Genomic preselection with genotyping-by-sequencing increases performance of commercial oil palm hybrid crosses

Cros, David; Bocs, Stéphanie; Riou, Virginie; Ortega-Abboud, Enrique; Tisné, Sébastien; Argout, Xavier; Pomiès, Virginie; Nodichao, Leifi; Lubis, Zulkifli; Cochard, Benoît; Durand‐Gasselin, Tristan

doi:10.1186/s12864-017-4179-3

Cited by 32 publications

(23 citation statements)

References 59 publications

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“…Use of genomic selection, for example, to rapidly develop heterotic pools in crops in which they are not well-established—e.g., rice and wheat— is worth trying ( Rembe et al, 2019 ). Further reports on RRGS programs which have been initiated in oil palm, which has a long generation interval, high phenotyping costs, and high environmental impact, are anticipated ( Cros et al, 2017 ; Nyouma et al, 2019 ). In selection of single crosses, genomic prediction has potential to reduce the need for testcrossing and field evaluation ( Longin et al, 2015 ; Kadam et al, 2016 ).…”

Section: Discussionmentioning

confidence: 99%

Heterosis and Hybrid Crop Breeding: A Multidisciplinary Review

2021

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Although hybrid crop varieties are among the most popular agricultural innovations, the rationale for hybrid crop breeding is sometimes misunderstood. Hybrid breeding is slower and more resource-intensive than inbred breeding, but it allows systematic improvement of a population by recurrent selection and exploitation of heterosis simultaneously. Inbred parental lines can identically reproduce both themselves and their F1 progeny indefinitely, whereas outbred lines cannot, so uniform outbred lines must be bred indirectly through their inbred parents to harness heterosis. Heterosis is an expected consequence of whole-genome non-additive effects at the population level over evolutionary time. Understanding heterosis from the perspective of molecular genetic mechanisms alone may be elusive, because heterosis is likely an emergent property of populations. Hybrid breeding is a process of recurrent population improvement to maximize hybrid performance. Hybrid breeding is not maximization of heterosis per se, nor testing random combinations of individuals to find an exceptional hybrid, nor using heterosis in place of population improvement. Though there are methods to harness heterosis other than hybrid breeding, such as use of open-pollinated varieties or clonal propagation, they are not currently suitable for all crops or production environments. The use of genomic selection can decrease cycle time and costs in hybrid breeding, particularly by rapidly establishing heterotic pools, reducing testcrossing, and limiting the loss of genetic variance. Open questions in optimal use of genomic selection in hybrid crop breeding programs remain, such as how to choose founders of heterotic pools, the importance of dominance effects in genomic prediction, the necessary frequency of updating the training set with phenotypic information, and how to maintain genetic variance and prevent fixation of deleterious alleles.

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Section: Discussionmentioning

confidence: 99%

Heterosis and Hybrid Crop Breeding: A Multidisciplinary Review

2021

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“…It should be noted, however, that QTL studies and associated candidate gene investigations should be seen as a first step to gain insights into the genotype-phenotype map, and that additional studies are needed to verify that candidate genes are indeed causal in affecting the trait in question. Such genotype-phenotype datasets can also be used to develop multi-marker models (based on multiple QTL), which explain variation of one or more phenotypic traits (Cros et al 2017).…”

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confidence: 99%

High-Density Linkage Map and QTLs for Growth in Snapper (Chrysophrys auratus)

Ashton

Ritchie

Wellenreuther

2019

G3 Genes|Genomes|Genetics

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Characterizing the genetic variation underlying phenotypic traits is a central objective in biological research. This research has been hampered in the past by the limited genomic resources available for most non-model species. However, recent advances in sequencing technologies and related genotyping methods are rapidly changing this. Here we report the use of genome-wide SNP data from the ecologically and commercially important marine fish species Chrysophrys auratus (snapper) to 1) construct the first linkage map for this species, 2) scan for growth QTL, and 3) search for putative candidate genes in the surrounding QTL regions. The newly constructed linkage map contained ∼11K SNP markers and is one of the densest maps to date in the fish family Sparidae. Comparisons with genome scaffolds of the recently assembled snapper genome indicated that marker placement was mostly consistent between the scaffolds and linkage map (R = 0.7), but that at fine scales (< 5 cM) some precision limitations occurred. Of the 24 linkage groups, which likely reflect the 24 chromosomes of this species, three were found to contain QTL with genome-wide significance for growth-related traits. A scan of 13 candidate growth genes located the growth hormone, myogenin, and parvalbumin genes within 5.3, 9.6, and 25.0 cM of these QTL, respectively. The linkage map and QTL found in this study will advance the investigation of genome structure and aquaculture breeding efforts in this and related species.

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“…GP could also be coupled with somatic embryo-genesis for clonal propagation of elite genotypes by selecting elite zygotic embryos based on their genomic breeding value (Grattapaglia et al, 2018). GP has the potential to predict untested hybrid genotypes (Technow et al, 2014) in woody perennials (Cros et al, 2017;Tan et al, 2017) by genotyping potential parental lines and phenotyping few F1 hybrids. Prioritizing inter-specific combinations for field trials can speed up hybrid breeding.…”

Section: Predictive Breeding Promises Boosting Forest Tree Genetic Immentioning

confidence: 99%

Modern Strategies to Assess and Breed Forest Tree Adaptation to Changing Climate

2020

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Studying the genetics of adaptation to new environments in ecologically and industrially important tree species is currently a major research line in the fields of plant science and genetic improvement for tolerance to abiotic stress. Specifically, exploring the genomic basis of local adaptation is imperative for assessing the conditions under which trees will successfully adapt in situ to global climate change. However, this knowledge has scarcely been used in conservation and forest tree improvement because woody perennials face major research limitations such as their outcrossing reproductive systems, long juvenile phase, and huge genome sizes. Therefore, in this review we discuss predictive genomic approaches that promise increasing adaptive selection accuracy and shortening generation intervals. They may also assist the detection of novel allelic variants from tree germplasm, and disclose the genomic potential of adaptation to different environments. For instance, natural populations of tree species invite using tools from the population genomics field to study the signatures of local adaptation. Conventional genetic markers and whole genome sequencing both help identifying genes and markers that diverge between local populations more than expected under neutrality, and that exhibit unique signatures of diversity indicative of "selective sweeps." Ultimately, these efforts inform the conservation and breeding status capable of pivoting forest health, ecosystem services, and sustainable production. Key long-term perspectives include understanding how trees' phylogeographic history may affect the adaptive relevant genetic variation available for adaptation to environmental change. Encouraging "big data" approaches (machine learning-ML) capable of comprehensively merging heterogeneous genomic and ecological datasets is becoming imperative, too.

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Genomic preselection with genotyping-by-sequencing increases performance of commercial oil palm hybrid crosses

Cited by 32 publications

References 59 publications

Heterosis and Hybrid Crop Breeding: A Multidisciplinary Review

Heterosis and Hybrid Crop Breeding: A Multidisciplinary Review

High-Density Linkage Map and QTLs for Growth in Snapper (Chrysophrys auratus)

Modern Strategies to Assess and Breed Forest Tree Adaptation to Changing Climate

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