Your search keyword '"Zoë Migicovsky"' showing total 8 results

1. Topological Data Analysis as a Morphometric Method: Using Persistent Homology to Demarcate a Leaf Morphospace

Author

Mao Li, Hong An, Ruthie Angelovici, Clement Bagaza, Albert Batushansky, Lynn Clark, Viktoriya Coneva, Michael J. Donoghue, Erika Edwards, Diego Fajardo, Hui Fang, Margaret H. Frank, Timothy Gallaher, Sarah Gebken, Theresa Hill, Shelley Jansky, Baljinder Kaur, Phillip C. Klahs, Laura L. Klein, Vasu Kuraparthy, Jason Londo, Zoë Migicovsky, Allison Miller, Rebekah Mohn, Sean Myles, Wagner C. Otoni, J. C. Pires, Edmond Rieffer, Sam Schmerler, Elizabeth Spriggs, Christopher N. Topp, Allen Van Deynze, Kuang Zhang, Linglong Zhu, Braden M. Zink, and Daniel H. Chitwood

Subjects

leaf shape, leaves, morphology, shape, topology, topological data analysis, Plant culture, SB1-1110

Abstract

Current morphometric methods that comprehensively measure shape cannot compare the disparate leaf shapes found in seed plants and are sensitive to processing artifacts. We explore the use of persistent homology, a topological method applied as a filtration across simplicial complexes (or more simply, a method to measure topological features of spaces across different spatial resolutions), to overcome these limitations. The described method isolates subsets of shape features and measures the spatial relationship of neighboring pixel densities in a shape. We apply the method to the analysis of 182,707 leaves, both published and unpublished, representing 141 plant families collected from 75 sites throughout the world. By measuring leaves from throughout the seed plants using persistent homology, a defined morphospace comparing all leaves is demarcated. Clear differences in shape between major phylogenetic groups are detected and estimates of leaf shape diversity within plant families are made. The approach predicts plant family above chance. The application of a persistent homology method, using topological features, to measure leaf shape allows for a unified morphometric framework to measure plant form, including shapes, textures, patterns, and branching architectures.

Published

2018

2. Prediction of Cacao (Theobroma cacao) Resistance to Moniliophthora spp. Diseases via Genome-Wide Association Analysis and Genomic Selection

Author

Michel S. McElroy, Alberto J. R. Navarro, Guiliana Mustiga, Conrad Stack, Salvador Gezan, Geover Peña, Widem Sarabia, Diego Saquicela, Ignacio Sotomayor, Gavin M. Douglas, Zoë Migicovsky, Freddy Amores, Omar Tarqui, Sean Myles, and Juan C. Motamayor

Subjects

Theobroma cacao, witches’ broom disease, frosty pod rot, SNPs, GWAS, genomic selection, Plant culture, SB1-1110

Abstract

Cacao (Theobroma cacao) is a globally important crop, and its yield is severely restricted by disease. Two of the most damaging diseases, witches’ broom disease (WBD) and frosty pod rot disease (FPRD), are caused by a pair of related fungi: Moniliophthora perniciosa and Moniliophthora roreri, respectively. Resistant cultivars are the most effective long-term strategy to address Moniliophthora diseases, but efficiently generating resistant and productive new cultivars will require robust methods for screening germplasm before field testing. Marker-assisted selection (MAS) and genomic selection (GS) provide two potential avenues for predicting the performance of new genotypes, potentially increasing the selection gain per unit time. To test the effectiveness of these two approaches, we performed a genome-wide association study (GWAS) and GS on three related populations of cacao in Ecuador genotyped with a 15K single nucleotide polymorphism (SNP) microarray for three measures of WBD infection (vegetative broom, cushion broom, and chirimoya pod), one of FPRD (monilia pod) and two productivity traits (total fresh weight of pods and % healthy pods produced). GWAS yielded several SNPs associated with disease resistance in each population, but none were significantly correlated with the same trait in other populations. Genomic selection, using one population as a training set to estimate the phenotypes of the remaining two (composed of different families), varied among traits, from a mean prediction accuracy of 0.46 (vegetative broom) to 0.15 (monilia pod), and varied between training populations. Simulations demonstrated that selecting seedlings using GWAS markers alone generates no improvement over selecting at random, but that GS improves the selection process significantly. Our results suggest that the GWAS markers discovered here are not sufficiently predictive across diverse germplasm to be useful for MAS, but that using all markers in a GS framework holds substantial promise in accelerating disease-resistance in cacao.

