应用三元递减法筛选特异性心脏生长相关基因

心脏是由胚胎干细胞特异性分化而来的 ,但其分化的分子生物学机制尚不十分了解 .为建立一种新的筛选特异性心脏相关基因的方法 ,克隆特异性心脏生长相关基因 .从胚胎心、成年心和去胎心的胚胎中提取 m RNA,建立胎心 /成年心和胎心 /胎身两个递减性 c DNA文库 ,通过 DNA芯片和微阵列杂交筛选和克隆 ,建立了三元递减克隆的新方法 .获得了一个全长为 1 0 0 6 bp可编码1 94个氨基酸的新的与心脏生长相关的基因 ,它是 LIM家族的新成员 ,可特异性在心肌细胞表达 ,并可促进心肌细胞的生长 .结果表明 ,三元递减筛选法可以应用于寻找新的组织特异性表达的基因 .并且获得了一个新的与心脏生长相关的新基因 ,它可能在心肌生长和心肌肥厚的发生中发挥重要作用     

Diffusable growth factors induce bladder smooth muscle differentiation

Bladder smooth muscle differentiation is dependent on the presence of bladder epithelium. Previously, we have shown that direct contact between the epithelium and bladder mesenchyme (BLM) is necessary for this interaction. In this study, we tested the hypothesis that bladder smooth muscle can be induced via diffusable growth factors. Fourteen-day embryonic rat bladders were separated into bladder mesenchyme (prior to smooth muscle differentiation) and epithelium by enzymatic digestion and microdissection. Six in vitro experiments were performed with either direct cellular contact or no contact (1) 14-d embryonic bladder mesenchyme (BLM) alone (control), (Contact) (2) 14-d embryonic bladders intact (control), (3) 14-d embryonic bladder mesenchyme combined with BPH-1 cells (an epithelial prostate cell line) in direct contact, (4) 14-d embryonic bladder mesenchyme with recombined bladder epithelium (BLE) in direct contact, (No Contact) (5) 14-d embryonic bladder mesenchyme with BPH-1 prostatic epithelial cells cocultured in type 1 collagen gel on the bottom of the well, and (6) 14-d embryonic bladder mesenchyme with BPH-1 epithelium cultured in a monolayer on a transwell filter. In each case the bladder tissue was cultured on Millicell-CM 0.4-microm membranes for 7 d in plastic wells using serum free medium. Growth was assessed by observing the size of the bladder organoids in histologic cross section as well as the vertical height obtained in vitro. Immunohistochemical analysis of the tissue explants was performed to assess cellular differentiation with markers for smooth muscle alpha-actin and pancytokeratin to detect epithelial cells. Control (1) bladder mesenchyme grown alone did not exhibit growth or smooth muscle and epithelial differentiation. Contact experiments (2) intact embryonic bladder, (3) embryonic bladder mesenchyme recombined with BPH-1 cells, and (4) embryonic bladder mesenchyme recombined with urothelium each exhibited excellent growth and bladder smooth muscle and epithelial differentiation. Both noncontact experiments (5) and (6) exhibited growth as well as bladder smooth muscle and epithelial differentiation but to a subjectively lesser degree than the contact experiments. Direct contact of the epithelium with bladder mesenchyme provides the optimal environment for growth and smooth muscle differentiation. Smooth muscle growth and differentiation can also occur without direct cell to cell contact and is not specific to urothelium. This data supports the hypothesis that epithelium produces diffusable growth factors that induce bladder smooth muscle.     

