Microbial metabolic quotient(MMQ) is the rate of soil microbial respiration per unit of microbial biomass, and represents the capacity of soil microbes to utilize soil organic matter.Understanding the regional variati...Microbial metabolic quotient(MMQ) is the rate of soil microbial respiration per unit of microbial biomass, and represents the capacity of soil microbes to utilize soil organic matter.Understanding the regional variation and determinants of MMQ can help predict the responses of soil respiration rate to global climate change.Accordingly, we measured and analyzed MMQ-related data(e.g., soil basic respiration rate at 20℃ and soil microbial biomass) from 17 grassland sites, which located in meadow steppe, typical steppe, and desert steppe along a 1000-km transect across the Inner Mongolian grasslands, China.Results showed that MMQ varied significantly among the different grassland types(P < 0.05;desert > typical > meadow) and decreased from southwest to northeast(r =–0.81) with increasing latitude(r = – 0.50), and with increasing mean annual precipitation(r = –0.69).Precipitation accounted for 56% of the total variation in MMQ, whereas temperature accounted for 26%.MMQ was negatively correlated with precipitation across the Inner Mongolian grasslands.Therefore, climate change, especially in regard to precipitation, may influence soil microbial respiration and soil carbon dynamics through altering MMQ.These results highlighted the importance of spatial patterns in MMQ for accurately evaluating the responses of soil respiration to climate change at regional and global scales.展开更多
The mechanisms driving changes in dominant plant species are the key for understanding how grassland ecosystems respond to climate change.In this study,we examined plant functional traits(morphological characteristic...The mechanisms driving changes in dominant plant species are the key for understanding how grassland ecosystems respond to climate change.In this study,we examined plant functional traits(morphological characteristics:plant height,leaf area,and leaf number;biomasses:aboveground,belowground,and total;and growth indices:root-to-shoot ratio,specific leaf area,and leaf mass ratio) of four zonal Stipa species(S.baicalensis,S.bungeana,S.grandis,and S.breviflora) from Inner Mongolian grassland in response to warming(control,+1.5,+2.0,+4.0,and +6.0℃),changing precipitation(-30%,-15%,control,+15%,and+30%),and their combined effects via climate control chambers.The results showed that warming and changing precipitation had significant interactive effects,different from the accumulation of single-factor effects,on functional traits of Stipa species.The correlation and sensitivity of different plant functional traits to temperature and precipitation differed.Among the four species,the accumulation and variability of functional traits had greater partial correlation with precipitation than temperature,except for leaf number,leaf area,and specific leaf area,in S.breviflora,S.bungeana,and S.grandis.For S.baicalensis,the accumulation and variability of plant height,aboveground biomass,and root-to-shoot ratio only had significant partial correlation with precipitation.However,the variability of morphological characteristics,biomasses,and some growth indices,was more sensitive to temperature than precipitation in S.bungeana,S.grandis,and S.breviflora—except for aboveground biomass and plant height.These results reveal that precipitation is the key factor determining the growth and changes in plant functional traits in Stipa species,and that temperature mainly influences the quantitative fluctuations of the changes in functional traits.展开更多
基金Under the auspices of National Key R&D Program of China(No.2016YFA0600104,2016YFC0500102,2017YFD0200604)National Natural Science Foundation of China(No.31770655,41671045,31772235)
文摘Microbial metabolic quotient(MMQ) is the rate of soil microbial respiration per unit of microbial biomass, and represents the capacity of soil microbes to utilize soil organic matter.Understanding the regional variation and determinants of MMQ can help predict the responses of soil respiration rate to global climate change.Accordingly, we measured and analyzed MMQ-related data(e.g., soil basic respiration rate at 20℃ and soil microbial biomass) from 17 grassland sites, which located in meadow steppe, typical steppe, and desert steppe along a 1000-km transect across the Inner Mongolian grasslands, China.Results showed that MMQ varied significantly among the different grassland types(P < 0.05;desert > typical > meadow) and decreased from southwest to northeast(r =–0.81) with increasing latitude(r = – 0.50), and with increasing mean annual precipitation(r = –0.69).Precipitation accounted for 56% of the total variation in MMQ, whereas temperature accounted for 26%.MMQ was negatively correlated with precipitation across the Inner Mongolian grasslands.Therefore, climate change, especially in regard to precipitation, may influence soil microbial respiration and soil carbon dynamics through altering MMQ.These results highlighted the importance of spatial patterns in MMQ for accurately evaluating the responses of soil respiration to climate change at regional and global scales.
基金Supported by the China Meteorological Administration Special Public Welfare Research Fund(GYHY201506001-3)Strategic Priority Research Program of the Chinese Academy of Sciences(XDA05050408)National(Key)Basic Research and Development(973)Program of China(2010CB951300)
文摘The mechanisms driving changes in dominant plant species are the key for understanding how grassland ecosystems respond to climate change.In this study,we examined plant functional traits(morphological characteristics:plant height,leaf area,and leaf number;biomasses:aboveground,belowground,and total;and growth indices:root-to-shoot ratio,specific leaf area,and leaf mass ratio) of four zonal Stipa species(S.baicalensis,S.bungeana,S.grandis,and S.breviflora) from Inner Mongolian grassland in response to warming(control,+1.5,+2.0,+4.0,and +6.0℃),changing precipitation(-30%,-15%,control,+15%,and+30%),and their combined effects via climate control chambers.The results showed that warming and changing precipitation had significant interactive effects,different from the accumulation of single-factor effects,on functional traits of Stipa species.The correlation and sensitivity of different plant functional traits to temperature and precipitation differed.Among the four species,the accumulation and variability of functional traits had greater partial correlation with precipitation than temperature,except for leaf number,leaf area,and specific leaf area,in S.breviflora,S.bungeana,and S.grandis.For S.baicalensis,the accumulation and variability of plant height,aboveground biomass,and root-to-shoot ratio only had significant partial correlation with precipitation.However,the variability of morphological characteristics,biomasses,and some growth indices,was more sensitive to temperature than precipitation in S.bungeana,S.grandis,and S.breviflora—except for aboveground biomass and plant height.These results reveal that precipitation is the key factor determining the growth and changes in plant functional traits in Stipa species,and that temperature mainly influences the quantitative fluctuations of the changes in functional traits.