Mer receptor tyrosine kinase mediates both tethering and phagocytosis of apoptotic cells

Billions of inflammatory leukocytes die and are phagocytically cleared each day. This regular renewal facilitates the normal termination of inflammatory responses, suppressing pro-inflammatory mediators and inducing their anti-inflammatory counterparts. Here we investigate the role of the receptor tyrosine kinase (RTK) Mer and its ligands Protein S and Gas6 in the initial recognition and capture of apoptotic cells (ACs) by macrophages. We demonstrate extremely rapid binding kinetics of both ligands to phosphatidylserine (PtdSer)-displaying ACs, and show that ACs can be co-opsonized with multiple PtdSer opsonins. We further show that macrophage phagocytosis of ACs opsonized with Mer ligands can occur independently of a requirement for αV integrins. Finally, we demonstrate a novel role for Mer in the tethering of ACs to the macrophage surface, and show that Mer-mediated tethering and subsequent AC engulfment can be distinguished by their requirement for Mer kinase activity. Our results identify Mer as a receptor uniquely capable of both tethering ACs to the macrophage surface and driving their subsequent internalization.

Glial control of neuronal development

Reciprocal interactions between differentiating glial cells and neurons define the course of nervous system development even before the point at which these two cell types become definitively recognizable. Glial cells control the survival of associated neurons in both Drosophila and mammals, but this control is dependent on the prior neuronal triggering of glial cell fate commitment and trophic factor expression. In mammals, the growth factor neuregulin-1 and its receptors of the ErbB family play crucial roles in both events. Similarly, early differentiating neurons and their associated glia rely on reciprocal signaling to establish the basic axon scaffolds from which neuronal connections evolve. The importance of this interactive signaling is illustrated by the action of glial transcription factors and of glial axon guidance cues such as netrin and slit, which together regulate the commissural crossing of pioneer axons at the neural midline. In these and related events, the defining principle is one of mutually reinforced and mutually dependent signaling that occurs in a network of developing neurons and glia.

The collagen receptor DDR2 regulates proliferation and its elimination leads to dwarfism

The discoidin domain receptor 2 (DDR2) is a member of a subfamily of receptor tyrosine kinases whose ligands are fibrillar collagens, and is widely expressed in postnatal tissues. We have generated DDR2-deficient mice to establish the in vivo functions of this receptor, which have remained obscure. These mice exhibit dwarfism and shortening of long bones. This phenotype appears to be caused by reduced chondrocyte proliferation, rather than aberrant differentiation or function. In a skin wound healing model, DDR2-/- mice exhibit a reduced proliferative response compared with wild-type littermates. In vitro, fibroblasts derived from DDR2-/- mutants proliferate more slowly than wild-type fibroblasts, a defect that is rescued by introduction of wild-type but not kinase-dead DDR2 receptor. Together our results suggest that DDR2 acts as an extracellular matrix sensor to modulate cell proliferation.

Homeostatic regulation of the immune system by receptor tyrosine kinases of the Tyro 3 family

Receptor tyrosine kinases and their ligands mediate cell-cell communication and interaction in many organ systems, but have not been known to act in this capacity in the mature immune system. We now provide genetic evidence that three closely related receptor tyrosine kinases, Tyro 3, Axl, and Mer, play an essential immunoregulatory role. Mutant mice that lack these receptors develop a severe lymphoproliferative disorder accompanied by broad-spectrum autoimmunity. These phenotypes are cell nonautonomous with respect to lymphocytes and result from the hyperactivation of antigen-presenting cells in which the three receptors are normally expressed.

Induction of postnatal schwann cell death by the low-affinity neurotrophin receptor in vitro and after axotomy

Schwann cells express the low-affinity neurotrophin receptor (p75), but no role for either the neurotrophins or their cognate receptors in Schwann cell development has been established. We have found that Schwann cells isolated from postnatal day 1 (P1) or P2 mice that were p75-deficient exhibited potentiated survival compared to wild-type cells after growth factor and serum withdrawal. There was, however, no disparity in the survival of p75-deficient and wild-type Schwann cells isolated at embryonic day 15, suggesting that the death-inducing effects of p75 are developmentally regulated. A comparable degree of cell death was also observed in the sciatic nerves of both wild-type and p75-deficient mice at P1. However, 24 hr after axotomy, there was a 13-fold increase in the percentage of apoptotic nuclei in the distal nerve stumps of the transected sciatic nerves of neonatal wild-type but not p75-deficient mice. The expression of both the p75 and nerve growth factor (NGF) genes was upregulated after axotomy in neonatal wild-type nerves. Collectively, these results suggest that NGF-mediated activation of p75 is likely to be an important mediator of Schwann cell apoptosis in the context of peripheral nerve injury.

