Beta 1 integrin activation mediates adhesive differences between trisomy 21 and non-trisomic fibroblasts on type VI collagen

Trisomy 21 (Down syndrome) is a common genetic condition with a high incidence of congenital heart defects (CHD), particularly those involving abnormal development of the embryonic atrioventricular (AV) canal. Type VI collagen (Col VI) is expressed in the developing AV canal extracellular matrix, and has been associated with trisomy 21 AV canal defects in human genetic studies. Although the molecular mechanisms linking Col VI and trisomy 21 AV canal defects are not well understood, a computer model predicts increased cell adhesiveness is responsible for these CHD. We compared integrin-mediated cell adhesive properties for skin fibroblasts isolated from trisomy 21 and non-trisomic individuals on Col VI, fibronectin (FN) and type I collagen (Col I). Cell lines demonstrate similar adhesion profiles to FN and Col I, but all trisomy 21 cells display increased adhesive capacity for Col VI compared to non-trisomic fibroblasts. Cell adhesion to type VI collagen was shown to be GRGDS independent, but beta(1) integrin family dependent. Function-blocking antibodies identified alpha(3)beta(1) as the predominant integrin mediating trisomy 21 and non-trisomic skin fibroblast adhesion on Col VI. Trisomy 21 and non-trisomic fibroblasts display similar expression levels for each of the integrin receptors examined. A beta(1) integrin-activating antibody augments non-trisomic cell adhesion on Col VI, but has no effect upon trisomy 21 fibroblasts. These results demonstrate that beta(1) integrin family members mediate trisomy 21 and non-trisomic skin fibroblast adhesion for Col VI. Altered activation state of the beta(1) integrin is a mechanism responsible for increased trisomy 21 cell adhesion on Col VI.     

Collagen XVIII/endostatin is associated with the epithelial-mesenchymal transformation in the atrioventricular valves during cardiac development.

Type XVIII collagen is a multidomain protein that contains cleavable C-terminal NC1 and endostatin fragments, which have been shown to either induce or inhibit cell migration. Endostatin is being intensely studied because of its anti-angiogenic activity. Three variants of type XVIII collagen have been reported to be distributed in epithelial and endothelial basement membranes in a tissue-specific manner. The single gene encoding collagen XVIII is on chromosome 21 within the region associated with the congenital heart disease phenotype observed in Down's syndrome. In this study, we investigated the expression pattern of collagen XVIII in embryonic mouse hearts during formation of the atrioventricular (AV) valves. We found that collagen XVIII is localized not only in various basement membranes but is also highly expressed throughout the connective tissue core of the endocardial cushions and forming AV valve leaflets. It was closely associated with the epithelial-mesenchymal transformation of endothelial cells into mesenchymal cushion tissue cells and was localized around these cells as they migrated into the cardiac jelly to form the initial connective tissue elements of the valve leaflets. However, after embryonic day 17.5 collagen XVIII expression decreased rapidly in the connective tissue and thereafter remained detectable only in the basement membranes of the endothelial layer covering the leaflets. The staining pattern observed within the AV endocardial cushions suggests that collagen XVIII may have a role in cardiac valve morphogenesis. These results may help us to better understand normal heart development and the aberrant mechanisms that cause cardiac malformations in Down's syndrome.     

Beta 1 integrin activation mediates adhesive differences between trisomy 21 and non‐trisomic fibroblasts on type VI collagen

Trisomy 21 (Down syndrome) is a common genetic condition with a high incidence of congenital heart defects (CHD), particularly those involving abnormal development of the embryonic atrioventricular (AV) canal. Type VI collagen (Col VI) is expressed in the developing AV canal extracellular matrix, and has been associated with trisomy 21 AV canal defects in human genetic studies. Although the molecular mechanisms linking Col VI and trisomy 21 AV canal defects are not well understood, a computer model predicts increased cell adhesiveness is responsible for these CHD. We compared integrin‐mediated cell adhesive properties for skin fibroblasts isolated from trisomy 21 and non‐trisomic individuals on Col VI, fibronectin (FN) and type I collagen (Col I). Cell lines demonstrate similar adhesion profiles to FN and Col I, but all trisomy 21 cells display increased adhesive capacity for Col VI compared to non‐trisomic fibroblasts. Cell adhesion to type VI collagen was shown to be GRGDS independent, but β₁ integrin family dependent. Function‐blocking antibodies identified α₃β₁ as the predominant integrin mediating trisomy 21 and non‐trisomic skin fibroblast adhesion on Col VI. Trisomy 21 and non‐trisomic fibroblasts display similar expression levels for each of the integrin receptors examined. A β₁ integrin‐activating antibody augments non‐trisomic cell adhesion on Col VI, but has no effect upon trisomy 21 fibroblasts. These results demonstrate that β₁ integrin family members mediate trisomy 21 and non‐trisomic skin fibroblast adhesion for Col VI. Altered activation state of the β₁ integrin is a mechanism responsible for increased trisomy 21 cell adhesion on Col VI. © 2002 Wiley‐Liss, Inc.     

