ErbB transmembrane tyrosine kinase receptors are expressed by sensory and motor neurons projecting into sciatic nerve.

Adult spinal cord motor and dorsal root ganglion (DRG) sensory neurons express multiple neuregulin-1 (NRG-1) isoforms that act as axon-associated factors promoting neuromuscular junction formation and Schwann cell proliferation and differentiation. NRG-1 isoforms are also expressed by muscle and Schwann cells, suggesting that motor and sensory neurons are themselves acted on by NRG-1 isoforms produced by their peripheral targets. To test this hypothesis, we examined the expression of the NRG-1 receptor subunits erbB2, erbB3, and erbB4 in rat lumbar DRG and spinal cord. All three erbB receptors are expressed in these tissues. Sciatic nerve transection, an injury that induces Schwann cell expression of NRG-1, alters erbB expression in DRG and cord. Virtually all DRG neurons are erbB2- and erbB3-immunoreactive, with erbB4 also detectable in many neurons. In spinal cord white matter, erbB2 and erbB4 antibodies produce dense punctate staining, whereas the erbB3 antibody primarily labels glial cell bodies. Spinal cord dorsal and ventral horn neurons, including alpha-motor neurons, exhibit erbB2, erbB3, and erbB4 immunoreactivity. Spinal cord ventral horn also contains a population of small erbB3+/S100beta+/GFAP- cells (GFAP-negative astrocytes or oligodendrocytes). We conclude that sensory and motor neurons projecting into sciatic nerve express multiple erbB receptors and are potentially NRG-1 responsive.     

Colonic epithelial expression of ErbB2 is required for postnatal maintenance of the enteric nervous system

We utilized the Cre-LoxP system to establish erbB2 conditional mutant mice in order to investigate the role of erbB2 in postnatal development of the enteric nervous system. The erbB2/nestin-Cre conditional mutants exhibit retarded growth, distended colons, and premature death, resembling human Hirschsprung's disease. Enteric neurons and glia are present at birth in the colon of erbB2/nestin-Cre mutants; however, a marked loss of multiple classes of enteric neurons and glia occurs by 3 weeks of age. Furthermore, we demonstrate that the requirement for erbB2 in maintaining the enteric nervous system is not cell autonomous, but rather erbB2 signaling in the colonic epithelia is required for the postnatal survival of enteric neurons and glia.     

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.     

ErbB4 signaling during breast and neural development: novel genetic models reveal unique ErbB4 activities

The erbB4 gene encodes one of the four members of the mammalian ErbB family of transmembrane tyrosine kinases. The ErbB4 protein plays a role as a receptor for the neuregulins, a large group of structurally related molecules and a few other epidermal growth factor (EGF)-related polypeptides, such as heparin-binding EGF, betacellulin and epiregulin. The importance of this receptor tyrosine kinase in development has been demonstrated by the generation of mice with a targeted inactivation of the erbB4 gene. Such mice die by embryonic day eleven due to defective trabeculation in the heart, precluding analysis of phenotypes at later stages in development and in the adult. Now, using two unique genetic approaches our laboratories succeeded in overcoming this obstacle. In the first approach, the heart defects of ErbB4 null mutant mice were rescued by transgenic expression of an ErbB4 cDNA under a cardiac-specific myosin promoter. This allowed the generation of ErbB4 mutants that develop into adulthood and are fertile. In the second approach, the role of ErbB4 during mammary gland development was specifically addressed by Cre-mediated deletion of both erbB4 alleles within the mammary epithelium. Below we discuss the progress made studying these genetic models in understanding the physiological roles of ErbB4 with a focus on the mammary gland and the nervous system.     

ErbB4 Signaling During Breast and Neural Development: Novel Genetic Models Reveal Unique ErbB4 Activities

The erbB4 gene encodes one of the four members of the mammalian ErbB family of transmembrane tyrosine kinases. The ErbB4 protein plays a role as a receptor for the neuregulins, a large group of structurally related molecules and a few other epidermal growth factor (EGF)-related polypeptides, such as heparin-binding EGF, betacellulin and epiregulin. The importance of this receptor tyrosine kinase in development has been demonstrated by the generation of mice with a targeted inactivation of the erbB4 gene. Such mice die by embryonic day eleven due to defective trabeculation in the heart, precluding analysis of phenotypes at later stages in development and in the adult. Now, using two unique genetic approaches our laboratories succeeded in overcoming this obstacle. In the first approach, the heart defects of ErbB4 null mutant mice were rescued by transgenic expression of an ErbB4 cDNA under a cardiac-specific myosin promoter. This allowed the generation of ErbB4 mutants that develop into adulthood and are fertile. In the second approach, the role of ErbB4 during mammary gland development was specifically addressed by Cre-mediated deletion of both erbB4 alleles within the mammary epithelium. Bellow we discuss the progress made studying these genetic models in understanding the physiological roles of ErbB4 with a focus on the mammary gland and the nervous system.     

