Ramona Marino

Interactions between neuroactive steroids and reelin haploinsufficiency in Purkinje cell survival.

We determined total Purkinje cell (PC) numbers in cerebella of wild-type (+/+) and heterozygous (rl/+) reeler mice of either sex during early postnatal development; in parallel, we quantified levels of neuroactive steroids in the cerebellum with mass spectrometry. We also quantified reelin mRNA and protein expression with RT-PCR and Western blotting. PC numbers are selectively reduced at postnatal day 15 (P15) in rl/+ males in comparison to +/+ males, +/+ females, and rl/+ females. Administration of 17beta-estradiol (17beta-E) into the cisterna magna at P5 increases PC numbers in rl/+ males, but not in the other groups; conversely, estrogen antagonists 4-OH-tamoxifen or ICI 182,780 reduce PC numbers in +/+ and rl/+ females, but have no effect in males. Testosterone (T) levels at P5 are much higher in males than in females, reflecting the perinatal testosterone surge in males. In addition, rl/+ male cerebella at P5 show a peculiar hormonal profile in comparison with the other groups, consisting of increased levels of T and 17beta-E, and decreased levels of dihydrotestosterone. RT-PCR analysis indicated that heterozygosity leads to a 50% reduction of reelin mRNA in the cerebellum in both sexes, as expected, and that 17beta-E upregulates reelin mRNA, particularly in rl/+ males; reelin mRNA upregulation is associated with an increase of all major reelin isoforms. These effects may represent a novel model of how reelin deficiency interacts with variable perinatal levels of neuroactive steroids, leading to gender-dependent differences in genetic vulnerability.

Reelin is transiently expressed in the peripheral nerve during development and is upregulated following nerve crush

Reelin is an extracellular matrix protein which is critical for the positioning of migrating post-mitotic neurons and the laminar organization of several brain structures during development. We investigated the expression and localization of Reelin in the rodent peripheral nerve during postnatal development and following crush injury in the adult stage. As shown with Western blotting, immunocytochemistry and RT-PCR, Schwann cells in the developing peripheral nerve and in primary cultures from neonatal nerves produce and secrete Reelin. While Reelin levels are downregulated in adult stages, they are again induced following sciatic nerve injury. A morphometric analysis of sciatic nerve sections of reeler mice suggests that Reelin is not essential for axonal ensheathment by Schwann cells, however, it influences the caliber of myelinated axons and the absolute number of fibers per unit area. This indicates that Reelin may play a role in peripheral nervous system development and repair by regulating Schwann cell-axon interactions.

Impaired nerve regeneration in reeler mice after peripheral nerve injury

Reelin, an extracellular matrix protein, plays an important role in the regulation of neuronal migration and cortical lamination in the developing brain. Little is known, however, about the role of this protein in axonal regeneration. We have previously shown that Reelin is secreted by Schwann cells in the peripheral nerve compartment during postnatal development and that it is up‐regulated following nerve injury in adult mice. In this work, we generated mice deficient in Reelin (reeler) that express yellow fluorescent protein (YFP) in a subset of neurons and examined the axonal regeneration following nerve crush. We found that axonal regeneration was significantly altered compared with wild‐type mice. By contrast, retrograde tracing with Fluorogold dye after sciatic nerve crush was unaffected in these mutants, being comparable with normal axonal transport observed in wild‐type. These results indicate that the absence of Reelin impairs axonal regeneration following injury and support a role for this protein in the process of peripheral nerve regeneration.

Focusing on the Interactions between the GABAergic System and Neurosteroids in Neurodevelopmental Disorders

Neurosteroids play essential roles in the control of central nervous system functions during physiological and pathological conditions. Increasing evidences show gender differences in the pathogenesis and clinical manifestations of several neurodevelopmental conditions, including Autism Spectrum Disorders (ASD), possibly due to the action of sex hormones during critical periods of brain development. Furthermore, it is known that neuroactive steroids contribute to neuroprotection, spinogenesis, synaptogenesis, as well as to modulation of neuronal excitability via their interaction with GABA receptors. Dysfunctions of GABAergic signaling early in development lead to a severe excitation-inhibition unbalance in neuronal circuits, which may contribute to the pathophysiology of autism. In this review, we summarize recent data concerning the functional role of neurosteroids and their relationship with the GABAergic system, focusing on GABA-mediated neurotrasmission alterations characterizing some neurodevelopmental disorders.

