The effect of sonic hedgehog on motor neuron positioning in the spinal cord during chicken embryo development

ABSTRACTSonic hedgehog (Shh) is a vertebrate homologue of the secreted Drosophila protein hedgehog, and is expressed by the notochord and the floor plate in the developing spinal cord. Shh provides signals relevant for positional information, cell proliferation, and possibly cell survival depending on the time and location of the expression. Although the role of Shh in providing positional information in the neural tube has been experimentally proven, the exact underlying mechanism still remains unclear. In this study, we report that overexpression of Shh affects motor neuron positioning in the spinal cord during chicken embryo development by inducing abnormalities in the structure of the motor column and motor neuron integration. In addition, Shh overexpression inhibits the expression of dorsal transcription factors and commissural axon projections. Our results indicate that correct location of Shh expression is the key to the formation of the motor column. In conclusion, the overexpression of Shh in the spinal cord not only affects the positioning of motor neurons, but also induces abnormalities in the structure of the motor column.

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Sonic hedgehog synergizes with the extracellular matrix protein vitronectin to induce spinal motor neuron differentiation

Development ◽

10.1242/dev.127.2.333 ◽

2000 ◽

Vol 127 (2) ◽

pp. 333-342 ◽

Cited By ~ 6

Author(s):

S. Pons ◽

E. Marti

Keyword(s):

Extracellular Matrix ◽

Motor Neuron ◽

Sonic Hedgehog ◽

Motor Neurons ◽

Neural Tube ◽

Matrix Protein ◽

Floor Plate ◽

Binding Domain ◽

Extracellular Matrix Protein ◽

Neuron Differentiation

Patterning of the vertebrate neural tube depends on intercellular signals emanating from sources such as the notochord and the floor plate. The secreted protein Sonic hedgehog and the extracellular matrix protein Vitronectin are both expressed in these signalling centres and have both been implicated in the generation of ventral neurons. The proteolytic processing of Sonic hedgehog is fundamental for its signalling properties. This processing generates two secreted peptides with all the inducing activity of Shh residing in the highly conserved 19 kDa amino-terminal peptide (N-Shh). Here we show that Vitronectin is also proteolitically processed in the embryonic chick notochord, floor plate and ventral neural tube and that this processing is spatiotemporally correlated with the generation of motor neurons. The processing of Vitronectin produces two fragments of 54 kDa and 45 kDa, as previously described for Vitronectin isolated from chick yolk. The 45 kDa fragment lacks the heparin-binding domain and the integrin-binding domain, RGD, present in the non-processed Vitronectin glycoprotein. Here we show that N-Shh binds to the three forms of Vitronectin (70, 54 and 45 kDa) isolated from embryonic tissue, although is preferentially associated with the 45 kDa form. Furthermore, in cultures of dissociated neuroepithelial cells, the combined addition of N-Shh and Vitronectin significantly increases the extent of motor neuron differentiation, as compared to the low or absent inducing capabilities of either N-Shh or Vitronectin alone. Thus, we conclude that the differentiation of motor neurons is enhanced by the synergistic action of N-Shh and Vitronectin, and that Vitronectin may be necessary for the proper presentation of the morphogen N-Shh to one of its target cells, the differentiating motor neurons.

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The control of rostrocaudal pattern in the developing spinal cord: specification of motor neuron subtype identity is initiated by signals from paraxial mesoderm

Development ◽

10.1242/dev.125.6.969 ◽

1998 ◽

Vol 125 (6) ◽

pp. 969-982 ◽

Cited By ~ 10

Author(s):

M. Ensini ◽

T.N. Tsuchida ◽

H.G. Belting ◽

T.M. Jessell

Keyword(s):

