Uniform Selection as a Primary Force Reducing Population Genetic Differentiation of Cavitation Resistance across a Species Range

Background: Cavitation resistance to water stress-induced embolism determines plant survival during drought. This adaptive trait has been described as highly variable in a wide range of tree species, but little is known about the extent of genetic and phenotypic variability within species. This information is essential to our understanding of the evolutionary forces that have shaped this trait, and for evaluation of its inclusion in breeding programs. Methodology: We assessed cavitation resistance (P 50), growth and carbon isotope composition in six Pinus pinaster populations in a provenance and progeny trial. We estimated the heritability of cavitation resistance and compared the distribution of neutral markers (FST) and quantitative genetic differentiation (QST), for retrospective identification of the evolutionary forces acting on these traits. Results/Discussion: In contrast to growth and carbon isotope composition, no population differentiation was found for cavitation resistance. Heritability was higher than for the other traits, with a low additive genetic variance (h 2 ns = 0.4360.18, CVA = 4.4%). QST was significantly lower than FST, indicating uniform selection for P50, rather than genetic drift. Putativ

Variations in xylem structure and function and drought-induced plasticity in poplar

Cette thèse visait à caractériser l’architecture hydraulique du xylème chez les hybrides de peuplier Populusdeltoides × P. nigra et à juger de ses relations avec le fonctionnement hydrique et carboné de l’arbre en conditions d’irrigation contrastées. A cette fin, huit génotypes se distinguant par leur discrimination isotopique vis-à-vis du carbone 13 ont été cultivés en pépinière. Nos travaux ont permis de mettre en évidence d’importantes variations entre génotypes pour les caractéristiques anatomiques du xylème, l’efficience hydraulique de la tige et de la plante entière ainsi que la résistance à la cavitation. Nos travaux démontrent également que l’anatomie et la résistance à la cavitation du xylème s’ajustent aux conditions hydriques du milieu de façon génotype-dépendante. En condition hydrique non limitante, nous avons mis en évidence un compromis entre l’efficience hydraulique et la résistance à la cavitation ou le potentiel de croissance. Ces deux compromis expliquent la relation positive observée entre la résistance à la cavitationet le potentiel de croissance. En condition hydrique limitante, cette relation n’était toutefois plus observable. Aucune relation n’a pu être identifiée entre les propriétés hydrauliques et l’efficience d’utilisation de l’eau. Ces travaux suggèrent que certaines relations couramment observées à l’échelle inter-spécifique ne sont pas nécessairement applicables à des échelles d’étude plus réduites. Ce travail ouvre des perspectives sur le plan fondamental pour l’identification du déterminisme moléculaire à l’origine de la plasticité structurale observée et sur le plan appliqué, pour la création variétale.This work aimed at characterizing xylem hydraulic architecture and at describing its relationships with whole plant water and carbon relations among Populus deltoides × P. nigra hybrids under contrasting water regimes. Eight genotypes differing in carbon isotope discrimination were grown in the field in a common garden test. Significant variations were observed between genotypes for all xylem anatomical characteristics, stem or whole-plant hydraulic efficiency and xylem resistance to cavitation. Drought-induced acclimation was observed for xylem structural features and xylem resistance to cavitation, but in a genotype-dependant manner. Under optimal irrigation, a trade-off was observed between hydraulic efficiency and xylem resistance to cavitation or growth performance. These two trade-offs translated into an uncommon positive relationship between xylem resistance to cavitation and growth performance. Under water deficit,this relationship broke down. No relationship could be detected between xylem hydraulics and water-use efficiency estimates. Our results suggest in part that several common relationships that are observed at the between-species level may not necessarily hold true at narrower scales. Further, this work opens up prospects both for identifying the molecular basis of xylem structural acclimation and for breeding strategies

Variabilité structurale et fonctionnelle du xylème et plasticité en réponse à la sécheresse chez le peuplier

