[Effects of fertilizer of calcium silicon magnesium potassium on the dynamics of soil acidity and exchangeable base cation in paddy field of southern China]. / ç¡ é’™é’¾é•è‚¥å¯¹å—æ–¹ç¨»ç”°åœŸå£¤é ¸æ€§å’Œç›åŸºç¦»å­åŠ¨æ€å˜åŒ–çš„å½±å“.

Soil acidification of large areas of paddy fields in southern China has become an important problem in rice production. Therefore, how to ameliorate or remedy the acidifying paddy soil and to exposit its mechanism has important theoretical and practical significance for rebuilding healthy soils and guaranteeing national food security. Although lime has already been extensively used to remedy acidified soils, long-term application of a large amount of lime would not only cause the soil to harden, but also disturb the balance between calcium, potassium and magnesium in the soil. Given the advantages of lower solubility and comprehensive nutrient supply, fertilizer of calcium silicon magnesium potassium (CSMP) may be used as an alternative. The aim of this study was to clarify the functions of CSMP and its effects on soil acidification in paddy fields. A four-year field experiment was conducted to investigate the dynamics of soil pH, exchangeable acidi-ty, exchangeable base cation and available silicon, as well as 0~30 cm pH buffer capacity (pHBC), net base production under CSMP fertilization in the paddy soil. There were five treatments, i.e. CK (traditional fertilization practice of the local farmers), treatment I (CK plus 750 kg·hm-2 CSMP); treatment II (CK plus 1125 kg·hm-2 CSMP), treatment III (CK plus 1500 kg·hm-2 CSMP), and treatment IV (CK plus 1875 kg·hm-2 CSMP). The results showed that the traditional fertilization practice of the local farmers resulted in a decline of soil pH, soil exchangeable base cation and base saturation year by year, but soil exchangeable acid was increased with year. Conversely, CSPM fertlization significantly raised soil pH, with the magnitude of increases positively depending on the number of application times or application rate. Continuous and repeated application of CSMP effectively promoted the accumulation of exchangeable base cation and the consumption of soil exchangeable acid in paddy soil, especially for the accumulation of soil exchangeable Ca2+, Mg2+ and the consumption of soil exchangeable Al3+. Furthermore, the more amount of CSPM application resulted in the more accumulation or consumption, but with relatively slower rate. The exchangeable base cation and alkali released by CSMP contributed 108.8% to the total reduction of soil exchangeable acid, suggesting that it was the main path to reduce soil exchangeable acid. Meanwhile, CSMP application improved soil acidity in paddy field, with the content of available silicon increased year by year and the increase amplitude became larger with the more amount of CSMP application. The traditional fertilization of local farmers resulted in soil acidification, with a acidification rate was 2.86 kmol H+·hm-2·a-1. CSMP application could effectively control soil acidification, producing a lot of alkalinity with net alkalinity production of 9.93-13.82 kmol OH-·hm-2·a-1. CSPM could release Ca2+, Mg2+ and alkali, which would mitigate soil acidification in paddy fields.

[Isolation of endophytic fungi from Zanthoxylum simulans and screening of its active strain].

This study aims at making full use of microbial resources, and screening the active endophytic fungi of anti-rheumatoid arthritis from Zanthoxylum simulans. The endophytic fungi were cultured and isolated by tissue culture and scribing method, and the active strain of inhibiting the proliferation of human rheumatoid arthritis synovial fibroblasts (HFLS-RA) was screened by MTT method. Morphological characteristics and rDNA ITS1-5.8S-ITS2 sequences were applied for the taxonomy of endophytic fungi. Strains were isolated from Z. simulans. Among them, MK-05, MK-17, MK-19, MK-23 having inhibiting activity to HFLS-RA, the IC50 were 0.367, 0.775, 0.689, 0.757 g·L⁻¹, respectively. By classic morphologic classification and sequencing the PCR-amplified rDNA ITS1-5.8S-ITS2 regions, four effective strains were identified as Botryosphaeria dothidea, Phomopsis sp., P. liquidambari and Diaporthe perseae. The active endophyic fungi that inhibited the proliferation of HFLS-RA were screened from Z. simulans for the first time, and the results lay the foundation for the development and utilization of the Z. simulans resources.