02898nas a2200205 4500008004100000245011700041210006900158300001300227490000600240520226200246653001402508653001402522653001702536653001102553653001702564100001902581700001602600700002002616856005602636 2014 eng d00aGeographic variation in growth and phenology of two dominant Central US grasses: Consequences for climate change0 aGeographic variation in growth and phenology of two dominant Cen a211 -2210 v73 a
Aims The rate of climate change may exceed many plant species’ migration rates, particularly for long-lived perennial species that dominate most ecosystems. If bioclimatic envelopes shift more rapidly than dominant species can migrate, individuals located peripheral to biomes or in adjacent biomes may become a significant source of traits for future dominant populations (DPs). Thus, traits of individuals from peripheral populations (PPs) may affect future ecosystem functioning more than those of today’s DPs. Methods We assessed key traits of individuals collected from populations that currently dominate two central US grasslands, the shortgrass steppe (Bouteloua gracilis) and the tallgrass prairie (Andropogon gerardii). We compared these to individuals from PPs in a reciprocal-transplant common garden experiment with gardens at the Shortgrass Steppe Long Term Ecological Research site in Colorado and the Konza Prairie Biological Station Long Term Ecological Research site in Kansas. DPs and PPs were subjected to high and reduced water availability in common gardens located in each biome. Traits measured included the following: individual plant biomass, reproductive allocation, specific leaf area (SLA) and plant–water relations. We focused on the climate-change relevant comparisons of traits from PPs versus DPs expressed under the climate of DPs. Important Findings PPs of B. gracilis differed from DPs primarily in phenological traits. Under a semiarid shortgrass steppe climate, PPs initiated flowering later in the season, produced fewer reproductive tillers and were more sensitive to water stress. Biomass differences between populations were minimal. For A. gerardii, biomass in PPs was 50% lower than in DPs under the mesic tallgrass prairie climate and reproductive tillers were considerably smaller, despite higher SLA in PPs. Biomass of PPs was less sensitive to water stress, however. From these results, we conclude that key traits of PPs differed from DPs in both grassland types, but potential effects on reproductive phenology were greater for the bioclimatic shift in which a mesic biome becomes arid, whereas aboveground productivity may be affected more when a semiarid biome becomes more mesic.
10agrassland10aphenology10aproductivity10atraits10awater stress1 aGiuliani, A.L.1 aKelly, E.F.1 aKnapp, Alan, K. uhttps://academic.oup.com/jpe/article/7/3/211/90574602698nas a2200241 4500008004100000245009200041210006900133300001300202490000700215520193900222653002002161653003002181653003202211653002302243100001702266700002002283700001702303700001802320700001602338700002002354700001602374856006602390 2010 eng d00aFire and grazing impacts on silica production and storage in grass dominated ecosystems0 aFire and grazing impacts on silica production and storage in gra a263 -2780 v973 aGrassland ecosystems are an important terrestrial component of the global biogeochemical silicon cycle. Although the structure and ecological functioning of grasslands are strongly influenced by fire and grazing, the role of these key ecological drivers in the production and storage of silicon represents a significant knowledge gap, particularly since they are being altered worldwide by human activities. We evaluated the effects of fire and grazing on the range and variability of plant derived biogenic silica stored in plant biomass and soils by sampling plants and soils from long-term experimental plots with known fire and grazing histories. Overall, plants and soils from grazed sites in the South African ecosystems had up to 76 and 54% greater biogenic silica totals (kg ha−1), respectively, than grazed North American sites. In North American soils, the combination of grazing and annual fire resulted in the greatest abundance of biogenic silica, whereas South African soils had the highest biogenic silica content where grazed regardless of burn frequency. These results as well as those that show greater Si concentrations in grazed South African plants indicate that South African plants and soils responded somewhat differently to fire and grazing with respect to silicon cycling, which may be linked to differences in the evolutionary history and in the grazer diversity and grazing intensity of these ecosystems. We conclude that although fire and grazing (as interactive and/or independent factors) do not affect the concentration of Si taken up by plants, they do promote increased silicon storage in aboveground biomass and soil as a result of directly affecting other site factors such as aboveground net primary productivity. Therefore, as management practices, fire and grazing have important implications for assessing global change impacts on the terrestrial biogeochemical cycling of silicon.
