Your search keyword '"Michael J. Scanlon"' showing total 44 results

1. Plant stem-cell organization and differentiation at single-cell resolution

Author

Michael J. Scanlon, Josh Strable, and James W. Satterlee

Subjects

Plant stem cell, Transcription, Genetic, Cell division, Somatic cell, Cellular differentiation, Meristem, Morphogenesis, Plant Biology, Biology, maize, Zea mays, Gene Expression Regulation, Plant, Induced pluripotent stem cell, Plant Proteins, shoot apical meristem, Multidisciplinary, Stem Cells, fungi, food and beverages, Cell Differentiation, Biological Sciences, Cell biology, Plant Leaves, Single-Cell Analysis, Stem cell, Transcriptome, single-cell transcriptomics, Cell Division, Genome, Plant

Abstract

Significance Plants possess the remarkable ability to grow and produce new organs throughout their lifespan, owing to the activities of persistent populations of pluripotent stem cells within their meristematic tips. Here we isolated individual cells from the microscopic shoot apical meristem (SAM) of maize and provide single-cell transcriptomic analysis of a plant shoot meristem. This study enabled an unbiased analysis of the developmental genetic organization of the maize shoot apex and uncovered evolutionarily divergent and conserved signatures of SAM homeostasis. The fine-scale resolution of single-cell analysis was used to reconstruct the process of shoot cell differentiation, whereby stem cells acquire diverse and distinct cell fates over developmental time in wild-type and mutant maize seedlings., Plants maintain populations of pluripotent stem cells in shoot apical meristems (SAMs), which continuously produce new aboveground organs. We used single-cell RNA sequencing (scRNA-seq) to achieve an unbiased characterization of the transcriptional landscape of the maize shoot stem-cell niche and its differentiating cellular descendants. Stem cells housed in the SAM tip are engaged in genome integrity maintenance and exhibit a low rate of cell division, consistent with their contributions to germline and somatic cell fates. Surprisingly, we find no evidence for a canonical stem-cell organizing center subtending these cells. In addition, trajectory inference was used to trace the gene expression changes that accompany cell differentiation, revealing that ectopic expression of KNOTTED1 (KN1) accelerates cell differentiation and promotes development of the sheathing maize leaf base. These single-cell transcriptomic analyses of the shoot apex yield insight into the processes of stem-cell function and cell-fate acquisition in the maize seedling and provide a valuable scaffold on which to better dissect the genetic control of plant shoot morphogenesis at the cellular level.

Published

2020

2. Transcriptomic network analyses shed light on the regulation of cuticle development in maize leaves

Author

Michael J. Scanlon, Isabel Molina, Richard Bourgault, Susanne Matschi, Michael A. Gore, Marc Mohammadi, Pengfei Qiao, Laurie G. Smith, and Glenn Philippe

Subjects

0106 biological sciences, Light, Cuticle, Mutant, Plant Biology, PHYTOCHROME, Cutin, Biology, maize, Physcomitrella patens, Zea mays, 01 natural sciences, 03 medical and health sciences, Gene Expression Regulation, Plant, evolution, Plant Proteins, 030304 developmental biology, Plant evolution, 0303 health sciences, Multidisciplinary, Phytochrome, Gene Expression Profiling, fungi, food and beverages, RNA, Biological Sciences, biology.organism_classification, Bryopsida, Cell biology, Plant Leaves, network, cuticle, Transcriptome, Function (biology), 010606 plant biology & botany

Abstract

Significance Plant cuticles provide barriers to water loss and arose as aquatic plants adapted to the dry terrestrial environment. The cuticle components, waxes and the fatty acid-based polymer cutin, are synthesized in the plant epidermis, exported across the cell wall, and deposited on the plant surface. This study suggests a role for PHYTOCHROME light receptors during cuticle development in leaves of maize and moss, diverse species that are separated by more than 400 million y of land plant evolution. We hypothesize that phytochrome-mediated light signaling contributed to the evolution of cuticles in land plants., Plant cuticles are composed of wax and cutin and evolved in the land plants as a hydrophobic boundary that reduces water loss from the plant epidermis. The expanding maize adult leaf displays a dynamic, proximodistal gradient of cuticle development, from the leaf base to the tip. Laser microdissection RNA Sequencing (LM-RNAseq) was performed along this proximodistal gradient, and complementary network analyses identified potential regulators of cuticle biosynthesis and deposition. A weighted gene coexpression network (WGCN) analysis suggested a previously undescribed function for PHYTOCHROME-mediated light signaling during the regulation of cuticular wax deposition. Genetic analyses reveal that phyB1 phyB2 double mutants of maize exhibit abnormal cuticle composition, supporting the predictions of our coexpression analysis. Reverse genetic analyses also show that phy mutants of the moss Physcomitrella patens exhibit abnormal cuticle composition, suggesting an ancestral role for PHYTOCHROME-mediated, light-stimulated regulation of cuticle development during plant evolution.

Published

2020

3. Genome-Wide Association Study for Maize Leaf Cuticular Conductance Identifies Candidate Genes Involved in the Regulation of Cuticle Development

Author

Isabel Molina, Michael G. Miller, Laurie G. Smith, Michael A. Gore, Miguel F. Vasquez, Michael J. Scanlon, Ethan L. Stewart, James Chamness, Matheus Baseggio, Nicholas Kaczmar, Susanne Matschi, Pengfei Qiao, and Meng Lin

Subjects

0106 biological sciences, Genome-wide association study, Candidate gene, Cuticle, Drought tolerance, Cutin, QH426-470, Investigations, Biology, Zea mays, 01 natural sciences, 03 medical and health sciences, Gene Expression Regulation, Plant, Genetics, Molecular Biology, Gene, Cell wall modification, Genetics (clinical), Cuticular conductance, 030304 developmental biology, Laser capture microdissection, 0303 health sciences, Human Genome, fungi, food and beverages, RNA, RNA sequencing, Plant, Droughts, Cell biology, Plant Leaves, Gene Expression Regulation, Waxes, Whole-genome prediction, Biotechnology, 010606 plant biology & botany

Abstract

The cuticle, a hydrophobic layer of cutin and waxes synthesized by plant epidermal cells, is the major barrier to water loss when stomata are closed at night and under water-limited conditions. Elucidating the genetic architecture of natural variation for leaf cuticular conductance (gc) is important for identifying genes relevant to improving crop productivity in drought-prone environments. To this end, we conducted a genome-wide association study ofgcof adult leaves in a maize inbred association panel that was evaluated in four environments (Maricopa, AZ, and San Diego, CA in 2016 and 2017). Five genomic regions significantly associated withgcwere resolved to seven plausible candidate genes (ISTL1, two SEC14 homologs, cyclase-associated protein, a CER7 homolog, GDSL lipase, and β-D-XYLOSIDASE 4). These candidates are potentially involved in cuticle biosynthesis, trafficking and deposition of cuticle lipids, cutin polymerization, and cell wall modification. Laser microdissection RNA sequencing revealed that all these candidate genes, with the exception of the CER7 homolog, were expressed in the zone of the expanding adult maize leaf where cuticle maturation occurs. With direct application to genetic improvement, moderately high average predictive abilities were observed for whole-genome prediction ofgcin locations (0.46 and 0.45) and across all environments (0.52). The findings of this study provide novel insights into the genetic control ofgcand have the potential to help breeders more effectively develop drought-tolerant maize for target environments.Article summaryThe cuticle serves as the major barrier to water loss when stomata are closed at night and under water-limited conditions and potentially relevant to drought tolerance in crops. We performed a genome-wide association study to elucidate the genetic architecture of natural variation for maize leaf cuticular conductance. We identified epidermally expressed candidate genes that are potentially involved in cuticle biosynthesis, trafficking and deposition, cutin polymerization, and cell wall modification. Finally, we observed moderately high predictive abilities for whole-genome prediction of leaf cuticular conductance. Collectively, these findings may help breeders more effectively develop drought-tolerant maize.

Published

2020

4. Cytokinin-CLAVATA cross-talk is an ancient mechanism regulating shoot meristem homeostasis in land plants

Author

Joseph Cammarata, Christopher Morales Farfan, Michael J. Scanlon, and Adrienne H. K. Roeder

Subjects

Multidisciplinary, Cytokinins, Gene Expression Regulation, Plant, fungi, Meristem, food and beverages, Homeostasis, Bryopsida, Plant Shoots

Abstract

Significance Plants grow from their tips. The gametophore (shoot-like organ) tip of the moss Physcomitrium patens is a single cell that performs the same functions as those of multicellular flowering plants, producing the cells that make leaves and regenerating new stem cells to maintain the shoot tip. Several pathways, including CLAVATA and cytokinin hormonal signaling, regulate stem cell abundance in flowering plants and in mosses, although the mechanisms whereby these pathways regulate stem cell abundance and their conservation between these plant lineages is poorly understood. Using moss, we investigated how Pp CLAVATA and cytokinin signaling interact. Overall, we found evidence that Pp CLAVATA and cytokinin signaling interact similarly in moss and flowering plants, despite their distinct anatomies, life cycles, and evolutionary distance.

Published

2022

5. Cytokinin-CLAVATA crosstalk is an ancient mechanism regulating shoot meristem homeostasis in land plants

Author

Michael J. Scanlon, Joseph Cammarata, Christopher Morales Farfan, and Adrienne H. K. Roeder

Subjects

Physcomitrella, fungi, Cell, food and beverages, Organogenesis, Biology, Meristem, biology.organism_classification, Cell biology, Crosstalk (biology), chemistry.chemical_compound, medicine.anatomical_structure, chemistry, Arabidopsis, Cytokinin, medicine, Stem cell

Abstract

Plant shoots grow from stem cells within Shoot Apical Meristems (SAMs), which produce lateral organs while maintaining the stem cell pool. In the model flowering plant Arabidopsis, the CLAVATA (CLV) pathway functions antagonistically with cytokinin signaling to control the size of the multicellular SAM via negative regulation of the stem cell organizer WUSCHEL (WUS). Although comprising just a single cell, the SAM of the model moss Physcomitrium patens (formerly Physcomitrella) performs equivalent functions during stem cell maintenance and organogenesis, despite the absence of WUS-mediated stem cell organization. Our previous work showed that the stem cell-delimiting function of the CLV pathway receptors CLAVATA1 (CLV1) and RECEPTOR-LIKE PROTEIN KINASE2 (RPK2) is conserved in the moss P. patens. Here, we use P. patens to assess whether CLV-cytokinin crosstalk is also an evolutionarily conserved feature of stem cell regulation. Genetic analyses reveal that CLV1 and RPK2 regulate SAM proliferation via separate pathways in moss. Surprisingly, cytokinin receptor mutants also form ectopic stem cells in the absence of cytokinin signaling. Through modeling, we identified regulatory network archtectures that recapitulated the stem cell phenotypes of clv1 and rpk2 mutants, cytokinin application, cytokinin receptor mutations, and higher-order combinations of these perturbations. These models predict that CLV1 and RPK2 act through separate pathways wherein CLV1 represses cytokinin-mediated stem cell initiation and RPK2 inhibits this process via a separate, cytokinin-independent pathway. Our analysis suggests that crosstalk between CLV1 and cytokinin signaling is an evolutionarily conserved feature of SAM homeostasis that preceded the role of WUS in stem cell organization.

