Myocardin-related Transcription Factor Research Articles

Myocardin related transcription factors are required for coordinated cell cycle progression

Myocardin related transcription factors A and B (MRTFs) activate serum response factor-driven transcription in response to Rho signaling and changes in actin dynamics. Myocardin and MRTFs have been implicated in anti-proliferative effects on a range of cell types. The precise mechanisms, however, remained elusive. We employed double knockdown of MRTF-A and MRTF-B in NIH 3T3 fibroblasts to evaluate its effects on cell cycle progression and proliferation. We show that transient depletion of MRTFs conveys a modest anti-proliferative effect and impinges on normal cell cycle progression, resulting in significantly shortened G1 phase and slightly extended S and G2 phase under normal growth conditions. Under serum-starved conditions we observed aberrant entry into the S and G2 phases without subsequent cell division. This was accompanied by downregulation of cyclin-CDK inhibitors p27Kip1, p18Ink4c and 19Ink4d as well as upregulation of p21Waf1 and cyclin D1. Extended knockdown led to increased formation of micronuclei, while cells stably depleted of MRTFs tend to become aneuploid and polyploid. Thus, MRTFs are required for accurate cell cycle progression and maintenance of genomic stability in fibroblast cells.

SRF selectively controls tip cell invasive behavior in angiogenesis

Efficient angiogenic sprouting is essential for embryonic, postnatal and tumor development. Serum response factor (SRF) is known to be important for embryonic vascular development. Here, we studied the effect of inducible endothelial-specific deletion of Srf in postnatal and adult mice. We find that endothelial SRF activity is vital for postnatal growth and survival, and is equally required for developmental and pathological angiogenesis, including during tumor growth. Our results demonstrate that SRF is selectively required for endothelial filopodia formation and cell contractility during sprouting angiogenesis, but seems dispensable for vascular remodeling. At the molecular level, we observe that vascular endothelial growth factor A induces nuclear accumulation of myocardin-related transcription factors (MRTFs) and regulates MRTF/SRF-dependent target genes including Myl9, which is important for endothelial cell migration in vitro. We conclude that SRF has a unique function in regulating migratory tip cell behavior during sprouting angiogenesis. We hypothesize that targeting the SRF pathway could provide an opportunity to selectively target tip cell filopodia-driven angiogenesis to restrict tumor growth.

SRF selectively controls tip cell invasive behavior in angiogenesis

Efficient angiogenic sprouting is essential for embryonic, postnatal and tumor development. Serum response factor (SRF) is known to be important for embryonic vascular development. Here, we studied the effect of inducible endothelial-specific deletion of Srf in postnatal and adult mice. We find that endothelial SRF activity is vital for postnatal growth and survival, and is equally required for developmental and pathological angiogenesis, including during tumor growth. Our results demonstrate that SRF is selectively required for endothelial filopodia formation and cell contractility during sprouting angiogenesis, but seems dispensable for vascular remodeling. At the molecular level, we observe that vascular endothelial growth factor A induces nuclear accumulation of myocardin-related transcription factors (MRTFs) and regulates MRTF/SRF-dependent target genes including Myl9, which is important for endothelial cell migration in vitro. We conclude that SRF has a unique function in regulating migratory tip cell behavior during sprouting angiogenesis. We hypothesize that targeting the SRF pathway could provide an opportunity to selectively target tip cell filopodia-driven angiogenesis to restrict tumor growth.

Serum amyloid A and Toll‐like receptor 2 activation promote de‐differentiation of vascular smooth muscle cells

Smooth muscle cells (SMCs) regulate vascular tone, and during chronic inflammation associated with atherosclerosis, SMCs contribute to the disease process via de‐differentiation from a contractile state. We study the impact of acute phase serum amyloid A (SAA), a cardiovascular risk marker that localizes to atherosclerotic plaques, on SMC function. The goal of this study was to define a role for SAA in SMC phenotypic expression. SMC marker expression was down‐regulated by SAA, consistent with de‐differentiation. Myocardin, a transcriptional co‐activator of SMC marker gene expression, was down‐regulated by SAA, and its overexpression rescued the SAA‐mediated repression of the smooth muscle α‐actin and smooth muscle 22 α (SM22) promoters. SAA‐mediated down‐regulation of SM22 promoter activity was also rescued by expression of the myocardin family members, myocardin related transcription factor (MRTF)‐A and MRTF‐B. It was reported that SAA is a ligand for the Toll‐like receptor (TLR)2, which has been implicated in atherosclerosis. Interestingly, FSL‐1 and Pam3CSK4, known TLR2 ligands, down‐regulated SM22 promoter activity, and the effects were rescued with myocardin overexpression. Moreover, knockdown of TLR2 using siRNA rescued the de‐differentiated phenotype induced by SAA. These data suggest that SAA and TLR2 activation promote SMC de‐differentiation characteristic of atherosclerosis.This work was supported by NIH grant HL079201.