Topographic mapping from the retina to the midbrain is controlled by relative but not absolute levels of EphA receptor signaling

Topographic maps are a fundamental feature of sensory representations in nervous systems. The formation of one such map, defined by the connection of ganglion cells in the retina to their targets in the superior colliculus of the midbrain, is thought to depend upon an interaction between complementary gradients of retinal EphA receptors and collicular ephrin-A ligands. We have tested this hypothesis by using gene targeting to elevate EphA receptor expression in a subset of mouse ganglion cells, thereby producing two intermingled ganglion cell populations that express distinct EphA receptor gradients. We find that these two populations form separate maps in the colliculus, which can be predicted as a function of the net EphA receptor level that a given ganglion cell expresses relative to its neighbors.

Rat oligodendroglia express c-met and focal adhesion kinase, protein tyrosine kinases implicated in regulating epithelial cell motility

Oligodendrocytes, the myelinating cells of the central nervous system, arise from a profilerating pool of motile progenitor cells. The proliferation and survival of these cells is dependent on signal transduction via several protein tyrosine kinases (PTKs) including receptors for fibroblast growth factor -2, the platelet-derived growth factor receptors and the neurotrophin receptor, trkC. We hypothesized that additional PTKs could also influence oligodendroglial development. Utilizing RTPCR, we amplified from post-natal day 6 rat oligodendroglia 17 distinct kinase domain sequences, 14 of which were not previously known to be expressed by oligodendroglia. Amongst the sequences identified were the c-met and Fak genes, whose protein products regulate the motility of other epithelial cell types. Utilizing immunohistochemistry, we confirmed that both c-met and Fak are expressed by cultured oligodendroglia, suggesting that these proteins could also be implicated in regulating the motility of these cells.

The homeodomain protein vax1 is required for axon guidance and major tract formation in the developing forebrain

The homeodomain protein Vax1 is expressed in a highly circumscribed set of cells at the ventral anterior midline of the embryonic CNS. These cells populate the choroid fissure of the optic disk, the body of the optic stalk and nerve, the optic chiasm and ventral diencephalon, and the anterior midline zones that abut developing commissural tracts. We have generated mutant mice that lack Vax1. In these mice (1) the optic disks fail to close, leading to coloboma and loss of the eye-nerve boundary; (2) optic nerve glia fail to associate with and appear to repulse ingrowing retinal axons, resulting in a fascicle of axons that are completely segregated from optic nerve astrocytes; (3) retinal axons fail to penetrate the brain in significant numbers and fail to form an optic chiasm; and (4) axons in multiple commissural tracts of the anterior CNS, including the corpus callosum and the hippocampal and anterior commissures, fail to cross the midline. These axon guidance defects do not result from the death of normally Vax1(+) midline cells but, instead, correlate with markedly diminished expression of attractive guidance cues in these cells. Vax1 therefore regulates the guidance properties of a set of anterior midline cells that orchestrate axon trajectories in the developing mammalian forebrain.

Tyro-3 family receptors are essential regulators of mammalian spermatogenesis

We have generated and analysed null mutations in the mouse genes encoding three structurally related receptors with tyrosine kinase activity: Tyro 3, Axl, and Mer. Mice lacking any single receptor, or any combination of two receptors, are viable and fertile, but male animals that lack all three receptors produce no mature sperm, owing to the progressive death of differentiating germ cells. This degenerative phenotype appears to result from a failure of the tropic support that is normally provided by Sertoli cells of the seminiferous tubules, whose function depends on testosterone and additional factors produced by Leydig cells. Tyro 3, Axl and Mer are all normally expressed by Sertoli cells during postnatal development, whereas their ligands, Gas6 and protein S, are produced by Leydig cells before sexual maturity, and by both Leydig and Sertoli cells thereafter. Here we show that the concerted activation of Tyro 3, Axl and Mer in Sertoli cells is critical to the role that these cells play as nurturers of developing germ cells. Additional observations indicate that these receptors may also be essential for the tropic maintenance of diverse cell types in the mature nervous, immune and reproductive systems.

Evectins: vesicular proteins that carry a pleckstrin homology domain and localize to post-Golgi membranes

We have identified two vesicular proteins, designated evectin (evt)-1 and -2. These proteins are approximately 25 kDa in molecular mass, lack a cleaved N-terminal signal sequence, and appear to be inserted into membranes through a C-terminal hydrophobic anchor. They also carry a pleckstrin homology domain at their N termini, which potentially couples them to signal transduction pathways that result in the production of lipid second messengers. evt-1 is specific to the nervous system, where it is expressed in photoreceptors and myelinating glia, polarized cell types in which plasma membrane biosynthesis is prodigious and regulated; in contrast, evt-2 is widely expressed in both neural and nonneural tissues. In photoreceptors, evt-1 localizes to rhodopsin-bearing membranes of the post-Golgi, an important transport compartment for which specific molecular markers have heretofore been lacking. The structure and subcellular distribution of evt-1 strongly implicate this protein as a mediator of post-Golgi trafficking in cells that produce large membrane-rich organelles. Its restricted cellular distribution and genetic locus make it a candidate gene for the inherited human retinopathy autosomal dominant familial exudative vitreoretinopathy and suggest that it also may be a susceptibility gene for multiple sclerosis.