Published

2021

6. A high-resolution gene expression atlas links dedicated meristem genes to key architectural traits

Author

Sunita Kumari, Robyn Johnston, Kokulapalan Wimalanathan, Marie Javelle, Xianran Li, Patrick S. Schnable, Robert B. Meeley, Marja C.P. Timmermans, Xiaoli Ma, Michael J. Scanlon, Carolyn J. Lawrence-Dill, Gary J. Muehlbauer, Jianming Yu, Doreen Ware, Samuel Leiboff, Steffen Knauer, and Lin Li

Subjects

Meristem, Arabidopsis, Biology, Genes, Plant, 03 medical and health sciences, 0302 clinical medicine, Gene Expression Regulation, Plant, Gene expression, Genetics, Gene family, Gene, Transcription factor, Genetics (clinical), 030304 developmental biology, Regulation of gene expression, 0303 health sciences, Research, fungi, food and beverages, biology.organism_classification, Evolutionary biology, Subfunctionalization, Databases, Nucleic Acid, 030217 neurology & neurosurgery

Abstract

The shoot apical meristem (SAM) orchestrates the balance between stem cell proliferation and organ initiation essential for postembryonic shoot growth. Meristems show a striking diversity in shape and size. How this morphological diversity relates to variation in plant architecture and the molecular circuitries driving it are unclear. By generating a high-resolution gene expression atlas of the vegetative maize shoot apex, we show here that distinct sets of genes govern the regulation and identity of stem cells in maize versus Arabidopsis. Cell identities in the maize SAM reflect the combinatorial activity of transcription factors (TFs) that drive the preferential, differential expression of individual members within gene families functioning in a plethora of cellular processes. Subfunctionalization thus emerges as a fundamental feature underlying cell identity. Moreover, we show that adult plant characters are, to a significant degree, regulated by gene circuitries acting in the SAM, with natural variation modulating agronomically important architectural traits enriched specifically near dynamically expressed SAM genes and the TFs that regulate them. Besides unique mechanisms of maize stem cell regulation, our atlas thus identifies key new targets for crop improvement.

Published

2019

7. Machine Learning Enables High-Throughput Phenotyping for Analyses of the Genetic Architecture of Bulliform Cell Patterning in Maize

Author

Pengfei Qiao, Michael A. Gore, Meng Lin, Laurie G. Smith, Matheus Baseggio, Michael J. Scanlon, Susanne Matschi, James Chamness, Miguel F. Vasquez, and Mert R. Sabuncu

Subjects

0106 biological sciences, Cell type, Genomics, Quantitative trait locus, Biology, QH426-470, Investigations, Machine learning, computer.software_genre, 01 natural sciences, Zea mays, Machine Learning, 03 medical and health sciences, Quantitative Trait, Heritable, Gene Expression Regulation, Plant, Genetics, bulliform cell, GWAS, Molecular Biology, development, Genetics (clinical), 030304 developmental biology, 2. Zero hunger, 0303 health sciences, business.industry, Drought resistance, fungi, food and beverages, Phenotype, Bulliform cell, Genetic architecture, Plant Leaves, Artificial intelligence, business, computer, Function (biology), 010606 plant biology & botany, Genome-Wide Association Study

Abstract

Bulliform cells comprise specialized cell types that develop on the adaxial (upper) surface of grass leaves, and are patterned to form linear rows along the proximodistal axis of the adult leaf blade. Bulliform cell patterning affects leaf angle and is presumed to function during leaf rolling, thereby reducing water loss during temperature extremes and drought. In this study, epidermal leaf impressions were collected from a genetically and anatomically diverse population of maize inbred lines. Subsequently, convolutional neural networks were employed to measure microscopic, bulliform cell-patterning phenotypes in high-throughput. A genome-wide association study, combined with RNAseq analyses of the bulliform cell ontogenic zone, identified candidate regulatory genes affecting bulliform cell column number and cell width. This study is the first to combine machine learning approaches, transcriptomics, and genomics to study bulliform cell patterning, and the first to utilize natural variation to investigate the genetic architecture of this microscopic trait. In addition, this study provides insight toward the improvement of macroscopic traits such as drought resistance and plant architecture in an agronomically important crop plant.

Published

2019

8. Cytokinin and CLE signaling are highly intertwined developmental regulators across tissues and species

Author

Michael J. Scanlon, Adrienne H. K. Roeder, and Joseph Cammarata

Subjects

0106 biological sciences, 0301 basic medicine, Cytokinins, Cell division, Cellular differentiation, Arabidopsis, Plant Science, Physcomitrella patens, Plant Roots, 01 natural sciences, 03 medical and health sciences, chemistry.chemical_compound, Plant Growth Regulators, Arabidopsis thaliana, biology, Arabidopsis Proteins, fungi, food and beverages, biology.organism_classification, Cell biology, 030104 developmental biology, chemistry, Cytokinin, Signal transduction, Signal Transduction, 010606 plant biology & botany, Hormone

Abstract

The control of cell identity and differentiation is critical for proper development. In plants, cell identity is largely determined by a cell's spatial context, which is communicated in the form of varying abundances of hormones. Two classes of hormones, the classical phytohormone cytokinin and the small CLE peptide hormones, are potent regulators of cell division and cell differentiation. While a relationship between these two classes of hormones is well-established at developing shoot tips, recent evidence suggests that CLE and cytokinin signaling converge on the same developmental processes across many different contexts and in widely divergent species. Here, we review evidence predominately from Arabidopsis thaliana and the moss Physcomitrella patens that supports a general model where CLE and cytokinin signaling are highly intertwined developmental regulators with antagonistic functions in shoots and synergistic functions in roots.

Published

2019

9. Network analyses identify a transcriptomic proximodistal prepattern in the maize leaf primordium

Author

Josh Strable, Samuel Leiboff, Anne W. Sylvester, Robyn Johnston, Silvia Federici, and Michael J. Scanlon

Subjects

0106 biological sciences, 0301 basic medicine, Physiology, Plant Science, Biology, 01 natural sciences, Zea mays, Transcriptome, 03 medical and health sciences, Gene Expression Regulation, Plant, medicine, Primordium, Plant Proteins, Auricle, Gene Expression Profiling, fungi, food and beverages, Computational Biology, Cell biology, Structure and function, Plant Leaves, Multicellular organism, 030104 developmental biology, medicine.anatomical_structure, Ligule, Boundary formation, 010606 plant biology & botany

Abstract

The formation of developmental boundaries is a common feature of multicellular plants and animals, and impacts the initiation, structure and function of all organs. Maize leaves comprise a proximal sheath that encloses the stem, and a distal photosynthetic blade that projects away from the plant axis. An epidermally derived ligule and a joint-like auricle develop at the blade/sheath boundary of maize leaves. Mutations disturbing the ligule/auricle region disrupt leaf patterning and impact plant architecture, yet it is unclear how this developmental boundary is established. Targeted microdissection followed by transcriptomic analyses of young leaf primordia were utilized to construct a co-expression network associated with development of the blade/sheath boundary. Evidence is presented for proximodistal gradients of gene expression that establish a prepatterned transcriptomic boundary in young leaf primordia, before the morphological initiation of the blade/sheath boundary in older leaves. This work presents a conceptual model for spatiotemporal patterning of proximodistal leaf domains, and provides a rich resource of candidate gene interactions for future investigations of the mechanisms of blade/sheath boundary formation in maize.

Published

2020

10. A maize LIPID TRANSFER PROTEIN may bridge the gap between PHYTOCHROME-mediated light signaling and cuticle biosynthesis

Author

Pengfei Qiao, Michael J. Scanlon, Michael A. Gore, Isabel Molina, Richard Bourgault, and Marc Mohammadi

Subjects

0106 biological sciences, 0301 basic medicine, Transgene, Cuticle, Short Communication, Arabidopsis, Plant Science, Biology, 01 natural sciences, Zea mays, 03 medical and health sciences, Gene Expression Regulation, Plant, Plant evolution, Phytochrome, Epidermis (botany), fungi, food and beverages, biology.organism_classification, Cell biology, Plant Leaves, 030104 developmental biology, Carrier Proteins, Plant lipid transfer proteins, Function (biology), 010606 plant biology & botany

Abstract

Plant epidermal cuticles are composed of hydrophobic lipids that provide a barrier to non-stomatal water loss, and arose in land plants as an adaptation to the dry terrestrial environment. The expanding maize adult leaf displays a dynamic, proximodistal gradient of cuticle development, from the leaf base to the tip. Recently, our gene co-expression network analyses together with reverse genetic analyses suggested a previously undescribed function for PHYTOCHROME-mediated light signaling during cuticular wax deposition. The present work extends these findings by identifying a role for a specific LIPID TRANSFER PROTEIN (LTP) in cuticle development, and validating it via transgenic experiments in Arabidopsis. Given that LTPs and cuticles both evolved in land plants and are absent from aquatic green algae, we propose that during plant evolution, LTPs arose as one of the innovations of land plants that enabled development of the cuticle.

Published

2020

11. Plant Development: How Leaves Take Shape

Author

Michael J. Scanlon and James W. Satterlee

Subjects

0301 basic medicine, Arabidopsis thaliana, Process (engineering), computational modelling, Plant Development, morphogenesis, Biology, Machine learning, computer.software_genre, Outcome (game theory), Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, organ shape, Simple (philosophy), KNOX, growth and patterning, business.industry, fungi, Cardamine hirsuta, food and beverages, Plant Leaves, RCO, Plant development, 030104 developmental biology, live-imaging, Artificial intelligence, General Agricultural and Biological Sciences, business, computer, leaf development, 030217 neurology & neurosurgery

Abstract

Summary How do genes modify cellular growth to create morphological diversity? We study this problem in two related plants with differently shaped leaves: Arabidopsis thaliana (simple leaf shape) and Cardamine hirsuta (complex shape with leaflets). We use live imaging, modeling, and genetics to deconstruct these organ-level differences into their cell-level constituents: growth amount, direction, and differentiation. We show that leaf shape depends on the interplay of two growth modes: a conserved organ-wide growth mode that reflects differentiation; and a local, directional mode that involves the patterning of growth foci along the leaf edge. Shape diversity results from the distinct effects of two homeobox genes on these growth modes: SHOOTMERISTEMLESS broadens organ-wide growth relative to edge-patterning, enabling leaflet emergence, while REDUCED COMPLEXITY inhibits growth locally around emerging leaflets, accentuating shape differences created by patterning. We demonstrate the predictivity of our findings by reconstructing key features of C. hirsuta leaf morphology in A. thaliana. Video Abstract, Graphical Abstract, Highlights • Complete growth and fate maps are made for C. hirsuta and A. thaliana leaf surfaces • Patterning of the leaf margin modifies organ-wide growth pattern to produce leaf shape • Altering growth relative to patterning generates leaf shape diversity • Reconstructing dissected leaf shape by combining STM and RCO in A. thaliana leaves, By understanding the impact of growth and patterning on leaf shape diversity, it is possible to convert the leaf morphology of A. thaliana to that of another plant species.