Rho kinase; myocardin-related transcription factor A (MKL1; MAL; MRTF-1)

Rho kinase; myocardin-related transcription factor A (MKL1; MAL; MRTF-1)

Differences in the Nuclear Export Mechanism between Myocardin and Myocardin-related Transcription Factor A

Myocardin (Mycd), a key factor in smooth muscle cell differentiation, is constitutively located in the nucleus, whereas myocardin-related transcription factors A and B (MRTF-A/B) reside mostly in the cytoplasm and translocate to the nucleus in a Rho-dependent manner. Here, we investigated the nuclear export of Mycd family members. They possess two leucine-rich sequences: L1 in the N terminus and L2 in the Gln-rich domain. Although L2 (but not L1) served as a CRM1-binding site for Mycd, CRM1-mediated nuclear export did not affect its subcellular localization. Serum response factor (SRF) competitively inhibited Mycd/CRM1 interaction. Furthermore, such interaction was autonomously inhibited. The N terminus of Mycd bound intramolecularly to Mycd, resulting in masking L2. In contrast, the CRM1-binding affinity of MRTF-A was much higher than that of Mycd because both L1 and L2 of MRTF-A served as functional CRM1-binding sites, and the autoinhibition observed in the Mycd/CRM1 interaction was absent in the MRTF-A/CRM1 interaction. Additionally, because the SRF-binding affinity of MRTF-A was lower than that of Mycd, the inhibitory effect of SRF on the MRTF-A/CRM1 interaction was weak. Thus, MRTF-A is much more likely to be exported from the nucleus. These differences could be the reason for the distinct subcellular localization of Mycd and MRTF-A.

Role of myocardin-related transcription factors in myofibroblastic activation of valvular interstitial cells from aortic valves

Role of myocardin-related transcription factors in myofibroblastic activation of valvular interstitial cells from aortic valves

LPA1‐induced cytoskeleton reorganization drives fibrosis through CTGF‐dependent fibroblast proliferation

There has been much recent interest in lysophosphatidic acid (LPA) signaling through one of its receptors, LPA1, in fibrotic diseases, but the mechanisms by which LPA-LPA1 signaling promotes pathological fibrosis remain to be fully elucidated. Using a mouse peritoneal fibrosis model, we demonstrate central roles for LPA and LPA1 in fibroblast proliferation. Genetic deletion or pharmacological antagonism of LPA1 protected mice from peritoneal fibrosis, blunting the increases in peritoneal collagen by 65.4 and 52.9%, respectively, compared to control animals and demonstrated that peritoneal fibroblast proliferation was highly LPA1 dependent. Activation of LPA1 on mesothelial cells induced these cells to express connective tissue growth factor (CTGF), driving fibroblast proliferation in a paracrine fashion. Activation of mesothelial cell LPA1 induced CTGF expression by inducing cytoskeleton reorganization in these cells, causing nuclear translocation of myocardin-related transcription factor (MRTF)-A and MRTF-B. Pharmacological inhibition of MRTF-induced transcription also diminished CTGF expression and fibrosis in the peritoneal fibrosis model, mitigating the increase in peritoneal collagen content by 57.9% compared to controls. LPA1-induced cytoskeleton reorganization therefore makes a previously unrecognized but critically important contribution to the profibrotic activities of LPA by driving MRTF-dependent CTGF expression, which, in turn, drives fibroblast proliferation.

Importance of Dimer Formation of Myocardin Family Members in the Regulation of Their Nuclear Export

Myocardin (Mycd) family members function as a transcriptional cofactor for serum response factor (SRF). Dimer formation is necessary to exhibit their function, and the coiled-coil domain (CC) plays a critical role in their dimerization. We have recently revealed a detailed molecular mechanism for their Crm1 (exportin1)-mediated nuclear export. Here, we found other unique significances of the dimerization of Mycd family members. Introduction of mutations in the CC of myocardin-related transcription factor A (MRTF-A) and truncated Mycd resulted in significant decreases in their cytoplasmic localization and increases in their nuclear localization. In accordance with such subcellular localization changes, their binding to Crm1 were reduced. These results indicate that the dimerization of Mycd family members is necessary for their Crm1-mediated nuclear export. We have recently found that the N-terminal region of Mycd consisting of 128 amino acids (Mycd N128) self-associates to Mycd via the central basic domain (CB), resulting in masking the Crm1-binding site. Such self-association of MRTF-A would be unlikely. In this study, we also revealed that the dimerization of Mycd was also necessary for this self-association. Wild-type Mycd activated SRF-mediated transcription more potently than Mycd lacking the Mycd N128 (Mycd ΔN128) did. These results suggest two possible functions of the Mycd N128: 1) stabilization of Mycd dimer to enhance SRF-mediated transcription and 2) positive regulation of the transactivation ability of Mycd. These findings provide a new insight into the functional regulation of Mycd family members.