BMP4 is required in the anterior heart field and its derivatives for endocardial cushion remodeling, outflow tract septation, and semilunar valve development

The endocardial cushions play a critical role in septation of the four-chambered mammalian heart and in the formation of the valve leaflets that control blood flow through the heart. Within the outflow tract (OFT), both cardiac neural crest and endocardial-derived mesenchymal cells contribute to the endocardial cushions. Bone morphogenetic protein 4 (BMP4) is required for endocardial cushion development and for normal septation of the OFT. In the present study, we show that anterior heart field (AHF)-derived myocardium is an essential source of BMP4 required for normal endocardial cushion expansion and remodeling. Loss of BMP4 from the AHF in mice results in an insufficient number of cells in the developing OFT endocardial cushions, defective cushion remodeling, ventricular septal defects, persistent truncus arteriosus, and abnormal semilunar valve formation.     

Cell autonomous requirement of endocardial Smad4 during atrioventricular cushion development in mouse embryos

Atrioventricular (AV) cushions are the precursors of AV septum and valves. In this study, we examined roles of Smad4 during AV cushion development using a conditional gene inactivation approach. We found that endothelial/endocardial inactivation of Smad4 led to the hypocellular AV cushion defect and that both reduced cell proliferation and increased apoptosis contributed to the defect. Expression of multiple genes critical for cushion development was down‐regulated in mutant embryos. In collagen gel assays, the number of mesenchymal cells formed is significantly reduced in mutant AV explants compared to that in control explants, suggesting that the reduction of cushion mesenchyme formation in mutants is unlikely secondary to their gross vasculature abnormalities. Using a previously developed immortal endocardial cell line, we showed that Smad4 is required for BMP signaling‐ stimulated upregulation of Tbx20 and Gata4. Therefore, our data collectively support the cell‐autonomous requirement of endocardial Smad4 in regulating AV cushion development. Developmental Dynamics, 2011. © 2010 Wiley‐Liss, Inc.     

Morphological classification of nuchal skin in human fetuses with trisomy 21, 18, and 13 at 12—18 weeks and in a trisomy 16 mouse

An increase in the nuchal translucency that can be detected at 10–14 weeks of gestation by ultrasound forms the basis for a screening test for chromosomal abnormality. Several mechanisms leading to this increase in skin thickness have been proposed, including changes of the extracellular matrix, cardiac defects and abnormalities of the large vessels. This study examines the composition of the extracellular matrix of the skin in gestational age-matched fetuses with trisomy 21, 18 and 13 from 12–18 weeks. Immunohistochemistry was applied with monoclonal and polyclonal antibodies against collagen type I, III, IV, V and VI and against laminin and fibronectin. Collagen type VI gene expression was further studied by in situ hybridization to detect differences in expression patterns of COL6A1, COL6A3 and COL1A1 between normal fetuses and those with trisomy 21. The ultrastructure of tissue samples was studied by transmission electron microscopy (TEM) and additionally by immunogold TEM. Further, we examined the morphology of the skin in an animal model for Down’s syndrome, the murine trisomy 16, by light and TEM. The dermis of trisomy 21 fetuses was richer in collagen type VI than that of normal fetuses and other trisomies, and COL6A1, located on chromosome 21, was expressed in a wider area than COL6A3, which is located on chromosome 2. Collagen type I was less abundant in the skin of trisomy 18 fetuses, while the skin of all three trisomies contained a dense network of collagen type III and V in comparison with normal fetuses. Collagen type IV, of which two genes are located on chromosome 13, was expressed in the basement membranes of the skin in all fetuses and additionally in the dermal fibroblasts only of trisomy 13 fetuses. Likewise, laminin was present in all basement membranes of normal and trisomic fetuses as well as in dermal fibroblasts of fetuses with trisomy 18. LAMA1 and LAMA3 genes are located on chromosome 18. Dermal cysts were found in the skin of trisomy 18 and 13, but not in trisomy 21 and normal fetuses. Ultrastructural findings showed that an extracellular precipitate containing glycosaminoglycans was regularly present in the skin of trisomy 21 fetuses and murine trisomy 16 embryos. In conclusion, this study suggests that the skin edema in fetal trisomies is characterized by specific alterations of the extracellular matrix that may be attributed to gene dosage effects as a result of a genetic imbalance due to the condition of fetal trisomy.     

