Analysis of the action of euxanthone, a plant-derived compound that stimulates neurite outgrowth.

We have investigated the neurite growth-stimulating properties of euxanthone, a xanthone derivative isolated from the Chinese medicinal plant Polygala caudata. Euxanthone was shown to exert a marked stimulatory action on neurite outgrowth from chick embryo dorsal root ganglia explanted in collagen gels, in the absence of added neurotrophins. It was also shown to promote cell survival in explanted chick embryo ganglia, and to stimulate neurite outgrowth from isolated adult rat primary sensory neurons in vitro. The further finding that euxanthone stimulates neurite outgrowth from explants of chick embryo retina and ventral spinal cord suggests an action on signaling pathways downstream of neuronal receptors for specific neurotrophic factors. Consistent with this, euxanthone did not promote neurite outgrowth from non-transfected PC12 cells, or from PC12 cells transfected with TrkB or TrkC, under conditions in which these cells extended neurites in response to, respectively, the neurotrophins nerve growth factor, brain-derived neurotrophic factor and neurotrophin 3. Western blot analysis of euxanthone-stimulated dorsal root ganglion explants showed that expression of phospho-mitogen-activated protein (MAP) kinase was up-regulated after 1 h of euxanthone-treatment. Inhibition of the MAP kinase pathway using PD98059, a specific inhibitor of MAP kinase kinase, blocked all euxanthone-stimulated neurite outgrowth. However, analysis of phospho-Akt expression indicated that the phosphatidylinositol-3 kinase-Akt pathway, another major signaling pathway engaged by neurotrophins, is not significantly activated by euxanthone. These results suggest that euxanthone promotes neurite outgrowth by selectively activating the MAP kinase pathway.

Neuroinhibitory molecules in Alzheimer's disease.

Aberrant neurite growth is one of the neuropathological signatures of the Alzheimer's disease brain, both around amyloid plaques and in the cortical neuropil. Disruption of neuroinhibitory or repulsive growth and guidance signals, as well as of neurotrophic or permissive signals, may contribute to this dystrophic growth. Hence, therapeutic efforts directed exclusively at restoring neurotrophic activity are unlikely to meet with success. The molecular species responsible for neuroinhibitory effects in the Alzheimer's disease brain are beginning to be elucidated.

Neural crest patterning and the evolution of the jaw.

Here we present ideas connecting the behaviour of the cranial neural crest during development with the venerable, perhaps incorrect, view that gill-supporting cartilages of an ancient agnathan evolved into the skeleton of an early gnathostome's jaw. We discuss the pattern of migration of the cranial neural crest ectomesenchyme in zebrafish, along with the subsequent arrangement of postmigratory crest and head mesoderm in the nascent pharyngeal segments (branchiomeres), in diverse gnathostomes and in lampreys. These characteristics provide for a plausible von Baerian explanation for the problematic inside-outside change in topology of the gills and their supports between these 2 major groups of vertebrates. We consider it likely that the jaw supports did indeed arise from branchiomeric cartilages.

The role of the notochord in vertebral column formation.

The backbone or vertebral column is the defining feature of vertebrates and is clearly metameric. Given that vertebrae arise from segmented paraxial mesoderm in the embryo, this metamerism is not surprising. Fate mapping studies in a variety of species have shown that ventromedial sclerotome cells of the differentiated somite contribute to the developing vertebrae and ribs. Nevertheless, extensive studies in amniote embryos have produced conflicting data on exactly how embryonic segments relate to those of the adult. To date, much attention has focused on the derivatives of the somites, while relatively little is known about the contribution of other tissues to the formation of the vertebral column. In particular, while it is clear that signals from the notochord induce and maintain proliferation of the sclerotome, and later promote chondrogenesis, the role of the notochord in vertebral segmentation has been largely overlooked. Here, we review the established role of the notochord in vertebral development, and suggest an additional role for the notochord in the segmental patterning of the vertebral column.

Founding editorial: embryology--an integrated approach.

