lipotoxicity.

Published
2022

38. Intravascular Follistatin gene delivery improves glycemic control in a mouse model of type 2 diabetes

Author

Mark A. Febbraio, Darren C. Henstridge, Paul Gregorevic, Jonathan R. Davey, Hongwei Qian, Helen Ludlow, Mark P. Hedger, Martin Whitham, Melinda T. Coughlan, Sean L. McGee, Adam Hagg, Rachel E. Thomson, Emma Estevez, and Kevin I. Watt

Subjects
0301 basic medicine, Follistatin, endocrine system, medicine.medical_specialty, medicine.medical_treatment, Glucose uptake, Glycemic Control, Type 2 diabetes, Biochemistry, Diabetes Mellitus, Experimental, Mice, 03 medical and health sciences, 0302 clinical medicine, Insulin resistance, Internal medicine, Diabetes mellitus, Genetics, medicine, Animals, Molecular Biology, Glycemic, biology, business.industry, Insulin, Gene Transfer Techniques, Skeletal muscle, Genetic Therapy, medicine.disease, 030104 developmental biology, Endocrinology, medicine.anatomical_structure, Diabetes Mellitus, Type 2, Hyperglycemia, biology.protein, Administration, Intravenous, Insulin Resistance, business, hormones, hormone substitutes, and hormone antagonists, 030217 neurology & neurosurgery, Biotechnology
Abstract

Type 2 diabetes (T2D) manifests from inadequate glucose control due to insulin resistance, hypoinsulinemia, and deteriorating pancreatic β-cell function. The pro-inflammatory factor Activin has been implicated as a positive correlate of severity in T2D patients, and as a negative regulator of glucose uptake by skeletal muscle, and of pancreatic β-cell phenotype in mice. Accordingly, we sought to determine whether intervention with the Activin antagonist Follistatin can ameliorate the diabetic pathology. Here, we report that an intravenous Follistatin gene delivery intervention with tropism for striated muscle reduced the serum concentrations of Activin B and improved glycemic control in the db/db mouse model of T2D. Treatment reversed the hyperglycemic progression with a corresponding reduction in the percentage of glycated-hemoglobin to levels similar to lean, healthy mice. Follistatin gene delivery promoted insulinemia and abundance of insulin-positive pancreatic β-cells, even when treatment was administered to mice with advanced diabetes, supporting a mechanism for improved glycemic control associated with maintenance of functional β-cells. Our data demonstrate that single-dose intravascular Follistatin gene delivery can ameliorate the diabetic progression and improve prognostic markers of disease. These findings are consistent with other observations of Activin-mediated mechanisms exerting deleterious effects in models of obesity and diabetes, and suggest that interventions that attenuate Activin signaling could help further understanding of T2D and the development of novel T2D therapeutics.

Published
2020

39. Mechanisms involved in follistatin‐induced hypertrophy and increased insulin action in skeletal muscle

Author

Erik A. Richter, Zhencheng Li, Jonathan R. Davey, Kirstine N. Bojsen-Møller, Jonas R. Knudsen, Thomas E. Jensen, Carlos Henríquez-Olguín, Lykke Sylow, Lisbeth L. V. Møller, Estelle De Groote, Paul Gregorevic, Xiuqing Han, and Sten Madsbad

Subjects
Male, 0301 basic medicine, Follistatin, lcsh:Diseases of the musculoskeletal system, Glucose uptake, medicine.medical_treatment, Muscle wasting, Muscle hypertrophy, Mice, 0302 clinical medicine, Parvovirinae, Glycaemic control, Faculty of Science, Orthopedics and Sports Medicine, Inhibin-beta Subunits, biology, TBC1D1, lcsh:Human anatomy, Dependovirus, Muscular Atrophy, medicine.anatomical_structure, 030220 oncology & carcinogenesis, Original Article, Female, Signal Transduction, TGF-β, Adult, medicine.medical_specialty, Genetic Vectors, Gastric Bypass, lcsh:QM1-695, 03 medical and health sciences, Insulin resistance, Physiology (medical), Internal medicine, TGF beta signaling pathway, medicine, Animals, Humans, Obesity, Muscle, Skeletal, Protein kinase B, TGF‐β, business.industry, Insulin, Skeletal muscle, Original Articles, medicine.disease, Rats, HEK293 Cells, 030104 developmental biology, Endocrinology, biology.protein, lcsh:RC925-935, business
Abstract

