Role of the chicken homeobox-containing genes GHox-4.6 and GHox-8 in the specification of positional identities during the development of normal and polydactylous chick limb buds.

During early stages of normal chick limb development, the homeobox-containing (HOX) gene GHox-4.6 is expressed throughout the posterior mesoderm of the wing bud from which most of the skeletal elements including the digits will develop, whereas GHox-8 is expressed in the anterior limb bud mesoderm which will not give rise to skeletal elements. In the present study, we have examined the expression of GHox-4.6 and GHox-8 in the wing buds of two polydactylous mutant chick embryos, diplopodia-5 and talpid2, from which supernumerary digits develop from anterior limb mesoderm, and have also examined the expression of these genes in response to polarizing zone grafts and retinoic acid-coated bead implants which induce the formation of supernumerary digits from anterior limb mesoderm. We have found that the formation of supernumerary digits from the anterior mesoderm in mutant and experimentally induced polydactylous limb buds is preceded by the ectopic expression of GHox-4.6 in the anterior mesoderm and the coincident suppression of GHox-8 expression in the anterior mesoderm. These observations suggest that the anterior mesoderm of the polydactylous limb buds is "posteriorized" and support the suggestion that GHox-8 and GHox-4.6, respectively, are involved in specifying the anterior non-skeletal and posterior digit-forming regions of the limb bud. Although the anterior mesodermal domain of GHox-8 expression is severely impaired in the mutant and experimentally induced polydactylous limb buds, this gene is expressed by the prolonged, thickened apical ectodermal ridges of the polydactylous limb buds that extend along the distal anterior as well as the distal posterior mesoderm.(ABSTRACT TRUNCATED AT 250 WORDS)     

Altered expression of the chicken homeobox-containing genes GHox-7 and GHox-8 in the limb buds of limbless mutant chick embryos.

It has been suggested that the reciprocal expression of the chicken homeobox-containing genes GHox-8 and GHox-7 by the apical ectodermal ridge and subjacent limb mesoderm might be involved in regulating the proximodistal outgrowth of the developing chick limb bud. In the present study the expression of GHox-7 and GHox-8 has been examined by in situ and dot blot hybridization in the developing limb buds of limbless mutant chick embryos. The limb buds of homozygous mutant limbless embryos form at the proper time in development (stage 17/18), but never develop an apical ectodermal ridge, fail to undergo normal elongation, and eventually degenerate. At stage 18, which is shortly following the formation of the limb bud, the expression of GHox-7 is considerably reduced (about 3-fold lower) in the mesoderm of limbless mutant limb buds compared to normal limb bud mesoderm. By stages 20 and 21, as the limb buds of limbless embryos cease outgrowth, GHox-7 expression in limbless mesoderm declines to very low levels, whereas GHox-7 expression increases in the mesoderm of normal limb buds which are undergoing outgrowth. In contrast to GHox-7, expression of GHox-8 in limbless mesoderm at stage 18 is quantitatively similar to its expression in normal limb bud mesoderm, and in limbless and normal mesoderm GHox-8 expression is highly localized in the anterior mesoderm of the limb bud. In normal limb buds, GHox-8 is also expressed in high amounts by the apical ectodermal ridge.(ABSTRACT TRUNCATED AT 250 WORDS)     

Expression of the Dan gene during chicken embryonic development.

The Dan gene was first identified as the putative rat tumor suppressor gene and encodes a protein structurally related to Cerberus and Gremlin in vertebrates. Xenopus DAN, as with Cerberus and Gremlin, was demonstrated to block bone morphogenetic protein (BMP) signaling by binding BMPs, and to be capable of inducing additional anterior structures by ectopic overexpression in Xenopus embryos. DAN, thus, is suggested to play pivotal roles in early patterning and subsequent organ development, as in the case of other BMP antagonists. In this report, we isolated the chicken counterpart of Dan. Chicken Dan is mainly expressed in the cephalic and somitic mesoderm and several placodes during organ development.     

Expression of the chick vascular endothelial growth factor D gene during limb development

Vascular endothelial growth factor D (VEGF-D) is a member of the VEGF/PDGF superfamily that has been implicated in angiogenesis and lymphangiogenesis. We have isolated a chick cDNA that shows homology with VEGF-D (also known as FIGF, c-fos-induced growth factor) of other species. Here, we describe the expression pattern of cVegf-D in chick embryos. In the limb buds, cVegf-D shows a dynamic expression pattern that is restricted to the mesenchyme of the posterior region. cVegf-D expression is also detected in the ectoderm and mesenchyme of the head region, somites, notochord and pharyngeal arches. We also report on the capability of Sonic hedgehog and retinoic acid to regulate cVegf-D expression.     

