The embryonic epidermis of Xenopus tropialis: developing a model system for the study of mucociliary epithelia

Mucociliary epithelia are found in the human airways and act as the first line of defence against inhaled foreign agents. Mucus traps potentially damaging particles and the cilia transport the mucus away from the airways to remove the threat. Modelling mucociliary epithelia for research purposes is challenging. This is because the airways are enclosed and are thus difficult to study directly. Instead, tissue is extracted or in vitro techniques are employed. Whilst these systems are useful, there is a need for accessible in vivo models to complement them. In this thesis I assess a new model system for studying mucociliary epithelia. This system is the larval epidermis of the amphibian, Xenopus tropicalis. Its epidermis comprises multi-ciliated cells that beat in a polarised direction reminiscent of those found in the human airways. It is also proposed to have a number of other cell types including mucus-secreting cells, but very little is known about them. The epidermis is open and accessible to manipulation meaning that it has great potential to be used in the study of mucociliary epithelia in live, native conditions. Such a system would be a valuable addition to the current models employed. However, the epidermis has not been thoroughly characterized before so its utility as a model system remains speculative.To develop and evaluate this new model, I fully characterize the epidermis, showing that it has five distinguishable cell types. This includes a population of cells called ionocytes that are shown to be essential for the health and function of the epidermis. I also test for the presence of mucins, the structural component of mucus, secreted from the epidermis in order to evaluate the proposal that mucus-secreting cells are present in the epidermis. A mucin-like protein called otogelin is identified. After characterizing the epidermal cell types, I compare them to the human mucociliary epithelium and consider potential applications and future perspectives for this model.EThOS - Electronic Theses Online ServiceWellcome TrustGBUnited Kingdo

Selective Inhibition of Heparan Sulphate and Not Chondroitin Sulphate Biosynthesis by a Small, Soluble Competitive Inhibitor

From MDPI via Jisc Publications RouterHistory: accepted 2021-06-19, pub-electronic 2021-06-29Publication status: PublishedFunder: Biotechnology and Biological Sciences Research Council; Grant(s): 978724Funder: Medical Research Council; Grant(s): MR/L007525/1The glycosaminoglycan, heparan sulphate (HS), orchestrates many developmental processes. Yet its biological role has not yet fully been elucidated. Small molecule chemical inhibitors can be used to perturb HS function and these compounds provide cheap alternatives to genetic manipulation methods. However, existing chemical inhibition methods for HS also interfere with chondroitin sulphate (CS), complicating data interpretation of HS function. Herein, a simple method for the selective inhibition of HS biosynthesis is described. Using endogenous metabolic sugar pathways, Ac4GalNAz produces UDP-GlcNAz, which can target HS synthesis. Cell treatment with Ac4GalNAz resulted in defective chain elongation of the polymer and decreased HS expression. Conversely, no adverse effect on CS production was observed. The inhibition was transient and dose-dependent, affording rescue of HS expression after removal of the unnatural azido sugar. The utility of inhibition is demonstrated in cell culture and in whole organisms, demonstrating that this small molecule can be used as a tool for HS inhibition in biological systems

Embryonic frog epidermis: A model for the study of cell-cell interactions in the development of mucociliary disease

Specialised epithelia such as mucociliary, secretory and transporting epithelia line all major organs, including the lung, gut and kidney. Malfunction of these epithelia is associated with many human diseases. The frog embryonic epidermis possesses mucus-secreting and multiciliated cells, and has served as an excellent model system for the biogenesis of cilia. However, ionic regulation is important for the function of all specialised epithelia and it is not clear how this is achieved in the embryonic frog epidermis. Here, we show that a third cell type develops alongside ciliated and mucus-secreting cells in the tadpole skin. These cells express high levels of ion channels and transporters; therefore, we suggest that they are analogous to ionocytes found in transporting epithelia such as the mammalian kidney. We show that frog ionocytes express the transcription factor foxi1e, which is required for the development of these cells. Depletion of ionocytes by foxi1e knockdown has detrimental effects on the development of multiciliated cells, which show fewer and aberrantly beating cilia. These results reveal a newly identified role for ionocytes and suggest that the frog embryonic skin is a model system that is particularly suited to studying the interactions of different cell types in mucociliary, as well as in secretory and transporting, epithelia

Inositol kinase and its product accelerate wound healing by modulating calcium levels, Rho GTPases, and F-actin assembly.

