Changes in the abundance of C3/C4 species of Inner Mongolia grassland: evidence from isotopic composition of soil and vegetation

Global warming, increasing CO2 concentration, and environmental disturbances affect grassland communities throughout the world. Here, we report on variations in the C3/C4 pattern of Inner Mongolian grassland derived from soil and vegetation. Soil samples from 149 sites covering an area of approximately 250 000 km 2 within Inner Mongolia, People’s Republic of China were analyzed for the isotopic composition (d 13 C) of soil organic carbon (SOC). The contrast in d 13 C between C3 and C4 plants allowed for calculation of the C3/C4 ratio from d 13 C of SOC with a two-member mixing model, which accounted for influences of aridity and altitude on d 13 C of the C3 end-member and for changes in d 13 C of atmospheric CO2. Maps were created geostatistically, and showed a substantially lower C4 abundance in soil than in recent vegetation (� 10%). The difference between soil and vegetation varied regionally and was most pronounced within an E–W belt along 441N and in a mountainous area, suggesting a spread of C4 plants toward northern latitudes (about 11) and higher altitudes. The areas of high C4 abundance for present vegetation and SOC were well delineated by the isotherms of crossover temperature based on the climatic conditions of the respective time periods. Our study indicates that change in the patterns of C3/C4 composition in the Inner Mongolia grassland was mainly triggered by increasing temperature, which overrode the antagonistic effect of rising CO2 concentrations.

[1]  Xiangming Xiao,et al.  Sensitivity of Inner Mongolia Grasslands to Climate Change , 1995 .

[2]  Organic carbon and carbon isotopes in modern and 100‐year‐old‐soil archives of the Russian steppe , 2002 .

[3]  Howard E. Epstein,et al.  Plant Effects on Spatial and Temporal Patterns of Nitrogen Cycling in Shortgrass Steppe , 1998, Ecosystems.

[4]  R. Wang Photosynthetic and morphological functional types from different steppe communities in Inner Mongolia, North China , 2004, Photosynthetica.

[5]  J. Paruelo,et al.  Relative Abundance of Plant Functional Types in Grasslands and Shrublands of North America , 1996 .

[6]  Susan E. Trumbore,et al.  AGE OF SOIL ORGANIC MATTER AND SOIL RESPIRATION: RADIOCARBON CONSTRAINTS ON BELOWGROUND C DYNAMICS , 2000 .

[7]  Deliang Chen,et al.  Annual temperatures during the last 2485 years in the mid-eastern Tibetan Plateau inferred from tree rings , 2009 .

[8]  J. Ehleringer,et al.  Quantum Yields for CO(2) Uptake in C(3) and C(4) Plants: Dependence on Temperature, CO(2), and O(2) Concentration. , 1977, Plant physiology.

[9]  Carbon isotope discrimination of C3 vegetation in Central Asian grassland as related to long-term and short-term precipitation patterns , 2008 .

[10]  J. Ni,et al.  Plant functional types and climate along a precipitation gradient in temperate grasslands, north-east China and south-east Mongolia , 2003 .

[11]  V. Pyankov,et al.  C4 plants in the vegetation of Mongolia: their natural occurrence and geographical distribution in relation to climate , 2000, Oecologia.

[12]  C. Humphrey,et al.  PASTORALISM AND INSTITUTIONAL CHANGE IN INNER ASIA : COMPARATIVE PERSPECTIVES FROM THE MECCIA RESEARCH PROJECT , 1999 .

[13]  Carbon isotope discrimination of C3 vegetation in Central Asian grassland as related to long-term and short-term precipitation patterns , 2008 .

[14]  K. Price,et al.  Response of seasonal vegetation development to climatic variations in eastern central Asia , 2003 .

[15]  J. Ehleringer,et al.  Carbon isotope ratios in belowground carbon cycle processes , 2000 .

[16]  K. Auerswald,et al.  Altitudinal gradients of grassland carbon and nitrogen isotope composition are recorded in the hair of grazers , 2007 .

[17]  Bilal M. Ayyub,et al.  Optimum Sampling for Structural Strength Evaluation , 1990 .

[18]  James S. Clark,et al.  Effects of climate and atmospheric CO2 partial pressure on the global distribution of C4 grasses: present, past, and future , 1998, Oecologia.

[19]  D. Etheridge,et al.  A 1000-year high precision record of δ 13 C in atmospheric CO 2 , 1999 .

[20]  M. Bird,et al.  Environmental controls on the stable carbon isotopic composition of soil organic carbon: implications for modelling the distribution of C3 and C4 plants, Australia , 2008 .

[21]  J. A. Teeri Interaction of temperature and other environmental variables influencing plant distribution. , 1988, Symposia of the Society for Experimental Biology.

[22]  Martin Bachmaier,et al.  Variogram or semivariogram? Understanding the variances in a variogram , 2008, Precision Agriculture.

[23]  R. Sage,et al.  Quo vadis C4? An ecophysiological perspective on global change and the future of C4 plants , 2004, Photosynthesis Research.

[24]  C. Daly,et al.  A knowledge-based approach to the statistical mapping of climate , 2002 .

[25]  S. Archer,et al.  δ13C values of soil organic carbon and their use in documenting vegetation change in a subtropical savanna ecosystem , 1998 .

[26]  C. D. Keeling,et al.  Recent trends in the 13C/12C ratio of atmospheric carbon dioxide , 1979, Nature.