BackgroundSkeletal muscle wasting is often associated with insulin resistance. A major regulator of muscle mass is the transforming growth factor β (TGF-β) superfamily, including activin A, which causes atrophy. TGF-β superfamily ligands also negatively regulate insulin-sensitive proteins, but whether this pathway contributes to insulin action remains to be determined.MethodsTo elucidate if TGF-β superfamily ligands regulate insulin action we used an adeno-associated virus gene editing approach to overexpress the activin A inhibitor, follistatin (Fst288) in mouse muscle of lean and diet-induced obese mice. We determined basal and insulin-stimulated 2 deoxy-glucose uptake using isotopic tracers in vivo. Furthermore, to evaluate whether circulating Fst and activin A concentrations are associated with obesity, insulin resistance, and weight loss in humans we analysed serum from morbidly obese subjects before, 1 week, and 1 year after Roux-en-Y gastric bypass (RYGB).ResultsFst288 muscle overexpression markedly increased in vivo insulin-stimulated (but not basal) glucose uptake (+75%, pConclusionsWe here present evidence that Fst is a potent regulator of insulin action in muscle and in addition to AKT and p70S6K, we identify TBC1D1, TBC1D4 and PAK1 as Fst targets. A possible role for Fst in regulating glycemic control is suggested because circulating Fst more than doubled post RYGB surgery, a treatment that markedly improved insulin sensitivity. These findings demonstrate the therapeutic potential of inhibiting TGF-β superfamily ligands to improve insulin action and Fst’s relevance to muscle wasting associated insulin resistant conditions in mice and humans.

Published
2019

40. A Step-By-Step Method to Detect Neutralizing Antibodies Against AAV using a Colorimetric Cell-Based Assay

Author

Julie R. McMullen, Kate L. Weeks, Paul Gregorevic, Clive N. May, Colleen J. Thomas, and Sebastian Bass-Stringer

Subjects
Sheep, General Immunology and Microbiology, General Chemical Engineering, General Neuroscience, Genetic Vectors, Animals, Colorimetry, Dependovirus, Antibodies, Viral, Antibodies, Neutralizing, General Biochemistry, Genetics and Molecular Biology
Abstract

Recombinant adeno-associated viruses (rAAV) have proven to be a safe and successful vector for transferring genetic material to treat various health conditions in both the laboratory and the clinic. However, pre-existing neutralizing antibodies (NAbs) against AAV capsids pose an ongoing challenge for the successful administration of gene therapies in both large animal experimental models and human populations. Preliminary screening for host immunity against AAV is necessary to ensure the efficacy of AAV-based gene therapies as both a research tool and as a clinically viable therapeutic agent. This protocol describes a colorimetric in vitro assay to detect neutralizing factors against AAV serotype 6 (AAV6). The assay utilizes the reaction between an AAV encoding an alkaline phosphatase (AP) reporter gene and its substrate NBT/BCIP, which generates an insoluble quantifiable purple stain upon combination. In this protocol, serum samples are combined with an AAV expressing AP and incubated to permit potential neutralizing activity to occur. Virus serum mixture is subsequently added to cells to allow for viral transduction of any AAVs that have not been neutralized. The NBT/BCIP substrate is added and undergoes a chromogenic reaction, corresponding to viral transduction and neutralizing activity. The proportion of area colored is quantitated using a free software tool to generate neutralizing titers. This assay displays a strong positive correlation between coloration and viral concentration. Assessment of serum samples from sheep before and after administration of a recombinant AAV6 led to a dramatic increase in neutralizing activity (125 to10,000-fold increase). The assay displayed adequate sensitivity to detect neutralizing activity in1:32,000 serum dilutions. This assay provides a simple, rapid, and cost-effective method to detect NAbs against AAVs.

