Immunohistochemical study of creatine kinase isozymes in the human upper limb bud

Creatine kinase (CK) is involved in the production of ATP and is composed of two immunologically distinct subunits, B (CK-B) and M (CK-M). In the differentiation of myoblasts, the isozyme of CK changes from CK-B to CK-M. In the present study, the expression of CK subunits was studied immunohistochemically in the upper limb bud of human embryos (Carnegie stages 13-21). It was found that CK-B and CK-M immunoreactive cells appeared at stage 15 and at stage 18, respectively.     

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.     

Experimental manipulation leading to induction of dorsal ectodermal ridges on normal limb buds results in a phenocopy of the eudiplopodia chick mutant

Elongation of chick limb buds depends on the presence of the apical ectodermal ridge which is induced by subjacent limb bud mesoderm. Recombination experiments have shown that the limb bud mesoderm loses the capacity to induce ridges by late stage 17. Moreover, in normal limb development only one ridge forms. However, in the eudiplopodia chick mutant accessory ectodermal ridges form on the dorsal surface of limb buds as late as stage 22. Tissue recombinant experiments show that the mutation affects the ectoderm, extending the time it responds to ridge induction (Fraser and Abbott, 1971a, Fraser and Abbott, 1971b while the mesoderm is normal. The result is polydactyly, with extra digits dorsal to the normal digits. Because eudiplopodia limb bud dorsal mesoderm can induce ridges at stage 22 but is unaffected by the gene, genetically normal dorsal limb bud mesoderm may also be able to induce ridges after stage 17. To test this possibility we grafted stages 14–18 flank ectoderm to normal limb bud dorsal mesoderm and found that mesoderm from stages 17 through 20 was able to induce a ridge and subsequently dorsal digits developed. Limbs with duplicate digits were similar to eudiplopodia limbs. In other experiments, stage 18, 19, and 20 leg bud dorsal ectoderm did not form ridges when grafted to leg bud dorsal mesoderm of the same stage, indicating a lack of response to the mesoderm. Finally, the inductive capacity of limb bud mesoderm appeared to be reduced compared to mesoderm at pre-limb bud stages. These experiments demonstrate a spatially generalized potential in limb bud dorsal mesoderm to induce ridges during the stages when the apical ridge is induced. The determination of where the ridge will form and the acquired inability of limb bud dorsal ectoderm to respond to induction by underlying mesoderm are necessary early pattern forming events which assure that a single proximodistal limb axis will form.     

Chondrogenesis in mouse limb bud in vitro. I. Effect of the ectoderm

The role of the ectoderm in the chondrogenesis of mouse limb bud mesoderm was investigated in vitro at several developmental stages by analysis of the evolution of DNA content, the accumulation of sulfated glycosaminoglycans and histochemical procedures. Young limb buds or the undifferentiated apex of older buds (stages 17 and 19 of Theiler's table) from which the ectoderm had been removed with trypsin treatment initiated a large chondrogenesis but not morphogenesis. When the ectoderm was present, these limb buds showed a polarized proximal to distal outgrowth and differentiated skeletal primordia. Mesodermal cells of stage 20 limb bud apex were able to differentiate autopodial skeletons with or without the presence of the ectoderm: cartilaginous areas of the limb skeleton seem determined at this developmental stage. These results, which show the importance of the ectoderm in limb bud morphogenesis, are compared with results obtained using other methods with mouse or bird buds.     

Temporal pattern of posterior positional identity in mouse limb buds

This study describes the temporal pattern of posterior positional identity in mouse limb bud cells. To do this wedges of tissue from the posterior edge of mouse limb buds at various stages (limb stages: Wanek et al., 1989b. J. Exp. Zool. 249, 41-49) were grafted to the anterior edge of a host chick embryo wing bud. Grafts of mouse posterior cells are able to induce the formation of supernumerary digits every time when they are taken from buds from stage 3 through stage 6. At stage 7, the frequency declines and by stage 8 the chick cells no longer respond. The results indicate a change in tissue properties at stage 7, which progresses by stage 8 to the point at which posterior positional identity is no longer detectable by this assay. These temporal changes in this aspect of limb pattern formation can be used as an additional criterion to guide the identification of genes involved in the specification of posterior positional identity.     