Published

2019

12. A functionally informed evolutionary framework for the study of LRR-RLKs during stem cell maintenance

Author

Joseph Cammarata and Michael J. Scanlon

Subjects

0106 biological sciences, 0301 basic medicine, Plant stem cell, Phylogenetic tree, Stem Cells, fungi, Protein domain, food and beverages, Plant Science, Biology, Genes, Plant, 01 natural sciences, Evolution, Molecular, 03 medical and health sciences, Magnoliopsida, 030104 developmental biology, Phylogenetics, Evolutionary biology, Stem cell, Clade, Gene, Function (biology), Phylogeny, 010606 plant biology & botany, Signal Transduction

Abstract

Plants maintain populations of stem cells to generate new organs throughout the course of their lives. The pathways that regulate plant stem cell maintenance have garnered great interest over the past decades, as variation in these pathways contributes plant morphological diversity and can be harnessed for crop improvement. In order to facilitate cross-species comparisons of gene function and better understand how these stem cell regulatory pathways evolved, we undertook a functionally informed phylogenetic analysis of leucine-rich receptor-like kinases (LRR-RLK) and related proteins across diverse land plant model systems. Based on our phylogenetic analysis and on functional data, we propose a naming scheme for these stem cell signaling genes. We discovered evidence for frequent loss of protein domains in angiosperms but not in bryophytes. In addition, several clades of stem cell signaling genes are closely related to genes that function in immunity, although these distinct developmental and immune functions likely separated or after the divergence of lycophytes and angiosperms. Overall, the phylogenetic framework and evolutionary hypotheses we provide here will empower future research on cross-species comparisons of stem cell signaling pathways.

Published

2020

13. Network analyses implicate a role for PHYTOCHROME-mediated light signaling in the regulation of cuticle development in plant leaves

Author

Marc Mohammadi, Pengfei Qiao, Isabel Molina, Laurie G. Smith, Michael J. Scanlon, Michael A. Gore, and Richard Bourgault

Subjects

0106 biological sciences, 2. Zero hunger, chemistry.chemical_classification, Plant evolution, 0303 health sciences, biology, Phytochrome, Cuticle, Mutant, fungi, food and beverages, Cutin, Physcomitrella patens, biology.organism_classification, 01 natural sciences, Cell biology, 03 medical and health sciences, chemistry, Auxin, Function (biology), 030304 developmental biology, 010606 plant biology & botany

Abstract

Plant cuticles are composed of wax and cutin, and evolved in the land plants as a hydrophobic boundary that reduces water loss from the plant epidermis. The expanding maize adult leaf displays a dynamic, proximodistal gradient of cuticle development, from the leaf base to the tip. Laser microdissection RNA Sequencing (LM-RNAseq) was performed along this proximodistal gradient, and complementary network analyses identified potential regulators of cuticle biosynthesis and deposition. Correlations between cuticle development and cell wall biosynthesis processes were identified, as well as evidence of roles for auxin and brassinosteroids. In addition, our network analyses suggested a previously undescribed function for PHYTOCHROME-mediated light signaling during cuticular wax deposition. Genetic analyses reveal that the phyB1 phyB2 double mutant of maize exhibits abnormal cuticle composition, supporting predictions of our coexpression analyses. Reverse genetic analyses also show that phy mutants of the moss Physcomitrella patens exhibit abnormal cuticle composition, suggesting a role for light-stimulated development of cuticular waxes during plant evolution.

Published

2019

14. Coordination of Leaf Development Across Developmental Axes

Author

James W. Satterlee and Michael J. Scanlon

Subjects

0106 biological sciences, 0301 basic medicine, Mutant, Plant Science, Review, Biology, 01 natural sciences, 03 medical and health sciences, transcription factors, Gene, Leaf development, Transcription factor, Ecology, Evolution, Behavior and Systematics, Ecology, leaf, fungi, Botany, food and beverages, differentiation, Meristem, Phenotype, developmental patterning, Cell biology, 030104 developmental biology, QK1-989, Shoot, Leaf morphogenesis, plant hormones, 010606 plant biology & botany

Abstract

Leaves are initiated as lateral outgrowths from shoot apical meristems throughout the vegetative life of the plant. To achieve proper developmental patterning, cell-type specification and growth must occur in an organized fashion along the proximodistal (base-to-tip), mediolateral (central-to-edge), and adaxial–abaxial (top-bottom) axes of the developing leaf. Early studies of mutants with defects in patterning along multiple leaf axes suggested that patterning must be coordinated across developmental axes. Decades later, we now recognize that a highly complex and interconnected transcriptional network of patterning genes and hormones underlies leaf development. Here, we review the molecular genetic mechanisms by which leaf development is coordinated across leaf axes. Such coordination likely plays an important role in ensuring the reproducible phenotypic outcomes of leaf morphogenesis.

Published

2019

15. Diversity of Maize Shoot Apical Meristem Architecture and Its Relationship to Plant Morphology

Author

James E. Crants, Gary J. Muehlbauer, Marja C.P. Timmermans, Patrick S. Schnable, Michael J. Scanlon, Jianming Yu, and Addie Thompson

Subjects

Plant stem cell, Genotype, QTL, Meristem, Quantitative Trait Loci, Population, Organogenesis, maize development, Investigations, Biology, Zea mays, Quantitative Trait, Heritable, Botany, heterosis, Genetics, Cluster Analysis, education, Molecular Biology, Genetic Association Studies, Genetics (clinical), shoot apical meristem, 2. Zero hunger, education.field_of_study, fungi, Chromosome Mapping, food and beverages, Genetic architecture, ABC model of flower development, Phenotype, Plant morphology, NAM, Shoot, Plant Shoots

Abstract

The shoot apical meristem contains a pool of undifferentiated stem cells and controls initiation of all aerial plant organs. In maize (Zea mays), leaves are formed throughout vegetative development; on transition to floral development, the shoot meristem forms the tassel. Due to the regulated balance between stem cell maintenance and organogenesis, the structure and morphology of the shoot meristem are constrained during vegetative development. Previous work identified loci controlling meristem architecture in a recombinant inbred line population. The study presented here expanded on this by investigating shoot apical meristem morphology across a diverse set of maize inbred lines. Crosses of these lines to common parents showed varying phenotypic expression in the F1, with some form of heterosis occasionally observed. An investigation of meristematic growth throughout vegetative development in diverse lines linked the timing of reproductive transition to flowering time. Phenotypic correlations of meristem morphology with adult plant traits showed an association between the meristem and flowering time, leaf shape, and yield traits, revealing links between the control and architecture of undifferentiated and differentiated plant organs. Finally, quantitative trait loci mapping was utilized to map the genetic architecture of these meristem traits in two divergent populations. Control of meristem architecture was mainly population-specific, with 15 total unique loci mapped across the two populations with only one locus identified in both populations.

Published

2015

16. Dissecting the molecular signatures of apical cell‐type shoot meristems from two ancient land plant lineages

Author

Michael J. Scanlon, Molly B. Edwards, Zhangjun Fei, Eric R. Schultz, Jocelyn K. C. Rose, Margaret H. Frank, Iben Sørensen, and Michael R. McKain

Subjects

Selaginellaceae, Vascular plant, Transcription, Genetic, Physiology, Equisetum, Meristem, Laser Capture Microdissection, Plant Science, Apical cell, Transcriptome, Selaginella moellendorffii, Gene Expression Regulation, Plant, Selaginella, Botany, RNA, Messenger, In Situ Hybridization, Phylogeny, biology, Gene Expression Profiling, fungi, food and beverages, biology.organism_classification, Up-Regulation, Equisetum arvense, Embryophyta

Abstract

Shoot apical meristem (SAM) structure varies markedly within the land plants. The SAMs of many seedless vascular plants contain a conspicuous inverted, pyramidal cell called the apical cell (AC), which is unidentified in angiosperms. In this study, we use transcriptomic sequencing with precise laser microdissections of meristem subdomains to define the molecular signatures of anatomically distinct zones from the AC-type SAMs of a lycophyte (Selaginella moellendorffii) and a monilophyte (Equisetum arvense). The two model species for this study represent vascular plant lineages that diverged > 400 million yr ago. Our data comprise comprehensive molecular signatures for the distinct subdomains within AC-type SAMs, an anatomical anomaly whose functional significance has been debated in the botanical literature for over two centuries. Moreover, our data provide molecular support for distinct gene expression programs between the AC-type SAMs of Selaginella and Equisetum, as compared with the SAM transcriptome of the angiosperm maize. The results are discussed in light of the functional significance and evolutionary success of the AC-type SAM within the embryophytes.

Published

2015

17. The Barley Uniculme4 Gene Encodes a BLADE-ON-PETIOLE-Like Protein That Controls Tillering and Leaf Patterning

Author

Robbie Waugh, Hatice Bilgic, Ron J. Okagaki, Michael J. Scanlon, Elahe Tavakol, Ruvini Ariyadasa, Axel Himmelbach, Vahid Shariati J, Gary J. Muehlbauer, Burkhard Steuernagel, Natalie R Todt, Nils Stein, Timothy J. Close, Gabriele Verderio, Arnis Druka, Ahmed Hussien, and Laura Rossini

Subjects

Ankyrins, Positional cloning, Physiology, Molecular Sequence Data, Arabidopsis, Locus (genetics), Flowers, Plant Science, Genes, Plant, Axillary bud, Botany, Genetics, Cloning, Molecular, Triticeae, Body Patterning, Plant Proteins, 2. Zero hunger, biology, Arabidopsis Proteins, fungi, food and beverages, Hordeum, Articles, 15. Life on land, biology.organism_classification, Plant Leaves, Phenotype, Ligule, Mutation, Hordeum vulgare, Plant Shoots

Abstract

Tillers are vegetative branches that develop from axillary buds located in the leaf axils at the base of many grasses. Genetic manipulation of tillering is a major objective in breeding for improved cereal yields and competition with weeds. Despite this, very little is known about the molecular genetic bases of tiller development in important Triticeae crops such as barley (Hordeum vulgare) and wheat (Triticum aestivum). Recessive mutations at the barley Uniculme4 (Cul4) locus cause reduced tillering, deregulation of the number of axillary buds in an axil, and alterations in leaf proximal-distal patterning. We isolated the Cul4 gene by positional cloning and showed that it encodes a BROAD-COMPLEX, TRAMTRACK, BRIC-À-BRAC-ankyrin protein closely related to Arabidopsis (Arabidopsis thaliana) BLADE-ON-PETIOLE1 (BOP1) and BOP2. Morphological, histological, and in situ RNA expression analyses indicate that Cul4 acts at axil and leaf boundary regions to control axillary bud differentiation as well as the development of the ligule, which separates the distal blade and proximal sheath of the leaf. As, to our knowledge, the first functionally characterized BOP gene in monocots, Cul4 suggests the partial conservation of BOP gene function between dicots and monocots, while phylogenetic analyses highlight distinct evolutionary patterns in the two lineages.

