The Performance of Early-Generation Perennial Winter Cereals at 21 Sites across Four Continents

Hayes, Richard; Wang, Shuwen; Newell, Matthew T.; Turner, Kathryn; Larsen, Julie S.; Gazza, Laura; Anderson, James A.; Bell, Lindsay W.; Cattani, Douglas J.; Frels, Katherine; Galassi, Elena; Morgounov, Alexey; Revell, Clinton; Thapa, Dhruba Bahadur; Sacks, Erik J.; Sameri, Mohammad; Wade, Leonard; Westerbergh, Anna; Шаманин, Владимир; Amanov, A. A.; Li, Guangdi D.

doi:10.3390/su10041124

Cited by 39 publications

(27 citation statements)

References 46 publications

(75 reference statements)

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“…However, unlike wheat, IWG is usually self-incompatible meaning that most populations are highly heterogeneous and most individuals are highly heterozygous (Jensen et al 2016;Jensen et al 1990; Kantarski et al 2017;Zhang et al 2016). Wheat-Thinopyrum hybrids have also been utilized for the development of perennial grain crops (Curwen-McAdams and Jones 2017; Hayes et al 2018), but commercial production of these plant materials has not yet been realized because it has been difficult to introgress and stabilize this complex trait in wheat. However, parallel efforts to directly domesticate IWG itself as a perennial grain crop (Cox et al 2006;Cox et al 2010;Wagoner 1990) have led to small-scale production and utilization of IWG grain or flour for baking, beverages, and other edible food products (DeHaan and Ismail 2017).…”

Section: Introductionmentioning

confidence: 99%

Genome mapping of quantitative trait loci (QTL) controlling domestication traits of intermediate wheatgrass (Thinopyrum intermedium)

et al. 2019

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Allohexaploid (2n=6x=42) intermediate wheatgrass (Thinopyrum intermedium), abbreviated IWG, is an outcrossing perennial grass belonging to the tertiary gene pool of wheat. Perenniality would be valuable option for grain production, but attempts to introgress this complex trait from wheat-Thinopyrum hybrids have not been commercially successful. Efforts to breed IWG itself as a dual-purpose forage and grain crop have demonstrated useful progress and applications, but grain yields are significantly less than wheat. Therefore, genetic and physical maps have been developed to accelerate domestication of IWG. Herein, these maps were used to identify quantitative trait loci (QTLs) and candidate genes associated with IWG grain production traits in a family of 266 full-sib progenies derived from two heterozygous parents, M26 and M35. Transgressive segregation was observed for 17 traits related to seed size, shattering, threshing, inflorescence capacity, fertility, stem size, and flowering time. A total of 111 QTLs were detected in 36 different regions using 3,826 genotype-by-sequence (GBS) markers in 21 linkage groups. The most prominent QTL had a LOD score of 15 with synergistic effects of 29% and 22% over the family means for seed retention and percent naked seed, respectively. Many QTLs aligned to one or more IWG gene models corresponding to 42 possible domestication orthogenes including the wheat Q and RHT genes. A cluster of seed-size and fertility QTLs showed possible alignment to a putative Z self-incompatibility gene, which could have detrimental grain-yield effects when genetic variability is low. These findings elucidate pathways and possible hurdles in the domestication of IWG.

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Section: Introductionmentioning

confidence: 99%

Genome mapping of quantitative trait loci (QTL) controlling domestication traits of intermediate wheatgrass (Thinopyrum intermedium)

et al. 2019

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“…Wide hybridization is attractive because, if successful, the new hybrid species can largely inherit highly developed traits such as yield and end-use quality from the already domesticated annual parent. Challenges arise, however, when the chromosome sets (genomes) or number of chromosome sets (ploidy level) in the annual and perennial parents do not match and/or do not recombine during meiosis (see, for example, papers by Cox et al [27] and Hayes et al [28] in this volume).…”

Section: Breeding Perennial Grainsmentioning

confidence: 99%

“…× Thinopyrum spp.) [28], rice (Oryza sativa × O. longistaminata) [35], and buckwheat (Fagopyrum spp. × Fagopyrum spp.)…”

