Effect of F1 and F2 generations on genetic variability and working steps of doubled haploid production in maize

Couto, Evellyn Giselly de Oliveira; Cury, Mayara Neves; Souza, Massaine Bandeira e; Granato, Ítalo Stefanine Correia; Vidotti, Miriam Suzane; Garbuglio, Deoclécio Domingos; Crossa, José; Burgueño, Juan; Fritsche‐Neto, Roberto

doi:10.1371/journal.pone.0224631

Cited by 19 publications

(22 citation statements)

References 26 publications

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“…Moreover, the discrepancy between HIR in 2012/2013 and 2014/2015 can be explained by natural selection disfavoring the haploidy-inducing gametes during selfing. From an evolutionary point of view, a higher proportion of haploids in the family caused by high HIR of the pollinator would result in reduced plant vigor, because haploid maize plants are less vigorous, often male sterile, and therefore generally less likely to produce progenies than diploid maize plants (Couto et al 2020), which explains the action of natural selection (Prigge et al 2012). The latter may also explain the difficulties of maintaining haploid inducers described by maize breeders.…”

Section: Resultsmentioning

confidence: 99%

“…Maize haploid inducer lines, when used as pollinators, trigger the production of seeds with a haploid embryo at a mean rate of 8% due to a hetero-fertilization together with failed egg-sperm cell fusion (Tian et al 2018). In spite of the successful development of maize haploid inducers in the tropics (Chaikam 2012, Couto et al 2020), compared to temperate conditions, data on this DH process are still scarce.…”

Section: Introductionmentioning

confidence: 99%

“…Moreover, specifically the use of binomial models has been intensified in other related studies (Wegenast et al 2010, Batistelli et al 2013, Couto et al 2015. Couto et al (2020) used the multinomial model to evaluate haploid induction rate, diploid seed rate and inhibition seed rate.…”

Section: Introductionmentioning

confidence: 99%

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Breeding strategies for tropical maize targeting in vivo haploid inducers

Ribeiro

Rezende

Filho

et al. 2020

Crop Breed. Appl. Biotechnol.

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The objective of this study was to compare the selection of plants bred by different pedigree methods using selection among, among and within and only within families. The haploid induction rate of 14 S 0:1 and seven S 2:3 families, all crossed with the single-cross hybrid GNZ9501, was evaluated. An experimental area of the Department of Biology of the Federal University of Lavras (UFLA), in Lavras, Minas Gerais, in the growing seasons 2012/2013 and 2014/2015, was used for the experiments. In each growing season, one experiment per was carried out, arranged in a complete randomized design, with one and two replications, respectively. Haploid induction was most effective in the families 2 and 6 in both growing seasons. Selection among and within families resulted in higher genetic gains for haploid induction. The results indicated a high genetic variability for haploid induction rate in plants within families.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Breeding strategies for tropical maize targeting in vivo haploid inducers

Ribeiro

Rezende

Filho

et al. 2020

Crop Breed. Appl. Biotechnol.

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“…Results were compared for HIR, diploid seed rate, and inhibition seed rate. Findings showed that HIR, inhibition seed rate, and diploid seed rate were 1.23, 23.48, and 75.21% for F 1 generation and 1.78, 15.82, and 82.38% for F 2 generation respectively (Couto et al., 2019). Conclusively stating that very high inhibition rate was observed in genetic background of tropical germplasm for expression of R1‐navajo phenotype.…”

Section: Phenotypic Markersmentioning

confidence: 99%

Doubled haploids in maize: Development, deployment, and challenges

Maqbool¹,

Beshir²,

Khokhar³

2020

Crop Science

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Haploids are naturally produced in maize (Zea mays L.) at different rates and can also be induced through different methods. Haploids are used to develop doubled haploids (DHs), which have many potential uses. The development of DH lines in maize involves haploid induction, haploid identification, chromosome doubling, and field sowing for self‐pollination of D0 plants. Different potential methods are used for haploid induction, in‐vivo maternal haploid induction being the most prevalent. Haploid induction is highly reliant on the unambiguous identification of haploids among a mixture of different ploidies. Haploid identification is facilitated by visual morphological markers, chromosome counting, flow cytometry, molecular markers, and many other approaches. Chromosome doubling may be achieved by spontaneous doubling or by induction with different antimicrotubular treatments. Among the potential uses of DH lines are the development of inbred lines, genomic selection (GS), quantitative trait loci (QTL) mapping, and unlocking new genetic variations. Although DH technology can potentially accelerate maize breeding, it still faces challenges at each step of DH line development. This article aims to highlight the importance, procedural steps, potential opportunities, and key challenges in DH line development in maize.

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“…To obtain seeds from induction crosses marked by R1-nj, we used a haploid inducer population derived from a cross of two inducer lines (W23 and Stock6) with a maize hybrid adapted to tropical conditions. This inducer population has a dominant inheritance for the R1-nj marker and a putative haploid induction rate equal to 1.51% (Couto et al, 2019). As donors, we used two commercial singlecrosses, one from the flint and another from the dent heterotic group, where 50 unique plants from the haploid inducer were crossed with two plants from each donor.…”

Section: Plant Materials and Field Trialsmentioning

confidence: 99%

Haploid maize seeds prediction using deep learning and using mock reference genomes for genomic prediction of hybrids

Sabadin¹

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Haploid maize seeds prediction using deep learning and using mock reference genomes for genomic prediction of hybrids Prediction is a key concept for animal and plant breeding. Accurate estimates of phenotypic and genetic values are crucial for the selection of the best genotypes. For this reason, several tools have been used to improve the accuracy of these estimates, from molecular markers, used to access genetic information, to high-throughput phenotyping, used to increase sample size and phenotypic precision. Here, we present two studies involving the use of different approaches and tools in the prediction process. First, we describe a study using deep learning and images for seed phenotyping. We built a convolutional neural network (CNN) model to classify images from putative and true haploid maize seeds based on the R1-nj phenotype. Our results reveal that the CNN model could classify putative haploid maize seeds with high accuracy (97%). However, the CNN model was unable to recognize true haploid seeds. Finally, we provide a highly accurate and trained CNN model to the scientific community to classify haploid maize seeds via R1-nj. In the latter, we studied using mock genomes to discover markers and their effect on estimates of genetic diversity and genomic prediction of hybrids. Moreover, we compared them with SNP markers from SNP-array and genotyping-bysequencing (GBS) scored in the reference genome B73. Our results show that using mock genomes delivers estimates comparable to standard platforms when considering simple traits and additive effects. However, for complex traits and dominance effects, the estimates were slightly worse. We believe that these studies provide relevant knowledge for the phenotypic and genomic prediction applied to plant breeding.

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Effect of F1 and F2 generations on genetic variability and working steps of doubled haploid production in maize

Cited by 19 publications

References 26 publications

Breeding strategies for tropical maize targeting in vivo haploid inducers

Breeding strategies for tropical maize targeting in vivo haploid inducers

Doubled haploids in maize: Development, deployment, and challenges

Haploid maize seeds prediction using deep learning and using mock reference genomes for genomic prediction of hybrids

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