• Energy Research

Bien que l'on sache beaucoup de choses sur les facteurs qui contrôlent chaque composante du cycle terrestre de l'azote (N), il est moins clair comment ces facteurs affectent la disponibilité totale de l'azote, la somme des formes organiques et inorganiques potentiellement disponibles pour les micro-organismes et les plantes. Cela est particulièrement vrai pour les écosystèmes pauvres en N tels que les terres arides, qui sont très sensibles au changement climatique et aux processus de désertification pouvant entraîner la perte de nutriments du sol tels que N. Nous avons évalué la corrélation entre différents facteurs climatiques, abiotiques, végétaux et liés aux nutriments et la disponibilité de N dans les prairies semi-arides de Stipa tenacissima le long d'un large gradient d'aridité allant de l'Espagne à la Tunisie. L'aridité avait la relation la plus forte avec la disponibilité de l'azote, suggérant l'importance des contrôles abiotiques sur le cycle de l'azote dans les terres arides. L'aridité semble moduler les effets du pH, de la couverture végétale et du C organique (CO) sur la disponibilité de l'azote. Nos résultats suggèrent que les taux de transformation de l'azote, qui sont largement influencés par les variations de l'humidité du sol, ne sont pas les moteurs directs de la disponibilité de l'azote dans les prairies étudiées. Au contraire, la forte relation entre l'aridité et la disponibilité de l'azote pourrait être motivée par des effets indirects qui opèrent sur de longues échelles de temps (des décennies à des millénaires), y compris à la fois biotiques (par exemple, la couverture végétale) et abiotiques (par exemple, le CO et le pH du sol). Si ces facteurs sont en fait plus importants que les effets à court terme des précipitations sur les taux de transformation de l'azote, alors nous pourrions nous attendre à observer une diminution décalée de la disponibilité de l'azote en réponse à l'augmentation de l'aridité. Néanmoins, nos résultats suggèrent que l'augmentation de l'aridité prévue avec le changement climatique en cours réduira la disponibilité de l'azote dans le bassin méditerranéen, affectant l'absorption des nutriments végétaux et la production primaire nette dans les prairies semi-arides de cette région. Si bien se sabe mucho sobre los factores que controlan cada componente del ciclo del nitrógeno (N) terrestre, está menos claro cómo estos factores afectan la disponibilidad total de N, la suma de formas orgánicas e inorgánicas potencialmente disponibles para microorganismos y plantas. Esto es particularmente cierto para los ecosistemas pobres en N, como las tierras secas, que son altamente sensibles al cambio climático y los procesos de desertificación que pueden conducir a la pérdida de nutrientes del suelo, como N. Evaluamos cómo los diferentes factores climáticos, abióticos, vegetales y relacionados con los nutrientes se correlacionan con la disponibilidad de N en los pastizales semiáridos de Stipa tenacissima a lo largo de un amplio gradiente de aridez desde España hasta Túnez. La aridez tuvo la relación más fuerte con la disponibilidad de N, lo que sugiere la importancia de los controles abióticos en el ciclo de N en las tierras secas. La aridez pareció modular los efectos del pH, la cobertura vegetal y el C orgánico (OC) sobre la disponibilidad de N. Nuestros resultados sugieren que las tasas de transformación de N, que son impulsadas en gran medida por las variaciones en la humedad del suelo, no son los impulsores directos de la disponibilidad de N en los pastizales estudiados. Más bien, la fuerte relación entre la aridez y la disponibilidad de N podría ser impulsada por efectos indirectos que operan en escalas de tiempo largas (décadas a milenios), incluyendo tanto bióticos (por ejemplo, cobertura vegetal) como abióticos (por ejemplo, OC y pH del suelo). Si estos factores son de hecho más importantes que los efectos a corto plazo de la precipitación en las tasas de transformación de N, entonces podríamos esperar observar una disminución retardada en la disponibilidad de N en respuesta al aumento de la aridez. Sin embargo, nuestros resultados sugieren que el aumento de la aridez predicho con el cambio climático en curso reducirá la disponibilidad de N en la cuenca mediterránea, lo que afectará la absorción de nutrientes de las plantas y la producción primaria neta en los pastizales semiáridos en toda esta región. While much is known about the factors that control each component of the terrestrial nitrogen (N) cycle, it is less clear how these factors affect total N availability, the sum of organic and inorganic forms potentially available to microorganisms and plants. This is particularly true for N-poor ecosystems such as drylands, which are highly sensitive to climate change and desertification processes that can lead to the loss of soil nutrients such as N. We evaluated how different climatic, abiotic, plant and nutrient related factors correlate with N availability in semiarid Stipa tenacissima grasslands along a broad aridity gradient from Spain to Tunisia. Aridity had the strongest relationship with N availability, suggesting the importance of abiotic controls on the N cycle in drylands. Aridity appeared to modulate the effects of pH, plant cover and organic C (OC) on N availability. Our results suggest that N transformation rates, which are largely driven by variations in soil moisture, are not the direct drivers of N availability in the studied grasslands. Rather, the strong relationship between aridity and N availability could be driven by indirect effects that operate over long time scales (decades to millennia), including both biotic (e.g. plant cover) and abiotic (e.g. soil OC and pH). If these factors are in fact more important than short-term effects of precipitation on N transformation rates, then we might expect to observe a lagged decrease in N availability in response to increasing aridity. Nevertheless, our results suggest that the increase in aridity predicted with ongoing climate change will reduce N availability in the Mediterranean basin, impacting plant nutrient uptake and net primary production in semiarid grasslands throughout this region. في حين أن الكثير معروف عن العوامل التي تتحكم في كل مكون من مكونات دورة النيتروجين الأرضية (N)، إلا أنه من غير الواضح كيف تؤثر هذه العوامل على إجمالي توافر N، وهو مجموع الأشكال العضوية وغير العضوية التي يحتمل أن تكون متاحة للكائنات الحية الدقيقة والنباتات. وينطبق هذا بشكل خاص على النظم الإيكولوجية التي تعاني من فقر النيتروجين مثل الأراضي الجافة، وهي حساسة للغاية لتغير المناخ وعمليات التصحر التي يمكن أن تؤدي إلى فقدان مغذيات التربة مثل النيتروجين. قمنا بتقييم كيفية ارتباط العوامل المناخية واللاأحيائية والنباتية والمغذيات المختلفة بتوافر النيتروجين في المراعي شبه القاحلة على طول تدرج جفاف واسع من إسبانيا إلى تونس. كان للجفاف أقوى علاقة بتوافر النيتروجين، مما يشير إلى أهمية الضوابط اللاأحيائية في دورة النيتروجين في الأراضي الجافة. يبدو أن الجفاف يعدل تأثيرات الأس الهيدروجيني والغطاء النباتي و C العضوي (OC) على توافر N. تشير نتائجنا إلى أن معدلات تحول N، التي تحركها إلى حد كبير الاختلافات في رطوبة التربة، ليست هي الدوافع المباشرة لتوافر N في الأراضي العشبية المدروسة. بدلاً من ذلك، يمكن أن تكون العلاقة القوية بين الجفاف وتوافر N مدفوعة بالتأثيرات غير المباشرة التي تعمل على نطاقات زمنية طويلة (من عقود إلى آلاف السنين)، بما في ذلك كل من الحيوية (مثل الغطاء النباتي) واللاأحيائية (مثل OC التربة ودرجة الحموضة). إذا كانت هذه العوامل في الواقع أكثر أهمية من الآثار قصيرة الأجل لهطول الأمطار على معدلات تحول N، فقد نتوقع ملاحظة انخفاض متأخر في توافر N استجابة لزيادة الجفاف. ومع ذلك، تشير نتائجنا إلى أن الزيادة في القحولة المتوقعة مع تغير المناخ المستمر ستقلل من توافر N في حوض البحر الأبيض المتوسط، مما يؤثر على امتصاص المغذيات النباتية وصافي الإنتاج الأولي في المراعي شبه القاحلة في جميع أنحاء هذه المنطقة.

