Changes in the pericellular matrix during differentiation of limb bud mesoderm

Mesodermal cells in the developing chick embryo limb bud appear morphologically homogeneous until stage 21. At stage 22 the prechondrogenic and premyogenic areas begin to condense, culminating in the appearance of cartilage and muscle by stage 25-26. We have examined changes in the hyaluronate-dependent pericellular matrices elaborated by mesodermal cells of the limb bud from different developmental stages and the corresponding changes in production of cell surface-associated and secreted glycosaminoglycans. When placed in culture, most early mesodermal cells (stage 17 lateral plate and stage 19 limb bud) exhibited pericellular coats as visualized by the exclusion of particles. These coats were removed by treatment of the cultures with Streptomyces hyaluronidase. Cells from stage 20-21 limb buds (precondensation) had smaller coats, whereas cells derived from stage 22, 24, and 26 limb buds (condensed chondrogenic and myogenic regions) lacked coats. However, coats were reformed during subsequent cytodifferentiation of chondrocytes; chondrocytes from stage 28 and 30 limb buds, and more mature chondrocytes from stage 38 tibiae, had pericellular coats. Thus, cytodifferentiation of cartilage is accompanied by extensive intercellular matrix accumulation in vivo and reacquisition of pericellular coats in vitro. Although their structure was still dependent on hyaluronate, chondrocyte coats were associated with increased proteoglycan content compared to the coats of early mesodermal cells. The amount of incorporation of [3H]acetate into cell surface hyaluronate remained relatively constant from stages 17 to 38, whereas in the medium compartment, incorporation into hyaluronate was more than 4-fold greater by stage 17 and 19 mesodermal cells than by cells from stages between 20 and 38. However, there was a progressive increase in incorporation into cell surface and medium chondroitin sulfate throughout these developmental stages. Thus, at the time of cellular condensation in the limb bud in vivo, we have observed a reduction in size of hyaluronate-dependent pericellular coats and a dramatic change in the relative proportion of hyaluronate and chondroitin sulfate produced by the mesodermal cells in vitro.     

Thalidomide induces limb anomalies by PTEN stabilization, Akt suppression, and stimulation of caspase-dependent cell death

Thalidomide, a drug used for the treatment of multiple myeloma and inflammatory diseases, is also a teratogen that causes birth defects, such as limb truncations and microphthalmia, in humans. Thalidomide-induced limb truncations result from increased cell death during embryonic limb development and consequential disturbance of limb outgrowth. Here we demonstrate in primary human embryonic cells and in the chicken embryo that thalidomide-induced signaling through bone morphogenetic proteins (Bmps) protects active PTEN from proteasomal degradation, resulting in suppression of Akt signaling. As a consequence, caspase-dependent cell death is stimulated by the intrinsic and Fas death receptor apoptotic pathway. Most importantly, thalidomide-induced limb deformities and microphthalmia in chicken embryos could be rescued by a pharmacological PTEN inhibitor as well as by insulin, a stimulant of Akt signaling. We therefore conclude that perturbation of PTEN/Akt signaling and stimulation of caspase activity is central to the teratogenic effects of thalidomide.     

The in vitro maintenance of the apical ectodermal ridge of the chick embryo wing bud: an assay for polarizing activity.

We have devised an in vitro bioassay for limb bud polarizing activity in the chick embryo. This assay has proven to be a relatively quick and effective test for a morphogenetic factor asymmetrically distributed in the limb bud which is capable of maintaining or thickening the apical ectodermal ridge.A small section of the preaxial border of the chick embryo wing bud was cultured alone, with tissue from the posterior border, mid-dorsal or anterior corner of a second donor wing, or from the flank. The tissue from the preaxial border (responding tissue) consisted of mesoderm with overlying ectoderm and apical ectodermal ridge. When the responding tissue was cultured alone, with flank, or with anterior corner limb tissue, the apical ectodermal ridge flattened in 24–36 hr and many macrophages appeared in the underlying mesoderm. When cultured with posterior border limb tissue however, the apical ridge of the responding tissue remained thickened for up to 48 hr., and no macrophages appear in the underlying mesoderm. The behavior of responding tissue was intermediate between these two extremes when cultured with mid-dorsal limb tissue. The morphogenetic activity assayed by this procedure thus seems to be present as a gradient in the wing bud, with activity decreasing from posterior to anterior. Contact with the responding tissue is not required to enable posterior border tissue to elicit ridge thickening and inhibit the cell death.     