Cytoskeletal heart-enriched actin-associated protein (CHAP) is expressed in striated and smooth muscle cells in chick and mouse during embryonic and adult stages

We recently identified a new Z-disc protein, CHAP (Cytoskeletal Heart-enriched Actin-associated Protein), which is expressed in striated muscle and plays an important role during embryonic muscle development in mouse and zebrafish. Here, we confirm and further extend these findings by (i) the identification and characterization of the CHAP orthologue in chick and (ii) providing a detailed analysis of CHAP expression in mouse during embryonic and adult stages. Chick CHAP contains a PDZ domain and a nuclear localization signal, resembling the human and mouse CHAPa. CHAP is expressed in the developing heart and somites, as well as muscle precursors of the limb buds in mouse and chick embryos. CHAP expression in heart and skeletal muscle is maintained in adult mice, both in slow and fast muscle fibers. Moreover, besides expression in striated muscle, we demonstrate that CHAP is expressed in smooth muscle cells of aorta, carotid and coronary arteries in adult mice, but not during embryonic development.     

DNA synthesis, mitosis, and differentiation in cardiac myogenesis

Cardiac muscle cells obtained by trypsinizing 5-day chick embryonic heart were cultured as single cells in separate culture dishes. Using this technique, problems of heterotypic cell interactions, “overgrowth” of one cell type, etc., are eliminated. Experiments performed on these single cell cultures show that the muscle cells in the embryonic chick hearts differ in morphology, including content of cross-striated myofibrils; in ability to synthesize DNA and undergo mitosis; and in frequency of contraction. Contracting cells containing cross-striated myofibrils undergo mitosis in vitro, giving rise to spontaneously beating daughter cells. These daughter cells contain cytoplasmic fibrils, which bind fluorescein-labeled antimyosin immediately after cytokinesis. Some cardiac muscle cells from 5-day heart do not divide in culture; the rest undergo 1–5 doublings. This preliminary investigation suggests that the new muscle cells formed during cardiac growth are derived from mitotically active “overtly” differentiated cardiac muscle cells.     

The development of cystic embryoid bodies in vitro from clonal teratocarcinoma stem cells

Previous findings on exogenous RNA-induced heart muscle differentiation in the non-heartforming cultured explants of the chick blastoderm, the postnodal pieces, were reexamined. Some of the changes that characterized the transition in the host tissues were: (i) the formation of highly ordered myofibrils; (ii) the appearance of characteristic cytoplasmic glycogen particles; (iii) a 2.5- and 3.5-fold increase in actin and myosin-like polypetides respectively; (iv) an increase in acetylcholinesterase activity; and (v) the acquisition of spontaneous and rhythmic pulsations. These specific changes appeared only in those explants that received a poly(A)-containing RNA fraction obtained from the 16-day-old chick embryonic heart. Neither synthetic polynucleotides nor a variety of RNA from several sources could replace the RNA from chick embryonic heart as an inducer of heart muscle differentiation.     

Mammalian target of rapamycin is essential for cardiomyocyte survival and heart development in mice

Mammalian target of rapamycin (mTOR) is a critical regulator of protein synthesis, cell proliferation and energy metabolism. As constitutive knockout of Mtor leads to embryonic lethality, the in vivo function of mTOR in perinatal development and postnatal growth of heart is not well defined. In this study, we established a muscle-specific mTOR conditional knockout mouse model (mTOR-mKO) by crossing MCK-Cre and Mtor^flox/flox mice. Although the mTOR-mKO mice survived embryonic and perinatal development, they exhibited severe postnatal growth retardation, cardiac muscle pathology and premature death. At the cellular level, the cardiac muscle of mTOR-mKO mice had fewer cardiomyocytes due to apoptosis and necrosis, leading to dilated cardiomyopathy. At the molecular level, the cardiac muscle of mTOR-mKO mice expressed lower levels of fatty acid oxidation and glycolysis related genes compared to the WT littermates. In addition, the mTOR-mKO cardiac muscle had reduced Myh6 but elevated Myh7 expression, indicating cardiac muscle degeneration. Furthermore, deletion of Mtor dramatically decreased the phosphorylation of S6 and AKT, two key targets downstream of mTORC1 and mTORC2 mediating the normal function of mTOR. These results demonstrate that mTOR is essential for cardiomyocyte survival and cardiac muscle function.     

