Feedback from plant species change amplifies CO2 enhancement of grassland productivity

Dynamic global vegetation models simulate feedbacks of vegetation change on ecosystem processes, but direct, experimental evidence for feedbacks that result from atmospheric CO₂ enrichment is rare. We hypothesized that feedbacks from species change would amplify the initial CO₂ stimulation of aboveground net primary productivity (ANPP) of tallgrass prairie communities. Communities of perennial forb and C₄ grass species were grown for 5 years along a field CO₂ gradient (250–500 μL L^?1) in central Texas USA on each of three soil types, including upland and lowland clay soils and a sandy soil. CO₂ enrichment increased community ANPP by 0–117% among years and soils and increased the contribution of the tallgrass species Sorghastrum nutans (Indian grass) to community ANPP on each of the three soil types. CO₂‐induced changes in ANPP and Sorghastrum abundance were linked. The slope of ANPP‐CO₂ regressions increased between initial and final years on the two clay soils because of a positive feedback from the increase in Sorghastrum fraction. This feedback accounted for 30–60% of the CO₂‐mediated increase in ANPP on the upland and lowland clay soils during the final 3 years and 1 year of the experiment, respectively. By contrast, species change had little influence on the ANPP‐CO₂ response on the sandy soil, possibly because Sorghastrum increased largely at the expense of a functionally similar C₄ grass species. By favoring a mesic C₄ tall grass, CO₂ enrichment approximately doubled the initial enhancement of community ANPP on two clay soils. The CO₂‐stimulation of grassland productivity may be significantly underestimated if feedbacks from plant community change are not considered.     

Polymorphism of fecundity genes (FecB, FecX, and FecG) in the Indian Bonpala sheep

The present study was designed for screening polymorphism of known fecundity genes in prolific Indian Bonpala sheep. Employing tetra-primer amplification refractory mutation system PCR, 11-point mutations of BMP1B, BMP15, and GDF9 genes of 97 Bonpala ewes were genotyped. The FecB locus of the BMPR1B gene and two loci (G1 and G4) of GDF9 gene were found to be polymorphic. In FecB locus, three genotypes, namely, wild type (Fec++, 0.02), heterozygous (FecB+, 0.23), and mutant (FecBB, 0.75) were detected. At G1 locus of GDF9 gene, three genotypes, namely, wild type (GG, 0.89), heterozygous (GA, 0.10), and mutant (AA, 0.01) were detected. At G4 locus of GDF9 gene, three genotypes, namely, wild type (AA, 0.01), heterozygous (AG, 0.14), and mutant (GG, 0.85) were detected. Statistically no significant correlation of polymorphism of FecB, G1, and G4 loci and litter size was found in this breed. All five loci of BMP15 and three loci of GDF 9 genes were monomorphic. This study reports Bonpala sheep as the first sheep breed where concurrent polymorphism at three important loci (FecB, G1, and G4) of two different fecundity genes (BMPR1B and GDF9) has been found.     

Structural Attributes of Schizachyrium scoparium in Restored Texas Blackland Prairies

Structural attributes of the C₄, perennial bunchgrass Schizachyrium scoparium in restored prairies may be affected by the time since restoration. One hundred plants each in 8‐, 17‐, and 23‐year‐old restored prairies and a native Texas Blackland prairie were assessed for the presence/absence and diameter of a hollow crown (i.e., dead center portion), degree of fragmentation, plant height, and tiller density. Structural attributes of S. scoparium plants were generally (1) different between recent (8 years) and older (17 and 23 years) restored prairies (2) similar between the 17‐ and 23‐year‐old restored prairies, and (3) more similar between the 8‐ and 17‐year restored prairies and the native, remnant prairie than between the 23‐year restored prairie and the native prairie. Plants were shorter in restored prairies, regardless of time since restoration, than in the native prairie. Mean basal area of plants was 80–163% greater in the 17‐ and 23‐year restored prairies compared with the native and 8‐year restored prairies. Percentage of hollow crowns and fragmentation was smallest in the 8‐year restored prairie, largest in the 17‐ and 23‐year restored prairies, and intermediate in the native prairie. Tiller density exhibited inverse second‐order polynomial decreases with increasing plant basal area for all prairies. In contrast to tiller density, diameter of hollow crowns increased logarithmically with increasing plant basal area. Structural attributes of S. scoparium in restored prairies changed predictably with age, despite growing in different communities.     