Separate effects of exogenous hyaluronic acid on proteoglycan synthesis and deposition in pericellular matrix by cultured chick embryo limb chondrocytes

The effects of exogenous hyaluronic acid on cell cultures of chick embryo limb chondrocytes are reported in this paper. The evidence shows that exogenous hyaluronic acid (HA) can both depress the incorporation of ³⁵SO₄ into glycosaminoglycans and cause a displacement of newly synthesized proteoglycan from the cell layer to the culture medium. The results demonstrate that these two effects are mediated by distinct mechanisms. The displacement effect has a rapid onset (by 2 hr) while the effect of exogenous HA on ³⁵SO₄ incorporation has a long latency (12 hr). The displacement effect is produced by a lower concentration (5 μg/ml) of hyaluronate oligomers than the effect on ³⁵SO₄ incorporation (50 μg/ml). In addition, displacement is produced only by hyaluronate oligomers that are decasaccharides or larger. The depression of ³⁵SO₄ incorporation is produced by tetrasaccharides as well as high molecular weight HA. In fact tetrasaccharides can depress ³⁵SO₄ incorporation without causing the displacement effect.     

Mechanics of head fold formation: investigating tissue-level forces during early development

During its earliest stages, the avian embryo is approximately planar. Through a complex series of folds, this flat geometry is transformed into the intricate three-dimensional structure of the developing organism. Formation of the head fold (HF) is the first step in this cascading sequence of out-of-plane tissue folds. The HF establishes the anterior extent of the embryo and initiates heart, foregut and brain development. Here, we use a combination of computational modeling and experiments to determine the physical forces that drive HF formation. Using chick embryos cultured ex ovo, we measured: (1) changes in tissue morphology in living embryos using optical coherence tomography (OCT); (2) morphogenetic strains (deformations) through the tracking of tissue labels; and (3) regional tissue stresses using changes in the geometry of circular wounds punched through the blastoderm. To determine the physical mechanisms that generate the HF, we created a three-dimensional computational model of the early embryo, consisting of pseudoelastic plates representing the blastoderm and vitelline membrane. Based on previous experimental findings, we simulated the following morphogenetic mechanisms: (1) convergent extension in the neural plate (NP); (2) cell wedging along the anterior NP border; and (3) autonomous in-plane deformations outside the NP. Our numerical predictions agree relatively well with the observed morphology, as well as with our measured stress and strain distributions. The model also predicts the abnormal tissue geometries produced when development is mechanically perturbed. Taken together, the results suggest that the proposed morphogenetic mechanisms provide the main tissue-level forces that drive HF formation.     

The enhancement of in vitro survival and chondrogenesis of limb bud cells by cartilage conditioned medium

Dissociated stage 21–28 chick embryo limb bud cells showed an increasing ability to produce cartilage colonies in vitro with in vivo maturation. In addition dissociated stage 21–28 chick embryo limb bud cells exposed to cartilage conditioned medium continuously or only for 48 hr prior to subculture showed an enhanced (as much as 15-fold) ability to form differentiated cartilage colonies. By this criterion, cells were more responsive to conditioned medium prior to stage 25. Conditioned medium from fibroblast cultures caused an inhibition of cartilage colony formation, suggesting that the effect is cell-type specific. Besides increasing cartilage colony formation by enhanced cell survival, the incorporation of S³⁵O₄ into isolated glycosaminoglycans is also stimulated when limb bud cells are exposed to cartilage conditioned medium. The results support a model for cell differentiation which involves the enhancement of a particular differentiated capacity by a diffusible cell-type-specific macromolecule.     

Inductive activity of recombinant human growth and differentiation factor-5

Growth and differentiation factor-5 (GDF-5) is a divergent member of the transforming growth factor-beta/bone morphogenetic protein (BMP) superfamily that is required for proper skeletal patterning and development in the vertebrate limb. Based on the homology of GDF-5 with other bone-inducing BMP family members, the inductive activity of a recombinant form of human GDF-5 (rhGDF-5) was evaluated in a series of in vitro assays and in vivo bone-formation models. The in vitro response to rhGDF-5 resulted in the formation of chondrogenic nodules in fetal rat calvarial cells cultured in the context of collagen or collagen/hyaluronate extracellular matrices. Matrices loaded with rhGDF-5 induced ectopic cartilaginous and osseous tissue when implanted in subcutaneous or intramuscular sites. In non-human primate long-bone-defect and spinal-fusion models, rhGDF-5 combined with a mineralized collagen matrix induced bone formation in a manner equivalent to autogenous bone. These results highlight the unique potential of rhGDF-5 in a wide variety of orthopaedic applications.     

