Interaction of prion protein with acetylcholinesterase: potential pathobiological implications in prion diseases

The prion protein (PrP) binds to various molecular partners, but little is known about their potential impact on the pathogenesis of prion diseases. Here, we show that PrP can interact in vitro with acetylcholinesterase (AChE), a key protein of the cholinergic system in neural and non-neural tissues. This heterologous association induced aggregation of monomeric PrP and modified the structural properties of PrP amyloid fibrils. Following its recruitment into PrP fibrils, AChE loses its enzymatic activity and enhances PrP-mediated cytotoxicity. Using several truncated PrP variants and specific tight-binding AChE inhibitors (AChEis), we then demonstrate that the PrP-AChE interaction requires two mutually exclusive sub-sites in PrP N-terminal domain and an aromatic-rich region at the entrance of AChE active center gorge. We show that AChEis that target this site impair PrP-AChE complex formation and also limit the accumulation of pathological prion protein (PrPSc) in prion-infected cell cultures. Furthermore, reduction of AChE levels in prion-infected heterozygous AChE knock-out mice leads to slightly but significantly prolonged incubation time. Finally, we found that AChE levels were altered in prion-infected cells and tissues, suggesting that AChE might be directly associated with abnormal PrP. Our results indicate that AChE deserves consideration as a new actor in expanding pathologically relevant PrP morphotypes and as a therapeutic target

Adult-specific Reelin expression alters striatal neuronal organization: implications for neuropsychiatric disorders

In addition to neuronal migration, brain development, and adult plasticity, the extracellular matrix protein Reelin has been extensively implicated in human psychiatric disorders such as schizophrenia, bipolar disorder, and autism spectrum disorder. Moreover, heterozygous reeler mice exhibit features reminiscent of these disorders, while overexpression of Reelin protects against its manifestation. However, how Reelin influences the structure and circuits of the striatal complex, a key region for the above-mentioned disorders, is far from being understood, especially when altered Reelin expression levels are found at adult stages. In the present study, we took advantage of complementary conditional gain- and loss-of-function mouse models to investigate how Reelin levels may modify adult brain striatal structure and neuronal composition. Using immunohistochemical techniques, we determined that Reelin does not seem to influence the striatal patch and matrix organization (studied by μ-opioid receptor immunohistochemistry) nor the density of medium spiny neurons (MSNs, studied with DARPP-32). We show that overexpression of Reelin leads to increased numbers of striatal parvalbumin- and cholinergic-interneurons, and to a slight increase in tyrosine hydroxylase-positive projections. We conclude that increased Reelin levels might modulate the numbers of striatal interneurons and the density of the nigrostriatal dopaminergic projections, suggesting that these changes may be involved in the protection of Reelin against neuropsychiatric disorders

A conserved role for Syntaxin-1 in pre- and post-commissural midline axonal guidance in fly, chick, and mouse

Axonal growth and guidance rely on correct growth cone responses to guidance cues. Unlike the signaling cascades that link axonal growth to cytoskeletal dynamics, little is known about the crosstalk mechanisms between guidance and membrane dynamics and turnover. Recent studies indicate that whereas axonal attraction requires exocytosis, chemorepulsion relies on endocytosis. Indeed, our own studies have shown that Netrin-1/Deleted in Colorectal Cancer (DCC) signaling triggers exocytosis through the SNARE Syntaxin-1 (STX1). However, limited in vivo evidence is available about the role of SNARE proteins in axonal guidance. To address this issue, here we systematically deleted SNARE genes in three species. We show that loss-of-function of STX1 results in pre- and post-commissural axonal guidance defects in the midline of fly, chick, and mouse embryos. Inactivation of VAMP2, Ti-VAMP, and SNAP25 led to additional abnormalities in axonal guidance. We also confirmed that STX1 loss-of-function results in reduced sensitivity of commissural axons to Slit-2 and Netrin-1. Finally, genetic interaction studies in Drosophila show that STX1 interacts with both the Netrin-1/DCC and Robo/Slit pathways. Our data provide evidence of an evolutionarily conserved role of STX1 and SNARE proteins in midline axonal guidance in vivo, by regulating both pre- and post-commissural guidance mechanisms

