Fish intestinal cultures for ecotoxicological studies : in vitro and primary culture models

Langan, Laura

January 2017

Ecotoxicity testing of chemicals for environmental risk assessment is an area where a high number of vertebrates are used across a variety of industrial sectors. The application of the 3Rs in toxicity testing using fish address both the ethical and societal concerns around this issue in addition to the increasing legislative requests for the incorporation of animal alternatives. This thesis aims to highlight the potential of 3D cell culture models to "bridge the gap" between in vitro and in vivo screening procedures for testing of chemicals with the potential to persist or bioaccumulate thereby improving the predictive power of screening procedures. This thesis examines two alternative methods for their potential use as an intestinal based toxicokinetic tool for environmental risk assessment, utilising an in vitro fish cell line replacement tool (RTgutGC). In addition, for the first time a new intestinal primary cell culture based model was developed to address both intestine region specific response (pyloric, anterior, mid and posterior) and size related adaptability to toxins. Paramagnetic oximetry was used to measure oxygen content within 3D structures (spheroids) in order to better understand the microenvironment of these culture models. Using histology, immunohistochemistry, transepithelial electrical resistance (TEER), transmission electron microscopy (TEM), metabolic, fluorescence and gene expression assays, the comparability of this system to native intestinal response was established. Following exposure to carefully chosen environmental contaminants (Benzo[a]pyrene and Copper), the RTgutGC cell line demonstrated comparable responses to existing literature in terms of uptake, metabolism, DNA damage and the presence an equivalent saturable level. Primary enterocytes cultured on transwell inserts remained viable for upto six weeks, with permeability and metabolic activity comparable to native tissue (both in vitro and ex vivo). Taken in combination, these features of enterocytes represent a profile more closely representative of the intestine then the widely used "gut sac" method. With the potential advantages of incorporating complexity at differing levels (connective tissue layer, intestinal bacteria biome), the intestinal models described offer the potential to screen highly persistent toxins which may require prolonged incubation, in addition to the exploration of complex experimental designs which minimise animal usage (uptake, depuration, uptake). As a consequence, the models developed within this thesis significantly enrich the emerging fish based in vitro testing strategies.

615.9

Investigating In Vivo Roles of Osteocyte Estrogen Receptor beta (Ot-ERβ) in Skeletal Biology and Validation of a Novel Three-dimensional (3D) In Vitro System for Studying Osteocyte Biology

Xiaoyu Xu (12463830)

26 April 2022

<p>Osteoporosis causes over two million skeletal fractures in the United States every year in people over 50 years of age. Age-related bone loss results from imbalanced bone turnover mainly caused by decreases in sex hormones and skeletal mechanobiology. Estrogen receptor β (ERβ) in osteocytes (Ot) has been proposed to mediate skeletal structural adaptations in response to estrogen and mechanical stimuli. However, direct <em>in vivo</em> studies on Ot-ERβ are lacking, and relevant <em>in vitro</em> studies are mostly made in two-dimensional (2D) culture models, whose cellular environment restricts Ot morphology and biology. To better understand the mechanisms of estrogen-ERs in age-related bone loss, it is important to investigate the role of Ot-ERβ in skeletal turnover in response to sex hormonal and mechanical cues and develop a novel 3D culture model that can reproduce Ot morphology for future <em>in vitro</em> ER studies. The role of Ot-ERβ in bone turnover and skeletal adaptive response to mechanical load were examined in male and female mice at 12wk and 30wk old. Ot-ERβ shows age- and sex-dependent effects on bone morphology. Young male mice with Ot-ERβ deletion (ERβ-dOT) showed increased vertebral cancellous bone, whereas decreased cortical and cancellous vertebral bone mass appeared in adult male ERβ-dOT mice. No difference in bone mass occurred in female mice between genotypes. Ot-ERβ mediates tibial mechanoadaptation in cortical but not cancellous in young and adult male mice but plays an inhibitory role in young female mice during cortical mechanoadaptation. Gonadectomy studies on young adult mice revealed that deletion of Ot-ERβ inhibits the sex hormone withdrawal-induced decreases in bone mass and skeletal strength for male mice but did not play a major role for female mice. Lastly, a novel 3D <em>in vitro</em> culture system was developed using collagen-mineral composites for investigating culture mineralization, osteocyte biology, and osteocyte-osteoblast interaction. Cell viability and cellular differentiation were validated after 3 days and 56 days of culture. Optimal PSC-HA culture conditions were determined based on osteocyte differentiation, gene expression analyses, and tissue mineralization. Overall, this work takes novel steps to demonstrate the <em>in vivo</em> role osteocyte-ERβ plays in skeletal morphology and mechanobiology and develops a novel <em>in vitro</em> 3D culture using PSC-HA composites. These advances will contribute to future mechanistic studies of sex hormone receptors in osteoblasts and osteocytes in age-related bone loss using controlled <em>in vitro</em> environments. </p>

Biomechanical Engineering

osteocytes

estrogen receptor

Skeletal mechanoadaptation

sex hormones

three-dimensional cultures

osteocyte differentiation

skeletal siffness

age-related bone loss