Sulphonated phthalocyanine induced caudal malformative syndrome in the chick embryo

Sulphonated phthalocyanine (Pht.) has been tested for its possible noxious effect on the developing chick embryo. When injected into the subembryonic cavity of 40-45 hours incubated chick embryos (mainly 10-20 somite pairs), Pht. induces a highly reproducible caudal malformative syndrome (trunk and taillessness, various anomalies of the limbs). The main effect is--in about 15% of the malformed specimens--associated with unilateral microphthalmy and, less frequently, with coelosomy. Microscopically developmental disturbances of the caudal axial organs, of the mesonephros and of the limbs are observed. The initial pathological changes, at microscopic level, are necrosis and hemorrhages in the caudal axial and paraxial area. The allantois is poorly developed or even absent. Skeletal changes involve anomalies of the ribs and of the vertebral column and total or partial absence of the pelvic girdle bones. The high mortality, mainly during the first week, is due--first of all--to the developmental disturbances including the poor development or absence of the allantois. Control experiments with CuCl2 suggest the ethiological role of Cu. Pathogenetic aspects are discussed.     

Hemodynamic effects of acetylcholine in the chick embryo and differences from those in the rat embryo

It has been reported that acetylcholine induces cardiac anomalies in the chick embryo. Thus, we studied hemodynamic effects of this drug in the chick embryo and also compared them with those in the rat embryo since we found that the effect of caffeine was different between the chick and rat embryos. Acetylcholine was given at doses of 5, 0.5, and 0.05 micrograms into the vitelline vein in chick embryos at Hamburger-Hamilton stage 21 and at a dose of 0.5 micrograms into the placenta in rat embryos at gestational day 12. In the chick embryo, heart rate was reduced to 91, 88, and 87% of control at the end of injection of 0.05, 0.5, and 5 micrograms, respectively, then returned to the baseline level. Vitelline arterial blood pressure was 110% of control with 0.05 micrograms, 134% with 0.5 micrograms, and 142% with 5 micrograms at 1 min after injection. The dorsal aortic blood flow decreased with time after injection, but it was increased only by a 5 micrograms dose at the end of injection. The vascular resistance increased in a dose-dependent manner. In the rat embryo, the change of heart rate was qualitatively similar to that of the chick embryo. The blood pressure did not change significantly. The blood flow velocity at the outflow tract decreased at the end of injection, which indicated the decrease in cardiac output, along with slowing of heart rate, then returned to the control level thereafter.(ABSTRACT TRUNCATED AT 250 WORDS)     

A survey of differences between membrane polypeptides of transformed and nontransformed chick embryo fibroblasts

Plasma membrane-associated polypeptides of chick embryo fibroblasts and cells transformed by the Schmidt-Ruppin wild-type strain of Rous sarcoma virus and its temperature-sensitive tsNY68 mutant were compared by two-dimensional gel electrophoresis. Polypeptide and glycoprotein alterations were identified after incubation of cells with [35S]methionine and [3H]mannose and by staining of the gels with 125I-labeled concanavalin A and Coomassie brilliant blue. Polypeptides found to be consistently transformation-sensitive included a group of five polypeptides that were detected only by short-term labeling with methionine, fibronectin, a 180 kDa polypeptide with a pI of 5.6, a mannose-containing glycoprotein of 48 kDA and an unusually high pI of 8.4, and a 19 kDa polypeptide with a pI of approx. 4.5. Several of these polypeptides appear to be particularly interesting for further characterization.     

Molecular cloning and early expression of chick embryo SCO-spondin

SCO-spondin is a multidomain glycoprotein secreted by the subcommissural organ (SCO). It belongs to the thrombospondin type 1 repeat superfamily and has been identified in several vertebrate species. We report the cloning of the chick SCO-spondin ortholog and examine its temporal and spatial expression during early embryogenesis from Hamburger and Hamilton (HH) stage 12 to HH stage 21. Chick SCO-spondin cDNA contains a long open reading frame encoding a predicted protein of 5255 amino acids. Northern blot analysis has revealed SCO-spondin mRNA as a band of about 15 kb. Many conserved domains have been identified, including 27 thrombospondin type 1 repeats, 13 low-density lipoprotein receptor type A domains, one EMI domain (a cysteine-rich domain of extracellular proteins), three von Willebrand factor type D domains, and one cystine knot C-terminal domain. Whole-mount in situ hybridization enabled the first signal of mRNA expression to be detected at HH stage 17, exclusively in a thin area of the prosencephalon roof plate. During the following stages of development, SCO-spondin expression remained restricted to this region. The multidomain structure of SCO-spondin and its early expression suggest that it plays a role in developmental processes in the central nervous system.     

The rostral level of origin of sympathetic neurons in the chick embryo, studied in tissue culture.

Groups of three consecutive somites from the first to the eleventh somite from chick embryos of stages 17-18 were grown in tissue culture for seven days. Sympathetic neurons, identified both by phase contrast microscopy and FIF histochemistry, occurred only in cultures which included the sixth, or more caudal, somites. If it is assumed that sympathetic precursor cells (neural crest cells) have not undergone a caudal shift prior to stages 17-18, and taking into account the loss of one or two rostral somites, then the anterior sympathetic ganglia are derived from neural crest caudal to the sixth or seventh somite. Thus, the vagal zone (level with somites 1-7) contributes little to the sympathetic nervous system.     