Endocytic activity in embryonic cardiac cushion mesenchyme in vivo and in collagen gel lattices

Mesenchymal cells, termed cushion tissue (CT) cells, are the principal cellular elements in atrioventricular (AV) endocardial cushions, the latter constituting AV septal and valvular primordia in the embryonic heart. Atrioventricular canals of 2 1/2 day chick embryo hearts were explanted onto collagen gel lattices, wherein cushion endothelial cells acquired the characteristics of CT cells and invaded the gel. The endocytic activity of in situ CT cells was compared to that of gel-cultured CT cells by exposing appropriate preparations to horseradish peroxidase (HRP), cationized ferritin (CF) or to lysozyme. Stimulation by these exogenous proteins resulted in phagocytosis. In addition, all three markers were associated with coated pits, smooth surfaced vesicles (45-60 nm), C- or cup-shaped structures and other lysosomal elements, but were excluded from Golgi cisternae and their entire vesicle population. In CT cells, HRP does not act solely as a "content" marker that reflects fluid-phase uptake. Instead it appears to follow adsorptive endocytic pathways. The endocytic behavior of in vivo and in vitro cushion tissue cells appears to be the same. Endogenous endocytic activity may reflect in part membrane retrieval, which counterbalances the extensive exocytosis observed in these cells.     

Three-dimensional model system of valvulogenesis.

Valvular defects are among the most common and deleterious of all cardiac malformations. The early cardiac cushions are located in the atrioventricular (AV) canal of the embryonic heart. These cushions contain cells that are the primordia of the cardiac valves and membranous septa. Significant progress has been made in delineating the molecular mechanisms that regulate the early steps of cushion formation; however, little is known about how these cushions differentiate into valve leaflets. Here, a new three-dimensional collagen tube culturing system was tested for its ability to sustain the development and maturation of the AV cushion anlagen. We report that AV cushion tissues grown within the collagen tube scaffold recapitulate aspects of AV valve development both at the molecular and morphological levels. Furthermore, our results indicate that valve leaflet formation in the tube model is dependent on the presence of cardiac myocytes.     

超声诊断胎儿先天性心内膜垫缺损

目的探讨产前超声诊断胎儿心内膜垫缺损的临床价值。方法对2004年10月～2008年10月77832例孕18w以上的胎儿心脏应用超声检查,以胎儿四腔心切面为常规,多切面扫查观察胎儿心脏大小、形态、房室结构、房室瓣开闭、左右心室流出道。结果发现心内膜垫缺损16例,伴发其他畸形4例,漏诊1例。结论产前超声是诊断胎儿先天性心内膜垫缺损的可靠方法及技术,可阻止严重先天性畸形——心内膜垫缺损的胎儿出生。     

Expression and function of bone morphogenetic proteins in the development of the embryonic endocardial cushions

Bone morphogenetic proteins (BMPs) are considered to be significant factors in the morphogenesis of the endocardial cushions of the developing embryonic heart. Previous studies have suggested that they are involved in the epithelial–mesenchymal transformation and migration of the cells forming the cushions, or in triggering an apoptotic cascade in a sub-population of cushion cells. We investigated the expression and function of BMP2 and BMP4 proteins in the developing heart of the chick and mouse embryos. In the chick, by immunocytochemistry, we find expression of BMP2 protein in the endocardial cushions of the outflow tract (OT) and atrio-ventricular (AV) regions at embryonic days (ED) 5–6, as well as in adjacent myocardial layers. Immunoblotting indicated that such expression persisted through ED 4–7, but peaked at ED4–5 in the OT and 5–6 in the AV cushions. This temporal sequence correlated with the peaks of apoptotic cell death found previously in the OT and AV cushions of the chick embryo. At equivalent stages in mouse, no such expression of BMP2 was found in the cushions, although expression was detected in adjacent myocardial layers. In the case of BMP4, in both chick and mouse, expression was found only in the myocardia and not in the cushions. Furthermore, BMP-specific receptors were found in the cushions, but not the myocardia, in both the AV and OT regions of the chick embryo. These results provide circumstantial evidence to support the contention that BMPs, originating from the myocardium, could be significant in the induction of apoptosis in chick embryo cushion cells, and confirms that there is species-specific variation in the expression pattern of BMP proteins, as had been predicted from previous studies of mRNA expression. Culture media conditioned by the growth of tissues from various regions of the developing heart were tested for their ability to induce apoptosis in cushion cells in culture. It was found that medium derived from the myocardia induced significant levels of cell death in the cushion cells, and that BMP4 could be detected in such media; however, retroviral over-expression of constitutively active (CA) and dominant-negative (DN) isoforms of BMP-specific receptors 1A and 1B (BMPR-1A and BMPR-1B) in cultured cells of the AV cushions did not alter levels of apoptosis or cell proliferation. Similar over-expression in cultured endocardial cells resulted in a significant change in cell shape, from endothelial to fibroblastic, with BMPR-1A CA and BMPR-1B DN, suggesting an influence of these receptors on cell transformation and/or cell migration. Taken together, these results provide support for the contention that BMP2 and BMP4 are important factors in the phenotypic transformational events involved in the morphogenesis of the chick embryo endocardial cushions, and could be involved in the induction of apoptosis in the cushion cells.     

