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Fluorescence-Activated Cell Sorting as a Method to Isolate Ionocyte Populations from Gill TissueEl-Sakhli, Ibragim 03 August 2018 (has links)
In freshwater fish, such as the rainbow trout (Oncorhynchus mykiss), higher ion concentrations in the body fluids relative to the dilute surrounding environment lead to diffusive ion loss that is countered by active ion uptake. Active ion uptake is achieved via specialised cells in the gill epithelium known as ionocytes, with the species studied to date exhibiting multiple ionocyte subtypes with specific complements of ion transport proteins. To better understand the functions and responses of each ionocyte subtype, methods are needed to isolate specific ionocyte subtypes. This thesis developed a method to use fluorescence-activated cell sorting (FACS) to isolate the peanut lectin agglutinin-positive (PNA+) ionocyte subtype of the trout gill, which is posited to be a base-secreting cell that takes up Cl- ions. A suspension of gill cells dissociated using ethylenediaminetetraacetic acid (EDTA) was labelled with biotinylated PNA that was detected using streptavidin conjugated to a fluorophore, and subjected to FACS to yield a population of PNA+ ionocytes of high viability and purity. To validate the utility of the approach, it was used in a proof-of-principle experiment to evaluate transcript abundance of cytosolic carbonic anhydrase (CAc) in PNA+ ionocytes in trout that were subjected to metabolic alkalosis. This experiment revealed that the relative transcript abundance of CAc was significantly elevated in PNA+ ionocytes of alkalotic trout relative to that of control trout (P = 0.001; N = 7), a response that is consistent with the expected role of PNA+ ionocytes in compensation for systemic alkalosis.
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Intracellular pH Regulation in H+-ATPase-rich Ionocytes in zebrafish larvae Using in vivo Ratiometric ImagingHong Meng, Yew January 2017 (has links)
The H+-ATPase rich (HR) cells of zebrafish larvae are a sub-type of ion-transporting cell located on the yolk sac epithelium that are responsible for Na+ uptake and H+ extrusion. Current models of HR cell ion transport mechanisms in zebrafish larvae are well established, but little is known about the involvement of the various ion transport pathways in regulating intracellular acid-base status. In the present study, a ratiometric imaging technique using the pH indicator dye BCECF was developed to monitor intracellular pH (pHi) continuously in larval zebrafish HR cells in vivo. Initial validation experiments demonstrated that HR cells subjected to respiratory acidosis (1% CO2) or metabolic alkalosis (20 mM NH4Cl) exhibited changes in BCECF 513/438 emission ratios which were consistent with the expected effects of these treatments on pHi. Subsequent experiments focussed on the involvement of the two principal apical membrane acid excretory pathways, the Na+/H+ exchanger (isoform NHE3b; zslc9a3.2) and the H+-ATPase (atpv1aa) in pHi regulation. Additionally, the role of HR cell carbonic anhydrase (“CA2-like a”) was investigated because of its presumed role in providing H+ for Na+/H+ exchange and H+-ATPase. To do so, relative HR cell pHi changes were monitored during acid-base challenges in shams and in fish experiencing morpholino gene knockdown of either NHE3b, H+-ATPase or “CA2-like a”. The temporal pattern and extent of intracellular acidification during exposure of fish to 1% CO2 and the extent of post-CO2 alkalization were altered markedly in fish experiencing knockdown of “CA2-like a”, NHE3b or H+-ATPase. Although there were slight differences among the three knockdown experiments, the typical response was a greater degree of intracellular acidification during CO2 exposure and a reduced capacity to restore pHi to baseline levels post-hypercapnia. Knockdown of “CA2-like a”, although presumed to limit H+ availability to NHE3b and H+-ATPase, yielded qualitatively similar results to knockdown of either single H+ excretory pathway. The metabolic alkalosis and subsequent acidification associated with NH4Cl exposure and its washout were largely unaffected by gene knockdown. Overall, the results suggest markedly different mechanisms of intracellular acid-base regulation in zebrafish HR cells depending on the nature of the acid-base disturbance.
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