Spinal Cord ◽

Motor Neuron ◽

Motor Neurons ◽

Neural Tube ◽

Motor Behavior ◽

Neural Tube Closure ◽

Paraxial Mesoderm ◽

Homeodomain Protein ◽

Mesodermal Cell ◽

Developing Spinal Cord

The generation of distinct classes of motor neurons is an early step in the control of vertebrate motor behavior. To study the interactions that control the generation of motor neuron subclasses in the developing avian spinal cord we performed in vivo grafting studies in which either the neural tube or flanking mesoderm were displaced between thoracic and brachial levels. The positional identity of neural tube cells and motor neuron subtype identity was assessed by Hox and LIM homeodomain protein expression. Our results show that the rostrocaudal identity of neural cells is plastic at the time of neural tube closure and is sensitive to positionally restricted signals from the paraxial mesoderm. Such paraxial mesodermal signals appear to control the rostrocaudal identity of neural tube cells and the columnar subtype identity of motor neurons. These results suggest that the generation of motor neuron subtypes in the developing spinal cord involves the integration of distinct rostrocaudal and dorsoventral patterning signals that derive, respectively, from paraxial and axial mesodermal cell groups.

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Lower Motor Neuron Disease with Accumulation of Neurofilaments in a Cat

Veterinary Pathology ◽

10.1177/030098587601300604 ◽

1976 ◽

Vol 13 (6) ◽

pp. 428-435 ◽

Cited By ~ 29

Author(s):

M. Vandevelde ◽

C. E. Greene ◽

E. J. Hoff

Keyword(s):

Spinal Cord ◽

Motor Neuron ◽

Motor Neuron Disease ◽

Histological Examination ◽

Muscle Atrophy ◽

Motor Neurons ◽

Nerve Cells ◽

Lower Motor Neuron ◽

Motor Neuron Diseases ◽

Lower Motor Neuron Disease

A young cat had signs of tetraparesis that progressed to tetraplegia within a few weeks. Clinically, there was lower motor neuron disease with areflexia and muscle atrophy in all limbs. Degeneration of the motor neurons in the spinal cord was seen on histological examination. Ultrastructurally, the degeneration of nerve cells was characterized by abnormal proliferation of neurofilaments. These findings were compared to other motor neuron diseases and neurofibrillary accumulations in man and animals.

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Transgenic mice for interleukin 3 develop motor neuron degeneration associated with autoimmune reaction against spinal cord motor neurons

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.95.19.11354 ◽

1998 ◽

Vol 95 (19) ◽

pp. 11354-11359 ◽

Cited By ~ 28

Author(s):

C. Chavany ◽

C. Vicario-Abejon ◽

G. Miller ◽

M. Jendoubi

Keyword(s):

Spinal Cord ◽

Transgenic Mice ◽

Motor Neuron ◽

Motor Neurons ◽

Motor Neuron Degeneration ◽

Neuron Degeneration ◽

Autoimmune Reaction ◽

Interleukin 3

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A Comprehensive Profile of ChIP-Seq-Based Olig2 Target Genes in Motor Neuron Progenitor Cells Suggests the Possible Involvement of Olig2 in the Pathogenesis of Amyotrophic Lateral Sclerosis

Journal of Central Nervous System Disease ◽

10.4137/jcnsd.s23210 ◽

2015 ◽

Vol 7 ◽

pp. JCNSD.S23210 ◽

Cited By ~ 7

Author(s):

Jun-Ichi Satoh ◽

Naohiro Asahina ◽

Shouta Kitano ◽

Yoshihiro Kino

Keyword(s):

