Your search keyword '"Anne Lorant"' showing total 28 results

1. Dual inhibition of sirtuins 1 and 2: reprogramming metabolic energy dynamics in chronic myeloid leukemia as an immunogenic anticancer strategy

Author

Michael Schnekenburger, Anne Lorant, Sruthi Reddy Gajulapalli, Ridhika Rajora, Jin‐Young Lee, Aloran Mazumder, Haeun Yang, Christo Christov, Hyoung Jin Kang, Bernard Pirotte, and Marc Diederich

Subjects

Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Published

2024

2. Antileukemic potential of methylated indolequinone MAC681 through immunogenic necroptosis and PARP1 degradation

Author

Barbora Orlikova-Boyer, Anne Lorant, Sruthi Reddy Gajulapalli, Claudia Cerella, Michael Schnekenburger, Jin-Young Lee, Ji Yeon Paik, Yejin Lee, David Siegel, David Ross, Byung Woo Han, Thi Kim Yen Nguyen, Christo Christov, Hyoung Jin Kang, Mario Dicato, and Marc Diederich

Subjects

Indolequinone, NAD, PARP1, OXPHOS, Chronic myeloid leukemia, Necrosis, Therapeutics. Pharmacology, RM1-950

Abstract

Abstract Background Despite advancements in chronic myeloid leukemia (CML) therapy with tyrosine kinase inhibitors (TKIs), resistance and intolerance remain significant challenges. Leukemia stem cells (LSCs) and TKI-resistant cells rely on altered mitochondrial metabolism and oxidative phosphorylation. Targeting rewired energy metabolism and inducing non-apoptotic cell death, along with the release of damage-associated molecular patterns (DAMPs), can enhance therapeutic strategies and immunogenic therapies against CML and prevent the emergence of TKI-resistant cells and LSC persistence. Methods Transcriptomic analysis was conducted using datasets of CML patients' stem cells and healthy cells. DNA damage was evaluated by fluorescent microscopy and flow cytometry. Cell death was assessed by trypan blue exclusion test, fluorescent microscopy, flow cytometry, colony formation assay, and in vivo Zebrafish xenografts. Energy metabolism was determined by measuring NAD+ and NADH levels, ATP production rate by Seahorse analyzer, and intracellular ATP content. Mitochondrial fitness was estimated by measurements of mitochondrial membrane potential, ROS, and calcium accumulation by flow cytometry, and morphology was visualized by TEM. Bioinformatic analysis, real-time qPCR, western blotting, chemical reaction prediction, and molecular docking were utilized to identify the drug target. The immunogenic potential was assessed by high mobility group box (HMGB)1 ELISA assay, luciferase-based extracellular ATP assay, ectopic calreticulin expression by flow cytometry, and validated by phagocytosis assay, and in vivo vaccination assay using syngeneic C57BL/6 mice. Results Transcriptomic analysis identified metabolic alterations and DNA repair deficiency signatures in CML patients. CML patients exhibited enrichment in immune system, DNA repair, and metabolic pathways. The gene signature associated with BRCA mutated tumors was enriched in CML datasets, suggesting a deficiency in double-strand break repair pathways. Additionally, poly(ADP-ribose) polymerase (PARP)1 was significantly upregulated in CML patients’ stem cells compared to healthy counterparts. Consistent with the CML patient DNA repair signature, treatment with the methylated indolequinone MAC681 induced DNA damage, mitochondrial dysfunction, calcium homeostasis disruption, metabolic catastrophe, and necroptotic-like cell death. In parallel, MAC681 led to PARP1 degradation that was prevented by 3-aminobenzamide. MAC681-treated myeloid leukemia cells released DAMPs and demonstrated the potential to generate an immunogenic vaccine in C57BL/6 mice. MAC681 and asciminib exhibited synergistic effects in killing both imatinib-sensitive and -resistant CML, opening new therapeutic opportunities. Conclusions Overall, increasing the tumor mutational burden by PARP1 degradation and mitochondrial deregulation makes CML suitable for immunotherapy.

Published

2024

3. HDAC6 inhibitors sensitize resistant t(11;14) multiple myeloma cells to a combination of bortezomib and BH3 mimetics

Author

Cristina Florean, Manon Lernoux, Anne Lorant, Helene Losson, Guy Bormans, Michael Schnekenburger, and Marc Diederich

Subjects

Diseases of the blood and blood-forming organs, RC633-647.5

Abstract

Not available.

Published

2024

4. Editorial: Next-Generation Cancer Therapies Based on a (R)evolution of the Biomarker Landscape

Author

Claudia Cerella, Anne Lorant, Katia Aquilano, and Marc Diederich

Subjects

cancer biomarkers, precision oncology, targeted agents, immunotherapy, therapy response prediction, Therapeutics. Pharmacology, RM1-950

Published

2022

5. Selective sorting of ancestral introgression in maize and teosinte along an elevational cline.

Author

Erin Calfee, Daniel Gates, Anne Lorant, M Taylor Perkins, Graham Coop, and Jeffrey Ross-Ibarra

Subjects

Genetics, QH426-470

Abstract

While often deleterious, hybridization can also be a key source of genetic variation and pre-adapted haplotypes, enabling rapid evolution and niche expansion. Here we evaluate these opposing selection forces on introgressed ancestry between maize (Zea mays ssp. mays) and its wild teosinte relative, mexicana (Zea mays ssp. mexicana). Introgression from ecologically diverse teosinte may have facilitated maize's global range expansion, in particular to challenging high elevation regions (> 1500 m). We generated low-coverage genome sequencing data for 348 maize and mexicana individuals to evaluate patterns of introgression in 14 sympatric population pairs, spanning the elevational range of mexicana, a teosinte endemic to the mountains of Mexico. While recent hybrids are commonly observed in sympatric populations and mexicana demonstrates fine-scale local adaptation, we find that the majority of mexicana ancestry tracts introgressed into maize over 1000 generations ago. This mexicana ancestry seems to have maintained much of its diversity and likely came from a common ancestral source, rather than contemporary sympatric populations, resulting in relatively low FST between mexicana ancestry tracts sampled from geographically distant maize populations. Introgressed mexicana ancestry in maize is reduced in lower-recombination rate quintiles of the genome and around domestication genes, consistent with pervasive selection against introgression. However, we also find mexicana ancestry increases across the sampled elevational gradient and that high introgression peaks are most commonly shared among high-elevation maize populations, consistent with introgression from mexicana facilitating adaptation to the highland environment. In the other direction, we find patterns consistent with adaptive and clinal introgression of maize ancestry into sympatric mexicana at many loci across the genome, suggesting that maize also contributes to adaptation in mexicana, especially at the lower end of its elevational range. In sympatric maize, in addition to high introgression regions we find many genomic regions where selection for local adaptation maintains steep gradients in introgressed mexicana ancestry across elevation, including at least two inversions: the well-characterized 14 Mb Inv4m on chromosome 4 and a novel 3 Mb inversion Inv9f surrounding the macrohairless1 locus on chromosome 9. Most outlier loci with high mexicana introgression show no signals of sweeps or local sourcing from sympatric populations and so likely represent ancestral introgression sorted by selection, resulting in correlated but distinct outcomes of introgression in different contemporary maize populations.