Aims Relatively few studies so far have assessed how ongoing global warming will affect the photosynthetic performance of dryland plant species. We evaluated the effects of warming on the photosynthetic rates of 10 species with contrasting functional attributes, and whether their functional traits modulated photosynthetic responses to warming. Methods A common garden experiment was conducted over 2 years with distinct environmental conditions (drier vs. wetter year). The experiment was designed as a randomized block design with two treatments: warming (control vs. ~2.9°C temperature increase) and species (Agropyron cristatum, Festuca ovina, Lygeum spartum, Medicago sativa, Plantago lanceolata, Psoralea bituminosa, Sanguisorba minor, Hedysarum coronarium, Dorycnium pentaphyllum and Phlomis herba-venti). We linked functional traits measurements with temporal variations in photosynthetic responses to warming. Important Findings In the drier year, warming increased photosynthetic rates at the beginning of the growing season, suggesting a modification in the growing period (earlier spring). In the wetter year, functional traits modulated photosynthetic responses to warming. Larger species with shorter leaves (e.g. M. sativa) had higher photosynthetic rates under warming compared to smaller species with larger leaves (e.g. F. ovina). Our results highlight the importance of (i) studying photosynthetic responses along different years and (ii) considering functional traits when evaluating photosynthetic responses to climate change, particularly in stressful environments such as drylands.

