Crop-wild sunflower hybridization can mediate weediness throughout growth-stress tolerance trade-offs

•Wild, weedy and crop sunflower biotypes were contrasted.•The weedy sunflower biotype showed faster growth rate than wild biotype.•The weedy sunflower biotype was less tolerant to stresses than wild biotype.•Stress-related genes in the weedy biotype shifted in the crop direction. Agricultural weeds...

Full description

Saved in:
Bibliographic Details
Published in:Agriculture, ecosystems & environment ecosystems & environment, 2017-11, Vol.249, p.12-21
Main Authors: Presotto, Alejandro, Hernández, Fernando, Díaz, Marina, Fernández-Moroni, Ivana, Pandolfo, Claudio, Basualdo, Jessica, Cuppari, Selva, Cantamutto, Miguel, Poverene, Mónica
Format: Article
Language:English
Subjects:
Adaptation
Agrestal
Agricultural environment
Agricultural production
Biological evolution
Biotypes
Crop production
Crops
Defoliation
Ditches
Drought
Drought resistance
Economic impact
Gene sequencing
Genes
Genetic diversity
Genetic variance
Growth
Hedgerows
Helianthus annuus
Hybridization
Introgression
Plant growth
Plant tolerance
Plants (botany)
Positive selection
Resource allocation
Roadsides
Ruderal
Stresses
Tolerance
Trade-off
Tradeoffs
Transcription factors
Weeds
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•Wild, weedy and crop sunflower biotypes were contrasted.•The weedy sunflower biotype showed faster growth rate than wild biotype.•The weedy sunflower biotype was less tolerant to stresses than wild biotype.•Stress-related genes in the weedy biotype shifted in the crop direction. Agricultural weeds are plants well-adapted to agricultural environments interfering directly and indirectly with crop production and causing important economic losses worldwide. Crop-wild hybridization is one of the main forces that have ruled weed evolution along with adaptation to agricultural (or benign) environments. Considering the competing demands for resources in any plant, adaptation to agricultural environments might result in an increase in growth but with lower tolerance to stress. In Argentina, most of the non-native H. annuus populations grow on roadsides, ditches, fences, hedgerows (ruderals), but there are also a few cases of H. annuus growing in agricultural field as weeds (agrestals). We asume that weediness of these agrestal biotypes came after crop hybridization as result of growth-stress tolerance trade-offs. Ruderal, agrestal (with evidence of crop introgression), and crop biotypes were contrasted under studies of drought and defoliation stresses, as well as for plant growth under non-stressful conditions and sequences of stress-related genes. The agrestal biotype was less tolerant to defoliation and drought than the ruderal biotype. Drought tolerance variation was largely explained by plant height rate (growth) and defoliation tolerance variation was mainly explained by biomass accumulation (resource allocation). Agrestal biotype sequences of two genes encoding transcription factors involved in stress response, DREB2 and NAC, showed evidence of positive selection in the crop direction. Therefore, selection in the agricultural environment combined with crop hybridization driver the evolution of a well-adapted genetic variant of H. annuus with fast growth but reduced stress tolerance.
ISSN:0167-8809
1873-2305
DOI:10.1016/j.agee.2017.08.003