Published
2021

41. Expanding the MuRF1 Universe with Quantitative Ubiquitylomics

Author

Paul Gregorevic, Benjamin L. Parker, and Craig A. Goodman

Subjects
Physics, AcademicSubjects/SCI01360, muscle atrophy, electroporation, AcademicSubjects/SCI01270, media_common.quotation_subject, Astronomy, MuRF1, Universe, ubiquitin proteomics, protein degradation, AcademicSubjects/SCI00960, AcademicSubjects/MED00772, media_common, Original Research, Research Article
Abstract

MuRF1 (TRIM63) is a muscle-specific E3 ubiquitin ligase and component of the ubiquitin proteasome system. MuRF1 is transcriptionally upregulated under conditions that cause muscle loss, in both rodents and humans, and is a recognized marker of muscle atrophy. In this study, we used in vivo electroporation to determine whether MuRF1 overexpression alone can cause muscle atrophy and, in combination with ubiquitin proteomics, identify the endogenous MuRF1 substrates in skeletal muscle. Overexpression of MuRF1 in adult mice increases ubiquitination of myofibrillar and sarcoplasmic proteins, increases expression of genes associated with neuromuscular junction instability, and causes muscle atrophy. A total of 169 ubiquitination sites on 56 proteins were found to be regulated by MuRF1. MuRF1-mediated ubiquitination targeted both thick and thin filament contractile proteins, as well as, glycolytic enzymes, deubiquitinases, p62, and VCP. These data reveal a potential role for MuRF1 in not only the breakdown of the sarcomere but also the regulation of metabolism and other proteolytic pathways in skeletal muscle.

Published
2021

42. Phosphoproteomics of three exercise modalities identifies canonical signaling and C18ORF25 as an AMPK substrate regulating skeletal muscle function

Author

Ronnie Blazev, Christian S. Carl, Yaan-Kit Ng, Jeffrey Molendijk, Christian T. Voldstedlund, Yuanyuan Zhao, Di Xiao, Andrew J. Kueh, Paula M. Miotto, Vanessa R. Haynes, Justin P. Hardee, Jin D. Chung, James W. McNamara, Hongwei Qian, Paul Gregorevic, Jonathan S. Oakhill, Marco J. Herold, Thomas E. Jensen, Leszek Lisowski, Gordon S. Lynch, Garron T. Dodd, Matthew J. Watt, Pengyi Yang, Bente Kiens, Erik A. Richter, and Benjamin L. Parker

Subjects
Mice, Physiology, Muscle Fibers, Skeletal, Animals, Humans, Cell Biology, AMP-Activated Protein Kinases, Phosphorylation, Muscle, Skeletal, Exercise, Molecular Biology, Adaptor Proteins, Signal Transducing, Signal Transduction
Abstract

Exercise induces signaling networks to improve muscle function and confer health benefits. To identify divergent and common signaling networks during and after different exercise modalities, we performed a phosphoproteomic analysis of human skeletal muscle from a cross-over intervention of endurance, sprint, and resistance exercise. This identified 5,486 phosphosites regulated during or after at least one type of exercise modality and only 420 core phosphosites common to all exercise. One of these core phosphosites was S67 on the uncharacterized protein C18ORF25, which we validated as an AMPK substrate. Mice lacking C18ORF25 have reduced skeletal muscle fiber size, exercise capacity, and muscle contractile function, and this was associated with reduced phosphorylation of contractile and Casup2+/suphandling proteins. Expression of C18ORF25 S66/67D phospho-mimetic reversed the decreased muscle force production. This work defines the divergent and canonical exercise phosphoproteome across different modalities and identifies C18ORF25 as a regulator of exercise signaling and muscle function.

Published
2022

43. ACTN3 genotype influences skeletal muscle mass regulation and response to dexamethasone

Author

Lucinda Bek, Kelly N. Roeszler, Siaw F. Lee, Peter J. Houweling, Harrison D. Wood, Paul Gregorevic, Jane T. Seto, Lyra R. Meehan, Chrystal F. Tiong, Kathryn N. North, Manan Shah, and Kate G. R. Quinlan