Krox-20 controls SCIP expression, cell cycle exit and susceptibility to apoptosis in developing myelinating Schwann cells

The transcription factors Krox-20 and SCIP each play important roles in the differentiation of Schwann cells. However, the genes encoding these two proteins exhibit distinct time courses of expression and yield distinct cellular phenotypes upon mutation. SCIP is expressed prior to the initial appearance of Krox-20, and is transient in both the myelinating and non-myelinating Schwann cell lineages; while in contrast, Krox-20 appears approximately 24 hours after SCIP and then only within the myelinating lineage, where its expression is stably maintained into adulthood. Similarly, differentiation of SCIP−/− Schwann cells appears to transiently stall at the promyelinating stage that precedes myelination, whereas Krox-20(−/−) cells are, by morphological criteria, arrested at this stage. These observations led us to examine SCIP regulation and Schwann cell phenotype in Krox-20 mouse mutants. We find that in Krox-20(−/−) Schwann cells, SCIP expression is converted from transient to sustained. We further observe that both Schwann cell proliferation and apoptosis, which are normal features of SCIP+ cells, are also markedly increased late in postnatal development in Krox-20 mutants relative to wild type, and that the levels of cell division and apoptosis are balanced to yield a stable number of Schwann cells within peripheral nerves. These data demonstrate that the loss of Krox-20 in myelinating Schwann cells arrests differentiation at the promyelinating stage, as assessed by SCIP expression, mitotic activity and susceptibility to apoptosis.

A role for insulin-like growth factor-I in the regulation of Schwann cell survival

During postnatal development in the peripheral nerve, differentiating Schwann cells are susceptible to apoptotic death. Schwann cell apoptosis is regulated by axons and serves as one mechanism through which axon and Schwann cell numbers are correctly matched. This regulation is mediated in part by the provision of limiting axon-derived trophic molecules, although neuregulin-1 (NRG-1) is the only trophic factor shown to date to support Schwann cell survival. In this report, we identify insulin-like growth factor-I (IGF-I) as an additional trophin that can promote Schwann cell survival in vitro. We find that IGF-I, like NRG-1, can prevent the apoptotic death of postnatal rat Schwann cells cultured under conditions of serum withdrawal. Moreover, we show that differentiating Schwann cells in the rat sciatic nerve express both the IGF-I receptor (IGF-I R) and IGF-I throughout postnatal development. These results indicate that IGF-I is likely to control Schwann cell viability in the developing peripheral nerve and, together with other findings, raise the interesting possibility that such survival regulation may switch during postnatal development from an axon-dependent mechanism to an autocrine and/or paracrine one.

Progesterone stimulates the activity of the promoters of peripheral myelin protein-22 and protein zero genes in Schwann cells

To understand better the mechanisms by which progesterone (PROG) promotes myelination in the PNS, cultured rat Schwann cells were transiently transfected with reporter constructs in which luciferase expression was controlled by the promoter region of either the peripheral myelin protein-22 (PMP22) or the protein zero (P0) genes. PROG stimulated the P0 promoter and promoter 1, but not promoter 2, of PMP22. The effect of PROG was specific, as estradiol and testosterone only weakly activated promoters. Dose-response curves for stimulation of both promoter constructs by PROG were biphasic. RU486, a PROG antagonist, did not abolish the effect of PROG, but stimulated promoter activities by itself. In the human carcinoma cell line T47D expressing high levels of PROG receptor, PROG did not stimulate the P0 and PMP22 promoters, whereas the promoter region of the mouse mammary tumor virus was fully activated. Thus, the activation by PROG of promoter activity of two peripheral myelin protein genes is Schwann-cell specific.

Selective disruption of neuregulin-1 function in vertebrate embryos using ribozyme-tRNA transgenes

The products of the neuregulin-1 gene constitute a set of polypeptide growth factors whose signalling through the ErbB receptors is essential to the growth and differentiation of many cell types in culture. Although studies with neuregulin-1 mutant mice have demonstrated that these growth factors are also essential regulators of cellular differentiation in vivo, the mid-embryonic death of these mutants precludes an analysis of hypothesized neuregulin-1 roles in later aspects of development. To circumvent this early lethality, we have pursued a ribozyme-based strategy for the perturbation of neuregulin-1 function in developing chick embryos. Early administration of a retrovirus carrying neuregulin-1 hammerhead-type ribozymes to blastoderm-stage embryos leads to an embryonic lethal phenotype that results from the failure of ventricular trabeculation in the developing heart, a faithful phenocopy of the mouse neuregulin-1 mutations. Later, more localized delivery of the ribozyme to the developing retina inhibits both the differentiation of retinal ganglion cell neurons and the proliferation of the neuroepithelial cells from which they derive. These results suggest that neuregulin-1 promotes both muscle cell differentiation in the heart and neuronal differentiation in the central nervous system. In addition, they demonstrate the utility of hammerhead ribozymes as a simple, effective and easily adaptable method of conditional gene inactivation in vertebrates.

