Measurements of the wall shear stress distribution in the outflow tract of an embryonic chicken heart.

In order to study the role of blood-tissue interaction in the developing chicken embryo heart, detailed information about the haemodynamic forces is needed. In this study, we present the first in vivo measurements of the three-dimensional distribution of wall shear stress (WSS) in the outflow tract (OFT) of an embryonic chicken heart. The data are obtained in a two-step process: first, the three-dimensional flow fields are measured during the cardiac cycle using scanning microscopic particle image velocimetry; second, the location of the wall and the WSS are determined by post-processing flow velocity data (finding velocity gradients at locations where the flow approaches zero). The results are a three-dimensional reconstruction of the geometry, with a spatial resolution of 15-20 microm, and provides detailed information about the WSS in the OFT. The most significant error is the location of the wall, which results in an estimate of the uncertainty in the WSS values of 20 per cent.

Smoothelin expression during chicken embryogenesis: detection of an embryonic isoform.

Two isoforms of a novel smooth muscle cell (SMC) -specific cytoskeletal protein, smoothelin, have been described. In the adult chick, the 55-kDa smoothelin-A is expressed in visceral SMC, whereas the 120-kDa smoothelin-B is the major product in vascular SMC. Chicken was chosen to study smoothelin expression during embryogenesis and neonatally. Smoothelin-B was found in vascular SMC from stage 20 onward. In visceral SMC, smoothelin-B was present from stage 29 until hatching. Perinatally, a strong up-regulation of smoothelin synthesis was observed in visceral tissues, coinciding with a switch to the A-isoform. Transient smoothelin synthesis was observed in the somites and the developing heart. Western blotting revealed in these tissues a 62-kDa smoothelin isoform, designated smoothelin-C. Expression of the smoothelin isoforms seems to be strictly controlled with respect to cell type and developmental stage and may be related to the mode of contraction of the different cells.

Frizzled 2 is transiently expressed in neural crest-containing areas during development of the heart and great arteries in the mouse.

Frizzled 2 acts as a 7-transmembrane receptor in the Wnt-Dishevelled signal transduction cascade. Among others, this cascade has been associated with neural crest cell proliferation and early migration during development in mammals. The genes for some components of this cascade are located in chromosomal regions that are deleted in human syndromes associated with neural crest cell defects, like DiGeorge and Velo-Cardio-Facial Syndrome. These syndromes are often accompanied by abnormalities in cardiac morphology. Furthermore, we have reported in previous studies the upregulation of the tissue polarity gene frizzled 2 in myofibroblasts during their migration into the necrotic area after myocardial infarction in the adult heart. It is known that genes that are upregulated during cardiac remodeling due to pathology often play a role during development. To investigate whether frizzled 2 can be associated with the process of cardiac morphogenesis we studied its expression in the thoracic arterial system and heart of mouse embryo's of 10, 12, 14, 16 and 18 days after conception by means of in situ hybridization. At day 10 after conception signal could be found in the pharyngeal arches and arch arteries. The outflow tract, the ascending aorta and the pulmonary trunk were positive for frizzled 2 from day 12 on. This expression decreased with time and at day 18 only some signal could be detected in the aorta and pulmonary trunk. In contrast, in coronary and pulmonary arteries no expression was observed at any time point. Minor myocardial expression was observed in the ventricular septum at days 12 and 14. Atrial expression, although considerably lower than ventricular expression, could be detected somewhat later at days 14 and 16. Our results indicate that there is transient expression of frizzled 2 in areas that are invested by neural crest cells. This expression is downregulated upon neural crest cell differentiation. The frizzled 2 expression supports a role for the Wnt-frizzled pathway in neural crest-related disorders.

Expression of the beta 4 integrin subunit in the mouse heart during embryonic development: retinoic acid advances beta 4 expression.

Using immunohistochemical techniques as well as in situ hybridization we were able to elicit the expression pattern of the beta 4 integrin subunit in the murine heart during development. We show that beta 4 is not expressed in the heart before E13 and is afterwards restricted to the endocardium of the atrioventricular canal, the outflow tract, and the venous valves in the right atrium. As these are all sites of high shear stress in the heart, we propose a role for alpha 6 beta 4 in the tight adhesion of the endocardial cells to their basement membranes in these segments. Moreover, mouse embryos were treated with all-trans retinoic acid, which was previously shown to induce congenital malformations, among which malformations of the heart. We show an advanced expression without ectopic localization of cardiac beta 4 after the administration of retinoic acid. This advanced appearance of beta 4 was also shown in extracardiac tissue like migrating neural crest cells. Several hypotheses on the mechanism of beta 4 up-regulation and a possible role for alpha 6 beta 4 in the development of heart malformations after the administration of retinoic acid are discussed.

