Abstract
A pathophysiological consequence of both type 1 and 2 diabetes is remodelling of the myocardium leading to the loss of left ventricular pump function and ultimately heart failure (HF). Abnormal cardiac bioenergetics associated with mitochondrial dysfunction occurs in the early stages of HF. Key factors influencing mitochondrial function are the shape, size and organisation of mitochondria within cardiomyocytes, with reports identifying small, fragmented mitochondria in the myocardium of diabetic patients. Cardiac mitochondria are now known to be dynamic organelles (with various functions beyond energy production); however, the mechanisms that underpin their dynamism are complex and links to motility are yet to be fully understood, particularly within the context of HF. This review will consider how the outer mitochondrial membrane protein Miro1 (Rhot1) mediates mitochondrial movement along microtubules via crosstalk with kinesin motors and explore the evidence for molecular level changes in the setting of diabetic cardiomyopathy. As HF and diabetes are recognised inflammatory conditions, with reports of enhanced activation of the NLRP3 inflammasome, we will also consider evidence linking microtubule organisation, inflammation and the association to mitochondrial motility. Diabetes is a global pandemic but with limited treatment options for diabetic cardiomyopathy, therefore we also discuss potential therapeutic approaches to target the mitochondrial-microtubule-inflammatory axis.
Introduction
Diabetic Mellitus (DM) remains a global epidemic, with an estimated 463 million cases worldwide in 2019, and is associated with marked morbidity and mortality rates (1). Diabetes is a major risk factor for heart failure (HF), with a three-fold higher prevalence for developing coronary artery disease, CAD (2, 3). Although, approximately 50 years ago, it was revealed that myocardial remodelling and dysfunction can also occur in diabetic patients in the absence of CAD, a condition termed diabetic cardiomyopathy (DCM) which commonly advances to HF (4, 5). Recently it has emerged that in addition to HF with reduced ejection fraction (HFrEF) roughly half of all HF cases can be classified as HF with preserved ejection fraction (HFpEF), which is less well-understood in comparison. Further, treatments developed to manage HFrEF have limited efficacy in HFpEF patients; highlighting the need for a more detailed understanding of the disease mechanisms. Significantly, over a third of patients with HFpEF have type 2 diabetes (6, 7) indicating that the diabetic insult leads, at least initially, to the development of a distinct myocardial phenotype.
Mitochondrial dysfunction is a hallmark of HF (8) and more recently identified as a feature of HFpEF (9) and DCM (10). While mitochondrial dysfunction is a broad term a recurring feature of HF both in the presence and absence of diabetes, is morphological remodelling of mitochondria, with reports of both swelling and fragmentation [for a review see (11)]. Mitochondrial size, shape and distribution (factors dictating function) are regulated by mechanisms grouped under the umbrella term “mitochondrial dynamics,” which also encompasses mitochondrial turnover, mitophagy and biogenesis, as reviewed by (12). Mitochondrial movement, although less well-studied, particularly in the heart, is driven by the outer mitochondrial membrane protein Miro1 (also termed RHOT1) and is also believed to be important for regulating and maintaining a healthy mitochondrial network (13).
DCM is a chronic low grade inflammatory condition, with inflammation associated with the pathogenesis of HF and linked to the development of mitochondrial dysfunction [as reviewed recently (14)]. Kaludercic and Di Lisa (15) provided an overview of a number of studies indicating that excessive ROS production due to mitochondrial dysfunction is a causative agent of increased expression and activity of the inflammasome, NLRP3. NLRP3 is a multimeric complex formed from NOD-like receptor 3, the apoptosis-associated speck-like protein containing (ASC) adaptor protein, and caspase-1, (16, 17). Although, details are somewhat sparse (and not within the setting of the heart or DCM) an association between proteins mediating mitochondrial dynamics and NLRP3 inflammasome assembly is also emerging (18, 19).
This review will summarise evidence for the emerging role of dysregulated mitochondrial movement in HF/DCM, the intersection with aberrant mitochondrial dynamics and NLRP3 activity focusing on the involvement of Miro1; as well as considering the putative mechanisms involved.
Mitochondrial Dynamics in Cardiovascular Health and Disease
Previously perceived as “static” organelles within cardiomyocytes, mitochondria are now known to be highly dynamic undergoing restructuring via an equilibrium of fission and fusion (12). In brief, fission, mediated by the GTPase dynamin-related protein 1 (Drp1) and receptors Mitochondrial fission 1 protein (Fis1), Mitochondrial fission factor (MFF), and MiD49/51, leads to the division of a single mitochondrion into two, allowing removal of damaged mitochondria from the network. Whereas fusion, is the amalgamation of two mitochondria into one larger mitochondrion orchestrated by the outer mitochondrial membrane (OMM) proteins Mitofusin 1 (Mfn1) and Mitofusin 2 (Mfn2). Fusion of the inner mitochondrial membrane (IMM) next occurs and is regulated by Optic atrophy 1 (Opa1).
The dynamic nature of mitochondria underpins mitochondrial quality control that is, mitochondrial biogenesis (replacement with healthy mitochondria), maintenance and degradation (mitophagy). Over time mitochondria can accumulate damage as a result of multiple mutations in nuclear-encoded mitochondrial genes or oxidative damage via ROS formation as a by-product of OXPHOS. In brief, mitophagy, the removal of damaged mitochondria, is regulated by PTEN-induced kinase protein 1 (PINK1) which upon activation (via phosphorylation) recruits cytosolic Parkin (20, 21). Parkin selectively phospho-ubiquitinates the OMM proteins (including Mfn1/2) and facilitates the selective binding and extension of autophagosomes around damaged mitochondria, although details of the exact mechanisms involved remain incomplete (22).