Published

2018

3. Morphometrics Reveals Complex and Heritable Apple Leaf Shapes

Author

Zoë Migicovsky, Mao Li, Daniel H. Chitwood, and Sean Myles

Subjects

apple, leaf shape, morphometrics, elliptical Fourier descriptors, persistent homology, Malus domestica, Plant culture, SB1-1110

Abstract

Apple (Malus spp.) is a widely grown and valuable fruit crop. Leaf shape is important for flowering in apple and may also be an early indicator for other agriculturally valuable traits. We examined 9,000 leaves from 869 unique apple accessions using linear measurements and comprehensive morphometric techniques. We identified allometric variation as the result of differing length-to-width aspect ratios between accessions and species of apple. The allometric variation was due to variation in the width of the leaf blade, not the length. Aspect ratio was highly correlated with the first principal component (PC1) of morphometric variation quantified using elliptical Fourier descriptors (EFDs) and persistent homology (PH). While the primary source of variation was aspect ratio, subsequent PCs corresponded to complex shape variation not captured by linear measurements. After linking the morphometric information with over 122,000 genome-wide single nucleotide polymorphisms (SNPs), we found high SNP heritability values even at later PCs, indicating that comprehensive morphometrics can capture complex, heritable phenotypes. Thus, techniques such as EFDs and PH are capturing heritable biological variation that would be missed using linear measurements alone.

Published

2018

4. Prediction of Cacao (Theobroma cacao) Resistance to Moniliophthora spp. Diseases via Genome-Wide Association Analysis and Genomic Selection

Author

Freddy Amores, Guiliana M Mustiga, Geover Peña, Salvador A. Gezan, Conrad Stack, Widem Sarabia, Zoë Migicovsky, Sean Myles, Gavin M. Douglas, Alberto J. R. Navarro, Michel McElroy, Juan Carlos Motamayor, Diego Saquicela, Ignacio Sotomayor, and Omar Tarqui

Subjects

0301 basic medicine, Germplasm, Theobroma, Population, Moniliophthora roreri, Moniliophthora, Plant Science, lcsh:Plant culture, Plant disease resistance, Moniliophthora perniciosa, genomic selection, 03 medical and health sciences, GWAS, Theobroma cacao, lcsh:SB1-1110, frosty pod rot, education, 2. Zero hunger, Genetics, education.field_of_study, biology, Broom, witches’ broom disease, 15. Life on land, biology.organism_classification, 030104 developmental biology, SNPs

Abstract

Cacao (Theobroma cacao) is a globally important crop, and its yield is severely restricted by disease. Two of the most damaging diseases, witches’ broom disease (WBD) and frosty pod rot disease (FPRD), are caused by a pair of related fungi: Moniliophthora perniciosa and Moniliophthora roreri, respectively. Resistant cultivars are the most effective long-term strategy to address Moniliophthora diseases, but efficiently generating resistant and productive new cultivars will require robust methods for screening germplasm before field testing. Marker-assisted selection (MAS) and genomic selection (GS) provide two potential avenues for predicting the performance of new genotypes, potentially increasing the selection gain per unit time. To test the effectiveness of these two approaches, we performed a genome-wide association study (GWAS) and GS on three related populations of cacao in Ecuador genotyped with a 15K single nucleotide polymorphism (SNP) microarray for three measures of WBD infection (vegetative broom, cushion broom, and chirimoya pod), one of FPRD (monilia pod) and two productivity traits (total fresh weight of pods and % healthy pods produced). GWAS yielded several SNPs associated with disease resistance in each population, but none were significantly correlated with the same trait in other populations. Genomic selection, using one population as a training set to estimate the phenotypes of the remaining two (composed of different families), varied among traits, from a mean prediction accuracy of 0.46 (vegetative broom) to 0.15 (monilia pod), and varied between training populations. Simulations demonstrated that selecting seedlings using GWAS markers alone generates no improvement over selecting at random, but that GS improves the selection process significantly. Our results suggest that the GWAS markers discovered here are not sufficiently predictive across diverse germplasm to be useful for MAS, but that using all markers in a GS framework holds substantial promise in accelerating disease-resistance in cacao.

