Pax4-Ghrelin mediates the conversion of pancreatic ε-cells to ß-cells after extreme ß-cell loss in zebrafish.

Pancreatic ε-cells producing ghrelin are one type of endocrine cell found in islets, which have been shown to influence other intra-islet cells, especially in regulating the function of ß cells. However, the role of such cells during ß-cell regeneration is currently unknown. Here, using a zebrafish nitroreductase (NTR)-mediated ß-cell ablation model, we reveal that ghrelin-positive ε-cells in the pancreas act as contributors to neogenic ß-cells after extreme ß-cell loss. Further studies show that the overexpression of ghrelin or the expansion of ε-cells potentiates ß-cell regeneration. Lineage tracing confirms that a proportion of embryonic ε-cells can transdifferentiate to ß-cells, and that the deletion of Pax4 enhances this transdifferentiation of ε-cells to ß-cells. Mechanistically, Pax4 binds to the ghrelin regulatory region and represses its transcription. Thus, deletion of Pax4 derepresses ghrelin expression and causes producing more ghrelin-positive cells, enhancing the transdifferentiation of ε-cells to ß-cells and consequently potentiating ß-cell regeneration. Our findings reveal a previously unreported role for ε-cells during zebrafish ß-cell regeneration, indicating that Pax4 regulates ghrelin transcription and mediates the conversion of embryonic ε-cells to ß-cells after extreme ß-cell loss.

Hydrothermal carbonization of rape straw: Effect of reaction parameters on hydrochar and migration of AAEMs.

Hydrothermal carbonization (HTC) can improve biomass quality in both physical and chemical aspects for energy application. This study aims to investigate the characteristics and reactivities of rape straw (RS) hydrochars. Hydrochars were prepared at 160-240 °C with residence time of 15-120 min. Mass yield, energy yield, microstructure, functional group and migration of alkali and alkaline earth metals (AAEMs) were studied to evaluate the influence of different conditions on properties of hydrochar. The results showed that O/C and H/C ratio decreased, while the higher heating value (HHV) increased with increasing temperature and residence time. The effect of increasing temperature on hydrochar properties was more significant than residence time. The structure was changed, and hydrochar possessed a more stable form after the aromatization reaction. For the gasification reactivity of hydrochar, decomposition rate curves showed that the peak of pyrolysis and gasification moved to a higher temperature region with the increasing of HTC temperature because of the developed aromatic structures in hydrochar. The pyrolysis activation energy decreased from raw RS 71.68 to 41.03 kJ/mol in 240 °C, while gasification activation energy increased from 80.42 to 251.30 kJ/mol. Moreover, it was found that HTC can reduce the content of AAEMs efficiently and the best removal condition is 200 °C. Ca content dropped to a minimum value at 200 °C and then increased at higher temperature which may be caused by well-developed pore structure in hydrochars. This study provides basic data for comprehensive utilization of rape straw and migration mechanism of AAEMs in HTC process.