Published

2021

6. The genetic architecture of the maize progenitor, teosinte, and how it was altered during maize domestication.

Author

Qiuyue Chen, Luis Fernando Samayoa, Chin Jian Yang, Peter J Bradbury, Bode A Olukolu, Michael A Neumeyer, Maria Cinta Romay, Qi Sun, Anne Lorant, Edward S Buckler, Jeffrey Ross-Ibarra, James B Holland, and John F Doebley

Subjects

Genetics, QH426-470

Abstract

The genetics of domestication has been extensively studied ever since the rediscovery of Mendel's law of inheritance and much has been learned about the genetic control of trait differences between crops and their ancestors. Here, we ask how domestication has altered genetic architecture by comparing the genetic architecture of 18 domestication traits in maize and its ancestor teosinte using matched populations. We observed a strongly reduced number of QTL for domestication traits in maize relative to teosinte, which is consistent with the previously reported depletion of additive variance by selection during domestication. We also observed more dominance in maize than teosinte, likely a consequence of selective removal of additive variants. We observed that large effect QTL have low minor allele frequency (MAF) in both maize and teosinte. Regions of the genome that are strongly differentiated between teosinte and maize (high FST) explain less quantitative variation in maize than teosinte, suggesting that, in these regions, allelic variants were brought to (or near) fixation during domestication. We also observed that genomic regions of high recombination explain a disproportionately large proportion of heritable variance both before and after domestication. Finally, we observed that about 75% of the additive variance in both teosinte and maize is "missing" in the sense that it cannot be ascribed to detectable QTL and only 25% of variance maps to specific QTL. This latter result suggests that morphological evolution during domestication is largely attributable to very large numbers of QTL of very small effect.

Published

2020

7. Genome Synteny Has Been Conserved Among the Octoploid Progenitors of Cultivated Strawberry Over Millions of Years of Evolution

Author

Michael A. Hardigan, Mitchell J. Feldmann, Anne Lorant, Kevin A. Bird, Randi Famula, Charlotte Acharya, Glenn Cole, Patrick P. Edger, and Steven J. Knapp

Subjects

Fragaria, strawberry, polyploidy, genome evolution, domestication, Plant culture, SB1-1110

Abstract

Allo-octoploid cultivated strawberry (Fragaria × ananassa) originated through a combination of polyploid and homoploid hybridization, domestication of an interspecific hybrid lineage, and continued admixture of wild species over the last 300 years. While genes appear to flow freely between the octoploid progenitors, the genome structures and diversity of the octoploid species remain poorly understood. The complexity and absence of an octoploid genome frustrated early efforts to study chromosome evolution, resolve subgenomic structure, and develop a single coherent linkage group nomenclature. Here, we show that octoploid Fragaria species harbor millions of subgenome-specific DNA variants. Their diversity was sufficient to distinguish duplicated (homoeologous and paralogous) DNA sequences and develop 50K and 850K SNP genotyping arrays populated with co-dominant, disomic SNP markers distributed throughout the octoploid genome. Whole-genome shotgun genotyping of an interspecific segregating population yielded 1.9M genetically mapped subgenome variants in 5,521 haploblocks spanning 3,394 cM in F. chiloensis subsp. lucida, and 1.6M genetically mapped subgenome variants in 3,179 haploblocks spanning 2,017 cM in F. × ananassa. These studies provide a dense genomic framework of subgenome-specific DNA markers for seamlessly cross-referencing genetic and physical mapping information and unifying existing chromosome nomenclatures. Using comparative genomics, we show that geographically diverse wild octoploids are effectively diploidized, nearly completely collinear, and retain strong macro-synteny with diploid progenitor species. The preservation of genome structure among allo-octoploid taxa is a critical factor in the unique history of garden strawberry, where unimpeded gene flow supported its origin and domestication through repeated cycles of interspecific hybridization.

Published

2020

8. The interplay of demography and selection during maize domestication and expansion

Author

Li Wang, Timothy M. Beissinger, Anne Lorant, Claudia Ross-Ibarra, Jeffrey Ross-Ibarra, and Matthew B. Hufford

Subjects

Demography, Domestication, Genetic load, Maize, Biology (General), QH301-705.5, Genetics, QH426-470

Abstract

Abstract Background The history of maize has been characterized by major demographic events, including population size changes associated with domestication and range expansion, and gene flow with wild relatives. The interplay between demographic history and selection has shaped diversity across maize populations and genomes. Results We investigate these processes using high-depth resequencing data from 31 maize landraces spanning the pre-Columbian distribution of maize, and four wild teosinte individuals (Zea mays ssp. parviglumis). Genome-wide demographic analyses reveal that maize experienced pronounced declines in effective population size due to both a protracted domestication bottleneck and serial founder effects during post-domestication spread, while parviglumis in the Balsas River Valley experienced population growth. The domestication bottleneck and subsequent spread led to an increase in deleterious alleles in the domesticate compared to the wild progenitor. This cost is particularly pronounced in Andean maize, which has experienced a more dramatic founder event compared to other maize populations. Additionally, we detect introgression from the wild teosinte Zea mays ssp. mexicana into maize in the highlands of Mexico, Guatemala, and the southwestern USA, which reduces the prevalence of deleterious alleles likely due to the higher long-term effective population size of teosinte. Conclusions These findings underscore the strong interaction between historical demography and the efficiency of selection and illustrate how domesticated species are particularly useful for understanding these processes. The landscape of deleterious alleles and therefore evolutionary potential is clearly influenced by recent demography, a factor that could bear importantly on many species that have experienced recent demographic shifts.

Published

2017

9. Parallel altitudinal clines reveal trends in adaptive evolution of genome size in Zea mays.

Author

Paul Bilinski, Patrice S Albert, Jeremy J Berg, James A Birchler, Mark N Grote, Anne Lorant, Juvenal Quezada, Kelly Swarts, Jinliang Yang, and Jeffrey Ross-Ibarra

Subjects

Genetics, QH426-470

Abstract

While the vast majority of genome size variation in plants is due to differences in repetitive sequence, we know little about how selection acts on repeat content in natural populations. Here we investigate parallel changes in intraspecific genome size and repeat content of domesticated maize (Zea mays) landraces and their wild relative teosinte across altitudinal gradients in Mesoamerica and South America. We combine genotyping, low coverage whole-genome sequence data, and flow cytometry to test for evidence of selection on genome size and individual repeat abundance. We find that population structure alone cannot explain the observed variation, implying that clinal patterns of genome size are maintained by natural selection. Our modeling additionally provides evidence of selection on individual heterochromatic knob repeats, likely due to their large individual contribution to genome size. To better understand the phenotypes driving selection on genome size, we conducted a growth chamber experiment using a population of highland teosinte exhibiting extensive variation in genome size. We find weak support for a positive correlation between genome size and cell size, but stronger support for a negative correlation between genome size and the rate of cell production. Reanalyzing published data of cell counts in maize shoot apical meristems, we then identify a negative correlation between cell production rate and flowering time. Together, our data suggest a model in which variation in genome size is driven by natural selection on flowering time across altitudinal clines, connecting intraspecific variation in repetitive sequence to important differences in adaptive phenotypes.

Published

2018

10. The potential role of genetic assimilation during maize domestication.

Author

Anne Lorant, Sarah Pedersen, Irene Holst, Matthew B Hufford, Klaus Winter, Dolores Piperno, and Jeffrey Ross-Ibarra

Subjects

Medicine, Science

Abstract

Domestication research has largely focused on identification of morphological and genetic differences between extant populations of crops and their wild relatives. Little attention has been paid to the potential effects of environment despite substantial known changes in climate from the time of domestication to modern day. In recent research, the exposure of teosinte (i.e., wild maize) to environments similar to the time of domestication, resulted in a plastic induction of domesticated phenotypes in teosinte. These results suggest that early agriculturalists may have selected for genetic mechanisms that cemented domestication phenotypes initially induced by a plastic response of teosinte to environment, a process known as genetic assimilation. To better understand this phenomenon and the potential role of environment in maize domestication, we examined differential gene expression in maize (Zea mays ssp. mays) and teosinte (Zea mays ssp. parviglumis) between past and present conditions. We identified a gene set of over 2000 loci showing a change in expression across environmental conditions in teosinte and invariance in maize. In fact, overall we observed both greater plasticity in gene expression and more substantial changes in co-expressionnal networks in teosinte across environments when compared to maize. While these results suggest genetic assimilation played at least some role in domestication, genes showing expression patterns consistent with assimilation are not significantly enriched for previously identified domestication candidates, indicating assimilation did not have a genome-wide effect.

