Mouse myodulin, a new potential angiogenic factor, functionally expressed in yeast

Myodulin is a new integral membrane protein down-regulated in skeletal muscle atrophy. A first characterization suggested that myodulin could be a skeletal muscle angiogenic factor operating through direct cell-to-cell interactions. Here, we show that mouse myodulin can be expressed at the plasma membrane of Saccharomyces cerevisiae and purified. Co-culture experiments of myoblasts and cardiac vascular endothelial cells reveal that myodulin, either presented in yeast membranes or in liposomes after purification, increases the invasive potential of endothelial cells with a similar efficiency as when over-expressed in skeletal muscle cells. Functional essays using myodulin expressed in yeast bring new information about the myodulin functional mechanism, suggesting that one or several muscle cell components could be necessary for myodulin to increase the invasive potential of endothelial cells. The yield of purified myodulin should allow structure-function relationships studies for a better understanding of myodulin functional mechanisms.     

Cytochrome P450 epoxygenases and vascular tone: novel role for HMG-CoA reductase inhibitors in the regulation of CYP 2C expression

Over the last 10 years it has become increasingly clear that cytochrome P450 (CYP) enzymes expressed within endothelial and vascular smooth muscle cells play a crucial role in the modulation of vascular homeostasis. There is strong evidence suggesting that the activation of a CYP 2C epoxygenase in endothelial cells is an essential step in nitric oxide (NO)- and prostacyclin (PGI(2))-independent vasodilatation of several vascular beds, particularly in the heart and kidney. Moreover, CYP epoxygenase products as well as CYP-derived reactive oxygen species are intracellular signal transduction molecules involved in several signaling cascades affecting numerous cellular processes, including vascular cell proliferation and angiogenesis. Various pharmacological compounds enhance vascular CYP 2C expression. One group of substances which highlight the possible effects of CYP induction in endothelial cells on vascular function are the HMG-CoA reductase inhibitors (statins). Cerivastatin and fluvastatin increase CYP 2C mRNA and protein in native and cultured endothelial cells, and enhance the bradykinin-induced NO/PGI(2)-independent relaxation of arterial segments as well as the generation of reactive oxygen species. However, statins also increase the expression of the endothelial NO synthase by approximately twofold. As a consequence, the probability that NO and reactive oxygen species react to generate peroxynitrite is increased and the treatment of vascular segments with statins resulted in enhanced protein tyrosine nitration. These data highlight the role played by CYP 2C in vascular homeostasis and its potential regulation by cardiovascular drugs.     

Chondromodulin-I maintains cardiac valvular function by preventing angiogenesis

The avascularity of cardiac valves is abrogated in several valvular heart diseases (VHDs). This study investigated the molecular mechanisms underlying valvular avascularity and its correlation with VHD. Chondromodulin-I, an antiangiogenic factor isolated from cartilage, is abundantly expressed in cardiac valves. Gene targeting of chondromodulin-I resulted in enhanced Vegf-A expression, angiogenesis, lipid deposition and calcification in the cardiac valves of aged mice. Echocardiography showed aortic valve thickening, calcification and turbulent flow, indicative of early changes in aortic stenosis. Conditioned medium obtained from cultured valvular interstitial cells strongly inhibited tube formation and mobilization of endothelial cells and induced their apoptosis; these effects were partially inhibited by chondromodulin-I small interfering RNA. In human VHD, including cases associated with infective endocarditis, rheumatic heart disease and atherosclerosis, VEGF-A expression, neovascularization and calcification were observed in areas of chondromodulin-I downregulation. These findings provide evidence that chondromodulin-I has a pivotal role in maintaining valvular normal function by preventing angiogenesis that may lead to VHD.     