Spinal Cord ◽

Amyotrophic Lateral Sclerosis ◽

Motor Neuron ◽

Progenitor Cells ◽

Motor Neurons ◽

Target Genes ◽

Molecular Networks ◽

Bhlh Transcription Factor ◽

Wide Range ◽

Lateral Sclerosis

Background Amyotrophic lateral sclerosis (ALS) is an intractable neurodegenerative disease that primarily affects motor neurons in the cerebral cortex and the spinal cord. Recent evidence indicates that dysfunction of oligodendrocytes is implicated in the pathogenesis of ALS. The basic helix–loop–helix (bHLH) transcription factor Olig2 plays a pivotal role in the development of both motor neurons and oligodendrocytes in the progenitor of motor neuron (pMN) domain of the spinal cord, supporting evidence for the shared motor neuron/oligodendrocyte lineage. However, a comprehensive profile of Olig2 target genes in pMNs and oligodendrocyte progenitor cells (OPCs) with relevance to the pathogenesis of ALS remains to be characterized. Methods By analyzing the ChIP-Seq datasets numbered SRP007566 and SRP015333 with the Strand NGS program, we identified genome-wide Olig2 target genes in pMNs and OPCs, followed by molecular network analysis using three distinct bioinformatics tools. Results We identified 5966 Olig2 target genes in pMNs, including Nkx2.2, Pax6, Irx3, Ngn2, Zep2 (Cip1), Trp3, Mnx1 (Hb9), and Cdkn1a, and 1553 genes in OPCs. The genes closely related to the keyword “alternative splicing” were enriched in the set of 740 targets overlapping between pMNs and OPCs. Furthermore, approximately one-third of downregulated genes in purified motor neurons of presymptomatic mutant SOD1 transgenic mice and in lumbar spinal cord tissues of ALS patients corresponded to Olig2 target genes in pMNs. Molecular networks of Olig2 target genes indicate that Olig2 regulates a wide range of genes essential for diverse neuronal and glial functions. Conclusions These observations lead to a hypothesis that aberrant regulation of Olig2 function, by affecting biology of both motor neurons and oligodendrocytes, might be involved in the pathogenesis of ALS.

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Groucho/TLE opposes axial to hypaxial motor neuron development

10.1101/2020.03.10.986323 ◽

2020 ◽

Author(s):

Adèle Salin-Cantegrel ◽

Rola Dali ◽

Jae Woong Wang ◽

Marielle Beaulieu ◽

Mira Deshmukh ◽

...

Keyword(s):

Spinal Cord ◽

Motor Neuron ◽

Motor Neurons ◽

Molecular Mechanisms ◽

List Type ◽

Neuron Development ◽

In Ovo ◽

Motor Circuits ◽

Axial Muscles ◽

Muscle Innervation

ABSTRACTSpinal cord motor neuron diversity and the ensuing variety of motor circuits allow for the processing of elaborate muscular behaviours such as body posture and breathing. Little is known, however, about the molecular mechanisms behind the specification of axial and hypaxial motor neurons controlling postural and respiratory functions respectively. Here we show that the Groucho/TLE (TLE) transcriptional corepressor is a multi-step regulator of axial and hypaxial motor neuron diversification in the developing spinal cord. TLE first promotes axial motor neuron specification at the expense of hypaxial identity by cooperating with non-canonical WNT5A signalling within the motor neuron progenitor domain. TLE further acts during post-mitotic motor neuron diversification to promote axial motor neuron topology and axonal connectivity whilst suppressing hypaxial traits. These findings provide evidence for essential and sequential roles of TLE in the spatial and temporal coordination of events regulating the development of motor neurons influencing posture and controlling respiration.HIGHLIGHTSGroucho/TLE mediates non-canonical WNT signalling in developing motor neuronsNon canonical WNT:TLE pathway regulates thoracic motor neuron diversificationTLE promotes axial while inhibiting hypaxial motor neuron developmentTLE influences developing motor neuron topology and muscle innervationIN BRIEFSalin-Cantegrel et al use in ovo engineered approaches to show that a non-canonical WNT:TLE pathway coordinates temporally and spatially separated elements of motor neuron diversification, repressing hypaxial motor neuron development to promote the axial fate.GRAPHICAL ABSTRACTTLE contribution to the development of thoracic somatic motor columnsProgenitor cells in the ventral pMN domain are exposed to higher concentrations of non-canonical WNTs and express more TLE. Cooperation of non-canonical WNTs and TLE renders ventral pMN progenitors refractory to a respiratory MN fate, thereby contributing to the separation of MMC and RMC MN lineages. Differentiating MNs that maintain high TLE expression also maintain LHX3 expression, adopt axial motor neuron topology and connect to axial muscles. TLE activity in differentiating MMC MNs prevents the acquisition of respiratory MN topology and innervation traits.