This work aimed at characterizing xylem hydraulic architecture and at describing its relationships with whole plant water and carbon relations among Populus deltoides × P. nigra hybrids under contrasting water regimes. Eight genotypes differing in carbon isotope discrimination were grown in the field in a common garden test. Significant variations were observed between genotypes for all xylem anatomical characteristics, stem or whole-plant hydraulic efficiency and xylem resistance to cavitation. Drought-induced acclimation was observed for xylem structural features and xylem resistance to cavitation, but in a genotype-dependant manner. Under optimal irrigation, a trade-off was observed between hydraulic efficiency and xylem resistance to cavitation or growth performance. These two trade-offs translated into an uncommon positive relationship between xylem resistance to cavitation and growth performance. Under water deficit,this relationship broke down. No relationship could be detected between xylem hydraulics and water-use efficiency estimates. Our results suggest in part that several common relationships that are observed at the between-species level may not necessarily hold true at narrower scales. Further, this work opens up prospects both for identifying the molecular basis of xylem structural acclimation and for breeding strategies.Cette thèse visait à caractériser l’architecture hydraulique du xylème chez les hybrides de peuplier Populusdeltoides × P. nigra et à juger de ses relations avec le fonctionnement hydrique et carboné de l’arbre en conditions d’irrigation contrastées. A cette fin, huit génotypes se distinguant par leur discrimination isotopique vis-à-vis du carbone 13 ont été cultivés en pépinière. Nos travaux ont permis de mettre en évidence d’importantes variations entre génotypes pour les caractéristiques anatomiques du xylème, l’efficience hydraulique de la tige et de la plante entière ainsi que la résistance à la cavitation. Nos travaux démontrent également que l’anatomie et la résistance à la cavitation du xylème s’ajustent aux conditions hydriques du milieu de façon génotype-dépendante. En condition hydrique non limitante, nous avons mis en évidence un compromis entre l’efficience hydraulique et la résistance à la cavitation ou le potentiel de croissance. Ces deux compromis expliquent la relation positive observée entre la résistance à la cavitationet le potentiel de croissance. En condition hydrique limitante, cette relation n’était toutefois plus observable. Aucune relation n’a pu être identifiée entre les propriétés hydrauliques et l’efficience d’utilisation de l’eau. Ces travaux suggèrent que certaines relations couramment observées à l’échelle inter-spécifique ne sont pas nécessairement applicables à des échelles d’étude plus réduites. Ce travail ouvre des perspectives sur le plan fondamental pour l’identification du déterminisme moléculaire à l’origine de la plasticité structurale observée et sur le plan appliqué, pour la création variétale

Variations in xylem structure and function and drought-induced plasticity in poplar

Cette thèse visait à caractériser l architecture hydraulique du xylème chez les hybrides de peuplier Populusdeltoides . P. nigra et à juger de ses relations avec le fonctionnement hydrique et carboné de l arbre en conditions d irrigation contrastées. A cette fin, huit génotypes se distinguant par leur discrimination isotopique vis-à-vis du carbone 13 ont été cultivés en pépinière. Nos travaux ont permis de mettre en évidence d importantes variations entre génotypes pour les caractéristiques anatomiques du xylème, l efficience hydraulique de la tige et de la plante entière ainsi que la résistance à la cavitation. Nos travaux démontrent également que l anatomie et la résistance à la cavitation du xylème s ajustent aux conditions hydriques du milieu de façon génotype-dépendante. En condition hydrique non limitante, nous avons mis en évidence un compromis entre l efficience hydraulique et la résistance à la cavitation ou le potentiel de croissance. Ces deux compromis expliquent la relation positive observée entre la résistance à la cavitationet le potentiel de croissance. En condition hydrique limitante, cette relation n était toutefois plus observable. Aucune relation n a pu être identifiée entre les propriétés hydrauliques et l efficience d utilisation de l eau. Ces travaux suggèrent que certaines relations couramment observées à l échelle inter-spécifique ne sont pas nécessairement applicables à des échelles d étude plus réduites. Ce travail ouvre des perspectives sur le plan fondamental pour l identification du déterminisme moléculaire à l origine de la plasticité structurale observée et sur le plan appliqué, pour la création variétale.This work aimed at characterizing xylem hydraulic architecture and at describing its relationships with whole plant water and carbon relations among Populus deltoides . P. nigra hybrids under contrasting water regimes. Eight genotypes differing in carbon isotope discrimination were grown in the field in a common garden test. Significant variations were observed between genotypes for all xylem anatomical characteristics, stem or whole-plant hydraulic efficiency and xylem resistance to cavitation. Drought-induced acclimation was observed for xylem structural features and xylem resistance to cavitation, but in a genotype-dependant manner. Under optimal irrigation, a trade-off was observed between hydraulic efficiency and xylem resistance to cavitation or growth performance. These two trade-offs translated into an uncommon positive relationship between xylem resistance to cavitation and growth performance. Under water deficit,this relationship broke down. No relationship could be detected between xylem hydraulics and water-use efficiency estimates. Our results suggest in part that several common relationships that are observed at the between-species level may not necessarily hold true at narrower scales. Further, this work opens up prospects both for identifying the molecular basis of xylem structural acclimation and for breeding strategies.ORLEANS-SCD-Bib. electronique (452349901) / SudocSudocFranceF