Recently another method of “fusion” has been identified in cardiomyocytes via the formation of tubular protrusions known as nanotunnels, visualised by live-cell confocal imaging and electron microscopy (23, 24). Nanotunnels serve as a form of direct intercommunication between cardiac mitochondria over micron distances, which allows the exchange of matrix contents between non-adjacent mitochondria. Whether the frequency of nanotunnels is correlated to cell stress is not yet clear, although links to an imbalance in Ca2+ cycling has been implicated (25).
There is a plethora of studies, both clinical and preclinical, identifying decreased expression of fusion proteins and increased levels of fission proteins in the context of cardiovascular disease (26). For example, depressed levels of Mfn1/2 are a feature of human and rodent hearts with impaired contractility and mitochondrial dysfunction (27, 28). Ablation of Mfn1 and Mfn2 results in dilated cardiomyopathy, impaired mitochondrial respiration and mitochondrial fragmentation (29). Opa1 is also depressed in HF patients (30). Whereas, increased fission, fragmented mitochondria and cell death associated with Drp1 expression has been reported as a feature of HF (31). Consequently, research has focused upon developing pharmacological inhibitors of Drp1, for example, treatment of HL-1 cardiomyocytes with mitochondrial division inhibitor-1 is shown to be cardioprotective against ischemia/reperfusion injury (32). However, the Janus nature of Drp1-mediated pathways should not be ignored as in some conditions promotion of these pathways can be cardioprotective (33). Similarly, reduced levels of PINK1 and Parkin in the heart are also associated with ventricular hypertrophy, mitochondrial swelling (34) and disorganised mitochondria (35). Andres et al. (36) also reported how simvastatin provides cardioprotection by triggering Parkin-dependent mitophagy. A balance between mitochondrial fusion, fission and mitophagy is crucial for maintaining a healthy population of mitochondria.
Miro1 Plays a Central Role Governing Mitochondrial Movement
While Mfn1, Mfn2, Opa1 and Drp1 (and receptors) are essential for regulating mitochondrial size and shape, important for mitochondrial “quality control,” the movement of mitochondria within the cell is also a crucial factor with distribution tightly linked to cellular energy requirements. An elegant study from Bers and colleagues not only captured, using live imaging, fusion and fission events within cardiomyocytes but also tracked mitochondrial movement (37). Interestingly, the study showed that over a 1 h period the net movement of mitochondria between the sarcomeres (interfibrillar, IFM) was <0.3 μm compared to those adjacent to the nucleus (peri-nuclear, PNM) which traversed 2.8 μm; this difference in motility may be due to the IFM being more spatially restricted by the sarcomeric organisation.
Miro1 localised to the OMM, has been firmly established in neurons as central for regulating mitochondrial movement in response to temporal and spatial metabolic demands (13), with impaired mitochondrial trafficking associated with several neurodegenerative diseases (38). Miro1 is also highly expressed in the heart (39) and although less well-studied, knock-down of Miro1 in H9c2 cardiomyoblasts revealed a similar effect upon mitochondrial movement in a Ca2+ dependent manner (40). Interestingly, studies exploring mitochondrial transfer via transplantation of human induced pluripotent mesenchymal stem cells (iPSC-MSCs) for tissue regeneration in models of anthracycline-induced cardiomyopathy identify the intrinsically high Miro1 content of iPSC-MSCs as essential for facilitating mitochondrial relocation and improved cardiac bioenergetics (41). In contrast, a recent study suggested that knockdown of Miro1 in cultured neonatal cardiomyocytes (NRCMs) could be protective against phenylephrine-induced hypertrophy through attenuating mitochondrial fission (42). Whilst different cardiac pathologies likely require different approaches in terms of therapeutic targeting, NRCMs as a model system may not always be directly translatable to the mature cardiomyocyte in which mitochondria show a substrate preference for free fatty acids rather than pyruvate (product of glycolysis); Dorn et al. have proposed that after birth there is cell-wide replacement with “adult” mitochondria (43). It is noteworthy that Miro1 is also decreased in pancreatic cells of patients with type 2 diabetes, with a mouse model of islet Miro1 ablation developing insulin resistance, increased production of ROS, inflammation and dysregulated mitophagy (44). Evidence, mainly from studies of neuronal tissue (38), indicates that loss of Miro1 is a decisive factor leading to “arrested” motility and linked to the accumulation of damaged mitochondria.
A Miro1-Macromolecular Complex Mobilises Mitochondria Along Microtubules
Miro proteins bind to kinesin-1/KIF5 and Milton (also known as trafficking kinesin-binding protein 1, TRAK1 or OIP106) (39); interactions proposed to link mitochondria to the microtubule trafficking apparatus (45, 46). Miro1 also directly interacts with Mfn2 in neuronal cells, an association that is proposed as an essential step mediating mitochondrial movement (47) as shown in Figure 1; although, the molecular basis of this interaction remains unknown as is whether this association occurs in cardiomyocytes. Significantly, as discussed above, cardiac Mfn2 levels are reported to be down-regulated in models of DCM (48). How the loss of Mfn2 (which presumably leads to reduced Miro1-Mfn2 interactions) impacts mitochondrial movement and DCM linked phenotypic changes has yet to be clarified.
