Manipulation of the nuclear envelope-associated protein SLAP during mammalian brain development affects cortical lamination and exploratory behavior.

Here, we report the first characterization of the effects resulting from the manipulation of Soluble-Lamin Associated Protein (SLAP) expression during mammalian brain development. We found that SLAP localizes to the nuclear envelope and when overexpressed causes changes in nuclear morphology and lengthening of mitosis. SLAP overexpression in apical progenitors of the developing mouse brain altered asymmetric cell division, neurogenic commitment and neuronal migration ultimately resulting in unbalance in the proportion of upper, relative to deeper, neuronal layers. Several of these effects were also recapitulated upon Cas9-mediated knockdown. Ultimately, SLAP overexpression during development resulted in a reduction in subcortical projections of young mice and, notably, reduced their exploratory behavior. Our study shows the potential relevance of the previously uncharacterized nuclear envelope protein SLAP in neurodevelopmental disorders.

Salamander-Eci: An optical clearing protocol for the three-dimensional exploration of regeneration.

BACKGROUND: Salamander limb regeneration is a complex biological process that entails the orchestration of multiple cellular and molecular mechanisms in a three-dimensional space. Hence, a comprehensive understanding of this process requires whole-structure level explorations. Recent advances in imaging and optical clearing methods have transformed the study of regenerative phenomena, allowing the three-dimensional visualization of structures and entire organisms. RESULTS: Here we introduce Salamander-Eci, a rapid and robust optical clearing protocol optimized for the widely used axolotl model, which allows simultaneous immunohistochemistry and Click-chemistry detection with minimal volume disruption. We provide examples of its application, from whole larva to adult limbs and organs, and complement it with an image analysis pipeline for volumetric cell quantification. Further, we offer a detailed 3D quantitation of cell proliferation throughout axolotl limb regeneration. CONCLUSIONS: Salamander-Eci enables the comprehensive volumetric analysis of regenerative phenomena at both local and systemic levels.

Immunity in salamander regeneration: Where are we standing and where are we headed?

Salamanders exhibit the most extensive regenerative repertoire among vertebrates, being able to accomplish scar-free healing and faithful regeneration of significant parts of the eye, heart, brain, spinal cord, jaws and gills, as well as entire appendages throughout life. The cellular and molecular mechanisms underlying salamander regeneration are currently under extensive examination, with the hope of identifying the key drivers in each context, understanding interspecies differences in regenerative capacity, and harnessing this knowledge in therapeutic settings. The immune system has recently emerged as a potentially critical player in regenerative responses. Components of both innate and adaptive immunity have been found at critical stages of regeneration in a range of salamander tissues. Moreover, functional studies have identified a requirement for macrophages during heart and limb regeneration. However, our knowledge of salamander immunity remains scarce, and a thorough definition of the precise roles played by its members is lacking. Here, we examine the evidence supporting roles for immunity in various salamander regeneration models. We pinpoint observations that need revisiting through modern genetic approaches, uncover knowledge gaps, and highlight insights from various model organisms that could guide future explorations toward an understanding of the functions of immunity in regeneration.

TßRIII is induced by TCR signaling and downregulated in FoxP3+ regulatory T cells.

TGF-ß type III receptor (TßRIII) is a co-receptor for TGFß family members required for high-affinity binding of these ligands to their receptors, potentiating their cellular functions. TGF-ßs, Bone Morphogenetic Proteins (BMP2/4) and Inhibins/Activins regulate different checkpoints during T cell differentiation. We have previously reported that TßRIII modulates T cell development by protecting developing thymocytes from apoptosis, however the role of this co-receptor in peripheral lymphocytes still remains elusive. Here we describe a detailed characterization of TßRIII expression in murine and human lymphocyte subpopulations demonstrating that this co-receptor is significantly expressed in T but not B lymphocytes and among them, preferentially expressed on naïve and central memory T cells. TßRIII was upregulated after TCR stimulation, in parallel to other early activation markers. In contrast, natural and induced Tregs downregulated TßRIII in association with FoxP3 upregulation. Finally, anti-TßRIII blocking experiments demonstrated that TßRIII promotes TGFß-dependent iTreg conversion in vitro, and suggest that this co-receptor may be involved in modulating peripheral T cell tolerance and could be considered as a potential target to boost T cell immune responses.