Multiple compensatory mutations contribute to the de‐domestication of Iberian weedy rice

Li, Xiang; Zhang, Shulin; Amaro‐Blanco, Ignacio; Perera, S. A. U.; Khandekar, Nikhil Shirish; Lowey, Daniel; Osuna, M. D.; Caicedo, Ana L.

doi:10.1002/ppp3.10286

Cited by 5 publications

(24 citation statements)

References 55 publications

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“…Its genetic control has been associated with major loci with stable effects, which are related to crop domestication (for example, sh1, sh4, SHAT1, SHAT1-5, SHP1, Pdh1). 35 Interestingly, most feral weeds restore ancestral shattering phenotypes, not necessary by reversal of domesticated alleles, but through novel genetic mechanisms, 25 for example, weedy rice [36][37][38][39] and Tibetan weedy wheat. 40 Seed dormancy, defined as a temporary failure of viable seeds to germinate under environmental conditions that are favorable for germination, is another key trait in weeds because it regulates the timing of germination so that the environmental conditions are favorable for seedling survival and reproduction.…”

Section: Key Traits Of Weediness and Their Evolution In Feral Weedsmentioning

confidence: 99%

“…Its genetic control has been associated with major loci with stable effects, which are related to crop domestication (for example, sh1, sh4, SHAT1, SHAT1‐5, SHP1, Pdh1) 35 . Interestingly, most feral weeds restore ancestral shattering phenotypes, not necessary by reversal of domesticated alleles, but through novel genetic mechanisms, 25 for example, weedy rice 36–39 and Tibetan weedy wheat 40 …”

Section: Key Traits Of Weediness and Their Evolution In Feral Weedsmentioning

confidence: 99%

“…70,71 Therefore, not all feral weeds share all traits, suggesting that different genetic backgrounds may evolve weediness through distinct genetic mechanisms. 23,38,47 For example, some populations of weedy rice, feral rye, feral radish, and weedy Brassica rapa have not evolved seed dormancy; 8,46,72,73 feral rye, weedy artichoke and some weedy rice populations have not evolved early flowering; [74][75][76] and feral radish has not evolved seed shattering. 77,78 However, they are all important feral weeds.…”

Section: Key Traits Of Weediness and Their Evolution In Feral Weedsmentioning

confidence: 99%

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Agricultural weeds: the contribution of domesticated species to the origin and evolution of feral weeds

Vercellino

Hernández

Pandolfo

et al. 2022

Pest Management Science

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Agricultural weeds descended from domesticated ancestors, directly from crops (endoferality) and/or from crop-wild hybridization (exoferality), may have evolutionary advantages by rapidly acquiring traits pre-adapted to agricultural habitats. Understanding the role of crops on the origin and evolution of agricultural weeds is essential to develop more effective weed management programs, minimize crop losses due to weeds, and accurately assess the risks of cultivated genes escaping. In this review, we first describe relevant traits of weediness: shattering, seed dormancy, branching, early flowering and rapid growth, and their role in the feralization process. Furthermore, we discuss how the design of "super-crops" can affect weed evolution. We then searched for literature documenting cases of agricultural weeds descended from well-domesticated crops, and describe six case studies of feral weeds evolved from major crops: maize, radish, rapeseed, rice, sorghum, and sunflower. Further studies on the origin and evolution of feral weeds can improve our understanding of the physiological and genetic mechanisms underpinning the adaptation to agricultural habitats and may help to develop more effective weed-control practices and breeding better crops.

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Section: Key Traits Of Weediness and Their Evolution In Feral Weedsmentioning

confidence: 99%

Section: Key Traits Of Weediness and Their Evolution In Feral Weedsmentioning

confidence: 99%

Section: Key Traits Of Weediness and Their Evolution In Feral Weedsmentioning

confidence: 99%

See 1 more Smart Citation

Agricultural weeds: the contribution of domesticated species to the origin and evolution of feral weeds

Vercellino

Hernández

Pandolfo

et al. 2022

Pest Management Science

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“…Is feralization achieved primarily through few changes of large effect or small effect changes across many loci? feral rice, some of the selected alleles were derived from new mutations (Li et al, 2022;Scossa & Fernie, 2021). Also in rice, researchers have found that, in some cases, independently evolving feral populations have several shared "de-domestication" genomic blocks (Qiu et al, 2020).…”