Mitogen-Activated Protein Kinase 14 Is a Novel Negative Regulatory Switch for the Vascular Smooth Muscle Cell Contractile Gene Program

Several studies have shown through chemical inhibitors that p38 mitogen-activated protein kinase (MAPK) promotes vascular smooth muscle cell (VSMC) differentiation. Here, we evaluate the effects of knocking down a dominant p38MAPK isoform on VSMC differentiation. Knockdown of p38MAPKα (MAPK14) in human coronary artery SMCs unexpectedly increases VSMC differentiation genes, such as miR145, ACTA2, CNN1, LMOD1, and TAGLN, with little change in the expression of serum response factor (SRF) and 2 SRF cofactors, myocardin (MYOCD) and myocardin-related transcription factor A (MKL1). A variety of chemical and biological inhibitors demonstrate a critical role for a RhoA-MKL1-SRF-dependent pathway in mediating these effects. MAPK14 knockdown promotes MKL1 nuclear localization and VSMC marker expression, an effect partially reversed with Y27632; in contrast, MAP2K6 (MKK6) blocks MKL1 nuclear import and VSMC marker expression. Immunostaining and Western blotting of injured mouse carotid arteries reveal elevated MAPK14 (both total and phosphorylated) and reduced VSMC marker expression. Reduced MAPK14 expression evokes unanticipated increases in VSMC contractile genes, suggesting an unrecognized negative regulatory role for MAPK14 signaling in VSMC differentiation.

Reciprocal expression of MRTF-A and myocardin is crucial for pathological vascular remodelling in mice

Myocardin-related transcription factor (MRTF)-A is a Rho signalling-responsive co-activator of serum response factor (SRF). Here, we show that induction of MRTF-A expression is key to pathological vascular remodelling. MRTF-A expression was significantly higher in the wire-injured femoral arteries of wild-type mice and in the atherosclerotic aortic tissues of ApoE(-/-) mice than in healthy control tissues, whereas myocardin expression was significantly lower. Both neointima formation in wire-injured femoral arteries in MRTF-A knockout (Mkl1(-/-)) mice and atherosclerotic lesions in Mkl1(-/-); ApoE(-/-) mice were significantly attenuated. Expression of vinculin, matrix metallopeptidase 9 (MMP-9) and integrin β1, three SRF targets and key regulators of cell migration, in injured arteries was significantly weaker in Mkl1(-/-) mice than in wild-type mice. In cultured vascular smooth muscle cells (VSMCs), knocking down MRTF-A reduced expression of these genes and significantly impaired cell migration. Underlying the increased MRTF-A expression in dedifferentiated VSMCs was the downregulation of microRNA-1. Moreover, the MRTF-A inhibitor CCG1423 significantly reduced neointima formation following wire injury in mice. MRTF-A could thus be a novel therapeutic target for the treatment of vascular diseases.

Salt, skeletons, and suicide. Focus on “Hyperosmotic stress regulates the distribution and stability of myocardin-related transcription factor, a key modulator of the cytoskeleton”

high NaCl and other sources of hypertonicity are cellular stresses that span evolution. A protective response common to most organisms is cellular accumulation of compatible organic osmolytes, driven by increased transcription of transporters and synthesizing enzymes. In mammalian cells the

Circulation: Clinical Summaries

<i>Circulation:</i> Clinical Summaries

Hyperosmotic stress regulates the distribution and stability of myocardin-related transcription factor, a key modulator of the cytoskeleton

