Your search keyword '"Alexandra Asaro"' showing total 4 results

1. The Interaction of Genotype and Environment Determines Variation in the Maize Kernel Ionome

Author

Alexandra Asaro, Gregory Ziegler, Cathrine Ziyomo, Owen A. Hoekenga, Brian P. Dilkes, and Ivan Baxter

Subjects

Genetics, QH426-470

Abstract

Plants obtain soil-resident elements that support growth and metabolism from the water-flow facilitated by transpiration and active transport processes. The availability of elements in the environment interacts with the genetic capacity of organisms to modulate element uptake through plastic adaptive responses, such as homeostasis. These interactions should cause the elemental contents of plants to vary such that the effects of genetic polymorphisms will be dramatically dependent on the environment in which the plant is grown. To investigate genotype by environment interactions underlying elemental accumulation, we analyzed levels of elements in maize kernels of the Intermated B73 × Mo17 (IBM) recombinant inbred population grown in 10 different environments, spanning a total of six locations and five different years. In analyses conducted separately for each environment, we identified a total of 79 quantitative trait loci (QTL) controlling seed elemental accumulation. While a set of these QTL was found in multiple environments, the majority were specific to a single environment, suggesting the presence of genetic by environment interactions. To specifically identify and quantify QTL by environment interactions (QEIs), we implemented two methods: linear modeling with environmental covariates, and QTL analysis on trait differences between growouts. With these approaches, we found several instances of QEI, indicating that elemental profiles are highly heritable, interrelated, and responsive to the environment.

Published

2016

2. Multivariate analysis reveals environmental and genetic determinants of element covariation in the maize grain ionome

Author

Alexandra Asaro Fikas, Brian P. Dilkes, and Ivan Baxter

Subjects

genotype‐by‐environment interactions, ionomics, maize, mineral nutrients, multivariate traits, Botany, QK1-989

Abstract

Abstract The integrated responses of biological systems to genetic and environmental variation result in substantial covariance in multiple phenotypes. The resultant pleiotropy, environmental effects, and genotype‐by‐environmental interactions (GxE) are foundational to our understanding of biology and genetics. Yet, the treatment of correlated characters, and the identification of the genes encoding functions that generate this covariance, has lagged. As a test case for analyzing the genetic basis underlying multiple correlated traits, we analyzed maize kernel ionomes from Intermated B73 x Mo17 (IBM) recombinant inbred populations grown in 10 environments. Plants obtain elements from the soil through genetic and biochemical pathways responsive to physiological state and environment. Most perturbations affect multiple elements which leads the ionome, the full complement of mineral nutrients in an organism, to vary as an integrated network rather than a set of distinct single elements. We compared quantitative trait loci (QTL) determining single‐element variation to QTL that predict variation in principal components (PCs) of multiple‐element covariance. Single‐element and multivariate approaches detected partially overlapping sets of loci. QTL influencing trait covariation were detected at loci that were not found by mapping single‐element traits. Moreover, this approach permitted testing environmental components of trait covariance, and identified multi‐element traits that were determined by both genetic and environmental factors as well as genotype‐by‐environment interactions. Growth environment had a profound effect on the elemental profiles and multi‐element phenotypes were significantly correlated with specific environmental variables.

Published

2019

3. The Interaction of Genotype and Environment Determines Variation in the Maize Kernel Ionome

Author

Gregory Ziegler, Alexandra Asaro, Ivan Baxter, Cathrine Ziyomo, Owen A. Hoekenga, and Brian P. Dilkes

Subjects

0106 biological sciences, 0301 basic medicine, Genotype, Quantitative Trait Loci, Inheritance Patterns, Investigations, Environment, Biology, Quantitative trait locus, QH426-470, Zea mays, 01 natural sciences, complex mixtures, 03 medical and health sciences, Quantitative Trait, Heritable, Botany, Genetics, Inbreeding, Gene–environment interaction, Molecular Biology, Crosses, Genetic, Genetic Association Studies, Genetics (clinical), Transpiration, Recombination, Genetic, Models, Statistical, Models, Genetic, fungi, Chromosome Mapping, food and beverages, equipment and supplies, Phenotype, Qtl analysis, Genetics, Population, 030104 developmental biology, Evolutionary biology, Principal component analysis, Trait, bacteria, Gene-Environment Interaction, Algorithms, Ionomics, 010606 plant biology & botany

Abstract

Plants obtain soil-resident elements that support growth and metabolism via water-mediated flow facilitated by transpiration and active transport processes. The availability of elements in the environment interact with the genetic capacity of organisms to modulate element uptake through plastic adaptive responses, such as homeostasis. These interactions should cause the elemental contents of plants to vary such that the effects of genetic polymorphisms influencing elemental accumulation will be dramatically dependent on the environment in which the plant is grown. To investigate genotype by environment interactions underlying elemental accumulation, we analyzed levels of elements in maize kernels of the Intermated B73 x Mo17 (IBM) recombinant inbred population grown in 10 different environments spanning a total of six locations and five different years. In analyses conducted separately for each environment, we identified a total of 79 quantitative trait loci controlling seed elemental accumulation. While a set of these QTL were found in multiple environments, the majority were specific to a single environment, suggesting the presence of genetic by environment interactions. To specifically identify and quantify QTL by environment interactions (QEIs), we implemented two methods: linear modeling with environmental covariates and QTL analysis on trait differences between growouts. With these approaches, we found several instances of QEI, indicating that elemental profiles are highly heritable, interrelated, and responsive to the environment.Author SummaryPlants take up elements from the soil, a process that is highly regulated by the plant’s genome. To investigate how maize alters its elemental uptake in response to different environments, we analyzed the kernel elemental content of a population derived from a cross grown 10 different times in six locations. We found that environment had a profound effect on which genetic loci were important for elemental accumulation in the kernel. Our results suggest that to have a full understanding of elemental accumulation in maize kernels and other food crops, we will need to understand the interactions identified here at the level of the genes and the environmental variables that contribute to loading essential nutrients into seeds.

Published

2016

4. Multivariate analysis reveals environmental and genetic determinants of element covariation in the maize grain ionome

Author

Fikas, Alexandra Asaro, primary, Dilkes, Brian P., additional, and Baxter, Ivan, additional

Published

2019