RESUMEN
The primary heart tube is an endocardial tube, ensheathed by myocardial cells, that develops from bilateral primary heart fields located in the lateral plate mesoderm. Earlier mapping studies of the heart fields performed in whole embryo cultures indicate that all of the myocardium of the developed heart originates from the primary heart fields. In contrast, marking experiments in ovo suggest that the atrioventricular canal, atria and conotruncus are added secondarily to the straight heart tube during looping. The results we present resolve this issue by showing that the heart tube elongates during looping, concomitant with accretion of new myocardium. The atria are added progressively from the caudal primary heart fields bilaterally, while the myocardium of the conotruncus is elongated from a midline secondary heart field of splanchnic mesoderm beneath the floor of the foregut. Cells in the secondary heart field express Nkx2.5 and Gata-4, as do the cells of the primary heart fields. Induction of myocardium appears to be unnecessary at the inflow pole, while it occurs at the outflow pole of the heart. Accretion of myocardium at the junction of the inflow myocardium with dorsal mesocardium is completed at stage 12 and later (stage 18) from the secondary heart field just caudal to the outflow tract. Induction of myocardium appears to move in a caudal direction as the outflow tract translocates caudally relative to the pharyngeal arches. As the cells in the secondary heart field begin to move into the outflow or inflow myocardium, they express HNK-1 initially and then MF-20, a marker for myosin heavy chain. FGF-8 and BMP-2 are present in the ventral pharynx and secondary heart field/outflow myocardium, respectively, and appear to effect induction of the cells in a manner that mimics induction of the primary myocardium from the primary heart fields. Neither FGF-8 nor BMP-2 is present as inflow myocardium is added from the primary heart fields. The addition of a secondary myocardium to the primary heart tube provides a new framework for understanding several null mutations in mice that cause defective heart development.
Asunto(s)
Embrión no Mamífero/metabolismo , Atrios Cardíacos/embriología , Corazón/embriología , Miocardio/metabolismo , Factor de Crecimiento Transformador beta , Proteínas de Xenopus , Animales , Proteína Morfogenética Ósea 2 , Proteínas Morfogenéticas Óseas/biosíntesis , Antígenos CD57/biosíntesis , Diferenciación Celular , Embrión de Pollo , ADN Complementario/metabolismo , Proteínas de Unión al ADN/biosíntesis , Factor 2 de Crecimiento de Fibroblastos/biosíntesis , Factor 8 de Crecimiento de Fibroblastos , Factores de Crecimiento de Fibroblastos/biosíntesis , Factor de Transcripción GATA4 , Proteína Homeótica Nkx-2.5 , Proteínas de Homeodominio/biosíntesis , Inmunohistoquímica , Hibridación in Situ , Modelos Biológicos , Mutación , Fenotipo , Codorniz , Factores de Transcripción de la Familia Snail , Factores de Tiempo , Distribución Tisular , Factores de Transcripción/biosíntesisRESUMEN
Ablation of premigratory cardiac neural crest results in defective development of the cardiac outflow tract. The purpose of the present study was to correlate the earliest functional and morphological changes in heart development after cardiac neural crest ablation. Within 24 hours after neural crest ablation, the external morphology of the hearts showed straight outflow limbs, tighter heart loops, and variable dilations. Incorporation of bromodeoxyuridine in myocytes, an indication of proliferation, was doubled after cardiac neural crest ablation. The myocardial calcium transients, which are a measure of excitation-contraction coupling, were depressed by 50% in both the inflow and outflow portions of the looped heart tube. The myocardial transients could be rescued by replacing the cardiac neural crest. The cardiac jelly produced by the myocardium was distributed in an uneven, rather than uniform, pattern. An extreme variability in external morphology could be attributed to the uneven distribution of cardiac jelly. In the absence of cardiac neural crest, the myocardium was characterized by somewhat disorganized myofibrils that may be a result of abnormally elevated proliferation. In contrast, endocardial development appeared normal, as evidenced by normal expression of fibrillin-2 protein (JB3 antigen) and normal formation of cushion mesenchyme and trabeculae. The signs of abnormal myocardial development coincident with normal endocardium suggest that the presence of cardiac neural crest cells is necessary for normal differentiation and function of the myocardium during early heart development. These results indicate a novel role for neural crest cells in myocardial maturation.
