Makoto Kuro-o

Human smooth muscle myosin heavy chain isoforms as molecular markers for vascular development and atherosclerosis.

Smooth muscle myosin heavy chains (MHCs) exist in multiple isoforms. Rabbit smooth muscles contain at least three types of MHC isoforms: SM1 (204 kD), SM2 (200 kD), and SMemb (200 kD). SM1 and SM2 are specific to smooth muscles, but SMemb is a nonmuscle-type MHC abundantly expressed in the embryonic aorta. We recently reported that these three MHC isoforms are differentially expressed in rabbit during normal vascular development and in experimental arteriosclerosis and atherosclerosis. The purpose of this study was to clarify whether expression of human smooth muscle MHC isoforms is regulated in developing arteries and in atherosclerotic lesions. To accomplish this, we have isolated and characterized three cDNA clones from human smooth muscle: SMHC94 (SM1), SMHC93 (SM2), and HSME6 (SMemb). The expression of SM2 mRNA in the fetal aorta was significantly lower as compared with SM1 mRNA, but the ratio of SM2 to SM1 mRNA was increased after birth. SMemb mRNA in the aorta was decreased after birth but appeared to be increased in the aged. To further examine the MHC expression at the histological level, we have developed three antibodies against human SM1, SM2, and SMemb using the isoform-specific sequences of the carboxyl terminal end. Immunohistologically, SM1 was constitutively positive from the fetal stage to adulthood in the apparently normal media of the aorta and coronary arteries, whereas SM2 was negative in fetal arteries of the early gestational stage. In human, unlike rabbit, aorta or coronary arteries, SMemb was detected even in the adult. However, smaller-sized arteries, like the vasa vasorum of the aorta or intramyocardial coronary arterioles, were negative for SMemb. Diffuse intimal thickening in the major coronary arteries was found to be composed of smooth muscles, reacting equally to three antibodies for MHC isoforms, but reactivities with anti-SM2 antibody were reduced with aging. With progression of atherosclerosis, intimal smooth muscles diminished the expression of not only SM2 but also SM1, whereas alpha-smooth muscle actin was well preserved. We conclude from these results that smooth muscle MHC isoforms are important molecular markers for studying human vascular smooth muscle cell differentiation as well as the cellular mechanisms of atherosclerosis.

BTEB2, a Krüppel-Like Transcription Factor, Regulates Expression of the SMemb/Nonmuscle Myosin Heavy Chain B (SMemb/NMHC-B) Gene

We have recently characterized the promoter region of the rabbit embryonic smooth muscle myosin heavy chain (SMemb/NMHC-B) gene and identified the 15-bp sequence, designated SE1, located at -105 from the transcriptional start site as an important regulatory element for its transcriptional activity in a smooth muscle cell (SMC) line. In this study, we attempted to isolate cDNA clones encoding for the transcription factors that control the expression of the SMemb gene through binding to this cis-regulatory element. We screened a lambdagt11 cDNA library prepared from C2/2 cells, a rabbit-derived SMC line, by using a radiolabeled concatenated oligonucleotide containing SE1 as a probe. Sequence analysis revealed that one of the cDNA clones corresponds to the rabbit homologue of basic transcriptional element binding protein-2 (BTEB2), which has previously been identified as one of the Krüppel-like transcription factor. Gel mobility shift assays and antibody supershift analyses with nuclear extracts from C2/2 cells indicate that BTEB2 is a major component of nuclear factor:SE1 complexes. Furthermore, a glutathione S-transferase-BTEB2 fusion protein binds to the SE1 in a sequence-specific manner. In support of the functionality of BTEB2 binding, basal promoter activity and BTEB2-induced transcriptional activation were markedly attenuated by the disruption of the SE1. In adult rabbit tissues, BTEB2 mRNA was most highly expressed in intestine, urinary bladder, and uterus. BTEB2 mRNA levels were downregulated in rabbit aorta during normal development. Moreover, immunohistochemical analysis indicated a marked induction of BTEB2 protein in the neointimal SMC after balloon injury in rat aorta. These results suggest that BTEB2 mediates the transcriptional regulation of the SMemb/NMHC-B gene and possibly plays a role in regulating gene expression during phenotypic modulation of vascular SMC.