Published

2018

5. Prediction of Cacao (

Author

Michel S, McElroy, Alberto J R, Navarro, Guiliana, Mustiga, Conrad, Stack, Salvador, Gezan, Geover, Peña, Widem, Sarabia, Diego, Saquicela, Ignacio, Sotomayor, Gavin M, Douglas, Zoë, Migicovsky, Freddy, Amores, Omar, Tarqui, Sean, Myles, and Juan C, Motamayor

Subjects

witches’ broom disease, GWAS, Theobroma cacao, Plant Science, frosty pod rot, Original Research, SNPs, genomic selection

Abstract

Cacao (Theobroma cacao) is a globally important crop, and its yield is severely restricted by disease. Two of the most damaging diseases, witches’ broom disease (WBD) and frosty pod rot disease (FPRD), are caused by a pair of related fungi: Moniliophthora perniciosa and Moniliophthora roreri, respectively. Resistant cultivars are the most effective long-term strategy to address Moniliophthora diseases, but efficiently generating resistant and productive new cultivars will require robust methods for screening germplasm before field testing. Marker-assisted selection (MAS) and genomic selection (GS) provide two potential avenues for predicting the performance of new genotypes, potentially increasing the selection gain per unit time. To test the effectiveness of these two approaches, we performed a genome-wide association study (GWAS) and GS on three related populations of cacao in Ecuador genotyped with a 15K single nucleotide polymorphism (SNP) microarray for three measures of WBD infection (vegetative broom, cushion broom, and chirimoya pod), one of FPRD (monilia pod) and two productivity traits (total fresh weight of pods and % healthy pods produced). GWAS yielded several SNPs associated with disease resistance in each population, but none were significantly correlated with the same trait in other populations. Genomic selection, using one population as a training set to estimate the phenotypes of the remaining two (composed of different families), varied among traits, from a mean prediction accuracy of 0.46 (vegetative broom) to 0.15 (monilia pod), and varied between training populations. Simulations demonstrated that selecting seedlings using GWAS markers alone generates no improvement over selecting at random, but that GS improves the selection process significantly. Our results suggest that the GWAS markers discovered here are not sufficiently predictive across diverse germplasm to be useful for MAS, but that using all markers in a GS framework holds substantial promise in accelerating disease-resistance in cacao.

Published

2017

6. Exploiting Wild Relatives for Genomics-assisted Breeding of Perennial Crops

Author

Zoë Migicovsky and Sean Myles

Subjects

0106 biological sciences, 0301 basic medicine, Germplasm, linkage mapping, Introgression, Genomics, Plant Science, Review, Biology, 01 natural sciences, marker-assisted selection, crop wild relatives, 03 medical and health sciences, Plant breeding, Domestication, association mapping, genomics-assisted breeding, Selection (genetic algorithm), 2. Zero hunger, Genetic diversity, business.industry, food and beverages, Marker-assisted selection, Biotechnology, 030104 developmental biology, business, perennials, 010606 plant biology & botany

Abstract

Perennial crops are vital contributors to global food production and nutrition. However, the breeding of new perennial crops is an expensive and time-consuming process due to the large size and lengthy juvenile phase of many species. Genomics provides a valuable tool for improving the efficiency of breeding by allowing progeny possessing a trait of interest to be selected at the seed or seedling stage through marker-assisted selection (MAS). The benefits of MAS to a breeder are greatest when the targeted species takes a long time to reach maturity and is expensive to grow and maintain. Thus, MAS holds particular promise in perennials since they are often costly and time-consuming to grow to maturity and evaluate. Well-characterized germplasm that breeders can tap into for improving perennials is often limited in genetic diversity. Wild relatives are a largely untapped source of desirable traits including disease resistance, fruit quality, and rootstock characteristics. This review focuses on the use of genomics-assisted breeding in perennials, especially as it relates to the introgression of useful traits from wild relatives. The identification of genetic markers predictive of beneficial phenotypes derived from wild relatives is hampered by genomic tools designed for domesticated species that are often ill-suited for use in wild relatives. There is therefore an urgent need for better genomic resources from wild relatives. A further barrier to exploiting wild diversity through genomics is the phenotyping bottleneck: well-powered genetic mapping requires accurate and cost-effective characterization of large collections of diverse wild germplasm. While genomics will always be used in combination with traditional breeding methods, it is a powerful tool for accelerating the speed and reducing the costs of breeding while harvesting the potential of wild relatives for improving perennial crops.