Wound healing is essential for survival. We took advantage of the Xenopus embryo, which exhibits remarkable capacities to repair wounds quickly and efficiently, to investigate the mechanisms responsible for wound healing. Previous work has shown that injury triggers a rapid calcium response, followed by the activation of Ras homolog (Rho) family guanosine triphosphatases (GTPases), which regulate the formation and contraction of an F-actin purse string around the wound margin. How these processes are coordinated following wounding remained unclear. Here we show that inositol-trisphosphate 3-kinase B (Itpkb) via its enzymatic product inositol 1,3,4,5-tetrakisphosphate (InsP(4)) plays an essential role during wound healing by modulating the activity of Rho family GTPases and F-actin ring assembly. Furthermore, we show that Itpkb and InsP(4) modulate the speed of the calcium wave, which propagates from the site of injury into neighboring uninjured cells. Strikingly, both overexpression of itpkb and exogenous application of InsP(4) accelerate the speed of wound closure, a finding that has potential implications in our quest to find treatments that improve wound healing in patients with acute or chronic wounds

Selective Inhibition of Heparan Sulphate and Not Chondroitin Sulphate Biosynthesis by a Small, Soluble Competitive Inhibitor

The glycosaminoglycan, heparan sulphate (HS), orchestrates many developmental processes. Yet its biological role has not yet fully been elucidated. Small molecule chemical inhibitors can be used to perturb HS function and these compounds provide cheap alternatives to genetic manipulation methods. However, existing chemical inhibition methods for HS also interfere with chondroitin sulphate (CS), complicating data interpretation of HS function. Herein, a simple method for the selective inhibition of HS biosynthesis is described. Using endogenous metabolic sugar pathways, Ac(4)GalNAz produces UDP-GlcNAz, which can target HS synthesis. Cell treatment with Ac(4)GalNAz resulted in defective chain elongation of the polymer and decreased HS expression. Conversely, no adverse effect on CS production was observed. The inhibition was transient and dose-dependent, affording rescue of HS expression after removal of the unnatural azido sugar. The utility of inhibition is demonstrated in cell culture and in whole organisms, demonstrating that this small molecule can be used as a tool for HS inhibition in biological systems

Functional characterization of the mucus barrier on the Xenopus tropicalis skin surface

Significance The production of mucus helps to trap pathogens, preventing their entry into the body, while it also acts as an interface for many important physiological events (e.g., gas and nutrient exchange). In mammalian models, a detailed study of mucus and its component parts is hindered by the difficulty in accessing these internally located tissues. The Xenopus tropicalis tadpole skin offers a complementary nonmammalian model system to study mucosal epithelia. Using this, we identify a mucin, similar to human mucins, that protects against infection. This system offers an experimentally tractable approach to study mucins and the mucus barrier and their role in conferring protection at mucosal surfaces. </jats:p

A secretory cell type develops alongside multiciliated cells, ionocytes and goblet cells and provides a protective, anti-infective, function in the frog embryonic mucociliary epidermis

The larval epidermis of Xenopus is a bilayered epithelium, which is an excellent model system for the study of the development and function of mucosal and mucociliary epithelia. Goblet cells develop in the outer layer while multiciliated cells and ionocytes sequentially intercalate from the inner to the outer layer. Here, we identify and characterise a fourth cell type, the small secretory cell (SSC). We show that the development of these cells is controlled by the transcription factor Foxa1 and that they intercalate into the outer layer of the epidermis relatively late, at the same time as embryonic hatching. Ultrastructural and molecular characterisation shows that these cells have an abundance of large apical secretory vesicles, which contain highly glycosylated material, positive for binding of the lectin, peanut agglutinin, and an antibody to the carbohydrate epitope, HNK-1. By specifically depleting SSCs, we show that these cells are crucial for protecting the embryo against bacterial infection. Mass spectrometry studies show that SSCs secrete a glycoprotein similar to Otogelin, which may form the structural component of a mucus-like protective layer, over the surface of the embryo, and several potential antimicrobial substances. Our study completes the characterisation of all the epidermal cell types in the early tadpole epidermis and reinforces the suitability of this system for the in vivo study of complex epithelia, including investigation of innate immune defences