Induced neuroma formation and target muscle perturbation in the giant fiber pathway of the Drosophila temperature-sensitive mutant shibire

Summary The temperature-sensitive mutation shibire (shi) in Drosophila melanogaster is thought to disrupt membrane recycling processes, including endocytotic vesicle pinch-off. This mutation can perturb the development of nerves and muscles of the adult escape response. After exposure to a heat pulse (6 h at 30° C) at 20 h of pupal development, adults have abnormal flight muscles. Wing depressor muscles (DLM) are reduced in number from the normal six to one or two fibers, and are composed of enlarged fibers that appear to represent fiber fusion; large spaces devoid of muscle fibers suggested fiber deletion. The normal five motor axons are present in the peripheral nerve PDMN near the ganglion. However, while some motor axons pass dorsally to the extant fibers, other motor axons lacking end targets pass into an abnormal posterior branch and terminate in a neuroma, i.e., a tangle of axons and glia without muscle target tissue. Hemisynapses are common in axons of the proximal PDMN and within the neuroma, but they are rarely seen in control (no heat pulse) shi or wild-type flies. All surviving muscle fibers are innervated; no muscle tissue exists without innervation. Fibrillar fine structure and neuromuscular synapses appear normal. Fused fibers have dual innervation, suggesting correct and specific matching of target tissue and motor axons. Motor axons lacking target fibers do not innervate erroneous targets but instead terminate in the neuroma. These results suggest developmental constraints and rules, which may contribute to the orderly, stereotyped development in the normal flight system. The nature of the anomalies inducible in the flight motor system in shi flies implies that membrane recycling events at about 20 h of pupal development are critical to the formation of the normal adult nerve-muscle pattern for DLM flight muscles.     

Present State and Future Perspectives of Prostaglandins as a Differentiation Factor in Motor Neurons

Spinal motor neurons have the longest axons that innervate the skeletal muscles of the central nervous system. Motor neuron diseases caused by spinal motor neuron cell death are incurable due to the unique and irreplaceable nature of their neural circuits. Understanding the mechanisms of neurogenesis, neuritogenesis, and synaptogenesis in motor neurons will allow investigators to develop new in vitro models and regenerative therapies for motor neuron diseases. In particular, small molecules can directly reprogram and convert into neural stem cells and neurons, and promote neuron-like cell differentiation. Prostaglandins are known to have a role in the differentiation and tissue regeneration of several cell types and organs. However, the involvement of prostaglandins in the differentiation of motor neurons from neural stem cells is poorly understood. The general cell line used in research on motor neuron diseases is the mouse neuroblastoma and spinal motor neuron fusion cell line NSC-34. Recently, our laboratory reported that prostaglandin E₂ and prostaglandin D₂ enhanced the conversion of NSC-34 cells into motor neuron-like cells with neurite outgrowth. Moreover, we found that prostaglandin E₂-differentiated NSC-34 cells had physiological and electrophysiological properties of mature motor neurons. In this review article, we provide contemporary evidence on the effects of prostaglandins, particularly prostaglandin E₂ and prostaglandin D₂, on differentiation and neural conversion. We also discuss the potential of prostaglandins as candidates for the development of new therapeutic drugs for motor neuron diseases.

     

Innervation of developing intrafusal muscle fibers in the rat

The chronology of development of spindle neural elements was examined by electron microscopy in fetal and neonatal rats. The three types of intrafusal muscle fiber of spindles from the soleus muscle acquired sensory and motor innervation in the same sequence as they formed--bag2, bag1, and chain. Both the primary and secondary afferents contacted developing spindles before day 20 of gestation. Sensory endings were present on myoblasts, myotubes, and myofibers in all intrafusal bundles regardless of age. The basic features of the sensory innervation--first-order branching of the parent axon, separation of the primary and secondary sensory regions, and location of both primary and secondary endings beneath the basal lamina of the intrafusal fibers--were all established by the fourth postnatal day. Cross-terminals, sensory terminals shared by more than one intrafusal fiber, were more numerous at all developmental stages than in mature spindles. No afferents to immature spindles were supernumerary, and no sensory axons appeared to retract from terminations on intrafusal fibers. The earliest motor axons contacted spindles on the 20th day of gestation or shortly afterward. More motor axons supplied the immature spindles, and a greater number of axon terminals were visible at immature intrafusal motor endings than in adult spindles; hence, retraction of supernumerary motor axons accompanies maturation of the fusimotor system analogous to that observed during the maturation of the skeletomotor system. Motor endings were observed only on the relatively mature myofibers; intrafusal myoblasts and myotubes lacked motor innervation in all age groups. This independence of the early stages of intrafusal fiber assembly from motor innervation may reflect a special inherent myogenic potential of intrafusal myotubes or may stem from the innervation of spindles by sensory axons.     

