Abh�ngigkeit der normalen Schwanzregeneration beiXenopus-Larven von einem diencephalen Faktor im Zentralkanal

The Reissner Fiber Is Highly Dynamic In Vivo and Controls Morphogenesis of the Spine

Cerebrospinal fluid (CSF) physiology is important for the development and homeostasis of the central nervous system, and its disruption has been linked to scoliosis in zebrafish [1, 2]. Suspended in the CSF is an extracellular structure called the Reissner fiber, which extends from the brain through the central canal of the spinal cord. Zebrafish scospondin-null mutants are unable to assemble a Reissner fiber and fail to form a straight body axis during embryonic development [3]. Here, we describe hypomorphic missense mutations of scospondin, which allow Reissner fiber assembly and extension of a straight axis. However, during larval development, these mutants display progressive Reissner fiber disassembly, which is concomitant with the emergence of axial curvatures and scoliosis in adult animals. Using a scospondin-GFP knockin zebrafish line, we demonstrate several dynamic properties of the Reissner fiber in vivo, including embryonic fiber assembly, the continuous rostral to caudal movement of the fiber within the brain and central canal, and subcommissural organ (SCO)-spondin-GFP protein secretion from the floor plate to merge with the fiber. Finally, we show that disassembly of the Reissner fiber is also associated with the progression of axial curvatures in distinct scoliosis mutant zebrafish models. Together, these data demonstrate a critical role for the Reissner fiber for the maintenance of a straight body axis and spine morphogenesis in adult zebrafish. Our study establishes a framework for future investigations to address the cellular effectors responsible for Reissner-fiber-dependent regulation of axial morphology. VIDEO ABSTRACT.

Morphogenetic fields in embryogenesis, regeneration, and cancer: non-local control of complex patterning

Establishment of shape during embryonic development, and the maintenance of shape against injury or tumorigenesis, requires constant coordination of cell behaviors toward the patterning needs of the host organism. Molecular cell biology and genetics have made great strides in understanding the mechanisms that regulate cell function. However, generalized rational control of shape is still largely beyond our current capabilities. Significant instructive signals function at long range to provide positional information and other cues to regulate organism-wide systems properties like anatomical polarity and size control. Is complex morphogenesis best understood as the emergent property of local cell interactions, or as the outcome of a computational process that is guided by a physically encoded map or template of the final goal state? Here I review recent data and molecular mechanisms relevant to morphogenetic fields: large-scale systems of physical properties that have been proposed to store patterning information during embryogenesis, regenerative repair, and cancer suppression that ultimately controls anatomy. Placing special emphasis on the role of endogenous bioelectric signals as an important component of the morphogenetic field, I speculate on novel approaches for the computational modeling and control of these fields with applications to synthetic biology, regenerative medicine, and evolutionary developmental biology.

Spinal cord is required for proper regeneration of the tail in Xenopus tadpoles

Tail regeneration in urodeles is dependent on the spinal cord (SC), but it is believed that anuran larvae regenerate normal tails without the SC. To evaluate the precise role of the SC in anuran tail regeneration, we developed a simple operation method to ablate the SC completely and minimize the damage to the tadpole using Xenopus laevis. The SC-ablated tadpole regenerated a twisted and smaller tail. These morphological abnormalities were attributed to defects in the notochord (NC), as the regenerated NC in the SC-ablated tail was short, slim and twisted. The SC ablation never affected the early steps of the regeneration, including closure of the amputated surface with epidermis and accumulation of the NC precursor cells. The proliferation rate of the NC precursor cells, however, was reduced, and NC cell maturation was retarded in the SC-ablated tail. These results show that the SC has an essential role in the normal tail regeneration of Xenopus larvae, especially in the proliferation and differentiation of the NC cells. Gene expression analysis and implantation of a bead soaked with growth factor showed that fibroblast growth factor-2 and -10 were involved in the signaling molecules, which were expressed in the SC and stimulated growth of the NC cells.