Subjects
medicine.medical_specialty, Duchenne muscular dystrophy, Population, Myostatin, 03 medical and health sciences, 0302 clinical medicine, Atrophy, Internal medicine, medicine, education, Wasting, Dexamethasone, 030304 developmental biology, Denervation, 0303 health sciences, education.field_of_study, Multidisciplinary, biology, business.industry, Skeletal muscle, medicine.disease, Endocrinology, medicine.anatomical_structure, Sarcopenia, biology.protein, medicine.symptom, business, 030217 neurology & neurosurgery, Glucocorticoid, medicine.drug
Abstract

Homozygosity for the common ACTN3 null polymorphism (ACTN3 577X) results in α-actinin-3 deficiency in ~20% of humans worldwide and is linked to reduced sprint and power performance in both elite athletes and the general population. α-Actinin-3 deficiency is also associated with reduced muscle mass and strength, increased risk of sarcopenia in the elderly, and altered response to muscle wasting induced by denervation and immobilisation. ACTN3 genotype is also a disease modifier for Duchenne muscular dystrophy (DMD), with α-actinin-3 deficiency associated with slower disease progression. Here we show that α-actinin-3 plays a key role in the regulation of protein synthesis and breakdown signalling in skeletal muscle, and its influence on muscle mass begins during early postnatal muscle development. Actn3 genotype also influences the skeletal muscle response to the glucocorticoid dexamethasone. Following acute dexamethasone exposure, transcriptomic analyses by RT-qPCR and RNA-sequencing show reduced atrophy signalling (Mstn, Tmem100, mRas, Fbxo32, Trim63) and anti-inflammatory response in α-actinin-3 deficient mice compared to wild-type. α-Actinin-3 deficiency also protects against muscle wasting following prolonged daily treatment with dexamethasone in female, but not male mice. In combination, these data suggest that ACTN3 R577X is a pharmacogenetic variant influencing the anti-inflammatory and muscle wasting response to glucocorticoid therapy.

Published
2021

44. The E3 ligase MARCH5 is a PPARγ target gene that regulates mitochondria and metabolism in adipocytes

Author

Aldons J. Lusis, Simon T. Bond, Darren C. Henstridge, Bronwyn A. Kingwell, Sarah C. Moody, Yingying Liu, Andrea L. Hevener, Brian G. Drew, Anna C. Calkin, Paul Gregorevic, Mete Civelek, and Claudio J. Villanueva

Subjects
Adult, Male, 0301 basic medicine, medicine.medical_specialty, Physiology, Ubiquitin-Protein Ligases, Endocrinology, Diabetes and Metabolism, Peroxisome proliferator-activated receptor, Mitochondrion, Mitochondrial Proteins, Mice, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, 3T3-L1 Cells, Physiology (medical), Internal medicine, Adipocyte, Mitophagy, Adipocytes, medicine, Animals, Humans, Obesity, MARCH5, Metabolic Syndrome, Mice, Knockout, chemistry.chemical_classification, Adipogenesis, biology, Membrane Proteins, Lipid metabolism, Middle Aged, Mitochondria, Ubiquitin ligase, Cell biology, PPAR gamma, 030104 developmental biology, Endocrinology, Adipose Tissue, chemistry, Gene Knockdown Techniques, biology.protein, 030217 neurology & neurosurgery, Research Article
Abstract

Mitochondrial dynamics refers to the constant remodeling of mitochondrial populations by multiple cellular pathways that help maintain mitochondrial health and function. Disruptions in mitochondrial dynamics often lead to mitochondrial dysfunction, which is frequently associated with disease in rodents and humans. Consistent with this, obesity is associated with reduced mitochondrial function in white adipose tissue, partly via alterations in mitochondrial dynamics. Several proteins, including the E3 ubiquitin ligase membrane-associated RING-CH-type finger 5 (MARCH5), are known to regulate mitochondrial dynamics; however, the role of these proteins in adipocytes has been poorly studied. Here, we show that MARCH5 is regulated by peroxisome proliferator-activated receptor-γ (PPARγ) during adipogenesis and is correlated with fat mass across a panel of genetically diverse mouse strains, in ob/ob mice, and in humans. Furthermore, manipulation of MARCH5 expression in vitro and in vivo alters mitochondrial function, affects cellular metabolism, and leads to differential regulation of several metabolic genes. Thus our data demonstrate an association between mitochondrial dynamics and metabolism that defines MARCH5 as a critical link between these interconnected pathways.