Glycoconjugate synthesis during early pregnancy: hyaluronate synthesis and function

The synthesis of various glycoconjugate classes by mouse uteri during the pre- and peri-implantation period has been examined using [3H]glucosamine as a metabolic precursor. A unique and dramatic (five- to sixfold) increase was observed in the synthesis of hyaluronate on the day upon which embryo implantation normally occurs. Mated, but nonpregnant mice did not display increased hyaluronate biosynthesis. In contrast to hyaluronate, the synthesis of most other types of glycoconjugates remained fairly constant during the first 5 days of pregnancy. Low (1500-5000)-molecular-weight N-linked oligosaccharides constituted the major class of oligosaccharides synthesized under all conditions. High (greater than 10,000)-molecular-weight glycoconjugates constituted the second most abundant class of glycoconjugates synthesized (20-30%). Most (85%) of the newly synthesized hyaluronate was associated with the nonepithelial cell types of the uterus. Experiments using ovariectomized mice receiving steroid hormones demonstrated that uterine hyaluronate synthesis was induced preferentially by an artificial decidual stimulus and implicated stromal cells as the site of hyaluronate synthesis. In addition, it was demonstrated that tissue culture plates coated with hyaluronate, but not other polysaccharides, support attachment and spreading of a large fraction (60 to 70%) of embryos cultured in serum-free medium. Collectively, these studies indicate that increased hyaluronate biosynthesis accompanies decidual responses in the endometrium and may promote embryo implantation following initial penetration of the uterine epithelium.     

An in vitro Analogue of Early Chick Limb Bud Outgrowth

Our culture system appears to represent an in vitro analogue of early chick limb morphogenesis. Organized mesodermal cell accumulations resembling limb buds were derived from a monolayer of limb mesoderm cells when covered by limb ectoderm which included the apical ectodermal ridge (AER). The ridge retained its normal configuration when grown over a limb mesoderm monolayer and the mesoderm cells accumulated under the ridge to form a multilayered structure (10–25 cells in thickness) with the characteristic shape of a limb bud. Ectoderm which did not include the ridge failed to promote the formation of limb-like mesodermal accumulations thus the action of the ridge appears to be specific. The AER-elicited expression of mesodermal cell behaviour leading to early limb outgrowth is discussed in terms of possible morphogenetic mechanisms involved i.e. differential mitosis, cell migration, changes in cell shape and especially the adhesive properties of the cells.     

Tunicamycin-induced alterations in the synthesis of sulfated proteoglycans and cell surface morphology in the chick embryo fibroblast

The effect of tunicamycin (TM) on the synthesis and secretion of sulfated proteoglycans and hyaluronate was examined in chick embryo fibroblasts and chondrocytes. The incorporation of the precursors [³H]glucosamine, [³H]mannose and [³⁵S]sulfate into glycoconjugates in both the cell layer and medium of cultures was determined. In the chick embryo fibroblast, but not in the chondrocyte, synthesis of sulfated proteoglycan was inhibited 60–75% by TM (5 × 10⁻⁸ M), while synthesis of hyaluronate and protein was only inhibited slightly. The inhibition of sulfate incorporation into glycosaminoglycans of the chick embryo fibroblast was overcome to a great extent by addition of β-xyloside, which provides an exogenous initiator for chondroitin sulfate synthesis. TM treatment also altered cell shape and surface morphology in chick embryo fibroblasts, as observed by phase contrast and scanning electron microscopy (SEM). Cells treated with TM became rounded, and increased numbers of microvilli and blebs appeared on the cell surface. These alterations in cell morphology were reversed by removal of TM, but not by exogenous addition of xyloside, chondroitin sulfate or the adhesive cell surface glycoprotein fibronectin. These results demonstrate that TM inhibits synthesis of sulfated proteoglycans in the chick embryo fibroblast and causes a dramatic alteration in cell shape and surface morphology.     

Essential mesenchymal role of small GTPase Rac1 in interdigital programmed cell death during limb development

Developing vertebrate limbs are often utilized as a model for studying pattern formation and morphogenetic cell death. Herein, we report that conditional deletion of Rac1, a member of the Rho family of proteins, in mouse limb bud mesenchyme led to skeletal deformities in the autopod and soft tissue syndactyly, with the latter caused by a complete absence of interdigital programmed cell death. Furthermore, the lack of interdigital programmed cell death and associated syndactyly was related to down-regulated gene expression of Bmp2, Bmp7, Msx1, and Msx2, which are known to promote apoptosis in the interdigital mesenchyme. Our findings from Rac1 conditional mutants indicate crucial roles for Rac1 in limb bud morphogenesis, especially interdigital programmed cell death.     