Section: Breeding Perennial Grainsmentioning

confidence: 99%

Strategies, Advances, and Challenges in Breeding Perennial Grain Crops

Crews

Cattani

2018

Sustainability

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Abstract:The development of new perennial crop species is gaining momentum as a promising approach to change the fundamental nature of ecosystem processes in agriculture. The ecological argument for perennial crops grown in polycultures is strong, but until recently, perennial herbaceous grain crops have been absent from agricultural landscape. This is not because perennial herbaceous species do not exist in nature-there are thousands of perennial grasses, legumes, and other broad leaf plants. Rather, for a variety of reasons, early farmers focused on cultivating and domesticating annuals, and the perennial herbs were largely ignored. Today, we have a tremendous opportunity to explore another agricultural path. Building on contemporary knowledge of plant biology and genetics that early farmers lacked, and using a rapidly expanding toolbox that includes sophisticated genomic and analytical approaches, we can develop viable perennial grain crops. These crops can then be used to assemble diverse agroecosystems that regenerate soils and capture other important ecosystem functions.

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“…Adebiyi et al (2016) termed these innovations "radical transformative technologies" as "their architecture, functionality, component principles and underlying science markedly depart from existing agricultural systems" and suggests perennial grains as one of these "radical transformations". While other regions such as North America and Australia have been conducting research on perennial grain crops for more than a decade, similar research is still rare in Western Europe (Hayes et al, 2018). Recently a research program in France was set up in 2017.…”

Section: Perennial Grains: An Agroecological Innovation For Western Ementioning

confidence: 99%

“…Perennial grain: potential to provide ecosystem services for Western Europe Although current breeding efforts are promising and suggest further yield improvements will be forthcoming, IWG is currently unable to compete with annual counterparts in terms of grain productivity, mainly due to low harvest index which is around 0.10 (Culman et al, 2013;DeHaan et al, 2018). In contrast, perennial grain accessions obtained from the hybridization of domesticated varieties with close perennial relatives, most often using crosses between wheat (Triticum L.) and perennial Triticeae from the Thinopyrum genus, could be markedly higher yielding but also experience much lower perenniality and regrowth vigor (Cox et al, 2006;Hayes et al, 2018). Currently, plant breeders are working to improve breeding strategies and agronomic traits of perennial grains, including yield, threshability, favorable phenology, shattering rate, and plant persistence (Cox et al, 2010;DeHaan et al, 2018DeHaan et al, , 2014DeHaan et al, , 2005Hayes et al, 2012;Kantar et al, 2016).…”

Section: (Tons Ha-1)mentioning

confidence: 99%

Integrating multipurpose perennial grains crops in Western European farming systems

Duchêne

Celette

Ryan

et al. 2019

Agriculture, Ecosystems & Environment

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Western European agriculture is largely defined by the high level of productivity of its cereal grain production. Such productivity is largely a result of farm specialization and intensification. This approach however has led to environmental problems and farm sensitivity to climatic and economic hazards. Recently, perennial grains have been promoted as a potential alternative, particularly with intermediate wheatgrass (Thinopyrum intermedium). Perennial grains bring new perspectives and innovation, and can contribute to both system diversification and environmental performance. Above all, the value of yearround ground cover and root activity, as well as the ability to harvest both grain and forage production, offers a large range of interest and potential application for such a grain crop. Realization of the potential benefits from perennial grains depends on the development of suitable seed material and the identification of tangible economic and environmental benefits coming from the integration of perennial grains into crop rotations. Although more work is needed, perennial grains are compatible with the current European interests and policies for food security, soil health, water quality, and farmer interest in innovative practices and sustainable cropping systems.

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The Performance of Early-Generation Perennial Winter Cereals at 21 Sites across Four Continents

Cited by 39 publications

References 46 publications

Genome mapping of quantitative trait loci (QTL) controlling domestication traits of intermediate wheatgrass (Thinopyrum intermedium)

Genome mapping of quantitative trait loci (QTL) controlling domestication traits of intermediate wheatgrass (Thinopyrum intermedium)

Strategies, Advances, and Challenges in Breeding Perennial Grain Crops

Integrating multipurpose perennial grains crops in Western European farming systems

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