Published

2015

18. Ontogeny of the sheathing leaf base in maize (Zea mays)

Author

Samuel Leiboff, Robyn Johnston, and Michael J. Scanlon

Subjects

Physiology, Ontogeny, Plant Science, Biology, Models, Biological, Zea mays, Imaging, Three-Dimensional, Gene Expression Regulation, Plant, Auxin, Botany, Primordium, RNA, Messenger, Process (anatomy), Body Patterning, chemistry.chemical_classification, Indoleacetic Acids, fungi, food and beverages, Biological Transport, Meristem, Transport protein, Plant Leaves, chemistry, Shoot, Tomography, X-Ray Computed, Basipetal auxin transport

Abstract

Leaves develop from the shoot apical meristem (SAM) via recruitment of leaf founder cells. Unlike eudicots, most monocot leaves display parallel venation and sheathing bases wherein the margins overlap the stem. Here we utilized computed tomography (CT) imaging, localization of PIN-FORMED1 (PIN1) auxin transport proteins, and in situ hybridization of leaf developmental transcripts to analyze the ontogeny of monocot leaf morphology in maize (Zea mays). CT imaging of whole-mounted shoot apices illustrates the plastochron-specific stages during initiation of the basal sheath margins from the tubular disc of insertion (DOI). PIN1 localizations identify basipetal auxin transport in the SAM L1 layer at the site of leaf initiation, a process that continues reiteratively during later recruitment of lateral leaf domains. Refinement of these auxin transport domains results in multiple, parallel provascular strands within the initiating primordium. By contrast, auxin is transported from the L2 toward the L1 at the developing margins of the leaf sheath. Transcripts involved in organ boundary formation and dorsiventral patterning accumulate within the DOI, preceding the outgrowth of the overlapping margins of the sheathing leaf base. We suggest a model wherein sheathing bases and parallel veins are both patterned via the extended recruitment of lateral maize leaf domains from the SAM.

Published

2014

19. Genetic Control of Maize Shoot Apical Meristem Architecture

Author

Patrick S. Schnable, Marja C.P. Timmermans, Michael J. Scanlon, Nathan M. Springer, Addie Thompson, Jianming Yu, James E. Crants, and Gary J. Muehlbauer

Subjects

QTL, IBMRIL, Population, Meristem, Quantitative Trait Loci, Vegetative meristem growth, maize development, Biology, Quantitative trait locus, Investigations, Zea mays, Transgressive segregation, Chromosomes, Plant, Genetic variation, Botany, Genetics, education, Molecular Biology, Genetics (clinical), 2. Zero hunger, shoot apical meristem, education.field_of_study, plant morphology, fungi, food and beverages, Chromosome Mapping, Genetic Variation, ABC model of flower development, Phenotype, Plastochron, Plant Shoots

Abstract

The shoot apical meristem contains a pool of undifferentiated stem cells and generates all above-ground organs of the plant. During vegetative growth, cells differentiate from the meristem to initiate leaves while the pool of meristematic cells is preserved; this balance is determined in part by genetic regulatory mechanisms. To assess vegetative meristem growth and genetic control in Zea mays, we investigated its morphology at multiple time points and identified three stages of growth. We measured meristem height, width, plastochron internode length, and associated traits from 86 individuals of the intermated B73 × Mo17 recombinant inbred line population. For meristem height-related traits, the parents exhibited markedly different phenotypes, with B73 being very tall, Mo17 short, and the population distributed between. In the outer cell layer, differences appeared to be related to number of cells rather than cell size. In contrast, B73 and Mo17 were similar in meristem width traits and plastochron internode length, with transgressive segregation in the population. Multiple loci (6−9 for each trait) were mapped, indicating meristem architecture is controlled by many regions; none of these coincided with previously described mutants impacting meristem development. Major loci for height and width explaining 16% and 19% of the variation were identified on chromosomes 5 and 8, respectively. Significant loci for related traits frequently coincided, whereas those for unrelated traits did not overlap. With the use of three near-isogenic lines, a locus explaining 16% of the parental variation in meristem height was validated. Published expression data were leveraged to identify candidate genes in significant regions.

Published

2014

20. Meristems take their cues from organ primordia

Author

Michael J. Scanlon and Josh Strable

Subjects

0301 basic medicine, Plant stem cell, fungi, Meristem, Arabidopsis, food and beverages, Biology, Genes, Plant, Cell biology, 03 medical and health sciences, Multicellular organism, 030104 developmental biology, Gene Expression Regulation, Plant, Botany, Mutation, Genetics, Primordium, Stem cell, Cues, Plant genes

Abstract

Stem cell regulation is critical to the development of all multicellular organisms; in plants, stem cell niches reside in meristems. Two newly identified plant genes establish a novel signaling feedback from the incipient leaf primordia back to the meristem that is required to regulate stem cell proliferation.

Published

2016

21. Ontogeny of the Maize Shoot Apical Meristem

Author

Qi Sun, Gary J. Muehlbauer, Patrick S. Schnable, Marja C.P. Timmermans, Michael J. Scanlon, Jie Li, Dan Nettleton, Elizabeth M. Takacs, Chuanlong Du, Jianming Yu, Diane Janick-Buckner, and Lalit Ponnala

Subjects

Regulation of gene expression, Ontogeny, fungi, Embryogenesis, food and beverages, Embryo, Organogenesis, Cell Biology, Plant Science, Meristem, Biology, Transcriptome, Botany, Shoot

Abstract

The maize (Zea mays) shoot apical meristem (SAM) arises early in embryogenesis and functions during stem cell maintenance and organogenesis to generate all the aboveground organs of the plant. Despite its integral role in maize shoot development, little is known about the molecular mechanisms of SAM initiation. Laser microdissection of apical domains from developing maize embryos and seedlings was combined with RNA sequencing for transcriptomic analyses of SAM ontogeny. Molecular markers of key events during maize embryogenesis are described, and comprehensive transcriptional data from six stages in maize shoot development are generated. Transcriptomic profiling before and after SAM initiation indicates that organogenesis precedes stem cell maintenance in maize; analyses of the first three lateral organs elaborated from maize embryos provides insight into their homology and to the identity of the single maize cotyledon. Compared with the newly initiated SAM, the mature SAM is enriched for transcripts that function in transcriptional regulation, hormonal signaling, and transport. Comparisons of shoot meristems initiating juvenile leaves, adult leaves, and husk leaves illustrate differences in phase-specific (juvenile versus adult) and meristem-specific (SAM versus lateral meristem) transcript accumulation during maize shoot development. This study provides insight into the molecular genetics of SAM initiation and function in maize.

Published

2012

22. WOX4 Promotes Procambial Development

Author

Daniel Koenig, Rena Shimizu, Jiabing Ji, Neelima Sinha, Josh Strable, and Michael J. Scanlon

Subjects

biology, Physiology, fungi, food and beverages, Xylem, Plant Science, Meristem, Vascular bundle, biology.organism_classification, Cell biology, Ground tissue, Arabidopsis, Botany, Genetics, Vascular cambium, Homeobox, Phloem

Abstract

Plant shoot organs arise from initial cells that are recruited from meristematic tissues. Previous studies have shown that members of the WUSCHEL-related HOMEOBOX (WOX) gene family function to organize various initial cell populations during plant development. The function of the WOX4 gene is previously undescribed in any plant species. Comparative analyses of WOX4 transcription and function are presented in Arabidopsis (Arabidopsis thaliana), a simple-leafed plant with collateral vasculature, and in tomato (Solanum lycopersicum), a dissected-leafed species with bicollateral venation. WOX4 is transcribed in the developing vascular bundles of root and shoot lateral organs in both Arabidopsis and tomato. RNA interference-induced down-regulation of WOX4 in Arabidopsis generated small plants whose vascular bundles accumulated undifferentiated ground tissue and exhibited severe reductions in differentiated xylem and phloem. In situ hybridization analyses of Atwox4-RNA interference plants revealed delayed and reduced expression of both the phloem developmental marker ALTERED PHLOEM1 and HOMEOBOX GENE8, a marker of the vascular procambium. Overexpression of SlWOX4 correlated with overproliferation of xylem and phloem in transgenic tomato seedlings. The cumulative data suggest that the conserved WOX4 function is to promote differentiation and/or maintenance of the vascular procambium, the initial cells of the developing vasculature.

Published

2009

23. Tissue Specificity and Evolution of Meristematic WOX3 Function

Author

Patrick S. Schnable, Jiabing Ji, Kazuhiro Ohtsu, Michael J. Scanlon, Eric Kelsey, and Rena Shimizu

Subjects

DNA, Plant, Physiology, Meristem, Molecular Sequence Data, Mutant, Arabidopsis, Plant Science, Evolution, Molecular, Transcription (biology), Ribose-Phosphate Pyrophosphokinase, Genetics, Promoter Regions, Genetic, Gene, Homeodomain Proteins, biology, Arabidopsis Proteins, fungi, food and beverages, Promoter, biology.organism_classification, Mutation, Subfunctionalization, Homeobox, Transcription Factors, Research Article

Abstract

The WUSCHEL-related homeobox (WOX) gene PRESSED FLOWER1 (PRS1) performs a conserved function during lateral organ development in Arabidopsis (Arabidopsis thaliana). Expressed in the periphery of the shoot meristem, PRS1 recruits founder cells that form lateral domains of vegetative and floral organs. Null mutations in PRS1 cause the deletion of lateral stipules from leaves and of lateral sepals and stamens from flowers. Although PRS1 expression is described in the L1 layer, PRS1 recruits founder cells from all meristem layers. The mechanism of non-cell autonomous PRS1 function and the evolution of disparate WOX gene functions are investigated herein. Meristem layer-specific promoters reveal that both L1 and L1-L2 expression of PRS1 fail to fully rescue PRS1 function, and PRS1 protein does not traffic laterally or transversely between shoot meristem layers. PRS1 protein accumulates within all meristematic cell layers (L1-L2-L3) when expressed from the native promoter, presumably due to low-level transcription in the L2 and L3 layers. When driven from the PRS1 promoter, full rescue of vegetative and floral prs1 mutant phenotypes is provided by WUSCHEL1 (WUS1), which is normally expressed in the stem cell organizing center of shoot meristems. The data reveal that WUS1 and PRS1 can engage in equivalent protein-protein interactions and direct transcription of conserved target genes, suggesting that their subfunctionalization has evolved primarily via diverse promoter specificity. Unexpectedly, these results also suggest that meristematic stem cells and lateral organ founder cells are intrinsically similar and formed via equivalent processes such that their ultimate fate is dependent upon stage-specific and domain-specific positional signaling.

