Developing Schwann Cells Research Articles

Regulation of the myelin gene periaxin provides evidence for Krox-20-independent myelin-related signalling in Schwann cells

We investigated the role of Krox-20 (Egr2), a transcription factor that regulates myelination, in controlling the myelin-associated protein periaxin. In developing Schwann cells, periaxin immunoreactivity appeared at least 2 days before Krox-20-immunopositive nuclei. Consistent with this, in Krox-20 null mice periaxin was upregulated on schedule, albeit to a lower level. In culture Krox-20 and periaxin were upregulated by cAMP as expected for myelin genes. Only those cells with the highest periaxin levels also expressed Krox-20, while other periaxin-positive cells remained Krox-20-negative. Furthermore, cAMP elevated periaxin even in Krox-20 null cells. We also found that in culture enforced Krox-20 expression induced expression of periaxin mRNA and protein in the absence of cAMP elevating agents, and that this induction was inhibited by the co-repressor NAB2. These findings reveal a dual mechanism for periaxin regulation and suggest that the role of Krox-20 is to amplify an earlier Krox-20-independent activation of the periaxin gene. Thus the axonal signals responsible for myelination are only partially transduced in Schwann cells by mechanisms that depend on Krox-20.

A dual role of erbB2 in myelination and in expansion of the Schwann cell precursor pool

Neuregulin-1 provides an important axonally derived signal for the survival and growth of developing Schwann cells, which is transmitted by the ErbB2/ErbB3 receptor tyrosine kinases. Null mutations of the neuregulin-1, erbB2, or erbB3 mouse genes cause severe deficits in early Schwann cell development. Here, we employ Cre-loxP technology to introduce erbB2 mutations late in Schwann cell development, using a Krox20-cre allele. Cre-mediated erbB2 ablation occurs perinatally in peripheral nerves, but already at E11 within spinal roots. The mutant mice exhibit a widespread peripheral neuropathy characterized by abnormally thin myelin sheaths, containing fewer myelin wraps. In addition, in spinal roots the Schwann cell precursor pool is not correctly established. Thus, the Neuregulin signaling system functions during multiple stages of Schwann cell development and is essential for correct myelination. The thickness of the myelin sheath is determined by the axon diameter, and we suggest that trophic signals provided by the nerve determine the number of times a Schwann cell wraps an axon.

A Dual Role Of Erbb2 In Myelination And In Expansion Of The Schwann Cell Precursor Pool

Neuregulin‐1 provides an important axonally derived signal for the survival and growth of developing Schwann cells, which is transmitted by the ErbB2/ ErbB3 receptor tyrosine kinases. Null mutations of the neuregulin‐1, erbB2, or erbB3 mouse genes cause severe deficits in early Schwann cell development. Here, we employ Cre‐loxP technology to introduce erbB2 mutations late in Schwann cell development, using a Krox20‐cre allele. Cre‐mediated erbB2 ablation occurs perinatally in peripheral nerves, but already at E11 within spinal roots. The mutant mice exhibit a widespread peripheral neuropathy characterized by abnormally thin myelin sheaths, containing fewer myelin wraps. In addition, in spinal roots the Schwann cell precursor pool is not correctly established. Thus, the Neuregulin signaling system functions during multiple stages of Schwann cell development and is essential for correct myelination. The thickness of the myelin sheath is determined by the axon diameter, and we suggest that trophic signals provided by the nerve determine the number of times a Schwann cell wraps an axon.

A dual role of erbB2 in myelination and in expansion of the schwann cell precursor pool.

Neuregulin-1 provides an important axonally derived signal for the survival and growth of developing Schwann cells, which is transmitted by the ErbB2/ErbB3 receptor tyrosine kinases. Null mutations of the neuregulin-1, erbB2, or erbB3 mouse genes cause severe deficits in early Schwann cell development. Here, we employ Cre-loxP technology to introduce erbB2 mutations late in Schwann cell development, using a Krox20-cre allele. Cre-mediated erbB2 ablation occurs perinatally in peripheral nerves, but already at E11 within spinal roots. The mutant mice exhibit a widespread peripheral neuropathy characterized by abnormally thin myelin sheaths, containing fewer myelin wraps. In addition, in spinal roots the Schwann cell precursor pool is not correctly established. Thus, the Neuregulin signaling system functions during multiple stages of Schwann cell development and is essential for correct myelination. The thickness of the myelin sheath is determined by the axon diameter, and we suggest that trophic signals provided by the nerve determine the number of times a Schwann cell wraps an axon.

The role of perisynaptic Schwann cells in development of neuromuscular junctions in the frog (Xenopus laevis).