Intergenerational above- and belowground responses of spring wheat (Triticum aestivum L.) to elevated CO2

We quantified intergenerational above- and belowground responses of two genotypes of semi-dwarf, hard red, spring wheats (Triticum aestivum L.) to elevated (700 μmol mol⁻¹) CO₂. These plants were progeny of seeds produced from previous generation plants grown at elevated CO₂ under well-watered and high nutrient conditions. Because neither genotype in the first generation exhibited enhanced performance with CO₂ enrichment, our objective in this investigation was to assess if exposure to CO₂ enrichment in subsequent generations resulted in temporal changes in the relative enhancement (elevated/ambient) of above- and belowground plant growth. Relative enhancement occurred in both the second and third generations for both above- and belowground variables. Above- and belowground variables were enhanced by similar relative amounts at elevated CO₂ within a generation at each harvest date. Relative enhancement of measured variables was generally greater in the third than second generation when plants were in the seedling or vegetative stage, but not when plants were reproductive. Additional research is needed to investigate physiological or other limitations of translating above- and belowground responses to CO₂ in vegetative growth stages to reproductive performance. Intergenerational above- and belowground responses of this C₃ annual plant to CO₂ enrichment are not driven by genetic change (selection) that occurred between generations, but rather CO₂-induced changes in seeds that affected seedling responses to CO₂ enrichment. Wir quantifizierten die intergenerationelle ober- und unterirdische Reaktionen von zwei Genotypen mittellangen, hartroten Winterweizen (Triticum aestivum L.) auf erhöhtes CO₂ (700 μmol mol⁻¹). Diese Pflanzen waren Abkömmlinge von Samen, die von Pflanzen der vorherigen Generation produziert wurden, welche ihrerseits bei erhöhtem CO₂ und bei ausreichender Wasserversorgung sowie guten Nährstoffbedingungen kultiviert wurden. Weil keiner der beiden Genotypen in der ersten Generation eine verbesserte Leistung bei CO₂-Anreicherung zeigte, war unser Ziel, in der Untersuchung abzuschätzen, ob die Exposition einer CO₂-Anreicherung in den nachfolgenden Generationen zu temporären Veränderungen in der relativen Förderung (erhöht/umgebend) des ober- und unterirdischen Wachstums führte. Eine relative Steigerung fand in der zweiten und in der dritten Generation sowohl bei den ober- als auch unterirdischen Variablen statt. Bei jedem Erntetermin waren die ober- und unterirdischen Variablen innerhalb einer Generation bei erhöhtem CO₂ mit ähnlichen relativen Anteilen positiv beeinflusst. Die relative Steigerung der gemessenen Variablen war im Allgemeinen bei Pflanzen im Keimlings- oder vegetativen Stadium in der dritten Generation größer als in der zweiten, jedoch nicht bei reproduktiven Pflanzen. Zusätzliche Forschung ist notwendig, um physiologische oder andere Limitierungen zu untersuchen, die ober- und unterirdische Reaktionen von vegetativen Wachstumsstadien auf CO₂ in die reproduktiven Leistung übersetzen. Intergenerationelle, ober- und unterirdische Reaktionen dieser C₃-Pflanze auf CO₂-Anreicherung werden nicht durch genetische Veränderungen (Selektion) im Laufe der Generationen gesteuert, sondern eher durch CO₂-induzierte Veränderungen in den Samen, welche die Reaktion der Keimlinge auf eine CO₂-Anreicherung beeinflussen.     

