Abstract
The thrombospondin (Thbs) family of secreted matricellular proteins are stress- and injury-induced mediators of cellular attachment dynamics and extracellular matrix protein production. Here we show that Thbs1, but not Thbs2, Thbs3 or Thbs4, induces lethal cardiac atrophy when overexpressed. Mechanistically, Thbs1 binds and activates the endoplasmic reticulum stress effector PERK, inducing its downstream transcription factor ATF4 and causing lethal autophagy-mediated cardiac atrophy. Antithetically, Thbs1−/− mice develop greater cardiac hypertrophy with pressure overload stimulation and show reduced fasting-induced atrophy. Deletion of Thbs1 effectors/receptors, including ATF6α, CD36 or CD47 does not diminish Thbs1-dependent cardiac atrophy. However, deletion of the gene encoding PERK in Thbs1 transgenic mice blunts the induction of ATF4 and autophagy, and largely corrects the lethal cardiac atrophy. Finally, overexpression of PERK or ATF4 using AAV9 gene-transfer similarly promotes cardiac atrophy and lethality. Hence, we identified Thbs1-mediated PERK-eIF2α-ATF4-induced autophagy as a critical regulator of cardiomyocyte size in the stressed heart.
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Introduction
Cardiomyocytes within the adult mammalian heart are refractory to proliferation, hence all changes in heart size in response to increased workload, unloading, stress, or disease stimulation occur through hypertrophy or atrophy of individual cardiomyocytes1. Effector pathways central to size change of cardiomyocytes include calcineurin/nuclear factor of activated T-cells, mitogen-activated protein kinases, the mechanistic target of rapamycin (mTOR)/protein kinase B (AKT)/Forkhead box O (FOXO) pathway, Atrogin-1/MuRF1, and autophagy. These pathways regulate protein turnover by balancing protein synthesis and protein degradation and in general, hypertrophic growth takes place when protein synthesis outweighs degradation, and atrophy occurs when degradation outpaces new protein synthesis2,3.
The endoplasmic reticulum (ER) is the site where secreted or membrane bound proteins are generated, and this subcellular compartment dynamically responds to stress signals in regulating total protein production4. Accumulation of misfolded proteins in the ER also activates a signaling cascade known as the unfolded protein response (UPR), or simply the ER stress response. Unfolded ER proteins or stress are indirectly detected by protein kinase R (PKR)-like ER kinase (PERK), activating transcription factor 6α (ATF6α), and inositol requiring enzyme 1 alpha (IRE1α)4. Activation of these three primary sensors results in downregulation of general protein synthesis while also inducing expression of ER resident chaperones to enhance protein folding capacity4. Autophagy is induced by select signals that degrade misfolded proteins via lysosomes to also help resolve proteotoxic stress and to provide metabolic reserve5. The PERK-eukaryotic translation initiation factor 2 α (eIF2α)-activating transcription factor 4 (ATF4) pathway is essential in detecting ER stress and the induction of autophagy to resolve accumulation of misfolded proteins via lysosomal degradation6,7.
The family of thrombospondin (Thbs) matricellular glycoproteins consists of five members (Thbs1-5), and while they are secreted as part of their life-cycle, they also function as intracellular chaperones that mediate the ER stress response, facilitate secretory pathway activity and extracellular matrix production, and facilitate membrane residence of attachment complexes8,9,10. Group A Thbs proteins form trimers that consist of Thbs1 and Thbs2, while group B Thbs proteins form pentamers that consist of Thbs3, Thbs4, and Thbs511. Discrete spatio- and temporal expression patterns characterize Thbs gene expression during development, although in adulthood expression of all 5 genes is typically only observed upon injury12. Single Thbs gene-deleted mice have been described with a wide variety of phenotypes, although we recently showed that quintuple Thbs1/2/3/4/5−/− mice are viable as adults9, highlighting the fact that these proteins primarily function in stress or injury resolution. In the heart, both Thbs3 and Thbs4 are induced with injury, yet overexpression of Thbs4 is protective while Thbs3 overexpression predisposes to disease with pressure overload stimulation8,9,13. Interestingly, Thbs3 uniquely leads to loss of integrin attachment complexes at the sarcolemma in promoting cardiomyopathy while Thbs4 augments membrane content of integrin and dystrophin-glycoprotein attachment complexes as part of its protective profile8,9,10.
Here we investigated the role of Thbs1 and observed that Thbs1 heart-specific transgenic mice have dramatically reduced heart size leading to lethal cardiomyopathy by 16 weeks of age. Mechanistically, Thbs1 but not Thbs3, activate ER-stress via the PERK-eIF2α-ATF4 pathway and prominent autophagic flux in the cardiomyocyte. Exacerbated autophagy, cardiac atrophy, and lethality associated with Thbs1 overexpression was largely rescued by deleting the gene encoding PERK (Eif2ak3). Moreover, direct AAV9-mediated overexpression of PERK or ATF4 in the heart drives autophagy and recapitulates the Thbs1-mediated cardiac phenotype. Finally, deletion of Thbs1 in mice protects from cardiac atrophy. Hence, we identify a Thbs1-mediated PERK-eIF2α-ATF4-induced autophagy pathway as a fundamental regulator of protein homeostasis in the stressed heart.
Results
Thbs1 is induced in diseased hearts where it mediates ER stress
Thbs1 protein expression is strongly induced in the adult mouse heart with injury or stress stimulation, such as during cardiac hypertrophy mediated by 2 weeks of transverse aortic constriction (TAC) or cardiomyocyte-specific overexpression of activated calcineurin (ΔCnA TG)14 (Fig. 1a). Thbs1 was also induced in the hearts of Csrp3−/− mice15, a model of dilated cardiomyopathy (Fig. 1a). Immunohistochemical characterization of hearts from ΔCnA TG mice (Fig. 1b) and mice subjected to 2 weeks of TAC (Fig. 1c) showed that Thbs1 protein was robustly induced and localized inside cardiomyocytes, with appreciably less Thbs1 protein expression observed within fibroblasts or endothelial cells as marked by vimentin expression.
To recapitulate the induction of Thbs1 during heart disease we generated cardiomyocyte-restricted transgenic mice overexpressing Thbs1 using an inducible α-myosin heavy chain (αMHC) promoter system. This inducible tetracycline-regulated double transgenic system16 allows for temporal regulation of transgene expression (Fig. 1d). Double transgenic (DTG) mice containing the Thbs1 and the tetracycline transactivator (tTA) transgenes were compared with animals only expressing tTA as controls (tTA cont.). The previously described transgenic mouse line with cardiomyocyte-specific overexpression of Thbs3 was used as a control for ER-stress induction by Thbs proteins in general9. Thbs1 DTG hearts showed expression of Thbs1 and an induction of ER resident chaperones Armet, BiP (binding immunoglobulin protein) and calreticulin (Calret.) as observed in Thbs3 DTG hearts (Fig. 1e). Immunohistochemical analysis revealed that Thbs1 predominantly localized inside the cardiomyocyte, where it co-localized with BiP in the ER compartment (Fig. 1f), similar to our previous observations with Thbs3 and Thbs4 overexpression in the heart and skeletal muscle9,10,13. Furthermore, ultrastructural analysis by transmission electron microscopy showed ER- and post-ER vesicular expansion in Thbs1 DTG hearts (Fig. 1g, arrows show vesicular expansion). Comparable results were previously described in transgenic animals overexpressing Thbs3 or Thbs4 in the heart and skeletal muscle9,10,13, suggesting similar ER residency and induction of the general ER stress response with Thbs1.
Cardiac Thbs1 expression induces lethal cardiac atrophy
Overexpression of Thbs3 or Thbs4 in the heart or skeletal muscle had no effect at baseline, and Thbs4 DTG hearts were even protected from decompensation induced by pressure overload or myocardial infarction injury9,10,13. However, cardiomyocyte-specific overexpression of Thbs1 showed a profound and progressive reduction in ventricular weight-to-body weight ratio (VW/BW) (Fig. 2a, b) starting at 4 weeks of age. Compared to tTA controls, Thbs1 DTG mice also displayed a significant reduction in fractional shortening and increased incidence of pulmonary edema at 6–7 weeks of age (Fig. 2c, d). Thbs1 overexpressing transgenic mice had reduced survival with no animals living past 16 weeks of age (Fig. 2e). Importantly, using doxycycline (Dox) to repress transgene expression and bypass effects during early postnatal development, we showed that adult-specific induction of Thbs1 expression in the heart still led to lethal cardiomyopathy, as none survived past 32 weeks of age (Fig. 2f, g). Analysis of these Thbs1 DTG (-Dox 3w) animals again revealed reduced VW/BW ratio (Fig. 2h) and diminished fractional shortening at 24 weeks of age (Fig. 2i).