Published
2019

45. Yap regulates skeletal muscle fatty acid oxidation and adiposity in metabolic disease

Author

Dorit Samocha-Bonet, Mark Ziemann, Matthew J. Watt, René Koopman, Adam Hagg, Jerry R. Greenfield, Magdalene K. Montgomery, Hongwei Qian, Garron T. Dodd, Simon T. Bond, Darren C. Henstridge, Rachel E. Thomson, Paul Gregorevic, Talhah M. Salmi, Assam El-Osta, K. F. Harvey, Mark A. Febbraio, Choon Boon Sim, Kevin I. Watt, Brian G. Drew, Andrew G. Cox, Jonathan R. Davey, Rachel S. Lee, Benjamin L. Parker, and Enzo R. Porrello

Subjects
Male, 0301 basic medicine, Cell biology, medicine.medical_specialty, Science, General Physics and Astronomy, Biology, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Mediator, Insulin resistance, Metabolic Diseases, Internal medicine, Diabetes mellitus, medicine, Animals, Obesity, Muscle, Skeletal, Beta oxidation, Adaptor Proteins, Signal Transducing, Adiposity, Mice, Knockout, Hippo signaling pathway, Multidisciplinary, Reverse Transcriptase Polymerase Chain Reaction, Fatty Acids, Skeletal muscle, YAP-Signaling Proteins, General Chemistry, Metabolism, medicine.disease, Mice, Inbred C57BL, 030104 developmental biology, Endocrinology, medicine.anatomical_structure, Gene Expression Regulation, Lipotoxicity, RNA Interference, Insulin Resistance, Oxidation-Reduction, 030217 neurology & neurosurgery
Abstract

Obesity is a major risk factor underlying the development of metabolic disease and a growing public health concern globally. Strategies to promote skeletal muscle metabolism can be effective to limit the progression of metabolic disease. Here, we demonstrate that the levels of the Hippo pathway transcriptional co-activator YAP are decreased in muscle biopsies from obese, insulin-resistant humans and mice. Targeted disruption of Yap in adult skeletal muscle resulted in incomplete oxidation of fatty acids and lipotoxicity. Integrated ‘omics analysis from isolated adult muscle nuclei revealed that Yap regulates a transcriptional profile associated with metabolic substrate utilisation. In line with these findings, increasing Yap abundance in the striated muscle of obese (db/db) mice enhanced energy expenditure and attenuated adiposity. Our results demonstrate a vital role for Yap as a mediator of skeletal muscle metabolism. Strategies to enhance Yap activity in skeletal muscle warrant consideration as part of comprehensive approaches to treat metabolic disease., The mechanisms driving metabolic dysfunction in obesity remain incompletely understood. Here, the authors show that the levels of Hippo pathway effector YAP are reduced in muscle from individuals with insulin resistance and obese-diabetic mice, and that YAP promotes skeletal muscle lipid metabolism and limits adiposity in obese mice.

Published
2021

46. Tissue-specific expression of Cas9 has no impact on whole-body metabolism in four transgenic mouse lines

Author

Aowen Zhuang, Eleanor A.M. Gould, Julie R. McMullen, Anna C. Calkin, Simon T. Bond, Ying Fu, Yanie Tan, Paul Gregorevic, Tim Sikora, Yingying Liu, Christine Yang, Helen Kiriazis, Kevin I. Watt, Brian G. Drew, Darren C. Henstridge, Peter J. Meikle, and Graeme I. Lancaster

Subjects
Genetically modified mouse, Male, Transgene, Adipose tissue, Mice, Transgenic, Biology, Mice, Technical Report, Genome editing, Fibrosis, CRISPR-Associated Protein 9, medicine, CRISPR, Animals, Transgenic mice, Cas9, Internal medicine, Molecular Biology, Gene, Cell Biology, medicine.disease, RC31-1245, Phenotype, Cell biology, Mice, Inbred C57BL, Metabolism, Tissue specific, CRISPR-Cas Systems
Abstract

