Akt1 isoform modulates phenotypic conversion of vascular smooth muscle cells

In this study, we investigated the role of Akt1 isoform in phenotypic change of vascular smooth muscle cells (VSMCs) and neointima formation. Laminin-induced conversion of synthetic VSMCs into contractile VSMCs was measured by expression of marker proteins for contractile VSMCs and collagen gel contraction assay. Culture of synthetic VSMCs on laminin-coated plates induced expression of marker proteins for contractile VSMCs and showed contraction in response to angiotensin II (AngII) stimulation. Silencing integrin-linked kinase attenuated activation of Akt and blocked phenotypic conversion of VSMCs resulting in the loss of AngII-dependent contraction. Laminin-induced phenotypic conversion of VSMCs was abrogated by phosphatidylinositol 3-kinase inhibitor or in cells silencing Akt1 but not Akt2. Proliferation of contractile VSMCs on laminin-coated plate was enhanced in cells silencing Akt1 whereas silencing Akt2 did not affect. Promoter activity of myocardin and SM22α was enhanced in contractile phenotype and overexpression of myocardin stimulated promoter activity of SM22α in synthetic phenotype. Promoter activity of myocardin and SM22α was reduced in cells silencing Akt1 and promoter activity of SM22α was restored by overexpression of myocardin in cells silencing Akt1. However, silencing of Akt2 affected neither promoter activity of myocardin nor SM22α. Finally, neointima formation in carotid artery ligation and high fat-diet-induced atherosclerosis was facilitated in mice lacking Akt1. This study demonstrates that Akt1 isoform stimulates laminin-induced phenotypic conversion of synthetic VSMCs by regulating the expression of myocardin. VSMCs become susceptible to shifting from contractile to synthetic phenotype by the loss of Akt1 in pathological conditions.     

Myocardin is differentially required for the development of smooth muscle cells and cardiomyocytes

Myocardin is a serum response factor (SRF) coactivator exclusively expressed in cardiomyocytes and smooth muscle cells (SMCs). However, there is highly controversial evidence as to whether myocardin is essential for normal differentiation of these cell types, and there are no data showing whether cardiac or SMC subtypes exhibit differential myocardin requirements during development. Results of the present studies showed the virtual absence of myocardin(-/-) visceral SMCs or ventricular myocytes in chimeric myocardin knockout (KO) mice generated by injection of myocardin(-/-) embryonic stem cells (ESCs) into wild-type (WT; i.e., myocardin(+/+) ESC) blastocysts. In contrast, myocardin(-/-) ESCs readily formed vascular SMC, albeit at a reduced frequency compared with WT ESCs. In addition, myocardin(-/-) ESCs competed equally with WT ESCs in forming atrial myocytes. The ultrastructural features of myocardin(-/-) vascular SMCs and cardiomyocytes were unchanged from their WT counterparts as determined using a unique X-ray microprobe transmission electron microscopic method developed by our laboratory. Myocardin(-/-) ESC-derived SMCs also showed normal contractile properties in an in vitro embryoid body SMC differentiation model, other than impaired thromboxane A2 responsiveness. Together, these results provide novel evidence that myocardin is essential for development of visceral SMCs and ventricular myocytes but is dispensable for development of atrial myocytes and vascular SMCs in the setting of chimeric KO mice. In addition, results suggest that as yet undefined defects in development and/or maturation of ventricular cardiomyocytes may have contributed to early embryonic lethality observed in conventional myocardin KO mice and that observed deficiencies in development of vascular SMC may have been secondary to these defects.     

Transient reexpression of an embryonic autonomous growth phenotype by adult carotid artery smooth muscle cells after vascular injury

High rates of vascular smooth muscle cell (SMC) replication are observed, at least transiently, after injury to the arterial wall and contribute to the formation of a neointima. Neutralizing antibodies designed to inhibit growth of SMC have only been variably successful in inhibiting neointima formation, raising the possibility that neointimal cell proliferation involves unique growth mechanisms. This study examined the possibility that SMC isolated from injured rat carotid arteries would express an autonomous, mitogen-independent growth phenotype similar to that utilized by embryonic vascular SMC during periods of rapid growth. We found that primary cultures of SMC isolated 7 and 14 days after injury, times at which high in vivo replication rates were observed, demonstrated high intrinsic DNA synthetic rates compared to SMC isolated from uninjured arteries or at 2, 4, 21, and 28 days after injury where in vivo replication rates were far less. Subcultured SMC isolated from 7-day injured vessels (Neo7 SMC) exhibited a stable, autonomous growth phenotype, did not secrete detectable mitogenic activity, and had decreased alpha-actin and myosin expression compared to mitogen-dependent SMC. Heterokaryons constructed between autonomous Neo7 SMC and mitogen-dependent SMC exhibited a mitogen-dependent growth phenotype suggesting that nonautonomous SMC produce factors that actively inhibit autonomous growth. In contrast, heterokaryons constructed between Neo7 SMC and autonomous embryonic SMC retained an autonomous growth phenotype. We examined the expression of known tumor suppressors to determine if any of these factors played a role in inhibiting SMC autonomous growth. p27, p53, pRb, and PTEN were abundantly expressed by Neo7 SMC and e17 SMC under both basal and serum stimulated conditions. The data suggest that the mechanisms driving SMC replication during neointimal formation are self-driven and self-regulated, and that at specific times after injury, SMC escape normal growth suppressive mechanisms through the loss of intracellular growth suppressor activity.     

Repression of Smooth Muscle Differentiation by a Novel High Mobility Group Box-containing Protein,HMG2L1

The molecular mechanisms regulating smooth muscle-specific gene expression during smooth muscle development are poorly understood. Myocardin is an extraordinarily powerful cofactor of serum response factor (SRF) that stimulates expression of smooth muscle-specific genes. In an effort to search for proteins that regulate myocardin function, we identified a novel HMG box-containing protein HMG2L1 (high mobility group 2 like 1). We found that HMG2L1 expression is correlated with the smooth muscle cell (SMC) synthetic phenotype. Overexpression of HMG2L1 in SMCs down-regulated smooth muscle marker expression. Conversely, depletion of endogenous HMG2L1 in SMCs increases smooth muscle-specific gene expression. Furthermore, we found HMG2L1 specifically abrogates myocardin-induced activation of smooth muscle-specific genes. By GST pulldown assays, the interaction domains between HMG2L1 and myocardin were mapped to the N termini of each of the proteins. Finally, we demonstrated that HMG2L1 abrogates myocardin function through disrupting its binding to SRF and abolishing SRF-myocardin complex binding to the promoters of smooth muscle-specific genes. This study provides the first evidence of this novel HMG2L1 molecule playing an important role in attenuating smooth muscle differentiation.