Analysis of four maize mutants arrested in early embryogenesis reveals an irregular pattern of cell division

The process that leads to embryo formation appears to follow a defined pattern, whose sequential developmental steps—under strict genetic control—can be analysed through the study of mutants affecting embryogenesis. We present the analysis of four embryo-specific (emb) mutants of maize, characterised by abnormal development not overcoming the proembryo or early transition stage, that define three separate genes on the basis of their chromosomal location and complementation pattern. A common feature emerging from histological analysis is that suppression of morphogenesis is accompanied by an uncontrolled pattern of cell division. The block in embryo development is associated with abnormal suspensor proliferation, possibly due to the absence of a signal elaborated by the embryo proper and required for suspensor cell identity maintenance. Mutant endosperm morphogenesis is not impaired, as shown by the formation of the expected domains, i.e. aleurone, starchy endosperm, embryo-surrounding region and basal endosperm transfer layer. The program of cell death appears impaired in the mutants, as expected if this process is essential in determining the shape and morphology of the developing organs. An unexpected result is obtained when mutant embryo rescue is attempted. Immature embryos transferred to a basal medium germinated, yielding small but otherwise normal seedlings, an observation not consistent with the histological evidence of a complete absence of morphogenetic potential. The analysis of emb mutants appears a promising tool to elucidate crucial points of embryo development such as the coupling of cell division with morphogenesis, cell-to-cell interactions, the relationship between embryo and endosperm development, and the interaction between embryo proper and suspensor.     

Epithelial-mesenchymal interaction in the regulation of hyaluronate production during limb development

Cocultures of ectoderm and mesoderm from chick limb buds produced 1.5 to 2.5-fold more hyaluronate than the sum of that produced by epithelium and mesoderm cultures grown separately. Mesoderm incubated with conditioned medium prepared from cultures of limb ectoderm synthesized 2.5-fold more hyaluronate. The increase in hyaluronate was not due to a stimulation of cell proliferation, nor was there increased incorporation into total protein or chondroitin sulfate. These results suggest that in the developing limb the ectoderm may influence the subjacent mesoderm to maintain a relatively high rate of hyaluronate synthesis, resulting in a peripheral limb bud matrix enriched in hyaluronate.     

Vascular morphogenesis in the zebrafish embryo

During embryonic development, the vertebrate vasculature is undergoing vast growth and remodeling. Blood vessels can be formed by a wide spectrum of different morphogenetic mechanisms, such as budding, cord hollowing, cell hollowing, cell wrapping and intussusception. Here, we describe the vascular morphogenesis that occurs in the early zebrafish embryo. We discuss the diversity of morphogenetic mechanisms that contribute to vessel assembly, angiogenic sprouting and tube formation in different blood vessels and how some of these complex cell behaviors are regulated by molecular pathways.     

Analysis of Cyp26b1/Rarg compound-null mice reveals two genetically separable effects of retinoic acid on limb outgrowth

The role of retinoic acid (RA) in limb development is unclear, although it has been suggested to be a proximalizing factor which plays a morphogenetic role in pattern formation. Exogenous RA produces a teratogenic effect on limb morphology; similarly, changes in the endogenous distribution of RA following genetic ablation of the RA-metabolizing enzyme, CYP26B1, result in phocomelia accompanied by changes in expression of proximo-distal (P-D) patterning genes, increased cell death, and delayed chondrocyte maturation. Here we show that disruption of RA receptor (RAR) gamma in a Cyp26b1^−/− background is able to partially rescue limb skeletal morphology without restoring normal expression of proximo-distal patterning genes. We further show that embryos deficient in CYP26B1 exhibit early localized domains of mesenchymal cell death, which are reduced in compound-null animals. This model reveals two genetically separable effects of RA in the limb: an apoptotic effect mediated by RARγ in the presence of ectopic RA, and a P-D patterning defect which is uncovered following the loss of both CYP26B1 and RARγ. These data provide genetic evidence to clarify the roles of both RA and CYP26B1 in limb outgrowth and proximo-distal patterning.     

BMP1 controls TGFbeta1 activation via cleavage of latent TGFbeta-binding protein

Transforming growth factor beta1 (TGFbeta1), an important regulator of cell behavior, is secreted as a large latent complex (LLC) in which it is bound to its cleaved prodomain (latency-associated peptide [LAP]) and, via LAP, to latent TGFbeta-binding proteins (LTBPs). The latter target LLCs to the extracellular matrix (ECM). Bone morphogenetic protein 1 (BMP1)-like metalloproteinases play key roles in ECM formation, by converting precursors into mature functional proteins, and in morphogenetic patterning, by cleaving the antagonist Chordin to activate BMP2/4. We provide in vitro and in vivo evidence that BMP1 cleaves LTBP1 at two specific sites, thus liberating LLC from ECM and resulting in consequent activation of TGFbeta1 via cleavage of LAP by non-BMP1-like proteinases. In mouse embryo fibroblasts, LAP cleavage is shown to be predominantly matrix metalloproteinase 2 dependent. TGFbeta1 is a potent inducer of ECM formation and of BMP1 expression. Thus, a role for BMP1-like proteinases in TGFbeta1 activation completes a novel fast-forward loop in vertebrate tissue remodeling.