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Protocadherin Celsr3 is crucial in axonal tract development

In the embryonic CNS, the development of axonal tracts is required for the formation of connections and is regulated by multiple genetic and microenvironmental factors. Here we show that mice with inactivation of Celsr3, an ortholog of Drosophila melanogaster flamingo (fmi; also known as starry night, stan) that encodes a seven-pass protocadherin, have marked, selective anomalies of several major axonal fascicles, implicating protocadherins in axonal development in the mammalian CNS for the first time. In flies, fmi controls planar cell polarity (PCP) in a frizzled-dependent but wingless-independent manner. The neural phenotype in Celsr3 mutant mice is similar to that caused by inactivation of Fzd3, a member of the frizzled family. Celsr3 and Fzd3 are expressed together during brain development and may act in synergy. Thus, a genetic pathway analogous to the one that controls PCP is key in the development of the axonal blueprint.

Early forebrain wiring: genetic dissection using conditional Celsr3 mutant mice.

Development of axonal tracts requires interactions between growth cones and the environment. Tracts such as the anterior commissure and internal capsule are defective in mice with null mutation of Celsr3. We generated a conditional Celsr3 allele, allowing regional inactivation. Inactivation in telencephalon, ventral forebrain, or cortex demonstrated essential roles for Celsr3 in neurons that project axons to the anterior commissure and subcerebral targets, as well as in cells that guide axons through the internal capsule. When Celsr3 was inactivated in cortex, subcerebral projections failed to grow, yet corticothalamic axons developed normally, indicating that besides guidepost cells, additional Celsr3-independent cues can assist their progression. These observations provide in vivo evidence that Celsr3-mediated interactions between axons and guidepost cells govern axonal tract formation in mammals.

Reelin, the extracellular matrix protein deficient in reeler mutant mice, is processed by a metalloproteinase

Reelin is the extracellular protein defective in reeler mice. It is believed that reelin acts via the extracellular matrix to influence the development of nearby neurons, but the mechanism remains thus far unknown. In the present work, we present in vivo and in vitro evidence that reelin is cleaved. This processing did not occur in Relnrl-Orl mutant mice in which reelin is not secreted and was prevented in explant cultures by brefeldin treatment, suggesting that it takes place extracellularly or in a postendoplasmic reticulum compartment. Reelin cleavage was inhibited by zinc chelators known to inhibit metalloproteinases but was unaffected by inhibitors of serine, cysteine, or aspartate proteinases. Furthermore, reelin cleavage was insensitive to inhibitors of matrixins, neprilysin, meprin, and peptidyl dipeptidase A, suggesting that the processing enzyme belongs to a different enzyme family. This enzyme and the physiological meaning of reelin processing remain to be characterized further.

The evolution of cortical development. An hypothesis based on the role of the Reelin signaling pathway

Expression of the genes encoding Reelin and Dab1 during cortical development in turtle, lizard, chick and mammals correlates with architectonic patterns. In all species, Reelin is secreted by marginal zone cells, whereas Dab1, which mediates the response to Reelin, is synthesized by cortical plate neurons. This pattern was presumably present in stem amniotes. In mammals, the cortical plate is radially organized and develops from inside to outside, these features depend on amplification of reelin synthesis in the marginal zone. In lizards, the cortical plate develops from outside to inside, similar to other non-mammals, but is radially organized, with an additional layer of Reelin added in the subcortex. Thus, the Reelin pathway played a key role in cortical architectonic evolution in mammalian and squamate lineages.

A YAC contig containing the reeler locus with preliminary characterization of candidate gene fragments

The reeler mutation in the mouse maps to proximal chromosome 5 and defines a key gene involved in brain development and evolution. No gene product is known, and the locus is currently being characterized by positional cloning. YAC clones corresponding to the closest markers D5Mit61 and D5Mit72 have been isolated. Cloned extremities of the YAC inserts were used to construct a 1.1-Mb contig, a 700-kb fragment of which was shown to contain the reeler locus. The integrity of the contig was verified by physical mapping on genomic DNA. The classical allele of the reeler mutation was associated with a 150-kb deletion between D5Mit61 and D5Mit72, while no gross chromosomal anomaly was found in the Orleans allele. Candidate coding sequences were isolated to construct a preliminary transcriptional map of the reeler region. Cosmid clones mapping within the rl deletion revealed a large transcript of more than 11 kb, which was present in normal embryonic brain but barely detectable in homozygous rlOrl/rlOrl embryonic brain, suggesting strongly that it corresponds to the reeler transcript.

Reelin mRNA expression during embryonic brain development in the chick

The expression of reelin mRNA was studied during embryonic brain development in the chick, by using in situ hybridization. Reelin was highly expressed in the olfactory bulb and in subpial neurons in the marginal zone of the cerebral cortex. In the diencephalon, the ventral division of lateral geniculate nuclei and perirotundal nuclei were strongly positive. High levels of expression were associated with some layers of the tectum and with the external granule cell layer of the cerebellum. A more moderate signal was detected in the septal nuclei, hyperstriatal fields, retina, habenular nuclei and hypothalamus, in some reticular nuclei of the mid‐ and hindbrain, and in the spinal cord. Little or no expression was observed in the cortical plate, Purkinje cells, or the inferior olivary complex. Comparison with reelin expression during mammalian and reptilian brain development reveals several evolutionarily conserved features that presumably define a homology. In addition, significant differences are noted, particularly in telencephalic fields. Most importantly, the developing chick cortex does not exhibit high levels of reelin expression in subpial Cajal‐Retzius cells characteristic of the mammalian brain. These observations are compatible with an action of reelin on adhesion and/or of nucleokinesis at the level of target cells. They further suggest that, whereas the telencephalon of birds and archosaurs evolved primarily from dorsal ventricular ridge derivatives in which reelin is probably secondary, the increase in number of reelin‐positive cells, and amplification of reelin expression played a key part in the evolution of the cortex in the synapsid lineage leading to mammals. J. Comp. Neurol. 422:448–463, 2000.