Rules for ribozymes

The selective inactivation of genes, in a tissue-specific or temporally controlled manner, is now an important requirement for the analysis of nervous system development and function. Hammerhead ribozymes--catalytic RNA enzymes that specifically bind to and then cleave target RNAs--may provide a way to meet this requirement, particularly for organisms in which gene inactivation by homologous recombination is not feasible. However, ribozyme application has to some extent been hampered by limited knowledge as to the base-pairing accessibility of RNA target sites in vivo. In an attempt to circumvent this limitation, we have used a computer program based on free energy minimization to predict secondary structures for 128 RNA sequences for which corresponding ribozymes or antisense oligonucleotides have been synthesized, tested, and reported in the literature. A comparative analysis of the predicted structures of these targets with the reported efficacy of their corresponding antisense reagents has allowed us to formulate a set of rules for the rational choice of hammerhead ribozyme flanking arms and cleavage sites.

An orphan receptor tyrosine kinase family whose members serve as nonintegrin collagen receptors

Mammalian cells constantly monitor and respond to a myriad of extracellular signals, often by using cell surface receptors. Two important classes of cell surface receptors include the receptor tyrosine kinases, which recognize peptide growth factors such as insulin, and the integrins, which most often mediate binding to components of the extracellular matrix. We report that the collagens serve as ligands for the previously orphan family of discoidin domain-containing receptor-like tyrosine kinases. The unexpected realization that an extracellular matrix molecule can directly serve as a ligand for receptor tyrosine kinases provides an example of ligands shared by integrins and receptor tyrosine kinases, and this finding seems likely to change prevailing views about the mechanisms by which cells perceive and respond to the extracellular matrix.

Multiple regulatory elements control transcription of the peripheral myelin protein zero gene

The gene encoding protein zero (P0), the most abundant protein of peripheral nervous system myelin, is expressed uniquely in Schwann cells. Previous studies have demonstrated that much of the cell type specificity of this expression is due to transcriptional control elements in the 1.1-kilobase pair 5'-regulatory region of the gene. We have now analyzed this region and have identified a set of functional elements in the 500 base pairs proximal to the transcription start site. DNA sequence conservation within the 5' regions of the human, mouse, and rat P0 genes correlates closely with the results of promoter deletion analysis of the 1.1-kilobase pair region assayed in Schwann cell cultures and reveals a potent proximal region from position -350 to +45. Sites of protein/DNA interaction within the proximal 500 base pairs of the promoter were identified by footprinting assays. Functional transcriptional elements were identified within the protected regions in the proximal promoter by mutation and transient transfection analysis in P0-expressing cell lines. The core (or basal) P0 promoter is identified as two regulatory elements, a G/C-rich element that binds nuclear factor Sp1 and a CAAT box that binds NF-Y. These core elements are essential for the transcription observed from the transfected promoter in cultured Schwann cells.

Neuregulins and neuregulin receptors in neural development

The neuregulins are a family of closely related proteins that play important roles in neural and cardiac development, as well as in mammary carcinogenesis. The pleiotropic activities of these molecules are transduced by a set of receptor protein tyrosine kinases that exhibit structural similarity to the receptor for epidermal growth factor. Recent results have demonstrated essential roles for the neuregulins and their receptors in regulating cell number, determining cell fate, and establishing pattern in the developing central and peripheral nervous systems.

A transgenic mouse model for human hereditary neuropathy with liability to pressure palsies

Mutations in the gene encoding peripheral myelin protein 22 (PMP22) account for several inherited peripheral neuropathies in humans. We now show that transgenic mice expressing antisense PMP22 RNA exhibit modestly reduced levels of PMP22 together with a phenotype that is reminiscent of hereditary neuropathy with liability to pressure palsies (HNPP), a human disease caused by a 1.5-Mb deletion of a chromosome 17 region that contains the PMP22 gene. Transgenic antisense homozygotes display a striking movement disorder and a slowing of nerve conduction that worsens with age. Morphological analysis of peripheral nerves demonstrates that a subset of axons have thickened myelin sheaths and tomacula in young adults, with significant myelin degeneration detected in older animals. Together with other recent work, these data suggest that dosage of the PMP22 gene alone underlies the pathophysiology observed in HNPP and related disorders.

Schwann cell differentiation

Recent studies of Schwann cell differentiation in vivo and in vitro have provided new insights into determinative signal transduction events both at the cell surface and in the nucleus. Several polypeptide growth factors and their receptors, most notably the neuregulins and receptors of the ErbB family, have been implicated in the specification of cell fate, the control of precursor cell proliferation, and the regulation of programmed cell death during both early and late Schwann cell differentiation. Our understanding of the transcriptional control of Schwann cell development, particularly by the POU protein SCIP and the zinc-finger protein Krox-20, has been advanced by transgenic, knockout, and expression studies.