Spatial and temporal patterns of cell death in limb bud mesoderm after apical ectodermal ridge removal

A spatiotemporal pattern of cell death occurred in the chick wing and leg bud mesoderm after removal of apical ectodermal ridge at stages 18–20. Cells died in a region extending from the limb bud distal surface to 150–200 μm into the mesoderm. Limb buds from which ridge was removed at later stages in development did not exhibit a spatiotemporal pattern of cell death. In control experiments in which dorsal ectoderm was removed, a pattern of cell death did not occur. Removal of the ridge and part of the 150- to 200-μm zone of prospective cell death resulted in cell death in an area approximately equal to the amount of the zone remaining. After removal of all of the prospective zone of cell death plus the apical ridge, cell death was observed in the remaining limb bud mesoderm. In these limb buds, cell death occurred in a region in which it had not been seen in limb bud with apical ridge alone removed. We conclude that at stages 18–20 the mesodermal cells 150–200 μm beneath the ridge require the apical ridge to survive. More proximal mesodermal cells do not die after ridge removal alone, but apparently require the presence of the more distal mesoderm to survive. Whether this is a requirement for something intrinsic to the distal mesoderm or something it possesses by way of the ridge is unknown. After stage 23, the limb mesoderm cells do not die when the apical ridge is removed. Nevertheless, at the later stages, ridge continues to be required for limb bud proximal-distal elongation and the differentiation of distal limb elements.     

Retinoids reprogramme pre-bud mesenchyme to give changes in limb pattern

Retinoic acid was locally applied to presumptive limb regions of chick embryos to find out the earliest time at which the limb pattern can be reprogrammed. When beads soaked in retinoic acid were placed in the appropriate positions in embryos at stage 10 or older, duplicated or reduced leg patterns resulted. To pin point the time at which the cells in the limb rudiment respond to the retinoid, beads were removed at various times and the lengths of exposure required to reprogramme limb development found. The early limb rudiments require longer exposures to give duplications than late rudiments. The effective treatment periods last at least until stage 17 when the limb bud and apical ectodermal ridge develop. In contrast, the length of exposure to reduce the limb is constant at early stages. Retinoids first start acting to produce duplicated structures between stages 10 and 13. Therefore, retinoids appear to begin to reprogramme the cells as soon as they are determined to give rise to a limb.     

Onset of troponin synthesis in the chick wing bud.

Indirect antibody labeling techniques were used to determine when cells in the chick embryo wing bud begin to synthesize troponin. Frozen sections of stage 22 through stage 27 wing buds were treated with antibodies to the troponin complex and fluorescein-labeled antiimmunoglobulin. Cells producing detectable quantities of troponin were found first in late stage 24 or early stage 25 wing buds; all wing buds stage 25 and older contained labeled cells. Cells synthesizing troponin were initially localized in the muscle-forming areas of the wing bud nearest to the body wall. As the wing bud developed, cells located in more distal areas of the wing bud became labeled with fluorescent antibody, and the number of cells engaged in troponin synthesis increased in all areas. At all stages in which labeling occurred, some cells contained fluorescent cross-striations. When placed in the context of recent studies on the appearance of myofibrillar proteins, these results indicate that myogenic cells in the chick limb bud begin to synthesize large quantities of troponin at approximately the same time as the other muscle contractile proteins.     

