SummaryLong-term memory and synaptic plasticity are thought to require the synthesis of new proteins at activated synapses. The CPEB family of RNA binding proteins, including Drosophila Orb2, has been implicated in this process. The precise mechanism by which these molecules regulate memory formation is however poorly understood. We used gene targeting and site-specific transgenesis to specifically modify the endogenous orb2 gene in order to investigate its role in long-term memory formation. We show that the Orb2A and Orb2B isoforms, while both essential, have distinct functions in memory formation. These two isoforms have common glutamine-rich and RNA-binding domains, yet Orb2A uniquely requires the former and Orb2B the latter. We further show that Orb2A induces Orb2 complexes in a manner dependent upon both its glutamine-rich region and neuronal activity. We propose that Orb2B acts as a conventional CPEB to regulate transport and/or translation of specific mRNAs, whereas Orb2A acts in an unconventional manner to form stable Orb2 complexes that are essential for memory to persist.
Birbeck granules are unusual rod-shaped structures specific to epidermal Langerhans cells, whose origin and function remain undetermined. We investigated the intracellular location and fate of Langerin, a protein implicated in Birbeck granule biogenesis, in human epidermal Langerhans cells. In the steady state, Langerin is predominantly found in the endosomal recycling compartment and in Birbeck granules. Langerin internalizes by classical receptor-mediated endocytosis and the first Birbeck granules accessible to endocytosed Langerin are those connected to recycling endosomes in the pericentriolar area, where Langerin accumulates. Drug-induced inhibition of endocytosis results in the appearance of abundant open-ended Birbeck granule-like structures appended to the plasma membrane, whereas inhibition of recycling induces Birbeck granules to merge with a tubular endosomal network. In mature Langerhans cells, Langerin traffic is abolished and the loss of internal Langerin is associated with a concomitant depletion of Birbeck granules. Our results demonstrate an exchange of Langerin between early endosomal compartments and the plasma membrane, with dynamic retention in the endosomal recycling compartment. They show that Birbeck granules are not endocytotic structures, rather they are subdomains of the endosomal recycling compartment that form where Langerin accumulates. Finally, our results implicate ADP-ribosylation factor proteins in Langerin trafficking and the exchange between Birbeck granules and other endosomal membranes. INTRODUCTIONLangerhans cells (LCs), the representatives of the dendritic cell lineage in the epidermis and mucosal tissues, capture antigen in the skin before migrating to the T-cell-dependent areas of draining lymph nodes. During this migration, they undergo a maturation process that allows them to present antigens to naive T cells (Kripke et al., 1990;Moll et al., 1993). Notably, Langerhans cells are the only epidermal cells to constitutively express major histocompatibility complex class II molecules (Klareskog et al., 1977;Rowden et al., 1977), CD1a molecules (Fithian et al., 1981), and Langerin (Valladeau et al., 2000) at their cell surface. In addition, Langerhans cells differ ultrastructurally from other dendritic cells through the presence of Birbeck granules (BGs), distinctive rod-shaped structures of variable length with a central, periodically striated lamella (Birbeck et al., 1961).Despite the use of "dynamic" electron microscope studies (reviewed in Schuler et al., 1991), Birbeck granules remain enigmatic. Specifically, conflicting theories exist regarding Article published online ahead of print. Mol. Biol. Cell 10.1091/ mbc.01-06-0300. Article and publication date are at www.molbiolcell.org/cgi/doi/10.1091/mbc.01-06-0300.† These authors contributed equally to this work and are listed in alphabetical order. # Corresponding author. E-mail address: daniel.hanau@efs-alsace.fr. Abbreviations used: Au, gold-labeled; BG, Birbeck granule; ERC, endosomal recycling compartment; Fi, freshl...
The capability to take up mannosylated protein antigens is important for the biologic function of dendritic cells, as many glycoproteins derived from bacteria and fungi, e.g., Malassezia furfur, are mannosylated. The expression of the mannose receptor CD206 has been regarded a differentiation hallmark of immature dendritic cells, whereas monocytes and mature dendritic cells as well as epidermal Langerhans cells do not express CD206. This study describes some epidermal dendritic cells that may express CD206 under inflammatory skin conditions: Immunohistochemical and flow cytometric analysis with the CD206-specific D547 antibody confirmed that Langerhans cells from normal human skin do not express CD206. Epidermal cell suspensions from atopic dermatitis and psoriasis revealed two distinct subsets of epidermal dendritic cells: a CD1a(+++)/CD206(-) cell population (i.e., Langerhans cells) and a CD1a(+)/CD206(++) cell population, corresponding to the previously described inflammatory dendritic epidermal cells. CD206-mediated endocytosis, assessed by dextran-fluorescein isothiocyanate uptake, was demonstrated in inflammatory dendritic epidermal cells but not in Langerhans cells. CD206-independent uptake of the fluorescent dye Lucifer yellow, a pinocytosis marker, was demonstrated in both Langerhans cells and inflammatory dendritic epidermal cells. Electron microscopic examination, known to distinguish Langerhans cells from inflammatory dendritic epidermal cells by their Birbeck granules, revealed Langerhans cells with Birbeck granules and inflammatory dendritic epidermal cells without Birbeck granules. Inflammatory dendritic epidermal cells exhibited numerous coated pits and vesicles, the latter fusing with large endosome-like structures, thus suggesting a high endocytotic activity. Immunogold staining with D547 monoclonal antibody confirmed that inflammatory dendritic epidermal cells were positive for CD206. In conclusion, inflammatory dendritic epidermal cells but not Langerhans cells are expressing CD206 in situ and use it for receptor-mediated endocytosis.
The aim of the present study was to evaluate tissue architecture and lipid composition of commercially available reconstructed human skin models; EpiDerm™, SkinEthic™ and Episkin™ in comparison to in-house reconstructed epidermis on a de-epidermized dermis (RE-DED) model and native tissue. For this purpose, the tissue architecture was examined using light microscopy, electron microscopy and immunohistochemistry; epidermal lipid composition was analyzed by HPTLC. Histological examination showed a completely stratified epithelium in all skin models closely resembling normal human epidermis. Low intra-batch variation in tissue architecture was observed in all skin models, but moderate to considerable inter-batch variation was noticed. In the stratum corneum extracellular space, lipid lamellae consisting of multiple alternating electron-dense and electron-lucent bands were present. Lipid analyses revealed the presence of all major epidermal lipid classes. Compared with native epidermis and RE-DED in EpiDerm, SkinEthic and Episkin models, the content of polar ceramides 5 and 6 was lower, ceramide 7 was absent, and the content of free fatty acids was very low. Evaluation of the expression and localization of a number of differentiation-specific protein markers revealed that all skin models showed an aberrant expression of keratin 6, skin-derived antileukoproteinase, small-proline-rich proteins, involucrin and transglutaminase. Although variation within batches was low, in particular keratin 6, involucrin and skin-derived antileukoproteinase expression demonstrated some inter-batch variation. In conclusion, all skin models provide a promising means for studying the effects of topically applied chemicals, although the observed deviations in tissue homeostasis and barrier properties need to be diminished. All skin models tested reproduced many of the characteristics of normal human epidermis and therefore provide a morphologically relevant in vitro means to assess skin irritation and perform other skin-related studies.
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