AI Article Synopsis
- Current models of eukaryotic chemotaxis suggest that new pseudopods form directionally based on external signaling, but quantitative analysis shows this isn't the case in shallow gradients.
- Pseudopods are typically produced by bifurcating existing ones rather than being created independently, and their formation occurs at a consistent rate regardless of movement direction in these gradients.
- The study indicates that pseudopod generation is not guided by chemoattractants, and instead, directional sensing relies on the accurate maintenance of existing pseudopods rather than creating new ones.
Article Abstract
Current models of eukaryotic chemotaxis propose that directional sensing causes localized generation of new pseudopods. However, quantitative analysis of pseudopod generation suggests a fundamentally different mechanism for chemotaxis in shallow gradients: first, pseudopods in multiple cell types are usually generated when existing ones bifurcate and are rarely made de novo; second, in Dictyostelium cells in shallow chemoattractant gradients, pseudopods are made at the same rate whether cells are moving up or down gradients. The location and direction of new pseudopods are random within the range allowed by bifurcation and are not oriented by chemoattractants. Thus, pseudopod generation is controlled independently of chemotactic signalling. Third, directional sensing is mediated by maintaining the most accurate existing pseudopod, rather than through the generation of new ones. Finally, the phosphatidylinositol 3-kinase (PI(3)K) inhibitor LY294002 affects the frequency of pseudopod generation, but not the accuracy of selection, suggesting that PI(3)K regulates the underlying mechanism of cell movement, rather than control of direction.
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