We also examined mice in which the Thbs1 transgene was only active for the first 3 weeks of postnatal development, after which Dox was given (+Dox 3w) to continuously repress expression (Fig. 2j, k). With repression there was also reduced induction of BiP protein within the ER (Fig. 2k). Importantly, VW/BW ratio (Fig. 2l) and heart function (Fig. 2m) at 24 weeks of age were not affected by this early window of cardiac Thbs1 overexpression, indicating that Thbs1 did not inherently change cardiac cellularity or remodeling, but instead appeared to only affect growth/atrophy dynamics in real time.
Thbs1 in heart is independent of TGFβ and endothelial cells
Thbs1 release into the extracellular space can modify endothelial cell function by inhibiting proliferation or inducing cell death17. However, overexpression of Thbs1 in the heart had no effect on capillary number (Fig. 3a), endothelial cell proliferation as measured by 5-ethynyl-2´-deoxyuridine (EdU) incorporation (Fig. 3b) or apoptosis detected by terminal deoxynucleotidyl transferase dUTP nick end labeling (TUNEL) staining (Fig. 3c). Thbs1 has also been described as an endogenous activator of transforming growth factor-β (TGFβ)18. However, analysis of total and active levels of TGFβ by ELISA from heart tissue lysates showed no differences between Thbs1 DTG and tTA control mice (Fig. 3d, e).
The Thbs1 type-1 repeat domains are implicated in mediating inhibition of endothelial cell activity and in the direct binding and activation of TGFβ in vivo18,19. To analyze these potential effector functions in directing the atrophy phenotype, we generated a second Thbs1 overexpressing transgenic mouse line devoid of the Thbs1 type-1 repeat region (Thbs1Δt1 DTG) (Fig. 3f). Protein analysis revealed that both full-length Thbs1 and mutant Thbs1Δt1 are expressed and secreted in the extracellular matrix with the same efficiency (Fig. 3g). Importantly, cardiomyocyte-restricted overexpression of the Thbs1Δt1 showed a similar loss of heart mass and a significantly enhanced lethal phenotype compared to overexpression of full-length Thbs1 DTG, even though levels of the Thbs1Δt1 protein were ~50% lower compared with WT Thbs1 (Fig. 3h, i). Finally, we also generated cardiac-specific Thbs2 overexpressing DTG mice (Fig. 3j–l). This is mechanistically important because Thbs2 is in the same trimeric group A class as Thbs1, and both have the type-1 repeat domain11. However, Thbs2 overexpression (Fig. 3j) did not cause cardiac atrophy or cardiac dysfunction (Fig. 3k, l). Collectively, these results indicate that the lethal and cardiac atrophic phenotype observed with Thbs1 overexpression is not due to direct effects on cardiac endothelial cells or aberrant TGFβ activation in the heart.
CD47 and CD36 cell surface proteins were originally proposed to serve as Thbs1 receptors, where they mediate signaling associated with secreted extracellular Thbs111. While the field now understands that CD36 and CD47 are multiligand receptors with additional important functions in fatty acid transport and immune tolerance, respectively, we examined if these membrane proteins affected Thbs1-mediated cardiac atrophy. Hence, we crossed Thbs1 DTG mice with either Cd47−/− or Cd36−/− mice. Heart tissue extracts of Thbs1 DTG crossed with Cd47−/− mice showed complete absence of CD47 protein and slightly increased levels of Thbs1 in the heart compared to Thbs1 DTG hearts (Supplementary Fig. 1a). However, loss of Cd47 did not affect the Thbs1-mediated cardiac atrophy (Supplementary Fig. 1b), nor did it prolong survival of Thbs1 DTG Cd47−/− animals (Supplementary Fig. 1c). Deletion of Cd36−/− in the Thbs1 DTG background was confirmed by Western blot analysis (Supplementary Fig. 1d), which also had no effect on Thbs1-induced atrophy nor did it rescue the observed premature lethality (Supplementary Fig. 1e, f). Taken together, these results indicate that Thbs1-mediated cardiac atrophy and premature lethality are independent of CD36 or CD47.
Thbs3 and Thbs4 mediate ER stress and ER vesicular expansion through the transcription factor ATF6α20, and Thbs1 overexpression similarly induced ER stress and ER vesicular expansion (Fig. 1e, g). Here we crossed Thbs1 DTG mice into the Atf6−/− genetic background, which did not reduce the atrophy associated with the Thbs1 DTG, nor did it extend viability (Supplementary Fig. 1g, h). In fact, loss of ATF6α, as well as loss of CD36, significantly enhanced the cardiomyopathic lethal phenotype associated with Thbs1 overexpression in the heart (Supplementary Fig. 1f, h).
Thbs1 binds and activates a PERK-mediated ER-stress response
Overexpression of Thbs1, 3, and 4 in heart or skeletal muscle8,9,10,13 each induced a similar ER stress profile (Fig. 1e). However, Thbs1 was unique in that it alone caused lethal cardiomyopathy leading us to investigate more deeply into the ER stress response in the Thbs1 and Thbs3 transgenic hearts (Fig. 4a). Indeed, while both the Thbs1 and Thbs3 transgenic hearts displayed enhanced levels of nuclear ATF6α (ATF6α-N) and repressed IRE1α phosphorylation, Thbs1 strongly activated and induced the PERK-ATF4 ER stress effectors (Fig. 4a). Importantly, eIF2α phosphorylation was uniquely enhanced with Thbs1 overexpression, while ATF4 and its direct transcriptional target DNAJC3 were most highly induced in Thbs1 DTG hearts compared with tTA control or Thbs3 DTG hearts (Fig. 4a).
Previous studies have shown that Thbs proteins can interact with ER resident effectors while maturing in the secretory pathway, including BiP and ATF6α8,9,13,21. In line with these findings, immunoprecipitation (IP) experiments from protein extracts showed that Thbs1 and PERK interact in Thbs1 DTG hearts, but not in tTA control hearts or when performing an IgG control IP (Fig. 4b, c). Furthermore, we also investigated the structural domains of Thbs1 that interact with PERK using glutathione S-transferase (GST) fusion fragments22. Interestingly, this identified both the N-terminal laminin G (LamG) domain and the carboxy-terminal domain (CTD) of Thbs1 as PERK interacting in protein extracts of primary neonatal rat ventricular cardiomyocytes (NRVMs; Fig. 4d). Nevertheless, future confirmation of this finding is warranted as these GST fusion fragments are derived from a bacterial expression system where mammalian glycosylation is absent, and chaperones needed to mediate proper disulfide bond formation are lacking. Finally, quantitative PCR analysis in Thbs1 DTG hearts revealed upregulation of Eif2ak3 (PERK) at the mRNA level (Fig.4e), suggesting a transcriptional feed forward mechanism. Atf4 and known downstream targets such as Atf3, Ddit3 (Chop), and fibroblast growth factor 21 (Fgf21) were also upregulated in Thbs1 DTG hearts compared with controls (Fig. 4f–i). Such results are interesting given that ATF4 and its downstream effector Fgf21 mediate atrophic remodeling in skeletal muscle23,24. Taken together, our results suggest a mechanism whereby Thbs1 induces lethal cardiac atrophy, in part, through the PERK-eIF2α-ATF4 ER stress pathway.
Thbs1 induces autophagy and lysosomal protein degradation
We next investigated the molecular basis for Thbs1-mediated cardiac atrophy. The ubiquitin-proteasome system (UPS) and autophagy are two major mechanisms responsible for protein degradation in the heart2. However, no significant change in 20S proteasome activity was observed in Thbs1 transgenic hearts compared to Thbs3 DTG and tTA controls (Fig. 5a). Fbxo32 (Atrogin-1) and Trim63 (MuRF1) transcript levels were also unaffected by Thbs1 overexpression (Supplementary Fig. 2a, b). Interestingly, levels of certain ubiquitinated proteins and several key components of the ER-associated degradation (ERAD) machinery in the heart, including valosin-containing protein (VCP)/p97, Homocysteine Inducible ER Protein With Ubiquitin Like Domain 1 (Herpud1) and sel-1 suppressor of lin-12-like 1 (Sel1L), but not derlin-1 (Derl1) and ER degradation-enhancing alpha-mannosidase-like protein 1 (Edem1) were increased in the Thbs1 transgenic hearts, compared to tTA control (Fig. 5b and Supplementary Fig. 2c, d). Nevertheless, similar changes were observed in the Thbs3 transgenic hearts, which do not develop a lethal cardiac atrophy (Fig. 5b and Supplementary Fig. 2c, d).