Figure 1
Ca2+ binding to Miro1, via two EF-hands within the primary sequence, elicits a conformational change, mediating the association and dissociation of the Miro1-complex assembly from the microtubules, MTs, (with detachment halting mitochondrial motility). This process underpins mitochondrial moment (Figure 1) (49). Aberrant Ca2+ homeostasis is a hallmark of HF in patients (50) and associated with DCM (51). Mitochondria play a central role in regulating cytosolic [Ca2+] and maintaining the cellular redox status (52). Organisation of mitochondria straddling either side of the dyad (formed by t-tubules, specialised regions of the sarcolemma, and junctional sarcoplasmic reticulum) is essential for Ca2+ uptake into the mitochondria for driving bioenergetics (52, 53). While HF is associated with displacement of mitochondria (54), how impaired Ca2+ cycling influences mitochondrial movement along microtubules has yet to be examined in detail. Importantly, the Bers group have shown in isolated cardiomyocytes that under stress conditions, causing mitochondrial damage, there is migration of IFM (fission products) via MTs to the perinuclear region where they undergo mitophagy (37).
Microtubule Organisation and Cardiovascular Function and Disease
The presence of MTs in cardiomyocytes has been known for many years (55). MTs are formed by the polymerisation of α/β-tubulin dimers assembling into rods roughly ~ 25 nm in diameter which can extend up to tens of microns in length (56). Similar to mitochondria, MTs are organised into spatially distinct populations; (i) interfibrillar (55), (ii) those surrounding the nuclear envelope (57), and (iii) cortical MTs perpendicular to myofibrils (58). These differing populations of MTs are commonly believed to explain, in part, the diverse physiological roles of MTs in cardiomyocytes, for example, ion channel trafficking, mechanical signalling pathways fundamental for cardiac contractility and inter-organelle communication, as reviewed by Caporizzo et al. (59).
As also discussed in (59) there are numerous studies linking changes to MT properties to the development and progression of cardiovascular diseases. MT remodelling has been identified as the source of increased mechanical stiffness occurring in the early stages of diastolic dysfunction. Accordingly, there has been interest in the use of reagents that depolymerise MTs. Specifically, post-translational modification (PTM) (detyrosination) of MTs is associated with increased viscoelastic resistance in human failing hearts (60). Stiffening of the myocardium due to MT remodelling in the failing heart is also reported to displace mitochondria adjacent to the sarcolemma (subsarcolemmal mitochondria, SSM) triggering the propagation of abnormal Ca2+ transients, leading to arrhythmogenesis (8). However, since mitochondria have been demonstrated to provide a bridge between calcium cycling (and contractility) and mechano-electric and chemical MT-mediated inter-organelle tethering (61) the impact of disrupting the MT network upon mitochondrial motility and function needs further investigation.
Protein Post-Translational Modifications (PTMs) and Role in Mitochondrial Motility
In addition to Ca2+ homeostasis, regulatory mechanisms mediating mitochondrial motility include the cellular redox balance (62), as well PTMs of mitochondrial (63) and MT proteins (64). Miro1 is also regulated by PTMs being ubiquitinated after phosphorylation via PINK1, triggering Parkin and proteasomal pathways leading to Miro1 degradation (65). Given that the PINK1-Parkin pathway is activated in response to depolarisation of the mitochondrial membrane it is generally considered, in this context, that prevention of mitochondrial movement through Miro1 phosphorylation-degradation is important for preserving mitochondrial quality by segregating those damaged mitochondria for removal from the cell (66). How removal of damaged mitochondria is linked to the transport of mitochondria via Miro1 is not clear, particularly within cardiomyocytes; although the Bers study (37) would suggest that mitochondrial transport of IFM precedes mitophagy. The relationship between mitophagy and Miro1 also appears to be cell-type dependent with Miro1 loss-of-function mutations preventing the induction of mitophagy in neurons (67) but activating mitophagy in fibroblasts (68). Miro1 is also a substrate of the class II histone deacetylase, HDAC6, with acetylation of K105 (murine and rat) corresponding to K92 in human Miro1, involving different lysine residues than those targeted for ubiquitination, indicative of two different processes (69). HDAC6 co-immunopreciptates with Miro1 supporting a direct interaction between the two proteins. Importantly, Kalinski et al. (69) also demonstrated that deactetylation of Miro1 leads to stalled mitochondrial movement with detrimental effects upon axon growth, with pharmacological inhibition or deletion of HDAC6 protecting mitochondria against damage and abnormal mitochondrial clustering.
Notably, one of the main components of MTs, α-tubulin, is also an HDAC6 substrate. Acetylation is important for MT stability, as well-inducing conformationally directed MT organisation for the recruitment of kinesin motor proteins (70). Inhibition of HDAC6 in hippocampal neurons is shown to lead to higher levels of α-tubulin and enhanced mitochondrial motility (71). While the role of MT acetylation remains to be fully understood it is intriguing that HDAC6 separately regulates both Miro1 and MT engagement and disengagement and consequently mitochondrial motility.
Significantly, inhibition of HDAC6 activity is also reported as cardioprotective (72) preventing the development of hypertrophy and fibrosis (73). Further, in the context of DCM, HDAC6 inhibition using tubastatin A (TBA) is shown to be beneficial in a rat model of type 1 diabetes for improving outcomes from ischaemia/reperfusion (I/R) injury (74). Moreover, recently, pan-inhibitors of HDACs have been proposed as novel treatments for treating HFpEF, preserving cardiac function in a small animal model (rat) of hypertension induced LV-dysfunction (75) and a larger animal (feline) model of pressure overload (76).
Increased HDAC6 activity in the failing heart has been known for the past decade (77) but a key question that remains to be fully answered is how is HDAC6 activated? Chen and colleagues demonstrated, using an atrial cell line (HL-1), that mitochondrial dysfunction (impaired OXPHOS) induced by treatment with TNF-α, could be rescued using an inhibitor of HDAC6 (78) indicating a mechanistic link between inflammation, mitochondrial function and HDAC6 activity. Further, HDAC6 inhibition in SH-SY5Y cells (a model for Parkinson's disease) is reported to lead to reduced activation of the inflammasome, NLRP3, inflammatory response concomitant with attenuation of dopaminergic neuronal degeneration (79); although the pathways involved were not described.