Subepithelial type II collagen deposition during embryonic chick limb development

Summary Type II collagen is a major component of hyaline cartilage but recent studies have demonstrated the presence of this protein in a variety of interfaces that separate epithelia from mesenchyme, particularly in early stages of embryonic chick development. In the present study an immunohistochemical analysis of the distribution of type II collagen was performed on closely staged wing buds of early chick embryo. This report describes how using two different monoclonal antibodies against type II collagen and the peroxidase or fluorescence staining technique reveals that deposition of type II collagen at the ectoderm-mesenchyme interface occurs in the proximal part of the limb coincidentally with the appearance of this protein in the proximal core region, where chondrogenesis begins (stage 25). Then the staining in the subepithelial region spreads distallly with time, following the progression of the formation of cartilage rudiments. At about 7 days of development type II collagen is present under the apical ectoderm ridge and surrounds completely the wing bud underneath the epithelium. At the same time, another antibody directed against the cartilage-specific proteoglycan core protein only stains the chondrogenic central core of the limb and not the subepithelium. Although type II collagen and cartilage-specific proteoglycan are closely associated in the cartilage, the observations presented here suggest that the deposition of these proteins can be regulated independently during limb formation. The role of type II collagen at the epithelium-mesenchyme interface during limb formation is still to be determined.     

The expression pattern of the chicken homeobox-containing gene GHox-7 in developing polydactylous limb buds suggests its involvement in apical ectodermal ridge-directed outgrowth of limb mesoderm and in programmed cell death

Abstract. The limb buds of the polydactylous mutant embryos, talpid ² and diplopodia -5, possess expanded distal apexes surmounted by prolongated thickened apical ectodermal ridges that promote the outgrowth and formation of digits from both the anterior and posterior mesoderm of the mutant limb buds. The chicken homeobox-containing gene GHox-7 exhibits an expanded domain of expression throughout the expanded subridge mesoderm of the mutant limb buds, providing support for the hypothesis that GHox-7 expression by subridge mesenchymal cells is involved in the outgrowth-promoting effect of the apical ectodermal ridge. During normal limb development GHox-7 is also expressed by the mesoderm in the proximal anterior nonchondrogenic periphery of the limb bud, which includes, but is not limited to the anterior necrotic zone. GHox-7 is also expressed in the posterior necrotic zone at the mid-proximal posterior edge of the limb bud. In contrast, GHox-7 is not expressed in either the proximal anterior or posterior peripheral mesoderm of talpid ² and diplopodia -5 limb buds which lack proximal anterior and posterior necrotic zones. Furthermore, retinoic acid-coated bead implants, which diminish cell death in the anterior necrotic zone, elicit a local inhibition of GHox-7 expression in the proximal anterior peripheral mesoderm. These results support the suggestion that GHox-7 may be involved in defining regions of programmed cell death during limb development. Furthermore, these studies indicate that the distal subridge and proximal anterior nonchondrogenic mesodermal domains of GHox-7 expression are independently regulated.     

Temporal and spatial transitions in collagen types during embryonic chick limb development

To determine whether transitions occur in the types of collagen synthesized during embryonic chick limb development, the α chain composition of the collagens produced by whole limbs and various anatomical regions of limbs was analyzed at different stages (23–24 to 40). The tissues were incubated in the presence of ³H-proline and ³H-lysine and the α chain distribution of the purified, labeled collagens was determined by chromatography on carboxymethyl cellulose columns. We found that the stage 23–24 leg mesenchyme is producing predominantly, if not solely, an (α1)₂α2 type collagen (chain type as yet undetermined). At about stage 25–26 the limb core begins synthesizing detectable amounts of (α1)₃ collagen, which we presume to be cartilage type collagen, [α1 (II)]₃, while the outer portion of the limb largely continues to produce (α1)₂α2. The production of (α1)₃ collagen in the core progressively increases until, by stage 33 it is the only species detectable in the tibial diaphysis. Shortly thereafter (by stage 35⁺–36) (α1)₂α2 type collagen reappears in the tibial diaphysis signifying the production of bone collagen, [α1 (I)]₂α2. During the next several days of incubation, the relative proportion of (α1)₂α2 increases in the bony diaphysis while (α1)₃ remains the predominant species synthesized in the cartilaginous epiphysis.     