Emerging data suggest a regulatory role for the PERK-eIF2α-ATF4 ER stress axis in autophagy6,7. Similarly, markers of autophagy, microtubule-associated proteins 1A/1B light chain 3B-II (LC3b-II) and p62 were uniquely increased in Thbs1 DTG hearts compared with tTA control or Thbs3 DTG hearts (Fig. 5b and Supplementary Fig. 3a, b). Thbs1 DTG animals and tTA controls were treated with the inhibitor of autolysosomal degradation bafilomycin A1 (Baf. A1) to more closely investigate autophagic flux in the heart. A significant increase in LC3b-II and p62 was observed at baseline in Thbs1 DTG hearts that was further enhanced in Baf. A1 treated animals, thus confirming enhanced autophagic flux (Fig. 5c, d and Supplementary Fig. 3c). In agreement, immunohistochemical analysis using a LC3b specific antibody revealed strong vesicular staining only in Thbs1 DTG heart histological sections compared with tTA control; this was confirmed at the ultrastructural level by electron microscopy (Fig. 5e, f and Supplementary Fig. 3d, e).
To further demonstrate that Thbs1 enhances autophagic flux in cardiomyocytes, cultured primary neonatal rat ventricular cardiomyocytes (NRVMs) were infected with adenoviruses to overexpress tandem fluorescent monomeric red fluorescent protein (mRFP)- green fluorescent protein (GFP)-LC3 (tf-LC3)25 together with Thbs1, Thbs2, Thbs3, or β-galactosidase (βgal) control. After incorporation into autophagosomes, the tf-LC3 can effectively differentiate autophagosomes from autolysosomes because the acidic environment in autolysosomes quenches GFP but not mRFP fluorescence. Consistent with our in vivo results, we observed that Thbs1, but not Thbs2, Thbs3, or βgal significantly enhanced the number of autophagosomes (yellow puncta) and autolysosomes (red puncta), confirming increased autophagic flux in NRVMs upon Thbs1 overexpression (Fig. 5g–i and Supplementary Fig. 3f–h).
Finally, previous studies have also associated the PERK-eIF2α-ATF4 ER stress axis with increased expression of tuberous sclerosis protein 2 (TSC2) activator, and thus mTOR inhibitor DNA damage inducible transcript 4 (DDIT4)26. Activation of AKT/mTOR pathway promotes protein synthesis and cellular growth, whereas its inactivation leads to atrophic remodeling27. However, investigation of AKT, mTOR, and downstream targets such as ribosomal protein S6 kinase (p70S6K) revealed no overt changes in total protein levels in the hearts of Thbs1 DTG mice, although AKT phosphorylation was reduced compared with tTA control or Thbs3 overexpressing mice (Supplementary Fig. 3i).
Collectively, these results suggest a mechanism whereby Thbs1 mediates lethal cardiomyopathy through PERK-eIF2α-ATF4-induced and enhanced autophagic protein degradation in the heart, like previous results observed with Forkhead box O3 (FOXO3) mediated overactivation of autophagy in the heart28.
Thbs1 −/− mice have greater hypertrophy and less atrophy
Increased levels of Thbs1 protein were detected after TAC mediated cardiac injury (Fig. 1a). Moreover, western blot analysis revealed that Thbs1 overexpression in the heart induced a profile of ER stress markers like those observed during cardiac hypertrophy mediated by 2 weeks of TAC, including changes in nuclear ATF6α, phosphorylated and total PERK, phosphorylated and total IRE1α, ATF4 and calreticulin, and to a lesser extent Armet and BiP (Supplementary Fig. 4). Previous studies analyzing Thbs1−/− animals revealed that these mice have increased hypertrophic growth upon pressure overload29. Similarly, here we observed that Thbs1−/− mice responded with significantly increased heart weight to body weight (HW/BW) ratios 2 weeks after TAC surgery compared with wild-type (WT) controls, but without a further effect on function (Fig. 6a–c). This result suggests that induction of endogenous Thbs1 after TAC stimulation normally mediates an anti-hypertrophic effect, presumably through greater autophagy. To further characterize the effect of Thbs1 on protein homeostasis in the heart we utilized a 48-h fasting model. When WT animals were fasted for 48 h, Thbs1 mRNA levels were found to be significantly increased (Supplementary Fig. 5a). Remarkably, Thbs1−/− mice showed significantly less loss of heart weight and body weight with 48 h of fasting compared with matched controls (Supplementary Fig. 5b, c), which again suggests that induction of Thbs1 is likely involved in cardiac atrophy.
Quantitative PCR analysis of ER stress mediators revealed a general profile with increased mRNA levels of Eif2ak3 (PERK) and Atf6, and downstream target genes Manf (Armet) and Calr (calreticulin) in WT hearts in response to 2 weeks of TAC surgery, whereas no changes were observed for Ern1 (IRE1α) and Hspa5 (BiP; Fig. 6d–i). Furthermore, the TAC-induced expression of Eif2ak3, Atf6, Manf, and Calr was blunted in Thbs1−/− hearts (Fig. 6d–i). More importantly and in line with our previous findings, induction of hypertrophy by TAC and atrophy by fasting resulted in similar transcriptional changes associated with the PERK/ATF4/autophagy pathway. Specifically, quantitative mRNA PCR analysis revealed upregulation of Atf4 and its downstream target genes Atf3, Fgf21, Map1lc3b (LC3b), and Trim63 (MuRF1) in WT animals in both models, which was abrogated in Thbs1−/− hearts (Fig. 6j–n and Supplementary Fig. 5d–h). Fbxo32 (Atrogin-1) was upregulated in both models in WT animals, however, this effect was only blunted in Thbs1−/− hearts that underwent TAC surgery and not the fasting regimen (Fig. 6o and Supplementary Fig. 5i). A similar effect was observed analyzing Trib3, which was upregulated in WT animals after TAC surgery and downregulated in Thbs1−/− hearts, but unaffected in fasted animals of either genotype (Fig. 6p and Supplementary Fig. 5j). These results suggest a role for Thbs1 in regulating ATF4-dependent gene expression changes that underlie atrophic remodeling.
Thbs1 induces PERK/ATF4 to facilitate cardiac atrophy
The unique induction of PERK/ATF4 and enhanced autophagic flux in Thbs1 DTG hearts versus Thbs3 overexpression suggested a potential mechanistic basis for how Thbs1 functions in the heart to promote atrophy upon injury or stress stimulation. To directly examine this, we used Eif2ak3-loxP-targeted (Eif2ak3fl/fl) mice crossed with β-myosin heavy chain (βMHC) promoter driven Cre transgenic animals to establish cardiomyocyte-specific deletion of the Eif2ak3 gene (PERK protein) in the heart (Eif2ak3CKO) with Thbs1 overexpression (DTG Eif2ak3CKO). Deletion of Eif2ak3 in the heart significantly antagonized cardiac atrophy, dysfunction and pulmonary edema due to Thbs1 overexpression at 8 weeks of age (Fig. 7a–d), and the lethal cardiomyopathic phenotype was largely rescued (Fig. 7e). Protein analysis by western blot revealed near absent protein levels of PERK in the DTG Eif2ak3CKO hearts compared to DTG Eif2ak3 controls (Fig. 7f), and induction of ATF4, LC3b-II and p62 due to Thbs1 overexpression were all normalized upon deletion of Eif2ak3 in the heart (Fig. 7f and Supplementary Fig. 6a–c). Taken together, these data provide genetic evidence that Thbs1 induction mediates cardiac atrophy through PERK/ATF4 signaling in the heart.
Overexpression of PERK mediates cardiac atrophy
To recapitulate the induction of PERK in the adult myocardium by Thbs1, we utilized an adeno-associated virus serotype-9 (AAV9)-mediated approach to overexpress either PERK or luciferase (control) in the hearts of wild-type mice injected at postnatal (p) day 7 (Fig. 8a, b). Seven weeks later, AAV9-mediated overexpression of PERK resulted in activation of ATF4, LC3b-II, and p62 as shown by western blot analysis, whereas no changes were observed in the levels of ubiquitinated proteins as compared to AAV9-luciferase injected control littermates (Fig. 8c, d and Supplementary Fig. 7a–e). In addition, overexpression of PERK did not appear to impact the levels of general ER stress markers Armet, BiP, and calreticulin, nor did it alter the protein levels of Thbs1 compared to AAV9-Luciferase injected controls (Supplementary Fig. 7f). However, AAV9-mediated overexpression of PERK resulted in atrophic remodeling of the heart as shown by reduced heart size, HW/BW ratio, and cardiac function at 8 weeks of age (Fig. 8b, e, f). Furthermore, enhanced levels of PERK reduced cardiomyocyte surface area of infected, PERK positive cardiomyocytes (AAV9-PERK Pos.) but not neighboring uninfected cardiomyocytes (AAV9-PERK Neg.), as determined by PERK immunohistochemistry (Fig. 8g, h). Collectively, these data indicate a clear mechanism whereby PERK is sufficient to induce autophagic remodeling in the heart.