Objective CRISPR/Cas9 technology has revolutionized gene editing and fast tracked our capacity to manipulate genes of interest for the benefit of both research and therapeutic applications. Whilst many advances have, and continue to be made in this area, perhaps the most utilized technology to date has been the generation of knockout cells, tissues and animals. The advantages of this technology are many fold, however some questions still remain regarding the effects that long term expression of foreign proteins such as Cas9, have on mammalian cell function. Several studies have proposed that chronic overexpression of Cas9, with or without its accompanying guide RNAs, may have deleterious effects on cell function and health. This is of particular concern when applying this technology in vivo, where chronic expression of Cas9 in tissues of interest may promote disease-like phenotypes and thus confound the investigation of the effects of the gene of interest. Although these concerns remain valid, no study to our knowledge has yet to demonstrate this directly. Methods In this study we used the lox-stop-lox (LSL) spCas9 ROSA26 transgenic (Tg) mouse line to generate four tissue-specific Cas9-Tg models that express Cas9 in the heart, liver, skeletal muscle or adipose tissue. We performed comprehensive phenotyping of these mice up to 20-weeks of age and subsequently performed molecular analysis of their organs. Results We demonstrate that Cas9 expression in these tissues had no detrimental effect on whole body health of the animals, nor did it induce any tissue-specific effects on whole body energy metabolism, liver health, inflammation, fibrosis, heart function or muscle mass. Conclusions Our data suggests that these models are suitable for studying the tissue specific effects of gene deletion using the LSL-Cas9-Tg model, and that phenotypes observed utilizing these models can be confidently interpreted as being gene specific, and not confounded by the chronic overexpression of Cas9., Highlights • Detailed characterization of 4 tissue specific Cas9 TG mice in relevant metabolic tissues. • Demonstration that these models express robust Cas9 in a tissue specific manner. • Detailed phenotyping demonstrates that chronic Cas9 expression has no impact on tissue weight, body composition or body weight. • Metabolic phenotyping demonstrates that Cas9 expression does not impact whole body glucose tolerance, or heart function. • Tissue specific characterization confirms that there is no discernible effect on tissue health or function.

Published
2021

47. The regulation of polyamine pathway proteins in models of skeletal muscle hypertrophy and atrophy: a potential role for mTORC1

Author

Alan Hayes, Dean G Campelj, Craig A. Goodman, Michael Tabbaa, Tania Ruz Gomez, and Paul Gregorevic

Subjects
0301 basic medicine, Adenosylmethionine Decarboxylase, Physiology, Muscle Proteins, mTORC1, Mechanistic Target of Rapamycin Complex 1, Spermidine Synthase, Muscle hypertrophy, 03 medical and health sciences, chemistry.chemical_compound, Mice, 0302 clinical medicine, Acetyltransferases, medicine, Polyamines, Animals, Muscle, Skeletal, biology, Protein turnover, Skeletal muscle, Cell Biology, Hypertrophy, Muscle atrophy, Cell biology, Spermidine, Muscular Atrophy, 030104 developmental biology, medicine.anatomical_structure, chemistry, Spermine synthase, 030220 oncology & carcinogenesis, biology.protein, Female, biological phenomena, cell phenomena, and immunity, medicine.symptom, Polyamine, Signal Transduction
Abstract

Polyamines have been shown to be absolutely required for protein synthesis and cell growth. The serine/threonine kinase, the mechanistic target of rapamycin complex 1 (mTORC1), also plays a fundamental role in the regulation of protein turnover and cell size, including in skeletal muscle, where mTORC1 is sufficient to increase protein synthesis and muscle fiber size, and is necessary for mechanical overload-induced muscle hypertrophy. Recent evidence suggests that mTORC1 may regulate the polyamine metabolic pathway, however, there is currently no evidence in skeletal muscle. This study examined changes in polyamine pathway proteins during muscle hypertrophy induced by mechanical overload (7 days), with and without the mTORC1 inhibitor, rapamycin, and during muscle atrophy induced by food deprivation (48 h) and denervation (7 days) in mice. Mechanical overload induced an increase in mTORC1 signaling, protein synthesis and muscle mass, and these were associated with rapamycin-sensitive increases in adenosylmethione decarboxylase 1 (Amd1), spermidine synthase (SpdSyn), and c-Myc. Food deprivation decreased mTORC1 signaling, protein synthesis, and muscle mass, accompanied by a decrease in spermidine/spermine acetyltransferase 1 (Sat1). Denervation, resulted increased mTORC1 signaling and protein synthesis, and decreased muscle mass, which was associated with an increase in SpdSyn, spermine synthase (SpmSyn), and c-Myc. Combined, these data show that polyamine pathway enzymes are differentially regulated in models of altered mechanical and metabolic stress, and that Amd1 and SpdSyn are, in part, regulated in a mTORC1-dependent manner. Furthermore, these data suggest that polyamines may play a role in the adaptive response to stressors in skeletal muscle.

