Michael G. Becker

Genomic dissection of the seed

Seeds play an integral role in the global food supply and account for more than 70% of the calories that we consume on a daily basis. To meet the demands of an increasing population, scientists are turning to seed genomics research to find new and innovative ways to increase food production. Seed genomics is evolving rapidly, and the information produced from seed genomics research has exploded over the past two decades. Advances in modern sequencing strategies that profile every molecule in every cell, tissue, and organ and the emergence of new model systems have provided the tools necessary to unravel many of the biological processes underlying seed development. Despite these advances, the analyses and mining of existing seed genomics data remain a monumental task for plant biologists. This review summarizes seed region and subregion genomic data that are currently available for existing and emerging oilseed models. We provide insight into the development of tools on how to analyze large-scale datasets.

Transcriptome atlas of the Arabidopsis funiculus – a study of maternal seed subregions

The funiculus anchors the structurally complex seed to the maternal plant, and is the only direct route of transport for nutrients and maternal signals to the seed. While our understanding of seed development is becoming clearer, current understanding of the genetics and cellular mechanisms that contribute to funiculus development is limited. Using laser microdissection combined with global RNA-profiling experiments we compared the genetic profiles of all maternal and zygotic regions and subregions during seed development. We found that the funiculus is a dynamic region of the seed that is enriched for mRNAs associated with hormone metabolism, molecular transport, and metabolic activities corresponding to biological processes that have yet to be described in this maternal seed structure. We complemented our genetic data with a complete histological analysis of the funiculus from the earliest stages of development through to seed maturation at the light and electron microscopy levels. The anatomy revealed signs of photosynthesis, the endomembrane system, cellular respiration, and transport within the funiculus, all of which supported data from the transcriptional analysis. Finally, we studied the transcriptional programming of the funiculus compared to other seed subregions throughout seed development. Using newly designed in silico algorithms, we identified a number of transcriptional networks hypothesized to be responsible for biological processes like auxin response and glucosinolate biosynthesis found specifically within the funiculus. Taken together, patterns of gene activity and histological observations reveal putative functions of the understudied funiculus region and identify predictive transcriptional circuits underlying these biological processes in space and time.

Tissue-specific laser microdissection of the Brassica napus funiculus improves gene discovery and spatial identification of biological processes

Highlight Tissue-specific transcriptomic analysis reveals biological processes contributing to the development of the epidermis, cortex, and vasculature, and how these tissues contribute to the development and function of the canola funiculus.

Vitamin C deficiency improves somatic embryo development through distinct gene regulatory networks in Arabidopsis

Summary Depletion of cellular vitamin C improves somatic embryogenesis in Arabidopsis. Improved embryo number and quality is through changes in gene regulatory network activation and cellular architecture.

SeqEnrich: A tool to predict transcription factor networks from co-expressed Arabidopsis and Brassica napus gene sets

Transcription factors and their associated DNA binding sites are key regulatory elements of cellular differentiation, development, and environmental response. New tools that predict transcriptional regulation of biological processes are valuable to researchers studying both model and emerging-model plant systems. SeqEnrich predicts transcription factor networks from co-expressed Arabidopsis or Brassica napus gene sets. The networks produced by SeqEnrich are supported by existing literature and predicted transcription factor–DNA interactions that can be functionally validated at the laboratory bench. The program functions with gene sets of varying sizes and derived from diverse tissues and environmental treatments. SeqEnrich presents as a powerful predictive framework for the analysis of Arabidopsis and Brassica napus co-expression data, and is designed so that researchers at all levels can easily access and interpret predicted transcriptional circuits. The program outperformed its ancestral program ChipEnrich, and produced detailed transcription factor networks from Arabidopsis and Brassica napus gene expression data. The SeqEnrich program is ideal for generating new hypotheses and distilling biological information from large-scale expression data.

RNA sequencing of Brassica napus reveals cellular redox control of Sclerotinia infection

Protection against Sclerotinia sclerotiorum in Brassica napus is mediated via dynamic transcription factor networks and cellular redox homeostasis directly at the site of infection.

Chalazal seed coat development in Brassica napus

The chalazal seed coat (CZSC) is a maternal subregion adjacent to the funiculus which serves as the first point of entry into the developing seed. This subregion is of particular interest in Brassica napus (canola) because of its location within the seed and its putative contribution to seed filling processes. In this study, the CZSC of canola was characterized at an anatomical and molecular level to (i) describe the cellular and subcellular features of the CZSC throughout seed development, (ii) reveal cellular features of the CZSC that relate to transport processes, (iii) study gene activity of transporters and transcriptional regulators in the CZSC subregion over developmental time, and (iv) briefly investigate the contribution of the A and C constituent genomes to B. napus CZSC gene activity. We found that the CZSC contains terminating ends of xylem and phloem as well as a mosaic of endomembrane and plasmodesmatal connections, suggesting that this subregion is likely involved in the transport of material and information from the maternal tissues of the plant to other regions of the seed. Laser microdissection coupled with quantitative RT-PCR identified the relative abundance of sugar, water, auxin and amino acid transporter homologs inherited from the constituent genomes of this complex polyploid. We also studied the expression of three transcription factors that were shown to co-express with these biological processes providing a preliminary framework for the regulatory networks responsible for seed filling in canola and discuss the relationship of the CZSC to other regions and subregions of the seed and its role in seed development.