Analysis of Reelin function in brain development and in adult neurogenesis = Análisis de la función de Reelina en el desarrollo del cerebro y la neurogénesis adulta

[eng] Reelin is a large extracellular matrix glycoprotein with a crucial role both during brain development, where it is key for neuronal migration and for the formation of the layered structure of cerebral cortex and cerebellum, and in the adulthood, where it is involved in adult synaptic plasticity, including neurogenesis in the dentate gyrus and dendritogenesis amongst other processes. Reelin acts through the binding to its canonical receptors (apolipoprotein E receptor 2, ApoER2; and very low density lipoprotein receptor, VLDLR) which trigger a complex signaling cascade involving numerous kinases and the adaptor protein Dab1. At the embryonic stage, Reelin is expressed mainly by Cajal-Retzius cells on the developing brain whereas at perinatal stages its expression gradually disappears from Cajal-Retzius cells and starts to be expressed by GABAergic interneurons of the cortex and hippocampus. In the neocortex, postmitotic neurons migrate in an ordered sequence that determines the normal “inside-out” layer formation. The malpositioning of cortical neurons is a result of abnormal migration and could cause severe layering malformations with functional consequences related with neurodevelopmental diseases such as Schizophrenia, Autism and Epilepsy. In this context, one of the most studied models has been the reeler mouse which presents a characteristic phenotype caused by an autosomal mutation in the Rln gene. The reeler mouse presents several morphological defects including a failed pre-plate splitting that causes a roughly inverted neuronal layering in the cortex, mispositioning of pyramidal neurons as well as granular cells on the dentate gyrus and profound cerebellar hypoplasia. However the study of the effects of Reelin signaling in the adult brain is difficult in the reeler mouse model due to the failed migration and mispositioning during development. Thus, to unravel the function of Reelin at different developmental stages (from embryonic to adult) as well as to gain insight in the potential distinct contribution of Reelin from different cell-types, we have generated three Reelin deficient conditional transgenic lines which allow us to ubiquitously delete Reelin in a temporally-controlled manner (Cre fR/fR) or selectively remove Reelin from Cajal-Retzius cells (CR fR/fR) or GABAergic interneurons (Gad fR/fR). Analysis of the cortical organization using layer-specific markers reveals that, unlike the reeler mouse, none of our transgenic lines shows the characteristic inversion of cortical layers. Moreover, our data strongly indicates that Reelin from Cajal-Retzius cells is important for the typical inside-out laminar cortical development but seems to be dispensable for pre-plate splitting. Furthermore, our results suggest that the absence of Reelin during early postnatal and adult stages seems to impact on the well-defined laminar structure of the cortex, leading to an invasion of layer I by late-born neurons from layer II-III. Regarding the hippocampus, our results suggest, on the one hand, a differential contribution of Reelin expressed by Cajal-Retzius cells and by GABAergic interneurons in the formation of the laminar structures of the hippocampus. On the other hand, temporally-controlled removal of Reelin at postnatal stages demonstrates that it is essential for the correct formation of the hippocampus whereas in the adult seems to be key for several aspects of hippocampus neurogenesis, including neuronal positioning in the dentate gyrus and dendritic orientation at different maturation stages of adult new-born granule cells. Finally, our findings also support the importance of Reelin expression for proper Purkinje cell migration, but not for granule cell disposition in the cerebellum at early postnatal and adult stages. Taken altogether, our results suggest a causal relation between the absence of Reelin and structural alterations in the hippocampus, cortex and cerebellum, either at developments stages or adult stages.[spa] Reelina es una glicoproteína extracelular de matriz esencial para la regulación de los procesos de migración neuronal y posicionamiento de las neuronas corticales durante el desarrollo del encéfalo. Durante la embriogénesis, Reelina es producida por las células Cajal-Retzius de la superficie de la corteza en desarrollo. En este estadío, las neuronas postmitóticas migran de forma ordenada originando una estructura laminar en seis capas, en las cuáles las neuronas más jóvenes se sitúan en las capas más externas. La pérdida de Reelina durante el desarrollo comporta fallos en la migración de las neuronas, provocando a su vez grandes alteraciones en la estructuración de la corteza que contribuyen a la patogénesis de muchos trastornos neurológicos como el autismo, la epilepsia, la esquizofrenia, o el trastorno bipolar. En este contexto, uno de los fenotipos más estudiado es el del ratón mutante de Reelina, reeler, que presenta una estructura cortical alterada con las capas invertidas. Sin embargo, dado que la expresión de Reelina durante el desarrollo ocurre a edades embrionarias muy tempranas, es difícil estudiar el efecto de su pérdida en este tipo de mutantes a edades más tardías, en los que los primeros efectos de su pérdida son tan profundos. Todo ello evidencia la necesidad de desarrollar otro tipo de modelos en los que la pérdida de Reelina sea más gradual o selectiva. En estadíos perinatales y en el cerebro adulto Reelina es expresada principalmente por interneuronas gabaérgicas, donde presumiblemente Reelina controla funciones de formación de sinapsis y mantenimiento de la plasticidad sináptica de las neuronas del córtex y del hipocampo. Nuestros resultados muestran un fenotipo diferencial para cada uno de nuestros mutantes, sugiriendo un papel diferente de Reelina expresada por cada tipo celular, o en función del estadío en el cuál la deleccionamos. En concreto, hemos visto que la función de Reelina es imprescindible para la correcta laminación del córtex, para la formación del hipocampo, y para el correcto posicionamiento de las células Purkinje del cerebelo. Además la pérdida de Reelina en estadíos adultos comporta fallos en la neurogénesis de la zona subventricular del giro dentado