Distribution of retinoids in the chick limb bud: analysis with monoclonal antibody

Retinoic acid induces anteroposterior duplicate formation in developing chick limb bud, and it may be a natural morphogen involved in limb pattern formation. Retinoic acid is produced from retinol locally in the limb bud via retinal, and thus, to elucidate the distribution of these retinoids in the limb bud seems to be important for the understanding of the morphogen formation. We produced a monoclonal antibody against the retinoids with BSA-RA (bovine serum albumin-retinoic acid) conjugate for antigen, and investigated the distribution of retinoids in the chick limb bud. The antibody predominantly bound to retinoic acid, but weakly to retinol and retinal. Retinoids appeared in the limb bud at stage 18 and were distributed through stages 20-24, when the pattern formation in distal mesoderm was in progress. Initially they were found evenly in the whole mesoderm, but disappeared gradually from core mesoderm and remained only in the region of peripheral mesoderm at stage 24. At stage 26, retinoids were detected only in ectoderm. These results support the idea that the retinoids actually play roles in limb pattern formation and suggest that the retinoids in the peripheral mesoderm are important for pattern formation. Further, the role of retinoids in epidermis development at later limb bud stages is also suggested.     

Expression of Cre Recombinase in the developing mouse limb bud driven by a Prxl enhancer

We have used a Prx1 limb enhancer to drive expression of Cre Recombinase in transgenic mice. This regulatory element leads to Cre expression throughout the early limb bud mesenchyme and in a subset of craniofacial mesenchyme. Crossing a murine line carrying this transgene to a reporter mouse harboring a floxed Cre-reporter cassette revealed that recombinase activity is first observed in the earliest limb bud at 9.5 dpc. By early to mid bud stages at 10.5 dpc recombination is essentially complete in all mesenchymal cells in the limb. Expression of the Cre recombinase was never detected in the limb bud ectoderm. The use of Prx1-Cre mice should facilitate analysis of gene function in the developing limb.     

Accelerated maturation of limb mesenchyme by the BrachypodH mouse mutation

Mesenchyme cell populations prepared from proximal and distal halves of stage 20 mouse forelimb buds are shown to behave under in vitro micromass culture conditions like analogous cell populations obtained from chick embryo limb buds. While the distal cells are spontaneously chondrogenic, the proximal cells make aggregates which are only potentially chondrogenic after treatment with dibutyryl cyclic AMP. In addition, stage 20 mouse whole limb bud cells homozygous for the brachypodismH (bpH) mutation are shown to behave similarly to 'normal' proximal cells. Both make fewer aggregates and nodules and both have faster aggregation rates (determined as the rate of disappearance of single cells over time) in rotation cultures than 'normal' distal or whole limb bud cells. These results support the hypothesis that the bpH mutation specifically decreases the proportion of spontaneously chondrogenic mesenchyme cells (that is, distal-like cells) present at certain developmental stages in the limb bud, resulting in a prematurely high proportion of proximal-like cells.     

Accelerated maturation of limb mesenchyme by the BrachypodH mouse mutation

Abstract. Mesenchyme cell populations prepared from proximal and distal halves of stage 20 mouse forelimb buds are shown to behave under in vitro micromass culture conditions like analogous cell populations obtained from chick embryo limb buds. While the distal cells are spontaneously chondrogenic, the proximal cells make aggregates which are only potentially chondrogenic after treatment with dibutyryl cyclic AMP. In addition, stage 20 mouse whole limb bud cells homozygous for the brachypodism^H ( bp ^H ) mutation are shown to behave similarly to 'normal' proximal cells. Both make fewer aggregates and nodules and both have faster aggregation rates (determined as the rate of disappearance of single cells over time) in rotation cultures than 'normal' distal or whole limb bud cells. These results support the hypothesis that the bp ^H mutation specifically decreases the proportion of spontaneously chondrogenic mesenchyme cells (that is, distal-like cells) present at certain developmental stages in the limb bud, resulting in a prematurely high proportion of proximal-like cells.     

Vimentin Expression Pattern is Different between the Flank Region and Limb Regions of Somatopleural Mesoderm in the Chicken Embryo

It is known that the chicken flank somatopleure also has a limb-forming potential at early stages of development, but loses this potential later. Molecular changes during this process is, however, not well known. We obtained a monoclonal antibody which reacts to the flank somatopleure, but not to the wing bud, the leg bud and the neck somatopleure in the stage 22 chicken embryo. Further study revealed that this antibody is specific to vimentin. Time course of vimentin expression in the somatopleural mesoderm during the development was studied. It was revealed to be biphasic. Somatopleural mesoderm expressed vimentin at stage 10, but not at stage 16. Flank somatopleural mesoderm began to express vimentin again at stage 18, whereas limb bud mesenchymal cells did not until stage 27. The earlier re-expression of vimentin at the flank somatopleure suggests that certain physiological changes take place in cells at this region.     