Fluorescence microscopy was used to study the behavior of perisynaptic Schwann cells (PSCs) in relation to motor nerve terminals and postsynaptic clusters of acetylcholine receptors, during the development of the neuromuscular junction (NMJ) in the frog Xenopus laevis. Pectoral (supracoracoideus) muscles were labeled with monoclonal antibody 2A12 for Schwann cells, the dye FM4-64 for nerve terminals (NTs), alpha-bungarotoxin for acetylcholine receptors (AChRs), and Hoechst 33258 for cellular nuclei, in animals from tadpole stage 57 to fully grown adults. When muscle fibers first appeared in stage 57, NMJs consisted of tightly apposed NTs and AChRs and were only partially covered with PSCs or their processes. Within a few stages, PSCs fully occupied and overgrew the NMJs, extending fine sprouts between a few micrometers and hundreds of micrometers beyond the borders of the junction. Sprouts of PSCs were most abundant during the time when secondary myogenesis, synaptogenesis, and synaptic growth occurred at their highest rates. PSCs were recruited to NMJs during synaptic growth, at rates between 1.3 PSCs/100 microm junctional length early on and 0.4 PSCs/100 microm later. Shortly after metamorphosis, PSC sprouts disappeared and NMJs acquired the adult appearance, in which PSCs, NTs, and AChRs were mostly congruent. The results suggest that, although PSCs may not be required for initial nerve-muscle contacts, PSCs sprouts lead synaptic growth and play a role in the extension and maturation of developing NMJs.

Developing Schwann Cells Acquire the Ability to Survive without Axons by Establishing an Autocrine Circuit Involving Insulin-Like Growth Factor, Neurotrophin-3, and Platelet-Derived Growth Factor-BB

Although Schwann cell precursors from early embryonic nerves die in the absence of axonal signals, Schwann cells in older nerves can survive in the absence of axons in the distal stump of transected nerves. This is crucially important, because successful axonal regrowth in a damaged nerve depends on interactions with living Schwann cells in the denervated distal stump. Here we show that Schwann cells acquire the ability to survive without axons by establishing an autocrine survival loop. This mechanism is absent in precursors. We show that insulin-like growth factor, neurotrophin-3, and platelet-derived growth factor-BB are important components of this autocrine survival signal. The secretion of these factors by Schwann cells has significant implications for cellular communication in developing nerves, in view of their known ability to regulate survival and differentiation of other cells including neurons.

Promyelinating Schwann Cells Express Tst-1/SCIP/Oct-6

Tst-1/SCIP/Oct-6, a POU domain transcription factor, is transiently expressed by developing Schwann cells and is required for their normal development into a myelinating phenotype. In tst-1/scip/oct-6-null sciatic nerves, Schwann cells are transiently arrested at the "promyelinating" stage, when they have a one-to-one relationship with an axon but before they have elaborated a myelin sheath. To determine when Schwann cells express Tst-1/SCIP/Oct-6, we examined beta-galactosidase (beta-gal) expression in heterozygous tst-1/scip/oct-6 mice, in which one copy of the tst-1/scip/oct-6 gene has been replaced with the LacZ gene. beta-Gal expression from the LacZ gene seems to parallel Tst-1/SCIP/Oct-6 expression from the endogenous tst-1/scip/oct-6 gene in developing and regenerating sciatic nerves. Furthermore, electron microscopic examination of 5bromo-4-chloro-3-indolyl-beta-D-galactopyranoside- (X-gal) and halogenated indolyl-beta-D-galactoside- (Bluo-gal) stained nerves showed that promyelinating Schwann cells express the highest levels of beta-gal, both in developing and in regenerating nerves. Thus, the expression of beta-gal, a surrogate marker of Tst-1/SCIP/Oct-6, peaks at the same stage of Schwann cell development at which development is arrested in tst-1/scip/oct-6-null mice, indicating that Tst-1/SCIP/Oct-6 has a critical role in promyelinating Schwann cells.

Severe neuropathies in mice with targeted mutations in the ErbB3 receptor.

Neuregulins and their specific receptors, members of the ErbB family of tyrosine kinases, have been implicated in the control of growth and development of Schwann cells, specialized cells that wrap around nerve axons to provide electrical insulation. Here we use gene targeting to generate mice that lack ErbB3, a high-affinity neuregulin receptor. Homozygous erbB3 mutant embryos lack Schwann-cell precursors and Schwann cells that accompany peripheral axons of sensory and motor neurons. The initial development of motor neurons and sensory neurons of dorsal root ganglia occurs as it should, but at later stages most motor neurons (79%) and sensory neurons in dorsal root ganglia (82%) undergo cell death in erbB3 mutant embryos. Degeneration of the peripheral nervous system in erbB3 mutant pups is thus much more severe than the cell death in mice that lack neurotrophins or neurotrophin receptors. We also show that ErbB3 functions in a cell-autonomous way during the development of Schwann cells, but not in the survival of sensory or motor neurons. Our results indicate that sensory and motor neurons require factors for their survival that are provided by developing Schwann cells.

Neuregulin Expression in PNS Neurons: Isoforms and Regulation by Target Interactions

Neuregulins have several important functions in the development of the peripheral nervous system, acting on both developing Schwann cells and muscle fibers. To determine whether these factors are also important for peripheral nerve regeneration, we have analyzed neuregulin expression in motor and sensory neurons by Northern blots andin situhybridization. The results of this analysis show that the predominant neuregulin isoform expressed in these neurons is a novel transmembrane splice variant. After axotomy, there is a rapid decline in neuregulin expression in both motor and sensory neurons, but following reinnervation of target tissues, neuregulin expression returns to near normal levels. These results indicate that the normal expression of neuregulins in these neurons is maintained by the interactions with target tissues.

