Full description
1. Understanding the mechanisms that underlie the generation of beta-diversity remains a challenge in ecology. Underground plant adaptations to environmental gradients have received relatively little attention. 2. We studied plant nutrient-acquisition strategies and nutrient-use efficiency at three stages of pedogenesis in infertile soils from campos rupestres and on less infertile soil from cerrado sensu stricto in Brazil. All soils support very high plant diversity with high species turnover between soil types at small spatial scales (meters). We expected that differences in nutrient–acquisition and –use strategies would be associated with this high species turnover. With severely decreasing phosphorus (P) availability, we expected the effectiveness of arbuscular mycorrhizal (AM) symbioses for plant P acquisition to decrease, and reliance on non-mycorrhizal strategies (NM) to increase, while maintaining efficient nutrient-use. 3. Concentrations of total soil P and nitrogen (N) were greater in soils in cerrado than in those from campos rupestres, and the more weathered soils from campos rupestres were severely P– and N–impoverished. The proportion of the root length colonised by AM fungi was 71% in the soils from the cerrado and campos rupestres. Conversely, the proportion of species with non-mycorrhizal P-acquisition strategies such as rhizosheaths was greater in the most P-impoverished soils. Leaf [P] and [N] were very low and decreased with decreasing soil [P] and [N]. Leaf N: P ratios suggest P-limitation of plant productivity in the campos rupestres but N-P co-limitation in the cerrado. Photosynthetic rates decreased with increasing P-impoverishment, but photosynthetic P-use efficiency was very high and photosynthetic N-use efficiency moderately high on all soils. Most species had very high P-remobilisation efficiency during leaf senescence (>70%), but only moderate N-remobilisation efficiency (~50%). 4. Synthesis. We observed very high P-use efficiency and moderately high N-use efficiency in campos rupestres and cerrado species, consistent with plant productivity being more strongly limited by P than by N. Our findings demonstrate that different soil characteristics (nutrient availability and soil texture) select for species differing in nutrient-acquisition and -use strategies (especially belowground traits) which is likely key for the very high species turnover at a very small scale between soil types (i.e. beta-diversity) in campos rupestres and cerrado.,Abrahao_et_al_2018_Plant_data_Cipo_J_EcolPlant traits recorded for 40 species, 4 individuals per species growing on 4 different soil types in campos rupestres and cerradoAbrahao_Plant_data_Cipo_J_Ecol_Dryad.csvAbrahao_et_al_2018_Soil_data_Cipo_J_Ecol_DryadSoil attributes of 4 different soil types, 3 composite replicates per soil type in campos rupestres and cerrado vegetationAbrahao_Soil_data_Cipo_J_Ecol_Dryad.csv,Notes
External OrganisationsState University of Campinas
Associated Persons
Anna Abrahão (Creator); Patricia de Britto Costa (Creator); Rafael SIlva Oliveira (Creator)Sara Adrián L. De Andrade (Creator); Alexandra Christine Helena Frankland Sawaya (Creator)
Anna Abrahão (Creator); Patricia de Britto Costa (Creator); Rafael SIlva Oliveira (Creator)Sara Adrián L. De Andrade (Creator); Alexandra Christine Helena Frankland Sawaya (Creator)
Issued: 2019-01-01
Subjects
Actinocephalus cf. geniculatus |
Apochloa molinioides |
Aulonemia effusa |
Barbacenia flava |
Bulbostylis paradoxa |
Byrsonima sp. |
Byrsonima verbascifolia |
Cephalostemon riedelianus |
Coccoloba cereifera |
Cryptangium verticillatum |
Dalbergia miscolobium |
Determinants of plant community diversity and structure |
Echinolaena inflexa |
Erythroxylum suberosum |
Kielmeyera coriacea |
Lagenocarpus rigidus |
Lagenocarpus rigidus subsp. tenuifolius |
Lagenocarpus tenuifolius |
Lavoisiera cordata |
Marcetia sp. |
Marcetia taxifolia |
Myrsine guianensis |
Neea theifera |
OCBILs |
Paepalanthus cf. eriophaeus |
Paepalanthus paulinus |
Paspalum lineare |
Plant–soil (below-ground) interactions |
Quaternary |
Richterago arenaria |
Roupala montana |
Rynchospora riedeliana |
Stryphnodendron adstringens |
Trachypogon spicatus |
Trembleya laniflora |
Vellozia caruncularis |
Vochysia pygmea |
Vochysia thyrsoidea |
Xyris itatiayensis or Xyris longiscapa |
Xyris nubigena or X. pterygoblephara |
Xyris pilosa |
carboxylates |
ecophysiology |
mycorrhizas |
nutrient remobilisation |
rhizosheaths |
rupestrian grasslands |
sand-binding roots |
“Lychnophora jolyana sp. Ined” |
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Identifiers
- global : 4a65c5c9-b25e-4f8e-bdb9-c722261f8207
- DOI : 10.5061/dryad.2vg4cg1