Programmed cell death in the developing heart: regulation by BMP4 and FGF2.

Programmed cell death, or apoptosis, plays an important role in embryonic development. To provide new insights into the role of programmed cell death in cardiac development, we examined the hearts of the murine embryos from E9.5 to postnatal day 3. Using terminal transferase-mediated dUTP nick end-labeling assays, apoptosis was detected in the endocardial cushions and myocardium from E11.5 to postnatal day 3 (P3). In the ventricular myocardium, more apoptotic cells were observed in the left than right ventricles throughout embryonic and early postnatal development. Apoptosis was also present in the trabeculae and papillary muscles of the ventricles. In the outflow tract, cell death was present in the endocardial cushions before they fuse to form the conotruncal septum (E11.5-E12. 5) and reached a peak intensity when the conotruncal septum formed (E13.5). In the atrioventricular (AV) endocardial cushions, cell death was detected in the fusion seam of the cushion tissues at E12. 5 and E13.5 during AV septation. When the patterns of apoptosis were compared with patterns of cell division, we found that programmed cell death occurred in the areas in the endocardial cushions and trabeculae where rates of cell proliferation were low. We also found that programmed cell death was regulated by the growth factors, BMP4 and FGF2, in vitro. BMP4 induced, whereas FGF2 inhibited, apoptosis in both endocardial cushions and ventricular myocardium. Overall, our observations show that there is apoptosis in the regions where fusion or remodeling of tissues occurs. We also show that cardiac programmed cell death can be influenced by growth factors.     

Expression of bone morphogenetic protein-5 gene during chick heart development: possible roles in valvuloseptal endocardial cushion formation.

The bone morphogenetic protein (BMP) family, comprising multifunctional peptide growth factors, regulates many developmental processes in a variety of tissues. We examined the spatiotemporal expression of BMP5 by in situ hybridization in chick embryonic hearts from stages 5 to 33. The BMP5 gene was first expressed in the endoderm underlying the precardiac mesoderm at stages 5 to 8. Thereafter, BMP5 expression was restricted to the myocardium of the atrioventricular (AV) canal and outflow tract (OT) regions, where the valvuloseptal endocardial cushion tissue is induced. These results suggest that BMP5 may play important roles not only in myocardial differentiation, but also in the formation and maintenance of endocardial cushion tissue.     

Septation and valvar formation in the outflow tract of the embryonic chick heart

There is no agreement, in the chick, about the number of the endocardial cushions within the outflow tract or their pattern of fusion. Also, little is known of their relative contributions to the formation of the arterial valves, the subpulmonary infundibulum, and the arterial valvar sinuses. As the chick heart is an important model for studying septation of the outflow tract, our objective was to clarify these issues. Normal septation of the outflow tract was studied in a series of 60 staged chick hearts, by using stained whole-mount preparations, serial sections, and scanning electron microscopy. A further six hearts were examined subsequent to hatching. At stage 21, two pairs of endocardial cushions were seen within the developing outflow tract. One pair was positioned proximally, with the other pair located distally. By stage 25, a third distal cushion had developed. This finding was before the appearance of two further, intercalated, endocardial cushions, also distally positioned, which were first seen at stage 29. In the arterial segment, the aortic and pulmonary channels were separated by the structure known as the aortopulmonary septum. The dorsal limb of this septum penetrated the distal dorsal cushion, whereas the ventral limb grew between the remaining two distal cushions, both of which were positioned ventrally. The three distal endocardial cushions, and the two intercalated endocardial cushions, contributed to the formation of the leaflets and sinuses of the arterial roots. The two proximal cushions gave rise to a transient septum, which later became transformed into the muscular component of the subpulmonary infundibulum. Concomitant with these changes, an extracardiac tissue plane was formed which separated this newly formed structure from the sinuses of the aortic root. Our study confirms that three endocardial cushions are positioned distally, and two proximally, within the developing outflow tract of the chick. The pattern of the distal cushions, and the position of the ventral limb of the aortopulmonary septum, differs significantly from that seen in mammals.     