Laser Microdissection of Plant Tissues

Laser microdissection (LMD) is one of the most effective methods used to isolate cells from heterogeneous tissues. Global or targeted profiling of specific cells is easily achievable for the majority of plant and animal systems. However, for these methods to be successful, tissues must be processed to preserve cellular detail for the identification of target cell types using general light microscopy in addition to the recovery of target molecules (RNA, DNA, or proteins). Paraffin as an embedding medium is one of the few means by which tissues can be prepared for LMD. The main advantage of paraffin embedding compared with other methods is that it maintains anatomical integrity of plant cells, allowing for the identification of target cell types that may have subtle morphological differences. Using this technique, tissues are dehydrated, infiltrated, and embedded with paraffin wax, sectioned with a microtome, mounted on slides with a polyethylene naphthalate membrane, and finally de-paraffinized with xylenes. All tissues can be processed using this general procedure; however, the duration of each step must be optimized depending on the cellular features of the tissue of interest. Here, we present optimized tissue processing protocols for paraffin-embedded Brassica napus seed and leaf tissues for LMD for RNA profiling experiments. Paraffin-embedded LMD has been applied to multiple RNA profiling experiments such as microarray analyses, directed quantitative PCR, small RNA sequencing, methylome sequencing, and RNA sequencing. The combination of LMD with the versatility of its downstream applications makes it a powerful technology for the high-resolution study of cellular bioprocesses.

The biocontrol agent Pseudomonas chlororaphis PA23 primes Brassica napus defenses through distinct gene networks

BackgroundThe biological control agent Pseudomonas chlororaphis PA23 is capable of protecting Brassica napus (canola) from the necrotrophic fungus Sclerotinia sclerotiorum via direct antagonism. While we have elucidated bacterial genes and gene products responsible biocontrol, little is known about how the host plant responds to bacterial priming on the leaf surface, including global changes in gene activity in the presence and absence of S. sclerotiorum.ResultsApplication of PA23 to the aerial surfaces of canola plants reduced the number of S. sclerotiorum lesion-forming petals by 91.1%. RNA sequencing of the host pathogen interface showed that pretreatment with PA23 reduced the number of genes upregulated in response to S. sclerotiorum by 16-fold. By itself, PA23 activated unique defense networks indicative of defense priming. Genes encoding MAMP-triggered immunity receptors detecting flagellin and peptidoglycan were downregulated in PA23 only-treated plants, consistent with post-stimulus desensitization. Downstream, we observed reactive oxygen species (ROS) production involving low levels of H2O2 and overexpression of genes associated with glycerol-3-phosphate (G3P)-mediated systemic acquired resistance (SAR). Leaf chloroplasts exhibited increased thylakoid membrane structures and chlorophyll content, while lipid metabolic processes were upregulated.ConclusionIn addition to directly antagonizing S. sclerotiorum, PA23 primes the plant defense response through induction of unique local and systemic defense networks. This study provides novel insight into the effects of biocontrol agents applied to the plant phyllosphere. Understanding these interactions will aid in the development of biocontrol systems as an alternative to chemical pesticides for protection of important crop systems.

Tissue-specific localization of polyketide synthase and other associated genes in the lichen, Cladonia rangiferina, using laser microdissection

The biosynthesis of two polyketides, atranorin and fumarprotocetraric acid, produced from a lichen-forming fungus, Cladonia rangiferina (L.) F. H. Wigg. was correlated with the expression of eight fungal genes (CrPKS1, CrPKS3, CrPKS16, Catalase (CAT), Sugar Transporter (MFsug), Dioxygenase (YQE1), C2H2 Transcription factor (C2H2), Transcription Factor PacC (PacC), which are thought to be involved in polyketide biosynthesis, and one algal gene, NAD-dependent deacetylase sirtuin 2 (AsNAD)), using laser microdissection (LMD). The differential gene expression levels within the thallus tissue layers demonstrate that the most active region for potential polyketide biosynthesis within the lichen is the outer apical region proximal to the photobiont but some expression also occurs in reproductive tissue. This is the first study using laser microdissection to explore gene expression of these nine genes and their location of expression; it provides a proof-of-concept for future experiments exploring tissue-specific gene expression within lichens; and it highlights the utility of LMD for use in lichen systems.