The Genetic Architecture of Response to Long-Term Artificial Selection for Oil Concentration in the Maize Kernel

Laurie, Cathy C.; Chasalow, Scott D.; LeDeaux, John R.; McCarroll, Robert; Bush, David; Hauge, Brian M.; Lai, Chao‐Qiang; Clark, David F.; Rocheford, Torbert; Dudley, J. W.

doi:10.1534/genetics.104.029686

Cited by 263 publications

(190 citation statements)

References 27 publications

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“…The design combining large-scale diversity lines with deep RNA-seq can provide sufficient coverage of gene expression and help to narrow the eQTL to gene level, generating the hypothesis of gene regulatory relationship. The data set in this study has been successfully used in exploring the genetic architecture of oil biosynthesis and accumulation in maize kernel, which is a typical quantitative trait controlled by polygenic loci 46 . The results showed that 74 highly significantly associated loci were responsible for oil concentration and fatty acid composition 5 .…”

Section: Discussionmentioning

confidence: 99%

RNA sequencing reveals the complex regulatory network in the maize kernel

et al. 2013

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RNA sequencing can simultaneously identify exonic polymorphisms and quantitate gene expression. Here we report RNA sequencing of developing maize kernels from 368 inbred lines producing 25.8 billion reads and 3.6 million single-nucleotide polymorphisms. Both the MaizeSNP50 BeadChip and the Sequenom MassArray iPLEX platforms confirm a subset of high-quality SNPs. Of these SNPs, we have mapped 931,484 to gene regions with a mean density of 40.3 SNPs per gene. The genome-wide association study identifies 16,408 expression quantitative trait loci. A two-step approach defines 95.1% of the eQTLs to a 10-kb region, and 67.7% of them include a single gene. The establishment of relationships between eQTLs and their targets reveals a large-scale gene regulatory network, which include the regulation of 31 zein and 16 key kernel genes. These results contribute to our understanding of kernel development and to the improvement of maize yield and nutritional quality.

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Section: Discussionmentioning

confidence: 99%

RNA sequencing reveals the complex regulatory network in the maize kernel

et al. 2013

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“…For instance, Monsanto's breeding program uses a subset of >50 different QTLs that exist for each of the characteristics of days to silking, days to anthesis, and grain oil content (Laurie et al, 2004;Buckler et al, 2009). Additionally, there are >100 QTLs associated with the development of root architecture in maize (Zurek et al, 2015), and breeding companies screen for a targeted subset of them within their breeding pipeline.…”

Section: Technologies Used To Expedite the Breeding Processmentioning

confidence: 99%

Bringing New Plant Varieties to Market: Plant Breeding and Selection Practices Advance Beneficial Characteristics while Minimizing Unintended Changes

et al. 2017

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Commercial‐scale plant breeding is a complex process in which new crop varieties are continuously being developed to improve yield and agronomic performance over current varieties. A wide array of naturally occurring genetic changes are sources of new characteristics available to plant breeders. During conventional plant breeding, genetic material is exchanged that has the potential to beneficially or adversely affect plant characteristics. For this reason, commercial‐scale breeders have implemented extensive plant selection practices to identify the top‐performing candidates with the desired characteristics while minimizing the advancement of unintended changes. Selection practices in maize (Zea mays L.) breeding involve phenotypic assessments of thousands of candidate lines throughout hundreds of different environmental conditions over many years. Desirable characteristics can also be introduced through genetic modification. For genetically modified (GM) crops, molecular analysis is used to select transformed plants with a single copy of an intact DNA insert and without disruption of endogenous genes. All the while, GM crops go through the same extensive phenotypic characterization as conventionally bred crops. Data from both conventional and GM maize breeding programs are presented to show the similarities between these two processes.

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“…These high genomic mutation rates can be explained by either a low mutation rate per locus with a very large number of loci (e.g. more than 50 in Laurie et al 2004) or a high mutation rate per locus with a moderate number of loci (of the order of 5 or 10) as found for the onset of flowering (Lande 1981;see references in Fox 2003) and other traits in plants (Kearsey & Farquhar 1998), for example due to unequal exchange in tandemly duplicated gene families ( Frankham et al 1978). The ratio of the mutational to the environmental variance was taken from Lande (1975) and Lynch (1988), while the value of the environmental variance was chosen to match previous observations for flowering time in herbaceous species (Lande 1981;O'Neil 1997;Shaw & Chang 2006 single ovule but a large number of pollen grains so that it can contribute once as female and several times as male to the next generation.…”

Section: The Modelmentioning

confidence: 99%

Incipient allochronic speciation due to non-selective assortative mating by flowering time, mutation and genetic drift

2008

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We model the evolution of flowering time using a multilocus quantitative genetic model with non-selective assortative mating and mutation to investigate incipient allochronic speciation in a finite population. For quantitative characters with evolutionary parameters satisfying empirical observations and two approximate inequalities that we derived, disjunct clusters in the population flowering phenology originated within a few thousand generations in the absence of disruptive natural or sexual selection. Our simulations and the conditions we derived showed that cluster formation was promoted by limited population size, high mutational variance of flowering time, short individual flowering phenology and a long flowering season. By contrast, cluster formation was hindered by inbreeding depression, stabilizing selection and pollinator limitation. Our results suggest that incipient allochronic speciation in populations of limited size (satisfying two inequalities) could be a common phenomenon.

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The Genetic Architecture of Response to Long-Term Artificial Selection for Oil Concentration in the Maize Kernel

Cited by 263 publications

References 27 publications

RNA sequencing reveals the complex regulatory network in the maize kernel

RNA sequencing reveals the complex regulatory network in the maize kernel

Bringing New Plant Varieties to Market: Plant Breeding and Selection Practices Advance Beneficial Characteristics while Minimizing Unintended Changes

Incipient allochronic speciation due to non-selective assortative mating by flowering time, mutation and genetic drift

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