Microtubules Play a Critical Role for NLRP3 Activation
Activation of NLRP3 modulates the release of inflammatory cytokines, IL-1β and IL-18, cell death and fibrosis associated with the pathogenesis of DCM (80). The acetylation of α-tubulin, whilst linked to mitochondrial transport, is also shown to play a role in the movement of NLRP3 inflammasome components along microtubules leading to the subsequent apposition of NLRP3 to mitochondrion-associated ASC (81). Multiple studies have established the link between microtubule dynamics and NLRP3 inflammasome activity, for example (82). Significantly NLRP3 activation is a feature of several cardiac pathologies as reviewed in (83). For example, colchicine (a microtubule polymerisation inhibitor) disrupts microtubule/tubulin dynamics suppressing the activation of the NLRP3 inflammasome. Animal models of myocardial infarction treated with colchicine have improved cardiac performance, improved survival rates and attenuated HF development and inflammatory response (84).
Since the acetylation of α-tubulin/NLRP3 is under the control of HDAC6 it is perhaps not surprising that beneficial effects of using HDAC6 inhibitors in preventing IL-1β generation have been demonstrated (85). Although, one macrophage study concluded that HDAC6 is a negative regulator of NLRP3, due to a direct interaction mediated by the ubiquitin binding domains (86); with this mechanism suggested to mediate NLRP3 transport into aggresomes via the microtubule network. More recently, Magupalli et al. also demonstrated in macrophages that specific regions of MTs, the microtubule-organising centre (the centrosome), are the sites for NLRP3 assembly and HDAC6 knockout (and loss of ubiquitin-binding) leads to impaired inflammasome assembly and activation (87). Clearly, there is a complex association between NLRP3 assembly, activation and MTs, which may also be tissue/cell type specific.
An indirect link between Miro1 and NLRP3 has also been identified in a rat pancreatic cells using high-fat and high glucose stressors to mimic T2DM conditions (88). Specifically, cells exhibited dysregulated Ca2+ homeostasis, which was suggested to lead to the dissociation of Miro1 from mitochondria and subsequent impaired mitochondrial movement, stalled mitophagy and accumulation of damaged ROS producing mitochondria that in turn triggered activation of NLRP3.
Concluding Remarks
Here we have highlighted evidence for the physio-pathological role of Miro1-mediated movement of mitochondria along MTs and while the majority of data is from the study of neurons evidence is emerging to support a similar role for Miro1 in the heart (40). Therefore, in addition to studies focussing upon strategies to prevent fission (89, 90) an emerging area for future studies is the delineation of the mechanisms surrounding mitophagy, mitochondrial movement, and role of the Miro1-macromolecular complex. For example, it remains unclear as to whether Miro1 expression and activity influences the processes of fission and fusion and is essential for mitophagy in the heart.
Additionally, we have highlighted a potential link between mitochondrial motility and inflammation and the involvement of deacetylation and HDAC6 (Figure 2). Although technically there remain significant challenges around studying PTMs (91) a better understanding of the functional effects of PTMs on the proteins underpinning mitochondrial motility will provide new avenues for future research. In conclusion, this review article summarises some of the current evidence, and areas where knowledge is lacking, for mitochondrial motility in the heart, and suggests a possible unifying mechanism linking impaired mitophagy, the MT network and the inflammatory response to arrested mitochondrial movement. As the causative agents and mechanisms of mitochondrial dysfunction and impaired motility are discovered, then new promising treatment therapies may emerge for promoting better cardiac outcomes in DCM/HF.
Figure 2
Statements
Author contributions
AK and SK wrote and planned the manuscript. ZA and HD contributed to the writing process. SK generated the figures in consultation with AK. All authors contributed and approved the submitted article.
Funding
This work was supported in part by the British Heart Foundation PG/18/61/33966. HD was supported by King Abdulaziz University and ZA by The Saudi Arabian Cultural Bureau (SACB).
Conflict of interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
References
1.
SaeediPPetersohnISalpeaPMalandaBKarurangaSUnwinNet al. Global and regional diabetes prevalence estimates for 2019 and projections for 2030 and 2045: Results from the International Diabetes Federation Diabetes Atlas, 9(th) edition. Diabetes Res Clin Pract. (2019) 157:107843. 10.1016/j.diabres.2019.107843
2.
AnejaATangWHWBansilalSGarciaMJFarkouhME. Diabetic cardiomyopathy: Insights into pathogenesis, diagnostic challenges, and therapeutic options. Am J Med. (2008) 121:748–57. 10.1016/j.amjmed.2008.03.046
3.
AvogaroAde KreutzenbergSVNegutCTiengoAScognamiglioR. Diabetic cardiomyopathy: a metabolic perspective. Am J Cardiol. (2004) 93:13–6. 10.1016/j.amjcard.2003.11.003
4.
RublerSDlugashJYuceogluYZKumralTBranwoodAWGrishmanA. New type of cardiomyopathy associated with diabetic glomerulosclerosis. The Am J Cardiol. (1972) 30:595–602. 10.1016/0002-9149(72)90595-4
5.
DillmannWH. Diabetic cardiomyopathy. Circ Res. (2019) 124:1160–2. 10.1161/CIRCRESAHA.118.314665
6.
PaulusWJDal CantoE. Distinct myocardial targets for diabetes therapy in heart failure with preserved or reduced ejection fraction. JACC Heart Fail. (2018) 6:1–7. 10.1016/j.jchf.2017.07.012
7.