Published

2017

11. Genomic abundance is not predictive of tandem repeat localization in grass genomes.

Author

Paul Bilinski, Yonghua Han, Matthew B Hufford, Anne Lorant, Pingdong Zhang, Matt C Estep, Jiming Jiang, and Jeffrey Ross-Ibarra

Subjects

Medicine, Science

Abstract

Highly repetitive regions have historically posed a challenge when investigating sequence variation and content. High-throughput sequencing has enabled researchers to use whole-genome shotgun sequencing to estimate the abundance of repetitive sequence, and these methodologies have been recently applied to centromeres. Previous research has investigated variation in centromere repeats across eukaryotes, positing that the highest abundance tandem repeat in a genome is often the centromeric repeat. To test this assumption, we used shotgun sequencing and a bioinformatic pipeline to identify common tandem repeats across a number of grass species. We find that de novo assembly and subsequent abundance ranking of repeats can successfully identify tandem repeats with homology to known tandem repeats. Fluorescent in-situ hybridization shows that de novo assembly and ranking of repeats from non-model taxa identifies chromosome domains rich in tandem repeats both near pericentromeres and elsewhere in the genome.

Published

2017

12. Male Linked Genomic Region Determines Sex in Dioecious Amaranthus palmeri

Author

Mohsen B. Mesgaran, Markus G Stetter, Maor Matzrafi, Cátia José Neves, Meik Thiele, Anne Lorant, and Wilson, Melissa

Subjects

AcademicSubjects/SCI01140, 0106 biological sciences, 0301 basic medicine, Evolution of sexual reproduction, Evolution, Dioecy, Jhered/3, Y chromosome, 01 natural sciences, Chromosomes, Chromosomes, Plant, Evolution, Molecular, 03 medical and health sciences, Gene Frequency, Genetics, Plant reproductive morphology, sex chromosome, Molecular Biology, Allele frequency, Alleles, Plant Physiological Phenomena, Genetics (clinical), Whole genome sequencing, Evolutionary Biology, Genome, Amaranthus, Sex Chromosomes, biology, Human Genome, Molecular, Plant, Original Articles, Sex Determination Processes, biology.organism_classification, dioecy, Amaranthus palmeri, 030104 developmental biology, invasive weed, Evolutionary biology, Ploidy, Genome, Plant, 010606 plant biology & botany, Biotechnology

Abstract

Dioecy, the separation of reproductive organs on different individuals, has evolved repeatedly in different plant families. Several evolutionary paths to dioecy have been suggested, but the mechanisms behind sex determination is not well understood. The diploid dioecious Amaranthus palmeri represents a well-suited model system to study sex determination in plants. Despite the agricultural importance of the species, the genetic control and evolutionary state of dioecy in A. palmeri is currently unknown. Early cytogenetic experiments did not identify heteromorphic chromosomes. Here, we used whole-genome sequencing of male and female pools from 2 independent populations to elucidate the genetic control of dioecy in A. palmeri. Read alignment to a close monoecious relative and allele frequency comparisons between male and female pools did not reveal significant sex-linked genes. Consequently, we employed an alignment-free k-mer comparison which enabled us to identify a large number of male-specific k-mers. We assembled male-specific contigs comprising a total of almost 2 Mb sequence, proposing a XY sex-determination system in the species. We were able to identify the potential Y chromosome in the A. palmeri draft genome sequence as 90% of our male-specific sequence aligned to a single scaffold. Based on our findings, we suggest an intermediate evolutionary state of dioecy with a young Y chromosome in A. palmeri. Our findings give insight into the evolution of sex chromosomes in plants and may help to develop sustainable strategies for weed management.

Published

2020

13. Selective sorting of ancestral introgression in maize and teosinte along an elevational cline

Author

Graham Coop, M. Taylor Perkins, Jeffrey Ross-Ibarra, Erin Calfee, Anne Lorant, Daniel J. Gates, and Mauricio, Rodney

Subjects

Cancer Research, Heredity, Introgression, Single Nucleotide Polymorphisms, Plant Science, QH426-470, Plant Genetics, Gene flow, Plant Genomics, skin and connective tissue diseases, Genetics (clinical), education.field_of_study, Genome, Eukaryota, Chromosome Mapping, Genomics, Cline (biology), Plants, Adaptation, Physiological, Experimental Organism Systems, Sympatric speciation, Engineering and Technology, Genome, Plant, Research Article, Biotechnology, Gene Flow, Evolutionary Processes, Physiological, Population, Bioengineering, Biology, Research and Analysis Methods, Zea mays, Model Organisms, Genetic, Plant and Algal Models, parasitic diseases, Genetics, Animals, Domestic Animals, Grasses, Adaptation, education, Domestication, Hybridization, Mexico, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Local adaptation, Hybrid, Evolutionary Biology, Population Biology, Human Genome, Organisms, Biology and Life Sciences, Plant, Maize, Haplotypes, Genetic Loci, Evolutionary biology, Chromosome Inversion, Animal Studies, Hybridization, Genetic, Plant Biotechnology, Generic health relevance, Zoology, Population Genetics, Developmental Biology

Abstract

While often deleterious, hybridization can also be a key source of genetic variation and pre-adapted haplotypes, enabling rapid evolution and niche expansion. Here we evaluate these opposing selection forces on introgressed ancestry between maize (Zea mays ssp. mays) and its wild teosinte relative, mexicana (Zea mays ssp. mexicana). Introgression from ecologically diverse teosinte may have facilitated maize’s global range expansion, in particular to challenging high elevation regions (> 1500 m). We generated low-coverage genome sequencing data for 348 maize and mexicana individuals to evaluate patterns of introgression in 14 sympatric population pairs, spanning the elevational range of mexicana, a teosinte endemic to the mountains of Mexico. While recent hybrids are commonly observed in sympatric populations and mexicana demonstrates fine-scale local adaptation, we find that the majority of mexicana ancestry tracts introgressed into maize over 1000 generations ago. This mexicana ancestry seems to have maintained much of its diversity and likely came from a common ancestral source, rather than contemporary sympatric populations, resulting in relatively low FST between mexicana ancestry tracts sampled from geographically distant maize populations. Introgressed mexicana ancestry in maize is reduced in lower-recombination rate quintiles of the genome and around domestication genes, consistent with pervasive selection against introgression. However, we also find mexicana ancestry increases across the sampled elevational gradient and that high introgression peaks are most commonly shared among high-elevation maize populations, consistent with introgression from mexicana facilitating adaptation to the highland environment. In the other direction, we find patterns consistent with adaptive and clinal introgression of maize ancestry into sympatric mexicana at many loci across the genome, suggesting that maize also contributes to adaptation in mexicana, especially at the lower end of its elevational range. In sympatric maize, in addition to high introgression regions we find many genomic regions where selection for local adaptation maintains steep gradients in introgressed mexicana ancestry across elevation, including at least two inversions: the well-characterized 14 Mb Inv4m on chromosome 4 and a novel 3 Mb inversion Inv9f surrounding the macrohairless1 locus on chromosome 9. Most outlier loci with high mexicana introgression show no signals of sweeps or local sourcing from sympatric populations and so likely represent ancestral introgression sorted by selection, resulting in correlated but distinct outcomes of introgression in different contemporary maize populations., Author summary When species expand their ranges, new encounters with diverse wild relatives can introduce deleterious genetic variation, but may also accelerate the colonization of novel environments by providing ‘ready-made’ genetic adaptations. Maize today is a global staple, far exceeding the original ecological niche of its wild progenitor. We show that gene flow from highland-endemic wild mexicana facilitated maize’s range expansion from the valleys where it was domesticated to sites over 1500m in the mountains of Mexico. We find loci where mexicana ancestry has been repeatedly favored in highland maize populations. We also find loci (including a newly identified inversion) where mexicana ancestry increases steeply with elevation, providing evidence for adaptive trade-offs. We additionally demonstrate selection against mexicana ancestry, especially near domestication genes. We sampled mexicana growing alongside maize fields, yet find little evidence that introgression is recent or locally-sourced genomewide or at adaptive loci. Rather, the majority of mexicana ancestry was introduced into maize over 1000 generations ago, and subsequently diverged and was sorted by selection in individual populations. These results add to our understanding of the effects of introgression on range expansions and adaptation.

