小檗碱通过挟持药物外排泵Mdr1p逆转白色念珠菌的多药耐药

药物外排泵的过量表达是病原微生物产生多药耐药(MDR)的重要原因之一.逆转药物外排泵的功能有望对抗多药耐药问题.在能危及人类生命的真菌病原菌白色念珠菌中,主要易化子超家族(MFS)类型转运蛋白Mdr1p能非特异性地向细胞外转运很多结构上不相关的抗真菌化合物,从而导致了白色念珠菌的多药耐药.本研究报道了一个有悖过往认知的案例:一个天然产物小檗碱不仅不会被白色念珠菌Mdr1p外排,而且还能特异性地挟持过表达的Mdr1p把自己运输进细胞.进一步研究发现,进入白色念珠菌细胞后的小檗碱能够在线粒体中积累,通过破坏线粒体膜电势和线粒体复合物I引起线粒体功能紊乱,从而杀死Mdr1p过表达的多药耐药白色念珠菌.在用Mdr1p过表达的白色念珠菌小鼠感染模型中,小檗碱治疗组小鼠的平均存活时间(MST)得到了显著延长.本研究提示找寻药物外排泵的逆转剂可能为如何克服多药耐药问题提供了一个新的思路.

Beauvericin counteracted multi-drug resistant Candida albicans by blocking ABC transporters

Multi-drug resistance of pathogenic microorganisms is becoming a serious threat,particularly to immunocompromised populations.The high mortality of systematic fungal infections necessitates novel antifungal drugs and therapies.Unfortunately,with traditional drug discovery approaches,only echinocandins was approved by FDA as a new class of antifungals in the past two decades.Drug efflux is one of the major contributors to multi-drug resistance,the modulator of drug efflux pumps is considered as one of the keys to conquer multi-drug resistance.In this study,we combined structure-based virtual screening and whole-cell based mechanism study,identified a natural product,beauvericin(BEA)as a drug efflux pump modulator,which can reverse the multi-drug resistant phenotype of Candida albicans by specifically blocking the ATP-binding cassette(ABC)transporters;meantime,BEA alone has fungicidal activity in vitro by elevating intracellular calcium and reactive oxygen species(ROS).It was further demonstrated by histopathological study that BEA synergizes with a sub-therapeutic dose of ketoconazole(KTC)and could cure the murine model of disseminated candidiasis.Toxicity evaluation of BEA,including acute toxicity test,Ames test,and hERG(human ether-a-go-go-related gene)test promised that BEA can be harnessed for treatment of candidiasis,especially the candidiasis caused by ABC overexpressed multi-drug resistant C.albicans.

Discovery of tanshinone derivatives with anti-MRSA activity via targeted bio-transformation

Two potent anti-MRSA tanshinone glycosides(1 and 2)were discovered by targeted microbial biotransformation,along with rapid identification via MS/MS networking.Serial reactions including dehydrogenation,demethylations,reduction,glycosylation and methylation have been observed after incubation of tanshinone IIA and fungus Mucor rouxianus AS 3.3447.In addition,tanshinosides B(2)showed potent activities against serial clinical isolates of oxacillin-resistant Staphylococcus aureus with MIC values of 0.78 mg/mL.This is the first study that shows a significant increase in the level and activities of tanshinone glycosides relative to the substrate tanshinone IIA.