10aBiogenic silica10aNorth American grasslands10aSoil South African savannas10aTerrestrial plants1 aMelzer, S.E.1 aKnapp, Alan, K.1 aFynn, R.W.S.1 aKirkman, K.P.1 aSmith, M.D.1 aBlair, John, M.1 aKelly, E.F. uhttps://link.springer.com/article/10.1007%2Fs10533-009-9371-302174nas a2200229 4500008004100000245010200041210006900143300001300212490000700225520140200232653002501634653003101659653003701690653002001727100001901747700001801766700001801784700001901802700002001821700001601841856008701857 2010 eng d00aPhosphorus biogeochemistry across a precipitation gradient in grasslands of central North America0 aPhosphorus biogeochemistry across a precipitation gradient in gr a954 -9610 v743 aSoil P transformations and distribution studies under water limited conditions that characterize many grasslands may provide further insight into the importance of abiotic and biotic P controls within grass-dominated ecosystems. We assessed transformations between P pools across four sites spanning the shortgrass steppe, mixed grass prairie, and tallgrass prairie along a 400-mm precipitation gradient across the central Great Plains. Pedon total elemental and constituent mass balance analyses reflected a pattern of increased chemical weathering from the more arid shortgrass steppe to the more mesic tallgrass prairie. Soil surface A horizon P accumulation was likely related to increased biocycling and biological mining. Soluble P, a small fraction of total P in surface A horizons, was greatest at the mixed grass sites. The distribution of secondary soil P fractions across the gradient suggested decreasing Ca-bound P and increasing amounts of occluded P with increasing precipitation. Surface A horizons contained evidence of Ca-bound P in the absence of CaCO3, while in subsurface horizons the Ca-bound P was associated with increasing CaCO3 content. Calcium-bound P, which dominates in water-limited systems, forms under different sets of soil chemical conditions in different climatic regimes, demonstrating the importance of carbonate regulation of P in semi-arid ecosystems.
10aGrassland ecosystems10aPhosphorus biogeochemistry10aSequential phosphorus extraction10aSoil weathering1 aIppolito, J.A.1 aBlecker, S.W.1 aFreeman, C.L.1 aMcCulley, R.L.1 aBlair, John, M.1 aKelly, E.F. uhttps://www.sciencedirect.com/science/article/abs/pii/S014019631000011X?via%3Dihub02509nas a2200169 4500008004100000245009600041210006900137300001500206490000700221520193700228100002402165700002002189700001602209700001702225700002002242856007702262 2009 eng d00aContingent productivity responses to more extreme rainfall regimes across a grassland biome0 aContingent productivity responses to more extreme rainfall regim a2894 -29040 v153 aClimate models predict, and empirical evidence confirms, that more extreme precipitation regimes are occurring in tandem with warmer atmospheric temperatures. These more extreme rainfall patterns are characterized by increased event size separated by longer within season drought periods and represent novel climatic conditions whose consequences for different ecosystem types are largely unknown. Here, we present results from an experiment in which more extreme rainfall patterns were imposed in three native grassland sites in the Central Plains Region of North America, USA. Along this 600 km precipitation–productivity gradient, there was strong sensitivity of temperate grasslands to more extreme growing season rainfall regimes, with responses of aboveground net primary productivity (ANPP) contingent on mean soil water levels for different grassland types. At the mesic end of the gradient (tallgrass prairie), longer dry intervals between events led to extended periods of below-average soil water content, increased plant water stress and reduced ANPP by 18%. The opposite response occurred at the dry end (semiarid steppe), where a shift to fewer, but larger, events increased periods of above-average soil water content, reduced seasonal plant water stress and resulted in a 30% increase in ANPP. At an intermediate mixed grass prairie site with high plant species richness, ANPP was most sensitive to more extreme rainfall regimes (70% increase). These results highlight the inherent complexity in predicting how terrestrial ecosystems will respond to forecast novel climate conditions as well as the difficulties in extending inferences from single site experiments across biomes. Even with no change in annual precipitation amount, ANPP responses in a relatively uniform physiographic region differed in both magnitude and direction in response to within season changes in rainfall event size/frequency.
1 aHeisler-White, J.L.1 aBlair, John, M.1 aKelly, E.F.1 aHarmoney, K.1 aKnapp, Alan, K. uhttps://onlinelibrary.wiley.com/doi/abs/10.1111/j.1365-2486.2009.01961.x02732nas a2200205 4500008004100000245011100041210006900152300001300221490000800234520204700242653001902289653001502308653003002323653002702353653002002380100002402400700002002424700001602444856006602460 2008 eng d00aIncreased precipitation event size increases aboveground net primary productivity in a semi-arid grassland0 aIncreased precipitation event size increases aboveground net pri a129 -1400 v1583 aWater availability is the primary constraint to aboveground net primary productivity (ANPP) in many terrestrial biomes, and it is an ecosystem driver that will be strongly altered by future climate change. Global circulation models predict a shift in precipitation patterns to growing season rainfall events that are larger in size but fewer in number. This “repackaging” of rainfall into large events with long intervening dry intervals could be particularly important in semi-arid grasslands because it is in marked contrast to the frequent but small events that have historically defined this ecosystem. We investigated the effect of more extreme rainfall patterns on ANPP via the use of rainout shelters and paired this experimental manipulation with an investigation of long-term data for ANPP and precipitation. Experimental plots (n = 15) received the long-term (30-year) mean growing season precipitation quantity; however, this amount was distributed as 12, six, or four events applied manually according to seasonal patterns for May–September. The long-term mean (1940–2005) number of rain events in this shortgrass steppe was 14 events, with a minimum of nine events in years of average precipitation. Thus, our experimental treatments pushed this system beyond its recent historical range of variability. Plots receiving fewer, but larger rain events had the highest rates of ANPP (184 ± 38 g m−2), compared to plots receiving more frequent rainfall (105 ± 24 g m−2). ANPP in all experimental plots was greater than long-term mean ANPP for this system (97 g m−2), which may be explained in part by the more even distribution of applied rain events. Soil moisture data indicated that larger events led to greater soil water content and likely permitted moisture penetration to deeper in the soil profile. These results indicate that semi-arid grasslands are capable of responding immediately and substantially to forecast shifts to more extreme precipitation patterns.