Guidance of regenerating motor axons in vivo by gradients of diffusible peripheral nerve‐derived factors

During development of the central nervous system, neurons rely on target‐derived factors to guide their outgrowing processes. Several CNS target‐derived chemoattractive and repellant factors have been isolated and characterized, and their mechanism of action determined. For the peripheral nervous system, the results from numerous experiments suggest that during regeneration axons also respond to concentration gradients of target‐derived factors leading to an oriented outgrowth up the gradient to the denervated target in vivo. The results from in vitro experiments have shown that diffusible concentration gradients of factors released from a length of denervated peripheral nerve, composed predominantly of Schwann cells, direct the outgrowth of sensory and motor neuron growth cones over distances of several hundred microns. However, a conclusive demonstration of a chemoattractive influence of diffusible concentration gradients on regenerating adult motor axons in vivo has remained elusive. The present experiments show that concentration gradients of denervated peripheral nerve‐released factors direct the regeneration of adult motor axons in vivo, and that these gradients are effective over distances of more than 6.5 mm. Nonconditioned medium exerted no influence on the regenerating axons. Thus, results from in vivo experiments parallel those from in vitro experiments and indicate that isolated peripheral nerve‐released factors that are effective in vitro will play a similar role on sensory and motor axons in vivo. Finally, the results show that diffusible concentration gradients of target‐derived factors direct axon outgrowth both during both development and regeneration, as well as in vivo and in vitro. © 2000 John Wiley & Sons, Inc. J Neurobiol 42: 212–219, 2000     

Cell adhesion and migration in the organization of spinal motor neurons

Spinal motor neurons are critical to the ability of animals to move and thus essential to survival. Motor neurons that project axons to distinct limb-muscle targets are topographically organized such that central nervous system position reflects the location of the muscle in the limb. The central positioning of limb-projecting motor neurons arises during development through motor neuron migration followed by a period of coalescence into discrete groupings of motor neurons which project axons to an individual muscle. These so-called motor pools are a common feature of motor organization in higher vertebrates. Recent work has highlighted the critical role for armadillo family member catenin-dependent functions of the cadherin family of cell adhesion molecules in directing the organization of motor neurons. Cadherin function appears to be important for both the motor neuron migration and coalescence phases of the emergence of motor neuron topography. Here, I review this recent work in the context of our understanding of the general development of spinal motor neurons.     

Cell adhesion and migration in the organization of spinal motor neurons

Spinal motor neurons are critical to the ability of animals to move and thus essential to survival. Motor neurons that project axons to distinct limb-muscle targets are topographically organized such that central nervous system position reflects the location of the muscle in the limb. The central positioning of limb-projecting motor neurons arises during development through motor neuron migration followed by a period of coalescence into discrete groupings of motor neurons which project axons to an individual muscle. These so-called motor pools are a common feature of motor organization in higher vertebrates. Recent work has highlighted the critical role for armadillo family member catenin-dependent functions of the cadherin family of cell adhesion molecules in directing the organization of motor neurons. Cadherin function appears to be important for both the motor neuron migration and coalescence phases of the emergence of motor neuron topography. Here, I review this recent work in the context of our understanding of the general development of spinal motor neurons.     