Section: Genetic Architecture and Pathwaymentioning

confidence: 99%

“…For example, advances have been made in understanding the pathways to ferality, with feralization occurring either through introgression from wild relatives (exoferality) or without such introgression (endoferality) (Cronin et al, 2020;Gressel, 2005). Many of our insights into the genetic and phenotypic changes involved in ferality are derived from research on feral rice, which has identified key loci, traits, and evolutionary pathways associated with feralization (Li et al, 2022;Wedger & Olsen, 2018;Zhou et al, 2021). Recently, ferality has also become a topic of interest in the study of domestication, as wild-weedy-domesticated complexes were likely frequent in the early stages of domestication for many plants (Allaby et al, 2021;Purugganan, 2019Purugganan, , 2022.…”

Section: Introductionmentioning

confidence: 99%

Building a feral future: Open questions in crop ferality

Mabry

Bagavathiannan

Bullock

et al. 2023

Plants People Planet

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Societal Impact StatementGiven the rapidly increasing drought and temperature stresses associated with climate change, innovative approaches for food security are imperative. One understudied opportunity is using feral crops—plants that have escaped and persisted without cultivation—as a source of genetic diversity, which could build resilience in domesticated conspecifics. In some cases, however, feral plants vigorously compete with crops as weeds, challenging food security. By bridging historically siloed ecological, agronomic, and evolutionary lines of inquiry into feral crops, there is the opportunity to improve food security and understand this relatively understudied anthropogenic phenomenon.SummaryThe phenomenon of feral crops, that is, free‐living populations that have established outside cultivation, is understudied. Some researchers focus on the negative consequences of domestication, whereas others assert that feral populations may serve as useful pools of genetic diversity for future crop improvement. Although research on feral crops and the process of feralization has advanced rapidly in the last two decades, generalizable insights have been limited by a lack of comparative research across crop species and other factors. To improve international coordination of research on this topic, we summarize the current state of feralization research and chart a course for future study by consolidating outstanding questions in the field. These questions, which emerged from the colloquium “Darwins' reversals: What we now know about Feralization and Crop Wild Relatives” at the BOTANY 2021 conference, fall into seven categories that span both basic and applied research: (1) definitions and drivers of ferality, (2) genetic architecture and pathway, (3) evolutionary history and biogeography, (4) agronomy and breeding, (5) fundamental and applied ecology, (6) collecting and conservation, and (7) taxonomy and best practices. These questions serve as a basis for ferality researchers to coordinate research in these areas, potentially resulting in major contributions to food security in the face of climate change.

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A derived weedy rice × ancestral cultivar cross identifies evolutionarily relevant weediness QTLs

Li,

Zhang,

Lowey

et al. 2023

Molecular Ecology

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Weedy rice (Oryza spp.) is a weedy relative of the cultivated rice that competes with the crop and causes significant production loss. The BHA (blackhull awned) US weedy rice group has evolved from aus cultivated rice and differs from its ancestors in several important weediness traits, including flowering time, plant height and seed shattering. Prior attempts to determine the genetic basis of weediness traits in plants using linkage mapping approaches have not often considered weed origins. However, the timing of divergence between crossed parents can affect the detection of quantitative trait loci (QTL) relevant to the evolution of weediness. Here, we used a QTL‐seq approach that combines bulked segregant analysis and high‐throughput whole genome resequencing to map the three important weediness traits in an F2 population derived from a cross between BHA weedy rice with an ancestral aus cultivar. We compared these QTLs with those previously detected in a cross of BHA with a more distantly related crop, indica. We identified multiple QTLs that overlapped with regions under selection during the evolution of weedy BHA rice and some candidate genes possibly underlying the evolution weediness traits in BHA. We showed that QTLs detected with ancestor–descendant crosses are more likely to be involved in the evolution of weediness traits than those detected from crosses of more diverged taxa.

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Multiple compensatory mutations contribute to the de‐domestication of Iberian weedy rice

Cited by 5 publications

References 55 publications

Agricultural weeds: the contribution of domesticated species to the origin and evolution of feral weeds

Agricultural weeds: the contribution of domesticated species to the origin and evolution of feral weeds

Building a feral future: Open questions in crop ferality

A derived weedy rice × ancestral cultivar cross identifies evolutionarily relevant weediness QTLs

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