Regulation and Function of SF/HGF during Migration of Limb Muscle Precursor Cells in Chicken

Limb muscles of vertebrates are derived from migratory dermomyotomal cells which emanate from a limited number of somites located adjacent to the developing limb buds. We have generated additional limb buds in chicken embryos by implantation of FGF-beads into the interlimb region in order to analyze whether these somites can be programmed to supply ectopic limbs with myogenic precursor cells. We show that migrating myogenic precursor cells are released from somites at the level of the newly formed limb, even when cell migration into the natural limb has been completed. The implantation of FGF beads in the lateral plate mesoderm rapidly induces SF/HGF expression. FGF beads implanted between HH stages 10 and 12 inhibit limb bud formation or shift the normal limb position. When an additional FGF bead was implanted at the original limb position at HH stage 15, SF/HGF expression was transiently induced to low levels without inducing a new limb. This demonstrates that the initial induction of SF/HGF by FGF does not require limb formation. Expression of SF/HGF during early limb bud stages was found in the entire developing bud and the adjacent lateral plate mesoderm with direct contacts to the lateral edge of the dermomyotome. Later, the SF/HGF expression domain retracts to a distal region below the apical ectodermal ridge. To investigate the role of SF/HGF in the migratory process, we implanted beads soaked in SF/HGF-alone or together with FGF into different locations of the developing chick embryo. In the experiments SF/HGF caused delamination of migratory cells from the dermomyotomal epithelium but no chemotactic attraction of migrating cells toward the SF/HGF source.     

Cell-cell interaction by mouse limb cells during in vitro chondrogenesis: Analysis of the brachypod mutation

This paper contains observations and experiments which collectively demonstrate a requirement for cell-cell interactions among limb bud mesenchyme cells during chondrogenic differentiation. Limb bud cells isolated from brachypodism^H (bp^H) and wild-type mouse embyros between Thieler stage 16–17 and midstage 21 were compared with respect to their abilities to undergo chondrogenic differentiation in high-density micromass cultures. Nodules formed by dissociated Day 12 (stage 20) bp^H limb bud cells have been reported previously to be abnormally reduced in size and number, and delayed in formation. We corroborate these results, but find that bp^H cultures prepared from earlier-stage limb buds (between stages 16–17 and early stage 21) are progressively more like wild-type cultures. Stage 16–17 bp^H cultures at 72 hr actually contain normal numbers of and size nodules, while stage 18 bp^H cultures are intermediate between stages 16–17 and stage 21 in nodule formation. On the other hand, we also find that the initial rate of aggregate formation is normal even in bp^H cultures prepared from stage 20 cultures in which nodule formation is not normal. Preparation of cultures composed primarily of early stage 21 bp^H limb bud cells mixed with small quantities (e.g., 5%) of stage 16–17 wild-type limb bud cells showed significant increases in cartilage nodule formation over control cultures composed only of early stage 21 bp^H cells. Greater proportions of wild-type cells obtained from embryos older than stages 16–17 were required for the same degree of normalization, supporting the hypothesis that a specific cell type, whose proportion decreases normally in the limb bud over time, is required to increase in vitro chondrogenesis by bp^H cells. Additionally, cultures containing stage 23 chick limb cells and early stage 21 bp^H cells at a ratio of 1:20 contained wild-type levels of nodules per square millimeter of culture. Thus, bp^H cells appear to respond to chondrogenic inductive signals from normal limb mesenchyme cells. In order to test for the ability of bp^H limb bud mesenchyme to induce chondrogenesis, stage 16–17 bp^H and wild-type limb bud cells, which form identical numbers of aggregates and nodules in culture, were each mixed with early stage 21 bp^H cells at ratios of 1:20, 1:10, and 1:3. Although low proportions of wild-type stage 17 cells significantly increased the number of aggregates and nodules in these mixed cultures, low proportions of bp^H stage 16–17 cells did not. It is, therefore, concluded that the primary defect of the bp^H mutation is likely to reside in the reduced ability of a specific mesenchyme cell subpopulation to provide an inductive stimulus for chondrogenesis.     