Molecular characterization of the rostral-most somites in early somitic stages of the chick embryo

Segmentation consists on the progressive formation of repetitive embryonic structures, named somites, which are formed from the most rostral part of the presomitic mesoderm. Somites are subdivided into anterior and posterior compartments and several genes are differentially expressed in either compartment. This has provided evidence for the importance of establishing the anterior-posterior polarity within each somite, which is critical for the correct segmented pattern of the adult vertebrate body. Although all somites appear morphologically similar, fate map studies have shown that the first 4 somites do not give rise to segmented structures, in contrast to more posterior ones. Moreover, in several somitogenesis-related mutants the anterior somites are not affected while posterior somites present clear defects or do not form at all. Altogether these data suggest relevant differences between rostral and caudal somites. In order to check for molecular differences between anterior and posterior somites, we have performed a detailed expression pattern analysis of several Notch signalling related genes. For the first time, we show that the somitic expression pattern profile is not the same along the anterior-posterior axis and that the differences are not observed always at the same somite level.     

Different clonal dispersion in the rostral and caudal mouse central nervous system

We have performed a systematic clonal analysis to describe the modes of growth, dispersion and production of cells during the development of the mouse neural system. We have used mice expressing a LaacZ reporter gene under the control of the neuron specific enolase promoter to randomly generate LacZ clones in the central nervous system (CNS). We present evidence for (1) a pool of CNS founder cells that is not regionalized, i.e. give descendants dispersed along the entire A-P axis, (2) an early separation between pools of precursors for the anterior and posterior CNS and (3) distinct modes of production of progenitors in these two domains. More specifically, cell growth and dispersion of the progenitors follow a relatively coherent pattern throughout the anterior CNS, a mode that leads to a progressive regionalization of cell fates. In contrast, cell growth of progenitors of the SC appears to involve self-renewing stem cells that progress caudally during regression of the mode. Therefore, at least part of the area surrounding the node is composed of precursors with self-renewing properties and the development of the trunk is dependent on pools of stem cells regressing from A to P. Taken together with our analysis of the cell growth changes associated with neuromere formation (Mathis, L., Sieur, J., Voiculescu, O., Charnay, P. and Nicolas, J. F. (1999) Development 126, 4095-4106), our results suggest that major transitions in CNS development correspond to changes in cell behavior and may provide a link between morphogenesis and genetic patterning mechanisms (i.e. formation of the body plan).     

Molecular characterization and developmental expression of the aryl hydrocarbon receptor from the chick embryo

The aryl hydrocarbon receptor (AhR) was cloned from the chick embryo and its function and developmental expression characterized. Chicken AhR cDNA coded for 858 amino acid protein and 396 bp of 3' UTR. The basic helix loop helix domain exhibited 87-100% amino acid identity to avian, mammalian, and amphibian AhR, and 69-74% to piscine AhR. The PAS (Per-ARNT-Sim) region was slightly less well conserved with (a) 97% identity to other avian sequences, (b) 81-86% to amphibian and mammalian AhR, and (c) 64-69% with piscine AhR. The carboxy terminus diverged the most among species with less than 53% amino acid identity between chicken and any available mammalian and piscine AhR sequences. The chicken AhR RNA and protein were 6.1 kb and 103 kDa, respectively. Chicken AhR dimerized with human AhR nuclear translocator and bound the mammalian dioxin-response element in a ligand-dependent manner. AhR protein was detected in neural ganglia; smooth, cardiac, and skeletal muscle; and epithelium involved in epithelial-to-mesenchymal transformations, such as pituitary, gastrointestinal tract, limb apical-ectodermal ridge, and kidney collecting ducts. AhR mRNA was detected in all tissues expressing protein, except myocardium. Cytochrome P4501A4 mRNA was highly induced by 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) in a subset of tissues expressing AhR, including small intestine, liver, kidney, blood vessels, and outflow tract myocardium. In conclusion, the AhR sequence and function is highly conserved between birds and mammals, and although many tissues express AhR during chick embryo development, only a subset are responsive to TCDD induction of CYP1A4.     

Molecular cloning and developmental expression of two chick embryo gap junction proteins

The connexins are a family of related gap junction proteins which contain conserved transmembrane and extracellular domains but unique cytoplasmic regions. To identify connexins with potential roles in development, a chick embryo cDNA library was screened by hybridization at low stringency with a cDNA for rat connexin-43. cDNA clones for two previously undescribed connexins were isolated. Chick connexin-45 has a predicted molecular mass of 45,376 daltons; connexin-42 has a predicted molecular mass of 41,748 daltons. Both of these predicted connexin proteins share the homologous regions noted in other members of this family, and each has its own unique regions. Southern blots of chicken genomic DNA suggest that each connexin is encoded by a distinct single copy gene. RNA blots demonstrate that while chick connexin-43, -42, and -45 are each expressed in a number of chick organs, they each have a unique tissue distribution. Each connexin mRNA is present in heart. Blots of total RNA isolated from hearts of chick embryos of different ages demonstrate that the abundance of connexin-42 and -43 mRNAs varies no more than 2-fold between the embryo and the adult. However, connexin-45 mRNA shows a dramatic change, falling 10-fold from the 6-day embryonic heart to the adult. These multiple connexins are likely to have different physiological properties and may account for the multiple physiologically distinct gap junction channels which have been observed in cardiac myocytes. They may provide a mechanism for the formation of communication compartments in the developing myocardium.