Summary
The embryonic development of the body wall musculature in the grasshopper was characterized from the appearance of the first muscle pioneers up to the establishment of a mature body wall muscle pattern. For this, a muscle-specific monoclonal antibody was used to carry out a detailed description of the temporal sequence of the developing muscle pattern in different embryonic stages. Muscle pioneers first appear at 35% of embryonic development. They form a patterned, segmentally reiterated substrate for the fusion of numerous smaller mesodermal cells. This results in the formation of an ordered array of multinuclear muscle precursor cells by the 50% stage. Subsequently, these muscle precursor cells begin to grow in size and some shift their position in the body wall. At 70% of embryonic development the pattern of muscle precursors reaches maturity, in that identified precursor cells at this stage can be related to all adult muscles. Moreover, at this stage identified muscle precursors also prefigure those muscles which will disappear during postembryonic development. Thus, between 35% and 70% of embryogenesis a basic pattern consisting of the full complement of muscle precursors is formed which is subsequently acted upon by postembryonic differentiation processes to generate the adult body wall musculature.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Albrecht FO (1953) The anatomy of the migratory locust. Athlone, London
Anderson MS, Halpern ME, Keshishian HS (1988) Identification of the neuropeptide transmitter proctolin inDrosophila larvae. Characterization of muscle fiber-specific neuromuscular endings. J Neurosci 8:242–255
Ball EE, Goodman CS (1985a) Muscle development in the grasshopper embryo: II. Syncytial origin of the extensor tibiae muscle pioneers. Devel Biol 111:399–416
Ball EE, Goodman CS (1985b) Muscle development in the grasshopper embryo: III. Sequential origin of the flexor muscle pioneers. Dev Biol 111:417–424
Ball EE, Ho RK, Goodman CS (1985a) Development of neuromuscular specificity in the grasshopper embryo: Guidance of motoneuron growth cones by muscle pioneers. J Neurosci 5:1808–1819
Ball EE, Ho RK, Goodman CS (1985b) Muscle development in the grasshopper embryo: I. Muscles, nerves, and apodemes in the metathoracic leg. Dev Biol 111:383–398
Bate M (1991) The embryonic development of larval muscles inDrosophila. Development 110:791–804
Bate M, Rushton E, Currie D (1991) Cells with persistent twist expression are the embryonic precursors of adult muscles inDrosophila. Development 113:79–89
Bentley D, Keshishian H, Shankland M, Toroian-Raymond A (1979) Quantitative staging of embryonic development of the grasshopper,Schistocerca nitens. J Embryol Exp Morphol 54:47–74
Bernays EA (1972) The muscles of newly hatchedSchistocerca gregaria larvae and their possible functions in hatching, digging and ecdysial movements (Insecta: Acrididae). J Zool 166:141–158
Bourne JA (1983) Handbook of immunoperoxidase staining methods. Dako, Santa Barbara
Broadie KS, Bate M (1991) The development of adult muscles inDrosophila: ablation of identified muscle precursor cells. Development 113:103–118
Campos-Ortega JA, Hartenstein V (1985) The embryonic development of Drosophila melanogaster. Springer, Berlin Heidelberg New York Tokyo
Chabaud F, Friedli M, Reichert H (1991) Neuronal development of the crustacean stomatogastric nervous system. In: Elsner N, Penzlin H (eds) Synapse-Transmission Modulation. Thieme, Stuttgart, p 495
Chang TN, Chiba A, Jay D, Keshishian H (1991) Fasciclin III expression during synaptic target recognition inDrosophila. Soc Neurosci [Abstr] 17:214
Crossley CA (1978) The morphology and development of the Drosophila muscular system. In: Ashburner M, Wright TRF (eds) The genetics and biology ofDrosophila. Academic New York
Currie D, Bate M (1991) The development of adult abdominal muscles in Drosophila: myoblasts express twist and are associated with nerves. Development 113:91–102
Ewer DW (1954) On the nymphal musculature of the pterothorax of certain Acrididae (Orthoptera). Ann Natal Mus 13:79–89
Fernandes J, Bate M, Vijayraghavan K (1991) Development of the indirect flight muscles ofDrosophila. Development 113:67–77
Halpern ME, Chiba A, Johansen J, Keshishian H (1991) Growth cone behavior underlying the development of stereotypic synaptic connections inDrosophila embryos. J Neurosci 11:3227–3238
Ho RK, Ball EE, Goodman CS (1983) Muscle pioneers: large mesodermal cells that erect a scaffold for developing muscles and motoneurons in grasshopper embryos. Nature (Lond) 301:6669
Jellies J (1990) Muscle assembly in simple systems. Trends Neurosci 13:126–131
Johansen J, Halpern ME, Keshishian H (1989) Axonal guidance and the development of muscle fiber-specific innervation inDrosophila embryos. J Neurosci 9:4318–4332
Johnson GD, Nogueira Araujo G (1981) A simple method of reducing the fading of immunofluorescence during microscopy. J Immunol Methods 43:349–350
Landmesser L (1980) The generation of neuromuscular specificity. Annu Rev Neurosci 3:279–302
Myers CM, Whitington PM, Ball EE (1990) Embryonic development of the innervation of the locust extensor tibiae muscle by identified neurons: Formation and elimination of inappropriate axon branches. Dev Biol 137:194–206
Nose A, Goodman CS (1991) Connectin: a surface protein expressed on a subset of motoneuron axons and the target muscles they innervate inDrosophila. Soc Neurosci [Abstr] 17:742
Purves D, Lichtman JW (1985) Principles of neural development. Sinauer, Sunderland
Shepherd D, Bate CM (1990) Spatial and temporal patterns of neurogenesis in the embryo of the locust (Schistocerca gregaria). Development 108:83–96
Sink H, Whitington PM (1991) Pathfinding in the central nervous system and periphery by identified embryonicDrosophila motor axons. Development 112:307–316
Snodgrass RE (1929) The thoracic mechanism of a grasshopper and its antecedents. Smithson Misc Collect 82:1–111
Snodgrass RE (1931) Morphology of the insect abdomen. Smithson Misc Collect 85:1–128
Tyrer NM, Altman J (1974) Motor and sensory flight neurones in a locust demonstrated using cobalt chloride. J Comp Neurol 157:117–138
Wiesend P (1957) Die postembryonale Entwicklung der Thoraxmusculatur bei einigen Feldheuschrecken mit besonderer Berilcksichtigung der Flugmuskeln. Z Morphol Oekol Tiere 46:259–270
Whitington PM (1989) The early development of motor axon pathways in the locust embryo: the establishment of the segmental nerves in the thoracic ganglia. Development 105:715–721
Whitington PM, Seifert E (1984) Axon growth from limb motoneurons in the locust embryo: The effect of target limb removal on the pattern of axon branching in the periphery. Dev Biol 106:438–449
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Xie, F., Meier, T. & Reichert, H. Embryonic development of muscle patterns in the body wall of the grasshopper. Roux's Arch Dev Biol 201, 301–311 (1992). https://doi.org/10.1007/BF00592111
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00592111