We introduce the Embryology domain of TheScientificWorld and outline the scope and aims. We argue for an interdisciplinary approach to problems in develop-mental biology. Three areas are identified as being of particular relevance to this domain: evolutionary developmental biology, teratology, and descriptive or experimental embryology.

Spinal nerve segmentation in the chick embryo: analysis of distinct axon-repulsive systems.

In higher vertebrates, the segmental organization of peripheral spinal nerves is established by a repulsive mechanism whereby sensory and motor axons are excluded from the posterior half-somite. A number of candidate axon repellents have been suggested to mediate this barrier to axon growth, including Sema3A, Ephrin-B, and peanut agglutinin (PNA)-binding proteins. We have tested the candidacy of these factors in vitro by examining their contribution to the growth cone collapse-inducing activity of somite-derived protein extracts on sensory, motor, and retinal axons. We find that Sema3A is unlikely to play a role in the segmentation of sensory or motor axons and that Ephrin-B may contribute to motor but not sensory axon segmentation. We also provide evidence that the only candidate molecule(s) that induces the growth cone collapse of both sensory and motor axons binds to PNA and is not Sema3A or Ephrin-B. By grafting primary sensory, motor, and quail retinal neurons into the chick trunk in vivo, we provide further evidence that the posterior half-somite represents a universal barrier to growing axons. Taken together, these results suggest that the mechanisms of peripheral nerve segmentation should be considered in terms of repellent molecules in addition to the identified molecules.

Life, death and Sonic hedgehog.

The secreted glycoprotein Sonic hedgehog (SHH), a vertebrate homologue of the Drosophila segment polarity gene Hedgehog, is essential for the development of diverse tissues during embryogenesis. Studies of SHH function during neural tube and somite development have focused on its role in specifying the dorsoventral polarity of these structures, but a recent report by Ahlgren and Bronner-Fraser(1) supports the possibility that SHH has additional functions in cell survival and cell proliferation. Perturbation of SHH signaling after the early dorsoventral specification of the cranial neural tube leads to increased cell death in both the neural tube and the neural crest. This implies that SHH is continually required as a trophic and/or mitogenic factor during brain development, and expands the variety of cellular responses to SHH signaling. BioEssays 22:499-502, 2000.

Peripheral, but not central, axotomy induces neuropilin-1 mRNA expression in adult large diameter primary sensory neurons.

Neuropilin-1 (NP-1) is a component of the receptor for semaphorin3a (Sema3a), a member of a large family of molecules with widespread expression and demonstrable influence (via their ability to repel growing axons) on nervous system development. Recent studies have shown that some types of adult mammalian neurons retain the capacity to respond to Sema3a, particularly in relation to neuronal injury and regeneration. Although variations in expression of Sema3a mRNA have been revealed in neurons in both the central and peripheral nervous systems in this context, relatively little is known about NP-1 expression patterns. In this study we investigated the expression of NP-1 mRNA in adult dorsal root ganglion (DRG) neurons in intact and lesioned animals. We compared the effect of unilateral lesioning of the sciatic nerve or unilateral dorsal rhizotomy at lumbar levels L4/5, and bilateral dorsal funiculus lesioning at thoracic levels T10/11 on NP-1 mRNA expression in the cell bodies of lumbar DRGs. A significantly increased level of NP-1 mRNA expression was detected only following sciatic nerve lesioning (P < 0.001), but not after rhizotomy or dorsal funiculus lesioning. Furthermore, this upregulation was mainly confined to large diameter neurons of DRGs at lumbar levels L4/5, which provide the main sensory contribution to the sciatic nerve. These results suggest a role for NP-1 in the axonal response to peripheral nerve injury, which may be specific to a particular subset of primary sensory neurons.

Orienting axon growth: spinal nerve segmentation and surround-repulsion.