Stomatal acclimation over a subambient to elevated CO2 gradient in a C3/C4 grassland

An investigation to determine whether stomatal acclimation to [CO₂] occurred in C₃/C₄ grassland plants grown across a range of [CO₂] (200–550 µmol mol^?1) in the field was carried out. Acclimation was assessed by measuring the response of stomatal conductance (g_s) to a range of intercellular CO₂ (a g_s–C_i curve) at each growth [CO₂] in the third and fourth growing seasons of the treatment. The g_s–C_i response curves for Solanum dimidiatum (C₃ perennial forb) differed significantly across [CO₂] treatments, suggesting that stomatal acclimation had occurred. Evidence of non–linear stomatal acclimation to [CO₂] in this species was also found as maximum g_s (g_smax; g_s measured at the lowest C_i) increased with decreasing growth [CO₂] only below 400 µmol mol^?1. The substantial increase in g_s at subambient [CO₂] for S. dimidiatum was weakly correlated with the maximum velocity of carboxylation (V_cmax; r² = 0·27) and was not associated with CO₂ saturated photosynthesis (A_max). The response of g_s to C_i did not vary with growth [CO₂] in Bromus japonicus (C₃ annual grass) or Bothriochloa ischaemum (C₄ perennial grass), suggesting that stomatal acclimation had not occurred in these species. Stomatal density, which increased with rising [CO₂] in both C₃ species, was not correlated with g_s. Larger stomatal size at subambient [CO₂], however, may be associated with stomatal acclimation in S. dimidiatum. Incorporating stomatal acclimation into modelling studies could improve the ability to predict changes in ecosystem water fluxes and water availability with rising CO₂ and to understand their magnitudes relative to the past.     

Patterns of Plant Species Diversity in Remnant and Restored Tallgrass Prairies

To restore diversity of native vegetation, we must understand factors responsible for diversity in targeted communities. These factors operate at different spatial scales and may affect the number and relative abundances of species differently. We measured diversity of plant species and functional groups of species in replicated plots within paired restored and remnant (relic) tallgrass prairies at three locations in central Texas, U.S.A. To determine the contributions of species abundances and of spatial patterns of diversity to differences between prairie types, we separated diversity into richness and evenness (relative biomass) and into within‐plot (α), among‐plot (β), and prairie (γ) components. Species diversity was greater in remnant than in restored prairies at all spatial scales. At the γ scale, both species richness and species evenness were greater in remnants because of greater spatial variation in species composition. At the α scale, remnants were more diverse because of greater richness alone. Mean α richness correlated positively with the size of the species pool in restored prairies only, implying that in remnants, α richness was influenced more by colonization dynamics than by the number of species available for colonization. Plots in remnant prairies contained more functional groups and fewer species per group than did plots in restored prairies, suggesting that resource partitioning was greater in relic prairies. Our results are consistent with the interpretation that local ecological processes, like resource partitioning and limitations on seed dispersal, contribute to the greater diversity of remnant than restored prairies in central Texas. Restoration practices that limit abundances of competitive dominants, increase the number of species in seed mixtures, and increase the proximity of plants of different functional groups thus may be required to better simulate the plant diversity of tallgrass prairies.     

Is Dietary Fat Intake Related to Liking or Household Availability of High‐ and Low‐Fat Foods?