Published

2008

24. Leaves of grass: focusing phenomics on maize leaf growth

Author

Michael J. Scanlon

Subjects

Transcriptome, Phenomics, Research, fungi, Botany, Related research, food and beverages, Biology, Zea mays, Human genetics

Abstract

Background To sustain the global requirements for food and renewable resources, unraveling the molecular networks underlying plant growth is becoming pivotal. Although several approaches to identify genes and networks involved in final organ size have been proven successful, our understanding remains fragmentary. Results Here, we assessed variation in 103 lines of the Zea mays B73xH99 RIL population for a set of final leaf size and whole shoot traits at the seedling stage, complemented with measurements capturing growth dynamics, and cellular measurements. Most traits correlated well with the size of the division zone, implying that the molecular basis of final leaf size is already defined in dividing cells of growing leaves. Therefore, we searched for association between the transcriptional variation in dividing cells of the growing leaf and final leaf size and seedling biomass, allowing us to identify genes and processes correlated with the specific traits. A number of these genes have a known function in leaf development. Additionally, we illustrated that two independent mechanisms contribute to final leaf size, maximal growth rate and the duration of growth. Conclusions Untangling complex traits such as leaf size by applying in-depth phenotyping allows us to define the relative contributions of the components and their mutual associations, facilitating dissection of the biological processes and regulatory networks underneath. Electronic supplementary material The online version of this article (doi:10.1186/s13059-015-0735-9) contains supplementary material, which is available to authorized users.

Published

2015

25. Radial leaves of the maize mutant ragged seedling2 retain dorsiventral anatomy

Author

David C. Henderson, Michael J. Scanlon, and Gary J. Muehlbauer

Subjects

Cell type, Dorsiventral, Mutant, Meristem, Biology, medicine.disease_cause, Genes, Plant, Models, Biological, Zea mays, Founder cells, Gene expression, medicine, Primordium, Molecular Biology, In Situ Hybridization, Regulation of gene expression, Mutation, Leaf development, fungi, food and beverages, Gene Expression Regulation, Developmental, Anatomy, Cell Biology, Vascular bundle, Phenotype, Immunohistochemistry, Maize, Plant Leaves, SAM, Microscopy, Electron, Scanning, Signal Transduction, Developmental Biology

Abstract

ragged seedling2 (rgd2) is a novel, recessive mutation affecting lateral organ development in maize. The mutant phenotype of homozygous rgd2-R leaves is variable. Mild leaf phenotypes have a reduced midrib and may be moderately narrow and furcated; severe Rgd2-R− leaves are filamentous or even radial. Despite their radial morphology, severe Rgd2-R− mutant leaves develop distinct adaxial and abaxial anatomical features. Although Rgd2-R− mutants exhibit no reduction in adaxial or abaxial cell types, areas of epidermal cell swapping may occur that are associated with misaligned vascular bundles and outgrowths of ectopic margins. Scanning electron microscopy of young primordia and analyses of leaf developmental-marker gene expression in mutant apices reveal that RGD2 functions during recruitment of leaf founder cells and during expansive growth of leaf primordia. Overall, these phenotypes suggest that development is uncoordinated in Rgd2-R− mutant leaves, so that leaf components and tissues may develop quasi-independently. Models whereby RGD2 is required for developmental signaling during the initiation, anatomical patterning, and lateral expansion of maize leaves are discussed.

Published

2005

26. The Polar Auxin Transport InhibitorN-1-Naphthylphthalamic Acid Disrupts Leaf Initiation, KNOX Protein Regulation, and Formation of Leaf Margins in Maize

Author

Michael J. Scanlon

Subjects

Physiology, Phthalimides, Plant Science, Biology, Zea mays, Lycopersicon, Gene Expression Regulation, Plant, Auxin, Arabidopsis, Botany, Genetics, Poaceae, Primordium, Cells, Cultured, Plant Proteins, Homeodomain Proteins, chemistry.chemical_classification, Indoleacetic Acids, fungi, food and beverages, Biological Transport, Meristem, biology.organism_classification, Plant Leaves, chemistry, Shoot, Microscopy, Electron, Scanning, Polar auxin transport, Plant Shoots, Research Article

Abstract

Maize (Zea mays) leaves develop basipetally (tip to base); the upper blade emerges from the shoot apical meristem (SAM) before the expansion of the lower sheath. Founder cells, leaf initials located in the periphery of the SAM, are distinguished from the SAM proper by the differential accumulation of KNOX proteins. KNOX proteins accumulate in the SAM, but are excluded from maize leaf primordia and leaf founder cells. As in Arabidopsis and tomato (Lycopersicon esculentum), maize shoots failed to initiate new leaves when cultured in the polar auxin transport inhibitor N-1-naphthylphthalamic acid (NPA). We demonstrate that NPA-induced arrest of leaf initiation in maize is correlated with the failure to down-regulate KNOX accumulation in the SAM. In addition, NPA-cultured shoots formed abnormal tubular leaf bases in which the margins failed to separate in the lower leaf zone. The tubular leaf bases always formed in the fourth leaf from the arrested meristem. Moreover, the unseparated margin domains of these tubular leaf bases accumulated ectopic KNOX protein(s). Transfer of NPA-cultured apices to NPA-free media resulted in the resumption of leaf initiation from the SAM and the restoration of normal patterns of KNOX down-regulation, accordingly. These data suggest that the lower sheath margins emerge from the leaf base late in maize leaf development and that the separation of these leaf margin domains is correlated with auxin transport and down-regulation of KNOX proteins. In addition, these results suggest that the down-regulation of KNOX accumulation in maize apices is not upstream of polar auxin transport, although a more complicated feedback network may exist. A model for L1-derived margin development in maize leaves is presented.

Published

2003

27. SEMAPHORE1 functions during the regulation of ancestrally duplicatedknoxgenes and polar auxin transport in maize

Author

Michael J. Scanlon, David C. Henderson, and Brad Bernstein

Subjects

Genetics, chemistry.chemical_classification, Regulation of gene expression, Indoleacetic Acids, Transcription, Genetic, fungi, Mutant, Gene Expression Regulation, Developmental, food and beverages, Meristem, Biology, Zea mays, Repressor Proteins, Gene product, Protein Transport, chemistry, Gene Expression Regulation, Plant, Mutagenesis, Auxin, Ectopic expression, Polar auxin transport, Molecular Biology, Gene, Plant Proteins, Developmental Biology

Abstract

The expression of class 1 knotted1-like homeobox (knox) genes affects numerous plant developmental processes, including cell-fate acquisition, lateral organ initiation, and maintenance of shoot apical meristems. The SEMAPHORE1 gene product is required for the negative regulation of a subset of maize knox genes, the duplicated loci rough sheath 1 and gnarley1 (knox4). Recessive mutations in semaphore1 result in the ectopic expression of knox genes in leaf and endosperm tissue. Genetic analyses suggest that SEMAPHORE1 may regulate knox gene expression in a different developmental pathway than ROUGH SHEATH2, the first-identified regulator of knox gene expression in maize. Mutations at semaphore1 are pleiotropic, disrupting specific domains of the shoot. However, unlike previously described mutations that cause ectopic knox gene expression, semaphore1 mutations affect development of the embryo, endosperm, lateral roots, and pollen. Moreover, polar transport of the phytohormone auxin is significantly reduced in semaphore1 mutant shoots. The data suggest that many of the pleiotropic semaphore1 phenotypes result from defective polar auxin transport (PAT) in sem1 mutant shoots, and support models correlating down-regulated knox gene expression and PAT in maize shoots.

Published

2002

28. Transcriptomic analyses indicate that maize ligule development recapitulates gene expression patterns that occur during lateral organ initiation

Author

Sarah Hake, Minghui Wang, Michael J. Scanlon, Robyn Johnston, Qi Sun, and Anne W. Sylvester

Subjects

Genetics, Regulation of gene expression, Gene Expression Profiling, fungi, Mutant, food and beverages, Computational Biology, Cell Biology, Plant Science, Biology, Zea mays, Gene expression profiling, Transcriptome, Ligule, Gene Expression Regulation, Plant, Primordium, RNA, Messenger, Gene, Research Articles, Laser capture microdissection, Signal Transduction

Abstract

Development of multicellular organisms proceeds via the correct interpretation of positional information to establish boundaries that separate developmental fields with distinct identities. The maize (Zea mays) leaf is an ideal system to study plant morphogenesis as it is subdivided into a proximal sheath and a distal blade, each with distinct developmental patterning. Specialized ligule and auricle structures form at the blade-sheath boundary. The auricles act as a hinge, allowing the leaf blade to project at an angle from the stem, while the ligule comprises an epidermally derived fringe. Recessive liguleless1 mutants lack ligules and auricles and have upright leaves. We used laser microdissection and RNA sequencing to identify genes that are differentially expressed in discrete cell/tissue-specific domains along the proximal-distal axis of wild-type leaf primordia undergoing ligule initiation and compared transcript accumulation in wild-type and liguleless1-R mutant leaf primordia. We identified transcripts that are specifically upregulated at the blade-sheath boundary. A surprising number of these “ligule genes” have also been shown to function during leaf initiation or lateral branching and intersect multiple hormonal signaling pathways. We propose that genetic modules utilized in leaf and/or branch initiation are redeployed to regulate ligule outgrowth from leaf primordia.