Published
2021

48. Detailed metabolic phenotyping of four tissue specific Cas9 transgenic mouse lines

Author

Graeme I. Lancaster, Paul Gregorevic, Kevin I. Watt, Brian G. Drew, Helen Kiriazis, Darren C. Henstridge, Eleanor A.M. Gould, Yingying Liu, McMullen, Ying Fu, Christine Yang, Simon T. Bond, Aowen Zhuang, Peter J. Meikle, Anna C. Calkin, Yanie Tan, and Tim Sikora

Subjects
Genetically modified mouse, Genome editing, Cas9, Transgene, Adipose tissue, CRISPR, Computational biology, Biology, Phenotype, Gene
Abstract

CRISPR/Cas9 technology has revolutionized gene editing and fast tracked our capacity to manipulate genes of interest for the benefit of both research and therapeutic applications. Whilst many advances have, and continue to be made in this area, perhaps the most utilized technology to date has been the generation of knockout cells, tissues and animals by taking advantage of Cas9 function to promote indels in precise locations in the genome. Whilst the advantages of this technology are many fold, some questions still remain regarding the effects that long term expression of foreign proteins such as Cas9, have on mammalian cell function. Several studies have proposed that chronic overexpression of Cas9, with or without its accompanying guide RNAs, may have deleterious effects on cell function and health. This is of particular concern when applying this technology in vivo, where chronic expression of Cas9 in tissues of interest may promote disease-like phenotypes and thus confound the investigation of the effects of the gene of interest. Although these concerns remain valid, no study to our knowledge has yet to demonstrate this directly. Thus, in this study we used the lox-stop-lox (LSL) spCas9 ROSA26 transgenic (Tg) mouse line to generate four tissue-specific Cas9-Tg models with expression in the heart, liver, skeletal muscle and adipose tissue. We performed comprehensive phenotyping of these mice up to 20-weeks of age and subsequently performed molecular analysis of their organs. We demonstrated that Cas9 expression in these tissues had no detrimental effect on whole body health of the animals, nor did it induce any tissue-specific effects on energy metabolism, liver health, inflammation, fibrosis, heart function or muscle mass. Thus, our data suggests that these models are suitable for studying the tissue specific effects of gene deletion using the LSL-Cas9-Tg model, and that phenotypes observed utilizing these models can be confidently interpreted as being gene specific, and not confounded by the chronic overexpression of Cas9.

Published
2021

49. Bone Geometry Is Altered by Follistatin‐Induced Muscle Growth in Young Adult Male Mice

Author

Ingrid J Poulton, T. John Martin, Ellie H-J Cho, Audrey S. M. Chan, Narelle E. McGregor, Paul Gregorevic, Justin P. Hardee, Gordon S. Lynch, and Natalie A. Sims

Subjects
CELL/TISSUE SIGNALING—PARACRINE PATHWAYS, medicine.medical_specialty, Endocrinology, Diabetes and Metabolism, Diseases of the musculoskeletal system, Myostatin, BONE–MUSCLE INTERACTION, Bone morphogenetic protein, Bone resorption, Muscle hypertrophy, PRECLINICAL STUDIES, Tibialis anterior muscle, Internal medicine, medicine, Orthopedics and Sports Medicine, Tibia, MOLECULAR PATHWAYS—REMODELING, TRANSFORMING GROWTH FACTOR β, BONE MORPHOGENETIC PROTEIN, Orthopedic surgery, biology, Original Articles, Endocrinology, SYSTEMS BIOLOGY—BONE INTERACTORS, RC925-935, ANIMAL MODELS, biology.protein, Original Article, BONE MODELING AND REMODELIN, medicine.symptom, RD701-811, Follistatin, Muscle contraction
Abstract