ATF4 is sufficient to induce cardiac atrophy
Like PERK overexpression in the mouse heart, ATF4 overexpression using AAV9-mediated gene transfer beginning at p7 also promoted a profound atrophic phenotype (Fig. 9a). AAV9-ATF4 at a high (0.5E11 Genome Copies (GC)) and low titer (1E10) induced robust protein levels of ATF4 in the heart (Fig. 9b). The highest viral titer led to high mortality by 4 weeks of age, which was not observed in the AAV9-Luciferase injected control littermates. These high levels of ATF4 resulted in reduced heart size, as well as reduced cardiomyocyte surface area of infected, ATF4 positive cardiomyocytes (Fig. 9c–e). Lowering the dose of AAV9-ATF4 (1E10) circumvented mortality yet was still sufficient to induce high levels of ATF4 in the heart as well as a minor but significant elevation of PERK protein levels, suggesting a positive feedback mechanism (Fig. 9b and Supplementary Fig. 7g, h). Low dose of AAV9-ATF4 resulted in atrophy of the heart as shown by a reduced heart size, HW/BW ratio, as well as reduced cardiomyocyte surface area of the ATF4 positive cardiomyocytes (Fig. 9f–i). Western blot analysis confirmed activation of autophagy markers LC3b-II and p62 in the heart as compared to control injected hearts (Fig. 9j and Supplementary Fig. 7i, j). In agreement with our findings in the AAV9-PERK injected hearts, ATF4 overexpression did not alter the levels of ubiquitinated proteins, impact the protein levels of general ER stress markers Armet, BiP, and calreticulin, nor did it alter the protein levels of Thbs1 compared to AAV9-Luciferase injected controls (Fig. 9j and Supplementary Fig. 7k, l). More importantly, adenoviral-mediated overexpression of ATF4 in NRVMs was sufficient to increase autophagosome and autolysosome formation, thus confirming that induction of ATF4 is sufficient to enhance autophagic flux in cardiomyocytes (Fig. 9k, l and Supplementary Fig. 7m). Hence, our data reveal that overexpression of ATF4 drives the induction of autophagy, cardiomyocyte size reduction, and cardiac atrophy as observed with PERK or Thbs1.
Discussion
Positive and negative effects have been ascribed to the different Thbs proteins in the adult mammalian heart. Thbs129,30,31, Thbs232,33,34, and Thbs413,35 gene-deleted mice are viable and overtly normal but are predisposed to greater cardiac injury with disease-associated stimulation, while Thbs3−/− mice are uniquely protected from injury9. Consistent with these findings, we observed greater cardiac hypertrophy with pressure overload stimulation in Thbs1 −/− mice. In addition, these same mice displayed less fasting-induced cardiac atrophy, together suggesting a role for Thbs1 in regulating adult cardiomyocyte size and ventricular plasticity1,2.
Interestingly, while all 5 Thbs matricellular proteins traverse the intracellular secretory pathway and are ultimately secreted, they are also taken back up into cells by the low-density lipoprotein receptor-related protein 1 (LRP1) receptor36 and as such, only small amounts of these proteins appear to reside within the extracellular matrix (ECM) of tissues. Such observations suggest functionality of the Thbs proteins from within the secretory pathway, such as the known ability of Thbs1, Thbs3, and Thbs4 to mediate an ATF6α-dependent ER-stress response that expands the vesicular network, alters the levels of membrane attachment complex proteins, and augments the levels of select ECM proteins8,9,10,13,21. Moreover, we have also shown that Thbs4 itself functions as an ER resident chaperone where it can directly refold proteins9. Finally, overexpression of a mutant form of Thbs4 that cannot be secreted is pathologic to the heart because it now reduces the content of dystrophin-glycoprotein attachment complexes within the sarcolemma of cardiomyocytes8. However, addition of recombinant Thbs3 or Thbs4 to the outside of cells did not affect the transport or total levels of integrins to the sarcolemma of cardiomyocytes, indicating that Thbs3 and Thbs4 work from within the secretory pathway as they are being secreted to alter membrane attachment complexes9.
In pancreatic β-cells Thbs1 was shown to activate PERK within the ER leading to NRF2 activation, which then reduced oxidative stress damage to these cells37. Here, we determined that the N-terminal LamG domain and C-terminal domain in Thbs1 interact with PERK, which could mediate PERK activation, followed by downstream phosphorylation of eIF2α and induction of ATF4. However, while we observed that Thbs1 activates PERK, our results differ from the work in β-cells in that we failed to find a protective effect37. Instead, our studies revealed that Thbs1-mediated activation of the PERK-eIF2α-ATF4 ER stress axis in cardiomyocytes selectively induced autophagy, autophagic flux, and lysosomal protein degradation, and ultimately a lethal atrophic cardiomyopathy.
Increased PERK activity and induction of ATF4 was previously shown to augment the transcription of genes involved in the formation, elongation, and function of the autophagosome, including becn1, Map1lc3b, multiple autophagy-related genes (Atg’s), and Sqstm1 (p62)6,7. Furthermore, hyperactivation of the autophagy-lysosomal system has recently emerged as a central pathway that facilitates cardiac atrophy28,38,39,40,41, whereas inhibition of autophagy can reverse cardiac atrophy and dysfunction in mouse models of cardiac atrophy38,39. In line with these findings, we show for the first time that overexpression of PERK or ATF4 in myocytes of the heart was sufficient to induce autophagy, cardiomyocyte size reduction, and cardiac atrophy, like Thbs1 overexpression. These findings are in line with recent studies in skeletal muscle where activation the PERK-eIF2α-ATF4 pathway was sufficient to promote muscle fiber atrophy24,42, whereas genetic deletion of Atf4 could delay it42,43. Finally, the enhanced autophagy and lethal cardiac atrophy with Thbs1 overexpression was largely corrected by deletion of the Eif2ak3 gene (PERK protein), suggesting a direct causal relationship.
Our findings indicate that Thbs1 functions in a unique manner in cardiac muscle, compared with Thbs2, 3, and 4. Indeed, overexpression of Thbs1, but not Thbs2, or 3 in cultured cardiac myocytes was sufficient to enhance the formation of autophagosomes and increase autophagosome-lysosomes fusion, and thus autophagic flux. Furthermore, in vivo cardiac-specific overexpression of Thbs3 did not lead to increased autophagy or atrophy9, and overexpression of Thbs4 in the heart was even protective in response to stress stimulation13. Finally, we demonstrated that overexpression of Thbs2 in the heart, which is similar to Thbs111, did not produce a pathologic phenotype or cardiac atrophy.
PERK appears to be a central effector of Thbs1 in the heart given the strong corrective phenotype observed with deletion of Eif2ak3 in Thbs1 DTG hearts. We also observed that the levels of ubiquitinated proteins and several key components of the ERAD machinery were enhanced with cardiac overexpression of Thbs1. However, this is probably independent of the atrophic mechanism given that some of these same changes were observed in Thbs3 DTG hearts, and given the fact that all Thbs proteins increase ATF6α activity, which is a known regulator of proteostasis in the heart, primarily by inducing genes encoding ER-resident chaperones and ERAD components13,44,45,46. Indeed, we observed comparable changes in ERAD in the Thbs3 and Thbs4 transgenic hearts, but these mice do not develop lethal cardiac atrophy9,13. In fact, we show that loss of Atf6 appeared to exaggerate the atrophic cardiomyopathy in Thbs1 DTG mice, further suggesting that ATF6α is part of an adaptive and protective response. In addition, protein ubiquitination that is a key step in the ERAD pathway47 was not altered during cardiac atrophy due to AAV9-mediated PERK or ATF4 overexpression.
Thbs1 is reported to function as an activator of TGFβ48, which has been implicated in skeletal muscle cachexia and atrophy49. However, generation of a cardiomyocyte-specific Thbs1 overexpressing transgenic mouse which lacked the type-1 repeats that binds TGFβ acted similar to WT Thbs1, each causing lethal atrophic cardiomyopathy. This result suggests that Thbs1 has its pathologic effect in the heart independent of TGFβ. Indeed, we previously generated cardiac-specific transgenic mice expressing an activated and non-latent form of TGFβ that did not impact heart growth or atrophy, but instead caused fibrosis50. This suggests that TGFβ is unique in regulating skeletal muscle atrophy directly, but this relationship does not appear to exist in the heart.
