IntroductionHyaluronan, or hyaluronic acid (HA) is a linear, highmolecular-weight (mega-Dalton) polymer comprised of repeating disaccharide units of (β1→3)D-glucuronate-(β1→4)N-acetyl-D-glucosamine. HA is synthesized by integral plasma membrane glycosyltransferases and is exported directly into the extracellular space (1, 2). Although HA is chemically homogeneous, there are three distinct mammalian HA synthases (designated Has1, Has2, and Has3), encoded by related but nonlinked genes (3-9). Each synthase has distinct catalytic properties, and the distribution and abundance of each varies during development of the mouse (6, 10). These observations suggest that the different Has enzymes play distinct roles.HA binds salt and water, expanding the extracellular space (11)(12)(13)(14). HA is especially prominent at sites where cell migration occurs, such as pathways of neural crest cell migration and in the developing cardiovascular system. In vivo, HA interacts with other extracellular matrix molecules, typically via an HA-binding domain called the link module (15). These interactions create a supramolecular architecture of the extracellular matrix, i.e., the composite matrix network of HA, link protein, and aggrecan that plays a critical role in load-bearing articular cartilage (16)(17)(18).In addition to its important physical properties, the overexpression of Has genes results in increased anchorage-independent growth and metastasis of transformed cells (19,20), suggesting a link between HA and transformation. HA is also implicated in receptor-mediated cell adhesion and intracellular signaling (21,22). Taken together, such observations suggest that HA plays a vital role in diverse cellular events, including cell migration, tissue remodeling, and metastasis. However, the near-ubiquitous distribution of HA in vivo, the biological activity of HA fragments released by degradative enzymes (23), and the inability to inhibit HA synthesis in vivo have hindered definitive analysis of the physiological roles of HA. Accordingly, we used a genetic approach to investigate the roles of HA in vivo and to identify the HA synthase that is critical during embryogenesis.Expression of Has2 appeared to correlate with expansion of cardiac cushion tissue and subsequent transformation of endocardial cells into mesenchyme. The tar- We identified hyaluronan synthase-2 (Has2) as a likely source of hyaluronan (HA) during embryonic development, and we used gene targeting to study its function in vivo. Has2 -/-embryos lack HA, exhibit severe cardiac and vascular abnormalities, and die during midgestation (E9.5-10). Heart explants from Has2 -/-embryos lack the characteristic transformation of cardiac endothelial cells into mesenchyme, an essential developmental event that depends on receptor-mediated intracellular signaling. This defect is reproduced by expression of a dominant-negative Ras in wild-type heart explants, and is reversed in Has2 -/-explants by gene rescue, by administering exogenous HA, or by expressing activated Ras. Conversely, ...
Vitamin A signals play critical roles during embryonic development. In particular, heart morphogenesis depends on vitamin A signals mediated by the retinoid X receptor ␣ (RXR␣), as the systemic mutation of this receptor results in thinning of the myocardium and embryonic lethality. However, the molecular and cellular mechanisms controlled by RXR␣ signaling in this process are unclear, because a myocardium-restricted RXR␣ mutation does not perturb heart morphogenesis. Here, we analyze a series of tissuerestricted mutations of the RXR␣ gene in the cardiac neural crest, endothelial, and epicardial lineages, and we show that RXR␣ signaling in the epicardium is required for proper cardiac morphogenesis. Moreover, we detect an additional phenotype of defective coronary arteriogenesis associated with RXR␣ deficiency and identify a retinoid-dependent Wnt signaling pathway that cooperates in epicardial epithelial-to-mesenchymal transformation.coronary vessels ͉ epicardium ͉ retinoids ͉ wnt ͉ FGF
Although cytoskeletal mutations are known causes of genetically based forms of dilated cardiomyopathy, the pathways that link these defects with cardiomyopathy are unclear. Here we report that the alpha-actinin-associated LIM protein (ALP; Alp in mice) has an essential role in the embryonic development of the right ventricular (RV) chamber during its exposure to high biomechanical workloads in utero. Disruption of the gene encoding Alp (Alp) is associated with RV chamber dilation and dysfunction, directly implicating alpha-actinin-associated proteins in the onset of cardiomyopathy. In vitro assays showed that Alp directly enhances the capacity of alpha-actinin to cross-link actin filaments, indicating that the loss of Alp function contributes to destabilization of actin anchorage sites in cardiac muscle. Alp also colocalizes at the intercalated disc with alpha-actinin and gamma-catenin, the latter being a known disease gene for human RV dysplasia. Taken together, these studies point to a novel developmental pathway for RV dilated cardiomyopathy via instability of alpha-actinin complexes.
We have isolated murine embryonic atrial and ventricular cells derived from timed-pregnant females at different periods and used patch-clamp procedures to investigate age- and chamber-specific expression of ionic channels in the developing fetal mouse. Our data indicate that L-type Ca2+ channels play a dominant role in excitation during early murine cardiac embryogenesis and that Na+ channel expression increases dramatically just before birth. K+ channel expression is particularly sensitive to changes during development. Neither atrial nor ventricular cells express a slowly activating component of delayed rectification (IKs) until just before birth, and inwardly rectifying channel activity, associated with determination of cellular resting potential, is not markedly apparent until late stages of embryogenesis. Instead, we find robust expression of the ATP-regulated K+ channel at early and late states of embryonic development, which may indicate a novel functional role for this channel during morphogenesis of the heart. These results have important implications for the physiology and development of the murine cardiac conduction system and will also serve as a baseline for future studies designed to investigate developmental changes of ion channel expression in the myocardium of both wild-type and genetically modified mice.
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