Genomic selection for non-key traits in radiata pine when the documented pedigree is corrected using DNA marker information

Li, Yongjun; Klápště, Jaroslav; Telfer, Emily; Wilcox, Phillip; Graham, Natalie; Macdonald, Lucy; Dungey, Heidi S.

doi:10.1186/s12864-019-6420-8

Cited by 30 publications

(25 citation statements)

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“…GBS marker information has been successfully used for parentage reconstruction in Scots pine [ 34 ], as well as to perform genomic predictions studies in livestock [ 35 , 36 ], maize [ 37 ], wheat [ 33 ], soybean [ 38 ], Picea glauca (Moench) Voss × Picea engelmannii Parry ex Engelm. [ 39 ] and radiata pine [ 40 ]. Therefore, GBS is an attractive technology that can be used to perform GS and genome-wide association studies (GWAS) for Scots pine [ 41 , 42 ].…”

Section: Introductionmentioning

confidence: 99%

Evaluation of the efficiency of genomic versus pedigree predictions for growth and wood quality traits in Scots pine

et al. 2020

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Background Genomic selection (GS) or genomic prediction is a promising approach for tree breeding to obtain higher genetic gains by shortening time of progeny testing in breeding programs. As proof-of-concept for Scots pine (Pinus sylvestris L.), a genomic prediction study was conducted with 694 individuals representing 183 full-sib families that were genotyped with genotyping-by-sequencing (GBS) and phenotyped for growth and wood quality traits. 8719 SNPs were used to compare different genomic with pedigree prediction models. Additionally, four prediction efficiency methods were used to evaluate the impact of genomic breeding value estimations by assigning diverse ratios of training and validation sets, as well as several subsets of SNP markers. Results Genomic Best Linear Unbiased Prediction (GBLUP) and Bayesian Ridge Regression (BRR) combined with expectation maximization (EM) imputation algorithm showed slightly higher prediction efficiencies than Pedigree Best Linear Unbiased Prediction (PBLUP) and Bayesian LASSO, with some exceptions. A subset of approximately 6000 SNP markers, was enough to provide similar prediction efficiencies as the full set of 8719 markers. Additionally, prediction efficiencies of genomic models were enough to achieve a higher selection response, that varied between 50-143% higher than the traditional pedigree-based selection. Conclusions Although prediction efficiencies were similar for genomic and pedigree models, the relative selection response was doubled for genomic models by assuming that earlier selections can be done at the seedling stage, reducing the progeny testing time, thus shortening the breeding cycle length roughly by 50%.

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Section: Introductionmentioning

confidence: 99%

Evaluation of the efficiency of genomic versus pedigree predictions for growth and wood quality traits in Scots pine

et al. 2020

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“…Trait data must be in Linkage Disequilibrium-LD or genetic auto-correlation (e.g., Kelleher et al, 2012), with the molecular markers or with the samples' genetic co-ancestry. GP utility has been demonstrated ( Table 1) in model forest tree species such as Eucalyptus Suontama et al, 2019), and conifers as Pinus Li et al, 2019) and Douglas-fir (Thistlethwaite et al, 2017(Thistlethwaite et al, , 2019b, but also in non-model perennial crops such as coffee (Sousa et al, 2018), rubber (Cros et al, 2019;Souza et al, 2019) and oil palm (Cros et al, 2015). GP may even fit epigenetics (Roudbar et al, 2020), as well as multi-trait genomic models as was recently confirmed in Norway spruce for growth, wood quality and weevil resistance traits (Lenz et al, 2020).…”

Section: Predictive Breeding Promises Boosting Forest Tree Genetic Immentioning

confidence: 82%

“…Yet, the power of population genomics must be further extended to comprehend neutral and adaptive processes in noncommercial species of ecological value in order to advance not just productivity, but also climate adaptation, forest health and conservation (Isabel et al, 2020). In this sense, GP is starting to permeate novel non-key traits other than growth and wood density, but still of interest for breeding, such as branching, stem straightness and external resin bleeding (Li et al, 2019). GP is also predicting adaptive trait variation for abiotic (Eckert et al, 2010) and biotic (Westbrook et al, 2020) stresses.…”