Hyperosmotic stress initiates several adaptive responses, including the remodeling of the cytoskeleton. Besides maintaining structural integrity, the cytoskeleton has emerged as an important regulator of gene transcription. Myocardin-related transcription factor (MRTF), an actin-regulated coactivator of serum response factor, is a major link between the actin skeleton and transcriptional control. We therefore investigated whether MRTF is regulated by hyperosmotic stress. Here we show that hypertonicity induces robust, rapid, and transient translocation of MRTF from the cytosol to the nucleus in kidney tubular cells. We found that the hyperosmolarity-triggered MRTF translocation is mediated by the RhoA/Rho kinase (ROK) pathway. Moreover, the Rho guanine nucleotide exchange factor GEF-H1 is activated by hyperosmotic stress, and it is a key contributor to the ensuing RhoA activation and MRTF translocation, since siRNA-mediated GEF-H1 downregulation suppresses these responses. While the osmotically induced RhoA activation promotes nuclear MRTF accumulation, the concomitant activation of p38 MAP kinase mitigates this effect. Moderate hyperosmotic stress (600 mosM) drives MRTF-dependent transcription through the cis-element CArG box. Silencing or pharmacological inhibition of MRTF prevents the osmotic stimulation of CArG-dependent transcription and renders the cells susceptible to osmotic shock-induced structural damage. Interestingly, strong hyperosmolarity promotes proteasomal degradation of MRTF, concomitant with apoptosis. Thus, MRTF is an osmosensitive and osmoprotective transcription factor, whose intracellular distribution is regulated by the GEF-H1/RhoA/ROK and p38 pathways. However, strong osmotic stress destabilizes MRTF, concomitant with apoptosis, implying that hyperosmotically induced cell death takes precedence over epithelial-myofibroblast transition, a potential consequence of MRTF-mediated phenotypic reprogramming.

Structures of the Phactr1 RPEL Domain and RPEL Motif Complexes with G-Actin Reveal the Molecular Basis for Actin Binding Cooperativity

The Phactr family of PP1-binding proteins and the myocardin-related transcription factor family of transcriptional coactivators contain regulatory domains comprising three copies of the RPEL motif, a G-actin binding element. We report the structure of a Phactr1 G-actin⋅RPEL domain complex. Three G-actins surround the crank-shaped RPEL domain forminga closed helical assembly. Their spatial relationship is identical to the RPEL-actins within the pentavalent MRTF G-actin⋅RPEL domain complex, suggesting that conserved cooperative interactions between actin⋅RPEL units organize the assembly. In the trivalent Phactr1 complex, each G-actin⋅RPEL unit makes secondary contacts with its downstream actin involving distinct RPEL residues. Similar secondary contacts are seen in G-actin⋅RPEL peptide crystals. Loss-of-secondary-contact mutations destabilize the Phactr1 G-actin⋅RPEL assembly. Furthermore, actin-mediated inhibition of Phactr1 nuclear import requires secondary contact residues in the Phactr1 N-terminal RPEL-N motif, suggesting that it involves interaction of RPEL-N with the C-terminal assembly. Secondary actin contacts by actin-bound RPEL motifs thus govern formation of multivalent actin⋅RPEL assemblies.

G 13 -Mediated Signaling Pathway Is Required for Pressure Overload–Induced Cardiac Remodeling and Heart Failure

Cardiac remodeling in response to pressure or volume overload plays an important role in the pathogenesis of heart failure. Various mechanisms have been suggested to translate mechanical stress into structural changes, one of them being the release of humoral factors such as angiotensin II and endothelin-1, which in turn promote cardiac hypertrophy and fibrosis. A large body of evidence suggests that the prohypertrophic effects of these factors are mediated by receptors coupled to the G(q/11) family of heterotrimeric G proteins. Most G(q/11)-coupled receptors, however, can also activate G proteins of the G(12/13) family, but the role of G(12/13) in cardiac remodeling is not understood. We use siRNA-mediated knockdown in vitro and conditional gene inactivation in vivo to study the role of the G(12/13) family in pressure overload-induced cardiac remodeling. We show in detail that inducible cardiomyocyte-specific inactivation of the α subunit of G(13), Gα(13), does not affect basal heart function but protects mice from pressure overload-induced hypertrophy and fibrosis as efficiently as inactivation of Gα(q/11). Furthermore, inactivation of Gα(13) prevents the development of heart failure up to 1 year after overloading. On the molecular level, we show that Gα(13), but not Gα(q/11), controls agonist-induced expression of hypertrophy-specific genes through activation of the small GTPase RhoA and consecutive activation of myocardin-related transcription factors. Our data show that the G(12/13) family of heterotrimeric G proteins is centrally involved in pressure overload-induced cardiac remodeling and plays a central role in the transition to heart failure.