The study of spinal nerve trajectories in higher vertebrate embryos has revealed an inherent polarity within somites along the antero-posterior axis, and provides a simple system in which to study the factors that influence axon pathfinding. We argue that the orientation of spinal axons is determined by the simultaneous operation of two distinct guidance mechanisms, contact repulsion and chemorepulsion. Motor and sensory axons traverse the anterior half of each somite because they are excluded by contact repulsion from the posterior half-somite, and the molecular nature of several candidate contact repellents is reviewed. In contrast, we find that the dorsoventral trajectory of primary sensory axons is oriented by diffusible repellents originating from the notochord medially and dermamyotome laterally. In this system, therefore, repulsion by surrounding tissues ('surround-repulsion') is the main force directing axon growth in three dimensions.

Human oligodendroglial cell line, MO3.13, can be protected from apoptosis using the general caspase inhibitor zVAD-FMK.

Recent evidence suggests that the oligodendrocyte cell loss observed in multiple sclerosis sufferers is in part mediated by apoptosis. Here we use a human cell line, MO3.13, as a model system to investigate the biochemical processes involved in oligodendroglial cell death. Treatment with staurosporine kills both naive and differentiated cells in a dose-dependent manner; however, much higher concentrations of staurosporine are required to kill differentiated cells compared to their naive progenitors. Dying cells displayed the typical morphological characteristics of apoptosis, including cell shrinkage and chromatin condensation. Biochemical analysis showed that caspases, a group of enzymes intimately involved in the execution of apoptosis, are activated in both naive and differentiated cells. Western blotting analysis revealed that similar subsets of caspase enzymes were operating and that the substrate cleavage patterns were identical in both naive and differentiated cells. Treatment of MO3.13 cells with the general caspase inhibitor zVAD-FMK protected them from toxin-induced cell death. These results indicate that when an oligodendroglial human cell line is exposed to toxin it dies in an apoptotic manner. In addition, we show that cells can be protected from toxin-induced death using an appropriate inhibitor.

Embryonic lens repels retinal ganglion cell axons.

During development of the vertebrate visual system, retinal ganglion cell (RGC) axons follow a precise path toward their midbrain targets. Although much is known about the cues that direct RGC axons once they have left the optic disc, less is known about the guidance of axons at earlier stages, when RGCs first send out their axons to navigate within the developing retina. Using collagen gel coculture experiments, we find that the embryonic lens produces a powerful diffusible repulsive activity for RGC axons. We also find that this activity is localized to the lens epithelium and not the lens fiber layer, while the pigmented epithelium and vitreous humour are devoid of activity. The further observation that the lens also chemorepels primary sensory axons, but does not repel olfactory bulb axons, shows that this activity is specific for subsets of axons. Our experiments have excluded two candidate repellents for RGC axons (collapsin-1/sema III and chondroitin sulfate proteoglycans). These results implicate the lens in the earliest stages of RGC axon guidance. One function of the lens repellent may be to prevent aberrant targeting toward the lens, and it may also be involved in the directional guidance of RGC axons toward the optic disc.

The screw-helical voltage gating of ion channels.

In the voltage-gated ion channels of every animal, whether they are selective for K+, Na+ or Ca2+, the voltage sensors are the S4 transmembrane segments carrying four to eight positive charges always separated by two uncharged residues. It is proposed that they move across the membrane in a screw-helical fashion in a series of three or more steps that each transfer a single electronic charge. The unit steps are stabilized by ion pairing between the mobile positive charges and fixed negative charges, of which there are invariably two located near the inner ends of segments S2 and S3 and a third near the outer end of either S2 or S3. Opening of the channel involves three such steps in each domain.

Axon guidance to and from choice points.

Significant progress has been made recently in understanding axon guidance to and from choice points. Netrins have been shown to function as conserved midline chemoattractants in vertebrates and insects, and receptors for netrins and semaphorins/collapsins have been identified. More evidence has accumulated that repulsion plays a key role in guidance, including the involvement of the ephrin/Eph receptor system in contact repulsion.

On the slowly rising phase of the sodium gating current in the squid giant axon.

