Effects of the mesonephros and insulin-like growth factor I on chondrogenesis of limb explants.

The mesonephros has been shown to have a growth-promoting influence in vivo on limb outgrowth. This influence has been studied in detail using an organ culture system. The results show that in the presence of the mesonephros limb explants formed larger cartilages than cultures without mesonephros. Furthermore, with mesonephros, morphology of the cartilages is comparable to that of skeletal elements in vivo while cartilages formed in cultures lacking mesonephros were amorphous. The mesonephric influence also promoted the formation of a well-organized extracellular matrix in the cartilage while cartilage in cultures without mesonephros formed an abnormal appearing matrix. Cartilage matrices in cultures with or without mesonephros were immunoreactive to type IX and type II collagens, cartilage proteoglycan PGH, and link protein although cultures lacking mesonephros had a very restricted distribution of type IX collagen immunoreactivity. Despite the different distribution of type IX collagen, long-form-type IX collagen transcripts appeared similar in both types of culture based on in situ hybridization. The mesonephric effect on limb explants could be partially duplicated by the addition of insulin-like growth factor I (IGF-I) to cultures without mesonephros. Furthermore, the mesonephric influence on cartilage growth and morphological differentiation could be blocked by the addition of a blocking antibody to IGF-I to cultures with mesonephros. The results support the hypothesis that IGF-I is one of the growth factors produced by the mesonephros which may play a role in early limb development and chondrogenesis.

Cellular contribution of the different regions of the somatopleure to the developing limb.

Regionalization of the presumptive limb region was examined before and at the onset of limb development by means of a variety of transplantation experiments between quail and chick embryos in ovo. The results demonstrate a two-step process, the first of which is the designation of the region of the somatopleure that would become part of the limb, followed by specification of dorsal and ventral regions of the limb. The medial half of the somatic mesoderm is the region which gives rise to the limb with only a smaller cellular contribution from the lateral half of the somatic mesoderm. The cellular contribution of the medial region of the somatopleure appeared to determine the type of limb formed (i.e., wing or leg). The second process relates to changes in the ability of the somatic ectoderm to undergo extensive lateral displacement with development. Starting at stage 14, the medial and lateral somatic ectoderms maintain their position after transplantation, in contrast to earlier stage limb or flank ectoderms which undergo extensive lateral displacement with development. The positional determination of the dorsal and ventral properties of the medial and lateral ectoderms of the prospective limb region and their distal displacement during limb outgrowth may be important morphogenetic events in limb development.

Coordinate expression of IGF-I and its receptor during limb outgrowth.

The morphogenetic mechanisms involved in shaping the embyro are largely unknown. Previous studies from this laboratory suggest that the mesonephros promotes limb outgrowth in ovo in the chicken embryo and might be involved in early limb morphogenesis, since damage to the mesonephros results in truncated limbs. In limb bud organ cultures, the presence of the mesonephros promotes cartilage formation. This effect can be reproduced by exogenous IGF-I or prevented by blocking antibody to IGF-I. In order to examine the hypothesis that mesonephros-derived IGF-I is involved in the early morphogenesis of the limb, we examined the spatial and temporal expression of IGF-I and type I receptor for IGF by in situ hybridization at stages when the onset of limb development occurs. The results show that neither transcript is detected at stage 13, prior to the appearance of the limb bud; but both transcripts are detected in the mesonephros at stage 14, an early stage in limb outgrowth. The hybridization signal in the mesonephros for both transcripts increases with development and signal was codistributed as well. At stage 18 the level of receptor transcripts detected in the flank relative to the limb decreased. Thus, the temporal and spatial patterns of expression of IGF-I and its receptor are consistent with their involvement in the initiation of limb outgrowth and support the model that localized expression of a growth factor and its receptor can be involved in shaping the embryo.

A growth-promoting influence from the mesonephros during limb outgrowth.

It has been suggested that the mesonephros has a role in normal limb development. This hypothesis was directly tested by removing the mesonephros adjacent to the presumptive limb region of stage 12-18 chick embryos using microsurgery or laser ablation. The experimental manipulation resulted in reduced limb outgrowth on the operated side. The poor limb outgrowth was correlated with either the lack of or the presence of a rudimentary mesonephros on the operated side. Furthermore, the presence of nephric tissue in limb bud organ culture enhanced growth and morphological differentiation of cartilage formed in culture. In vivo, the influence of the mesonephros resulted in significantly higher cell proliferation in the adjoining medial half of the limb mesoderm compared with the lateral half. The removal of the mesonephros adjoining the prospective limb region reduced the number of dividing cells in the medial mesoderm. The higher proliferation in the medial limb mesoderm is significant to limb outgrowth since grafting experiments showed that most of the cells that form the limb are derived from the medial mesoderm. The results suggest that the influence from the mesonephros may provide some signal for limb outgrowth.

Transfer of dorsoventral information from mesoderm to ectoderm at the onset of limb development.

Control of dorsoventral patterns in the chick at the prelimb stages resides in the limb mesoderm. Recombination experiments at stage 14, with dorsoventrally reversed ectoderm, result in wings with mesodermal dorsoventral polarity. Similar recombinations at stage 16 show that the ectoderm has acquired dorsoventral information and can impose this polarity on the patterns of mesodermal differentiation in the distal regions of the wing. The dorsoventral information in the ectoderm comes from the mesoderm, which transfers this information to the overlying ectoderm between stages 14 and 16. The initial dorsoventral overlying ectoderm between stages 14 and 16. The initial dorsoventral information in the ectoderm is not stable and can be reprogrammed by stage 14 mesoderm. Subsequently, there is a gradual stabilization of the ectodermal information. At the same time the mesoderm loses its capacity to reprogram dorsoventral information in the ectoderm.

The ectodermal control of mesodermal patterns of differentiation in the developing chick wing.

The influence of limb ectoderm on the dorso-ventral muscle and skeletal patterns in the chick wing was studied by recombining stage 14-21 limb mesoderm with the same stage ectoderm in dorso-ventrally reversed orientation. Recombinants grafted to the flank of host embryos were allowed to develop for 10 days. Fully developed wings obtained from stage 15-21 donor embryos have at their distal half d-v polarity conforming to the reversed ectoderm and proximally polarity conforming with the mesoderm. The ectodermal effect is generally observed as a bidorsal feather pattern at the autopod and an almost complete d-v reversal of muscle and skeletal patterns. In experimental wings from donor embryos younger than stage 15, the dorso-ventral pattern conforms with the polarity of the limb mesoderm. The results suggest that control of dorso-ventral polarity resides in the mesoderm until the onset of limb development at stage 15. At this stage, the ectoderm acquires dorso-ventral information which it can impose on the mesoderm.