Objective·To preliminarily investigate the regulatory effect and underlying mechanism of fibroblast growth factor 2(FGF2)on R-spondin 1(Rspo1)expression in CD34+CD81+stromal cells from the mouse colon.Methods·Colonic CD45-CD326-CD31-GP38+CD81+Rspo1-tdTomato+stromal cells were sorted from Rspo1-tdTomato reporter mice by flow cytometry and subsequently cultured in vitro.The expression of surface protein markers was evaluated by flow cytometry after 14 d of culture.qPCR was employed to quantify Rspo1 expression in response to stimulation with FGF2,FGF9,epidermal growth factor(EGF),platelet-derived growth factor-bb(PDGF-bb),insulin-like growth factor 1(IGF1),or hepatocyte growth factor(HGF).RNA sequencing and bioinformatic analyses were used to identify the signaling pathways underlying FGF2-mediated regulation of Rspo1,followed by preliminary validation with pathway-specific inhibitors and qPCR.Results·After 14 d of culture,the sorted colonic stromal cells retained expression of CD34,CD81,and glycoprotein GP38,while remaining negative for other lineages markers CD45,CD326,and CD31.qPCR revealed that 20 ng/mL FGF2 significantly suppressed Rspo1 expression,whereas the other tested growth factors exerted no notable effect.RNA sequencing and bioinformatic analysis indicated that mitogen-activated protein kinase(MAPK)signaling pathway played a key role in the regulatory effect of FGF2 on Rspo1.qPCR further demonstrated that pretreatment with U0126,an inhibitor of mitogen extracellular kinase 1/2(MEK1/2),reversed FGF2-mediated suppression of Rspo1 expression.Conclusion·FGF2 may inhibit Rspo1 expression in mouse colonic CD34+CD81+stromal cells via the MEK1/2-extracellular regulated protein kinase 1/2(ERK1/2)signaling pathway.

Objective·To preliminarily investigate the regulatory effect and underlying mechanism of fibroblast growth factor 2(FGF2)on R-spondin 1(Rspo1)expression in CD34+CD81+stromal cells from the mouse colon.Methods·Colonic CD45-CD326-CD31-GP38+CD81+Rspo1-tdTomato+stromal cells were sorted from Rspo1-tdTomato reporter mice by flow cytometry and subsequently cultured in vitro.The expression of surface protein markers was evaluated by flow cytometry after 14 d of culture.qPCR was employed to quantify Rspo1 expression in response to stimulation with FGF2,FGF9,epidermal growth factor(EGF),platelet-derived growth factor-bb(PDGF-bb),insulin-like growth factor 1(IGF1),or hepatocyte growth factor(HGF).RNA sequencing and bioinformatic analyses were used to identify the signaling pathways underlying FGF2-mediated regulation of Rspo1,followed by preliminary validation with pathway-specific inhibitors and qPCR.Results·After 14 d of culture,the sorted colonic stromal cells retained expression of CD34,CD81,and glycoprotein GP38,while remaining negative for other lineages markers CD45,CD326,and CD31.qPCR revealed that 20 ng/mL FGF2 significantly suppressed Rspo1 expression,whereas the other tested growth factors exerted no notable effect.RNA sequencing and bioinformatic analysis indicated that mitogen-activated protein kinase(MAPK)signaling pathway played a key role in the regulatory effect of FGF2 on Rspo1.qPCR further demonstrated that pretreatment with U0126,an inhibitor of mitogen extracellular kinase 1/2(MEK1/2),reversed FGF2-mediated suppression of Rspo1 expression.Conclusion·FGF2 may inhibit Rspo1 expression in mouse colonic CD34+CD81+stromal cells via the MEK1/2-extracellular regulated protein kinase 1/2(ERK1/2)signaling pathway.

The paper described efforts made by Guangdong province to achieve a goal of the healthcare reform Serious diseases can be treated within the county.In this reform,the province attempts such operation mechanisms as autonomous type,guided type and trusted type for the purpose of elevating the service capabilities of county-level public hospitals.To this end,four independent operation mechanisms have also been built for talent development,remuneration incentive,specialty development,and cost control.All these efforts aim at encouraging the hospitals to improve service capability and quality.

The expensive production of bioethanol is because it has not yet reached the 'THREE-HIGH' (High-titer, high-conversion and high-productivity) technical levels of starchy ethanol production. To cope with it, it is necessary to implement a high-gravity mash bioethanol production (HMBP), in which sugar hydrolysates are thick and fermentation-inhibitive compounds are negligible. In this work, HMBP from an atmospheric glycerol autocatalytic organosolv pretreated wheat straw was carried out with different fermentation strategies. Under an optimized condition (15% substrate concentration, 10 g/L (NH4)2SO4, 30 FPU/g dry matter, 10% (V/V) inoculum ratio), HMBP was at 31.2 g/L with a shaking simultaneous saccharification and fermentation (SSF) at 37 degrees C for 72 h, and achieved with a conversion of 73% and a productivity of 0.43 g/(L x h). Further by a semi-SFF with pre-hydrolysis time of 24 h, HMBP reached 33.7 g/L, the conversion and productivity of which was 79% and 0.47 g/(L x h), respectively. During the SSF and semi-SSF, more than 90% of the cellulose in both substrates were hydrolyzed into fermentable sugars. Finally, a fed-batch semi-SFF was developed with an initial substrate concentration of 15%, in which dried substrate (= the weight of the initial substrate) was divided into three portions and added into the conical flask once each 8 h during the first 24 h. HMBP achieved at 51.2 g/L for 72 h with a high productivity of 0.71 g/(L x h) while a low cellulose conversion of 62%. Interestingly, the fermentation inhibitive compound was mainly acetic acid, less than 3.0 g/L, and there were no other inhibitors detected, commonly furfural and hydroxymethyl furfural existing in the slurry. The data indicate that the lignocellulosic substrate subjected to the atmospheric glycerol autocatalytic organosolv pretreatment is very applicable for HMBP. The fed-batch semi-SFF is effective and desirable to realize an HMBP.
Biofuels ; Carbohydrates ; chemistry ; Cellulose ; chemistry ; Ethanol ; metabolism ; Fermentation ; Furaldehyde ; chemistry ; Glycerol ; chemistry ; Hydrolysis ; Triticum