皖西白鹅胚胎中、后期肌组织发育变化的观察

分别于17、23、29胚龄各取6枚胚胎发育正常的种蛋,分离鹅胚的心脏、肌胃及大腿骨骼肌,制作石蜡切片,HE染色,显微观察、摄影.观察皖西白鹅胚胎中、后期肌肉组织发育的变化.结果表明,17d时的骨骼肌、平滑肌、心肌的发育程度均较低,没有形成正常的肌纤维形态,之后呈现随龄性增长.骨骼肌和平滑肌在17 d～23 d期间是以肌纤维数量的增加为主,即成肌细胞的分裂增殖,23 d～29 d 期间成肌细胞分化融合形成肌纤维;心脏成纤维细胞增殖速度较快,17 d心脏肌纤维已经排列紧密基本吻合成网状;17 d后主要是心肌纤维的伸长和成熟化的过程.说明胚胎期心肌组织的生长发育要早于骨骼肌与平滑肌.     

Follistatin regulates bone morphogenetic protein-7 (BMP-7) activity to stimulate embryonic muscle growth

Bone morphogenetic proteins (BMPs) can either promote growth of embryonic muscle by expanding the Pax-3-expressing muscle precursor population or restrict its development by inducing apoptosis. Follistatin, a proposed BMP antagonist, is expressed in embryonic muscle. Deficiency in Follistatin results in muscle defects and postnatal asphyxia. Here, we report that during chick limb development Follistatin enhances BMP-7 action to induce muscle growth but prevents the ability of BMP-7 to induce apoptosis and muscle loss. Follistatin, unlike another BMP-binding protein, Noggin, promotes Pax-3 expression and transiently delays muscle differentiation and thus exerts proliferative signalling during muscle development. We provide data which show that Follistatin binds BMP-7 and BMP-2 at low affinities and that the binding is reversible. These data suggest that Follistatin acts to present BMPs to myogenic cells at a concentration that permits stimulation of embryonic muscle growth.     

Identification of two variants of troponin T in the developing chicken heart using a monoclonal antibody

Troponin T (TNT) expressed in the developing chicken cardiac muscle was examined by immunoblotting combined with two-dimensional electrophoresis (2-D PAGE) and peptide mapping. When the whole lysate of the neonatal heart was examined by 2-D PAGE, two TNT variants were detected on the gel by monoclonal antibody to TNT. Expression of the two variants was developmentally regulated: one isoform (type I) was expressed from embryonic through neonatal stages, and the other (type II) from the late embryonic stage through adulthood during cardiac muscle development. The type-I isoform, but not type-II isoform, was also expressed transiently in chicken skeletal muscle at embryonic stages. As judged from the peptide maps, the two isoforms differed in the N-terminal region but not in the C-terminal region.     

Characterization of a myosin heavy chain in the conductive system of the adult and developing chicken heart

A monoclonal antibody (anterior latissimus dorsi 58 [ALD58]; antimyosin heavy chain, MHC) directed against myosin from slow tonic muscle was found to react specifically with the striated muscle cells of the conductive system in the adult chicken heart. This monoclonal antibody was used to study the expression of myosin in the conductive system of the adult and developing heart. Using immunofluorescence microscopy with ALD58, muscle cells of the conductive system were demonstrated in both the atria and ventricles of the adult heart as previously shown by Sartore et al. (Sartore, S., S. Pierobon-Bormioli, and S. Schiafinno, 1978, Nature (Lond.), 274: 82-83). Radioactive myosin from adult atria and ventricles was precipitated with ALD58 and subjected to limited proteolysis and subsequent peptide mapping. Peptide maps of ALD58 reactive myosin from atria and ventricles were very similar, if not identical, but differed from peptide maps of ordinary atrial and ventricular myosin. The same antibody was used to study cardiac myogenesis in the chick embryo. When ALD58 was reacted with myosin isolated from atria and ventricles at selected stages of development in radioimmunoassays, reactivity was not observed until the last week of embryonic life (greater than 15 d of egg incubation). Thereafter concomitant and progressively increased reactivity was observed in atrial and ventricular preparations. Also, no ALD58 positive cells were observed in immunofluorescence studies of embryonic hearts until 17 d of egg incubation. Primary cell cultures of embryonic hearts also proved to be negative for this antibody. This study demonstrates that an epitope recognized by ALD58 associated with an antimyosin heavy chain of striated muscle cells of the adult heart conductive system is absent or present in only small amounts in the early embryonic heart.     