Published

2014

29. Transcriptomic evidence for the evolution of shoot meristem function in sporophyte-dominant land plants through concerted selection of ancestral gametophytic and sporophytic genetic programs

Author

Michael J. Scanlon and Margaret H. Frank

Subjects

Gametophyte, biology, Physcomitrella, fungi, Meristem, Marchantia, food and beverages, Sporophyte, Apical cell, biology.organism_classification, Physcomitrella patens, Biological Evolution, Bryopsida, Evolution, Molecular, Gene Expression Regulation, Plant, Botany, Alternation of generations, Genetics, Germ Cells, Plant, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Plant Proteins

Abstract

Alternation of generations, in which the haploid and diploid stages of the life cycle are each represented by multicellular forms that differ in their morphology, is a defining feature of the land plants (embryophytes). Anciently derived lineages of embryophytes grow predominately in the haploid gametophytic generation from apical cells that give rise to the photosynthetic body of the plant. More recently evolved plant lineages have multicellular shoot apical meristems (SAMs), and photosynthetic shoot development is restricted to the sporophyte generation. The molecular genetic basis for this evolutionary shift from gametophyte-dominant to sporophyte-dominant life cycles remains a major question in the study of land plant evolution. We used laser microdissection and next generation RNA sequencing to address whether angiosperm meristem patterning genes expressed in the sporophytic SAM of Zea mays are expressed in the gametophytic apical cells, or in the determinate sporophytes, of the model bryophytes Marchantia polymorpha and Physcomitrella patens. A wealth of upregulated genes involved in stem cell maintenance and organogenesis are identified in the maize SAM and in both the gametophytic apical cell and sporophyte of moss, but not in Marchantia. Significantly, meiosis-specific genetic programs are expressed in bryophyte sporophytes, long before the onset of sporogenesis. Our data suggest that this upregulated accumulation of meiotic gene transcripts suppresses indeterminate cell fate in the Physcomitrella sporophyte, and overrides the observed accumulation of meristem patterning genes. A model for the evolution of indeterminate growth in the sporophytic generation through the concerted selection of ancestral meristem gene programs from gametophyte-dominant lineages is proposed.

Published

2014

30. NARROW SHEATH1 functions from two meristematic foci during founder-cell recruitment in maize leaf development

Author

Michael J. Scanlon

Subjects

viruses, Meristem, Mutant, Biology, Genes, Plant, medicine.disease_cause, Zea mays, Genes, Duplicate, Botany, medicine, Founder cell, Molecular Biology, Gene, Leaf development, Plant Proteins, Mutation, Homozygote, fungi, Chromosome Mapping, food and beverages, Phenotype, Cell biology, Plant Leaves, Function (biology), Developmental Biology

Abstract

The narrow sheath duplicate genes (ns1 and ns2) perform redundant functions during maize leaf development. Plants homozygous for mutations in both ns genes fail to develop wild-type leaf tissue in a lateral domain that includes the leaf margin. Previous studies indicated that the NS gene product(s) functions during recruitment of leaf founder-cells in a lateral, meristematic domain that contributes to leaf margin development. A mosaic analysis was performed in which the ns1-O mutation was exposed in hemizygous, clonal sectors in a genetic background already homozygous for ns2-O. Analyses of mutant, sectored plants demonstrate that NS1 function is required in L2-derived tissue layers for development of the narrow sheath leaf domain. NS1 function is not required for development of the central region of maize leaves. Furthermore, the presence of the non-mutant ns1 gene outside the narrow sheath domain cannot compensate for the absence of the non-mutant gene within the narrow sheath domain. NS1 acts non-cell autonomously within the narrow sheath-margin domain and directs recruitment of marginal, leaf founder cells from two discrete foci in the maize meristem. Loss of NS1 function during later stages of leaf development results in no phenotypic consequences. These data support our model for NS function during founder-cell recruitment in the maize meristem.

Published

2000

31. Developmental complexities of simple leaves

Author

Michael J. Scanlon

Subjects

Body Patterning, biology, Meristem, fungi, Morphogenesis, food and beverages, Plant Science, Plasmodesma, Phyllotaxis, Compartmentalization (psychology), biology.organism_classification, Cell biology, Plant Leaves, Magnoliopsida, Botany, Shoot, Arabidopsis thaliana, Cell Lineage

Abstract

Recent papers have explored early events in the development of simple leaves. Functional compartmentalization of the shoot apical meristem correlates with distinct fields of cells connected by plasmodesmata. Molecules important in the initiation of phyllotactic pattern are described and the relationship between dorsoventral patterning and lateral leaf expansion is investigated.

Published

2000

32. The maize gene empty pericarp-2 is required for progression beyond early stages of embryogenesis

Author

Richard Schneeberger, Michael Freeling, Alan M. Myers, and Michael J. Scanlon

Subjects

Genetics, Mutation, fungi, Embryogenesis, Mutant, food and beverages, Embryo, Cell Biology, Plant Science, Meristem, Scutellum, Biology, medicine.disease_cause, Endosperm, Coleoptile, embryonic structures, medicine

Abstract

Summary The defective kernel mutation empty pericarp2-R (emp2-R) causes retardation and subsequent abortion of maize kernel development. Analyses of genetic aneuploid kernels indicate that the embryo phenotype is not dependent on the endosperm genotype; the mutation conditions embryo defects even in the presence of a normal endosperm. Embryos reach an abnormal coleoptilar stage before aborting and disintegrating. The mutants form primary embryonic organs only; the scutellum and coleoptile develop, but no leaves are formed. Immunohisto-localization studies utilized KNOX homeodomain proteins as markers of meristem formation and identity. These analyses indicate that the shoot meristem forms in emp2-R mutant embryos, but does not mature to a tunica-corpus shape. No evidence of leaf founder cell initialization was revealed in the mutant meristems. These data indicate that the emp2 gene may be required for embryogenic patterning beyond the coleoptilar stage of development.

Published

1997

33. Clonal Sectors Reveal That a Specific Meristematic Domain Is Not Utilized in the Maize Mutantnarrow sheath

Author

Michael J. Scanlon and Michael Freeling

Subjects

0106 biological sciences, Plant stem cell, Lineage (genetic), Meristem, Mutant, Population, Cell lineage, Biology, Zea mays, 01 natural sciences, 03 medical and health sciences, Species Specificity, Botany, education, Molecular Biology, 030304 developmental biology, 0303 health sciences, education.field_of_study, fungi, food and beverages, Cell Biology, Phenotype, Plant Leaves, Lateral region, Microscopy, Electron, Scanning, 010606 plant biology & botany, Developmental Biology

Abstract

The narrow leaf and shortened stem phenotypes of the maize mutant narrow sheath (ns) are postulated to result from the lack of founder cell initialization in a region of the meristem that gives rise to leaf and stem margins. To test this model, a lineage map of the maize meristem is presented which compares the development of leaf margins in the narrow leaf mutant, narrow sheath (ns), and wild-type sibling plants. X-irradiation of mature seeds produced aneuploid albino sectors in wild-type and ns mutant plants. Of particular interest are sectors occurring in more than one leaf, which reflect a meristematic albino cell lineage. Analyses of these sectors indicated that: (1) a region of the ns meristem does not contribute to the founder cell population of the incipient leaf; (2) the margins of ns mutant leaves are derived from a lateral region of the meristem different from those in wild-type siblings; (3) founder cells in wild-type, juvenile-staged vegetative meristems encircle the meristem to a greater extent than do founder cells in adult-staged meristems; and (4) meristematic leaf founder cells may be subdivided into specific lateral domains, such that the position of a sector on the meristem correlates with a particular cell lineage. These data support our model fornsgene function in a specific domain of the meristem.

Published

1997

34. The maize mutant narrow sheath fails to establish leaf margin identity in a meristematic domain

Author

Michael J. Scanlon, Richard Schneeberger, and Michael Freeling

Subjects

Meristem, Mutant, Morphogenesis, Gene Expression, Organogenesis, Biology, medicine.disease_cause, Plant Roots, Zea mays, medicine, Animals, Molecular Biology, Gene, Plant stem, Homeodomain Proteins, Genetics, Mutation, fungi, food and beverages, Phenotype, Plant Leaves, Rabbits, Developmental Biology

Abstract

The maize mutant narrow sheath (ns) displays a leaf shape and plant stature phenotype that suggests the preprimordial deletion of a leaf domain. The ns mutant phenotype is inherited as a recessive, duplicate-factor trait, conditioned upon homozygosity for each of the two unlinked mutations narrow sheath-1 (ns1) and narrow sheath-2 (ns2). Mutant leaves are missing a large domain including the leaf margin, and mutant internodes are shortened on the marginal side of the stem. This domain deletion extends from the internode to beyond the longitudinal mid-length of the blade, and corresponds to an alteration in the organization of a specific region of the shoot apical meristem. The premargin region of mutant founder cells fail to down-regulate expression of Knox genes, markers of nonleaf meristematic identity. Our results indicate that leaf domains may acquire identity in the meristem itself, and that the subdivision of preprimordial developmental fields into differential domains is a common feature of both plant and animal organogenesis.

Published

1996

35. Discolored1 (DSC1) is an ADP-Ribosylation Factor-GTPase Activating Protein Required to Maintain Differentiation of Maize Kernel Structures

Author

Michael J. Scanlon, Masaharu Suzuki, and Elizabeth M. Takacs

Subjects

0106 biological sciences, GTPase-activating protein, ADP ribosylation factor, Mutant, dsc1, Transposon tagging, embryo, Plant Science, lcsh:Plant culture, Biology, maize, 01 natural sciences, Endosperm, endosperm, 03 medical and health sciences, ADP-ribosylation factor-GTPase activating protein (ARF-GAP), lcsh:SB1-1110, Endomembrane system, Gene, endomembrane trafficking, Original Research, 030304 developmental biology, Genetics, 0303 health sciences, fungi, food and beverages, Embryo, ADP-RIBOSYLATION FACTOR-GTPase ACTIVATING PROTEIN, 010606 plant biology & botany

Abstract

The embryo and endosperm are the products of double fertilization and comprise the clonally distinct products of angiosperm seed development. Recessive mutations in the maize gene discolored1 (dsc1) condition inviable seed that are defective in both embryo and endosperm development. Here, detailed phenotypic analyses illustrate that discolored mutant kernels are able to establish, but fail to maintain, differentiated embryo, and endosperm structures. Development of the discolored mutant embryo and endosperm is normal albeit delayed, prior to the abortion and subsequent degeneration of all differentiated kernel structures. Using a genomic fragment that was previously isolated by transposon tagging, the full length dsc1 transcript is identified and shown to encode an ADP-ribosylation factor-GTPase activating protein (ARF-GAP) that co-localizes with the trans-Golgi network/early endosomes and the plasma membrane during transient expression assays in N. benthamiana leaves. DSC1 function during endomembrane trafficking and the maintenance of maize kernel differentiation is discussed.