10aClimate change10aGrasslands10aPrecipitation variability10aPulse-reserve paradigm10aRain event size1 aHeisler-White, J.L.1 aKnapp, Alan, K.1 aKelly, E.F. uhttps://link.springer.com/article/10.1007%2Fs00442-008-1116-901505nas a2200145 4500008004100000245006700041210006700108490000700175520100900182100001801191700001901209700001901228700001601247856009601263 2006 eng d00aBiologic cycling of silica across a grassland bioclimosequence0 aBiologic cycling of silica across a grassland bioclimosequence0 v203 a[1] The dynamics of biologic Si cycling in grassland ecosystems are largely unknown and likely to impact mineral weathering rates regionally and diatom productivity globally; key regulatory processes in the global Si cycle are closely tied to the global carbon cycle. Across a bioclimatic sequence spanning major grassland ecosystems in the Great Plains, soil biogenic silica depth distributions are similar to that of soil organic carbon; however, unlike soil organic carbon, quantities of soil biogenic silica decrease with increasing precipitation, despite an increase in annual biogenic inputs through litterfall across the same gradient. Though comprising only 1–3% of the total Si pool, faster turnover of biogenic Si and annual cycling by grasses should positively impact mineral dissolution. Our results suggest that the largest reservoir of biogenic Si in terrestrial ecosystems resides in soils, and emphasize the potential significance of grasslands in the global biogeochemical cycle of Si.1 aBlecker, S.W.1 aMcCulley, R.L.1 aChadwick, O.A.1 aKelly, E.F. uhttp://lter.konza.ksu.edu/content/biologic-cycling-silica-across-grassland-bioclimosequence02493nas a2200265 4500008004100000245008100041210006900122300001300191490000600204520166200210653001401872653001701886653002501903653002701928653001801955653002001973653002101993100001902014700001602033700001702049700002002066700002002086700001602106856010502122 2005 eng d00aRegional patterns in carbon cycling across the Great Plains of North America0 aRegional patterns in carbon cycling across the Great Plains of N a106 -1210 v83 aThe large organic carbon (C) pools found in noncultivated grassland soils suggest that historically these ecosystems have had high rates of C sequestration. Changes in the soil C pool over time are a function of alterations in C input and output rates. Across the Great Plains and at individual sites through time, inputs of C (via aboveground production) are correlated with precipitation; however, regional trends in C outputs and the sensitivity of these C fluxes to annual variability in precipitation are less well known. To address the role of precipitation in controlling grassland C fluxes, and thereby soil C sequestration rates, we measured aboveground and belowground net primary production (ANPP-C and BNPP-C), soil respiration (SR-C), and litter decomposition rates for 2 years, a relatively dry year followed by a year of average precipitation, at five sites spanning a precipitation gradient in the Great Plains. ANPP-C, SR-C, and litter decomposition increased from shortgrass steppe (36, 454, and 24 g C m−2 y−1) to tallgrass prairie (180, 1221, and 208 g C m−2 y−1 for ANPP-C, SR-C, and litter decomposition, respectively). No significant regional trend in BNPP-C was found. Increasing precipitation between years increased rates of ANPP-C, BNPP-C, SR-C, and litter decomposition at most sites. However, regional patterns of the sensitivity of ANPP-C, BNPP-C, SR-C, and litter decomposition to between-year differences in precipitation varied. BNPP-C was more sensitive to between-year differences in precipitation than were the other C fluxes, and shortgrass steppe was more responsive than were mixed grass and tallgrass prairie.10agrassland10aGreat Plains10alitter decomposition10aNet primary production10aPrecipitation10aRegional trends10asoil respiration1 aMcCulley, R.L.1 aBurke, I.C.1 aNelson, J.A.1 aLauenroth, W.K.1 aKnapp, Alan, K.1 aKelly, E.F. uhttp://lter.konza.ksu.edu/content/regional-patterns-carbon-cycling-across-great-plains-north-america