[Expert consensus on Injection of Breviscapine in clinical practice].

With the advancement of the aging process, cerebrovascular disease has become China's first cause of death. Injection of Breviscapine is a type of traditional Chinese medicine injections published in the Chinese Pharmacopoeia of 2015 Edition and the National Basic Medical Insurance, Industrial Injury Insurance and Maternity Insurance Drug Catalogue, and used to treat ischemic cerebrovascular disease in clinic. In order to further improve clinicians' understanding of the drug and guidance of its rational clinical use, we gave full consideration of clinical research evidences and expert experience, followed the procedures developed based on expert consensus of Chinese Academy of Traditional Chinese Medicine, and then offered recommendations for clinical problems summarized by clinical first-line investigations and evidence-based clinical problems according to internationally accepted evidence grading and recommendation standards, i.e. Grade. As for clinical problems without evidence, we reached through nominal group method, and formed consensus recommendations. Safety issues of Injection of Breviscapine, such as indication, syndrome, dosage, course of treatment, precautions, suggestions and contraindications, were defined to improve clinical efficacy, promote rational drug use and reduce drug risks. This consensus needs to be revised in the future based on emerging clinical issues and evidence-based updates in practical applications.

miR156 modulates rhizosphere acidification in response to phosphate limitation in Arabidopsis.

Rhizosphere acidification is a general response to Pi deficiency, especially in dicotyledonous plants. However, the signaling pathway underlying this process is still unclear. Here, we demonstrate that miR156 is induced in the shoots and roots of wild type Arabidopsis plants during Pi starvation. The rhizosphere acidification capacity was increased in 35S:MIR156 (miR156 overexpression) plants, but was completely inhibited in 35S:MIM156 (target mimicry) plants. Both 35S:MIR156 and 35S:MIM156 plants showed altered proton efflux and H(+)-ATPase activity. In addition, significant up-regulation of H(+)-ATPase activity in 35S:MIR156 roots coupled with increased citric acid and malic acid exudates was observed. qRT-PCR results showed that most H(+)-ATPase and PPCK gene transcript levels were decreased in 35S:MIM156 plants, which may account for the decreased H(+)-ATPase activity in 35S:MIM156 plants. MiR156 also affect the root architecture system. Collectively, our results suggest that miR156 regulates the process of rhizosphere acidification in plants.

Modulation of the Phosphate-Deficient Responses by MicroRNA156 and its Targeted SQUAMOSA PROMOTER BINDING PROTEIN-LIKE 3 in Arabidopsis.

The microRNA156 (miR156)-modulated SQUAMOSA PROMOTER BINDING PROTEIN-LIKE (SPL) is involved in diverse biological processes that include growth, development and metabolism. Here, we report that the Arabidopsis miR156 and SPL3 as regulators play important roles in phosphate (Pi) deficiency response. MiR156 was induced during Pi starvation whereas SPL3 expression was repressed. Phenotypes of reduced rhizosphere acidification and decreased anthocyanin accumulation were observed in 35S:MIM156 (via target mimicry) transgenic plants under Pi deficiency. The content and uptake of Pi in 35S:MIM156 Arabidopsis plants were increased compared with wild-type (Col-0 ecotype) plants. 35S:rSPL3 seedlings showed similar anthocyanin accumulation and Pi content phenotypes to those of 35S:MIM156 plants. Chromatin immunoprecipitation and an electrophoretic mobility shift assay indicated that the SPL3 protein directly bound to GTAC motifs in the PLDZ2, Pht1;5 and miR399f promoters. The expression of several Pi starvation-induced genes was increased in 35S:MIM156 and 35S:rSPL3 plants, including high-affinity Pi transporters, Mt4/TPS1-like genes and phosphatases. Collectively, our results suggest that the miR156-SPL3-Pht1;5 (-PLDZ2 and -miR399f) pathways constitute a component of the Pi deficiency-induced regulatory mechanism of Arabidopsis.