Published

2021

14. Not so local: the population genetics of convergent adaptation in maize and teosinte

Author

José de Jesús Sánchez-González, James B. Holland, Sean McGinty, Arun S. Seetharam, Maud I. Tenaillon, Silas Tittes, John Doebley, Jeffrey Ross-Ibarra, and Anne Lorant

Subjects

education.field_of_study, Sympatric speciation, Evolutionary biology, Population, Population genetics, Subspecies, Biology, Adaptation, education, Domestication, Genetic architecture, Local adaptation

Abstract

What is the genetic architecture of local adaptation and what is the geographic scale that it operates over? We investigated patterns of local and convergent adaptation in five sympatric population pairs of traditionally cultivated maize and its wild relative teosinte (Zea mayssubsp.parviglumis). We found that signatures of local adaptation based on the inference of adaptive fixations and selective sweeps are frequently exclusive to individual populations, more so in teosinte compared to maize. However, for both maize and teosinte, selective sweeps are frequently shared by several populations, and often between the subspecies. We were further able to infer that selective sweeps were shared among populations most often via migration, though sharing via standing variation was also common. Our analyses suggest that teosinte has been a continued source of beneficial alleles for maize, post domestication, and that maize populations have facilitated adaptation in teosinte by moving beneficial alleles across the landscape. Taken together, out results suggest local adaptation in maize and teosinte has an intermediate geographic scale, one that is larger than individual populations, but smaller than the species range.

Published

2021

15. Selective sorting of ancestral introgression in maize and teosinte along an elevational cline

Author

M. Taylor Perkins, Erin Calfee, Graham Coop, Anne Lorant, Daniel J. Gates, and Jeffrey Ross-Ibarra

Subjects

education.field_of_study, Sympatric speciation, Evolutionary biology, Population, Introgression, Cline (biology), Biology, Domestication, education, Local adaptation, Hybrid, Gene flow

Abstract

While often deleterious, hybridization can also be a key source of genetic variation and pre-adapted haplotypes, enabling rapid evolution and niche expansion. Here we evaluate these opposing selection forces on introgressed ancestry between maize (Zea mays ssp. mays) and its wild teosinte relative, mexicana (Zea mays ssp. mexicana). Introgression from ecologically diverse teosinte may have facilitated maize’s global range expansion, in particular to challenging high elevation regions (> 1500 m). We generated low-coverage genome sequencing data for 348 maize and mexicana individuals to evaluate patterns of introgression in 14 sympatric population pairs, spanning the elevational range of mexicana, a teosinte endemic to the mountains of Mexico. While recent hybrids are commonly observed in sympatric populations and mexicana demonstrates fine-scale local adaptation, we find that the majority of mexicana ancestry tracts introgressed into maize over 1000 generations ago. This mexicana ancestry seems to have maintained much of its diversity and likely came from a common ancestral source, rather than contemporary sympatric populations, resulting in relatively low FSTbetween mexicana ancestry tracts sampled from geographically distant maize populations.Introgressed mexicana ancestry in maize is reduced in lower-recombination rate quintiles of the genome and around domestication genes, consistent with pervasive selection against introgression. However, we also find mexicana ancestry increases across the sampled elevational gradient and that high introgression peaks are most commonly shared among high-elevation maize populations, consistent with introgression from mexicana facilitating adaptation to the highland environment. In the other direction, we find patterns consistent with adaptive and clinal introgression of maize ancestry into sympatric mexicana at many loci across the genome, suggesting that maize also contributes to adaptation in mexicana, especially at the lower end of its elevational range. In sympatric maize, in addition to high introgression regions we find many genomic regions where selection for local adaptation maintains steep gradients in introgressed mexicana ancestry across elevation, including at least two inversions: the well-characterized 14 Mb Inv4m on chromosome 4 and a novel 3 Mb inversion Inv9f surrounding the macrohairless1 locus on chromosome 9. Most outlier loci with high mexicana introgression show no signals of sweeps or local sourcing from sympatric populations and so likely represent ancestral introgression sorted by selection, resulting in correlated but distinct outcomes of introgression in different contemporary maize populations.Author SummaryWhen species expand their ranges, new encounters with diverse wild relatives can introduce deleterious genetic variation, but may also accelerate the colonization of novel environments by providing ‘ready-made’ genetic adaptations. Maize today is a global staple, far exceeding the original ecological niche of its wild progenitor. We show that gene flow from highland-endemic wild mexicana facilitated maize’s range expansion from the valleys where it was domesticated to sites over 1500m in the mountains of Mexico. We find loci where mexicana ancestry has been repeatedly favored in highland maize populations. We also find loci (including a newly identified inversion) where mexicana ancestry increases steeply with elevation, providing evidence for adaptive trade-offs.We additionally demonstrate selection against mexicana ancestry, especially near domestication genes. We sampled mexicana growing alongside maize fields, yet find little evidence that introgression is recent or locally-sourced genomewide or at adaptive loci. Rather, the majority of mexicana ancestry was introduced into maize over 1000 generations ago, and subsequently diverged and was sorted by selection in individual populations. These results add to our understanding of the effects of introgression on range expansions and adaptation.

Published

2021

16. Unraveling the Complex Hybrid Ancestry and Domestication History of Cultivated Strawberry

Author

Vance M. Whitaker, Mitchell J. Feldmann, Patrick P. Edger, Nahla V. Bassil, Jason D. Zurn, Steven J. Knapp, Anne Lorant, Randi A. Famula, Dominique D A Pincot, Charlotte B. Acharya, Kevin A. Bird, Seonghee Lee, Sujeet Verma, Glenn S. Cole, Michael A. Hardigan, and Purugganan, Michael

Subjects

0106 biological sciences, selection, genome evolution, Biology, AcademicSubjects/SCI01180, nucleotide diversity, Fragaria, 01 natural sciences, Chromosomes, Plant, Chromosomes, Linkage Disequilibrium, Nucleotide diversity, Polyploidy, Domestication, Loss of heterozygosity, 03 medical and health sciences, Genetic, Polyploid, Botany, Genetics, Selection, Genetic, Hybridization, Molecular Biology, Discoveries, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Hybrid, Evolutionary Biology, 0303 health sciences, Genetic diversity, Genome, Human Genome, AcademicSubjects/SCI01130, polyploid, Genetic Variation, Plant, biology.organism_classification, Hybridization, Genetic, Biochemistry and Cell Biology, Fragaria virginiana, Genome, Plant, 010606 plant biology & botany