The pathologic effect of Thbs1 is also likely independent of angiogenesis in the heart because capillary density was not altered in Thbs1 DTG hearts compared with controls. Indeed, the mutant form of Thbs1 lacking the type-1 repeat region, which harbors the angiogenesis and TGFβ affecting domains, similarly led to lethal cardiomyopathy due to persistent atrophy. Finally, the pathologic effect of Thbs1 was also independent of the previously proposed cell surface receptors CD36 and CD4751.
The results presented here reveal a previously undescribed and critical role for Thbs1, PERK, and ATF4 in maintaining protein homeostasis in the heart. More specifically, we identified Thbs1-mediated activation of the PERK-eIF2α-ATF4 ER stress pathway and subsequent induction of unrestrained autophagic protein degradation as a novel pathway central to size control of adult cardiomyocytes in the stressed heart.
Methods
Genetically modified mice
All experimental procedures with animals were approved by the Institutional Animal Care and Use Committee (IACUC) of Cincinnati Children’s Medical Center, protocols IACUC 2016-0069 and 2018-0047. The number of mice used in this study reflects the minimum number needed to achieve statistical significance based on experience and previous power analysis. Blinding was performed for some experimental procedures with mice, although blinding was not possible in every instance. Both sexes of mice were used in equal ratios. Animals were kept in the following controlled housing conditions: 21–22 °C, 40–60% humidity and 12-h light/12-h dark cycle.
Cardiomyocyte-specific transgenic mice were generated using the bigenic tetracycline murine α-myosin heavy chain (αMHC) promoter expression vector system16. In the absence of doxycycline (Dox) expression is induced, but with Dox administration (200 mg Dox/kg chow, irradiated; Envigo Teklad Diets, #TD.00502) expression is suppressed. Dox in the chow was used to repress transgene expression until weaning (Fig. 2f–i) or after weaning (Fig. 2j–m). Full-length mouse Thbs1 cDNA was obtained from Open Biosystems (#BC042422), amplified by PCR, and cloned in the Sal1 and HindIII sites of the αMHC responder vector, followed by NotI digestion and gel purification to remove the vector backbone. The Thbs1Δt1 DTG mutant lacking the Thbs1 type1 repeats was created using the In-Fusion HD cloning system (Takara Bio, #639649) and the Thbs1-αMHC responder vector. Thbs2 transgenic mice were generated in the same bi-genic inducible αMHC promoter system and the Thbs2 cDNA was obtained from Open Biosystems (#BC146676.1), amplified by PCR and cloned in the Sal1 site of the αMHC responder vector, followed by NotI digestion and gel purification to remove the vector backbone. Primer sequences used for cloning are listed in Supplementary Table 1. The final constructs were confirmed by DNA sequencing and injected into newly fertilized oocytes to generate transgenic animals at the University of Cincinnati Transgenic Mouse Core (C57Bl/6J background). Mice harboring the αMHC-Thbs transgenes were crossed to mice expressing the tetracycline trans-activator (tTA) under the control of the αMHC promoter to generate double transgenic animals (DTG), which were maintained in the C57Bl/6J background16. Thbs3 inducible cardiac-specific transgenic mice were previously generated in our lab9. Mice deficient for Thbs1, Cd36, Cd47, and Eif2ak3-loxP targeted (B6.129S2-Thbs1tm1Hyn/J, B6.129S1-Cd36tm1Mfe/J, B6.129S7-Cd47tm1Fpl/J, and Eif2ak3tm1.2Drc/J) were purchased from Jackson Laboratories and maintained on a C57Bl6 background. Gene-deleted mice lacking ATF6α protein were obtained from the lab of Kazutoshi Mori (Kyoto University, Kyoto, Japan)52. Other mice used in this study included the βMHC-Cre mouse line53, mice with cardiomyocyte-specific overexpression of activated calcineurin (ΔCnA TG)14 and Csrp3−/− mice15.
For fasting studies, 8-week-old male mice were deprived of food for 48 h with free access to drinking water54. To measure autophagic flux in vivo, 8-week-old mice were subject to intraperitoneal injections of bafilomycin A1 (Baf. A1, 2.5 mg/kg (InvivoGen, #tlrl-baf1)), or vehicle control (60% dimethyl sulfoxide in saline). Mice were killed 4 h after Baf. A1 or DMSO injection for further analysis55. No human subjects or human tissue was used in this study.
AAV9 virus production and injection into neonatal mice
Full-length mouse Atf4 cDNA was obtained from Addgene (plasmid #21845, deposited by Dr. David Ron), amplified by PCR using CloneAMP HiFi PCR premix (Takara Bio, #639298) and cloned into the Cla1 and XhoI sites of pAAV-MCS vector (Cell biolabs, #VPK-410) using the NEBuilder HiFi DNA Assembly Master Mix (New England Biolabs, #E2621). The firefly luciferase cDNA was obtained from Addgene (plasmid #120522, deposited by Dr. Petr Svoboda), amplified by PCR and cloned into the Cla1 and XhoI sites of pAAV-MCS vector (Cell biolabs, #VPK-410) using the NEBuilder HiFi DNA Assembly Master Mix (New England Biolabs, #E2621). Primer sequences used for cloning are listed in Supplementary Table 1. The PERK-Myc insert was obtained from PERK1:WT.9E10.pCDNA (Addgene #21814, deposited by Dr. David Ron) and cloned into CAG-TdTomato AAV backbone by the Howard Hughes Medical Institute (HHMI)-Janelia Viral Tools. Briefly, the PERK-Myc insert was excised by KasI and SphI digestion. New ApaI and SfuI sites were added to the 5′ and 3′ ends of the PERK-Myc insert, respectively, and then cloned into an ApaI-SfuI digested CAG-TdTomato AAV backbone (generated by HHMI-Janelia Viral Tools), resulting in pAAV-CAG-PERK-Myc. The final constructs were confirmed by DNA sequencing. AAV9-CMV-Luciferase, AAV9-CMV-ATF4, and AAV9-CAG-PERK-Myc were produced by the HHMI-Janelia Viral Tools- using a polyethylenimine (PEI) triple transfection protocol into 293 cells, grown under serum-free conditions, purified by two rounds of CsCl density gradient centrifugation and exchanged into storage buffer containing 1x PBS, 5% sorbitol and 350 mM NaCl and subsequently stored at −80 °C until commencing the in vivo experiments. Virus titers (GC/ml) were determined by qPCR targeting the AAV ITRs.
The indicated titers of AAV9-Luciferase, AAV9-PERK or AAV9-ATF4 were injected into the mediastinum of 7-day-old C57Bl/6J wild-type mice (Jackson Laboratories, #000664)56. Mice were killed and hearts were excised at 4 or 8 weeks of age and the apex was snap frozen in liquid nitrogen for storage at −80 °C. The remainder of the heart was fixed overnight in 4% paraformaldehyde, dehydrated in ethanol, and paraffin embedded for further histological and immunohistochemical analysis.
Adenoviruses, cell culture, and in vitro autophagic flux assay
Adenoviruses harboring Thbs1, Thbs3, tandem mRFP-GFP-LC3 (Ad-tf-LC3; gift from Dr. J. Sadoshima of the University of Medicine and Dentistry of New Jersey, Newark), and β-galactosidase (βgal) expressing control were previously generated and validated9,13,25. The Thbs2 and Atf4 cDNA were amplified by PCR for insertion into the pShuttle-CMV vector (Agilent Technologies #240007) to generate recombinant adenoviruses according to the manufacturer’s instructions13.
Primary neonatal rat ventricular myocytes (NRVMs) were prepared from 1- to 2-day-old Sprague-Dawley rat pups9. Briefly, neonatal hearts were collected, the atria were removed and the ventricles were minced in Hanks’ Balanced Salt Solution (HBSS) prior to five rounds of enzymatic digestion using 0.05% pancreatin (Sigma) and 84 units/ml of collagenase (Worthington, Lakewood, NJ). Next, cells were collected by centrifugation (500×g for 5 min at 4 °C) and resuspended in HyClone Medium 199/ Earle’s Balanced Salt Solution (EBSS) (ThermoScientific, SH30253FS) supplemented with 2% fetal bovine serum (Sigma-Aldrich, F2442) and 1x penicillin-streptomycin (Cellgro 30-0002-CI, Mediatech, Corning Life Sciences, Tewksbury, MA). The cells were then differentially plated for 1 h on uncoated culture dishes to reduce fibroblasts. Finally, NRVMs were plated on gelatin-coated cell culture dishes and maintained in the culture medium described above.