Vulnerability to drought-induced cavitation in poplars: synthesis and future opportunities

National audienceVulnerability to drought-induced cavitation is a key trait of plant water relations. Here, we summarize the available literature on vulnerability to drought-induced cavitation in poplars (Populus spp.), a genus of agronomic, ecological and scientific importance. Vulnerability curves and vulnerability parameters (including the water potential inducing 50% loss in hydraulic conductivity, P50) were collected from 37 studies published between 1991 and 2014, covering a range of 10 species and 12 inter-specific hybrid crosses. Results of our meta-analysis confirm that poplars are among the most vulnerable woody species to drought-induced cavitation (mean P50 = -1.44 and -1.55 MPa across pure species and hybrids, respectively). Yet, significant variation occurs among species (P50 range: 1.43 MPa) and among hybrid crosses (P50 range: 1.12 MPa), within species and hybrid crosses (max. P50 range reported: 0.8 MPa), as well as in response to environmental factors including nitrogen fertilization, irradiance, temperature and drought (max. P50 range reported: 0.75 MPa). Potential implications and gaps in knowledge are discussed in the context of poplar cultivation, species adaptation and climate modifications. We suggest that poplars represent a valuable model for studies on droughtinduced cavitation, especially to elucidate the genetic and molecular basis of cavitation resistance

Seasonal variations in photosynthesis, intrinsic water-use efficiency and stable isotope composition of poplar leaves in a short-rotation plantation.

International audiencePhotosynthetic carbon assimilation and transpirational water loss play an important role in the yield and the carbon sequestration potential of bioenergy-devoted cultures of fast-growing trees. For six poplar (Populus) genotypes in a short-rotation plantation, we observed significant seasonal and genotypic variation in photosynthetic parameters, intrinsic water-use efficiency (WUEi) and leaf stable isotope composition (δ13C and δ18O). The poplars maintained high photosynthetic rates (between 17.8 and 26.9 μmol m(-2) s(-1) depending on genotypes) until late in the season, in line with their fast-growth habit. Seasonal fluctuations were mainly explained by variations in soil water availability and by stomatal limitation upon photosynthesis. Stomatal rather than biochemical limitation was confirmed by the constant intrinsic photosynthetic capacity (Vcmax) during the growing season, closely related to leaf nitrogen (N) content. Intrinsic water-use efficiency scaled negatively with carbon isotope discrimination (Δ13Cbl) and positively with the ratio between mesophyll diffusion conductance (gm) and stomatal conductance. The WUEi-Δ13Cbl relationship was partly influenced by gm. There was a trade-off between WUEi and photosynthetic N-use efficiency, but only when soil water availability was limiting. Our results suggest that seasonal fluctuations in relation to soil water availability should be accounted for in future modelling studies assessing the carbon sequestration potential and the water-use efficiency of woody energy crops

Genetic variation for leaf morphology, leaf structure and leaf carbon isotope discrimination in European populations of black poplar Populus nigra