Abstract

Cultivated strawberry (Fragaria × ananassa) is one of our youngest domesticates, originating in early eighteenth-century Europe from spontaneous hybrids between wild allo-octoploid species (Fragaria chiloensis and Fragaria virginiana). The improvement of horticultural traits by 300 years of breeding has enabled the global expansion of strawberry production. Here, we describe the genomic history of strawberry domestication from the earliest hybrids to modern cultivars. We observed a significant increase in heterozygosity among interspecific hybrids and a decrease in heterozygosity among domesticated descendants of those hybrids. Selective sweeps were found across the genome in early and modern phases of domestication—59–76% of the selectively swept genes originated in the three less dominant ancestral subgenomes. Contrary to the tenet that genetic diversity is limited in cultivated strawberry, we found that the octoploid species harbor massive allelic diversity and that F. × ananassa harbors as much allelic diversity as either wild founder. We identified 41.8 M subgenome-specific DNA variants among resequenced wild and domesticated individuals. Strikingly, 98% of common alleles and 73% of total alleles were shared between wild and domesticated populations. Moreover, genome-wide estimates of nucleotide diversity were virtually identical in F. chiloensis,F. virginiana, and F. × ananassa (π = 0.0059–0.0060). We found, however, that nucleotide diversity and heterozygosity were significantly lower in modern F. × ananassa populations that have experienced significant genetic gains and have produced numerous agriculturally important cultivars.

Published

2021

17. Male linked genomic regions determine sex in dioecious Amaranthus palmeri

Author

Cátia José Neves, Markus G Stetter, Mohsen B. Mesgaran, Meik Thiele, Maor Matzrafi, and Anne Lorant

Subjects

Amaranthus palmeri, Whole genome sequencing, biology, Evolution of sexual reproduction, Evolutionary biology, Dioecy, Plant reproductive morphology, Ploidy, XY sex-determination system, biology.organism_classification, Sex linkage

Abstract

Dioecy, the separation of reproductive organs on different individuals, has evolved repeatedly in different plant families. Several evolutionary paths to dioecy have been suggested, but the mechanisms behind sex determination is not well understood. The diploid dioecious Amaranthus palmeri represents a well suited model system to study sex determination in plants. A. palmeri is one of the most troublesome weeds in the US, has successfully colonized other regions in the world and has evolved resistance to several herbicide classes. Despite the agricultural importance of the species, the genetic control and evolutionary state of dioecy in A. palmeri is currently unknown. Early cytogenetic experiments did not identify heteromorphic chromosomes. Here, we used whole genome sequencing of male and female pools from two independent populations to elucidate the genetic control of dioecy in A. palmeri. Read alignment to a close monoecious relative and allele frequency comparisons between male and female pools did not reveal significant sex linked genes. Consequently, we employed an alignment free k-mer comparison which enabled us to identify a large number of male specific k-mers. We assembled male specific contigs comprising a total of almost 2 Mb sequence, proposing a XY sex determination system in the species. Based on our findings we suggest an intermediate evolutionary state of dioecy in A. palmeri. Our findings give insight into the evolution of sex chromosomes in plants and may help to develop sustainable strategies for weed management.

Published

2020

18. The genetic architecture of the maize progenitor, teosinte, and how it was altered during maize domestication

Author

Maria Cinta Romay, Jeffrey Ross-Ibarra, Qi Sun, Bode A. Olukolu, John Doebley, Qiuyue Chen, Edward S. Buckler, Anne Lorant, Peter J. Bradbury, Michael A. Neumeyer, Chin Jian Yang, James B. Holland, Luis Fernando Samayoa, and Mauricio, Rodney

Subjects

Cancer Research, Heredity, Population genetics, Plant Science, QH426-470, Plant Genetics, Domestication, 0302 clinical medicine, Gene Frequency, Plant Genomics, Natural Selection, Genetics (clinical), 0303 health sciences, education.field_of_study, Natural selection, Eukaryota, Genomics, Plants, Experimental Organism Systems, Engineering and Technology, Research Article, Biotechnology, Gene Flow, Evolutionary Processes, Animal Types, Population, Quantitative Trait Loci, Bioengineering, Quantitative trait locus, Biology, Research and Analysis Methods, Genes, Plant, Zea mays, Quantitative Trait, 03 medical and health sciences, Model Organisms, Quantitative Trait, Heritable, Genetic, Plant and Algal Models, Genetic variation, Genetics, Animals, Domestic Animals, Grasses, Allele, Selection, Genetic, education, Heritable, Selection, Molecular Biology, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Crop Genetics, Evolutionary Biology, Population Biology, Human Genome, Organisms, Biology and Life Sciences, Genetic Variation, Plant, Genetic architecture, Maize, Genetics, Population, Genes, Evolutionary biology, Genetic Loci, Animal Studies, Plant Biotechnology, Zoology, 030217 neurology & neurosurgery, Population Genetics, Developmental Biology

Abstract

The genetics of domestication has been extensively studied ever since the rediscovery of Mendel’s law of inheritance and much has been learned about the genetic control of trait differences between crops and their ancestors. Here, we ask how domestication has altered genetic architecture by comparing the genetic architecture of 18 domestication traits in maize and its ancestor teosinte using matched populations. We observed a strongly reduced number of QTL for domestication traits in maize relative to teosinte, which is consistent with the previously reported depletion of additive variance by selection during domestication. We also observed more dominance in maize than teosinte, likely a consequence of selective removal of additive variants. We observed that large effect QTL have low minor allele frequency (MAF) in both maize and teosinte. Regions of the genome that are strongly differentiated between teosinte and maize (high FST) explain less quantitative variation in maize than teosinte, suggesting that, in these regions, allelic variants were brought to (or near) fixation during domestication. We also observed that genomic regions of high recombination explain a disproportionately large proportion of heritable variance both before and after domestication. Finally, we observed that about 75% of the additive variance in both teosinte and maize is “missing” in the sense that it cannot be ascribed to detectable QTL and only 25% of variance maps to specific QTL. This latter result suggests that morphological evolution during domestication is largely attributable to very large numbers of QTL of very small effect., Author summary Although the genetics of trait differences between crops and their progenitors has been extensively studied, far less is known about the genetic architecture of trait variation in crop progenitors and how this architecture was altered during domestication. Here, we address this issue by comparing the genetic architecture of 18 domestication traits in maize and its ancestor teosinte using matched populations. Our results show that genetic architecture was reshaped during domestication in multiple ways. Maize has a greatly reduced number of QTL for domestication traits relative to teosinte and alleles at these QTL show greater dominance in maize. QTL alleles of large effect are present in both maize and teosinte, but more common in maize. We observed that regions of the genome that are strongly differentiated between teosinte and maize (high FST) explain less additive variation in maize than teosinte and that genomic regions of high recombination explain a disproportionately large proportion of heritable variance both before and after domestication. Finally, we observed that about 75% of heritability is “missing” in the sense that it not associated with detectable QTL, which suggests that the raw material for domestication was largely composed of vast numbers of QTL of diminishingly small effects.