Role of nerve and muscle factors in the development of rat muscle spindles

The soleus muscles of fetal rats were examined by electron microscopy to determine whether the early differentiation of muscle spindles is dependent upon sensory innervation, motor innervation, or both. Simple unencapsulated afferent-muscle contacts were observed on the primary myotubes at 17 and 18 days of gestation. Spindles, encapsulations of muscle fibers innervated by afferents, could be recognized early on day 18 of gestation. The full complement of spindles in the soleus muscle was present at day 19, in the region of the neuromuscular hilum. More afferents innervated spindles at days 18 and 19 of gestation than at subsequent developmental stages, or in adult rats; hence, competition for available myotubes may exist among afferents early in development. Some of the myotubes that gave rise to the first intrafusal (bag2) fiber had been innervated by skeletomotor (alpha) axons prior to their incorporation into spindles. However, encapsulated intrafusal fibers received no motor innervation until fusimotor (gamma) axons innervated spindles 3 days after the arrival of afferents and formation of spindles, at day 20. The second (bag1) intrafusal fiber was already formed when gamma axons arrived. Thus, the assembly of bag1 and bag2 intrafusal fibers occurs in the presence of sensory but not gamma motor innervation. However, transient innervation of future bag2 fibers by alpha axons suggests that both sensory and alpha motor neurons may influence the initial stages of bag2 fiber assembly. The confinement of nascent spindles to a localized region of the developing muscle and the limited number of spindles in developing muscles in spite of an abundance of afferents raise the possibility that afferents interact with a special population of undifferentiated myotubes to form intrafusal fibers.     

Innervation and motor patterns of the abdominal superficial flexor muscles in larval lobsters

The pattern of innervation and motor program of the abdominal superficial flexor muscle was investigated electrophysiologically in larval lobsters (Homarus americanus). The muscle receives both excitatory and inhibitory innervation in the larval as well as in the embryonic stages. Individual muscle fibers receive a single inhibitory neuron (f5) and a maximum of three excitors. Based on spike heights these axons belong to either the small (f1 or f2) or large (f3, f4) motoneurons. While the small axons preferentially innervate the medial muscle fibers the large axons innervate medial as well as lateral fibers. This larval pattern of innervation resembles the pattern in the adult lobster. The resemblance extends to the firing patterns as well with both large and small excitors firing spontaneously. Furthermore, evoked activity in the larvae produces reciprocal (and occasionally cyclical) bursts of excitor and inhibitor neurons denoting abdominal extension and flexion and resembling the firing patterns in adults. Consequently motor programs employed in steering the pelagic larvae are reminiscent of the programs for maintaining posture in the benthic adult lobsters.     

Motor innervation of intrafusal fibers in rat muscle spindles: incomplete separation of dynamic and static systems

Distributions of 53 motor axons to different types of intrafusal fibers were reconstructed from serial 1-micron-thick transverse sections of 13 poles of spindles in the rat soleus muscle. The mean number of motor axons that innervated a spindle pole was 4.1. Approximately 60% of motor axons lost their myelination prior to or shortly after entry into the periaxial fluid space of spindles. Motor innervation to the juxtaequatorial portion of nuclear bag fibers (particularly the bag1) consisted of groups of short, synaptic contacts that were terminations of thin, unmyelinated axons. In contrast, motor endings on both the bag1 and bag2 fibers were platelike in the polar intracapsular region. Chain fibers had a single midpolar platelike ending. The ratio of motor axons that innervated the bag1 fiber exclusively to axons that innervated bag2 and/or chain fibers was 1:1. However, one-fourth of motor axons coinnervated the dynamic bag1 fiber in conjunction with static bag2 and/or chain fibers. Thus the complete separation of motor control of the dynamic bag1 and static bag2 intrafusal systems observed in cat tenuissimus spindles is neither representative of the pattern of motor innervation in all other species of mammals nor essential to normal spindle function.     

Elimination of sensory inputs induces growth and synaptic changes in crayfish motor axons

Damage to motor neurons induces regeneration processes including axonal growth and change of synaptic properties. Sensory axons that run along the motor axons are also damaged, but their possible role in the motor neuron''s regeneration is generally ignored. Here, the effect of eliminating some sensory inputs from intact motor axons on the motor axon''s properties was studied. Micro-dissecting one of the segmental, bilateral, sensory stretch receptor pairs of the crayfish abdomen induced the deep extensor abdominal motor axons to grow and changed their synaptic properties. The results demonstrate directly, probably for the first time, that change in sensory neuron activity can induce motor axons to grow, form new synapses, and change their synaptic properties.     