Reelin mRNA expression during embryonic brain development in the turtle Emys orbicularis

The expression of reelin messenger ribonucleic acid (mRNA) was studied during embryonic brain development in the turtle Emys orbicularis, by using radioactive in situ hybridization. A high expression was consistently found in the olfactory bulb and in a few neurons in the marginal zone and, to a lesser extent, in the subplate of the dorsal and medial cortical sectors. In the diencephalon, the ventral division of lateral geniculate nuclei and the prospective reticular thalamic nuclei were strongly positive. High reelin signal was also associated with some layers of the tectum and with the external granule cell layer of the cerebellum. A more moderate signal was detected in the septal nuclei, striatum, dorsal ventricular ridge, retina, habenular nuclei, and hypothalamus, and in some reticular nuclei of the midbrain and hindbrain and in ventral spinal cord. The cortical plate, basal forebrain, amygdala, and tegmentum were weakly labeled. When they are compared to reelin expression during mammalian brain development, our data reveal an evolutionarily conserved canvas of reelin expression and significant differences, particularly in developing cortical fields. Most significantly, the developing turtle cortex does not display the heavy reelin expression in subpial Cajal‐Retzius cells that is so typical of its mammalian counterpart. Given the key role of reelin in laminar cortical development, our data suggest that the increase in the number of reelin‐producing cells and/or the amplification of reelin expression in the cortical marginal zone might have been a driving factor during the evolution of the laminated cerebral cortex from stem reptiles to mammals, as indicated in previous comparative analyses. J. Comp. Neurol. 413:463–479, 1999.

Reelin expression during embryonic brain development in lacertilian lizards

The expression of reelin mRNA and protein was studied during embryonic brain development in the lacertilian lizards L. viridis and L. galloti, by using radioactive in situ hybridization and immunohistochemistry. At all stages studied, high reelin expression was consistently found in the olfactory bulb, in the lateral cortex, and in neurons of the marginal zone and subplate of medial and dorsal cortical sectors. In the dorsal ventricular ridge (DVR), reelin expression was confined to deeply located, large cells which were more abundant in the caudal than the rostral part of the DVR. In the diencephalon, the ventral lateral geniculate complex and the perirotundal were strongly positive, whereas other nuclei were mostly negative. High reelin signal was associated with some layers in the tectum, with the torus semicircularis, cerebellar granule cell layers, and the ventral horn of the spinal cord. A more moderate signal was detected in the septal nuclei, striatum, retina, habenular nuclei, preoptic and periventricular hypothalamic components, and in reticular nuclei of the mid‐ and hindbrain. The medial and dorsal cortical plate and Purkinje cells were reelin‐negative but expressed disabled‐1 (Dab1) mRNA. When they are compared with reelin expression during mammalian brain development, our data reveal an evolutionarily conserved canvas of reelin expression, as well as significant differences, particularly in developing cortical fields. The developing lizard cortex differs from that of turtles, birds, crocodiles, and mammals in that it displays heavy reelin expression not only in neurons of the marginal zone that might be homologous to mammalian Cajal‐Retzius cells, but also in subplate neurons. This difference in the pattern of reelin expression suggests that the elaborate radial organization of the lacertilian cortical plate, somewhat reminiscent of its mammalian counterpart, results from evolutionary convergence. Our data lend support to the hypothesis that the reelin signaling pathway played a significant role during cortical evolution. J. Comp. Neurol. 414:533–550, 1999.

Developmental neurobiology: Decoding the Reelin signal

Thereelermutant mouse has been used as a model of abnormal brain development for over 50 years. These mice lack a protein called Reelin, and they show a series of developmental abnormalities. Mice lacking two other proteins — the very low density lipoprotein receptor, and the apolipoprotein E receptor-2 — have now been found to show the same abnormalities, indicating that these molecules are involved in the Reelin signalling pathway.

The Reelin signaling pathway in mouse cortical development.

Most of the cerebral cortex derives from the cortical plate which, in all mammals, is radially organized and develops from inside to outside. Several genes involved in the organization and inside-outside development of the embryonic cortical plate in the mouse form the so-called Reelin signaling pathway. Biochemical and genetic arguments show that the extracellular matrix protein Reelin binds to two lipoprotein receptors (VLDLR and ApoER2), which relay the Reelin signal inside target neurons by docking the tyrosine kinase adapter disabled-1 (Dab1). In addition, biochemical evidence suggests that the integrins alpha 3/beta 1 and protocadherins of the CNR family may also modulate the Reelin signal. The mechanisms by which the presence of Reelin stops migration and instructs the radial organization of cortical plate cells remains unknown.