Smooth muscle progenitor cells from peripheral blood promote the neovascularization of endothelial colony-forming cells

Proangiogenic cell therapy using autologous progenitors is a promising strategy for treating ischemic disease. Considering that neovascularization is a harmonized cellular process that involves both endothelial cells and vascular smooth muscle cells, peripheral blood-originating endothelial colony-forming cells (ECFCs) and smooth muscle progenitor cells (SMPCs), which are similar to mature endothelial cells and vascular smooth muscle cells, could be attractive cellular candidates to achieve therapeutic neovascularization. We successfully induced populations of two different vascular progenitor cells (ECFCs and SMPCs) from adult peripheral blood. Both progenitor cell types expressed endothelial-specific or smooth muscle-specific genes and markers, respectively. In a protein array focused on angiogenic cytokines, SMPCs demonstrated significantly higher expression of bFGF, EGF, TIMP2, ENA78, and TIMP1 compared to ECFCs. Conditioned medium from SMPCs and co-culture with SMPCs revealed that SMPCs promoted cell proliferation, migration, and the in vitro angiogenesis of ECFCs. Finally, co-transplantation of ECFCs and SMPCs induced robust in vivo neovascularization, as well as improved blood perfusion and tissue repair, in a mouse ischemic hindlimb model. Taken together, we have provided the first evidence of a cell therapy strategy for therapeutic neovascularization using two different types of autologous progenitors (ECFCs and SMPCs) derived from adult peripheral blood.     

Induction of Src-suppressed C kinase substrate (SSeCKS) in vascular endothelial cells by bacterial lipopolysaccharide.

We isolated cDNA of the mouse homologue of the src-suppressed C kinase substrate (SSeCKS) and analyzed the effects of lipopolysaccharide (LPS) injection on the tissue expression pattern of this protein. Northern blotting analysis showed that SSeCKS mRNA was expressed abundantly in the testis but at undetectable levels in other tissues of untreated control mice. Intraperitoneal administration of LPS strongly induced SSeCKS mRNA expression in the lung, heart, liver, spleen, kidney, lymph node, adrenal gland, and pituitary gland, as well as in the brain. In lung and spleen, the SSeCKS mRNA levels increased almost 10-fold at 1 hr after LPS injection and persisted at high levels until 4 hr. Both in situ hybridization and immunohistochemical studies revealed that LPS administration conspicuously elevated expression of SSeCKS mRNA and protein in vascular endothelial cells of several organs. Ectopic expression of SSeCKS caused loss of cytoplasmic F-actin fibers in the mouse endothelial cell line LEII. These results indicate that SSeCKS is one of the major LPS-responsive proteins and may participate in alteration of cytoskeletal architecture in endothelial cells during inflammation.     

Molecular cloning of human chondromodulin-I, a cartilage-derived growth modulating factor, and its expression in Chinese hamster ovary cells.

Bovine chondromodulin-I (ChM-I) purified from fetal cartilage stimulated the matrix synthesis of chondrocytes, and inhibited the growth of vascular endothelial cells in vitro. The human counterpart of this bovine growth regulating factor has not been identified. We report here the cloning of human ChM-I precursor cDNA and its functional expression in Chinese hamster ovary (CHO) cells. We first identified a genomic DNA fragment which encoded the N-terminus of the ChM-I precursor, and then isolated human ChM-I cDNA from chondrosarcoma tissue by PCR. The deduced amino acid sequence revealed that mature human ChM-I consists of 120 amino acids. In total, 16 amino acid residues were substituted in the human sequence, compared to the bovine counterpart. Almost of all the substitutions were found in the N-terminal hydrophilic domain. In the C-terminal hydrophobic domain (from Phe42 to Val120), the amino acid sequence was identical except for Tyr90, indicating a functional significance of the domain. Northern blotting and in situ hybridization indicated a specific expression of ChM-I mRNA in cartilage. We also successfully determined the cartilage-specific localization of ChM-I protein, using a specific antibody against recombinant human ChM-I. Multiple transfection of the precursor cDNA into CHO cells enabled us to isolate the mature form of human ChM-I from the culture supernatant. Purified recombinant human ChM-I stimulated proteoglycan synthesis in cultured chondrocytes. In contrast, it inhibited the tube morphogenesis of cultured vascular endothelial cells in vitro and angiogenesis in chick chorioallantoic membrane in vivo.     