Activation of Na+-H+ Antiporter (NHE-1) gene expression during growth, hypertrophy and proliferation of the rabbit cardiovascular system

The Na(+)-H+ antiporter is a unique transmembrane protein with multiple roles in cellular functions through intracellular alkalization. It participates in the regulation of intracellular pH, cell volume and intracellular signalling in response to various mitogenic stimuli. To clarify its role as a subcellular signal in cardiovascular remodeling like vascular hyperplasia or cardiac hypertrophy, we determined mRNA levels of the Na(+)-H+ antiporter isoform, NHE-1, in vascular smooth muscles and pressure-overloaded hearts in rabbits. The NHE-1 mRNA levels in rabbit aortas and hearts were developmentally regulated with high levels at embryonic and neonatal stages than in adults. In primary-cultured smooth muscle cells (SMC), the mRNA levels were increased during exponential growth, but decreased to initial levels at confluency. Growth of a mutant SMC line, C5, which is deficient in Na(+)-H+ antiporter activity, was markedly reduced in bicarbonate-free medium. However, when the activity was restored by transfecting cells with a full-length NHE-1 cDNA in an expression vector, the growth rate of C5 was accelerated again. After balloon injury to the vascular wall, the NHE-1 mRNA levels of the injured arteries were also increased, suggesting that Na(+)-H+ antiporter contributes to the network of the growth promoting systems in smooth muscle cells in vivo. Pressure-overload on the ventricle increased the NHE-1 mRNA levels in hearts approximately two-fold of sham-operated rabbits after 3 days and remained for at least two weeks (P < 0.05). We further demonstrated that 3-methylsulfonyl-4-piperidino-benzoyl guanidine mesylate (Hoe 694), a potent antagonist of Na(+)-H+ antiporter, partially inhibited stretch-induced activation of mitogen-activated kinase (MAP kinase) in the cultured cardiomyocytes. From these results, we conclude that activation of the Na(+)-H+ antiporter and its gene expression is involved in molecular mechanisms of both cardiac hypertrophy and vascular smooth muscle cell proliferation, indicating a potential target in developing new therapeutics for cardiovascular diseases.

Ductus arteriosus. Advanced differentiation of smooth muscle cells demonstrated by myosin heavy chain isoform expression in rabbits.

BackgroundThe closure of the ductus arteriosus (DA) is one of the most striking cardiovascular events that occur at birth. It has been attributed to oxygenation and intrinsic prostaglandins. However, selective constriction of DA suggests the presence of highly specialized contractile mechanisms in DA. We previously reported that smooth muscle myosin heavy chain isoforms, SM1 and SM2, are molecular markers for smooth muscle differentiation because of their unique expression pattern during vascular development. SM1 and SM2 are generated from a single gene through developmentally regulated alternative RNA splicing; SMI is expressed in almost all stages of differentiation of the vascular smooth muscles, but SM2 is found only after birth. Methods and ResultsImmunohistochemistry was performed to study the expression of the different types of myosin heavy chain isoforms in DA of fetal and neonatal rabbits. Electron microscopic examinations were also carried out to demonstrate ultrastructural characteristics of ductus muscles. We found that SM2 is expressed before birth in the medial layer of DA, indicating advanced differentiation of smooth muscle cells in DA. The exact location of immunoreactivity for SM2 was in the smooth muscle cell of the medial layer of DA. Immunoreactivity for SM1, however, was not different for DA and adjacent great arteries. Transmission electron microscopy demonstrated greater amounts of myofilaments in medial smooth muscles of DA than those of aorta ConclusionsThese results indicate that smooth muscles in DA are more differentiated than those in other arteries, which may be one of the cellular mechanisms responsible for the unique closure of DA at birth.