The Actin–MRTF–SRF Gene Regulatory Axis and Myofibroblast Differentiation

Cardiac fibroblasts are responsible for necrotic tissue replacement and scar formation after myocardial infarction (MI) and contribute to remodeling in response to pathological stimuli. This response to insult or injury is largely due to the phenotypic plasticity of fibroblasts. When fibroblasts encounter environmental disturbances, whether biomechanical or humoral, they often transform into smooth muscle-like, contractile cells called "myofibroblasts." The signals that control myofibroblast differentiation include the transforming growth factor (TGF)-β1-Smad pathway and Rho GTPase-dependent actin polymerization. Recent evidence implicates serum response factor (SRF) and the myocardin-related transcription factors (MRTFs) as key mediators of the contractile gene program in response to TGF-β1 or RhoA signaling. This review highlights the function of myofibroblasts in cardiac remodeling and the role of the actin-MRTF-SRF signaling axis in regulating this process.

Bone Morphogenetic Protein Signaling in Vascular Disease: ANTI-INFLAMMATORY ACTION THROUGH MYOCARDIN-RELATED TRANSCRIPTION FACTOR A

Pulmonary artery hypertension (PAH) patients exhibit elevated levels of inflammatory cytokines and infiltration of inflammatory cells in the lung. Concurrently, mutations of bmpr2, the gene encoding the type II receptor of bone morphogenetic proteins (BMP), are found in ∼75% of patients with familial PAH, but a possible nexus between increased inflammation and diminished BMP signaling has hitherto remained elusive. We previously showed that BMP4 triggers nuclear localization of the Myocardin-related transcription factor A (MRTF-A) in human pulmonary artery smooth muscle cells (PASMC), resulting in the induction of contractile proteins. Here we report the BMPR2-dependent repression of a set of inflammatory mediators in response to BMP4 stimulation of PASMC. Forced expression of MRTF-A precisely emulates the anti-inflammatory effect of BMP4, while MRTF-A depletion precludes BMP4-mediated cytokine inhibition. BMP4 and MRTF-A block signaling through NF-κB, the keystone of most pathways leading to inflammatory responses, at the level of chromatin recruitment and promoter activation. Moreover, MRTF-A physically interacts with RelA/p65, the NF-κB subunit endowed with a transcription activation domain. Interestingly, the MRTF-A-NF-κB interaction is mutually antagonistic: stimulation of NF-κB signaling by TNFα, as well as p65 overexpression, hinders MRTF-A activity and the expression of contractile genes. Thus, a molecular inhibitory pathway linking BMP4 signaling, activation of MRTF-A, and inhibition of NF-κB provides insights into the etiology of PAH and a potential focus of therapeutic intervention.

MKLs: Co-factors of serum response factor (SRF) in neuronal responses

Serum response factor (SRF) is a major transcription factor that regulates activity-driven gene expression in neurons. Activation of SRF-driven transcription occurs through its interaction with two families of co-factors: ternary complex factor (TCF) and myocardin-related transcription factors (MRTFs). This review focuses on the MRTF family members MKL1 (MAL/MRTF-A/BSAC) and MKL2 (MRTF-B/MAL16). MKLs share several high-homology domains but a low level of sequence identity in the transactivation domain. Both co-activators are expressed in the brain and regulate SRF-dependent gene expression. MKL1 and MKL2 function as major co-activators of SRF function in the developing mouse brain. MKLs inactivation causes ineffective neuronal migration and aberrant neurite outgrowth during development. Moreover, inhibition of MKL1 or MKL2 by short-hairpin RNAs results in a decreased number of dendritic processes and dendritic length. Altogether, MKLs appear to regulate plasticity-related structural changes in neurons.

Repression of Cardiac Hypertrophy by KLF15: Underlying Mechanisms and Therapeutic Implications

The Kruppel-like factor (KLF) family of transcription factors regulates diverse cell biological processes including proliferation, differentiation, survival and growth. Previous studies have shown that KLF15 inhibits cardiac hypertrophy by repressing the activity of pivotal cardiac transcription factors such as GATA4, MEF2 and myocardin. We set out this study to characterize the interaction of KLF15 with putative other transcription factors. We first show that KLF15 interacts with myocardin-related transcription factors (MRTFs) and strongly represses the transcriptional activity of MRTF-A and MRTF-B. Second, we identified a region within the C-terminal zinc fingers of KLF15 that contains the nuclear localization signal. Third, we investigated whether overexpression of KLF15 in the heart would have therapeutic potential. Using recombinant adeno-associated viruses (rAAV) we have overexpressed KLF15 specifically in the mouse heart and provide the first evidence that elevation of cardiac KLF15 levels prevents the development of cardiac hypertrophy in a model of Angiotensin II induced hypertrophy.