High-resolution records of the sodium gating current in the squid giant axon demonstrate the existence of a slowly rising phase that is first apparent at pulse potentials slightly below zero, and becomes increasingly pronounced at more positive potentials. At +80 mV the current reaches its peak with a delay of 30 microseconds at 10 degrees C. It is suggested that this current is generated by the first two steps labelled R-->P and P-->A in the S4 units of all four domains of the series-parallel gating system, activating the channel before its opening by the third steps A-->B in domains I, II and III in conjunction with hydration. The kinetics of the slowly rising phase can only be explained by the incorporation of an appropriate degree of voltage-dependent cooperativity between the S4 voltage-sensors for their two initial transitions.

Modelling the activation, opening, inactivation and reopening of the voltage-gated sodium channel.

A model of the voltage-gated sodium channel is put forward suggesting that the four S4 voltage-sensors behave as screw-helices making a series of discrete transitions that carry one elementary charge for each notch of the screw helix. After the channel has been activated by the first two steps R in equilibrium with P in equilibrium with A in all four domains, followed by a voltage-independent rearrangement, it is opened by a third cooperative step A in equilibrium with B in domains I, II and III in conjunction with hydration. Inactivation is a voltage-dependent process controlled by the third step A in equilibrium with I in sensor IVS4, and the closing of the channel is brought about its dehydration. From the inactivated steady state the channel may be reopened by a fourth step, I in equilibrium with C in sensor IVS4 and rehydration. The computed kinetics of the model are shown to conform closely with those observed experimentally.

Axon guidance and somites.

The segmental arrangement of spinal nerves in higher vertebrate embryos provides a simple system in which to study the factors that influence axon pathfinding. Developing motor and sensory axons are intimately associated with surrounding tissues that direct axon guidance. We argue that two distinct guidance mechanisms, viz. contact repulsion and chemorepulsion, act simultaneously to prescribe spinal axon trajectories by 'surround-repulsion'. Motor and sensory axons grow freely within the anterior half of each mesodermal somite, because they are excluded from posterior half-somites by contact repulsion. By contrast, the dorsoventral trajectory that bipolar sensory axons of the dorsal root ganglia follow is governed by diffusible repellents originating from the notochord medially and dermamyotome laterally. Even though spinal nerve development appears to be a simple system for elucidating axon guidance mechanisms, many distinct candidate guidance molecules have been implicated and their relative contributions remain to be evaluated.

Steps on the path to the origin of species.

The choice of Charles Darwin to serve as geologist on H.M.S. Beagle came about in a somewhat haphazard fashion, and by modern standards his technical qualifications for the post were not strong. However, during the voyage he was exposed to a wider range of phenomena, both in geology and in natural history, than any previous scientist, and his innate qualities of enquiring critically with an open mind into the why and wherefore of every one of his observations enabled him to make very effective use of his experience. By the end of the voyage he had found himself ready to abandon the doctrine of the fixity of species, and a few months later he opened the first of the series of notebooks on "Transmutation of Species" in which he recorded his private thinking. He quite quickly arrived at the Principle of Natural Selection as a mechanism for the creation of new species, but the process of building up adequate evidence in support of his theory was a slow one, and more than 20 years had passed before his great work was finally ready for publication.

Surround repulsion of spinal sensory axons in higher vertebrate embryos.

We have tested whether the orientation of axons sprouting from bipolar dorsal root ganglion neurons is influenced by diffusible cues from surrounding tissues. Surface ectoderm, dermomyotome, and notochord exert strong chemorepulsion on axons growing in collagen gels, operating at separations beyond those found in vivo and active in cocultures of chick and mouse tissues. Basal and alar plates of the neural tube are devoid of activity, as is the posterior-half-sclerotome, which repels in a contact-dependent manner. When ganglia are sandwiched between dermomyotome and notochord placed at a distance, axon growth is channeled in a bipolar trajectory. These results show that gradients of diffusible repulsion molecules flanking axon pathways can generate linear patterns of axon growth. We suggest that such "surround repulsion" may function generally, in concert with contact-dependent guidance mechanisms, to guide axons in the developing nervous system.