Published

2020

19. Dysregulation of expression correlates with rare-allele burden and fitness loss in maize

Author

Mei-Hsiu Su, M. Cinta Romay, Anne Lorant, Peter J. Bradbury, Karl A. Kremling, Kelly Swarts, Edward S. Buckler, Fei Lu, Nicholas Lepak, and Shu-Yun Chen

Subjects

Crops, Agricultural, 0301 basic medicine, Linkage disequilibrium, Genotype, Quantitative Trait Loci, Biology, Zea mays, Genome, Linkage Disequilibrium, 03 medical and health sciences, Inbred strain, Gene Expression Regulation, Plant, Genetic linkage, Allele, Alleles, Population Density, Regulation of gene expression, Genetics, Multidisciplinary, Sequence Analysis, RNA, Genetic Variation, Phenotype, 030104 developmental biology, RNA, Plant, Seeds, Expression quantitative trait loci, Genetic Fitness, Genome, Plant

Abstract

Here we report a multi-tissue gene expression resource that represents the genotypic and phenotypic diversity of modern inbred maize, and includes transcriptomes in an average of 255 lines in seven tissues. We mapped expression quantitative trait loci and characterized the contribution of rare genetic variants to extremes in gene expression. Some of the new mutations that arise in the maize genome can be deleterious; although selection acts to keep deleterious variants rare, their complete removal is impeded by genetic linkage to favourable loci and by finite population size. Modern maize breeders have systematically reduced the effects of this constant mutational pressure through artificial selection and self-fertilization, which have exposed rare recessive variants in elite inbred lines. However, the ongoing effect of these rare alleles on modern inbred maize is unknown. By analysing this gene expression resource and exploiting the extreme diversity and rapid linkage disequilibrium decay of maize, we characterize the effect of rare alleles and evolutionary history on the regulation of expression. Rare alleles are associated with the dysregulation of expression, and we correlate this dysregulation to seed-weight fitness. We find enrichment of ancestral rare variants among expression quantitative trait loci mapped in modern inbred lines, which suggests that historic bottlenecks have shaped regulation. Our results suggest that one path for further genetic improvement in agricultural species lies in purging the rare deleterious variants that have been associated with crop fitness.

Published

2018

20. Genomics of Long- and Short-Term Adaptation in Maize and Teosintes

Author

Anne, Lorant, Jeffrey, Ross-Ibarra, and Maud, Tenaillon

Subjects

Domestication, Climate Change, Genetic Variation, Selection, Genetic, Adaptation, Physiological, Zea mays

Abstract

Maize is an excellent model for the study of plant adaptation. Indeed, post domestication maize quickly adapted to a host of new environments across the globe. And work over the last decade has begun to highlight the role of the wild relatives of maize-the teosintes Zea mays ssp. parviglumis and ssp. mexicana-as excellent models for dissecting long-term local adaptation.Although human-driven selection associated with maize domestication has been extensively studied, the genetic basis of natural variation is still poorly understood. Here we review studies on the genetic basis of adaptation and plasticity in maize and its wild relatives. We highlight a range of different processes that contribute to adaptation and discuss evidence from natural, cultivated, and experimental populations. From an applied perspective, understanding the genetic bases of adaptation and the contribution of plasticity will provide us with new tools to both better understand and mitigate the effect of climate changes on natural and cultivated populations.

Published

2020

21. Chromosome Evolution of Octoploid Strawberry

Author

Randi A. Famula, Anne Lorant, Charlotte B. Acharya, Steven J. Knapp, Mitchell J. Feldmann, Patrick P. Edger, Michael A. Hardigan, and Glenn S. Cole

Subjects

education.field_of_study, Polyploid, Gene mapping, Genetic marker, Evolutionary biology, Population, Biology, education, Genome, DNA sequencing, SNP genotyping, Gene flow

Abstract

The allo-octoploid cultivated strawberry (Fragaria×ananassa) originated through a combination of polyploid and homoploid hybridization, domestication of an interspecific hybrid lineage, and continued admixture of wild species over the last 300 years. While genes appear to flow freely between the octoploid progenitors, the genome structures and diversity of the octoploid species remain poorly understood. The complexity and absence of an octoploid genome frustrated early efforts to study chromosome evolution, resolve subgenomic structure, and develop a single coherent linkage group nomenclature. Here, we show that octoploidFragariaspecies harbor millions of subgenome-specific DNA variants. Their diversity was sufficient to distinguish duplicated (homoeologous and paralogous) DNA sequences and develop 50K and 850K SNP genotyping arrays populated with co-dominant, disomic SNP markers distributed throughout the octoploid genome. Whole-genome shotgun genotyping of an interspecific segregating population yielded 1.9M genetically mapped subgenome variants in 5,521 haploblocks spanning 3,394 cM inF. chiloensissubsp.lucida, and 1.6M genetically mapped subgenome variants in 3,179 haploblocks spanning 2,017 cM inF. ×ananassa. These studies provide a dense genomic framework of subgenome-specific DNA markers for seamlessly cross-referencing genetic and physical mapping information, and unifying existing chromosome nomenclatures. Through comparative genetic mapping, we show that the genomes of geographically diverse wild octoploids are effectively diploidized and completely collinear. The preservation of genome structure among allo-octoploid taxa is a critical factor in the unique history of garden strawberry, where unimpeded gene flow supported both its origin and domestication through repeated cycles of interspecific hybridization.

Published

2019

22. Genomics of long- and short- term adaptation in maize and teosinte

Author

Jeffrey Ross-Ibarra, Anne Lorant, Maud I. Tenaillon, Génétique Quantitative et Evolution - Le Moulon (Génétique Végétale) (GQE-Le Moulon), Centre National de la Recherche Scientifique (CNRS)-AgroParisTech-Université Paris-Sud - Paris 11 (UP11)-Institut National de la Recherche Agronomique (INRA), and Institut National de la Recherche Agronomique (INRA)-Université Paris-Sud - Paris 11 (UP11)-AgroParisTech-Centre National de la Recherche Scientifique (CNRS)

Subjects

2. Zero hunger, 0106 biological sciences, 0303 health sciences, Range (biology), [SDV]Life Sciences [q-bio], Genomics, 15. Life on land, Biology, Natural variation, 01 natural sciences, Zea mays, [SDV.GEN.GPL]Life Sciences [q-bio]/Genetics/Plants genetics, 03 medical and health sciences, Evolutionary biology, Adaptation, Domestication, Selection (genetic algorithm), 030304 developmental biology, 010606 plant biology & botany

Abstract

Maize is an excellent model for the study of plant adaptation. Indeed, post domestication maize quickly adapted to a host of new environments across the globe. And work over the last decade has begun to highlight the role of the wild relatives of maize – the teosintes Zea mays ssp. parviglumis and ssp. mexicana – as excellent models for dissecting long-term local adaptation. Although human-driven selection associated with maize domestication has been extensively studied, the genetic bases of natural variation is still poorly understood. Here we review studies on the genetic basis of adaptation and plasticity in maize and its wild relatives. We highlight a range of different processes that contribute to adaptation and discuss evidence from natural, cultivated, and experimental populations. From an applied perspective, understanding the genetic bases of adaptation and the contribution of plasticity will provide us with new tools to both better understand and mitigate the effect of climate changes on natural and cultivated populations.

Published

2018

23. A less selfish view of genome size evolution in maize

Author

Mark N. Grote, Anne Lorant, James A. Birchler, Juvenal Quezada, Kelly Swarts, Jeremy J. Berg, Jeffrey Ross-Ibarra, Patrice S. Albert, Jinliang Yang, Paul Bilinski, and Copenhaver, Gregory P