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“Stretch-Growth” of Motor Axons in Custom Mechanobioreactors to Generate Long-Projecting Axonal and Axonal-Myocyte Constructs

10.1101/598755 ◽

2019 ◽

Cited By ~ 1

Author(s):

Kritika S. Katiyar ◽

Laura A. Struzyna ◽

Suradip Das ◽

D. Kacy Cullen

Keyword(s):

Spinal Cord ◽

Nervous System ◽

Motor Neuron ◽

Motor Neurons ◽

Motor Axon ◽

Central Feature ◽

Motor Axons ◽

Ganglion Neurons

AbstractThe central feature of peripheral motor axons is their remarkable lengths as they project from a motor neuron residing in the spinal cord to an often-distant target muscle. However, to date in vitro models have not replicated this central feature owing to challenges in generating motor axon tracts beyond a few millimeters in length. To address this, we have developed a novel combination of micro-tissue engineering and mechanically assisted growth techniques to create long-projecting centimeter-scale motor axon tracts. Here, primary motor neurons were isolated from the spinal cords of rats and induced to form engineered micro-spheres via forced aggregation in custom micro-wells. This three-dimensional micro-tissue yielded healthy motor neurons projecting dense, fasciculated axonal tracts. Within our custom-built mechanobioreactors, motor neuron culture conditions, neuronal/axonal architecture, and mechanical growth conditions were systematically optimized to generate parameters for robust and efficient “stretch-growth” of motor axons. We found that axons projecting from motor neuron aggregates were able to respond to axon displacement rates at least 10 times greater than that tolerated by axons projecting from dissociated motor neurons. The growth and structural characteristics of these stretch-grown motor axons were compared to benchmark stretch-grown axons from sensory dorsal root ganglion neurons, revealing similar axon densities yet increased motor axon fasciculation. Finally, motor axons were integrated with myocytes and then stretch-grown to create novel long-projecting axonal-myocyte constructs that better recreate characteristic dimensions of native nerve-muscle anatomy. This is the first demonstration of mechanical elongation of spinal cord motor axons and may have applications as anatomically inspired in vitro testbeds or as tissue engineered “living scaffolds” for targeted axon tract reconstruction following nervous system injury or disease.Significance StatementWe have developed novel axon tracts of unprecedented lengths spanning either two discrete populations of neurons or a population of neurons and skeletal myocytes. This is the first demonstration of “stretch-grown” motor axons that recapitulate the structure of spinal motor neurons in vivo by projecting long axons from a pool of motor neurons to distant targets, and may have applications as anatomically inspired in vitro test beds to study mechanisms of axon growth, development, and neuromuscular function in anatomically accurate axo-myo constructs; as well as serve as “living scaffolds” in vivo for targeted axon tract reconstruction following nervous system trauma.

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Three forms of the scratch reflex in the spinal turtle: central generation of motor patterns

Journal of Neurophysiology ◽

10.1152/jn.1985.53.6.1517 ◽

1985 ◽

Vol 53 (6) ◽

pp. 1517-1534 ◽

Cited By ~ 77

Author(s):

G. A. Robertson ◽

L. I. Mortin ◽

J. Keifer ◽

P. S. Stein

Keyword(s):