Neuregulin induces the rapid association of focal adhesion kinase with the erbB2-erbB3 receptor complex in schwann cells

Neuregulins signal cells by binding to an activating hetero- and homodimeric forms of the neuregulin receptors HER2 (erbB2), HER3 (erbB3), and HER4 (erbB4). Axonally derived neuregulin signals myelin forming cells of the central and peripheral nervous systems through different receptor complexes: oligodendrocytes through erbB2/erbB4 heterodimers and Schwann cells through erbB2/erbB3 heterodimers. Since the leading edge of myelinating cells interacts directly with the axonal surface, we were interested in determining if signaling molecules localized at the leading edge associate with activated neuregulin receptors. We found a novel association between neuregulin receptors and focal adhesion kinase (FAK) in primary cultures of Schwann cells. Following stimulation with ligand, maximal binding of FAK to HER2 occurred by 1 min whereas maximal binding to HER3 was delayed to approximately 7 min. FAK is localized in focal adhesions of Schwann cells. We have previously shown HER2 and HER3 are distributed evenly throughout the plasmalemma. Neuregulins thus use FAK to transmit intracellular signals and the differential kinetics of FAK association with individual neuregulin receptors, as well as its restricted subcellular localization, may play a role in specifying biologic responses.     

ErbB receptors and the development of the nervous system

Tyrosine kinase receptors and their ligands allow communication between cells in the developing and adult organism. An extensive line of research has revealed that ‘neuregulins’, a family of EGF-like factors that signal via ErbB receptors, are used frequently for cell communication during nervous system development, and control a spectacular spectrum of developmental processes. For instance, during development of the peripheral nervous system, Schwann cells require neuronally-produced neuregulin (Nrg1) for growth, migration and myelination, neural crest cells rely on mesenchymally-generated Nrg1 signals for migration, while muscle requires neuronally-produced Nrg1 for the differentiation of a muscle spindle. In the central nervous system, neuregulin signals allow cells to act as guideposts or as barriers for axons during pathfinding. Neuregulin signals are also important in other organs, but the nervous system functions have received recently considerable attention due to the finding that particular haplotypes of Nrg1 and ErbB4 predispose to schizophrenia. Understanding the neuregulin signaling system can thus contribute to define causes of this devastating mental disorder.     

In vivo knockdown of ErbB3 in mice inhibits Schwann cell precursor migration

The myelin sheath insulates neuronal axons and markedly increases the nerve conduction velocity. In the peripheral nervous system (PNS), Schwann cell precursors migrate along embryonic neuronal axons to their final destinations, where they eventually wrap around individual axons to form the myelin sheath after birth. ErbB2 and ErbB3 tyrosine kinase receptors form a heterodimer and are extensively expressed in Schwann lineage cells. ErbB2/3 is thought to be one of the primary regulators controlling the entire Schwann cell development. ErbB3 is the bona fide Schwann cell receptor for the neuronal ligand neuregulin-1. Although ErbB2/3 is well known to regulate both Schwann cell precursor migration and myelination by Schwann cells in fishes, it still remains unclear whether in mammals, ErbB2/3 actually regulates Schwann cell precursor migration. Here, we show that knockdown of ErbB3 using a Schwann cell-specific promoter in mice causes delayed migration of Schwann cell precursors. In contrast, littermate control mice display normal migration. Similar results are seen in an in vitro migration assay using reaggregated Schwann cell precursors. Also, ErbB3 knockdown in mice reduces myelin thickness in sciatic nerves, consistent with the established role of ErbB3 in myelination. Thus, ErbB3 plays a key role in migration, as well as in myelination, in mouse Schwann lineage cells, presenting a genetically conservative role of ErbB3 in Schwann cell precursor migration.     

Adult rat otic placode-derived neurons and sensory epithelium express all four erbB receptors: a role in regulating vestibular ganglion neuron viability.

The erbB receptor family consists of erbB1/epidermal growth factor receptor, erbB2/neu, erbB3, and erbB4, all of which have been implicated in cell proliferation, differentiation, and survival in several tissues. In the nervous system, these family members can function in a trophic capacity for certain subpopulations of neurons and some types of non-neuronal cells. Vestibular sensory epithelial cells and vestibular ganglion neurons are derived from ectodermal otic placode and are essential components of the peripheral vestibular system, the sensory system for balance. Recent studies in mammals suggest that certain ligands of the epidermal growth factor receptor can induce proliferation of vestibular sensory epithelial cells. We now show that vestibular ganglion neurons and vestibular sensory epithelial cells express all four erbB receptors in adult rats. Cultured vestibular ganglion neurons also expressed all four erbB family members and were therefore used to analyze the effects of modulating erbB signaling on differentiated vestibular ganglion neurons. Transforming growth factor-alpha (a ligand for epidermal growth factor receptor) and sensory and motor neuron-derived factor (a ligand for erbB3 and erbB4) promoted vestibular ganglion neuron viability, whereas epidermal growth factor (another ligand for epidermal growth factor receptor) did not. Glial growth factor 2 (another ligand for erbB3 and erbB4) and an antibody that blocks erbB2/neu-mediated signaling inhibited vestibular ganglion neuron viability. Collectively, these observations indicate that erbB signaling regulates the viability of differentiated otic placode-derived cells in mammals and suggest that exogenous modulation of erbB signaling in peripheral vestibular tissues may prove therapeutically useful in peripheral vestibular disorders.