The development of the musculoskeletal system and its maintenance depends on the reciprocal relationship between muscle and bone. The size of skeletal muscles and the forces generated during muscle contraction are potent sources of mechanical stress on the developing skeleton, and they shape bone structure during growth. This is particularly evident in hypermuscular global myostatin (Mstn)‐null mice, where larger muscles during development increase bone mass and alter bone shape. However, whether muscle hypertrophy can similarly influence the shape of bones after the embryonic and prepubertal period is unknown. To address this issue, bone structure was assessed after inducing muscle hypertrophy in the lower hindlimbs of young‐adult C57BL/6J male mice by administering intramuscular injections of recombinant adeno‐associated viral vectors expressing follistatin (FST), a potent antagonist of Mstn. Two FST isoforms were used: the full‐length 315 amino acid isoform (FST‐315) and a truncated 288 amino acid isoform (FST‐288). In both FST‐treated cohorts, muscle hypertrophy was observed, and the anterior crest of the tibia, adjacent to the tibialis anterior muscle, was lengthened. Hypertrophy of the muscles surrounding the tibia caused the adjacent cortical shell to recede inward toward the central axis: an event driven by bone resorption adjacent to the hypertrophic muscle. The findings reveal that inducing muscle hypertrophy in mice can confer changes in bone shape in early adulthood. © 2021 The Authors. JBMR Plus published by Wiley Periodicals LLC on behalf of American Society for Bone and Mineral Research.

Published
2021

50. Loss of the Long Non-coding RNA OIP5-AS1 Exacerbates Heart Failure in a Sex-Specific Manner

Author

Julie R. McMullen, T. Q. de Aguiar Vallim, James E. Hudson, Aowen Zhuang, S. Lau, Elizabeth J. Tarling, Paul Gregorevic, Sarah C. Moody, Sergio Ruiz-Carmona, D. Donner, Xiao-Jun Du, Eleanor A.M. Gould, Yingying Liu, Xiao-Ming Gao, Helen Kiriazis, Brian G. Drew, Simon T. Bond, Gregory A. Quaife-Ryan, Michael Inouye, Enzo R. Porrello, Anna C. Calkin, and Timothy D. Colgan

Subjects
Pressure overload, Transcriptome, Heart failure, Cellular differentiation, medicine, Disease, Biology, medicine.disease, Bioinformatics, Gene, Phenotype, Long non-coding RNA
Abstract

BackgroundLong ncRNAs (lncRNAs) are known to influence numerous biological processes including cellular differentiation and tissue development. They are also implicated in the maintenance, health and physiological function of many tissues including the heart. Indeed, manipulating the expression of specific lncRNAs has been shown to improve pathological cardiac phenotypes such as heart failure. One lncRNA studied in various settings is OIP5-AS1 (also known as 1700020I14Rik and Cyrano), however its role in cardiac pathologies remains mostly uncharacterised.MethodsWe used data generated from FACS sorted murine cardiomyocytes, human iPSC derived cardiomyocytes, as well as heart tissue from various animal models to investigate OIP5-AS1 expression in health and disease. Using CRISPR we engineered a global OIP5-AS1 knock out (KO) mouse model and performed cardiac pressure overload experiments to study heart failure in these animals. RNA-sequencing of left ventricles provided mechanistic insight between WT and KO mice.ResultsWe demonstrate that OIP5-AS1 expression is regulated during cardiac development and cardiac specific pathologies in both rodent and human models. Moreover, we demonstrate that global female OIP5-AS1 KO mice develop exacerbated heart failure, but male mice do not. Transcriptomics and gene set enrichment analysis suggests that OIP5-AS1 may regulate pathways that impact mitochondrial function.ConclusionsOIP5-AS1 is regulated in cardiac tissue and its deletion leads to worsening heart function under pressure overload in female mice. This may be due to impairments in mitochondrial function, highlighting OIP5-AS1 as a gene of interest in sex-specific differences in heart failure.

Published
2021

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