MeagherPAdamMCivitareseRBugyei-TwumAConnellyKA. Heart failure with preserved ejection fraction in diabetes: mechanisms and management. Can J Cardiol. (2018) 34:632–43. 10.1016/j.cjca.2018.02.026
8.
RoscaMGTandlerBHoppelCL. Mitochondria in cardiac hypertrophy and heart failure. J Mol Cell Cardiol. (2013) 55:31–41. 10.1016/j.yjmcc.2012.09.002
9.
KumarAAKellyDPChirinosJA. Mitochondrial dysfunction in heart failure with preserved ejection fraction. Circulation. (2019) 139:1435–50. 10.1161/CIRCULATIONAHA.118.036259
10.
SchillingJD. The mitochondria in diabetic heart failure: from pathogenesis to therapeutic promise. Antioxid Redox Signal. (2015) 22:1515–26. 10.1089/ars.2015.6294
11.
DaghistaniHMRajabBSKitmittoA. Three-dimensional electron microscopy techniques for unravelling mitochondrial dysfunction in heart failure and identification of new pharmacological targets. Br J Pharmacol. (2019) 176:4340–59. 10.1111/bph.14499
12.
DornGW2nd. Evolving concepts of mitochondrial dynamics. Annu Rev Physiol. (2019) 81:1–17. 10.1146/annurev-physiol-020518-114358
13.
BurteFCarelliVChinneryPFYu-Wai-ManP. Disturbed mitochondrial dynamics and neurodegenerative disorders. Nat Rev Neurol. (2015) 11:11–24. 10.1038/nrneurol.2014.228
14.
FilardTGhinassiBDi BaldassarreATanzilliGMoranoSLenziAet al. Cardiomyopathy associated with diabetes: the central role of the cardiomyocyte. Int J Mol Sci. (2019) 20:3299. 10.3390/ijms20133299
15.
KaludercicNDi LisaF. Mitochondrial ROS formation in the pathogenesis of diabetic cardiomyopathy. Front Cardiovasc Med. (2020) 7:12. 10.3389/fcvm.2020.00012
16.
MacDonaldJAWijekoonCPLiaoKCMuruveDA. Biochemical and structural aspects of the ATP-binding domain in inflammasome-forming human NLRP proteins. IUBMB Life. (2013) 65:851–62. 10.1002/iub.1210
17.
LiPL. Cardiovascular pathobiology of inflammasomes: inflammatory machinery and beyond. Antioxid Redox Signal. (2015) 22:1079–83. 10.1089/ars.2015.6319
18.
IchinoheTYamazakiTKoshibaTYanagiY. Mitochondrial protein mitofusin 2 is required for NLRP3 inflammasome activation after RNA virus infection. Proc Natl Acad Sci U S A. (2013) 110:17963–8. 10.1073/pnas.1312571110
19.
ParkSWonJHHwangIHongSLeeHKYuJW. Defective mitochondrial fission augments NLRP3 inflammasome activation. Sci Rep. (2015) 5:15489. 10.1038/srep15489
20.
YouleRJNarendraDP. Mechanisms of mitophagy. Nat Rev Mol Cell Biol. (2011) 12:9–14. 10.1038/nrm3028
21.
OkatsuKOkaTIguchiMImamuraKKosakoHTaniNet al. PINK1 autophosphorylation upon membrane potential dissipation is essential for Parkin recruitment to damaged mitochondria. Nature Comm. (2012) 3:1016. 10.1038/ncomms2016
22.
DornGW2nd. Parkin-dependent mitophagy in the heart. J Mol Cell Cardiol. (2016) 95:42–9. 10.1016/j.yjmcc.2015.11.023
23.
HuangXSunLJiSZhaoTZhangWXuJet al. Kissing and nanotunneling mediate intermitochondrial communication in the heart. Proc Natl Acad Sci U S A. (2013) 110:2846–51. 10.1073/pnas.1300741110
24.
VincentAENgYSWhiteKDaveyTMannellaCFalkousGet al. The spectrum of mitochondrial ultrastructural defects in mitochondrial myopathy. Sci Rep. (2016) 6:30610. 10.1038/srep30610
25.
LavoratoMIyerVRDewightWCupoRRDebattistiVGomezLet al. Increased mitochondrial nanotunneling activity, induced by calcium imbalance, affects intermitochondrial matrix exchanges. Proc Natl Acad Sci U S A. (2017) 114:E849–58. 10.1073/pnas.1617788113
26.
Vasquez-TrincadoCGarcia-CarvajalIPennanenCParraVHillJARothermelBAet al. Mitochondrial dynamics, mitophagy and cardiovascular disease. J Physiol. (2016) 594:509–25. 10.1113/JP271301
27.
MontaigneDMarechalXCoisneADebryNModineTFayadGet al. Myocardial contractile dysfunction is associated with impaired mitochondrial function and dynamics in type 2 diabetic but not in obese patients. Circulation. (2014) 130:554. 10.1161/CIRCULATIONAHA.113.008476
28.
GaoQWangXMYeHWYuYKangPFWangHJet al. Changes in the expression of cardiac mitofusin-2 in different stages of diabetes in rats. Mol Med Rep. (2012) 6:811–4. 10.3892/mmr.2012.1002
29.
ChenYLiuYQDornGW. Mitochondrial fusion is essential for organelle function and cardiac homeostasis. Circ Res. (2011) 109:1327–36. 10.1161/CIRCRESAHA.111.258723
30.
ChenLGongQSticeJPKnowltonAA. Mitochondrial OPA1, apoptosis, and heart failure. Cardiovas Res. (2009) 84:91–9. 10.1093/cvr/cvp181
31.