Sek4 and Nuk receptors cooperate in guidance of commissural axons and in palate formation

Sek4 and Nuk are members of the Eph-related family of receptor protein-tyrosine kinases. These receptors interact with a set of cell surface ligands that have recently been implicated in axon guidance and fasciculation. We now demonstrate that the formation of the corpus callosum and anterior commissure, two major commissural axon tracts that connect the two cerebral hemispheres, is critically dependent on Sek4 and Nuk. While mice deficient in Nuk exhibit defects in pathfinding of anterior commissure axons, sek4 mutants have defects in corpus callosum formation. The phenotype in both axon tracts is markedly more severe in sek4/nuk1 double mutants, indicating that the two receptors act in a partially redundant fashion. sek4/nuk1 double mutants also exhibit specific guidance and fasciculation defects of diencephalic axon tracts. Moreover, while mice singly deficient in either Sek4 or Nuk are viable, most sek4/nuk1 double mutants die immediately after birth primarily due to a cleft palate. These results demonstrate essential and cooperative functions for Sek4 and Nuk in establishing axon pathways in the developing brain, and during the development of facial structures.

Cell death in the Schwann cell lineage and its regulation by neuregulin

The development of Schwann cells, the myelin-forming glial cells of the vertebrate peripheral nervous system, involves a neonatal phase of proliferation in which cells migrate along and segregate newly formed axons. Withdrawal from the cell cycle, around postnatal days 2-4 in rodents, initiates terminal differentiation to the myelinating state. During this time, Schwann cell number is subject to stringent regulation such that within the first postnatal week, axons and myelinating Schwann cells attain the one-to-one relationship characteristic of the mature nerve. The mechanisms that underly this developmental control remain largely undefined. In this report, we examine the role of apoptosis in the determination of postnatal Schwann cell number. We find that Schwann cells isolated from postnatal day 3 rat sciatic nerve undergo apoptosis in vitro upon serum withdrawal and that Schwann cell death can be prevented by beta forms of neuregulin (NRG-beta) but not by fibroblast growth factor 2 or platelet-derived growth factors AA and BB. This NRG-beta-mediated Schwann cell survival is apparently transduced through an ErbB2/ErbB3 receptor heterodimer. We also provide evidence that postnatal Schwann cells undergo developmentally regulated apoptosis in vivo. Together with other recent findings, these results suggest that Schwann cell apoptosis may play an important role in peripheral nerve development and that Schwann cell survival may be regulated by access to axonally derived NRG.

The Transcription Factors SCIP and Krox-20 Mark Distinct Stages and Cell Fates in Schwann Cell Differentiation

We have studied the transcription factors SCIP and Krox-20 in differentiating Schwann cells-during normal development, in experimentally induced degenerating and regenerating peripheral nerves, and in cell culture-and have compared the expression of these regulators to a battery of genes that mark distinct stages in Schwann cell differentiation. In the myelinating Schwann cell lineage, we find that SCIP is initially induced by contact with axons and first appears near the last round of cell division in immature cells. This expression is transient-it is maximal in "promyelinating" cells and is then extinguished as Schwann cells overtly differentiate and myelinate axons. In contrast, Krox-20 appears in cells 24-36 h after they become SCIP+ and continues to be expressed in mature myelinating cells. These differences in regulation are seen in normal development, in regenerating nerves following nerve crush, and in cultured Schwann cells stimulated to adopt a myelination phenotype by elevation of intracellular cyclic AMP. Importantly, transient SCIP expression is also observed in the nonmyelinating Schwann cell lineage, but Krox-20 expression is not. Together with the myelination phenotypes exhibited by SCIP and Krox-20 mutant mice, these results suggest that SCIP preferentially acts during the predifferentiated phases of Schwann cell development, while in contrast, Krox-20 is associated with the later commitment to myelination and may therefore function as a direct transactivator of myelination genes.

Expression of the Tyro4/Mek4/Cek4 gene specifically marks a subset of embryonic motor neurons and their muscle targets

Tyro4 is a member of the eph family of receptor protein-tyrosine kinases. We present sequence analysis that identifies Tyro4 as the rat homolog of mouse Mek4 and chick Cek4. We also present expression studies that demonstrate an evolutionarily conserved pattern of expression for Tyro4, Mek4, and Cek4. Most strikingly, we find this receptor to be specifically expressed, in all three species, in a subset of motor neurons in the medial motor column and in a subset of axial, but not limb, muscles. Mek4 has previously been ascribed a role in guiding retinal axons to their targets in the optic tectum. Our results extend the purported role of Mek4 in axon guidance to include motor neurons of the medial motor column.

Aberrant neural and cardiac development in mice lacking the ErbB4 neuregulin receptor

Various in vitro studies have suggested that ErbB4 (HER4) is a receptor for the neuregulins, a family of closely related proteins implicated as regulators of neural and muscle development, and of the differentiation and oncogenic transformation of mammary epithelia. Here we demonstrate that ErbB4 is an essential in vivo regulator of both cardiac muscle differentiation and axon guidance in the central nervous system (CNS). Mice lacking ErbB4 die during mid-embryogenesis from the aborted development of myocardial trabeculae in the heart ventricle. They also display striking alterations in innervation of the hindbrain in the CNS that are consistent with the restricted expression of the ErbB4 gene in rhombomeres 3 and 5. Similarities in the cardiac phenotype of ErbB4 and neuregulin gene mutants suggest that ErbB4 functions as a neuregulin receptor in the heart; however, differences in the hindbrain phenotypes of these mutants are consistent with the action of a new ErbB4 ligand in the CNS.

