First Neuromuscular Contact Correlates with Onset of Primary Myogenesis in Rat and Mouse Limb Muscles.

Skeletal muscle development has been the focus of intensive study for many decades. Recent advances in genetic manipulation of the mouse have increased our understanding of the cell signalling involved in the development of muscle progenitors which give rise to adult skeletal muscles and their stem cell populations. However, the influence of a vital tissue type - the peripheral nerve-has largely been ignored since its earliest descriptions.

Developmental fate of the mammalian myotome.

The myotome is a segmented paraxial muscle present in all early vertebrate embryos, which in amniotes disappears in mid-embryogenesis, and is replaced by complex epaxial and hypaxial musculature. Little is known about how this transition occurs. Here, we describe the detailed morphogenesis of the epaxial muscles from the epaxial myotome, in rodent embryos.

Investigation of neuromuscular abnormalities in neurotrophin-3-deficient mice.

Neurotrophin-3 (NT-3) is a trophic factor that is essential for the normal development and maintenance of proprioceptive sensory neurons and is widely implicated as an important modulator of synaptic function and development. We have previously found that animals lacking NT-3 have a number of structural abnormalities in peripheral nerves and skeletal muscles. Here we investigated whether haploinsufficiency-induced reduction in NT-3 resulted in impaired neuromuscular performance and synaptic function.

The mammalian myotome: a muscle with no innervation.

The segmented muscular myotome is the first muscle to form in all vertebrates. In fish and amphibian embryos, the myotome becomes innervated very early and is essential for larval swimming. Its role in birds and mammals, however, is not clear.

Developmental loss of NT-3 in vivo results in reduced levels of myelin-specific proteins, a reduced extent of myelination and increased apoptosis of Schwann cells.

This work investigates the role of NT-3 in peripheral myelination. Recent articles, based in vitro, propose that NT-3 acting through its high-affinity receptor TrkC may act to inhibit myelin formation by enhancing Schwann cell motility and/or migration. Here, we investigate this hypothesis in vivo by examining myelination formation in NT-3 mutant mice.

Preliminary observations on the microarchitecture of the human abdominal muscles.

Precise knowledge of muscle architecture and innervation patterns is essential for the development of accurate clinical and biomechanical models. Although the gross anatomy of the human abdominal muscles has been investigated, the finer details of their microanatomy are not well described. Fascicles were systematically sampled from each of the human abdominal muscles, and small fiber bundles from selected fascicles stained with acetylcholinesterase to determine the location of motor endplate bands, myomyonal junctions, and myotendinous junctions.

Muscle fiber and motor unit behavior in the longest human skeletal muscle.

The sartorius muscle is the longest muscle in the human body. It is strap-like, up to 600 mm in length, and contains five to seven neurovascular compartments, each with a neuromuscular endplate zone. Some of its fibers terminate intrafascicularly, whereas others may run the full length of the muscle.

Neurotrophin-3 null mutant mice display a postnatal motor neuropathy.

This paper examines early postnatal development of the neuromuscular system in mice with a null mutation in the gene for neurotrophin-3. We report that alpha-motoneurons at first develop substantially normally, despite a known 15% deficit in their somal size [Woolley et al. (1999)Neurosci.

Integrins in the mouse myotome: developmental changes and differences between the epaxial and hypaxial lineage.

Integrins are cellular adhesion receptors that mediate signaling and play key roles in the development of multicellular organisms. However, their role in the cellular events leading to myotome formation is completely unknown. Here, we describe the expression patterns of the alpha1, alpha4, alpha5, alpha6, and alpha7 integrin subunits in the mouse myotome and correlate them with the expression of several differentiation markers.

Development of a mammalian series-fibered muscle.

This study examines the processes by which multiply innervated, serially fibered mammalian muscles are constructed during development. We previously reported that primary myotubes of such a muscle, the guinea pig sternomastoid muscle, span from tendon to tendon and are innervated at each of the muscle's four innervation zones. Secondary myotubes form later, in association with each point of innervation (Duxson and Sheard, Dev.

Distribution of neurotrophin receptors in the mouse neuromuscular system.

The neurotrophins are a family of secreted proteins with critical roles in regulation of many aspects of neural development, survival and maintenance. Their actions on neural tissue are thought to be mediated by interaction with high affinity (trk family members) or low affinity (p75NTR) cell surface receptors. In general, neurotrophins are considered to be supplied in limiting quantity by cells of a target tissue or synaptic partner.

Localization of alpha 7 integrins and dystrophin suggests potential for both lateral and longitudinal transmission of tension in large mammalian muscles.

Non-primate mammalian muscles with fascicles above 35 mm in length are composed predominantly of arrays of short, non-spanning muscle fibres, which terminate within the belly of the muscle fascicle at one or both ends. We have previously described the morphological form of various muscle-to-muscle and muscle-to-matrix junctions which are likely involved in tension transmission within one such muscle - the guinea pig sternomastoid muscle (Young et al. 2000).