Lack of TrkB and TrkC signaling alters the synaptogenesis and maturation of mossy fiber terminals in the hippocampus

We have studied the role of endogenous neurotrophins in the formation and maturation of intrinsic hippocampal connections in vivo and analyzed the dentate granule cell projections in both trkB(-/-) and trkC(-/-) mice. Immunohistochemistry against calbindin did not show major alterations in the distribution of granule cell axons, which were located exclusively in the hilus and the stratum lucidum. However, the thickness of the stratum lucidum (mossy fiber termination zone) and the density of mossy fiber terminals were reduced in the absence of TrkB signaling. Electron-microscopic analyses showed that the fine structure of mossy terminals was altered in both trkB(-/-) and trkC(-/-) mice. Mutant granule cell terminals were smaller than those in wild-type animals and showed a reduction in both the number of synaptic contacts and synaptic vesicles. Immunofluorescence assays demonstrated that the expression levels of most synaptic-associated proteins (v-SNAREs and t-SNAREs) were altered in the mossy fibers of trkB- and trkC-deficient mice. Our results therefore reveal that TrkB and TrkC signaling is required for the maturation of granule cell axons.     

Dynamic aspects of retinotectal map formation revealed by a vital-dye fiber-tracing technique

In the visual system of Xenopus laevis, the axons from the retinal ganglion cells of the eye form a topographic projection onto the optic tectum. Many studies have focused on revealing the mechanisms responsible for this precise and regular projection pattern. In contrast to the static view of the system that one might expect from examining the regularity of the projection, recent work on its regeneration and its changes during larval development indicate that part of the patterning process involves the dynamic behavior of optic fibers. Typically, anatomical and electrophysiological techniques have been used to obtain static views of the developing retinotectal projection which then must be complied to provide a glimpse of any dynamic behavior. Here we report on experiments using a newly developed fiber tracing technique to directly follow the emergence of topography in the developing retinotectal projection. Defined halves of the developing eyebud were labeled with a vital fluorescent dye which fills the growing axons, and the projection of the labeled cells was followed for up to 2 weeks in individual animals. The experiments confirm that dorsal and ventral optic nerve fibers sort out into an ordered projection early in development. In contrast, nasal and temporal fibers initially overlap, and the same sets of prelabeled fibers then sort out into the adult topography over a period of days.     

BDNF and NT4/5 promote survival and neurite outgrowth of pontocerebellar mossy fiber neurons

The neurotrophins nerve growth factor (NGF), brain‐derived neurotrophic factor (BDNF), neurotrophin‐3 (NT3), and NT4/5 are all found in the developing cerebellum. Granule cells, the major target neurons of mossy fibers, express BDNF during mossy fiber synaptogenesis. To determine whether neurotrophins contribute to the development of cerebellar afferent axons, we characterized the effects of neurotrophins on the growth of mossy fiber neurons from mice and rats in vitro. For a mossy fiber source, we used the basilar pontine nuclei (BPN), the major source of cerebellar mossy fibers in mammals. BDNF and NT4/5 increased BPN neuron survival, neurite outgrowth, growth cone size, and elongation rate, while neither NT3 nor NGF increased survival or outgrowth. In addition, BDNF and NT4/5 reduced the size of neurite bundles. Consistent with these effects, in situ hybridization on cultured basilar pontine neurons revealed the presence of mRNA encoding the TrkB receptor which binds both BDNF and NT4/5 with high affinity. We detected little or no message encoding the TrkC receptor which preferentially binds NT3. BDNF and NT4/5 also increased TrkB mRNA levels in BPN neurons. In addition to previously established functions as an autocrine/paracrine trophic factor for granule cells, the present results indicate that cerebellar BDNF may also act as a target‐derived trophic factor for basilar pontine mossy fibers. © 1999 John Wiley & Sons, Inc. J Neurobiol 40: 254–269, 1999     