Isozymic changes in myosin of human atrial myocardium induced by overload. Immunohistochemical study using monoclonal antibodies.

An immunohistochemical study using monoclonal antibodies specific for the heavy chains of either human atrial (HC alpha) or ventricular (HC beta) myosin was performed to clarify the distribution of each isozyme in normal as well as pressure-overloaded human hearts. In normal human ventricles, all muscle fibers were stained by a monoclonal antibody (HMC14) specific for HC beta, whereas a small number of fibers reacted with a monoclonal antibody (CMA19) specific for HC alpha. In contrast, in normal human atria, almost all muscle fibers were stained by CMA19, and a relatively larger number of muscle fibers also reacted with HMC14. Furthermore, in pressure-overloaded atria, muscle fibers reactive with HMC14 were strikingly increased while those reactive with CMA19 showed a corresponding decrease. The extent of this isozymic redistribution was in good correlation with atrial pressure. These results not only confirmed the existence of isoforms of myosin heavy chain in human hearts, but also demonstrated that redistribution of iso-myosins could occur as an adaptation to pressure overload.

Identification of three types of PDGF-A chain gene transcripts in rabbit vascular smooth muscle and their regulated expression during development and by angiotensin II

PDGF-like peptides secreted from smooth muscles have been suggested to be responsible for the smooth muscle growth. In order to elucidate the nature of PDGF-like molecules expressed in vascular smooth muscles, we have isolated and characterized cDNA clones for PDGF-A chain from a rabbit embryonic aorta cDNA library. One of the cDNA clones was found to encode a novel PDGF-A chain, named PDGF-A3 in this report. PDGF-A3 arises from a single PDGF-A chain gene by alternative RNA splicing and differs from the sequences of previously reported endothelial- or the glioma-type transcripts by a 110 bp insertion. Expression of PDGF-A3 mRNA was selectively induced by Angiotensin II in the smooth muscle cell in vitro. Total PDGF-A mRNA is most enriched in embryonic aortas, but its expression is down-regulated with vascular development. PDGF-A mRNA is markedly increased in primary-cultured smooth muscle cells during the log-phase growth. Our results suggest that autocrine production of PDGF-A chains from the smooth muscle cell may play a role in early vascular development and in Angiotensin II-induced smooth muscle cell proliferation.

Distribution of cardiac myosin isozymes in human conduction system. Immunohistochemical study using monoclonal antibodies.

To determine the presence and distribution of cardiac myosin isozymes in the human conduction system, we performed an immunohistochemical study using monoclonal antibodies CMA19 and HMC14, which are specific for myosin heavy chains of human atrial type (alpha-type) and ventricular type (beta-type), respectively. Serial frozen sections of human hearts were obtained from autopsy samples and examined by indirect immunofluorescence. Alpha-type was found in all myofibers of sinus node and atrio-ventricular node, and in 55.2 +/- 10.2% (mean +/- SD, n = 5) of the myofibers of ventricular conduction tissue, which consists of the bundle of His, bundle branches, and the Purkinje network. In contrast, beta-type was found in all myofibers of the atrio-ventricular node and ventricular conduction tissue, whereas almost all myofibers of the sinus node were unlabeled by HMC14. Although the number of ventricular myofibers labeled by CMA19 was small, the labeled myofibers were more numerous in the subepicardial region than in the subendocardial region. These findings show that the gene coding for alpha-type is expressed predominantly in specialized myocardium compared with the adjacent ordinary working myocardium.

