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. Received: 28 May 1997 / Accepted: 27 June 1997     

Axon guidance: the cytoplasmic tail

Recent advances in the study of axon guidance have begun to clarify the intricate signalling mechanisms utilised by receptors that mediate path-finding. Many of these axon guidance receptors, including Plexin B, EphA, ephrin B and Robo, regulate the Rho family of GTPases, to effect changes in motility. Recent studies demonstrate a critical role for the cytoplasmic tails of guidance receptors in signalling and also reveal the potential for a great deal of crosstalk between the various receptor-signalling pathways.     

Axon guidance: Robos make the rules

A central feature of the developing nervous system is the midline region, which guides growing axons with both short- and long-range signals. New research shows that a trio of receptors, the Robos, are crucial in allowing axons to interpret these signals, ensuring correct route-finding within the emerging axon scaffold.     

Axon guidance in the vertebrate central nervous system

The development of connections in the central nervous system depends on the ability of the tips of growing axons to find their appropriate, often distant, target field. Factors that regulate axon outgrowth may be distinct from those that influence direction finding. Tissue culture methods have helped to distinguish between possible in vivo mechanisms and, in some cases, have identified candidate molecules.     

Axon guidance: morphogens show the way

Hedgehog and Wnt family proteins can act as classic developmental morphogens to pattern a field of nai;ve cells. Surprising new studies show that members of these same protein families also act as guidance cues for growing axons in the developing nervous system.     

中脑多巴胺能神经元的轴突导向及其诱向因子

中脑多巴胺能神经元（mesodiencephalic dopamine,mdDA,neurons）由于涉及帕金森病、精神分裂症和药物成瘾等多种神经疾病的病理过程而历来受到人们的重视。研究中脑多巴胺能神经元的发育机制将给这些疾病的治疗带来希望。近来的研究表明多巴胺能神经元轴突的导向由各种诱向因子决定,诱向因子主要由相应投射部位的细胞所分泌,其中研究得最多的是ephrins,netrins,semaphorins,Slits及它们各自的受体。介绍胚胎期中脑多巴胺能神经元轴突导向过程及其主要诱向因子。     

Axon guidance by molecular gradients.

In the past year, evidence indicating that some developing axons are guided to their targets, at least in part, by gradients of diffusible chemoattractants secreted by their target cells has continued to accumulate. It has also been shown for the first time that axons can orient in response to smooth gradients of immobilized substrate molecules.     

Axon guidance: opposing EPHects in the growth cone

Cells communicate with other cells via (trans) interaction between membrane-linked ephrins and Eph receptors. In this issue of Cell, Pfaff and colleagues (Marquardt et al., 2005) demonstrate that coexpressed ephrin-As and Ephs do not interact in cis but rather segregate into separate membrane domains, from which they signal opposing effects during motor axon guidance.     

Axon guidance and neuronal migration research in China

Proper migration of neuronal somas and axonal growth cones to designated locations in the developing brain is essential for the assembly of functional neuronal circuits.Rapid progress in research of axon guidance and neuronal migration has been made in the last twenty years.Chinese researchers began their exploration in this field ten years ago and have made significant contributions in clarifying the signal transduction of axon guidance and neuronal migration.Several unique experimental approaches,includin...     

Axon guidance in the spinal cord: choosin' by exclusion

A critical step in the formation of correct patterns of sensory inputs to the spinal cord is the guidance of specific subsets of sensory axons to their appropriate target regions. Yoshida et al. demonstrate in this issue of Neuron that a repulsive interaction between plexinA1 and sema6C/6D prevents the growth of proprioceptive sensory axons into the superficial laminae of the dorsal horn where cutaneous sensory axons terminate.     

Axon guidance: Comm hither,Robo

In the developing CNS, commissural axons are initially attracted to the midline, but after crossing they acquire sensitivity to midline repellent cues which prevent re-crossing. Recent studies have shed new light on the mechanism by which commissural axons change their sensitivity to guidance cues after crossing the midline.     

Axon guidance: ephrins at WRK on the midline

Recent findings indicate that the embryonic motor neurons act as gatekeepers to regulate midline crossing during development of the nematode Caenorhabditis elegans. The newly identified protein WRK-1 and ephrins cooperate to prevent longitudinal axons from crossing the midline.     

Axon guidance: proteins turnover in turning growth cones

Accurate navigation by a neuronal growth cone requires the modulation of the growth cone's responsiveness to spatial and temporal changes in expression of guidance cues. These adaptations involve local protein synthesis and turnover in growth cones and distal axons.     

Histochemistry of glycogen in the inner ear

Synopsis The effect of fixation and processing upon the morphological appearance of glycogen within the outer hair cells of the guinea-pig was investigated using two methods. In each method, tissue was fixed for 12 h in cold phosphate-buffered 4% paraformaldehyde and eventually dehydrated in ethanol, embedded in Epon 812, and cut into 4 m sections. In procedure A, after complete processing, the sections were tained using the periodic acid-Schiff reaction (PAS) or the periodic acid-thiocarbo-hydrazide-osmium tetroxide (PATCO) reaction which resulted in the appearance of listinct, coarse granules in the cytoplasm of the outer hair cells. Diastase digestion on one of the two matched sections after Epon removal and prior to staining, confirmed the granules to be glycogen. In procedure B, after primary fixation, the tissue was post-fixed in 1% osmium tetroxide and then processed exactly as in procedure A. Here, unless the Epon and osmium was remoyed, there was no staining of the outer hair cell cytoplasm. However, after Epon removal there was diffuse, grainy appearance of the outer hair cell cytoplasm which we considered to be due to glycogen although diastase confirmation was not possible. We have concluded that osmium tetroxide (1) inhibits PAS or PATCO staining, (2) prevents diastase digestion, and (3) prevents the appearance by light microscopy of distinct granules of glycogen.     

Axon guidance: receptor complexes and signaling mechanisms

The generation of a functional neuronal network requires that axons navigate precisely to their appropriate targets. Molecules that specify guidance decisions have been identified, and the signaling events that occur downstream of guidance receptors are beginning to be understood. New research shows that guidance receptor signaling can be hierarchical -- one receptor silencing the other -- thereby allowing navigating growth cones to interpret opposing guidance cues. Among the known intracellular signaling molecules shared by all guidance receptor families, Rho GTPases appear to be primary regulators of actin dynamics and growth cone guidance. Novel effector molecules complete the picture and suggest additional signaling mechanisms.     

Aquaporin-mediated fluid regulation in the inner ear

1. The sensory functions of the inner ear (hearing and balance) critically depend on the precise regulation of two fluid compartments of highly desparate ion composition, i.e., the endolymph and the perilymph.2. The parameters volume, ion composition, and pH need to be held athomeostasis irrespective of the hydration status of the total organism.3. Specific cellular water channels, aquaporins, have been shown to be essential for the fluid regulation of several organs, e.g., kidney, lung, and brain.4. Because of functional similarities of water regulation in the kidney and inner ear this review initially summarizes some aquaporin functions in the kidney and then focuses on 6 out of 11 mammalian aquaporins that are present in the inner ear (AQP1-6).5. Their potential role in the inner ear fluid control will be discussed on the basis of the respective expression patterns and individual pore properties.6. Further, a working model is presented of how the endolymphatic sac may contribute to inner ear fluid regulation.