Specific contribution of Reelin expressed by Cajal-Retzius cells or GABAergic interneurons to cortical lamination

[Significance]: The present study highlights a fundamental role of GABAergic interneuron-derived Reelin in neuronal migration, in addition to CR cell–expressed Reelin. Further, we observed transient migratory deficits, indicating that Reelin expressed by either neuronal population is sufficient to reverse some lamination defects. We propose a model of Reelin action in corticogenesis based on the spatial and cell-specific expression of this key protein. Because several neuropsychiatric disorders are linked to Reelin deficits in interneurons, this study may provide a better understanding of the mechanisms associated with human brain disorders related to Reelin deficits.The extracellular protein Reelin, expressed by Cajal–Retzius (CR) cells at early stages of cortical development and at late stages by GABAergic interneurons, regulates radial migration and the “inside-out” pattern of positioning. Current models of Reelin functions in corticogenesis focus on early CR cell–derived Reelin in layer I. However, developmental disorders linked to Reelin deficits, such as schizophrenia and autism, are related to GABAergic interneuron–derived Reelin, although its role in migration has not been established. Here we selectively inactivated the Reln gene in CR cells or GABAergic interneurons. We show that CR cells have a major role in the inside-out order of migration, while CR and GABAergic cells sequentially cooperate to prevent invasion of cortical neurons into layer I. Furthermore, GABAergic cell–derived Reelin compensates some features of the reeler phenotype and is needed for the fine tuning of the layer-specific distribution of cortical neurons. In the hippocampus, the inactivation of Reelin in CR cells causes dramatic alterations in the dentate gyrus and mild defects in the hippocampus proper. These findings lead to a model in which both CR and GABAergic cell–derived Reelin cooperate to build the inside-out order of corticogenesis, which might provide a better understanding of the mechanisms involved in the pathogenesis of neuropsychiatric disorders linked to abnormal migration and Reelin deficits.This work was supported by grants from the Spanish Ministerio de Ciencia y Competitividad and Ministerio de Ciencia e Innovación (SAF2016-76340R and PID2019-106764RB-C21, Excellence Unit 629, María de Maeztu/Institute of Neurosciences) and by Centro de Investigación Biomédica en Red de Enfermedades Neurodegenerativas (Instituto de Salud Carlos III, Spanish Ministry of Health) (to E.S.).Peer reviewe