Impact of excluding cases with known chromosomal abnormalities on the prevalence of structural birth defects, Hawaii, 1986-1999

Chromosomal abnormalities are more common in the presence of structural birth defects. However, much of the literature have only provided chromosomal abnormality rates for one or a few structural birth defects at a time. This study calculated the chromosomal abnormality rates for a number of structural birth defects using data from the Hawaii Birth Defects Program (HBDP) for deliveries during 1986-1999 and evaluated the impact of exclusion of cases with chromosomal abnormalities when calculating birth prevalence. The chromosomal abnormality rates were highest for endocardial cushion defect (40%) and omphalocele (27%), while no chromosomal abnormalities were reported for pyloric stenosis, persistent cloaca, and deficiency of lower limbs. The majority of chromosomal abnormality rates fell within a certain range, with 32 (63%) of the birth defect categories having chromosomal abnormality rates of 5-15%. The chromosomal abnormality rates also tended to be higher for multiple than for isolated cases. For three of the structural birth defects (ventricular septal defect, atrial septal defect, endocardial cushion defect), the birth prevalence of the defect, when cases with a chromosomal abnormality were excluded, was significantly lower than the birth prevalence that included those cases. Chromosomal abnormality rates varied by type of structural birth defect and presence of other major structural birth defects. For at least several structural birth defects, exclusion of cases with chromosomal abnormalities significantly underestimated the birth prevalence. This underestimation may be important, depending on the purpose of the analysis.     

Expression of bone morphogenetic protein‐5 gene during chick heart development: Possible roles in valvuloseptal endocardial cushion formation

The bone morphogenetic protein (BMP) family, comprising multifunctional peptide growth factors, regulates many developmental processes in a variety of tissues. We examined the spatiotemporal expression of BMP5 by in situ hybridization in chick embryonic hearts from stages 5 to 33. The BMP5 gene was first expressed in the endoderm underlying the precardiac mesoderm at stages 5 to 8. Thereafter, BMP5 expression was restricted to the myocardium of the atrioventricular (AV) canal and outflow tract (OT) regions, where the valvuloseptal endocardial cushion tissue is induced. These results suggest that BMP5 may play important roles not only in myocardial differentiation, but also in the formation and maintenance of endocardial cushion tissue. Anat Rec 264:313–316, 2001. © 2001 Wiley‐Liss, Inc.     

Left-right lineage analysis of AV cushion tissue in normal and laterality defective Xenopus hearts

The majority of complex congenital heart defects occur in individuals who are afflicted by laterality disease. We hypothesize that the prevalence of valvuloseptal defects in this population is due to defective left-right patterning of the embryonic atrioventricular (AV) canal cushions, which are the progenitor tissue for valve and septal structures in the mature heart. Using embryos of the frog Xenopus laevis, this hypothesis was tested by performing left-right lineage analysis of myocytes and cushion mesenchyme cells of the superior and inferior cushion regions of the AV canal. Lineage analyses were conducted in both wild-type and laterality mutant embryos experimentally induced by misexpression of ALK4, a type I TGF-beta receptor previously shown to modulate left-right axis determination in Xenopus. We find that abnormalities in overall amount and left-right cell lineage composition are present in a majority of ALK4-induced laterality mutant embryos and that much variation in the nature of these abnormalities exists in embryos that exhibit the same overall body situs. We propose that these two parameters of cushion tissue formation-amount and left-right lineage origin-are important for normal processes of valvuloseptal morphogenesis and that defective allocation of cells in the AV canal might be causatively linked to the high incidence of valvuloseptal defects associated with laterality disease.     

