Your search keyword '"Evans MMS"' showing total 10 results

1. A Silk-Expressed Pectin Methylesterase Confers Cross-Incompatibility Between Wild and Domesticated Strains of Zea mays

Author

Samuel Hokin, Jerry L. Kermicle, Yongxian Lu, and Evans Mms

Subjects

0106 biological sciences, Genetics, 0303 health sciences, Gynoecium, education.field_of_study, Population, food and beverages, Reproductive isolation, Biology, medicine.disease_cause, 01 natural sciences, Gene flow, Cell wall, 03 medical and health sciences, Pollen, otorhinolaryngologic diseases, medicine, Domestication, education, Gene, 030304 developmental biology, 010606 plant biology & botany

Abstract

Despite being members of the same species, some strains of wild teosinte maintain themselves as a distinct breeding population by blocking fertilization by pollen from neighboring maize plants. These teosinte strains may be in the process of evolving into a separate species, since reproductive barriers that block gene flow are critical components in speciation. This trait is conferred by the Teosinte crossing barrier1-s (Tcb1-s) haplotype, making Tcb1 a speciation gene candidate. Tcb1-s contains a female gene that blocks non-self-type pollen and a male function that enables self-type pollen to overcome that block. The Tcb1-female gene encodes a Pectin Methylesterase, implying that modification of the pollen cell wall by the pistil is a key mechanism by which these teosinte females reject foreign (but closely related) pollen.One sentence summaryThe Tcb1-female gene encodes a Pectin Methylesterase that in teosinte silks prevents fertilization by maize pollen.

Published

2019

2. Gibberellins Promote Vegetative Phase Change and Reproductive Maturity in Maize

Author

Evans, MMS., primary and Poethig, R. S., additional

Published

1995

3. Control of cellularization, nuclear localization, and antipodal cell cluster development in maize embryo sacs.

Author

Chettoor AM, Yang B, and Evans MMS

Subjects

Cell Differentiation, Seeds genetics, Zea mays genetics, Ovule genetics

Abstract

The maize female gametophyte contains four cell types: two synergids, an egg cell, a central cell, and a variable number of antipodal cells. In maize, these cells are produced after three rounds of free-nuclear divisions followed by cellularization, differentiation, and proliferation of the antipodal cells. Cellularization of the eight-nucleate syncytium produces seven cells with two polar nuclei in the central cell. Nuclear localization is tightly controlled in the embryo sac. This leads to precise allocation of the nuclei into the cells upon cellularization. Nuclear positioning within the syncytium is highly correlated with their identity after cellularization. Two mutants are described with extra polar nuclei, abnormal antipodal cell morphology, and reduced antipodal cell number, as well as frequent loss of antipodal cell marker expression. Mutations in one of these genes, indeterminate gametophyte2 encoding a MICROTUBULE ASSOCIATED PROTEIN65-3 homolog, shows a requirement for MAP65-3 in cellularization of the syncytial embryo sac as well as for normal seed development. The timing of the effects of ig2 suggests that the identity of the nuclei in the syncytial female gametophyte can be changed very late before cellularization., Competing Interests: Conflicts of interest statement The author(s) declare no conflict of interest., (© The Author(s) 2023. Published by Oxford University Press on behalf of The Genetics Society of America. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2023

4. Insights into the molecular control of cross-incompatibility in Zea mays.

Author

Lu Y, Moran Lauter AN, Makkena S, Scott MP, and Evans MMS

Subjects

Breeding, Pollen genetics, Pollen Tube, Pollination, Reproduction genetics, Self-Incompatibility in Flowering Plants genetics, Genes, Plant genetics, Zea mays genetics

Abstract

Gametophytic cross-incompatibility systems in corn have been the subject of genetic studies for more than a century. They have tremendous economic potential as a genetic mechanism for controlling fertilization without controlling pollination. Three major genetically distinct and functionally equivalent cross-incompatibility systems exist in Zea mays: Ga1, Tcb1, and Ga2. All three confer reproductive isolation between maize or teosinte varieties with different haplotypes at any one locus. These loci confer genetically separable functions to the silk and pollen: a female function that allows the silk to block fertilization by non-self-type pollen and a male function that overcomes the block of the female function from the same locus. Identification of some of these genes has shed light on the reproductive isolation they confer. The identification of both male and female factors as pectin methylesterases reveals the importance of pectin methylesterase activity in controlling the decision between pollen acceptance versus rejection, possibly by regulating the degree of methylesterification of the pollen tube cell wall. The appropriate level and spatial distribution of pectin methylesterification is critical for pollen tube growth and is affected by both pectin methylesterases and pectin methylesterase inhibitors. We present a molecular model that explains how cross-incompatibility systems may function that can be tested in Zea and uncharacterized cross-incompatibility systems. Molecular characterization of these loci in conjunction with further refinement of the underlying molecular and cellular mechanisms will allow researchers to bring new and powerful tools to bear on understanding reproductive isolation in Zea mays and related species.