Adult-specific Reelin expression alters striatal neuronal organization : implications for neuropsychiatric disorders

In addition to neuronal migration, brain development, and adult plasticity, the extracellular matrix protein Reelin has been extensively implicated in human psychiatric disorders such as schizophrenia, bipolar disorder, and autism spectrum disorder. Moreover, heterozygous reeler mice exhibit features reminiscent of these disorders, while overexpression of Reelin protects against its manifestation. However, how Reelin influences the structure and circuits of the striatal complex, a key region for the above-mentioned disorders, is far from being understood, especially when altered Reelin expression levels are found at adult stages. In the present study, we took advantage of complementary conditional gain- and loss-of-function mouse models to investigate how Reelin levels may modify adult brain striatal structure and neuronal composition. Using immunohistochemical techniques, we determined that Reelin does not seem to influence the striatal patch and matrix organization (studied by μ-opioid receptor immunohistochemistry) nor the density of medium spiny neurons (MSNs, studied with DARPP-32). We show that overexpression of Reelin leads to increased numbers of striatal parvalbumin- and cholinergic-interneurons, and to a slight increase in tyrosine hydroxylase-positive projections. We conclude that increased Reelin levels might modulate the numbers of striatal interneurons and the density of the nigrostriatal dopaminergic projections, suggesting that these changes may be involved in the protection of Reelin against neuropsychiatric disorders

A conserved role for Syntaxin-1 in pre- and post-commissural midline axonal guidance in fly, chick, and mouse

Axonal growth and guidance rely on correct growth cone responses to guidance cues. Unlike the signaling cascades that link axonal growth to cytoskeletal dynamics, little is known about the crosstalk mechanisms between guidance and membrane dynamics and turnover. Recent studies indicate that whereas axonal attraction requires exocytosis, chemorepulsion relies on endocytosis. Indeed, our own studies have shown that Netrin-1/Deleted in Colorectal Cancer (DCC) signaling triggers exocytosis through the SNARE Syntaxin-1 (STX1). However, limited in vivo evidence is available about the role of SNARE proteins in axonal guidance. To address this issue, here we systematically deleted SNARE genes in three species. We show that loss-of-function of STX1 results in pre- and post-commissural axonal guidance defects in the midline of fly, chick, and mouse embryos. Inactivation of VAMP2, Ti-VAMP, and SNAP25 led to additional abnormalities in axonal guidance. We also confirmed that STX1 loss-of-function results in reduced sensitivity of commissural axons to Slit-2 and Netrin-1. Finally, genetic interaction studies in Drosophila show that STX1 interacts with both the Netrin-1/DCC and Robo/Slit pathways. Our data provide evidence of an evolutionarily conserved role of STX1 and SNARE proteins in midline axonal guidance in vivo, by regulating both pre- and post-commissural guidance mechanisms

A conserved role for Syntaxin-1 in pre- and post-commissural midline axonal guidance in fly, chick, and mouse