Published

2012

36. Mutagenesis by Transitive RNAi

Author

Richard A. Jorgensen, Chonglie Ma, Katherine Petsch, and Michael J. Scanlon

Subjects

education.field_of_study, RNA silencing, RNA interference, fungi, Population, Genetic redundancy, Gene family, Mutagenesis (molecular biology technique), Gene silencing, Computational biology, Biology, education, Gene

Abstract

Transitive RNAi is a posttranscriptional mechanism of gene silencing that is based on the phenomenon of “transitivity.” This term refers to the spreading of silencing outside of the initial target sequence and is associated with transgene-induced posttranscriptional gene silencing (PTGS). Transitive RNAi is triggered by placing an inverted repeat sequence immediately 3′ of the sense transgene that is to be targeted. Placement of the inverted repeat in this region is thought to increase the efficiency by which RDR6 initiates copying of the transgene to generate double-stranded RNA (dsRNA). In a proof-of-concept approach, we showed that select subsets of genes can be manipulated with transitive RNAi in a high-throughput forward mutagenesis approach (Plant J 61:873–882, 2010). Laser microdissection of Arabidopsis mesophyll cells and en masse cloning of the resulting cDNA libraries into transitive RNAi vectors demonstrated that approximately 15% of genes in the pilot study could generate visible phenotypes, resulting in photosynthetic defects. The capacity for transitive RNAi to silence multiple members of gene family members demonstrated the utility of this approach for forward mutagenesis of redundant gene functions. Targeted silencing of a focused population of gene transcripts by transitive RNAi provides an efficient and complementary approach to procedures that target the entire genome. The ability of RNAi to target closely related genes holds promise for its use in forward mutagenesis of polyploid plants, which exhibit high levels of genetic redundancy. Advantages of transitive RNAi as a forward genetic approach, as well as potential drawbacks to this method, are discussed.

Published

2011

37. A Maize Thiamine Auxotroph Is Defective in Shoot Meristem Maintenance[C][W][OA]

Author

Maria Rapala-Kozik, N. Dinuka Abeydeera, Michael Freeling, Paula McSteen, Steven E. Ealick, Michael J. Scanlon, Debamita Paul, Tadhg P. Begley, Kimberly A. Phillips, and John B. Woodward

Subjects

Positional cloning, Cell division, Mutant, Meristem, Molecular Sequence Data, Mutation, Missense, Organogenesis, Plant Science, Biology, Zea mays, Gene Expression Regulation, Plant, Thiamine, Cloning, Molecular, Research Articles, Plant Proteins, fungi, food and beverages, Cell Biology, Meristem maintenance, Plant Leaves, Stem cell division, Biochemistry, human activities, Plant Shoots

Abstract

Plant shoots undergo organogenesis throughout their life cycle via the perpetuation of stem cell pools called shoot apical meristems (SAMs). SAM maintenance requires the coordinated equilibrium between stem cell division and differentiation and is regulated by integrated networks of gene expression, hormonal signaling, and metabolite sensing. Here, we show that the maize (Zea mays) mutant bladekiller1-R (blk1-R) is defective in leaf blade development and meristem maintenance and exhibits a progressive reduction in SAM size that results in premature shoot abortion. Molecular markers for stem cell maintenance and organ initiation reveal that both of these meristematic functions are progressively compromised in blk1-R mutants, especially in the inflorescence and floral meristems. Positional cloning of blk1-R identified a predicted missense mutation in a highly conserved amino acid encoded by thiamine biosynthesis2 (thi2). Consistent with chromosome dosage studies suggesting that blk1-R is a null mutation, biochemical analyses confirm that the wild-type THI2 enzyme copurifies with a thiazole precursor to thiamine, whereas the mutant enzyme does not. Heterologous expression studies confirm that THI2 is targeted to chloroplasts. All blk1-R mutant phenotypes are rescued by exogenous thiamine supplementation, suggesting that blk1-R is a thiamine auxotroph. These results provide insight into the role of metabolic cofactors, such as thiamine, during the proliferation of stem and initial cell populations.

Published

2010

38. Analyses of WOX4 transgenics provide further evidence for the evolution of the WOX gene family during the regulation of diverse stem cell functions

Author

Michael J. Scanlon, Neelima Sinha, Jiabing Ji, and Rena Shimizu

Subjects

DNA, Plant, Arabidopsis, Plant Science, Phloem, Plant Roots, Solanum lycopersicum, Gene Expression Regulation, Plant, Xylem, Gene family, Cloning, Molecular, Gene, Transcription factor, Genetics, Homeodomain Proteins, biology, Arabidopsis Proteins, Development and Hormone Action, fungi, food and beverages, Chromosome Mapping, Gene Expression Regulation, Developmental, Promoter, Meristem, biology.organism_classification, Phenotype, Article Addendum, Homeobox, RNA Interference, Plant Shoots

Abstract

Plant shoot organs arise from initial cells that are recruited from meristematic tissues. Previous studies have shown that members of the WUSCHEL-related HOMEOBOX (WOX) gene family function to organize various initial cell populations during plant development. The function of the WOX4 gene is previously undescribed in any plant species. Comparative analyses of WOX4 transcription and function are presented in Arabidopsis (Arabidopsis thaliana), a simple-leafed plant with collateral vasculature, and in tomato (Solanum lycopersicum), a dissected-leafed species with bicollateral venation. WOX4 is transcribed in the developing vascular bundles of root and shoot lateral organs in both Arabidopsis and tomato. RNA interference-induced down-regulation of WOX4 in Arabidopsis generated small plants whose vascular bundles accumulated undifferentiated ground tissue and exhibited severe reductions in differentiated xylem and phloem. In situ hybridization analyses of Atwox4-RNA interference plants revealed delayed and reduced expression of both the phloem developmental marker ALTERED PHLOEM1 and HOMEOBOX GENE8, a marker of the vascular procambium. Overexpression of SlWOX4 correlated with overproliferation of xylem and phloem in transgenic tomato seedlings. The cumulative data suggest that the conserved WOX4 function is to promote differentiation and/or maintenance of the vascular procambium, the initial cells of the developing vasculature.

Published

2010

39. ragged seedling2 Encodes an ARGONAUTE7-Like Protein Required for Mediolateral Expansion, but Not Dorsiventrality, of Maize Leaves[C][W]

Author

Marja C.P. Timmermans, Nathan M. Springer, Michael J. Scanlon, Ananda K. Sarkar, Ryan N. Douglas, and Dan Wiley

Subjects

Positional cloning, Mutant, Molecular Sequence Data, Plant Science, Biology, Cell fate determination, Genes, Plant, Models, Biological, Zea mays, RNA Transport, Auxin, Gene Expression Regulation, Plant, Botany, RNA, Messenger, Cloning, Molecular, RNA, Small Interfering, Leaf formation, Research Articles, Alleles, In Situ Hybridization, Body Patterning, Plant Proteins, chemistry.chemical_classification, Polarity (international relations), fungi, food and beverages, Cell Biology, Meristem, Plant Leaves, MicroRNAs, chemistry, Shoot, Mutation

Abstract

Leaves arise from the flank of the shoot apical meristem and are asymmetrical along the adaxial/abaxial plane from inception. Mutations perturbing dorsiventral cell fate acquisition in a variety of species can result in unifacial (radially symmetrical) leaves lacking adaxial/abaxial polarity. However, mutations in maize (Zea mays) ragged seedling2 (rgd2) condition cylindrical leaves that maintain dorsiventral polarity. Positional cloning reveals that rgd2 encodes an ARGONAUTE7 (AGO7)-like protein required to produce ta-siARF, a trans-acting small interfering RNA that targets abaxially located auxin response factor3a (arf3a) transcripts for degradation. Previous studies implicated ta-siARF in dorsiventral patterning of monocot leaves. Here, we show that arf3a transcripts hyperaccumulate but remain abaxialized in rgd2 mutant apices, revealing that ta-siARF function is not required for arf3a polarization. RGD2 also regulates miR390 accumulation and localization in maize shoot apices. Similar to the abaxialized maize mutant leafbladeless1 (lbl1), rgd2 mutants exhibit ectopic accumulation of the abaxial identity factor miR166 in adaxial domains. Thus, hyperaccumulation of arf3a and ectopic accumulation of miR166 are insufficient to condition abaxialized leaf phenotypes in maize. Finally, transcripts of a maize ago1 paralog overaccumulate in lbl1 but not in rgd2 mutants, suggesting that upregulation of ago1 combined with ectopic accumulation of miR166 contribute to abaxialized leaf formation in lbl1. We present a revised model for the role of small RNAs in dorsiventral patterning of maize leaves.

Published

2010

40. Microdissection of shoot meristem functional domains

Author

Josh Strable, Diane Janick-Buckner, Douglas M. Eudy, Marja C.P. Timmermans, Michael J. Scanlon, Brent Buckner, Teresa E. Pawlowska, Kazuhiro Ohtsu, Doreen Ware, Patrick S. Schnable, Ananda K. Sarkar, Ruilian Zhou, Xiaolan Zhang, Robert J. Elshire, Lionel Brooks, Dan Nettleton, and Sarah K. Hargreaves

Subjects

0106 biological sciences, Cancer Research, Arabidopsis, Plant Biology, 01 natural sciences, Gene Expression Regulation, Plant, Gene expression, Databases, Genetic, Genetics (clinical), In Situ Hybridization, Phylogeny, Oligonucleotide Array Sequence Analysis, Plant Proteins, 2. Zero hunger, Regulation of gene expression, 0303 health sciences, biology, food and beverages, Gene Expression Regulation, Developmental, Phenotype, Multigene Family, Genetic redundancy, Microdissection, Research Article, lcsh:QH426-470, DNA, Plant, Meristem, Molecular Sequence Data, Genes, Plant, Zea mays, Evolution, Molecular, 03 medical and health sciences, Plant Biology/Plant Genetics and Gene Expression, Plant Biology/Plant Growth and Development, Species Specificity, Cyclin D, Cyclins, Genetics, Amino Acid Sequence, Molecular Biology, Gene, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Base Sequence, Gene Expression Profiling, fungi, 15. Life on land, Transport inhibitor, biology.organism_classification, Molecular biology, Gene expression profiling, Plant Leaves, lcsh:Genetics, Mutation, 010606 plant biology & botany