The in vitro autophagic flux assay was performed as described with modifications25. Briefly, NRVMs were plated with a density of 50 × 103 cells per well in Ibidi μ-slide eight-well dishes (Ibidi USA, Inc. Madison, WI, Cat# 80826) and cultured in HyClone Medium 199/EBSS (ThermoScientific, SH30253FS) supplemented with 2% fetal bovine serum (Sigma-Aldrich, F2442) and 1x penicillin-streptomycin (Cellgro 30-0002-CI, Mediatech, Corning Life Sciences, Tewksbury, MA). The next day, NRVMs were infected with recombinant adenoviruses to overexpress tandem mRFP-GFP-LC3 (Ad-tf-LC3) with either Thbs1, Thbs2, Thbs3, ATF4, or βgal control for 3 h in serum-free media after which they were switched back to culture media supplemented with 2% fetal bovine serum. Forty-eight hours later cells were washed with 1x PBS, fixed with 4% paraformaldehyde, washed again, mounted with Ibidi mounting medium (Ibidi USA, Inc. Madison, WI, Cat# 50001), and visualized using a Nikon A1 confocal laser microscope system equipped with 40x H2O objective (NA = 1.15). All imaging was performed under identical conditions using NIS Elements Advanced Research (AR) microscope imaging software (Nikon Instruments Inc. Melville, NY). The tf-LC3 is a modified LC3 (microtubule-associated protein 1 light chain 3) with N-terminal fusion of an GFP and a mRFP in tandem25. While imaging, tf-LC3–containing autophagosomes are visualized as yellow puncta because both the GFP and mRFP fluoresce. However, the tf-LC3-labeled autolysosomes emit only red fluorescence from mRFP because the acidic environment in autolysosomes quenches GFP25. The number of mRFP-GFP double fluorescent LC3 puncta (autophagosomes) and mRFP fluorescent LC3 puncta (autolysosomes) per NRVM was determined using NIS Elements Advanced Research (AR) microscope analysis software (Nikon Instruments Inc. Melville, NY). In parallel, protein lysates were prepared from NRVMs that were cultured in 100 mm cell culture dishes (Thomas Scientific, Swedesboro, NJ, Cat # 1156F06) to validate adenoviral-mediated overexpression of Thbs1, Thbs2, Thbs3, and ATF4 as described in the section ‘Protein isolation and western blotting’. All experiments described above were performed in triplicate.
Protein isolation and western blotting
Hearts were excised, immediately frozen in liquid nitrogen and stored at −80 °C until further use. Cultured primary NRVMs were washed three times with ice-cold 1x PBS, collected, centrifuged at 500×g at 4 °C and the pellet was snap frozen in liquid nitrogen and stored at −80 °C until further use. General protein samples were prepared in an ice-cold modified radio-immunoprecipitation assay (RIPA) buffer (1% Triton X-100, 1% sodium deoxycholate, 0.1% sodium dodecyl sulfate (SDS), 50 mM Tris-HCl, pH 7.4, 150 mM NaCl) supplemented with HaltTM Protease and Phosphatase single-use inhibitor cocktail (ThermoFisher Scientific, #78442). Samples were sonicated (SP Scientific, Warminster, PA, VirSonic 60, power setting 3 for three times 10 s), lysates were cleared by centrifugation at 20,500×g for 14 min at 4 °C and stored at −80 °C.
ECM proteins were extracted from frozen whole heart ventricles using a subcellular protein fractionation kit for tissues (ThermoFisher Scientific, Cat. #87790) according to the manufacturer’s instructions. In brief, heart tissue was washed in ice-cold 1x PBS, minced, and homogenized in ice-cold cytoplasmic extraction buffer (CEB). At this point, a 20 μl aliquots of ‘total protein extracts’ (TOTAL; Fig. 3g) were collected and kept separately. Next, the samples were alternatingly centrifuged and incubated in a series of buffers to sequentially remove cytoplasmic proteins (buffer ‘CEB’), plasma, mitochondria, and ER/Golgi membrane proteins (buffer ‘MEB’), soluble and chromatin-bound nuclear proteins (buffer ‘NEB’ and ‘NEB + CaCl2 and Micrococcal Nuclease’), cytoskeletal proteins (buffer ‘PEB’). The remaining ECM-enriched pellets were considered ‘ECM extracts’ (Fig. 3g), and were resuspended in 6 M urea, 0.1% SDS, and 1% dithiothreitol (DTT).
In general, protein concentrations were determined using a Direct Detect infrared spectrometer (Millipore Sigma). Protein concentrations of ECM fractions were determined using NanoDrop A280 measurements (Denovix, Wilmington, DE, Cat. # DS-11 FX + ). All protein preparations were mixed with 5x Laemmli loading buffer and heated at 95 °C for 10 min prior to loading on SDS-polyacrylamide gel electrophoresis (PAGE) or Phos-tag (Phos-tag™ acrylamide) SDS-PAGE gels (see below). For standard Western blots, a wet transfer method to polyvinylidene fluoride (PVDF) membranes with a 0.45-μm pore size (EMD Millipore, #IPFL00010) or PVDF membranes with a 0.2-μm pore size (EMD Millipore, #ISEQ20200) in case of LC3b blotting was utilized.
A Phos-tag based system was used to investigate the activation status of PERK due to the lack of reliable commercially available phospho-specific antibodies57. Phos-tag SDS-PAGE gels were run as previously described with modifications57. Briefly, Phos-Tag™ acrylamide compound (FUJIFILM Wako Chemicals, Cat. # 304-93521) was incorporated in 6% Bis acrylamide gels according to the manufacturer’s instructions. After electrophoresis at 115 V, Phos-tag gels were incubated for 10 min in transfer buffer containing 1 mM ethylenediaminetetraacetic acid (EDTA) followed by 10 min in transfer buffer without methanol or EDTA. Next, proteins were transferred to nitrocellulose membranes with a 0.2 μm pore size (Bio-Rad, Cat. # 162-0112) at 85 V for 1.5 h using the standard wet transfer method. Precision Plus Protein™ Dual Color Standards was utilized as protein marker for all regular western blots (Bio-Rad, Car. #1610374), whereas Wide-View™ Pre-stained Protein Size Marker III was used for Phos-tag gels (FUJIFILM Wako Chemicals, Cat. #230-0246).
Immunoblots were performed using appropriate primary antibodies and fluorescent conjugated secondary antibodies (LI-COR, IRdye 800CW Goat anti-Mouse #926-32350, IRdye 800CW Goat anti-Rat #926-32219, IRdye 800CW Goat anti-Rabbit #926-32211, IRdye 680RD Goat anti-Mouse #926-68072, IRdye 680RD Goat anti-Rabbit #925-68073, IRdye 800CW Donkey anti-Goat #926-32214, IRdye 680RD Donkey anti-Goat #926-68074, IRdye 680RD Donkey anti-Mouse #926-68072; all at 1:3000) in combination with an Odyssey CLx Infrared Imaging System (LI-COR). Western blot band intensities were quantified using the Li-Cor Image Studio software.
Primary antibodies used were: Armet (Abcam, #ab67271 at 1:1000), p-AKT ser473 (Cell Signaling Technology, #9271 at 1:1000), AKT (Cell Signaling Technology, #9272 at 1:1000), ATF4 (Cell Signaling Technology, #11815; at 1:1000), ATF6α (SAB SignalWayAntibody LLC, #SAB24383; at 1:1000), BiP (Sigma, #G9043 at 1:1000), CD36 (Abcam, #ab133625 at 1:1000), CD47 (Abcam, #ab108415; at 1:1000), calreticulin (Cell Signaling Technology, #2891; at 1:1000), Derlin-1 (Abcam, #ab176732; at 1:1000), Derlin-3 (Sigma, #D2194; at 1:1000), DNAJC3 (Abcam, #ab227140 at 1:1000), Edem1 (LifeSpan Biosciences, #LS-C80983), p-eIF2α ser51 (Cell Signaling Technology, #9721; at 1:1000), eIF2α (Cell Signaling Technology, #9722; at 1:1000), Herpud1 (Cell Signaling Technology, #26730; at 1:1000), IRE1α (Cell Signaling Technology, #3294; at 1:1000), p-IRE1α ser724 (Abcam, #ab48187; at 1:1000), LC3b (Cell Signaling Technology, #3868 at 1:1000), p-mTOR ser2448 (Cell Signaling Technology, #2971 at 1:1000), mTOR (Cell Signaling Technology, #2972 at 1:1000), p62 (Sigma, #p0067 at 1:1000), PERK (Cell Signaling Technology, #3192; at 1:1000), p-P70S6K thr389 (Cell Signaling Technology, #9205; at 1:1000), P70S6K (Cell Signaling Technology, #9202; at 1:1000), SEL1L (Sigma, #S3699; at 1:1000), Thbs1 (R&D Systems, #AF3074; at 1:500), Thbs2 (BD Bioscience, #611150; at 1:1000 in Fig. 2k and R&D Systems, #MAB1635; at 1:500 in SupFig. 3g), Thbs3 (Proteintech, #19727-1-AP; at 1:100), Ubiquitin (Santa Cruz Biotechnology, #sc-8017; at 1:200), VCP/P97 (Abcam, #ab36047; at 1:1000), and Vinculin (Sigma, #V9131; at 1:1000) or glyceraldehyde 3-phosphate dehydrogenase (Gapdh; Fitzgerald, #10R-G109A at 1:10000) served as loading controls. Coomassie Brilliant Blue staining of the electrophoresed gels was performed according to the Abcam website (https://www.abcam.com/protocols/transfer-and-staining-of-proteins-in-western-blot) to visualize protein loading of the ECM fractions. All antibodies were authenticated for proper specificity, in some cases using tissues or cells from gene-deleted mice or using authentication data provided by the vendor for each antibody. Uncropped images of all western blots presented in this study can be found in the Source Data File.
