Muscle patterning, differentiation and vascularisation in the chick wing bud.

Abstract

Adult muscle is highly vascularised, with blood vessels being essential for adequate oxygenation of the tissue and for supporting increased metabolic demands. Whether this is the case during muscle development has not been examined. Resin histology was used to map the muscle splitting process and conventional transmission electron microscopy to examine early muscle differentiation at the midlimb level or later at the mid radius/ulna level in the chick wing bud from stages 24 (4.5 d) to 36 (10 d) (Hamburger & Hamilton, 1951). Microinjection of India Ink into the extra-embryonic vasculature was used to visualise the patent muscle microcirculation. The results showed that the premuscle masses are present at stage 24 and initial splitting of the muscle masses commences at stage 28. The final muscle pattern is not established until stage 36. At stage 26 the cells within the premuscle masses exhibited a mesenchymal morphology, but at stage 28 overt muscle differentiation was evident with myofibrils present within myoblasts. Undifferentiated mononucleated cells were interspersed with the differentiating myoblasts. The ratio of mononucleated cells:myoblasts decreased and the myoblasts became plumper and increasingly packed with myofibrils with age. There was no evidence of secondary myotube formation at any of the stages examined. Vascular invasion of the limb occurred at stage 35 just prior to the establishment of the final muscle pattern. This was surprising as it was assumed that myogenic differentiation would be both oxygen and nutrient dependent. The results of this study provide descriptions of the splitting of the premuscle masses through to the establishment of the final muscle pattern at the midlimb or mid radius/ulna level of the chick wing bud together with the differentiation of the myogenic cells within the developing muscles. However, the relationship between muscle patterning at the tissue level and muscle differentiation at the cellular level with vascularisation remains unclear. It is hoped that the results of the study may provide the basis for future investigations into mechanisms involved in muscle patterning and the signalling mechanisms for vascular invasion.