Abstract

The shoot apical meristem (SAM) maintains a pool of indeterminate cells within the SAM proper, while lateral organs are initiated from the SAM periphery. Laser microdissection–microarray technology was used to compare transcriptional profiles within these SAM domains to identify novel maize genes that function during leaf development. Nine hundred and sixty-two differentially expressed maize genes were detected; control genes known to be upregulated in the initiating leaf (P0/P1) or in the SAM proper verified the precision of the microdissections. Genes involved in cell division/growth, cell wall biosynthesis, chromatin remodeling, RNA binding, and translation are especially upregulated in initiating leaves, whereas genes functioning during protein fate and DNA repair are more abundant in the SAM proper. In situ hybridization analyses confirmed the expression patterns of six previously uncharacterized maize genes upregulated in the P0/P1. P0/P1-upregulated genes that were also shown to be downregulated in leaf-arrested shoots treated with an auxin transport inhibitor are especially implicated to function during early events in maize leaf initiation. Reverse genetic analyses of asceapen1 (asc1), a maize D4-cyclin gene upregulated in the P0/P1, revealed novel leaf phenotypes, less genetic redundancy, and expanded D4-CYCLIN function during maize shoot development as compared to Arabidopsis. These analyses generated a unique SAM domain-specific database that provides new insight into SAM function and a useful platform for reverse genetic analyses of shoot development in maize., Author Summary All the organs of plant shoots are derived from the shoot apical meristem (SAM), a pool of plant stem cells that are both organogenic and self-sustaining. These dual SAM functions take place in distinct yet adjacent meristematic domains; leaves are derived from the peripheral zone (PZ) of the SAM whereas cells lost during organogenesis are replenished from the central zone (CZ). Deciphering the global patterns of differential gene expression within these discrete SAM functional domains is integral toward understanding the molecular-signaling networks that regulate plant development. We utilized laser-microdissection technology to isolate tissues from the SAM crown and center (SAM-proper) and from initiating leaves (P0/P1) at the SAM periphery for use in microarray comparisons of gene expression within these SAM functional domains. Nine hundred and sixty-two maize genes were differentially expressed, confirming that the distinct functions of these meristematic domains involve widespread differences in gene expression. Genes involved in cell division, cell wall biosynthesis, chromatin structure, and RNA binding are especially upregulated in initiating leaves, whereas genes regulating protein stability and DNA repair are upregulated in the SAM proper. Mutations in a D-cyclin gene that was upregulated in the P0/P1 render narrow-leafed mutant plants with defective stomatal patterning, providing functional genetic data for a previously uncharacterized maize gene.

Published

2009

41. Laser microdissection of narrow sheath mutant maize uncovers novel gene expression in the shoot apical meristem

Author

Marja C.P. Timmermans, Michael J. Scanlon, Brent Buckner, Lisa A. Borsuk, Jon Beck, Xiaolan Zhang, Patrick S. Schnable, Robert J. Elshire, Dan Nettleton, Shahinez Madi, and Diane Janick-Buckner

Subjects

Cancer Research, lcsh:QH426-470, Eukaryotes, Gene prediction, Meristem, Molecular Sequence Data, Mutant, Plant Biology, Biology, Zea mays, Gene Expression Regulation, Plant, None, Genetics, Primordium, Molecular Biology, Gene, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, Oligonucleotide Array Sequence Analysis, Laser capture microdissection, Regulation of gene expression, Lasers, fungi, Zea, food and beverages, Plants, lcsh:Genetics, Mutation, DNA microarray, Microdissection, Plant Shoots, Research Article

Abstract

Microarrays enable comparative analyses of gene expression on a genomic scale, however these experiments frequently identify an abundance of differentially expressed genes such that it may be difficult to identify discrete functional networks that are hidden within large microarray datasets. Microarray analyses in which mutant organisms are compared to nonmutant siblings can be especially problematic when the gene of interest is expressed in relatively few cells. Here, we describe the use of laser microdissection microarray to perform transcriptional profiling of the maize shoot apical meristem (SAM), a ~100-μm pillar of organogenic cells that is required for leaf initiation. Microarray analyses compared differential gene expression within the SAM and incipient leaf primordium of nonmutant and narrow sheath mutant plants, which harbored mutations in the duplicate genes narrow sheath1 (ns1) and narrow sheath2 (ns2). Expressed in eight to ten cells within the SAM, ns1 and ns2 encode paralogous WUSCHEL1-like homeobox (WOX) transcription factors required for recruitment of leaf initials that give rise to a large lateral domain within maize leaves. The data illustrate the utility of laser microdissection-microarray analyses to identify a relatively small number of genes that are differentially expressed within the SAM. Moreover, these analyses reveal potentially conserved WOX gene functions and implicate specific hormonal and signaling pathways during early events in maize leaf development., Author Summary Unlike animals, plants exhibit a prolonged period of organogenesis, generating new leaves throughout their life cycle. This ability to maintain an embryo-like state is dependent upon the activity of shoot meristems, whose dual functions are to supply an inner core of pluripotent cells that sustain the shoot meristem while simultaneously generating new leaves derived from cells at the meristem periphery. Deciphering the complex combinations of molecular signals that transform meristematic cells into leaf primordia is a central question in plant developmental biology. In this study, we used the power of focused laser light to microdissect shoot meristems from neighboring leaf and stem tissue in the maize plant. Once isolated, we compared patterns of gene expression in normal shoot meristems to those of genetically mutant shoot meristems that form abnormal, narrow leaves. Out of more than 21,000 maize genes analyzed, 66 genes were identified as misexpressed in the mutant shoot meristems. All but one of the differentially expressed genes are previously unstudied in maize, and the majority are predicted to function during cell division, growth, or developmental signaling. Many of these novel genes are expressed in specific domains of the shoot meristem, consistent with their predicted function during maize leaf initiation.

Published

2007

42. Auxin Immunolocalization Implicates Vesicular Neurotransmitter-Like Mode of Polar Auxin Transport in Root Apices

Author

Dieter Volkmann, Diedrik Menzel, Markus Schlicht, Klaus Palme, Frank Hochholdinger, František Baluška, Michael J. Scanlon, Miroslav Strnad, and Stefano Mancuso

Subjects

chemistry.chemical_classification, Endosome, Vesicle, fungi, food and beverages, Plant Science, Brefeldin A, Biology, Endocytosis, Cell biology, chemistry.chemical_compound, chemistry, Cytoplasm, Auxin, heterocyclic compounds, Polar auxin transport, Actin, Research Paper

Abstract

Immunolocalization of auxin using a new specific antibody revealed, besides the expected diffuse cytoplasmic signal, enrichments of auxin at end-poles (cross-walls), within endosomes and within nuclei of those root apex cells which accumulate abundant F-actin at their end-poles. In Brefeldin A (BFA) treated roots, a strong auxin signal was scored within BFA-induced compartments of cells having abundant actin and auxin at their end-poles, as well as within adjacent endosomes, but not in other root cells. Importantly, several types of polar auxin transport (PAT) inhibitors exert similar inhibitory effects on endocytosis, vesicle recycling, and on the enrichments of F-actin at the end-poles. These findings indicate that auxin is transported across F-actin-enriched end-poles (synapses) via neurotransmitter-like secretion. This new concept finds genetic support from the semaphore1, rum1 and rum1/lrt1 mutants of maize which are impaired in PAT, endocytosis and vesicle recycling, as well as in recruitment of F-actin and auxin to the auxin transporting end-poles. Although PIN1 localizes abundantly to the end-poles, and they also fail to support the formation of in these mutants affected in PAT, auxin and F-actin are depleted from their end-poles which also fail to support formation of the large BFA-induced compartments.

Published

2006

43. The maize duplicate genes narrow sheath1 and narrow sheath2 encode a conserved homeobox gene function in a lateral domain of shoot apical meristems

Author

Wolfgang Werr, Michael J. Scanlon, Jiabing Ji, and Judith Nardmann

Subjects

Transcription, Genetic, Mutant, Meristem, Molecular Sequence Data, Arabidopsis, Locus (genetics), Biology, Zea mays, Sepal, Genes, Duplicate, Primordium, Amino Acid Sequence, Cloning, Molecular, Molecular Biology, Gene, Plant Proteins, Sequence Deletion, Genetics, Homeodomain Proteins, fungi, Genes, Homeobox, food and beverages, Null allele, Phenotype, Mutagenesis, Sequence Alignment, Plant Shoots, Developmental Biology

Abstract

The narrow sheath (ns) phenotype of maize is a duplicate factor trait conferred by mutations at the unlinked loci ns1 and ns2. Recessive mutations at each locus together confer the phenotypic deletion of a lateral compartment in maize leaves and leaf homologs. Previous analyses revealed that the mediolateral axis of maize leaves is comprised of at least two distinct compartments, and suggest a model whereby NS function is required to recruit leaf founder cells from a lateral compartment of maize meristems. Genomic clones of two maize homeodomain-encoding genes were isolated by homology to the WUSCHEL-related gene PRESSED FLOWER(PRS). PRS is required for lateral sepal development in Arabidopsis, although no leaf phenotype is reported. Co-segregation of the ns phenotype with multiple mutant alleles of two maize PRShomologs confirms their allelism to ns1 and ns2. Analyses of NS protein accumulation verify that the ns-R mutations are null alleles. ns transcripts are detected in two lateral foci within maize meristems, and in the margins of lateral organ primordia. Whereas ns1and ns2 transcripts accumulate to equivalent levels in shoot meristems of vegetative seedlings, ns2 transcripts predominate in female inflorescences. Previously undiscovered phenotypes in the pressed flower mutant support a model whereby the morphology of eudicot leaves and monocot grass leaves has evolved via the differential elaboration of upper versus lower leaf zones. A model implicating an evolutionarily conserved NS/PRS function during recruitment of organ founder cells from a lateral domain of plant meristems is discussed.

Published

2004

44. The narrow sheath duplicate genes: sectors of dual aneuploidy reveal ancestrally conserved gene functions during maize leaf development

Author

K. D. Chen, Michael J. Scanlon, and C. C. McKnight

Subjects

DNA, Plant, Mutant, Biology, medicine.disease_cause, Zea mays, Translocation, Genetic, Conserved sequence, Genes, Duplicate, Gene duplication, Genetics, medicine, Gene, Alleles, Conserved Sequence, Chromosomal inversion, Recombination, Genetic, Mutation, Mosaicism, X-Rays, fungi, food and beverages, Chromosome Mapping, Meristem, Aneuploidy, Phenotype, Plant Leaves, Mutagenesis, Seeds, Pollen, Polymorphism, Restriction Fragment Length, Research Article

Abstract

The narrow sheath mutant of maize displays a leaf and plant stature phenotype controlled by the duplicate factor mutations narrow sheath1 and narrow sheath2. Mutant leaves fail to develop a lateral domain that includes the leaf margins. Genetic data are presented to show that the narrow sheath mutations map to duplicated chromosomal regions, reflecting an ancestral duplication of the maize genome. Genetic and cytogenetic evidence indicates that the original mutation at narrow sheath2 is associated with a chromosomal inversion on the long arm of chromosome 4. Meristematic sectors of dual aneuploidy were generated, producing plants genetically mosaic for NARROW SHEATH function. These mosaic plants exhibited characteristic half-plant phenotypes, in which leaves from one side of the plant were of nonmutant morphology and leaves from the opposite side were of narrow sheath mutant phenotype. The data suggest that the narrow sheath duplicate genes may perform ancestrally conserved, redundant functions in the development of a lateral domain in the maize leaf.

Published

2000