Functional aspects of the subcommissural organ-Reissner's fiber complex with emphasis in the clearance of brain monoamines

Reissner's fiber (RF) extends along the cerebral aqueduct, fourth ventricle, and the entire length of the central canal of the spinal cord. It grows continuously in the caudal direction by addition of newly released glycoproteins by the subcommissural organ (SCO) to its proximal end. Several hypotheses about RF function have been advanced. One of them postulates that RF binds biogenic amines present in the CSF and clears them away. In recent years, this hypothesis has been tested in our laboratory by using several experimental protocols. Firstly, the CSF concentration of monoamines was investigated in RF-deprived rats subjected to immunological neutralization of the SCO-RF complex. Secondly, the capacity of RF to bind monoamines in vivo was studied by injecting radiolabeled serotonin or noradrenaline into the rat CSF, and by perfusing them into the CSF, during one week, using an Alzet's osmotic pump. In vitro binding studies were performed using isolated bovine RF. All the findings obtained indicate that RF binds monoamines present in the ventricular CSF and then transports them along the central canal. In the absence of RF, the CSF concentration of monoamines increases sharply.

The subcommissural organ

The subcommissural organ (SCO) is a phylogenetically ancient and conserved structure. During ontogeny, it is one of the first brain structures to differentiate. In many species, including the human, it reaches its full development during embryonic life. The SCO is a glandular structure formed by ependymal and hypendymal cells highly specialized in the secretion of proteins. It is located at the entrance of the aqueduct of Sylvius. The ependymal cells secrete into the ventricle core-glycosylated proteins of high molecular mass. The bulk of this secretion is formed by glycoproteins that would derive from two different precursors of 540 and 320 kDa and that, upon release into the ventricle aggregate, form a threadlike structure known as Reissner's fiber (RF). By addition of newly released glycoproteins to its proximal end, RF grows caudally and extends along the aqueduct, fourth ventricle, and the whole length of the central canal of the spinal cord. RF material continuously arrives at the dilated caudal end of the central canal, known as the terminal ventricle or ampulla. When reaching the ampulla, the RF material undergoes chemical modifications, disaggregates, and then escapes through openings in the dorsal wall of the ampulla to finally reach local blood vessels. The SCO also appears to secrete a cerebrospinal fluid (CSF)-soluble material that is different from the RF material that circulates in the ventricular and subarachnoidal CSF. Cell processes of the ependymal and hypendymal cells, containing a secretory material, terminate at the subarachnoidal space and on the very special blood capillaries supplying the SCO. The SCO is sequestered within a double-barrier system, a blood-brain barrier, and a CSF-SCO barrier. The function of the SCO is unknown. Some evidence suggests that the SCO may participate in different processes such as the clearance of certain compounds from the CSF, the circulation of CSF, and morphogenetic mechanisms.

Ontogenesis of the secretory epithelium of the bovine subcommissural organ. A histofluorescence study using lectins and monoclonal antibodies

A spatio-temporal analysis of the differentiation of a group of specialized (secretory) ependymal cells in the subcommissural organ (SCO) of the brain was undertaken in the bovine using a monoclonal antibody (C1B8A8) which is specific of the secretory process in this organ. In addition, lectins (concanavalin agglutinin (Con A), Lens culinaris agglutinin (LCA), wheat germ agglutinin (WGA), and Phaseolus vulgaris agglutinin (PHA] were used to analyse the maturation of the carbohydrate moieties of the secretory product (subcommissuralin). Monoclonal antibody NC-1 specific to a complex carbohydrate epitope including a terminal 3-sulfoglucuronyl residue similar to HNK-1 was also tested to compare the reactivity of the SCO with that of other brain structures. These cells express a specific antigen related to the known secretory activity of the SCO during early embryogenesis (2 months). This antigen is recognized by C1B8A8 antibody and by Con A suggesting that high mannose-type glycoproteins are synthesized at this stage. Later on (approximately 3.5 months), appearance of C1B8A8, WGA, LCA, L- and E-PHA-positive material in the apical lining of the ependymal cells, close to the ventricular cavity, suggests that maturation of the complex-type glycoproteins (Asn-linked) occurs at this stage. Presence of secretory material in the CSF and Reissner's fibre could be detected using the same probes at a stage of 4 months. As early as 2 months NC-1-positive material was detected in the ependyma of the mesencephalic roof, while no reaction occurred in the SCO epithelium. This suggests that the carbohydrate moieties of subcommissuralin is different from that of ependymins beta and gamma. Using specific monoclonal antibodies, molecular characterization of subcommissuralin and experimental analyses on its accurate role in brain development will further our tentative comparison with ependymins. The secretory ependymal cells in the SCO express a particular phenotype and could represent an increasing model to study cell differentiation in the brain.