Published

2020

5. High expression in maize pollen correlates with genetic contributions to pollen fitness as well as with coordinated transcription from neighboring transposable elements.

Author

Warman C, Panda K, Vejlupkova Z, Hokin S, Unger-Wallace E, Cole RA, Chettoor AM, Jiang D, Vollbrecht E, Evans MMS, Slotkin RK, and Fowler JE

Subjects

Cell Lineage, Gene Expression Profiling, Genes, Plant genetics, Genome, Plant genetics, Meiosis, Mutagenesis, Insertional, Mutation, Pollination, Reproducibility of Results, Reproduction, Seeds genetics, Seeds growth & development, Up-Regulation, Zea mays cytology, Zea mays growth & development, DNA Transposable Elements genetics, Gene Expression Regulation, Plant, Genetic Fitness, Pollen genetics, Transcription, Genetic, Zea mays genetics

Abstract

In flowering plants, gene expression in the haploid male gametophyte (pollen) is essential for sperm delivery and double fertilization. Pollen also undergoes dynamic epigenetic regulation of expression from transposable elements (TEs), but how this process interacts with gene expression is not clearly understood. To explore relationships among these processes, we quantified transcript levels in four male reproductive stages of maize (tassel primordia, microspores, mature pollen, and sperm cells) via RNA-seq. We found that, in contrast with vegetative cell-limited TE expression in Arabidopsis pollen, TE transcripts in maize accumulate as early as the microspore stage and are also present in sperm cells. Intriguingly, coordinate expression was observed between highly expressed protein-coding genes and their neighboring TEs, specifically in mature pollen and sperm cells. To investigate a potential relationship between elevated gene transcript level and pollen function, we measured the fitness cost (male-specific transmission defect) of GFP-tagged coding sequence insertion mutations in over 50 genes identified as highly expressed in the pollen vegetative cell, sperm cell, or seedling (as a sporophytic control). Insertions in seedling genes or sperm cell genes (with one exception) exhibited no difference from the expected 1:1 transmission ratio. In contrast, insertions in over 20% of vegetative cell genes were associated with significant reductions in fitness, showing a positive correlation of transcript level with non-Mendelian segregation when mutant. Insertions in maize gamete expressed2 (Zm gex2), the sole sperm cell gene with measured contributions to fitness, also triggered seed defects when crossed as a male, indicating a conserved role in double fertilization, given the similar phenotype previously demonstrated for the Arabidopsis ortholog GEX2. Overall, our study demonstrates a developmentally programmed and coordinated transcriptional activation of TEs and genes in pollen, and further identifies maize pollen as a model in which transcriptomic data have predictive value for quantitative phenotypes., Competing Interests: The authors have declared that no competing interests exist.

Published

2020

6. Maternal regulation of seed growth and patterning in flowering plants.

Author

Phillips AR and Evans MMS

Subjects

Arabidopsis genetics, Arabidopsis growth & development, Endosperm genetics, Endosperm growth & development, Magnoliopsida classification, Magnoliopsida growth & development, Ovule growth & development, Reproduction genetics, Seeds growth & development, Zea mays genetics, Zea mays growth & development, Gene Expression Regulation, Developmental, Gene Expression Regulation, Plant, Magnoliopsida genetics, Meiosis genetics, Ovule genetics, Seeds genetics

Abstract

The plant haploid generation is specified late in higher plant development, and post-meiotic haploid plant cells divide mitotically to produce a haploid gametophyte, in which a subset of cells differentiates into the gametes. The immediate mother of the angiosperm seed is the female gametophyte, also called the embryo sac. In most flowering plants the embryo sac is comprised of two kinds of gametes (egg and central cell) and two kinds of subsidiary cells (antipodals and synergids) all of which descend from a single haploid spore produced by meiosis. The embryo sac develops within a specialized organ of the flower called the ovule, which supports and controls many steps in the development of both the embryo sac and the seed. Double fertilization of the central cell and egg cell by the two sperm cells of a pollen grain produce the endosperm and embryo of the seed, respectively. The endosperm and embryo develop under the influence of their precursor gametes and the surrounding tissues of the ovule and the gametophyte. The final size and pattern of the angiosperm seed then is the result of complex interactions across multiple tissues of three different generations (maternal sporophyte, maternal gametophyte, and the fertilization products) and three different ploidies (haploid gametophyte, diploid parental sporophyte and embryo, and triploid endosperm)., (© 2020 Elsevier Inc. All rights reserved.)