Subjects

0106 biological sciences, 0301 basic medicine, Leaves, Cancer Research, Plant Science, Plant Genetics, Bird Genomics, 01 natural sciences, Genome, Repetitive Sequences, Cell Signaling, Genome Size, Invertebrate Genomics, Natural Selection, Plant Genomics, Genome Evolution, In Situ Hybridization, Fluorescence, In Situ Hybridization, Genetics (clinical), 2. Zero hunger, education.field_of_study, Natural selection, Geography, Plant Anatomy, Altitude, Eukaryota, Genomics, Plants, Adaptation, Physiological, Experimental Organism Systems, Perspective, Genomic Signal Processing, Genome, Plant, Research Article, Biotechnology, Signal Transduction, Transposable element, Genome evolution, Evolutionary Processes, lcsh:QH426-470, Evolution, Physiological, Population, Biology, Genome Complexity, Research and Analysis Methods, Zea mays, Molecular Evolution, Fluorescence, Evolution, Molecular, 03 medical and health sciences, Model Organisms, Genetic Elements, Species Specificity, Genetic, Plant and Algal Models, Genetic variation, Genetics, Grasses, Selection, Genetic, Adaptation, education, Selection, Molecular Biology, Genome size, Ecology, Evolution, Behavior and Systematics, Selection (genetic algorithm), Repetitive Sequences, Nucleic Acid, Evolutionary Biology, Nucleic Acid, Evolutionary Developmental Biology, Human Genome, Organisms, Biology and Life Sciences, Computational Biology, Molecular, Genetic Variation, Central America, Cell Biology, Plant, South America, 15. Life on land, Genome Analysis, Genomic Libraries, Organismal Evolution, Maize, lcsh:Genetics, 030104 developmental biology, Animal Genomics, Evolutionary biology, Plant Biotechnology, Developmental Biology, 010606 plant biology & botany

Abstract

While the vast majority of genome size variation in plants is due to differences in repetitive sequence, we know little about how selection acts on repeat content in natural populations. Here we investigate parallel changes in intraspecific genome size and repeat content of domesticated maize (Zea mays) landraces and their wild relative teosinte across altitudinal gradients in Mesoamerica and South America. We combine genotyping, low coverage whole-genome sequence data, and flow cytometry to test for evidence of selection on genome size and individual repeat abundance. We find that population structure alone cannot explain the observed variation, implying that clinal patterns of genome size are maintained by natural selection. Our modeling additionally provides evidence of selection on individual heterochromatic knob repeats, likely due to their large individual contribution to genome size. To better understand the phenotypes driving selection on genome size, we conducted a growth chamber experiment using a population of highland teosinte exhibiting extensive variation in genome size. We find weak support for a positive correlation between genome size and cell size, but stronger support for a negative correlation between genome size and the rate of cell production. Reanalyzing published data of cell counts in maize shoot apical meristems, we then identify a negative correlation between cell production rate and flowering time. Together, our data suggest a model in which variation in genome size is driven by natural selection on flowering time across altitudinal clines, connecting intraspecific variation in repetitive sequence to important differences in adaptive phenotypes., Author summary Genome size in plants can vary by orders of magnitude, but this variation has long been considered to be of little functional consequence. Studying three independent adaptations to high altitude in Zea mays, we find that genome size experiences parallel pressures from natural selection, causing a reduction in genome size with increasing altitude. Though reductions in overall repetitive content are responsible for the genome size change, we find that only those individual loci contributing most to the variation in genome size are individually targeted by selection. To identify the phenotype influenced by genome size, we study how variation in genome size within a single wild population impacts leaf growth and cell division. We find that genome size variation correlates negatively with the rate of cell division, suggesting that individuals with larger genomes require longer to complete a mitotic cycle. Finally, we reanalyze data from maize inbreds to show that faster cell division is correlated with earlier flowering, connecting observed variation in genome size to an important adaptive phenotype.

Published

2018

24. Parallel altitudinal clines reveal trends adaptive evolution of genome size inZea mays

Author

Jeremy J Berg, Kelly Swarts, Jinliang Yang, James A. Birchler, Paul Bilinski, Jeffrey Ross-Ibarra, Patrice S. Albert, Mark N. Grote, Juvenal Quezada, and Anne Lorant

Subjects

0106 biological sciences, 2. Zero hunger, 0303 health sciences, education.field_of_study, Natural selection, Population, 15. Life on land, Biology, 01 natural sciences, Phenotype, Genome, Intraspecific competition, 03 medical and health sciences, Evolutionary biology, education, Genotyping, Genome size, Selection (genetic algorithm), 030304 developmental biology, 010606 plant biology & botany

Abstract

While the vast majority of genome size variation in plants is due to differences in repetitive sequence, we know little about how selection acts on repeat content in natural populations. Here we investigate parallel changes in intraspecific genome size and repeat content of domesticated maize (Zea mays) landraces and their wild relative teosinte across altitudinal gradients in Mesoamerica and South America. We combine genotyping, low coverage whole-genome sequence data, and flow cytometry to test for evidence of selection on genome size and individual repeat abundance. We find that population structure alone cannot explain the observed variation, implying that clinal patterns of genome size are maintained by natural selection. Our modeling additionally provides evidence of selection on individual heterochromatic knob repeats, likely due to their large individual contribution to genome size. To better understand the phenotypes driving selection on genome size, we conducted a growth chamber experiment using a population of highland teosinte exhibiting extensive variation in genome size. We find weak support for a positive correlation between genome size and cell size, but stronger support for a negative correlation between genome size and the rate of cell production. Reanalyzing published data of cell counts in maize shoot apical meristems, we then identify a negative correlation between cell production rate and flowering time. Together, our data suggest a model in which variation in genome size is driven by natural selection on flowering time across altitudinal clines, connecting intraspecific variation in repetitive sequence to important differences in adaptive phenotypes.Author summaryGenome size in plants can vary by orders of magnitude, but this variation has long been considered to be of little to no functional consequence. Studying three independent adaptations to high altitude inZea mays, we find that genome size experiences parallel pressures from natural selection, causing a linear reduction in genome size with increasing altitude. Though reductions in repetitive content are responsible for the genome size change, we find that only those individual loci contributing most to the variation in genome size are individually targeted by selection. To identify the phenotype influenced by genome size, we study how variation in genome size within a single teosinte population impacts leaf growth and cell division. We find that genome size variation correlates negatively with the rate of cell division, suggesting that individuals with larger genomes require longer to complete a mitotic cycle. Finally, we reanalyze data from maize inbreds to show that faster cell division is correlated with earlier flowering, connecting observed variation in genome size to an important adaptive phenotype.

Published

2017

25. Construction of the third-generation Zea mays haplotype map

Author

Longjiang Fan, Yingrui Li, M. Cinta Romay, Zhengqin Rong, Qi Sun, Xiaosen Guo, Vince Buffalo, Yanli Lu, Yinping Jiao, Jeffrey Ross-Ibarra, Xun Xu, John Doebley, Edward S. Buckler, Anne Lorant, Robert Bukowski, Shibin Gao, Gengyun Zhang, Chuanxiao Xie, Bo Wang, Dawen Xu, Doreen Ware, Jinsheng Lai, Bicheng Yang, Yunbi Xu, Cheng Zou, and Bing He

Subjects

0106 biological sciences, 0301 basic medicine, Research groups, Population genetics, Health Informatics, imputation, Biology, 01 natural sciences, Zea mays, identity by descent, 03 medical and health sciences, Zea may, variant discovery, International HapMap Project, Domestication, Whole genome sequencing, Genome, Research, Haplotype, Genetic Variation, Plant, sequencing, Genealogy, Third generation, Computer Science Applications, haplotype map, 030104 developmental biology, Haplotypes, genotyping, Genome, Plant, linkage disequilibrium, 010606 plant biology & botany

Abstract

Author(s): Bukowski, Robert; Guo, Xiaosen; Lu, Yanli; Zou, Cheng; He, Bing; Rong, Zhengqin; Wang, Bo; Xu, Dawen; Yang, Bicheng; Xie, Chuanxiao; Fan, Longjiang; Gao, Shibin; Xu, Xun; Zhang, Gengyun; Li, Yingrui; Jiao, Yinping; Doebley, John F; Ross-Ibarra, Jeffrey; Lorant, Anne; Buffalo, Vince; Romay, M Cinta; Buckler, Edward S; Ware, Doreen; Lai, Jinsheng; Sun, Qi; Xu, Yunbi | Abstract: BackgroundCharacterization of genetic variations in maize has been challenging, mainly due to deterioration of collinearity between individual genomes in the species. An international consortium of maize research groups combined resources to develop the maize haplotype version 3 (HapMap 3), built from whole-genome sequencing data from 1218 maize lines, covering predomestication and domesticated Zea mays varieties across the world.ResultsA new computational pipeline was set up to process more than 12 trillion bp of sequencing data, and a set of population genetics filters was applied to identify more than 83 million variant sites.ConclusionsWe identified polymorphisms in regions where collinearity is largely preserved in the maize species. However, the fact that the B73 genome used as the reference only represents a fraction of all haplotypes is still an important limiting factor.