New foetopathological section of the heart. Correlated to the ultrasonographic 4 Chamber view in fetuses

Our findings on hearts of trisomic 21 fetuses of a new minor cardiac anomaly, belonging to the atrioventricular septal defect (AVSD) spectrum and the improved performances of the fetal ultrasound screening lend us to propose a new section, complementary to the standard cardiopathological examination. It would enable us to test the anatomic level of insertion of the atrioventricular valves of the crux of the heart. It consists of a section of the fetal hearts, fixed in formaldehyde, in a plane correlated to the plane of the fetal ultrasonographic four chamber view. Three hallmarks have been chosen because of their relevance and of their reproductibility in ultra sonography as well as in fetopathology: the apex and the inferior pulmonary veins. This additional section was realized on fetal hearts, regarded as "normal" with the standard pathologic examination, because of a lack of defect. It allowed us to detect a minor cardiac abnormality of the AVSD spectrum, frequent in the trisomic 21 fetuses, which we called: linear insertion of the atrio ventricular valves( LIAVV) without defect. Initially described on a series of Trisomic 21 fetal hearts, the LIAVV without defect has also been found in other fetuses with another pathology often associated with an anomaly of the AVSD spectrum. The possible detection of this abnormality in fetal cardiac ultrasound scanning justifies the use of this new anatomical technique. It also has to be included it in the full standard pathologic examination of the fetal hearts of all the abnormal fetuses.     

The contribution of the inferior endocardial cushion of the atrioventricular canal to cardiac septation and to the development of the atrioventricular valves: Study in the chick embryo

The contribution of the inferior endocardial cushion of the atrioventricular canal to cardiac septation and to the development of the atrioventricular valves was studied in the chick embryo by in vivo labelling techniques. The study was performed in White Leghorn chick embryos in which the dorsal cushion was labelled at stage 20-21 (Hamburger and Hamilton, 1951), when the endocardial cushions were not yet fused. The embryos were sacrificed at stage 35 (mature heart). These experiments allow us to conclude that the inferior atrioventricular cushion gives origin to: (a) that part of the cardiac septum between the septal insertion of the antero-septal leaflet of the mitral valve and the fibrous ridge which is the equivalent to the human septal leaflet of the tricuspid valve (atrioventricular septum); (b) the region of the interatrial and the interventricular septa adjacent to the atrioventricular septum; (c) the portion of the antero-septal leaflet of the mitral valve which inserts into the septum; (d) the fibrous ridge corresponding to the septal leaflet of the tricuspid valve. Microdissection shows that, when they appear at stage 18, the superior and inferior endocardial cushions of the atrioventricular canal are in continuity, without boundaries, with both the interatrial and interventricular septa. Therefore, each atrioventricular orifice opens into its corresponding ventricle, there being no stage in the development of the chick embryo heart in which the atrioventricular orifices are connected to the left ventricle at the same time. The development of the atrioventricular canal is similar in the chick and human.     

小鼠胚胎心脏房室管心内膜垫发育的形态学特征

目的 探讨小鼠胚胎心脏房室管心内膜垫的形成与融合过程中的形态学特征。方法 选用抗α-平滑肌肌动蛋白（α-SMA）、抗心肌肌球蛋白重链（MHC）、抗磷酸化组蛋白H3（PHH3）抗体,对30只胚龄9～13d小鼠胚胎连续切片进行HE和免疫组织化学染色。另选15只胚龄12d、12.5d、13d小鼠胚胎心脏制作半薄切片和超薄切片进行观察。 结果 胚龄9d,心房与心室之间可见缩窄的房室管,房室管的心胶质较厚,但未见间充质细胞出现。胚龄10d,房室管心内膜垫开始形成,但连续切片观察显示背侧心内膜垫体积大于腹侧心内膜垫,且背侧心内膜垫对应的α-SMA、MHC阳性房室管心肌向心内膜垫内有明显延伸。心内膜垫内间充质细胞不表达α-SMA或PHH3。胚龄11～12d,背、腹侧心内膜垫变得对称,垫内间充质细胞增多,偶见α-SMA或PHH3阳性细胞。胚龄12～13d,两侧房室管心内膜垫彼此接近开始融合。透射电子显微镜下观察仅部分间充质细胞相邻细胞膜彼此相贴,局部形成细胞连接。胞质内可见粗面内质网、线粒体等细胞器,微丝较少。 结论 小鼠胚胎心脏房室管心内膜垫形成时首先表现为内皮细胞由扁平变为立方形;两侧房室管心内膜垫形成不同步;房室管心内膜垫融合时间充质细胞局部形成细胞连接,胞质内微丝少,与流出道嵴融合时的超微结构特点不同。