Spinal Cord ◽

Motor Neuron ◽

Neuromuscular Blockade ◽

Motor Neurons ◽

Muscle Activity ◽

Activity Patterns ◽

Knee Extensor ◽

The Body ◽

Retractor Muscle ◽

Neuron Activity

A turtle with a complete transection of the spinal cord, termed a spinal turtle, exhibits three types or “forms” of the scratch reflex: the rostral scratch, pocket scratch, and caudal scratch (21). Each scratch form is elicited by tactile stimulation of a site on the body surface innervated by afferents entering the spinal cord caudal to the transection. We recorded electromyographic (EMG) potentials from the hindlimb during each of the three forms of the scratch in the spinal turtle (see Fig. 1). Common to all scratch forms is the rhythmic alternation of the activity of the hip protractor muscle (VP-HP) and hip retractor muscle (HR-KF). Each form of the scratch displays a characteristic timing of the activity of the knee extensor muscle (FT-KE) with respect to the cycle of activity of the hip muscles VP-HP and HR-KF. In a rostral scratch, activation of FT-KE occurs during the latter portion of VP-HP activation. In a pocket scratch, activation of FT-KE occurs during HR-KF activation. In a caudal scratch, activation of FT-KE occurs after the cessation of HR-KF activation. The timing characteristics of these muscle activity patterns correspond to the timing characteristics of changes in the angles of the knee joint and the hip joint obtained with movement analyses (21). We recorded electroneurographic (ENG) potentials from peripheral nerves of the hindlimb during each of the three forms of the “fictive” scratch in the spinal turtle immobilized with neuromuscular blockade (see Fig. 4). Common to all forms of the fictive scratch is the rhythmic alternation of the activity of hip protractor motor neurons (VP-HP) and hip retractor motor neurons (HR-KF). Each form displays a characteristic timing of the activity of knee extensor motor neurons (FT-KE) with respect to the cycle of VP-HP and HR-KF motor neuron activity. The timing characteristics of these motor neuron activity patterns are similar to the timing characteristics of the muscle activity patterns obtained in the preparation with movement (cf. Figs. 1 and 4). The motor pattern for each scratch form is generated centrally within the spinal cord. In the spinal immobilized preparation, neuromuscular blockade prevents both limb movement and phasic sensory input, and complete spinal transection isolates the cord from supraspinal input.(ABSTRACT TRUNCATED AT 400 WORDS)

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An Inherited Lower Motor Neuron Disease of Pigs: Clinical Signs in Two Litters and Pathology of an Affected Pig

Journal of Veterinary Diagnostic Investigation ◽

10.1177/104063879400600112 ◽

1994 ◽

Vol 6 (1) ◽

pp. 62-71 ◽

Cited By ~ 3

Author(s):

Donal O'Toole ◽

James Ingram ◽

Val Welch ◽

Katie Bardsley ◽

Tom Haven ◽

...

Keyword(s):

Spinal Cord ◽

Motor Neuron ◽

Motor Neurons ◽

Clinical Signs ◽

Spinal Nerve ◽

Neuronal System ◽

Motor Neuron Diseases ◽

System Degeneration ◽

Progressive Neurodegeneration ◽

Gross Lesions

A chronic progressive neurodegeneration, called hereditary porcine neuronal system degeneration (HPNSD), was recognized in a swine herd in Devon, England. Adult pigs that were presumed carriers of the dominantly inherited trait for HPNSD were transferred from England, where a breeding colony was maintained for 9 years, to the Wyoming State Veterinary Laboratory (WSVL) for study. Two litters of affected piglets were born to 2 carrier sows at the WSVL. Clinical signs of muscular tremors, paresis, or ataxia developed at 12–59 days of age in 4 of 6 liveborn pigs. Three other pigs were stillborn. In the 4 affected livebom pigs, clinical signs progressed and included symmetrical (3 pigs) or asymmetrical (1 pig) posterior paresis, bilateral knuckling of metatarsal-phalangeal or carpal joints, poor exercise tolerance, and in 1 pig, marked hind limb hypermetria. A 34-kg gilt exhibiting clinical signs of muscular tremors and posterior paresis and clinical signs for 22 days was euthanized and examined postmortem at 83 days of age. Apart from decubitus ulcers, gross lesions were absent. Microscopically, perikaryal vacuolation and osmiophilic lipid droplets were observed in atrophic alpha motor neurons in the spinal cord. There was axonal (Wallerian) degeneration in sulcomarginal and dorsal spinocerebellar tracts. Axonal degeneration also involved ventral but not dorsal spinal nerve roots, and was present in eight peripheral nerves sampled for histopathology. Changes in skeletal muscles were consistent with denervation atrophy and were most pronounced in M. tibialis cranialis of the 6 muscles sampled. Immunohistochemical staining of spinal cord for phosphorylated and nonphosphorylated neurofilaments did not reveal abnormal patterns, unlike some well-characterized inherited motor neuron diseases in other species.

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