Immunoprecipitation and GST Pull-Down
Protein extracts from tTA cont. and Thbs1 DTG hearts were generated by homogenizing in immunoprecipitation (IP) lysis buffer (50 mM Tris-HCl pH 7.4, 150 mM NaCl, 1% Triton X-100) supplemented with HaltTM Protease and Phosphatase single-use inhibitor cocktail (ThermoFisher Scientific, #78442), followed by rotation at 4 °C for 2 h and clarification by centrifuging samples at 15,000×g for 20 min at 4 °C. Protein concentration was determined by Bradford. PERK IPs were performed with 1 mg of lysate incubated with 2 µg of primary antibody (Proteintech, #20582-1AP) or the corresponding IgG (Cell Signaling Technology, #2729) overnight at 4 °C with rotation. Next, magnetic beads (DynabeadsTM Protein G, Invitrogen, #1003D) were washed three times in lysis buffer then added to samples per manufacturer’s recommendation (8 μg IgG/mg beads) and rotated for an additional hour at 4 °C. Beads were then washed three times in wash buffer (50 mM Tris-HCl pH 7.4, 150 mM NaCl, 0.1% Triton X-100) supplemented with HaltTM Protease and Phosphatase single-use inhibitor cocktail. Finally, beads were resuspended in 2X sample buffer and heated at 95 °C for 10 min. Thbs1 IPs were performed simultaneously using a Biotin-labeled monoclonal Thbs1 primary antibody (Invitrogen, #MA5-13395), or mouse IgG (Santa Cruz Biotechnology, #sc-2025), and 10 μg/mg DynabeadsTM M-280 Streptavidin (Invitrogen, #11205D). Immunoblots were performed as described in the section ‘Protein isolation and western blotting’ using primary antibodies against PERK (Proteintech, 20582-1AP; at 1:1000), Thbs1 (R&DSystems, #AF3074; at 1:500), or Vinculin (Sigma, #V9131; at 1:1000) as a loading control.
GST-Thbs1 fusion plasmids were provided by Dr. Jack Lawler, Beth Israel Deaconess Medical Center58. GST empty vector and GST-Thbs1 fusion plasmids corresponding to the Thbs1 N-terminus (lamG domain), aa 1–240; procollagen (PC) domain, aa. 278–355; type 1 repeat (T1) domain, aa. 385–522; type 2 repeat (T2) domain, aa. 559 to 669; type 3 repeat (T3) domain, aa. 784–932; and the Thbs1 carboxy-terminal domain (CTD), aa. 926–1152 (see diagram Fig. 4d) were transformed into Bl21 Star (DE3) competent E. coli. Next, cultures were grown for protein expression in LB-Amp at 37 °C to an OD600 of 0.6 at which time 1 mM isopropyl β-d-1-thiogalactopyranoside (IPTG) was added, and cultures were grown for 4 more hours. Cultures were then centrifuged at 3000×g for 20 min; the pellet was washed by resuspending it in 10 ml of ice-cold 1x PBS and recentrifuged again. Pellets were snap frozen in liquid N2 and stored at −80 until further use. Frozen pellets were thawed, resuspended in suspension buffer (10 mM Tris-HCl pH 8.0, 1 mM EDTA, 150 mM NaCl), and lysed by addition of 1 mg/ml lysozyme and subsequent incubation for 15 min at 4 °C with gentle agitation. DTT (10 mM) and Sarkosyl (1.22%) were added followed by sonication for a total of one minute. Lysates were then centrifuged at 21,000×g for 20 min and the pellet was discarded. Triton-X 100 was added to the supernatant for a final concentration of 2% and incubated for 30 min on ice. Glutathione sepharose (Glutathione Sepharose 4B, GE Healthcare, #17-0756-01) was washed three times in suspension buffer with Sarkosyl (0.7%), DTT, and Triton X-100. Washed GST-sepharose (500 µl packed) was added to each sample and incubated for a minimum of 2 h at 4 °C with agitation. Sepharose was pelleted by centrifugation at 500×g for 5 min at 4 °C and washed three times in resuspension buffer with detergent followed by a final wash in 1x PBS. The protein bound glutathione sepharose samples were then resuspended in crude lysates from primary neonatal rat ventricular myocytes (NRVMs; 2 ug/sample) and rotated at 4 °C overnight. NRVM lysates were prepared as described for IPs. The samples were then washed and prepared for immunoblotting as described above. Immunoblots were performed as described in the section ‘Protein isolation and Western blotting’ using primary antibodies against PERK (Cell Signaling Technology, #3192; at 1:1000). Purity of isolated GST empty vector and GST-Thbs1 fusion constructs were confirmed by Coomassie Brilliant Blue staining of SDS-PAGE gels.
TGFβ ELISA and proteasome activity assay
Enzyme-linked immunosorbent assays (ELISA) were performed on heart homogenates using a kit for TGF-β1 purchased from R&D Systems (SMB100B) and according to the manufacturer’s instructions59. The chymotrypsin-like activity of the 20S proteasome in ventricular extracts was determined using a commercially available proteasome activity kit following the manufacturer’s instructions (Abcam, Cat. #ab107921).
Pressure overload and echocardiography
Eight- to ten-week-old mice of the relevant genotypes were subjected to transverse aortic constriction (TAC) or sham surgical procedure60. Briefly, the transverse aortic arch was visualized by performing a median sternotomy. A 7-0 silk ligature was then tied around the aorta and a 27-gauge wire to control the degree of constriction between the right branchiocephalic and left common carotid artery. Next, the wire was removed to generate a defined reduction in lumen area. Doppler echocardiography was performed on mice after TAC to ensure equal pressure gradients across the aortic constriction. Mice with pressure gradients of <45 mmHg were excluded from the results, as this indicated an unsuccessful surgery. Both sexes of mice were used for TAC surgeries. Mice were given buprenex (Henry Schein, #055175) as pain relief at a final concentration of 0.05 mg/ml by subcutaneous injection. Mice were then transferred to 30 °C incubators and monitored while in recovery, and any mouse displaying signs of distress was removed from the study in accordance institutional guidelines approved by the IACUC of Cincinnati Children’s Hospital. Echocardiography was performed and analyzed in a blinded manner on mice after isoflurane inhalation (2% to effect) for anesthesia using a Sonos 5500 ultrasound instrument (Hewlett Packard) with a 15-MHz microprobe and measurements were taken in M-mode in triplicate for each mouse and averaged.
Electron microscopy
Hearts of anesthetized mice were perfused with relaxing buffer (0.15% sucrose, 5% dextrose, 10 mM KCl in 1x PBS) for 3 min and then perfused with fixation buffer (1% paraformaldehyde, 2% glutaraldehyde in 100 mM sodium cacodylate pH 7.4), then fixed overnight in fixation buffer and post-fixed in 1% OsO4 for 2 h. Ultrathin sections of all tissues were counterstained with uranyl acetate and lead salts. Images were obtained using a 7600 transmission electron microscope (Hitachi) connected to a digital camera (AMT, Biosprint16).