Objectives : Despite the increasing availability of low‐ and reduced‐fat foods, Americans continue to consume more fat than recommended, which may be a contributing factor to the obesity epidemic. This investigation examined relationships between liking and household availability of high‐ and low‐fat foods and their association with dietary fat intake. Research Methods and Procedures : A food frequency questionnaire assessed percent calories from fat consumed over the past year in 85 men and 80 women. Participants reported their degree of liking 22 “high‐fat foods” (>45% calories from fat) and 22 “low‐fat foods” (<18% calories from fat), and the number and percentage (number of high‐ or low‐fat foods/total number of foods × 100) of these high‐ and low‐fat foods in their homes. Results : Hierarchical regression analyses examined the ability of liking and household availability of low‐ and high‐fat foods to predict percent dietary fat intake. After controlling for age, sex, and BMI, liking ratings for high‐ and low‐fat foods and the interaction of liking for low‐fat foods by the percentage of low‐fat foods in the household were significant predictors of percent dietary fat consumed. Greater liking of high‐fat foods and lower liking of low‐fat foods, both alone and combined with a lower percentage of low‐fat foods in the home, were predictive of higher dietary fat intake. Discussion : Interventions designed to reduce dietary fat intake should target both decreasing liking for high‐fat foods and increasing liking for low‐fat foods, along with increasing the proportion of low‐fat foods in the household.     

Biochemical responses of pea root tissue to cytokinin: enhanced rates of RNA synthesis

Rates of RNA synthesis were studied in cultured pea (Pisum sativum) root segments and cortical explants which require the hormone cytokinin for DNA replication and cell proliferation. Rate calculations were based on the specific radioactivity of the extracted RNA and the specific radioactivity of the extracted ATP pool after a pulse with ³H-adenosine. The kinetics of RNA synthesis was studied after 24 hours of culture with or without kinetin. We found that kinetin stimulated a 2- to 4-fold enhancement in the rate of RNA synthesis after 24 hours of culture as compared to controls. A similar order of magnitude of stimulation of RNA synthesis was found when RNA was isolated by cesium chloride centrifugation. Pulses during the first 24 hours indicate that kinetin stimulates the rate of RNA synthesis as early as 9 hours after treatment has begun. During the first 24 hours of culture, kinetin did not affect the specific radioactivity of the ATP pool. The ATP pool equilibrated slowly with the exogenous label (³H-adenosine) in the presence or absence of kinetin. After 3 days in culture, we found kinetin to cause an expansion of the extractable ATP pool and a corresponding reduction in the ATP pool specific radioactivity. We interpret these results to indicate a stimulation in the rate of RNA synthesis due to kinetin treatment prior to any other known response.     

Woody invasion of grasslands: evidence that CO2 enrichment indirectly promotes establishment of Prosopis glandulosa

Grasslands worldwide have been invaded by woody species during the last200 years. Atmospheric CO₂ enrichment may indirectly havefacilitatedinvasion by reducing soil water depletion by grasses. We used a two-stepcorrelative approach to test this hypothesis with the invasive and native shrubhoney mesquite (Prosopis glandulosa Torr. var.glandulosa). 1) Water content to 0.15 m depthwas measured in grassland exposed to a CO₂ gradient from 200 to 550mol/mol to evaluate the prediction that CO₂enrichment lessens soil water depletion by grasses. 2) Soil water content andemergence and survival of mesquite seedlings were measured in adjacentgrasslandplots from which grass roots were excluded to 0.15 m depth toreduce water depletion or that were irrigated to increase soil water levels.With these measurements, we tested the hypothesis that mesquite establishmentislimited by water.Excluding grass roots doubled emergence of mesquite and almost tripledthe fraction of emergent seedlings that survived for 12 weeks following thefirst of two plantings. Seedlings were taller, heavier, and had greater leafarea when grown without grass roots. Root exclusion did not measurably affectsoil water during the 3-week period of seedling emergence, but soilwatercontent over the 12 weeks that seedling survival was studied was higher inplotsfrom which grass roots were excluded and following an April than May planting.Survivorship of mesquite seedlings correlated positively with soil watercontent. Percentage survival of seedlings increased from 1.5% to15% and 28% at the soil water content measured in grasslandexposed to CO₂ concentrations of 270 (preindustrial), 360 (current),and 550 mol/mol (future), respectively. We infer thatrecent and projected increases in atmospheric CO₂ concentration maybe large enough to increase establishment of invading mesquite seedlings ingrasslands that are severely water-limited.