Characterization of NGF, trkANGFR, and p75NTR in Retina of Mice Lacking Reelin Glycoprotein

Both Reelin and Nerve Growth Factor (NGF) exert crucial roles in retinal development. Retinogenesis is severely impaired in E-reeler mice, a model of Reelin deficiency showing specific Green Fluorescent Protein expression in Rod Bipolar Cells (RBCs). Since no data are available on Reelin and NGF cross-talk, NGF and trkANGFR/ p75NTR expression was investigated in retinas from E-reeler versus control mice, by confocal microscopy, Western blotting, and real time PCR analysis. A scattered increase of NGF protein was observed in the Ganglion Cell Layer and more pronounced in the Inner Nuclear Layer (INL). A selective increase of p75NTR was detected in most of RBCs and in other cell subtypes of INL. On the contrary, a slight trend towards a decrease was detected for trkANGFR, albeit not significant. Confocal data were validated by Western blot and real time PCR. Finally, the decreased trkANGFR/ p75NTR ratio, representative of p75NTR increase, significantly correlated with E-reeler versus E-control. These data indicate that NGF-trkANGFR/ p75NTR is affected in E-reeler retina and that p75NTR might represent the main NGF receptor involved in the process. This first NGF-trkANGFR/ p75NTR characterization suggests that E-reeler might be suitable for exploring Reelin-NGF cross-talk, representing an additional information source in those pathologies characterized by retinal degeneration.

Ambra1 Shapes Hippocampal Inhibition/Excitation Balance: Role in Neurodevelopmental Disorders

Imbalances between excitatory and inhibitory synaptic transmission cause brain network dysfunction and are central to the pathogenesis of neurodevelopmental disorders. Parvalbumin interneurons are highly implicated in this imbalance. Here, we probed the social behavior and hippocampal function of mice carrying a haploinsufficiency for Ambra1, a pro-autophagic gene crucial for brain development. We show that heterozygous Ambra1 mice (Ambra+/−) are characterized by loss of hippocampal parvalbumin interneurons, decreases in the inhibition/excitation ratio, and altered social behaviors that are solely restricted to the female gender. Loss of parvalbumin interneurons in Ambra1+/− females is further linked to reductions of the inhibitory drive onto principal neurons and alterations in network oscillatory activity, CA1 synaptic plasticity, and pyramidal neuron spine density. Parvalbumin interneuron loss is underlined by increased apoptosis during the embryonic development of progenitor neurons in the medial ganglionic eminence. Together, these findings identify an Ambra1-dependent mechanism that drives inhibition/excitation imbalance in the hippocampus, contributing to abnormal brain activity reminiscent of neurodevelopmental disorders.

Current progress of reelin in development, inflammation and tissue remodeling: From nervous to visual systems

Reelin is a matrix glycoprotein that plays a pivotal role for the positioning of neurons throughout brain development. In the early developing cortex Reelin regulates radial migration of cortical neurons while later in development, Reelin promotes maturation of dendrites and dendritic spines. Low Reelin levels characterize healthy adult brain while increased Reelin levels have been associated with cellular events underlying response to injury. Reelin has been detected in structural and immune cells outside brain (liver, gut/colon tracts, kidney, testis, ovary, lung, retina and cornea). In the Visual system, Reelin was first described in the retina and thereafter in the cornea. Increased Reelin levels were observed during retinogenesis, low levels were found in adulthood and a significant increase was detected upon injury. Insult-driven Reelin changes occur after upregulation of adhesion molecules, cytokines, neurotrophins, growth factors, neuropeptides and other mediators as well as their receptors. These soluble factors contribute to the development of nervous and visual system and promote survival/recovery of neurons/accessory cells populating the injured visual system. Likewise, Reelin might modulate these factors by driving different multiple effects on homeostasis/plasticity, inflammation, healing and remodeling at different physiopathological levels. Very low-density lipoprotein receptor, apolipoprotein E receptor 2, integrins and the adaptor molecule Disabled 1 trigger Reelin. Recent advances highlight some Reelin activities during inflammation and tissue remodeling and point out to a crucial Reelin activity in the visual system. A better understanding of Reelin function in retinal development might open to new attractive perspective for counteracting retina degeneration.