[27]  A. Arneth,et al.  Soil carbon inventories and carbon-13 on a latitude transect in Siberia , 2002 .

[28]  Edzer J. Pebesma,et al.  Multivariable geostatistics in S: the gstat package , 2004, Comput. Geosci..

[29]  J. Ehleringer,et al.  Carbon Isotope Discrimination and Photosynthesis , 1989 .

[30]  Larry L. Tieszen,et al.  Climate controls on C3 vs. C4 productivity in North American grasslands from carbon isotope composition of soil organic matter , 2008 .

[31]  D. Schimel,et al.  Terrestrial ecosystems and the carbon cycle , 1995 .

[32]  G. Farquhar,et al.  13C discrimination during CO2 assimilation by the terrestrial biosphere , 1994, Oecologia.

[33]  James R. Ehleringer,et al.  Quantum Yields for CO2 Uptake in C3 and C4 Plants: Dependence on Temperature, CO2, and O2 Concentration , 1977 .

[34]  P. Hattersley The distribution of C3 and C4 grasses in Australia in relation to climate , 1983, Oecologia.

[35]  H. Friedli,et al.  Ice core record of the 13C/12C ratio of atmospheric CO2 in the past two centuries , 1986, Nature.

[36]  Yongfei Bai,et al.  Large regional-scale variation in C3/C4 distribution pattern of Inner Mongolia steppe is revealed by grazer wool carbon isotope Inner Mongolia steppe is revealed by grazer wool carbon isotope composition , 2009 .

[37]  H. Šantrůčková,et al.  Microbial processes and carbon‐isotope fractionation in tropical and temperate grassland soils , 2000 .

[38]  B. Wylie,et al.  NDVI, C3 AND C4 PRODUCTION, AND DISTRIBUTIONS IN GREAT PLAINS GRASSLAND LAND COVER CLASSES , 1997 .

[39]  R. Z. Wang,et al.  Photosynthetic Pathway and Morphological Functional Types in the Steppe Vegetation from Inner Mongolia, North China , 2003, Photosynthetica.

[40]  D. Manning,et al.  Influence of recent vegetation on labile and recalcitrant carbon soil pools in central Queensland, Australia: evidence from thermal analysis-quadrupole mass spectrometry-isotope ratio mass spectrometry. , 2008, Rapid communications in mass spectrometry : RCM.

[41]  J. Skjemstad,et al.  Recent vegetation changes in central Queensland, Australia: Evidence from δ13C and 14C analyses of soil organic matter , 2005 .

[42]  Richard Webster,et al.  Local disjunctive kriging of soil properties with change of support , 1991 .

[43]  C. Ghersa,et al.  Litter quality and nutrient cycling affected by grazing‐induced species replacements along a precipitation gradient , 2004 .

[44]  A. Zhisheng,et al.  δ13C variation of C3 and C4 plants across an Asian monsoon rainfall gradient in arid northwestern China , 2005 .

[45]  R. DeFries,et al.  Global distribution of C3 and C4 vegetation: Carbon cycle implications , 2003 .

[46]  Yongfei Bai,et al.  Large regional-scale variation in C3/C4 distribution pattern of Inner Mongolia steppe is revealed by grazer wool carbon isotope composition , 2009 .

[47]  Ming Xu,et al.  Material Flows and Economic Growth in Developing China , 2007 .

[48]  J. Ehleringer,et al.  C4 photosynthesis, atmospheric CO2, and climate , 1997, Oecologia.

[49]  R. Wang Photosynthetic Pathways, Life Forms, and Reproductive Types for Forage Species Along the Desertification Gradient on Hunshandake Desert, North China , 2002, Photosynthetica.

[50]  Graham D. Farquhar,et al.  Development of a stable isotope index to assess decadal‐scale vegetation change and application to woodlands of the Burdekin catchment, Australia , 2007 .

[51]  Harro A. J. Meijer,et al.  Environmental isotopes in the hydrological cycle: principles and applications , 2001 .

[52]  M. Bird,et al.  C4‐derived soil organic carbon decomposes faster than its C3 counterpart in mixed C3/C4 soils , 2007 .

[53]  L. Tieszen,et al.  Carbon Isotope Dynamics During Grass Decomposition and Soil Organic Matter Formation , 1995 .

[54]  Xiusheng Yang,et al.  An Analysis of Sensitivity of Terrestrial Ecosystems in China to ClimaticChange Using Spatial Simulation , 2000 .

[55]  W. Horwath,et al.  Acid fumigation of soils to remove carbonates prior to total organic carbon or CARBON‐13 isotopic analysis , 2001 .

[56]  Steve P. McGrath,et al.  Trends in 13C/12C ratios and C isotope discrimination of wheat since 1845 , 2001, Oecologia.

[57]  Frank Bruhn,et al.  Vertical distribution, age, and chemical composition of organic carbon in two forest soils of different pedogenesis , 2002 .

[58]  I. Kögel‐Knabner,et al.  Araucaria forest expansion on grassland in the southern Brazilian highlands as revealed by 14C and δ13C studies , 2008 .

[59]  M. Bird,et al.  Variations of δ13C in the surface soil organic carbon pool , 1997 .

[60]  David J. Mulla,et al.  Geostatistical Tools for Modeling and Interpreting Ecological Spatial Dependence , 1992 .