Rapid determination of microbial contamination of Bupleurum chinense DC. decoction slices by ATP bioluminescence technology combined with statistical analysis methods / 药学学报

This study focuses on the microbial quality control of the Chinese herbal decoction pieces. In view of the shortcomings of traditional culture methods such as slow detection speed and inability to detect unculturable microorganisms, a new method based on ATP bioluminescence technology combined with statistical analysis methods was established to rapidly predict and quantitatively detect the total aerobic microbial count (TAMC) and total yeast and mold count (TYMC) contaminated Bupleurum chinense DC. decoction pieces. Based on the optimized ATP bioluminesence detection system, accurate detection of pure bacterial solution of Escherichia coli, Bacillus subtilis and Staphylococcus aureus can be achieved, with detection limits of 47.86, 89.13 and 1 862.09 CFU·mL-1, respectively. The detection time was 6.5 h, and the detection cost was as low as 2 yuan/time. The upper and lower warning limits of TAMC were determined by the misjudgment rates of 10% and 20%, respectively. And the warning limit of TYMC was determined by the misjudgment rate of 20%. The proposed crossing method could quickly predict the amount of microbial contamination in Bupleurum chinense DC. decoction pieces. The constructed partial least squares regression (PLSR) model could accurately quantify the quantity of microbial contamination in Bupleurum chinense DC. decoction pieces. The optimal PLSR prediction model for TAMC had a correction coefficient (R2) of 0.826, a root mean square error of correction set (RMSEE) of 0.468 and a root mean square error of cross-validation set (RMSECV) of 0.465. The R2, RMSEE and RMSECV in the prediction model of TYMC were 0.778, 0.543 and 0.541, respectively. The aim of this study is to establish a kind of rapid detection method and prediction models for the microbial limit of traditional Chinese medicine and Chinese herbal decoction pieces, and to provide a more convenient and sensitive detection technology for the microbial quality process control of traditional Chinese medicine products.

Erratum: Tongxinluo inhibits neointimal formation by regulating the expression and post-translational modification of KLF5 in macrophages.

[This corrects the article on p. 4778 in vol. 8, PMID: 27904679.].

Tongxinluo inhibits neointimal formation by regulating the expression and post-translational modification of KLF5 in macrophages.

Neointimal hyperplasia is a common pathological characteristic in diverse vascular remodeling diseases. The inflammatory response that follows vascular injury plays an important role in intimal hyperplasia. Tongxinluo (TXL), a traditional Chinese medicine, can ameliorate neointimal formation via suppressing vascular inflammatory response induced by vascular injury. However, the mechanisms underlying anti-inflammatory and anti-intimal hyperplasia of TXL are still not fully understood. The aim of present study was to examine whether the expression and post-translational modification of KLF5 were involved in the vasoprotective effects of TXL. In vivo, TXL inhibited neointimal formation induced by carotid artery injury. In vitro, TNF-α treatment of macrophages resulted in the increased proliferation and migration, but the effects of TNF-α on macrophages were blocked by TXL treatment. Next, KLF5 expression was up-regulated by carotid artery injury in vivo, as well as by exposure of macrophages to TNF-α in vitro, whereas TXL treatment abrogated the up-regulation of KLF5 by TNF-α or vascular injury. Intimal hyperplasia was strongly reduced in macrophage-specific KLF5 knockout (KLF5ly-/-) mice, indicating that TXL inhibits intimal hyperplasia by suppression of KLF5 expression. Furthermore, besides down-regulating KLF5 expression in macrophages, TXL also regulated KLF5 stability by ubiquitination and sumoylation of KLF5. Finally, TNF-α induced KLF5 sumoylation via PI3K/Akt signaling, whereas TXL inhibited Akt phosphorylation induced by TNF-α. We conclude that the multiple ingredients in TXL may act on different targets, which in turn generates a range of actions that manifest as a comprehensively vasoprotective effect.

TMEM16A and myocardin form a positive feedback loop that is disrupted by KLF5 during Ang II-induced vascular remodeling.

The TMEM16A protein is an important component of Ca(2+)-dependent Cl(-) channels (CaCCs) in vascular smooth muscle cells. A recent study showed that TMEM16A inhibits angiotensin II-induced proliferation in rat basilar smooth muscle cells. However, whether and how TMEM16A is involved in vascular remodeling characterized by vascular smooth muscle cell proliferation remains largely unclear. In this study, luciferase reporter, Western blotting, and qRT-PCR assays were performed. The results suggested that myocardin promotes TMEM16A expression by forming a complex with serum response factor (SRF) on the TMEM16A promoter in human aortic smooth muscle cells (HASMCs). In turn, upregulated TMEM16A promotes expression of myocardin and vascular smooth muscle cell marker genes, thus forming a positive feedback loop that induces cell differentiation and inhibits cell proliferation. Angiotensin II inhibits TMEM16A expression via Krüppel-like factor 5 (KLF5) in cultured HASMCs. Moreover, in vivo experiments show that infusion of angiotensin II into mice causes a marked reduction in TMEM16A expression and vascular remodeling, and angiotensin II-induced effects are largely reversed in KLF5 null (KLF5(-/-)) mice. KLF5 competes with SRF to interact with myocardin, thereby limiting myocardin binding to SRF and the synergistic activation of the TMEM16A promoter by myocardin and SRF. Our studies demonstrated that angiotensin II induces KLF5 expression and facilitates KLF5 association with myocardin to disrupt the myocardin-SRF complex, subsequently leading to inhibition of TMEM16A transcription. Blocking the positive feedback loop between myocardin and TMEM16A may be a novel therapeutic approach for vascular remodeling.