Histological analysis, and immunohistochemistry
Heart tissue was fixed overnight in 10% formaldehyde, dehydrated in ethanol and paraffin embedded. Tissue was sectioned at 5 μm and stained with either hematoxylin and eosin (H&E) or Masson’s trichrome. Images were captured with a stereo microscope (Leica Microsystems, #M165FC) equipped with a digital camera (Leica Microsystems, #DFC310 FX) and the Leica Application Suite. General immunohistochemistry and co-labeling of Thbs1 and BiP was performed on paraffin embedded tissue sections, which were rehydrated and heated in 1x antigen retrieval CITRA (BioGenex, # HK086-9K). For co-labeling of tissue sections with Thbs1 and Vimentin, freshly harvested hearts were embedded in optimal cutting temperature (O.C.T) compound (VWR, #25608-930), frozen in liquid nitrogen and tissue sections were cut at a thickness of 10 μm. Afterwards, both paraffin- and cryo-tissue sections were rinsed in 1x PBS, permeabilized for 2 min in 0.1% triton X-100/PBS and incubated for 1 hour at room temperature in blocking buffer (1x PBS, 5% goat serum, 2% BSA). Primary antibody incubations were performed overnight at 4 °C for Thbs1 (ThermoFisher Scientific, #MA5-13395 at 1:200 for Fig.1b, c; R&D Systems, #AF3074; at 1:200 for Fig.1f), ATF4 (Cell Signaling Technology, #11815 at 1:200), vimentin (Abcam, #ab45939 at 1:200), BiP (Sigma, #G8918 at 1:200), LC3b (Cell Signaling Technology, #2775 at 1:100), and PERK (Santa Cruz Biotechnology, #sc-9477; at 1:50). Appropriate Alexa Fluor-488 (ThermoFisher Scientific, Goat anti-Mouse IgG, #A-11029; Donkey anti-Goat IgG, #A-11055; Goat anti-Rabbit IgG, #A11008), and Alexa Fluor-568 (ThermoFisher Scientific, Goat anti-Mouse IgG, #A-11031; Donkey anti-Rabbit IgG, #A-10042; Donkey anti-goat IgG, #A-11057) secondary antibodies at 1:400 in blocking buffer were applied for 1 h at room temperature and subsequently for 10 min with DAPI (4′,6-diamidino-2-phenylindole) nuclear DNA stain at 1:10.000 (ThermoFisher Scientific, #D1306). Staining with wheat germ agglutinin (WGA) conjugated to fluorescein isothiocyanate (FITC; Lectin from Triticum vulgaris, Millipore Sigma, #L4895 at 1:100 or WGA Alexa Fluor 647 conjugate (Molecular Probes, #w32466 at 1:100) was done for 1 h at room temperature to visualize the membranes. For all immunostains included in this study, sections were incubated with the appropriate secondary antibodies alone as a control for specificity.
All sections were mounted in Vectashield Hard Set (Vector Laboratories, #H-1400) to prevent photo bleaching and visualized using a Nikon A1 + confocal laser microscope system (Nikon Instruments) equipped with 40x H2O objective (Nikon Instruments, NA = 1.15). All imaging and analyses were performed under identical conditions using NIS Elements Advanced Research microscope imaging software (Nikon Instruments).
Quantification of cross sectional area (CSA) was performed on at least 4 random pictures of the left ventricle free wall. A minimum of 200 cardiomyocytes were analyzed per animal and per experiment. More specifically, quantitative analysis of AAV9-Lucif. versus AAV9-PERK positive (Pos.) and negative (Neg.) CSA was determined by PERK and WGA-FITC staining on cardiac sections at 8 weeks of age (see above); whereas quantitative analysis of CSA of AAV9-Lucif. versus AAV9-ATF4 positive cardiomyocytes was determined by ATF4 and WGA-FITC staining of cardiac histological sections at 4 weeks of age (see above).
Capillary counts were analyzed on cryosections, co-stained with biotinylated isolectin B4 (Vector Laboratories, #B-1205) and WGA-FITC (Lectin from Triticum vulgaris, Millipore Sigma, #L4895 at 1:100) for 1 h at room temperature, followed by treatment with streptavidin, Alexa 594 conjugate (ThermoFisher Scientific, #S11227 at 1:1000) for 1 h at room temperature to visualize isolectin B4. Pictures were taken with a Nikon A1 confocal microscope. Three random pictures of the left ventricle free wall were taken from 3 sections at different levels for quantitative analysis.
TUNEL staining was performed with an in situ TUNEL detection kit (Roche, #12156792910), and according to the manufacturer’s instructions28. Cryosections were then co-stained with isolectin B4 (Vector Laboratories, #B-1205) followed by treatment with streptavidin, Alexa 594 conjugate (ThermoFisher Scientific, #S11227 at 1:1000) for 1 h at room temperature to visualize isolectin B4. Pictures were taken with a Nikon A1 confocal microscope. Three random pictures of the left ventricle free wall were taken from three sections at different levels for quantitative analysis. For endothelial cell apoptosis, isolectin B4/TUNEL/DAPI cells were counted.
An EdU assay was used to determine endothelial cell proliferation61. Briefly, mice were treated with EdU (Santa Cruz Biotechnology, #61135-33-9) dissolved in 1x PBS by i.p. injection (5 μg/g of body weight). 24 h after EdU injection, hearts were fixed in 4% paraformaldehyde and frozen for immunohistochemical analysis. Cryosections were co-stained with anti-CD31 (BD Biosciences, #553370), then sections were incubated with a 1:500 dilution of goat anti-rat Alexa Fluor 568 secondary antibodies (A-11077, Life Technologies), followed by EdU staining using a Click-iT EdU Alexa Fluor 488 Imaging Kit (C10641, Life Technologies). Pictures were taken with a Nikon A1 confocal microscope. Three random pictures of the left ventricle free wall were taken from three sections at different levels for quantitative analysis. For endothelial cell proliferation, CD31/EdU/DAPI cells were counted.
RNA isolation and quantitative reverse-transcriptase PCR
RNA was isolated from hearts using RNeasy Fibrous Tissue Kit (QIAGEN, #74704) according to the manufacturer’s instructions. Synthesis of cDNA was performed using Superscript III First Strand Kit (Invitrogen, #18080-051) with random hexamer primers according to the manufacturer’s instructions. Quantitative real-time PCR was performed using SsoAdvanced SYBR Green (Bio-Rad, #6090) on a CFX96 Touch Real-Time PCR System (Bio-Rad). Primer sequences are listed in Supplementary Table 2. Rpl13 (ribosomal Protein L13) was used as a reference for relative quantification.
Statistics and reproducibility
Results are presented in all cases as mean ± SEM. Statistical analysis was performed using Graphpad Prism 9.0.0 (Graphpad Software). Individual variable comparison was analyzed using two-tailed Student’s t test, p-values <0.05 were considered significant. Comparison of multiple groups was performed using one-way analysis of variance (ANOVA) with Tukey multiple comparisons test, p-values <0.05 were considered significant. Comparison of survival curves was performed using a two-tailed log-rank (Mantel-Cox) test, p-values <0.05 were considered significant. The representative data shown as western blot photograph and microscopy images were obtained from at least three independent experiments or at least three mice per group (for Figs. 1a–g; 2a, k; 3g, j; 4a–d(lower panel); 5b, c, e, f; 6a; 7a, f; 8b–d, g; and 9b–d, f, h, j and Supplementary Figs. 1a, d; 2d; 3d–i; 4; and 7f, l–m). Data generated with cultured primary neonatal rat ventricular myocytes (Figs. 5g–i, and 9k, l) was derived from 3 independent experiments.
Reporting summary
Further information on research design is available in the Nature Research Reporting Summary linked to this article.
Data availability
All original data underlying selected data shown in the figures and supplemental figures are available from the corresponding author upon reasonable request. Source data are provided with this paper.
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Acknowledgements
This work was supported by a grant from the German research foundation (SCHI 1290/1-1) to T.G.S., and the National Institutes of Health (NIH) (2R01HL105924) to J.D.M.
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T.G.S., D.V., and J.D.M. conceptualized the study; D.V, T.G.S, and J.D.M designed the experiments; D.V., T.G.S., K.M.G., T.A.B., A.V., M.J.B., F.A., and M.A.S performed experiments; D.V., T.G.S., K.M.G., T.A.B., A.V., and M.J.B. analyzed data contributed experimental animals; D.V., T.G.S, and J.D.M wrote or edited the manuscript.
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Vanhoutte, D., Schips, T.G., Vo, A. et al. Thbs1 induces lethal cardiac atrophy through PERK-ATF4 regulated autophagy. Nat Commun 12, 3928 (2021). https://doi.org/10.1038/s41467-021-24215-4
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DOI: https://doi.org/10.1038/s41467-021-24215-4
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