Increasing temperature and drought intensity is inducing the phenomenon of the so-called ''hotter drought'', which is expected to increase in frequency over the coming decades across many areas of the globe, and is expected to have major implications for forest systems. Consequences of hotter drought could be especially relevant for closely related species overlapping their distributions, since differences in response can translate into range shifts. We assessed the effect of future climatic conditions on the performance of five ecologically distinct pine species common in Europe: Pinus halepensis, P. pinaster, P. nigra, P. sylvestris and P. uncinata. We hypothesised that Mediterranean species inhabiting dry, low-elevation sites will be less affected by the expected warming and drought increase than species inhabiting cold-wet sites. We performed a controlled conditions experiment simulating current and projected temperature and precipitation, and analysed seedling responses in terms of survival, growth, biomass allocation, maximum photochemical efficiency (Fv/Fm) and plant water potential (W). Either an increase in temperature or a reduction in water input alone reduced seedling performance, but the highest impact occurred when these two factors acted in combination. Warming and water limitation reduced W, whereas warming alone reduced biomass allocation to roots and Fv/Fm. However, species responded differentially to warmer and drier conditions, with lowland Mediterranean pines (P. halepensis and P. pinaster) showing higher survival and performance than mountain species. Interspecific differences in response to warmer, drier conditions could contribute to changes in the relative dominance of these pine species in Mediterranean regions where they co-occur and a hotter, drier climate is anticipated. Ministerio de Ciencia e Innovación

AbstractIntransitive competition networks, those in which there is no single best competitor, may ensure species coexistence. However, their frequency and importance in maintaining diversity in real‐world ecosystems remain unclear. We used two large data sets from drylands and agricultural grasslands to assess: (1) the generality of intransitive competition, (2) intransitivity–richness relationships and (3) effects of two major drivers of biodiversity loss (aridity and land‐use intensification) on intransitivity and species richness. Intransitive competition occurred in > 65% of sites and was associated with higher species richness. Intransitivity increased with aridity, partly buffering its negative effects on diversity, but was decreased by intensive land use, enhancing its negative effects on diversity. These contrasting responses likely arise because intransitivity is promoted by temporal heterogeneity, which is enhanced by aridity but may decline with land‐use intensity. We show that intransitivity is widespread in nature and increases diversity, but it can be lost with environmental homogenisation.

AbstractDespite their importance, how plant communities and soil microorganisms interact to determine the capacity of ecosystems to provide multiple functions simultaneously (multifunctionality) under climate change is poorly known. We conducted a common garden experiment using grassland species to evaluate how plant functional structure and soil microbial (bacteria and protists) diversity and abundance regulate soil multifunctionality responses to joint changes in plant species richness (one, three and six species) and simulated climate change (3°C warming and 35% rainfall reduction). The effects of species richness and climate on soil multifunctionality were indirectly driven via changes in plant functional structure and their relationships with the abundance and diversity of soil bacteria and protists. More specifically, warming selected for the larger and most productive plant species, increasing the average size within communities and leading to reductions in functional plant diversity. These changes increased the total abundance of bacteria that, in turn, increased that of protists, ultimately promoting soil multifunctionality. Our work suggests that cascading effects between plant functional traits and the abundance of multitrophic soil organisms largely regulate the response of soil multifunctionality to simulated climate change, and ultimately provides novel experimental insights into the mechanisms underlying the effects of biodiversity and climate change on ecosystem functioning.

Global Ecosystem AnalysisThe relationship between species richness and the functional properties of their ecosystems has often been studied at small scales in experimental plots.Maestreet al.(p.214; see the Perspective byMidgley) performed field measurements at 224 dryland sites from six continents and assessed 14 ecosystem functions related to carbon, nitrogen, and phosphorus cycling. Positive relationships were observed between perennial plant species richness and ecosystem functionality. The relative importance of biodiversity was found to be as large as, or larger than, many key abiotic variables. Thus, preservation of plant biodiversity is important to buffer negative effects of climate change and desertification in drylands, which collectively cover 41% of Earth's land surface and support over 38% of the human population.