Temporal and spatial analysis of hyaluronidase activity during development of the embryonic chick limb bud

The glycosaminoglycan hyaluronate (HA) appears to play an important role in limb cartilage differentiation. The large amount of extracellular HA accumulated by prechondrogenic mesenchymal cells may prevent the cell-cell and/or cell-matrix interactions necessary to trigger chondrogenesis, and the removal of extracellular HA may be essential to initiate the crucial cellular condensation process that triggers cartilage differentiation. It has generally been assumed that HA turnover during chondrogenesis is controlled by the activity of the enzyme hyaluronidase (HAase). In the present study we have performed a temporal and spatial analysis of HAase activity during the progression of limb development and cartilage differentiation in vivo. We have separated embryonic chick wing buds at several stages of development into well-defined regions along the proximodistal axis in which cells are in different phases of differentiation, and we have examined HAase activity in each region. We have found that HAase activity is clearly detectable in undifferentiated wing buds at stage 18/19, which is shortly following the formation of a morphologically distinct limb bud rudiment, and remains relatively constant throughout subsequent stages of development through stage 27/28, at which time well-differentiated cartilage rudiments are present. Moreover, HAase activity in the prechondrogenic distal subridge regions of the limb at stages 22/23 and 25 is just as high as, or even slightly higher than, it is in proximal central core regions where condensation and cartilage differentiation are progressing. We have also found that limb bud HAase is active between pH 2.2 and 4.5 and is inactive above pH 5.0. This suggests that limb HAase is a lysosomal enzyme and that extracellular HA would have to be internalized to be degraded. These results indicate that the onset of chondrogenesis is not associated with the appearance or increase in activity of HAase. We suggest that possibility that HA turnover may be regulated by the binding and endocytosis of extracellular HA in preparation for its intracellular degradation by lysosomal HAase. Finally, we have found that the apical ectodermal ridge (AER)-containing distal limb bud ectoderm possesses a relatively high HAase activity. We suggest the possibility that a high HAase activity in the AER may ensure a rapid turnover and remodeling of the disorganized HA-rich basal lamina of the AER that might be essential for limb outgrowth.     

Expression pattern of Siaz gene during the zebrafish embryonic development

Siah is a mammalian homolog of Drosophila seven in absentia (SINA). Here we report the identification of a new member of the SINA/Siah gene family. This new gene, designated Siaz, was found in zebrafish, and its product is predicted to share extensive amino acid sequence homology with Drosophila SINA. Siaz is maternally inherited, with zygotic expression in all blastomeres starting at the mid-blastula transition. After the 20-somite stage, Siaz expression occurs in a stage-specific manner in particular regions, including the brain, eye, cranial cavity, otic vesicle, optic chiasm and gut.     

Expression of the acatalytic carbonic anhydrase VIII gene, Car8, during mouse embryonic development

Summary The carbonic anhydrase (CA)-like protein, CA VIII, lacks the typical carbon dioxide hydrase activity of the CA isozymes. However, the high degree of amino acid sequence similarity between the products of the mouse and the human CA VIII genes suggests an important biological function. We have attempted to investigate the function of this gene in mammalian development by conducting an in situ hybridization study on sagittal sections of mouse embryos at gestation days of 9.5–16.5 using a ³⁵S-labelled riboprobe. Results indicate that this gene (called Car8 in mice) is expressed as early as day 9.5 in a variety of organs including liver, branchial arches, neuroepithelium and developing myocardium. Between days 10.5 and 12.5, it showed a widespread distribution of mRNA expression that became more restricted as development progressed. The level of expression of Car8 mRNA was relatively high in the brain, liver, lung, heart, gut, thymus and epithelium covering the head and the oronasal cavity. This revised version was published online in November 2006 with corrections to the Cover Date.     

Differential accumulation of extracellular materials beneath the ectoderm during development of the embryonic chick limb and flank regions.

Chick embryos from stage 10 to 18 were examined by electron microscopy to see if the limb and flank regions of the somatopleure are different. After stage 14, collagen fibrils become detectable in increasing numbers beneath the flank ectoderm but remain scarce in the limb region. Prior to stage 14 no difference could be found in the amounts or organization of extracellular materials beneath the ectoderm of the limb or flank. The accumulation of collagen beneath the flank ectoderm may correlate with the loss of its ability to support limb outgrowth after stage 17 and may be a sign of the progressive differentiation of the flank cells.     

Recombination of embryonic haemoglobin chains during the development of the chick.

Embryonic differentiation is at present interpreted as the expression of variable gene activity. It is commonly thought that derepression of operator gene groups is the main cause of progress during development. However it is equally possible that gene repression plays a role in the appearance of new phenotypic characteristics. This paper illustrates such a possibility. It is known that in chickens embryonic haemoglobins exist which are replaced by other haemoglobins at about the sixth day of incubation. Analyses of globin chain composition of these haemoglobins by chromatography and urea/starch gel electrophoresis as well as TLC-fingerprinting and amino acid analyses of the individual globin chains showed that the haemoglobin switch was not associated with appearance of new globin chains but rather with disappearance of a number of embryonic chains. Moreover the relative proportion of the various chains changed at that time. From these findings we conclude that new haemoglobins arise from a recombination ('hybridization in vivo') of those globin chains which remain after the repression of a gene coding for embryonic chains.