Premature Schwann Cell Differentiation and Hypermyelination in Mice Expressing a Targeted Antagonist of the POU Transcription Factor SCIP

The transcription factor SCIP is expressed by immature neurons and Schwann cells of the developing central and peripheral nervous systems, but this expression is largely extinguished when these cells fully differentiate. In immature Schwann cells in vitro, SCIP acts as a repressor of the myelin-specific genes that mark full differentiation. We have generated transgenic mice that express a dominant-negative antagonist of SCIP, specifically targeted to developing Schwann cells. This antagonist—designated ΔSCIP—is transcriptionally inactive, but retains full DNA-binding activity. Mice that express ΔSCIP exhibit a debilitating peripheral neuropathy that results from developmentally advanced Schwann cell differentiation, over-expression of myelin-specific gene products, and hypermyelination. These results suggest that SCIP functions as a transcriptional sensor of differentiation cues and thereby regulates the time and place at which Schwann cells differentiate.

Cell-specific action and mutable structure of a transcription factor effector domain.

POU proteins are cell-specific transcription factors whose specificity of action has been attributed to protein-DNA and protein-protein interactions mediated by their DNA-binding (POU) domains. Here we report that transcriptional activation by SCIP, a POU protein expressed by developing Schwann cells, is dependent on an amino-terminal effector domain and that this domain mediates cell-specific transactivation in the complete absence of the POU domain. When fused to a heterologous DNA-binding domain, this SCIP domain is a potent transactivator in Schwann cells but is inactive in three heterologous cell types. The primary structure of the SCIP amino-terminal domain is novel but contains a polymorphic string of alanine residues similar to those found in several other transcription factors. Although previously hypothesized to be important for transcription factor activity, we find that the SCIP string is functionally irrelevant. We propose that homopolymers of alanine, and certain other amino acids, do not represent a motif required for transcription factor function but instead reflect regions of unstable DNA related to those associated with four recently characterized human genetic disorders.

High and low affinity NGF receptor mRNAs in human foetal spinal cord and ganglia.

The cellular localization of mRNAs encoding the low affinity NGF receptor (here referred to as LANR) and the putative high affinity receptor for NGF, trk, have been studied in the human foetal spinal and sympathetic ganglia, and spinal cord, using in situ hybridization. The receptor mRNAs were highly expressed in the spinal and sympathetic ganglia, with most but not all neurons expressing both LANR and trk mRNA. Spinal nerve rootlets distal to the spinal ganglia expressed LANR but not trk mRNA, confirming the presence of the low affinity receptor in developing Schwann cells. In the spinal cord, LANR mRNA was found throughout the medial and lateral motor columns while, trk mRNA was detected in scattered cells in the dorsal aspect of developing grey matter.

Expression and Activity of the POU Transcription Factor SCIP

POU proteins have been shown to transcriptionally active cell-specific genes and to participate in the determination of cell fate. It is therefore thought that these proteins function in development through the stable activation of genes that define specific developmental pathways. Evidence is provided here for an alternative mode of action. The primary structure of SCIP, a POU protein expressed by developing Schwann cells of the peripheral nervous system, was deduced and SCIP activity was studied. Both in normal development and in response to nerve transection, SCIP expression was transiently activated only during the period of rapid cell division that separates the premyelinating and myelinating phases of Schwann cell differentiation. In cotransfection assays, SCIP acted as a transcriptional repressor of myelin-specific genes.

Electronmicroscopic observations on Auerbach's plexus in a 12 mm human embryo.

In a human embryo of 12 mm crown-rump length, the morphology of the primordial plexus of Auerbach in the small intestine was studied by the aid of the electronmicroscope. At this stage of development, no muscle layers have as yet differentiated. In the outer half of the intestinal wall, small disseminated cell clusters appeared, associated with blood capillaries and encapsulated by a single layer of spindle-shaped cells presumably corresponding to the capsular layer of Auerbach's plexus in the adult. This capsule is separated from the cell cluster by a subacpsular space. The cell clusters are made up of neuroblasts, developing Schwann cells, and processes emitted by both cell types. The cytoplasm of the neuroblast contains a Golgi complex, mitochondria, endoplasmic reticulum with or without osmiophilic particles, free RNA-particles, tubular structures and densecore bodies. In the cytoplasmic area at the base of the neural process, the cytoplasmic elements mentioned above are especially abundant. The axoplasm of the neuronal process contains dense-core bodies as well as tubular structures having a fairly uniform diameter of 200 to 250 A and extending into the neural process from the perikaryon. The dense-core bodies found in both the perikaryon and the axoplasm of the neuroblasts are similar in size and in shape to the dense bodies described by many authors in mature neurons and assumed to contain neurotransmittors. In addition to the dense-core bodies, the neuroblastic processes occasionally exhibit accumulations of small clear vesicles comparable to those commonly found in synaptic structures in adult animals. None of other structural details characterizing synaptic junctions could be identified. As yet, there is no evidence that the first appearance of either dense-core or small clear vesicles coincides with the onset of neuronal activity and interneuronal impulse transmission.