Published

2020

7. A pistil-expressed pectin methylesterase confers cross-incompatibility between strains of Zea mays.

Author

Lu Y, Hokin SA, Kermicle JL, Hartwig T, and Evans MMS

Subjects

Carboxylic Ester Hydrolases metabolism, Crosses, Genetic, Genetic Speciation, Mutation, Plant Proteins metabolism, Plants, Genetically Modified, Pollen Tube genetics, Pollen Tube metabolism, Sympatry genetics, Carboxylic Ester Hydrolases genetics, Plant Breeding, Plant Proteins genetics, Reproductive Isolation, Zea mays genetics

Abstract

A central problem in speciation is the origin and mechanisms of reproductive barriers that block gene flow between sympatric populations. Wind-pollinated plant species that flower in synchrony with one another rely on post-pollination interactions to maintain reproductive isolation. In some locations in Mexico, sympatric populations of domesticated maize and annual teosinte grow in intimate associate and flower synchronously, but rarely produce hybrids. This trait is typically conferred by a single haplotype, Teosinte crossing barrier1-s. Here, we show that the Teosinte crossing barrier1-s haplotype contains a pistil-expressed, potential speciation gene, encoding a pectin methylesterase homolog. The modification of the pollen tube cell wall by the pistil, then, is likely a key mechanism for pollen rejection in Zea and may represent a general mechanism for reproductive isolation in grasses.

Published

2019

8. RNA Isolation and Analysis of LncRNAs from Gametophytes of Maize.

Author

Han L, Li L, Muehlbauer GJ, Fowler JE, and Evans MMS

Subjects

Computational Biology methods, Gene Expression Regulation, Plant, Gene Regulatory Networks, Germ Cells, Plant growth & development, High-Throughput Nucleotide Sequencing methods, Transcriptome, Zea mays growth & development, Gene Expression Profiling methods, Genes, Plant genetics, Germ Cells, Plant metabolism, RNA, Long Noncoding genetics, RNA, Plant genetics, RNA, Plant isolation & purification, Zea mays genetics

Abstract

The explosion of RNA-Seq data has enabled the identification of expressed genes without relying on gene models with biases toward open reading frames, allowing the identification of many more long noncoding RNAs (lncRNAs) in eukaryotes. Various tissue enrichment strategies and deep sequencing have also enabled the identification of an extensive list of genes expressed in maize gametophytes, tissues that are intractable to both traditional genetic and gene expression analyses. However, the function of very few genes from the lncRNA and gametophyte sets (or from their intersection) has been tested. Methods for isolating and identifying lncRNAs from gametophyte samples of maize are described here. This method is transferable to any maize gametophyte mutant enabling the development of gene networks involving both protein-coding genes and lncRNAs. Additionally, these methods can be adapted to apply to other grass model systems to test for evolutionary conservation of lncRNA expression patterns.

Published

2019

9. Correction to: Genome-wide discovery and characterization of maize long non-coding RNAs.

Author

Li L, Eichten SR, Shimizu R, Petsch K, Yeh CT, Wu W, Chettoor AM, Givan SA, Cole RA, Fowler JE, Evans MMS, Scanlon MJ, Yu J, Schnable PS, Timmermans MCP, Springer NM, and Muehlbauer GJ

Abstract

The original version [1] of this article unfortunately contained a mistake. The additive effects of the eQTLs of lncRNAs were flipped, meaning that the base allele in the contrast to derive the additive effects should have been B73, rather than Mo17, due to the original coding of biallele SNPs as "0s" and "1s". Going through the entire analysis procedure, it was determined that the mistake was made while tabulating the eQTL results from QTL Cartographer.

Published

2018

10. Live-Cell Imaging of Auxin and Cytokinin Signaling in Maize Female Gametophytes.

Author

Chettoor AM and Evans MMS

Subjects

Gene Expression Regulation, Plant physiology, Germ Cells, Plant, Signal Transduction physiology, Cytokinins metabolism, Indoleacetic Acids metabolism, Optical Imaging methods, Ovule metabolism, Zea mays metabolism

Abstract

The plant life cycle is characterized by the alternation of generations between genetically active diploid sporophytes and haploid gametophytes. The gametophytes of flowering plants are sexually dimorphic. While the male gametophyte consists of only three cells (two sperm and a vegetative cell) and is released by the parent sporophyte, the female gametophyte (or embryo sac) is more complex and remains imbedded within diploid sporophyte tissues. In maize, the female gametophyte is embedded in a large ovule surrounded with multiple nucellar cell layers impeding live-cell imaging approaches to study embryo sac functions. Here, we describe a simple protocol to visualize embryo sacs with hormonal fluorescent reporters by increasing accessibility of the female gametophyte. The method described is applicable for visualization of any fluorescent embryo sac reporter. The embryo sacs visualization method developed for maize could be extended to facilitate visualization of embryos sac in other important cereals like wheat, rice, and oats.

Published

2017