Agarose Spot as a Comparative Method for in situ Analysis of Simultaneous Chemotactic Responses to Multiple Chemokines.

We describe a novel protocol to quantitatively and simultaneously compare the chemotactic responses of cells towards different chemokines. In this protocol, droplets of agarose gel containing different chemokines are applied onto the surface of a Petri dish, and then immersed under culture medium in which cells are suspended. As chemokine molecules diffuse away from the spot, a transient chemoattractant gradient is established across the spots. Cells expressing the corresponding cognate chemokine receptors migrate against this gradient by crawling under the agarose spots towards their centre. We show that this migration is chemokine-specific; meaning that only cells that express the cognate chemokine cell surface receptor, migrate under the spot containing its corresponding chemokine ligand. Furthermore, we show that migration under the agarose spot can be modulated by selective small molecule antagonists present in the cell culture medium.

Discovery and computer aided potency optimization of a novel class of small molecule CXCR4 antagonists.

Amongst the chemokine signalling axes involved in cancer, chemokine CXCL12 acting on chemokine receptor CXCR4 is particularly significant since it orchestrates migration of cancer cells in a tissue-specific metastatic process. High CXCR4 tumour expression is associated with poor prognosis of lung, brain, CNS, blood and breast cancers. We have identified a new class of small molecule CXCR4 antagonists based on the use of computational modelling studies in concert with experimental determination of in vitro activity against CXCL12-induced intracellular calcium mobilisation, proliferation and chemotaxis. Molecular modelling proved to be a useful tool in rationalising our observed potencies, as well as informing the direction of the synthetic efforts aimed at producing more potent compounds.

ABCG2-dependent dye exclusion activity and clonal potential in epithelial cells continuously growing for 1 month from limbal explants.

PURPOSE: To determine changes in ABCG2-transport-dependent dye exclusion in outgrowths from limbal explants. METHODS: Human or rabbit limbal strips were deposited onto inserts. Over a month, the segments were twice transferred to new inserts. Fresh tissue (FT) cells, obtained by sequential dispase-trypsin digestion and the cells growing from the explant cultures, were characterized for ABCG2-dependent efflux by flow cytometry using a newly identified substratum, JC1. Rabbit cells were sorted into JC1-excluding (JC1(low)) and main (JC1(main)) cohorts and seeded with feeder 3T3 cells to determine colony formation efficiency (CFE). RESULTS: The JC1(low) cells were all Hoechst 33342-excluding cells and vice versa, establishing the physical equivalence between JC1(low) and the side population (SP). JC1(low) cell content was reduced by three ABCG2-specific inhibitors: FTC, Ko143, and glafenine. JC1(low) percentiles for the fresh human and rabbit cells were 1.4% and 4.1% and CFEs for rabbit JC1(low) and JC1(main) were 1.2% and 5.3%. In contrast, the respective JC1(low) percentiles in the first and second outgrowths were 19.5% and 27.4% and 25.8% and 32.5%, and the rabbit JC1(low) and JC1(main) CFEs were 12.3% and 0.9%. Thus, although in FT the contribution of the JC1(low) cohort to the CFE is minimal, in the explant culture the phenotype incorporates >80% of the CFE. CONCLUSIONS: ABCG2-dependent dye exclusion undergoes a large expansion in explant culture and becomes associated with a high CFE. The transport increase is more pronounced at late outgrowth times, suggesting permanence of stem cells within the explant.