Ezh2 regulates anteroposterior axis specification and proximodistal axis elongation in the developing limb

Specification and determination (commitment) of positional identities precedes overt pattern formation during development. In the limb bud, it is clear that the anteroposterior axis is specified at a very early stage and is prepatterned by the mutually antagonistic interaction between Gli3 and Hand2. There is also evidence that the proximodistal axis is specified early and determined progressively. Little is known about upstream regulators of these processes or how epigenetic modifiers influence axis formation. Using conditional mutagenesis at different time points, we show that the histone methyltransferase Ezh2 is an upstream regulator of anteroposterior prepattern at an early stage. Mutants exhibit posteriorised limb bud identity. During later limb bud stages, Ezh2 is essential for cell survival and proximodistal segment elongation. Ezh2 maintains the late phase of Hox gene expression and cell transposition experiments suggest that it regulates the plasticity with which cells respond to instructive positional cues.     

Cell populations synthesizing cartilage proteoglycan core protein in the early chick limb bud.

Cartilage specific macromolecules are known to be synthesized in the mesenchyme of the embryonic chick limb bud, especially in areas of prechondrogenic condensations (Shinomura et al, 1984). Even though the mesenchyme seems homogeneous according to histological criteria, studies in the past have suggested the presence of different cell populations with different chondrogenic potential (Solursh et al, 1982; Swalla et al, 1984). In this study we have investigated by means of flow cytometry, the synthesis of proteoglycan core protein during early development of the chick limb bud in order to identify the different chondrocyte progenitor cells. We were able to identify by virtue of different size and density a cell population which synthesizes core protein extensively at stage 24 and stage 25 of development. This cell population synthesizes core protein predominantly at the proximal half of the limb bud at stage 24. However at stage 25 the same population synthesizes core protein predominantly at the distal half of the limb bud. These observations indicate that the distal half of stage 25 limb bud is mostly homogeneous with prechondrogenic cells and is in agreement with in vitro experiments that show high chondrogenic potential of the mesenchymal cells from this stage.     

Limb development in chick embryos: cyclic AMP-dependent protein kinase activity, cyclic AMP, and prostaglandin concentrations during cytodifferentiation and morphogenesis

The effects of prostaglandin E2 (PGE2) on cyclic AMP (cAMP) concentrations of chick limb bud cells obtained from limbs at various stages of development were investigated. In addition, endogenous concentrations of PGE2 were examined in whole limbs from comparable stages. Prior to either chondrogenesis or myogenesis (stages 20-23), cells were more responsive to PGE2, in terms of cAMP levels, than those of differentiated phenotypes, obtained at stages 25-28. This greater responsiveness to PGE2 of undifferentiated cells was correlated with endogenous concentrations of PGE2 which were significantly higher in undifferentiated limbs than in limbs containing differentiated cartilage and muscle. Cyclic AMP-dependent protein kinase (PKA) activity was detectable in cell homogenates at each stage examined and did not appear to change in cAMP dependency at any stage. The majority (80-85%) of total enzyme activity was localized in soluble fractions of cell homogenates while the residual activity was localized to membrane-enriched, particulate fractions. The results demonstrate that both responsiveness of limb mesenchyme to PGE2 and endogenous concentrations of PGE2 are maximal prior to cytodifferentiation of limb tissues. The presence of cAMP-dependent protein kinase in these undifferentiated cells supports a regulatory role for both PGE2 and a cAMP-protein phosphorylation system in the differentiation of limb tissues.