GivvimaniSPushpakumarSVeerankiSTyagiSC. Dysregulation of Mfn2 and Drp-1 proteins in heart failure. Can J Physiol Pharmacol. (2014) 92:583–91. 10.1139/cjpp-2014-0060
32.
OngSBSubrayanSLimSYYellonDMDavidsonSMHausenloyDJ. Inhibiting mitochondrial fission protects the heart against ischemia/reperfusion injury. Circulation. (2010) 121:2012–22. 10.1161/CIRCULATIONAHA.109.906610
33.
ShirakabeAZhaiPIkedaYSaitoTMaejimaYHsuCPet al. Drp1-dependent mitochondrial autophagy plays a protective role against pressure overload-induced mitochondrial dysfunction and heart failure. Circulation. (2016) 133:1249–63. 10.1161/CIRCULATIONAHA.115.020502
34.
BilliaFHauckLKonecnyFRaoVShenJMakTW. PTEN-inducible kinase 1 (PINK1)/Park6 is indispensable for normal heart function. Proc Natl Acad Sci U S A. (2011) 108:9572–7. 10.1073/pnas.1106291108
35.
KubliDAQuinsayMNGustafssonAB. Parkin deficiency results in accumulation of abnormal mitochondria in aging myocytes. Commun Integr Biol. (2013) 6:e24511. 10.4161/cib.24511
36.
AndresAMHernandezGLeePHuangCQRatliffEPSinJet al. Mitophagy is required for acute cardioprotection by simvastatin. Antioxid Redox Signal. (2014) 21:1960–73. 10.1089/ars.2013.5416
37.
LuXThaiPNLuSPuJBersDM. Intrafibrillar and perinuclear mitochondrial heterogeneity in adult cardiac myocytes. J Mol Cell Cardiol. (2019) 136:72–84. 10.1016/j.yjmcc.2019.08.013
38.
HsiehCHShaltoukiAGonzalezAEBettencourt da CruzABurbullaLFSt LawrenceEet al. Functional impairment in miro degradation and mitophagy is a shared feature in familial and sporadic parkinson's disease. Cell Stem Cell. (2016) 19:709–24. 10.1016/j.stem.2016.08.002
39.
FranssonARuusalaAAspenstromP. Atypical Rho GTPases have roles in mitochondrial homeostasis and apoptosis. J Biol Chem. (2003) 278:6495–502. 10.1074/jbc.M208609200
40.
SaotomeMSafiulinaDSzabadkaiGDasSFranssonAAspenstromPet al. Bidirectional Ca2+-dependent control of mitochondrial dynamics by the Miro GTPase. Proc Natl Acad Sci U S A. (2008) 105:20728–33. 10.1073/pnas.0808953105
41.
ZhangYYuZJiangDLiangXLiaoSZhangZet al. iPSC-MSCs with high intrinsic MIRO1 and sensitivity to TNF-alpha yield efficacious mitochondrial transfer to rescue anthracycline-induced cardiomyopathy. Stem Cell Rep. (2016) 7:749–63. 10.1016/j.stemcr.2016.08.009
42.
ConejerosCParraVSanchezGPedrozoZOlmedoI. Miro1 as a novel regulator of hypertrophy in neonatal rat cardiomyocytes. J Mol Cell Cardiol. (2020) 141:65–9. 10.1016/j.yjmcc.2020.03.014
43.
GongGSongMCsordasGKellyDPMatkovichSJDornGWet al. Parkin-mediated mitophagy directs perinatal cardiac metabolic maturation in mice. Science. (2015) 350:aad2459. 10.1126/science.aad2459
44.
BasuKLajoieDAumentado-ArmstrongTChenJKoningRIBossyBet al. Molecular mechanism of DRP1 assembly studied in vitro by cryo-electron microscopy. PLoS ONE. (2017) 12:e0179397. 10.1371/journal.pone.0179397
45.
BrickleyKSmithMJBeckMStephensonFA. GRIF-1 and OIP106, members of a novel gene family of coiled-coil domain proteins: association in vivo and in vitro with kinesin. J Biol Chem. (2005) 280:14723–32. 10.1074/jbc.M409095200
46.
Lopez-DomenechGCovill-CookeCIvankovicDHalffEFSheehanDFNorkettRet al. Miro proteins coordinate microtubule- and actin-dependent mitochondrial transport and distribution. EMBO J. (2018) 37:321–36. 10.15252/embj.201696380
47.
MiskoAJiangSWegorzewskaIMilbrandtJBalohRH. Mitofusin 2 is necessary for transport of axonal mitochondria and interacts with the Miro/Milton complex. J Neurosci. (2010) 30:4232–40. 10.1523/JNEUROSCI.6248-09.2010
48.
HuLDingMTangDGaoELiCWangKet al. Targeting mitochondrial dynamics by regulating Mfn2 for therapeutic intervention in diabetic cardiomyopathy. Theranostics. (2019) 9:3687–706. 10.7150/thno.33684
49.
MacaskillAFRinholmJETwelvetreesAEArancibia-CarcamoILMuirJFranssonAet al. Miro1 is a calcium sensor for glutamate receptor-dependent localization of mitochondria at synapses. Neuron. (2009) 61:541–55. 10.1016/j.neuron.2009.01.030
50.
BersDM. Altered cardiac myocyte Ca regulation in heart failure Physiology. Bethesda. (2006) 21:380–7. 10.1152/physiol.00019.2006
51.
PereiraLMatthesJSchusterIValdiviaHHHerzigSRichardSet al. Mechanisms of [Ca2+]i transient decrease in cardiomyopathy of db/db type 2 diabetic mice. Diabetes. (2006) 55:608–15. 10.2337/diabetes.55.03.06.db05-1284
52.