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 delta SCIP--is transcriptionally inactive, but retains full DNA-binding activity. Mice that express delta SCIP 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.

B-50/GAP-43 mRNA expression in cultured primary Schwann cells is regulated by cyclic AMP

Following peripheral nerve crush or transection, B-50 mRNA expression increased dramatically in the distal nerve stump. This increase has been fully attributed to an up-regulation of B-50 synthesis in reactive Schwann cells. Here we describe that B-50 mRNA expression in primary Schwann cell cultures is strongly down-regulated by cyclic AMP. Treatment of neonatal Schwann cell cultures with as low as 20 nM forskolin decreased B-50 mRNA expression. We show that B-50 promoter P2, but not P1, is active in Schwann cells and that the activity of P2 is inhibited 2.5 fold by forskolin. P2 does not contain a consensus sequence of a known cyclic AMP responsive element suggesting that the effect of forskolin is indirect.

Structure, expression, and activity of Tyro 3, a neural adhesion-related receptor tyrosine kinase

We have isolated mouse cDNA clones encoding Tyro 3, a receptor protein-tyrosine kinase (PTK) of the mammalin central nervous system (CNS). Expression of the Tyro 3 gene is strongly up-regulated in neurons of the mouse neocortex, cerebellum, and hippocampus after the day of birth, during periods of active synaptogenesis, and high expression is maintained in the adult CNS. The sequence of Tyro 3 cDNAs predicts a glycoprotein receptor with similarity to neural cell recognition and adhesion molecules--the extracellular (ligand binding) region of this receptor is composed of two immunoglobulin-related domains followed by two fibronectin type III repeats. Immunoblot and immunoprecipitation analyses with anti-Tyro 3 antibodies indicate that the 125 kD Tyro 3 protein is abundantly expressed in CNS synaptosomes, and immunohistochemical analysis of cultured hippocampal cells demonstrates that Tyro 3 is a product of neurons. Rat-2 fibroblasts stably transfected with a Tyro 3 expression construct acquire the ability to grow in soft agar, suggesting that Tyro 3 is potentially oncogenic.

Hypomyelinating peripheral neuropathies and schwannomas in transgenic mice expressing SV40 T-antigen

We have prepared transgenic mice carrying a temperature-sensitive mutant of the SV40 oncogene (tsA-1609) under the control of 5' flanking sequences from the Schwann cell-specific P0 gene. Four of six founder mice showed moderate to severe hypomyelination in peripheral nerves of tail biopsies, with only rare myelinated fibers. Offspring were obtained from three of these founders. Northern blot and immunohistochemical analyses showed that expression of T-antigen was restricted to the PNS. Mice expressing the highest levels of T-antigen exhibited the most severe hypomyelination. Mice expressing lower levels developed transient mild hypomyelination, but after long latencies developed sporadic schwannomas. An immortalized cell line exhibiting properties of Schwann cells at an arrested stage of differentiation, termed "SCT-1," was derived from one of these tumors.

Axons regulate Schwann cell expression of the POU transcription factor SCIP

SCIP (suppressed cAMP-inducible POU) is a POU domain transcription factor expressed by Schwann cells. Drugs that elevate intracellular cAMP, such as forskolin, increase the expression of SCIP and partially mimic the inductive effects of axons on Schwann cell gene expression. Thus, SCIP may be involved in a differentiation pathway in Schwann cells that is activated by axons. We have examined this issue by studying SCIP expression in developing, degenerating, and regenerating rat peripheral nerves, and in Schwann cell-neuron cocultures. High levels of SCIP mRNA were detected in developing and regenerating nerves, and axotomy at these times caused the level of SCIP mRNA to plummet. Similarly, there were many SCIP-immunoreactive Schwann cell nuclei in developing and regenerating nerves, and their number fell sharply after axotomy. SCIP-immunoreactive Schwann cells were associated with axons in developing and regenerating nerves, and in Schwann cell-neuron cocultures. These data demonstrate that axons upregulate the expression of SCIP in Schwann cells, and that SCIP is expressed in Schwann cells that ensheathe axons. Thus, SCIP may mediate some of the changes in Schwann cell gene expression that accompany axonal ensheathment.

Structure and expression of the Tyro 10 receptor tyrosine kinase

We have isolated cDNA clones encoding Tyro 10, a novel receptor protein-tyrosine kinase (PTK) whose catalytic domain exhibits significant similarity to the Trk family of neurotrophin receptors (Lai & Lemke, 1991). We find that the Tyro 10 gene is widely expressed, both within and outside the nervous system, and in both developing and mature neural tissue. The primary structure of Tyro 10, deduced from cDNA sequence, defines a new sub-family of receptor PTKs. Although the Tyro 10 kinase domain is more closely related to the equivalent domains of Trk, TrkB and TrkC than to the catalytic domains of other receptor PTKs, it is less closely related to these Trk domains than they are to each other. More significantly, the Tyro 10 extracellular (ligand binding) domain is not structurally related to the extracellular domains of the Trk receptors, but instead bears homology to cell surface mediators of protein-protein interactions, including blood coagulation Factors V and VIII, and the neuronal recognition protein A5. These appear to be structural features of a distinct receptor PTK sub-family, in that they are also found in the recently-described discoidin domain receptor (DDR).