Acetylcholine receptor distribution on regenerating mammalian muscle fibers at sites of mature and developing nerve-muscle junctions

When rat soleus muscles fibers regenerated after notexin-induced damage, AChRs were present at high density on the surface of the new muscle fibers at the sites of the original NMJs, even if the intact motor axons were not present during regeneration. Some AChR molecules which were labelled with R-BgTx before notexin-induced damage persisted for some days at junctional sites after new muscle fibres had regenerated. During muscle fiber degeneration, components of the muscle fiber plasma membrane appeared to remain longer in the junctional region than elsewhere. When muscles on which new "ectopic" NMJs had been forming for at least 2 weeks were damaged, AChR clusters together with sites of high AChE activity were present 2 weeks later on the regenerated muscles in the region of new NMJ formation, even if the "foreign" nerve was not intact during the period of regeneration. If ectopic NMJs had been forming for only 4 days at the time of muscle and nerve damage, neither AChR clusters nor AChE activity were detected on the regenerated muscle fibers.     

Regulation of SC1/DM-GRASP during the migration of motor neurons in the chick embryo brain stem

The hindbrain of the chick embryo contains three classes of motor neurons: somatic, visceral, and branchial motor. During development, somata of neurons in the last two classes undergo a laterally directed migration within the neuroepithelium; somata translocate towards the nerve exit points, through which motor axons are beginning to extend into the periphery. All classes of motor neuron are immunopositive for the SC1/DM-GRASP cell surface glycoprotein. We have examined the relationship between patterns of motor neuron migration, axon outgrowth, and expression of the SC1/DM-GRASP mRNA and protein, using anterograde or retrograde axonal tracing, immunohistochemistry, and in situ hybridization. We find that as motor neurons migrate laterally, SC1/DM-GRASP is down-regulated, both on neuronal somata and axonal surfaces. Within individual motor nuclei, these lateral, more mature neurons are found to possess longer axons than the young, medial cells of the population. Labelling of sensory or motor axons growing into the second branchial arch also shows that motor axons reach the muscle plate first, and that SC1/DM-GRASP is expressed on the muscle at the time growth cones arrive. 1994 John Wiley & Sons, Inc.     

Guidance of regenerating motor axons in vivo by gradients of diffusible peripheral nerve-derived factors

During development of the central nervous system, neurons rely on target-derived factors to guide their outgrowing processes. Several CNS target-derived chemoattractive and repellent factors have been isolated and characterized, and their mechanism of action determined. For the peripheral nervous system, the results from numerous experiments suggest that during regeneration axons also respond to concentration gradients of target-derived factors leading to an oriented outgrowth up the gradient to the denervated target in vivo. The results from in vitro experiments have shown that diffusible concentration gradients of factors released from a length of denervated peripheral nerve, composed predominantly of Schwann cells, direct the outgrowth of sensory and motor neuron growth cones over distances of several hundred microns. However, a conclusive demonstration of a chemoattractive influence of diffusible concentration gradients on regenerating adult motor axons in vivo has remained elusive. The present experiments show that concentration gradients of denervated peripheral nerve-released factors direct the regeneration of adult motor axons in vivo, and that these gradients are effective over distances of more than 6.5 mm. Nonconditioned medium exerted no influence on the regenerating axons. Thus, results from in vivo experiments parallel those from in vitro experiments and indicate that isolated peripheral nerve-released factors that are effective in vitro will play a similar role on sensory and motor axons in vivo. Finally, the results show that diffusible concentration gradients of target-derived factors direct axon outgrowth both during both development and regeneration, as well as in vivo and in vitro.     