Loss of FilaminC (FLNc) results in severe defects in myogenesis and myotube structure

FilaminC (FLNc) is the muscle-specific member of a family of actin binding proteins. Although it interacts with many proteins involved in muscular dystrophies, its unique role in muscle is poorly understood. To address this, two models were developed. First, FLNc expression was stably reduced in C2C12 myoblasts by RNA interference. While these cells start differentiation normally, they display defects in differentiation and fusion ability and ultimately form multinucleated "myoballs" rather than maintain elongated morphology. Second, a mouse model carrying a deletion of last 8 exons of Flnc was developed. FLNc-deficient mice die shortly after birth, due to respiratory failure, and have severely reduced birth weights, with fewer muscle fibers and primary myotubes, indicating defects in primary myogenesis. They exhibit variation in fiber size, fibers with centrally located nuclei, and some rounded fibers resembling the in vitro phenotype. The similarity of the phenotype of FLNc-deficient mice to the filamin-interacting TRIO null mice was further confirmed by comparing FLNc-deficient C2C12 cells to TRIO-deficient cells. These data provide the first evidence that FLNc has a crucial role in muscle development and maintenance of muscle structural integrity and suggest the presence of a TRIO-FLNc-dependent pathway in maintaining proper myotube structure.     

Shear stress induces endothelial transdifferentiation from mouse smooth muscle cells

Smooth muscle cells (SMCs) under shear stress may alter their gene expression patterns to adapt to a new hemodynamic environment. Their plasticity may play an important role in vascular development, healing, and remodeling as well as vascular lesion formation under abnormal environmental conditions. A mouse vascular SMC line (P53LMACO1) cultured under shear stress significantly increased the mRNA levels of endothelial cell markers including Platelet-endothelial cell adhesion molecule-1 (PECAM-1), von Willebrand factor (vWF), and VE-cadherin, while significantly decreasing the mRNA levels of SMC markers including alpha-smooth muscle actin (alpha-SMA), calponin-1, smooth muscle myosin heavy chain (SMMHC), and transgelin as compared to static control cells. Protein levels of PECAM-1 and vWF were significantly increased, while protein levels of alpha-SMA were substantially decreased in the shear stress-cultured cells. In addition, shear stress-cultured cells showed an enhanced capability to form capillary-like structures on Matrigel. Thus, shear stress may promote endothelial cell transdifferentiation from SMCs.     

Noxa1 is a central component of the smooth muscle NADPH oxidase in mice

NADPH oxidase is the most important source of oxygen-derived radicals (ROS) in the vascular wall. In vascular smooth muscle cells (VSMC), NADPH oxidase is characterized by the expression of the membrane subunit Nox1, which is activated by cytoplasmic proteins binding to its activation domain. We set out to identify the cytoplasmic protein involved in NADPH oxidase activation in mouse VSMC. Western blot analysis revealed that human endothelial cells and leukocytes but not VSMC from the aorta of the rat and the mouse express the classic NADPH oxidase activator p67phox. In mouse VSMC, however, the p67phox homologue Noxa1 was detected. Using antibodies generated against mouse Noxa1, the protein was observed in the cytosolic fraction of mouse VSMC with a molecular weight of about 51 kDa. Immunohistochemistry revealed that Noxa1 is expressed in the smooth muscle layer but not in endothelium or the adventitia of the mouse carotid artery. Fluorescent fusion proteins of Noxa1 were observed to be expressed in the cytoplasm of VSMC and coexpression of the NADPH oxidase organizer Noxo1 targeted the complex to membrane. An antisense plasmid of Noxa1 attenuated the endogenous Noxa1 protein expression in VSMC. This plasmid attenuated the ROS formation in mouse VSMC as detected using L012 chemiluminescence and prevented the agonist-induced ROS production in response to basic fibroblast growth factor and epidermal growth factor. In conclusion, these data indicate that Noxa1 replaces p67phox in VSMC and plays a central role in the activation of the NADPH oxidase in the vascular wall.     

Molecular cloning of a novel immunoglobulin superfamily gene preferentially expressed by brain and testis

We have cloned and characterized a novel gene from both human and mouse that encodes a new member of the immunoglobulin superfamily. The gene is preferentially expressed in both brain and testis, and hence, termed BT-IgSF (brain- and testis-specific immunoglobulin superfamily). The predicted protein consists of V-type and C2-type immunoglobulin domains as well as a hydrophobic signal sequence, a single transmembrane region, and a cytoplasmic domain. Human BT-IgSF protein (431 amino acids) is 88% identical to the mouse protein (428 amino acids) and both show significant homology to coxsackie and adenovirus receptor (CAR) and endothelial cell-selective adhesion molecule (ESAM). We examined the expression of BT-IgSF with various cultured cells and found that the gene was expressed in both neurons and glial cells in vitro. Furthermore, the expression was preferentially detected in pyramidal cell layers of the dentate gyrus and hippocampus and in commissure fibers of the corpus callosum, in brain tissue sections examined. These findings suggest that BT-IgSF plays a role in the development or function of the central nervous system.     