Asunto(s)
Corazón/embriología , Cresta Neural/fisiología , Animales , Embrión de Pollo , Modelos Animales de Enfermedad , Endocardio/embriología , Cardiopatías Congénitas/embriología , Cardiopatías Congénitas/patología , Miocardio/metabolismo , Miocardio/ultraestructuraRESUMEN
BACKGROUND: Chick coronary arteries originate as penetrating channels from a subepithelial peritruncal ring into the wall of all three aortic coronary sinuses. Two of these capillaries develop a muscular wall and become the definitive coronary arteries. Since cardiac neural crest (CNC) contributes ectomesenchyme to the tunica media (TM) of the aortic arch vessels, we wished to learn if the CNC also contributes to the media of the coronary arteries and if CNC plays an inductive role in determining the site of aortic penetrations and influences which channels persist to hatching. METHODS: Quail-to-chick chimeras were made by bilaterally removing the chick CNC and replacing it with quail CNC. The chimeras and unoperated controls were collected on embryonic days (ED) 7-18, fixed in Carnoy's fixative, serially sectioned, stained with Feulgen-Rossenbeck stain, and analyzed. Several ED 18 controls and chimeras were also stained with Gomori's trichrome stain, or labeled with antineurofilament or antivascular smooth muscle alpha actin. RESULTS: The TM of the coronary arteries and the aortic coronary sinuses did not consist of CNC cells. The media of the surviving coronary arteries was disrupted by clusters of CNC cells scattered in the wall of the base of the coronary artery on ED 14 and 18. Persisting coronary arteries were always associated with large neural crest-derived parasympathetic ganglia near their origin. Branches from parasympathetic nerves entered the base of the coronary arteries where the clusters of neural crest cells were located. Quail cells were also associated with tiny vessels exiting the ostia of the coronary arteries and traveling in the outer aortic wall. Labeling with antibodies confirmed a disruption of the TM at the base of the coronary arteries, and showed innervated clusters of quail cells in the disrupted part of the TM. CONCLUSION: Although the TM of the coronary arteries and the aortic coronary sinuses contained no CNC cells, clusters of innervated quail cells disrupted the TM at the base of the coronary arteries. CNC does not appear to induce capillary penetration directly; however, the exclusive association of CNC-derived parasympathetic ganglia and nerves with persisting coronary arteries suggests that the presence of parasympathetic ganglia is essential to the survival of the definitive coronary arteries. CNC cells may also be associated with the development of the aortic vasa vasorum.
Asunto(s)
Vasos Coronarios/embriología , Corazón/embriología , Cresta Neural/embriología , Animales , Embrión de Pollo , Quimera , Vasos Coronarios/citología , Vasos Coronarios/inervación , Codorniz , Seno Aórtico/embriologíaRESUMEN
The cardiac neural crest is essential for normal development of the cardiovascular system. Cardiac neural crest cells are derived from the neural folds located between the mid-otic placodes and the caudal limit of somite 3. These crest cells can differentiate into a variety of mesenchymal cell types that support cardiovascular development, in addition to neurogenic cells. When cultured, many express alpha-smooth muscle actin or neurofilaments and lose their undifferentiated neural crest phenotype as shown by a decrease in HNK-1 reactivity. We wanted to determine whether cultured cardiac neural crest cells maintained the potency to support normal heart development when backtransplanted into embryos lacking their native cardiac neural crest. Under usual circumstances removal of the cardiac neural crest results in 80-100% incidence of persistent truncus arteriosus. The present study reports a system in which cardiac neural folds are cultured for 3 days and the cells backtransplanted into chick embryos after laser-induced ablation of the intrinsic cardiac neural folds. Rescue of heart development was improved 50% when cultured cells were backtransplanted and almost 200% when the backtransplanted cells had been cultured in leukemia inhibitory factor (LIF). To determine whether the cultured cells are capable of following normal migratory routes, cultured homospecific cardiac neural crest cells were tagged with DiI. Initially, fluorescent cells were found concentrated around the neural tube. By the second day following backtransplantation, the cells had migrated to the circumpharyngeal crest, populated the pharyngeal arches and aortic arch arteries, and were in the region of the cardiac outflow tract. By the third day, the labeled cells had dispersed, but could be found around the neural tube, esophagus, cardiac outflow tract, and within the dorsal root ganglia. Interestingly, a cranial migration to the periphery of the eyes was also noted. With the exception of the cranial migration to the eyes, cultured and backtransplanted cardiac neural crest cells followed normal migratory pathways to the cardiac outflow tract. LIF is used for the in vitro maintenance of the pluripotential phenotype of embryonic stem cells. In an effort to understand why LIF improves the ability of cultured neural crest cells to support normal heart development, we have examined the relationship of neural crest expression of HNK-1 antigen, alpha-smooth muscle actin, and neurofilament protein in neural crest cells cultured in LIF. LIF treatment resulted in an expanded period of expression of HNK-1 antigen, associated with a decrease in expression of alpha-smooth muscle actin.(ABSTRACT TRUNCATED AT 400 WORDS)