Troponin I switching in the developing heart

Monoclonal antibodies identify two distinct isoforms of troponin I in rat cardiac muscle, one predominant in the embryonic and fetal heart and one predominant in the adult heart. The two isoforms can be resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, with apparent molecular weights of 27,000 and 31,500, respectively. The adult isoform is specifically recognized by a monoclonal antibody that is unreactive with the embryonic variant, while two other monoclonal antibodies recognize both isoforms. A monoclonal antibody to cardiac troponin T was used to isolate by affinity chromatography the troponin complex from adult and neonatal rat heart. Affinity purified troponin from neonatal heart was found to contain both the embryonic and adult isoforms of troponin I. Comparative immunoblotting analysis with different muscle tissues shows that embryonic troponin I is identical with respect to electrophoretic mobility and pattern of immunoreactivity to the major troponin I isoform found in adult slow skeletal muscle. Troponin I switching may be implicated in developmental changes involving Ca2+ and pH sensitivity of the contractile system and response to beta-adrenergic stimulation.     

Fast myosin heavy chain expression during the early and late embryonic stages of chicken skeletal muscle development

The development of embryonic skeletal muscles in the chick can be divided into two periods of fiber specialization--an early one during which the different muscles of the limb are formed and an initial round of fiber specialization occurs and a late or fetal period during which there is extensive growth of this previously established fiber pattern. This latter period of growth is dependent on the establishment and maintenance of functional neuromuscular contacts. As has been described for other developmental stages, we show here that there are different embryonic fast skeletal muscle myosin heavy chain (MHC) isoforms expressed during the different embryonic periods of muscle growth. The identification of these isoforms was based on differences in their reactivity with various fast MHC monoclonal antibodies and on their different peptide banding patterns. The in ovo accumulation of the late embryonic MHC isoform pattern was similar to the time course of the previously described changes in alpha-actin and troponin T isotype switching during embryogenesis. The appearances of the late embryonic isoforms were blocked by chronic treatment with the neuromuscular blocking agent, d-tubocurarine, and cell cultures of embryonic chicken skeletal muscle which differentiated in the absence of motorneurons expressed little of the late embryonic isoform, indicating that the expression of the late embryonic isoform was dependent on functional nerve-muscle interactions. These different embryonic fast MHC isoforms provide important markers for monitoring the progression of muscle through its embryonic stages and its interaction with motorneurons.     

FGF-16 is required for embryonic heart development

Fibroblast growth factor 16 (FGF-16) expression has previously been detected in mouse heart at mid-gestation in the endocardium and epicardium, suggesting a role in embryonic heart development. More specifically, exogenously applied FGF-16 has been shown to stimulate growth of embryonic myocardial cells in tissue explants. We have generated mice lacking FGF-16 by targeting the Fgf16 locus on the X chromosome. Elimination of Fgf16 expression resulted in embryonic death as early as day 11.5 (E11.5). External abnormalities, including hemorrhage in the heart and ventral body region as well as facial defects, began to appear in null embryos from E11.5. Morphological analysis of FGF-16 null hearts revealed cardiac defects including chamber dilation, thinning of the atrial and ventricular walls, and poor trabeculation, which were visible at E10.5 and more pronounced at E11.5. These findings indicate FGF-16 is required for embryonic heart development in mid-gestation through its positive effect on myocardial growth.