黄连素对变异链球菌抑制作用的体外研究

目的分析黄连素对体外变异链球菌生长、产酸、粘附的影响,探讨其防龋作用。方法采用微量肉汤稀释法进行最小抑菌浓度(MIC)的测定;然后通过试管粘附法测定不同浓度药液对变异链球菌粘附作用的影响;最后计算不同浓度药液作用24h后pH值的变化。结果黄连素对变异链球菌的MIC为1.25mg/mL,MBC为5.00mg/mL。实验组对变异链球菌的粘附及产酸的抑制作用随着药物浓度的增加而增强,与阴性对照组相比差异有统计学意义(P0.05)。结论黄连素可抑制体外变异链球菌的生长、产酸及粘附。     

Predominant gain of promoter TATA box after gene duplication associated with stress responses

TATA box, the core promoter element, exists in a broad range of eukaryotes, and the expression of TATA-containing genes usually responds to various environmental stresses. Hence, the evolution of TATA-box in duplicate genes may provide some clues for the interrelationship among environmental stress, expression differentiation, and duplicate gene preservation. In the present study, we observed that the TATA box is significantly overrepresented in duplicate genes compared with singletons in human, worm, Arabidopsis, and yeast genomes. We then conducted an extensive functional genomic analysis to investigate the evolution of TATA box along over 700 yeast gene family phylogenies. After reconstructing the ancestral TATA-box states (presence or absence), we found that significantly higher numbers of TATA box gain events than loss events had occurred after yeast gene duplications-the overall gain-loss ratio is about 3-4 to 1. Interestingly, these TATA-gain duplicate genes on average have experienced greater expression divergence from the ancestral expression states than their most closely related TATA-less duplicate partners, but only under environmental stress conditions (asymmetric evolution); indeed, under normal physiological conditions, they have similar expression divergence (symmetric evolution). Moreover, we showed that TATA-gain duplicates are enriched in stress-associated functional categories but that is not the case for TATA-ancestral duplicates (those inherited from their ancestors prior to duplication). Together, we conclude that after the gene duplication, gain of the TATA box in duplicate promoters may have played an important role in yeast duplicate preservation by accelerating expression divergence that may facilitate the adaptive evolution of the organism in response to environmental changes.