Differential expression of alpha-6 and other subunits of laminin binding integrins during development of the murine heart.

The development of the heart from a single heart tube to a four chambered organ with two separated unidirectional flows is a highly complex process. Events like looping, septation, tissue remodelling, and development of valves take place in a time period in which the heart already exerts its pump function. Adhesion of cells to each other and to their extracellular matrix as well as the capability to migrate in such a dynamic environment are extremely important. Integrins and extracellular matrix components have already been implicated in this process. In this report, we describe in detail the differential expression of the alpha-6 integrin subunit during late murine heart development, e.g., in the process from looping to the end of septation. We compare mRNA and protein expression patterns with those of beta-1 and other subunits of laminin-binding integrins, alpha-3 and alpha-7. We show a constant and high expression of alpha-6 in the atrial myocardium and a decrease in expression in the ventricular trabecular myocardium. The compact myocardial wall and the ventricular septum do not express alpha-6, except for the myocardium of the distal outflow tract at early stages. Moreover, we describe expression of this integrin subunit in the endocardial cushions that contribute to the development of the atrioventricular and semilunar valves. We propose a role for the alpha-6-beta-1 laminin receptor in the adhesion of cells to their extracellular matrix at sites of high stress due to cardiac contraction or blood flow induced shear stress. Moreover, site specific endothelial expression within the heart and surrounding extracardiac tissue is discussed. This study suggests a distinct role for alpha-6-beta-1 in the heart and provides insight concerning probably important roles of integrins and their extracellular matrix ligands during embryonic development.

Modified indirect immunodetection allows study of murine tissue with mouse monoclonal antibodies.

The indirect immunodetection method is powerful in detecting antigens in situ, but to date mouse monoclonal antibodies (MAbs) could not be used in immunohistochemical studies of murine tissues without severe background staining. We report here a modification of this method in which mouse MAbs are used to detect murine antigens in cryosections. Before application to the section, mouse MAbs and conjugated anti-mouse antiserum were allowed to complex in vitro. After blocking of the unbound secondary antiserum with normal mouse serum, standard immunohistochemistry was performed. Fifty percent of a randomly chosen panel of over 40 mouse MAbs recognized their antigens in our model system. Adaptation of, for example, the fixation protocol can probably even increase this number. An MAb to the intermediate filament protein desmin, staining both smooth and striated muscle, was used to demonstrate this technique in cryosections of 15-day-old mouse embryos. In contrast to standard immunohistochemistry with the same antibodies under the same conditions, background staining was completely absent with this technique. With this modification to the well-established indirect detection method, the usefulness of mouse MAbs is significantly increased.

Variants of the alpha 6 beta 1 laminin receptor in early murine development: distribution, molecular cloning and chromosomal localization of the mouse integrin alpha 6 subunit.

Laminin (A:B1:B2) is a major component of the first basement membrane to appear in the developing mouse embryo. Its effects on morphogenesis and differentiation are mediated by interaction with cell surface receptors that are members of the integrin family. We have studied the expression of the alpha 6 subunit of murine alpha 6 beta 1 and its ligand, laminin, in preimplantation mouse embryos, embryo outgrowths and in embryonic stem (ES) cells and embryonal carcinoma (EC) cells. The alpha 6 subunit is present in the oocyte and throughout preimplantation development. Laminin A chain appears later than alpha 6 and has a more restricted distribution until the late blastocyst stage. alpha 6 beta 1 is strongly expressed in ES and EC cells; the levels of mRNA expression are not altered by differentiation. Molecular cloning of cDNA for the murine integrin alpha 6 subunit from a mammary gland lambda gt11 library showed, as in man, an open reading frame encoding two variants of alpha 6, alpha 6A and alpha 6B. The identity of the alpha 6 amino acid sequence to that in man and chicken is 93% and 73%, respectively. The gene for murine alpha 6 was mapped to chromosome 2. While undifferentiated ES and EC cells express only alpha 6B, alpha 6A is co-expressed in ES cells after differentiation is induced by retinoic acid. alpha 6B is also the only variant expressed in blastocyst stage embryos, but when blastocysts have grown out in culture both alpha 6A and alpha 6B are expressed reflecting the results in the cell lines. We suggest that the deposition of laminin in the embryo is a receptor-mediated process and that the shift in the expression of the variants, as the inner cell mass forms its first differentiated progeny, reflects a change in functional properties.