BerteroEMaackC. Calcium signaling and reactive oxygen species in mitochondria. Circ Res. (2018) 122:1460–78. 10.1161/CIRCRESAHA.118.310082
53.
KohlhaasMMaackC. Calcium release microdomains and mitochondria. Cardiovasc Res. (2013) 98:259–68. 10.1093/cvr/cvt032
54.
BelmonteSMoradM. Shear fluid-induced Ca2+ release and the role of mitochondria in rat cardiac myocytes. Ann N Y Acad Sci. (2008) 1123:58–63. 10.1196/annals.1420.007
55.
GoldsteinMAEntmanML. Microtubules in mammalian heart muscle. J Cell Biol. (1979) 80:183–95. 10.1083/jcb.80.1.183
56.
GittesFMickeyBNettletonJHowardJ. Flexural rigidity of microtubules and actin filaments measured from thermal fluctuations in shape. J Cell Biol. (1993) 120:923–34. 10.1083/jcb.120.4.923
57.
StroudMJ. Linker of nucleoskeleton and cytoskeleton complex proteins in cardiomyopathy. Biophys Rev. (2018) 10:1033–51. 10.1007/s12551-018-0431-6
58.
SteeleDFFedidaD. Cytoskeletal roles in cardiac ion channel expression. Biochim Biophys Acta. (2014) 1838:665–73. 10.1016/j.bbamem.2013.05.001
59.
CaporizzoMAChenCYProsserBL. Cardiac microtubules in health and heart disease. Exp Biol Med. (2019) 244:1255–72. 10.1177/1535370219868960
60.
CaporizzoMAChenCYBediKMarguliesKBProsserBL. Microtubules increase diastolic stiffness in failing human cardiomyocytes and myocardium. Circulation. (2020) 141:902–15. 10.1161/CIRCULATIONAHA.119.043930
61.
Caffarra MalvezziCCabassiAMiragoliM. Mitochondrial mechanosensor in cardiovascular diseases. Vasc Biol. (2020) 2:R85–92. 10.1530/VB-20-0002
62.
DebattistiVGerencserAASaotomeMDasSHajnoczkyG. ROS Control mitochondrial motility through p38 and the motor adaptor miro/trak. Cell Rep. (2017) 21:1667–80. 10.1016/j.celrep.2017.10.060
63.
StramARPayneRM. Post-translational modifications in mitochondria: protein signaling in the powerhouse. Cell Mol Life Sci. (2016) 73:4063–73. 10.1007/s00018-016-2280-4
64.
MagieraMMSinghPGadadharSJankeC. Tubulin posttranslational modifications and emerging links to human disease. Cell. (2018) 173:1323–7. 10.1016/j.cell.2018.05.018
65.
BirsaNNorkettRWauerTMevissenTEWuHCFoltynieTet al. Lysine 27 ubiquitination of the mitochondrial transport protein Miro is dependent on serine 65 of the Parkin ubiquitin ligase. J Biol Chem. (2014) 289:14569–82. 10.1074/jbc.M114.563031
66.
WangXWinterDAshrafiGSchleheJWongYLSelkoeDet al. PINK1 and Parkin target Miro for phosphorylation and degradation to arrest mitochondrial motility. Cell. (2011) 147:893–906. 10.1016/j.cell.2011.10.018
67.
Berenguer-EscuderCGrossmannDAntonyPArenaGWasnerKMassartFet al. Impaired mitochondrial-endoplasmic reticulum interaction and mitophagy in Miro1-mutant neurons in Parkinson's disease. Hum Mol Genet. (2020) 29:1353–64. 10.1093/hmg/ddaa066
68.
GrossmannDBerenguer-EscuderCBelletMEScheibnerDBohlerJMassartFet al. Mutations in RHOT1 disrupt endoplasmic reticulum-mitochondria contact sites interfering with calcium homeostasis and mitochondrial dynamics in parkinson's disease. Antioxid Redox Signal. (2019) 31:1213–34. 10.1089/ars.2018.7718
69.
KalinskiALKarANCraverJTosoliniAPSleighJNLeeSJet al. Deacetylation of Miro1 by HDAC6 blocks mitochondrial transport and mediates axon growth inhibition. J Cell Biol. (2019) 218:1871–90. 10.1083/jcb.201702187
70.
BalabanianLBergerCLHendricksAG. Acetylated microtubules are preferentially bundled leading to enhanced kinesin-1 motility. Biophys J. (2017) 113:1551–60. 10.1016/j.bpj.2017.08.009
71.
ChenSOwensGCMakarenkovaHEdelmanDB. HDAC6 regulates mitochondrial transport in hippocampal neurons. PLoS ONE. (2010) 5:e10848. 10.1371/journal.pone.0010848
72.
Demos-DaviesKMFergusonBSCavasinMAMahaffeyJHWilliamsSMSpiltoirJIet al. HDAC6 contributes to pathological responses of heart and skeletal muscle to chronic angiotensin-II signaling. Am J Physiol Heart Circ Physiol. (2014) 307:H252–8. 10.1152/ajpheart.00149.2014
73.
KeeHJBaeEHParkSLeeKESuhSHKimSWet al. HDAC inhibition suppresses cardiac hypertrophy and fibrosis in DOCA-salt hypertensive rats via regulation of HDAC6/HDAC8 enzyme activity. Kidney Blood Press Res. (2013) 37:229–39. 10.1159/000350148
74.
LengYWuYLeiSZhouBQiuZWangKet al. Inhibition of HDAC6 activity alleviates myocardial ischemia/reperfusion injury in diabetic rats: potential role of peroxiredoxin 1 acetylation and redox regulation. Oxid Med Cell Longev. (2018) 2018:9494052. 10.1155/2018/9494052
75.
