Abstract
With the increase of world food demand, the intensity of cultivated land use also increased. To improve soil nutrient concentrations and crop yield, several straw returning techniques have been developed. Studies have shown that straw returning is beneficial to soil, but few studies have focused on the relationship between microbes and fertility in seasonal freeze-thaw periods. A two-year cropland experiment was set up that comprised three different straw return strategies, namely covering tillage with straw return for two years (CS), rotary tillage and straw return for two years (RS), rotary covering tillage with straw return (first year covering and the second year rotary tillage) (CRS), and conventional tillage with no straw return (CK). Illumina Miseq high throughput sequencing of 16S rRNA was applied to assess bacteria community structure. The relationship between bacteria community structure and changes in soil fertility induced by different straw incorporating during seasonal trends was studied. Our results showed that soil bacterial communities varied significantly during the soil seasonal freeze-thaw period in the northwest of Jilin province, China, and were influenced, to some extent, by the different straw returning procedures. Multidimensional analysis revealed that total phosphorus (TP), available nitrogen (AN), and total nitrogen (TN) were the major drivers of bacterial community structure. The co-occurrence network was divided into several modules. Notably, the major bacterial modules varied significantly in different sampling periods and different treatments. These results suggested that specific bacterial groups could contribute to soil fertility in relation to environmental fluctuations. Some bacterial groups (e.g., Pyrinomonadales, Rhizobiales, Sphingomonadales, and Xanthomonadales, in order level) were directly linked with specific environmental factors, indicating the key roles of these groups in soil fertility. In summary, the soil bacterial communities varied significantly during the freeze-thaw period and might play important roles in the degradation of straw. Thus, the straw return could enhance soil fertility.
Highlights
IntroductionThe soil microbiome is one of the most complex and dynamic microbiomes on earth [1]
The soil microbiome is one of the most complex and dynamic microbiomes on earth [1].Environmental conditions significantly influenced microbial community structure in the soil ecosystems
The results of two-way ANOVA showed that control and different treatments, sampling periods, and their interaction had significant effects on most soil chemical properties (TN, available nitrogen (AN), total phosphorus (TP), available phosphorus (AP), available K (AK), pH, and soil organic carbon (SOC)), except for TK (Table 2)
Summary
The soil microbiome is one of the most complex and dynamic microbiomes on earth [1]. Environmental conditions significantly influenced microbial community structure in the soil ecosystems. It has been revealed that an optimum condition for each microbe is the best for its growth and activities [2]. Seasonal soil temperature and moisture variations are the key factors in biomass and microbial activity fluctuations in ecosystems [3,4,5]. Existing researches have recognized the importance of the N and P sources in the soil microbial community structure and enzyme activities [6,7,8,9,10]. Soil microbes can transform the organic matter in straw into the low-molecular organic matter during the decomposition of straw [11]. Proteobacteria, Actinobacteria, and Acidobacteria were found to mediate the degradation of sugar and fat in straw [11,12]
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