Published

2017

7. Epigenetic modifications during angiosperm gametogenesis

Author

Zoë Migicovsky and Igor Kovalchuk

Subjects

Genetics, Cell division, Histone Modifications, epigenetic modifications, food and beverages, Embryo, Review Article, Plant Science, Biology, DNA Methylation, lcsh:Plant culture, Sperm, Germline, Genomic Imprinting, transposon reactivation, male and female gametes, DNA methylation, plant gametogenesis, lcsh:SB1-1110, Epigenetics, Genomic imprinting, Gametogenesis

Abstract

Angiosperms do not contain a distinct germline, but rather develop gametes from gametophyte initials that undergo cell division. These gametes contain cells that give rise to an endosperm and the embryo. DNA methylation is decreased in the vegetative nucleus (VN) and central cell nucleus (CCN) resulting in expression of transposable elements (TEs). It is thought that the siRNAs produced in response to TE expression are able to travel to the sperm cells and egg cells from VN and CCN, respectively, in order to enforce silencing there. Plant gene imprinting occurs as a result of the difference in TE expression between paternal (silent) and maternal (expressed) genomes in the endosperm. Demethylation during gametogenesis helps ensure that even newly integrated TEs are expressed and therefore silenced by the resulting siRNA production. A final form of epigenetic control is modification of histones, which includes accumulation of the H3 variant HTR10 in mature sperm that is then completely replaced following fertilization. In females, the histone isoforms present in the egg cell and CCN differ, potentially helping to differentiate the two components during gametogenesis. The histone dimorphism between cells is eliminated in both males and females following fertilization, likely preventing these newly acquired epigenetic marks from being transmitted to progeny.

Published

2012

8. Transgenerational Adaptation to Heavy Metal Salts in Arabidopsis

Author

Zoë Migicovsky, Igor Kovalchuk, Viktor Titov, and Mohammad Reza Rahavi

Subjects

Abiotic component, biology, stress tolerance, transgenerational response, Arabidopsis thaliana, fungi, Plant physiology, food and beverages, heavy metal salts, homologous recombination, Plant Science, lcsh:Plant culture, Biotic stress, biology.organism_classification, Acclimatization, Arabidopsis, Botany, lcsh:SB1-1110, Homologous recombination, Recombination, Original Research

Abstract

Exposure to abiotic and biotic stress results in changes in plant physiology and triggers genomic instability. Recent reports suggest that the progeny of stressed plants also exhibit changes in genome stability, stress tolerance, and methylation. Here we analyzed whether exposure to Ni(2+), Cd(2+), and Cu(2+) salts leads to transgenerational changes in homologous recombination frequency and stress tolerance. We found that the immediate progeny of stressed plants exhibited an increased rate of recombination. However, when the progeny of stressed plants was propagated without stress, recombination reverted to normal levels. Exposure of plants to heavy metals for five consecutive generations (S1-S5) resulted in recombination frequency being maintained at a high level. Skipping stress following two to three generations of propagation with 50 mM Ni(2+) or Cd(2+) did not decrease the recombination frequency, suggesting plant acclimation to upregulated recombination. Analysis of the progeny of plants exposed to Cu(2+) and Ni(2+) indicated higher stress tolerance to the heavy metal parental plants were exposed to. Tolerance was higher in plants propagated with stress for three to five generations, which resulted in longer roots than plants propagated on heavy metals for only one to two generations. Tolerance was also more prominent upon exposure to a higher concentration of salts. The progeny of stressed plants were also more tolerant to NaCl and methyl methane sulfonate.

Published

2011