Cloning of a gap junctional protein from vascular smooth muscle and expression in two-cell mouse embryos.

Gap junctional proteins (connexins) form aqueous channels that enable direct cell-cell transfer of ions and small molecules. The distribution and conductance of gap junction channels in cardiac muscle determine the pattern and synchrony of cellular activation. However, the capacity for smooth muscle to restrict contractile events temporally and spatially suggests that cell-cell coupling or its regulation may be decidedly different in this tissue. We isolated a cDNA from vascular smooth muscle which encodes a connexin (Mr 43,187) structurally homologous to cardiac connexin43. Vascular smooth muscle connexin43 mRNA was expressed prominently in smooth muscle tissues, cultured vascular myocytes, and arterial endothelial cells. A model for functional expression of connexins was developed in two-cell B6D2 mouse embryos. Microinjection of in vitro transcribed vascular smooth muscle connexin43 mRNA was shown to be sufficient to induce intercellular coupling in previously uncoupled blastomeres. Through the construction of two deletion mutants of connexin43, we also show that the formation of cell-to-cell connections does not depend upon a predicted cytoplasmic region within 98 residues of the carboxyl terminus. Finally, the identification of connexin43 in smooth muscle and endothelial cells provides supporting evidence for the existence of heterocellular coupling between cells of the vascular intima.     

CRBP-III:lacZ expression pattern reveals a novel heterogeneity of vascular endothelial cells

Vascular endothelial cells are structurally and functionally heterogeneous. However, the molecular basis of this heterogeneity remains poorly defined. We used subtractive and differential screening to identify genes that exhibit heterogeneous expression patterns among vascular endothelial cells. One such gene is cellular retinol binding protein III (CRBP-III/Rbp7). Analysis of the lacZ knockin line for this gene (CRBP-III:lacZ) revealed a novel organ-specific vascular endothelial expression pattern. LacZ was expressed in vascular endothelial cells in heart, skeletal muscle, adipose tissues, thymus, and salivary gland. However, it was not detected in other tissues such as brain, liver, and lung. Furthermore, the expression within each organ was primarily restricted to small capillary endothelial cells, but could not be detected in larger vessels. This organ-specific vascular endothelial expression of CRPB:lacZ is relatively resistant to the changes of organ microenvironment. However, the level of expression can be modified by vitamin A deficiency. Therefore, our results provide novel molecular evidence for the heterogeneity of vascular endothelial cells.     

Rho GTPase signaling modulates cell shape and contractile phenotype in an isoactin-specific manner

Rho family small GTPases (Rho, Rac, and Cdc42) play an important role in cell motility, adhesion, and cell division by signaling reorganization of the actin cytoskeleton. Here, we report an isoactin-specific, Rho GTPase-dependent signaling cascade in cells simultaneously expressing smooth muscle and nonmuscle actin isoforms. We transfected primary cultures of microvascular pericytes, cells related to vascular smooth muscle cells, with various Rho-related and Rho-specific expression plasmids. Overexpression of dominant positive Rho resulted in the formation of nonmuscle actin-containing stress fibers. At the same time, -vascular smooth muscle actin (VSMactin) containing stress fibers were disassembled, resulting in a dramatic reduction in cell size. Rho activation also yielded a disassembly of smooth muscle myosin and nonmuscle myosin from stress fibers. Overexpression of wild-type Rho had similar but less dramatic effects. In contrast, dominant negative Rho and C3 exotransferase or dominant positive Rac and Cdc42 expression failed to alter the actin cytoskeleton in an isoform-specific manner. The loss of smooth muscle contractile protein isoforms in pericyte stress fibers, together with a concomitant decrease in cell size, suggests that Rho activation influences "contractile" phenotype in an isoactin-specific manner. This, in turn, should yield significant alteration in microvascular remodeling during developmental and pathologic angiogenesis. vascular smooth muscle actin; Rho GTPase; pericyte; myosin; cytoskeleton