International audienceTo buffer against the high spatial and temporal heterogeneity of the riparian habitat, riparian tree species, such as black poplar (Populus nigra L.), may display a high level of genetic variation and phenotypic plasticity for functional traits. Using a multisite common garden experiment, we estimated the relative contribution of genetic and environmental effects on the phenotypic variation expressed for individual leaf area, leaf shape, leaf structure and leaf carbon isotope discrimination (Delta C-13) in natural populations of black poplar. Twenty-four to 62 genotypes were sampled in nine metapopulations covering a latitudinal range from 48A degrees N to 42A degrees N in France and in Italy and grown in two common gardens at Orl,ans (ORL) and at Savigliano (SAV). In the two common gardens, substantial genetic variation was expressed for leaf traits within all metapopulations, but its expression was modulated by the environment, as attested by the genotype x environment (G x E) interaction variance being comparable to or even greater than genetic effects. For LA, G x E interactions were explained by both changes in genotype ranking between common gardens and increased variation in SAV, while these interactions were mainly attributed to changes in genotype ranking for Delta C-13. The nine P. nigra metapopulations were highly differentiated for LA, as attested by the high coefficient of genetic differentiation (Q(ST) = 0.50 at ORL and 0.51 at SAV), and the pattern of metapopulation differentiation was highly conserved between the two common gardens. In contrast, they were moderately differentiated for Delta C-13 (Q(ST) = 0.24 at ORL and 0.25 at SAV) and the metapopulation clustering changed significantly between common gardens. Our results evidenced that the nine P. nigra metapopulations present substantial genetic variation and phenotypic plasticity for leaf traits, which both represent potentially significant determinants of populations' capacities to respond, on a short-term basis and over generations, to environmental variations

Planting density affects growth and water-use efficiency depending on site in Populus deltoides x P. nigra

International audiencePoplar coppice plantations for biomass production can be conducted under either short rotation coppice (SRC) or short rotation forestry (SRF) systems, depending on planting density and rotation length. It is likely that differences in planting density affect tree physiology through competition for resource acquisition, including light, water and nutrients. In this paper, we hypothesized that the effects of planting density on growth and water-use efficiency (assessed through bulk leaf carbon isotope discrimination, Delta C-13) in poplar depend on site characteristics in terms of soil fertility and water availability. To test this hypothesis, 56 Populus deltoides x P. nigra genotypes were planted under both SRC and SRF and replicated at two sites differing for pedoclimatic conditions. At the most favorable site for growth, trees grown at the higher density (SRC) displayed higher stem height, lower stem circumference, higher specific leaf area, higher mass-based leaf nitrogen contents and higher Delta C-13, indicating that increased tree density mainly accentuated competition for light. Under less favorable conditions, trees grown under SRC still displayed lower stem circumference, higher specific leaf area and higher mass-based leaf nitrogen contents. However, stem height remained unaffected by increasing planting density while Delta C-13 was lower, likely because of increased competition for water availability. Genotypic rankings across planting densities were overall conserved while they were significantly modified across sites, suggesting that rankings for genotypic performances were much less affected by planting density than by site. Realized growth measured after 2 years (height and circumference) was weakly correlated with Delta C-13, but a negative relationship between Delta C-13 and growing season leaf increment rate was observed in most cases. The absence of trade-off between growth and water-use efficiency combined with the large genotypic variations observed for these traits confirms the potential for selecting genotypes with high water-use efficiency without counter-selecting on biomass production in P. deltoides x P. nigra

Xylem anatomy correlates with gas exchange, water-use efficiency and growth performance under contrasting water regimes : evidence from Populus deltoides x Populus nigra hybrids

International audienceSix Populus deltoides Bartr. ex Marsh. × P. nigra L. genotypes were selected to investigate whether stem xylem anatomy correlated with gas exchange rates, water-use efficiency (WUE) and growth performance. Clonal copies of the genotypes were grown in a two-plot common garden test under contrasting water regimes, with one plot maintained irrigated and the other one subjected to moderate summer water deficit. The six genotypes displayed a large range of xylem anatomy, mean vessel and fibre diameter varying from about 40 to 60 μm and from 7.5 to 10.5 μm, respectively. Decreased water availability resulted in a reduced cell size and an important rise in vessel density, but the extent of xylem plasticity was both genotype and trait dependent. Vessel diameter and theoretical xylem-specific hydraulic conductivity correlated positively with stomatal conductance, carbon isotope discrimination and growth performance-related traits and negatively with intrinsic WUE, especially under water deficit conditions. Vessel diameter and vessel density measured under water deficit conditions correlated with the relative losses in biomass production in response to water deprivation; this resulted from the fact that a more plastic xylem structure was generally accompanied by a larger loss in biomass production

Survivorship in potted Populus deltoides x Populus nigra hybrids in response to gradual soil water depletion

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