Your search keyword '"Dickinson HG"' showing total 4 results

1. Anatomy and ultrastructure of embryonic leaves of the C4 species Setaria viridis.

Author

Junqueira NEG, Ortiz-Silva B, Leal-Costa MV, Alves-Ferreira M, Dickinson HG, Langdale JA, and Reinert F

Subjects

Microscopy, Electron, Scanning, Microscopy, Electron, Transmission, Phloem ultrastructure, Plant Leaves anatomy & histology, Plant Leaves ultrastructure, Plant Shoots anatomy & histology, Plant Shoots embryology, Plant Shoots ultrastructure, Seeds growth & development, Setaria Plant anatomy & histology, Setaria Plant ultrastructure, Xylem ultrastructure, Plant Leaves embryology, Setaria Plant embryology

Abstract

Background and Aims: Setaria viridis is being promoted as a model C4 photosynthetic plant because it has a small genome (~515 Mb), a short life cycle (~60 d) and it can be transformed. Unlike other C4 grasses such as maize, however, there is very little information about how C4 leaf anatomy (Kranz anatomy) develops in S. viridis. As a foundation for future developmental genetic studies, we provide an anatomical and ultrastructural framework of early shoot development in S. viridis, focusing on the initiation of Kranz anatomy in seed leaves., Methods: Setaria viridis seeds were germinated and divided into five stages covering development from the dry seed (stage S0) to 36 h after germination (stage S4). Material at each of these stages was examined using conventional light, scanning and transmission electron microscopy., Key Results: Dry seeds contained three embryonic leaf primordia at different developmental stages (plastochron 1-3 primordia). The oldest (P3) leaf primordium possessed several procambial centres whereas P2 displayed only ground meristem. At the tip of P3 primordia at stage S4, C4 leaf anatomy typical of the malate dehydrogenase-dependent nicotinamide dinucleotide phosphate (NADP-ME) subtype was evident in that vascular bundles lacked a mestome layer and were surrounded by a single layer of bundle sheath cells that contained large, centrifugally located chloroplasts. Two to three mesophyll cells separated adjacent vascular bundles and one mesophyll cell layer on each of the abaxial and adaxial sides delimited vascular bundles from the epidermis., Conclusions: The morphological trajectory reported here provides a foundation for studies of gene regulation during early leaf development in S. viridis and a framework for comparative analyses with other C4 grasses.

Published

2018

2. When genomes collide: aberrant seed development following maize interploidy crosses.

Author

Pennington PD, Costa LM, Gutierrez-Marcos JF, Greenland AJ, and Dickinson HG

Subjects

Genes, Reporter, Reverse Transcriptase Polymerase Chain Reaction, Starch metabolism, Zea mays genetics, Crosses, Genetic, Genome, Plant, Ploidies, Seeds growth & development, Zea mays embryology

Abstract

Background and Aims: The results of wide- or interploidy crosses in angiosperms are unpredictable and often lead to seed abortion. The consequences of reciprocal interploidy crosses have been explored in maize in detail, focusing on alterations to tissue domains in the maize endosperm, and changes in endosperm-specific gene expression., Methods: Following reciprocal interploidy crosses between diploid and tetraploid maize lines, development of endosperm domains was studied using GUS reporter lines, and gene expression in resulting kernels was investigated using semi-quantitative RT-PCR on endosperms isolated at different stages of development., Key Results: Reciprocal interploidy crosses result in very small, largely infertile seeds with defective endosperms. Seeds with maternal genomic excess are smaller than those with paternal genomic excess, their endosperms cellularize earlier and they accumulate significant quantities of starch. Endosperms from the reciprocal cross undergo an extended period of cell proliferation, and accumulate little starch. Analysis of reporter lines and gene expression studies confirm that functional domains of the endosperm are severely disrupted, and are modified differently according to the direction of the interploidy cross., Conclusions: Interploidy crosses affect factors which regulate the balance between cell proliferation and cell differentiation within the endosperm. In particular, unbalanced crosses in maize affect transfer cell differentiation, and lead to the temporal deregulation of the ontogenic programme of endosperm development.

Published

2008

3. Epigenetics and its implications for plant biology 2. The 'epigenetic epiphany': epigenetics, evolution and beyond.

Author

Grant-Downton RT and Dickinson HG

Subjects

Arabidopsis genetics, Genome, Plant, Hybridization, Genetic, Linaria anatomy & histology, Linaria genetics, Models, Genetic, Ploidies, Epigenesis, Genetic, Evolution, Molecular, Gene Expression Regulation, Plant, Plants genetics

Abstract

Scope: In the second part of a two-part review, the ubiquity and universality of epigenetic systems is emphasized, and attention is drawn to the key roles they play, ranging from transducing environmental signals to altering gene expression, genomic architecture and defence., Key Issues: The importance of transience versus heritability in epigenetic marks is examined, as are the potential for stable epigenetic marks to contribute to plant evolution, and the mechanisms generating novel epigenetic variation, such as stress and interspecific hybridization., Future Prospects: It is suggested that the ramifications of epigenetics in plant biology are immense, yet unappreciated. In contrast to the ease with which the DNA sequence can be studied, studying the complex patterns inherent in epigenetics poses many problems. Greater knowledge of patterns of epigenetic variation may be informative in taxonomy and systematics, as well as population biology and conservation.

Published

2006

4. Epigenetics and its implications for plant biology. 1. The epigenetic network in plants.

Author

Grant-Downton RT and Dickinson HG

Subjects

Alleles, Chimera genetics, DNA Methylation, DNA Packaging physiology, Gene Expression physiology, Genes, Plant physiology, Genetic Variation physiology, Histone Code physiology, Histones genetics, Histones physiology, RNA, Plant physiology, Transgenes physiology, Gene Expression Regulation, Plants genetics

Abstract

Background: Epigenetics has rapidly evolved in the past decade to form an exciting new branch of biology. In modern terms, 'epigenetics' studies molecular pathways regulating how the genes are packaged in the chromosome and expressed, with effects that are heritable between cell divisions and even across generations., Context: Epigenetic mechanisms often conflict with Mendelian models of genetics, and many components of the epigenetic systems in plants appeared anomalous. However, it is now clear that these systems govern how the entire genome operates and evolves., Scope: In the first part of a two-part review, how epigenetic systems in plants were elucidated is addressed. Also there is a discussion on how the different components of the epigenetic system--regulating DNA methylation, histones and their post-translational modification, and pathways recognizing aberrant transcripts--may work together.

Published

2005