The human TYRO3 gene and pseudogene are located in chromosome 15q14-q25

Partial cDNAs of the human TYRO3 gene, encoding a putative receptor tyrosine kinase, and its processed pseudogene (TYRO3P) were cloned from human teratocarcinoma cell, bone marrow and melanocyte cDNA libraries. The tyrosine kinase homologous domains of TYRO3 and TYRO3P were sequenced and compared with each other and with the mouse TYRO3 gene. Abundant levels of the 4.2-kb TYRO3 mRNA were detected in human brain, and lower levels in other human tissues. TYRO3 and TYRO3P were both assigned to human chromosome 15q14-q25 by analysis of DNAs from somatic cell hybrids.

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.

Single cell analysis of the expression of a nuclear protein, SCIP, by fluorescent immunohistochemistry visualized with confocal microscopy

A widely applicable method for the accurate quantification or semiquantification of macromolecules at the level of individual cells is described and validated; this is a method which may considerably facilitate the study of many biological processes. This method relies on measuring fluorescent emission in immunocytochemically labelled cells with a confocal microscope. Emission is related quantitatively to the level of the fluorophore by the combination of an analysis of the polarization of the fluorescent emission and fluorophore rationing methods. The method was applied to the study of the expression of the suppressed cyclic AMP-induced POU protein (SCIP) transcription factor in glial cells of the central nervous system. In particular, the method allowed the study of transcription factor expression in defined cells present in heterogeneous cultures and in cell types which cannot be isolated in sufficient numbers for biochemical analysis using conventional techniques.

Transcriptional regulation of the development of neurons and glia

The past year has seen significant progress in the analysis of transcriptional regulation as it relates to neural development. Highlights include the identification and analysis of new homeobox genes that delimit developmental boundaries in the vertebrate forebrain, the study of upstream regulators of homeobox genes, the analysis of Pax genes that may contribute to specification of the vertebrate dorso-ventral neuraxis, and the functional analysis of transcription factors that are likely to specify particular neural cell types in both vertebrate and invertebrate nervous systems.

Repression of the myelin P0 gene by the POU transcription factor SCIP

SCIP is a POU domain transcription factor expressed by Schwann cells, the myelin-forming glial cells of the peripheral nervous system. In this study, we investigate SCIP regulation of the gene encoding P0, the major structural protein of peripheral myelin. We find that SCIP represses transcription of this gene through the joint action of the SCIP POU domain and an amino terminal domain that acts cell specifically. Maximal repression is DNA-binding-dependent, and analysis of the P0 promoter reveals the presence of multiple SCIP binding sites. Surprisingly, none of these sites in their native positions dramatically affect P0 promoter activity or its repression by SCIP, although they mediate repression when moved closer to the P0 transcription start site. We propose that repression occurs through a quenching mechanism mediated by the SCIP POU and amino terminal domains acting in concert with other nuclear proteins, including a Schwann cell-specific adapter.

The molecular genetics of myelination: an update

Recent molecular genetic studies have provided new insights into the structure and function of 2 of the major integral membrane proteins of myelin--the proteolipid protein (PLP) and protein zero (P0)--and have uncovered a third such protein--PMP22/gas3. The rumpshaker mouse has been shown to carry a point mutation in the PLP gene that uncouples a deleterious effect on CNS myelin assembly, which these mice exhibit, from oligodendrocyte degeneration and cell death, which they do not. The developmental importance of the P0 protein in PNS myelination has been dramatically demonstrated by the analysis of loss-of-function mutations engineered through the expression of antisense RNA and through the insertional inactivation of the P0 gene by homologous recombination in embryonic stem cells and the generation of P0-deficient mice. The cloned promoter of the P0 gene has been shown to drive quantitative, Schwann cell-specific expression of heterologous genes in transgenic mice. The PMP22/gas3 gene, previously cloned from fibroblast cell lines, has been found to encode an axonally regulated Schwann cell protein that is assembled into PNS myelin. Importantly, this gene appears to be the target of mutations that result in the Trembler alleles in mice, and in Charcot-Marie-Tooth disease Type 1a, the most common inherited peripheral neuropathy in humans.

Notch2: a second mammalian Notch gene

Notch is a cell surface receptor that mediates a wide variety of cellular interactions that specify cell fate during Drosophila development. Recently, homologs of Drosophila Notch have been isolated from Xenopus, human and rat, and the expression patterns of these vertebrate proteins suggest that they may be functionally analogous to their Drosophila counterpart. We have now identified a second rat gene that exhibits substantial nucleic and amino acid sequence identity to Drosophila Notch. This gene, designated Notch2, encodes a protein that contains all the structural motifs characteristic of a Notch protein. Thus, mammals differ from Drosophila in having more than one Notch gene. Northern and in situ hybridisation analyses in the developing and adult rat identify distinct spatial and temporal patterns of expression for Notch1 and Notch2, indicating that these genes are not redundant. These results suggest that the great diversity of cell-fate decisions regulated by Notch in Drosophila may be further expanded in vertebrates by the activation of distinct Notch proteins.