JeongMYLinYHWennerstenSADemos-DaviesKMCavasinMAMahaffeyJHet al. Histone deacetylase activity governs diastolic dysfunction through a nongenomic mechanism. Sci Transl Med. (2018) 10:eaao0144. 10.1126/scitranslmed.aao0144
76.
WallnerMEatonDMBerrettaRMLiesingerLSchittmayerMGindlhuberJet al. HDAC inhibition improves cardiopulmonary function in a feline model of diastolic dysfunction. Sci Transl Med. (2020) 12:eaay7205. 10.1126/scitranslmed.aay7205
77.
LemonDDHornTRCavasinMAJeongMYHauboldKWLongCSet al. Cardiac HDAC6 catalytic activity is induced in response to chronic hypertension. J Mol Cell Cardiol. (2011) 51:41–50. 10.1016/j.yjmcc.2011.04.005
78.
LkhagvaBKaoYHLeeTILeeTWChengWLChenYJ. Activation of Class I histone deacetylases contributes to mitochondrial dysfunction in cardiomyocytes with altered complex activities. Epigenetics. (2018) 13:376–85. 10.1080/15592294.2018.1460032
79.
YanSWeiXJianWQinYLiuJZhuSet al. Pharmacological Inhibition of HDAC6 attenuates NLRP3 inflammatory response and protects dopaminergic neurons in experimental models of parkinson's disease. Front Aging Neurosci. (2020) 12:78. 10.3389/fnagi.2020.00078
80.
LuoBHuangFLiuYLiangYWeiZKeHet al. NLRP3 Inflammasome as a molecular marker in diabetic cardiomyopathy. Front Physiol. (2017) 8:519. 10.3389/fphys.2017.00519
81.
MisawaTTakahamaMKozakiTLeeHZouJSaitohTet al. Microtubule-driven spatial arrangement of mitochondria promotes activation of the NLRP3 inflammasome. Nat Immunol. (2013) 14:454–60. 10.1038/ni.2550
82.
LiXThomeSMaXAmrute-NayakMFiniganAKittLet al. MARK4 regulates NLRP3 positioning and inflammasome activation through a microtubule-dependent mechanism. Nat Commun. (2017) 8:15986. 10.1038/ncomms15986
83.
AnNGaoYSiZZhangHWangLTianCet al. Regulatory mechanisms of the NLRP3 inflammasome, a novel immune-inflammatory marker in cardiovascular diseases. Front Immunol. (2019) 10:1592. 10.3389/fimmu.2019.01592
84.
FujisueKSugamuraKKurokawaHMatsubaraJIshiiMIzumiyaYet al. Colchicine improves survival, left ventricular remodeling, and chronic cardiac function after acute myocardial infarction. Circ J. (2017) 81:1174–82. 10.1253/circj.CJ-16-0949
85.
CartaSTassiSSeminoCFossatiGMascagniPDinarelloCAet al. Histone deacetylase inhibitors prevent exocytosis of interleukin-1beta-containing secretory lysosomes: role of microtubules. Blood. (2006) 108:1618–26. 10.1182/blood-2006-03-014126
86.
HwangILeeEJeonSAYuJW. Histone deacetylase 6 negatively regulates NLRP3 inflammasome activation. Biochem Biophys Res Commun. (2015) 467:973–8. 10.1016/j.bbrc.2015.10.033
87.
MagupalliVGNegroRTianYHauensteinAVDi CaprioGSkillernWet al. HDAC6 mediates an aggresome-like mechanism for NLRP3 and pyrin inflammasome activation. Science. (2020) 369:eaas8995. 10.1126/science.aas8995
88.
GaoJLiuRTCaoSCuiJZWangAToEet al. NLRP3 inflammasome: activation and regulation in age-related macular degeneration. Mediators Inflamm. (2015) 2015:690243. 10.1155/2015/690243
89.
QiXQvitNSuYCMochly-RosenD. A novel Drp1 inhibitor diminishes aberrant mitochondrial fission and neurotoxicity. J Cell Sci. (2013) 126:789–802. 10.1242/jcs.114439
90.
Cassidy-StoneAChipukJEIngermanESongCYooCKuwanaTet al. Chemical inhibition of the mitochondrial division dynamin reveals its role in Bax/Bak-dependent mitochondrial outer membrane permeabilization. Develop Cell. (2008) 14:193–204. 10.1016/j.devcel.2007.11.019
91.
SmithLERogowska-WrzesinskaA. The challenge of detecting modifications on proteins. Essays Biochem. (2020) 64:135–53. 10.1042/EBC20190055
Summary
Keywords
diabetic cardiomyopathy, heart failure, Miro1, microtubules, HDAC6, NLRP3, mitochondrial dysfunction, mitochondrial movement
Citation
Kassab S, Albalawi Z, Daghistani H and Kitmitto A (2021) Mitochondrial Arrest on the Microtubule Highway—A Feature of Heart Failure and Diabetic Cardiomyopathy?. Front. Cardiovasc. Med. 8:689101. doi: 10.3389/fcvm.2021.689101
Received
31 March 2021
Accepted
08 June 2021
Published
02 July 2021
Volume
8 - 2021
Edited by
Venkatesh Sundararajan, The State University of New Jersey, United States
Reviewed by
Qiangrong Liang, New York Institute of Technology, United States; Iryna Bohovych, University of Nebraska-Lincoln, United States
Updates
Copyright
© 2021 Kassab, Albalawi, Daghistani and Kitmitto.
This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Ashraf Kitmitto ashraf.kitmitto@manchester.ac.uk
This article was submitted to Cardiovascular Biologics and Regenerative Medicine, a section of the journal Frontiers in Cardiovascular Medicine
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