Section: Discussionmentioning

confidence: 99%

“…More recently, major developments in the field of predictive breeding (i.e., GP) promise to speed up selection from natural sources, as well as within the breeding cycle, by shortening the generation intervals and increasing the selection accuracy prior field trials. We have already identified and discussed major improvements in this line, such as multitrait GP models (Lenz et al, 2020), coupled with integrative selection scores (Burdon and KlápšTě, 2019) on novel nonkey (Li et al, 2019) and ecological-worth (Holliday et al, 2017;Isabel et al, 2020) traits. These innovations can capture multi-scale trait-environment relationships (Bruelheide et al, 2018) in non-model tree species (Mayol et al, 2020).…”

Section: Perspectivesmentioning

confidence: 99%

“…Yet, this information has limitedly been utilized in tree improvement and conservation (Flanagan et al, 2018), despite genetic gains (Figure 1) and optimized management are urgently required due to environmental issues (Scherer et al, 2020). Besides, breeding woody perennials is primarily bottlenecked by their outcrossing reproductive systems, prolonged juvenile phases (Grattapaglia et al, 2018), large genome sizes lacking elimination mechanisms of long-terminal transposons (Nystedt et al, 2013), and an excessive focus on productivity (Burdon and KlápšTě, 2019) that omits adaptive traits ( Table 1; Li et al, 2019). Thus, here we discuss ways to side step these limitations by arguing how predictive genomics can increase selection accuracy and shorten generation intervals (Grattapaglia et al, 2018), assist the detection of exotic variants from tree germplasm (Migicovsky and Myles, 2017), and disclose the genomic potential of adaptation to different climates (Lind et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

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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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Soft rot of postharvest pepper: bacterial pathogen, pathogenicity and its biological control using Lactobacillus farciminis LJLAB1

Li,

et al. 2023

J Sci Food Agric

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BackgroundSoft rot is the most important bacterial disease of postharvest pepper during storage and transportation. The main objectives of this study were to investigate the bacterial pathogen species causing pepper soft rot and seek for an antagonistic bacterium to control this disease.ResultsPathogens Pectobacterium carotovorum, Enterobacter sp., Klebsiella sp., Pseudomonas sp. and Bacillus sp. were verified to be the causes of soft rot which were isolated from rotten peppers. Among them, P. carotovorum had the highest prevalence, including P. carotovorum subsp. carotovorum (Pcc) and P. carotovorum subsp. brasilisesis (Pcb). The result of pathogenicity analysis showed that Pcb Jm2 had strong pathogenicity at 25 °C even at a cell concentration of 103 CFU mL−1. Its pathogenicity decreased at 4 °C. Multiple pathogenic factors were identified in the draft genome of Pcb Jm2, including cellulase, pectinase, pectin methylesterase, pectinesterase, pectin lyase, polygalacturonase and so forth. Further, the disease control ability of Lactobacillus farciminis LJLAB1 was investigated. The cell‐free supernatant (CFS) and crude bacteriocin of L. farciminis LJLAB1 had good antibacterial activities to Pcb Jm2 in vitro, but CFS exhibited a better disease control effect in vivo. CFS treatment prevented the damage of pepper epidermal structure caused by Pcb Jm2, and 99.26% of pathogen cells on pepper were killed by it. Moreover, CFS treatment delayed firmness decrease, soluble solid content loss, weight loss, yellowing and malonaldehyde accumulation of pepper during storage after pathogen infection.ConclusionL. farciminis LJLAB1 can be an effective biological control agent to control pepper soft rot caused by Pcb. © 2023 Society of Chemical Industry.

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Genomic selection for non-key traits in radiata pine when the documented pedigree is corrected using DNA marker information

Cited by 30 publications

References 44 publications

Evaluation of the efficiency of genomic versus pedigree predictions for growth and wood quality traits in Scots pine

Evaluation of the efficiency of genomic versus pedigree predictions for growth and wood quality traits in Scots pine

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

Soft rot of postharvest pepper: bacterial pathogen, pathogenicity and its biological control using Lactobacillus farciminis LJLAB1

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