Structure and Characterization of the 5′-Flanking Region of the Mouse Smooth Muscle Myosin Heavy Chain (SM1/2) Gene

We have previously shown that smooth muscle myosin heavy chain isoforms (SMs), including SM1, SM2, and SMemb, are differentially expressed during vascular development, and in vascular lesions, such as atherosclerosis. The SM1/2 gene is expressed exclusively in smooth muscle cells and generates SM1 and SM2 mRNAs by alternative splicing. Whereas SM1 is constitutively expressed from early development, SM2 appears only after birth. In this study, we have isolated and characterized the 5-flanking region of the mouse SM1/2 gene. Transient transfection assays using a series of promoter-luciferase chimeric constructs demonstrated that tandem elements of the CCTCCC sequence, located at -89 and -61 bp relative to the transcription start site, were essential for transcriptional activity of the SM1/2 gene in primary cultured rabbit aortic smooth muscle cells and smooth muscle cell lines derived from the rabbit aorta but not in non-smooth muscle cells. Gel mobility shift assays indicated that CCTCCC was a binding site for nuclear proteins prepared from smooth muscle cells. Double-stranded oligonucleotides containing either the CACC box or the Sp1 consensus sequence efficiently competed with the CCTCCC elements for binding the nuclear extracts. Site-specific mutations of CCTCCC elements resulted in a significant reduction of the promoter activity. Moreover, CCTCCC elements are evolutionary conserved between mouse and rabbit. In conclusion, the results of this study indicate an important role for the interaction of the CCTCCC sequence with Sp1 or related factors in activating transcription from the SM1/2 gene promoter.

Phenotypic Modulation of Smooth Muscle Cells during Progression of Human Atherosclerosis as Determined by Altered Expression of Myosin Heavy Chain Isoforms

We have previously demonstrated that rabbit smooth muscle contains at least three types of myosin heavy chain (MHC) isoforms; SM1 (204 kDa), SM2 (200 kDa), and SMemb (200 kDa).I4 Two smooth muscle specific MHC isoforms, SM1 and SM2, were first identified by Rovner et al. on porous SDS-polyacrylamide gel electrophoresis (SDS-PAGE).5 Eddinger and Murphy showed by peptide mapping that the structural difference between SM1 and SM2 could lie in light meromyosin.h SMl and SM2 are generated from a single gene by alternative RNA sp l i~ ing .~ .~ Using cDNA probes and isoform-specific antibodies, we have shown that the expression of SM1 and SM2 in rabbit aorta is developmentally regulated; SMl is constitutively expressed from fetal stage to adulthood, whereas SM2 appears in well-differentiated smooth muscle only after birth.3 We have further revealed the presence of a third type of MHC isoform in rabbit embryonic aorta.4 We referred to this novel MHC isoform as SMemb because it is present in greater abundance in embryonic aortas. This MHC appears to be identical with MHC-B recently characterized in nonmuscle cells.8-10 Kawamoto et al. described that nonmuscle cells express two different MHCs, MHC-A and MHC-B. Proliferation and phenotypic modulation of vascular smooth muscle cells are important phenomena occurring during development of ather~sclerosis.~-~ Our previous studies on smooth muscle MHC expression in experimental arterioand atherosclerosis have clearly shown the importance of smooth muscle MHC isoforms as molecular markers to identify abnormally proliferating smooth muscle cells during formation of vascular lesion^.^ Furthermore, we demonstrated a marked contrast in MHC expression between the neointimal and medial smooth muscle cells. The

Heterogeneity in smooth muscle cell population accumulating in the neointimas and the media of poststenotic dilatation of the rabbit carotid artery

Rabbit smooth muscles contain at least three types of myosin heavy chain (MHC) isoforms; SM1, SM2 and SMemb (NMHC-B), the expression of which is developmentally regulated. We have recently reported that smooth muscles with the embryonic phenotype accumulate in the neointimas produced by endothelial denudation or high-cholesterol feeding. In this study, we examined MHC isoform expression in the neointimas and the media of poststenotic dilatation of the rabbit carotid artery, and determined the phenotype of the smooth muscle cell in the dilated segment. We report here that neointimal cells in the dilated segment are smooth muscle cells with the embryonic phenotype as previously reported in our ballooning-injury study. The medial smooth muscles, however, are composed of heterogeneous population of smooth muscles which differ in stage of differentiation as determined by the MHC isoform expression. These results indicate that MHC isoforms are useful molecular markers to identify abnormally proliferating smooth muscles in diseased arteries and to understand the process of atherogenesis occurring following vascular injury.