Mouse transgenic lines that selectively label Type I, Type IIA, and Types IIX+B skeletal muscle fibers

Skeletal muscle fibers vary in contractile and metabolic properties. Four main fiber types are present in mammalian trunk and limb muscles; they are called I, IIA, IIX, and IIB, ranging from slowest- to fastest-contracting. Individual muscles contain stereotyped proportions of two or more fiber types. Fiber type is determined by a combination of nerve-dependent and -independent influences, leading to formation of "homogeneous motor units" in which all branches of a single motor neuron form synapses on fibers of a single type. Fiber type composition of muscles can be altered in adulthood by multiple factors including exercise, denervation, hormones, and aging. To facilitate analysis of muscle development, plasticity, and innervation, we generated transgenic mouse lines in which Type I, Type IIA, and Type IIX+B fibers can be selectively labeled with distinguishable fluorophores. We demonstrate their use for motor unit reconstruction and live imaging of nerve-dependent alterations in fiber type.     

Immunocytochemical demonstration of alpha-tubulin modification during axonal maturation in the cerebellar cortex

Previous light microscopic immunocytochemical studies using two monoclonal antibodies that recognise alpha-tubulin (YOL/34 and YL1/2) but differ in their isotypic specificity have shown that the unmyelinated parallel fiber axons in the cerebellar cortex are labeled with only one of the antibodies (YOL/34). We now show that at 10 d postnatally the parallel fibers are labeled with both antibodies, and that during development YL1/2 (but not YOL/34) immunoreactivity disappears progressively from parallel fibers in the lower regions of the molecular layer upwards towards the external germinal layer. By approximately 28 d postnatally, the differential staining pattern of parallel fibers by the antibodies is established throughout the molecular layer. The time course, light microscopic, and ultrastructural staining distribution corresponds to a progressive change in alpha-tubulin immunoreactivity as the parallel fibers form synaptic contacts. This modification of alpha-tubulin (which was not observed in Purkinje cell dendrites or Bergmann glia) may be related to the formation of a basic isotype of alpha-tubulin within parallel fiber axons at maturation.     

Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR)/Cas9‐mediated kif15 mutations accelerate axonal outgrowth during neuronal development and regeneration in zebrafish

KIF15, the vertebrate kinesin‐12, is best known as a mitotic motor protein, but continues to be expressed in neurons. Like KIF11 (the vertebrate kinesin‐5), KIF15 interacts with microtubules in the axon to limit their sliding relative to one another. Unlike KIF11, KIF15 also regulates interactions between microtubules and actin filaments at sites of axonal branch formation and in growth cones. Our original work on these motors was done on cultured rat neurons, but we are now using zebrafish to extend these studies to an in vivo model. We previously studied kif15 in zebrafish by injecting splice‐blocking morpholinos injected into embryos. Consistent with the cell culture work, these studies demonstrated that axons grow faster and longer when KIF15 levels are reduced. In the present study, we applied CRISPR/Cas9‐based knockout technology to create kif15 mutants and labeled neurons with Tg(mnx1:GFP) transgene or transient expression of elavl3:EGFP‐alpha tubulin. We then compared by live imaging the homozygotic, heterozygotic mutants to their wildtype siblings to ascertain the effects of depletion of kif15 during Caudal primary motor neuron and Rohon‐Beard (R‐B) sensory neuron development. The results showed, compared to the kif15 wildtype, the number of branches was reduced while axon outgrowth was accelerated in kif15 homozygotic and heterozygotic mutants. In R‐B sensory neurons, after laser irradiation, injured axons with loss of kif15 displayed significantly greater regenerative velocity. Given these results and the fact that kif15 drugs are currently under development, we posit kif15 as a novel target for therapeutically augmenting regeneration of injured axons.      

神经元轴突生长的力生物学

神经系统作为一个复杂的体系,在其发育过程中轴突需要延伸较长的距离才能与下一级神经元或靶细胞形成突触。在这个复杂的移动过程中,神经元轴突在空间分布上形成了精确有序的结构。过去认为这种有序结构的形成主要由形态发生素的化学浓度梯度来指导,而最近的研究发现力学因素对调控轴突的延伸速度与方向发挥着重要的作用。因此,轴突的延伸本质上是一个力化学耦合过程。本文将结合自己过去的工作论述力学因素对轴突延伸的调控机制及相关的信号转导。这一领域的研究将为认识对神经系统疾病的发生以及神经再生提供重要的参考。