Published

2017

26. The potential role of genetic assimilation during maize domestication

Author

Jeffrey Ross-Ibarra, Matthew B. Hufford, Irene Holst, Dolores R. Piperno, Klaus Winter, Sarah Pedersen, Anne Lorant, and Lukens, Lewis

Subjects

0106 biological sciences, 0301 basic medicine, Gene Expression, lcsh:Medicine, Plant Science, Plant Genetics, 01 natural sciences, Domestication, Extant taxon, Plant Genomics, Publication data, lcsh:Science, Flowering Plants, 2. Zero hunger, 0303 health sciences, Multidisciplinary, Plant Anatomy, Paleogenetics, Genomics, Plants, Phenotype, Zea mays, Chemistry, Experimental Organism Systems, Inflorescence, Physical Sciences, Research Article, Biotechnology, Crops, Agricultural, Inflorescences, General Science & Technology, Crops, Biology, Environment, Research and Analysis Methods, 010603 evolutionary biology, 03 medical and health sciences, Model Organisms, Genetic, Plant and Algal Models, Botany, Genetic variation, Genetics, Paleobotany, Grasses, Selection, Genetic, Gene, Selection, 030304 developmental biology, Agricultural, Gene Expression Profiling, Human Genome, lcsh:R, fungi, Organisms, Chemical Compounds, Biology and Life Sciences, Paleontology, Computational Biology, Carbon Dioxide, Maize, 030104 developmental biology, Gene Ontology, Evolutionary biology, Earth Sciences, Plant Biotechnology, lcsh:Q, Paleobiology, Genetic assimilation, 010606 plant biology & botany

Abstract

Domestication research has largely focused on identification of morphological and genetic differences between extant populations of crops and their wild relatives. Little attention has been paid to the potential effects of environment despite substantial known changes in climate from the time of domestication to modern day. Recent research, in which maize and teosinte (i.e., wild maize) were exposed to environments similar to the time of domestication, resulted in a plastic induction of domesticated phenotypes in teosinte and little response to environment in maize. These results suggest that early agriculturalists may have selected for genetic mechanisms that cemented domestication phenotypes initially induced by a plastic response of teosinte to environment, a process known as genetic assimilation. To better understand this phenomenon and the potential role of environment in maize domestication, we examined differential gene expression in maize (Zea mays ssp. mays) and teosinte (Zea mays ssp. parviglumis) between past and present conditions. We identified a gene set of over 2000 loci showing a change in expression across environmental conditions in teosinte and invariance in maize. In fact, overall we observed both greater plasticity in gene expression and more substantial re-wiring of expression networks in teosinte across environments when compared to maize. While these results suggest genetic assimilation played at least some role in domestication, genes showing expression patterns consistent with assimilation are not significantly enriched for previously identified domestication candidates, indicating assimilation did not have a genome-wide effect.

Published

2017

27. Genomic abundance is not predictive of tandem repeat localization in grass genomes

Author

Yonghua Han, Pingdong Zhang, Matt C. Estep, Anne Lorant, Jeffrey Ross-Ibarra, Matthew B. Hufford, Jiming Jiang, Paul Bilinski, and Li, Xiu-Qing

Subjects

0106 biological sciences, 0301 basic medicine, Sequence assembly, lcsh:Medicine, Plant Science, Plant Genetics, 01 natural sciences, Genome, Plant Genomics, Direct repeat, lcsh:Science, In Situ Hybridization, Fluorescence, In Situ Hybridization, Centromeres, Genetics, Multidisciplinary, Fluorescent in Situ Hybridization, Chromosome Biology, Shotgun sequencing, Genomics, Plants, Tandem Repeats, Variable number tandem repeat, Experimental Organism Systems, Tandem Repeat Sequences, Genome, Plant, Research Article, Biotechnology, Chromosome Structure and Function, General Science & Technology, Centromere, Molecular Probe Techniques, Hybrid genome assembly, Computational biology, Biology, Research and Analysis Methods, Poaceae, Chromosomes, Fluorescence, 03 medical and health sciences, Model Organisms, Tandem repeat, Plant and Algal Models, Constitutive heterochromatin, Repeated Sequences, Grasses, Molecular Biology Techniques, Molecular Biology, Sequence Assembly Tools, Human Genome, lcsh:R, Organisms, Biology and Life Sciences, Computational Biology, Cell Biology, Plant, Comparative Genomics, Genome Analysis, Genomic Libraries, Probe Hybridization, Maize, 030104 developmental biology, Plant Biotechnology, lcsh:Q, Generic health relevance, Cytogenetic Techniques, 010606 plant biology & botany

Abstract

Highly repetitive regions have historically posed a challenge when investigating sequence variation and content. High-throughput sequencing has enabled researchers to use whole-genome shotgun sequencing to estimate the abundance of repetitive sequence, and these methodologies have been recently applied to centromeres. Previous research has investigated variation in centromere repeats across eukaryotes, positing that the highest abundance tandem repeat in a genome is often the centromeric repeat. To test this assumption, we used shotgun sequencing and a bioinformatic pipeline to identify common tandem repeats across a number of grass species. We find that de novo assembly and subsequent abundance ranking of repeats can successfully identify tandem repeats with homology to known tandem repeats. Fluorescent in-situ hybridization shows that de novo assembly and ranking of repeats from non-model taxa identifies chromosome domains rich in tandem repeats both near pericentromeres and elsewhere in the genome.

Published

2017

28. Diverse origins of high copy tandem repeats in grass genomes

Author

Jeffrey Ross-Ibarra, Jiming Jiang, Yonghua Han, Matthew B. Hufford, Pingdong Zhang, Paul Bilinski, and Anne Lorant

Subjects

0106 biological sciences, Genetics, 0303 health sciences, Shotgun sequencing, Heterochromatin, Sequence assembly, Computational biology, Biology, 010603 evolutionary biology, 01 natural sciences, Genome, Homology (biology), 03 medical and health sciences, Tandem repeat, Constitutive heterochromatin, Direct repeat, 030304 developmental biology

Abstract

In studying genomic architecture, highly repetitive regions have historically posed a challenge when investigating sequence variation and content. High-throughput sequencing has enabled researchers to use whole-genome shotgun sequencing to estimate the abundance of repetitive sequence, and these methodologies have been recently applied to centromeres. Here, we utilize sequence assembly and read mapping to identify and quantify the genomic abundance of different tandem repeat sequences. Previous research has posited that the highest abundance tandem repeat in eukaryotic genomes is often the centromeric repeat, and we pair our bioinformatic pipeline with fluorescent in-situ hybridization data to test this hypothesis. We find that de novo assembly and bioinformatic filters can successfully identify repeats with homology to known tandem repeats. Fluorescent in-situ hybridization, however, shows that de novo assembly fails to identify novel centromeric repeats, instead identifying other potentially important repetitive sequences. Together, our results test the applicability and limitations of using de novo repeat assembly of tandem repeats to identify novel centromeric repeats. Building on our findings of genomic composition, we also set forth a method for exploring the repetitive regions of non-model genomes whose diversity limits the applicability of established genetic resources.

Published

2016