<div><p>Axonal growth and guidance rely on correct growth cone responses to guidance cues. Unlike the signaling cascades that link axonal growth to cytoskeletal dynamics, little is known about the crosstalk mechanisms between guidance and membrane dynamics and turnover. Recent studies indicate that whereas axonal attraction requires exocytosis, chemorepulsion relies on endocytosis. Indeed, our own studies have shown that Netrin-1/Deleted in Colorectal Cancer (DCC) signaling triggers exocytosis through the SNARE Syntaxin-1 (STX1). However, limited <i>in vivo</i> evidence is available about the role of SNARE proteins in axonal guidance. To address this issue, here we systematically deleted SNARE genes in three species. We show that loss-of-function of STX1 results in pre- and post-commissural axonal guidance defects in the midline of fly, chick, and mouse embryos. Inactivation of VAMP2, Ti-VAMP, and SNAP25 led to additional abnormalities in axonal guidance. We also confirmed that STX1 loss-of-function results in reduced sensitivity of commissural axons to Slit-2 and Netrin-1. Finally, genetic interaction studies in <i>Drosophila</i> show that STX1 interacts with both the Netrin-1/DCC and Robo/Slit pathways. Our data provide evidence of an evolutionarily conserved role of STX1 and SNARE proteins in midline axonal guidance <i>in vivo</i>, by regulating both pre- and post-commissural guidance mechanisms.</p></div

A conserved role for Syntaxin-1 in pre- and post-commissural midline axonal guidance in fly, chick, and mouse

Axonal growth and guidance rely on correct growth cone responses to guidance cues. Unlike the signaling cascades that link axonal growth to cytoskeletal dynamics, little is known about the crosstalk mechanisms between guidance and membrane dynamics and turnover. Recent studies indicate that whereas axonal attraction requires exocytosis, chemorepulsion relies on endocytosis. Indeed, our own studies have shown that Netrin-1/Deleted in Colorectal Cancer (DCC) signaling triggers exocytosis through the SNARE Syntaxin-1 (STX1). However, limited in vivo evidence is available about the role of SNARE proteins in axonal guidance. To address this issue, here we systematically deleted SNARE genes in three species. We show that loss-of-function of STX1 results in pre- and post-commissural axonal guidance defects in the midline of fly, chick, and mouse embryos. Inactivation of VAMP2, Ti-VAMP, and SNAP25 led to additional abnormalities in axonal guidance. We also confirmed that STX1 loss-of-function results in reduced sensitivity of commissural axons to Slit-2 and Netrin-1. Finally, genetic interaction studies in Drosophila show that STX1 interacts with both the Netrin-1/DCC and Robo/Slit pathways. Our data provide evidence of an evolutionarily conserved role of STX1 and SNARE proteins in midline axonal guidance in vivo, by regulating both pre- and post-commissural guidance mechanisms

A conserved role for Syntaxin-1 in pre- and post-commissural midline axonal guidance in fly, chick, and mouse

Axonal growth and guidance rely on correct growth cone responses to guidance cues. Unlike the signaling cascades that link axonal growth to cytoskeletal dynamics, little is known about the crosstalk mechanisms between guidance and membrane dynamics and turnover. Recent studies indicate that whereas axonal attraction requires exocytosis, chemorepulsion relies on endocytosis. Indeed, our own studies have shown that Netrin-1/Deleted in Colorectal Cancer (DCC) signaling triggers exocytosis through the SNARE Syntaxin-1 (STX1). However, limited in vivo evidence is available about the role of SNARE proteins in axonal guidance. To address this issue, here we systematically deleted SNARE genes in three species. We show that loss-of-function of STX1 results in pre- and post-commissural axonal guidance defects in the midline of fly, chick, and mouse embryos. Inactivation of VAMP2, Ti-VAMP, and SNAP25 led to additional abnormalities in axonal guidance. We also confirmed that STX1 loss-of-function results in reduced sensitivity of commissural axons to Slit-2 and Netrin-1. Finally, genetic interaction studies in Drosophila show that STX1 interacts with both the Netrin-1/DCC and Robo/Slit pathways. Our data provide evidence of an evolutionarily conserved role of STX1 and SNARE proteins in midline axonal guidance in vivo, by regulating both pre- and post-commissural guidance mechanisms