Mouse P0 gene disruption leads to hypomyelination, abnormal expression of recognition molecules, and degeneration of myelin and axons

We have used homologous recombination in embryonic stem cells to generate mice carrying a mutation in the gene encoding P0, an immunoglobulin-related recognition molecule and the major protein of peripheral nervous system myelin. These mice are deficient in normal motor coordination and exhibit tremors and occasional convulsions. Axons in their peripheral nerves are severely hypomyelinated and a subset of myelin-like figures and axons degenerate. The mutation leads to an abnormal regulation of some, but not all, molecules involved in myelination. These results demonstrate that P0 is essential for the normal spiraling, compaction, and maintenance of the peripheral myelin sheath and the continued integrity of associated axons. They further suggest that this protein conveys a signal that regulates Schwann cell gene expression.

Down-regulation of the POU transcription factor SCIP is an early event in oligodendrocyte differentiation in vitro

The POU-domain transcription factor SCIP (also known as Tst-1) has been implicated in the development of Schwann cells, the myelinating cells of the peripheral nervous system (PNS). We have investigated the possibility that SCIP also might play a role in the development of oligodendrocytes, the myelinating cells of the central nervous system (CNS). We purified oligodendrocyte precursors (O-2A progenitors) by immunoselection and cultured them in the presence of platelet-derived growth factor (PDGF) and basic fibroblast growth factor (bFGF), which together keep O-2A progenitors proliferating and prevent oligodendrocyte differentiation. Under these culture conditions, O-2A progenitors expressed high levels of SCIP mRNA and protein, and did not express myelin-specific genes. When oligodendrocyte differentiation was initiated by withdrawing the growth factors, SCIP mRNA was rapidly down-regulated, followed by a decline in SCIP protein and the sequential activation of myelin-specific genes. Rapid down-regulation of SCIP mRNA required continued protein synthesis. In O-2A progenitors that were cultured in the presence of PDGF alone, SCIP expression declined to an intermediate level, and low levels of the myelin gene products were induced. Thus, the level of SCIP expression in O-2A progenitors is inversely related to the level of myelin gene expression, suggesting that SCIP may be involved in the developmental switch from proliferation to differentiation in the oligodendrocyte lineage. When O-2A progenitors are cultured in the presence of 10% fetal calf serum, they differentiate into type-2 astrocytes rather than oligodendrocytes. SCIP mRNA was also down-regulated in type-2 astrocytes, which do not express myelin genes, so down-regulation of SCIP seems to be more closely linked to the cessation of cell proliferation per se than the expression of a particular differentiated phenotype.

P0 promoter directs expression of reporter and toxin genes to Schwann cells of transgenic mice

We generated transgenic mice that specifically express foreign genes in myelinating Schwann cells. A 1.1 kb segment of 5' flanking sequence from the rat P0 gene was used to drive expression of the genes encoding human growth hormone (hGH) and bacterial diphtheria toxin A chain (DT-A). The P0-hGH mice expressed hGH in myelinating Schwann cells, but not in nonmyelinating Schwann cells, the central nervous system, or any other tissue assayed. This expression was activated on a developmental schedule comparable to that of endogenous myelin gene expression. One line of P0-DT-A mice developed a generalized hypomyelinating peripheral neuropathy, with Schwann cell deficiency apparent in newborn animals. Peripheral nerves from adult mice of this line displayed morphological alterations ranging from completely denuded axons to myelinated Schwann cells undergoing degeneration, although occasional Schwann cells were able to form apparently normal myelin sheaths. Pronounced secondary changes, including proliferation and retraction of processes, occurred in the nonmyelinating Schwann cells of these P0-DT-A mice.

Axon-regulated expression of a Schwann cell transcript that is homologous to a ‘growth arrest-specific’ gene

We have isolated a 1.8 kb cDNA (pCD25) clone that encodes a transcript that is differentially expressed during nerve regeneration. Nucleotide sequence comparison indicates 89.6% homology with the recently identified murine 'growth arrest-specific' gene gas3. The open reading frame of the CD25 transcript predicts a 17 kDa protein with four putative transmembrane regions. Steady-state levels of the CD25 mRNA are very much higher in sciatic nerve than in other tissues, and expression in sciatic nerve is confined to Schwann cells. Following nerve injury, the transcript levels rapidly declined in nerve segments distal to the site of lesion, but recovered upon nerve regeneration. In contrast, in distal stumps of permanently transected nerves, the mRNA level remained very low. Substantial amounts of the mRNA could be reinduced only upon anastomosis of these interrupted nerve stumps. Re-induction of the mRNA followed the elongation of regenerating axons through the distal nerve segment. Our data indicate that axons regulate expression of the CD25 mRNA in Schwann cells, and suggest that the CD25 protein functions during Schwann cell growth and differentiation.