21 research outputs found
jicbioimage: a tool for automated and reproducible bioimage analysis
ABSTRACT There has been steady improvement in methods for capturing bioimages. However analysing these images still remains a challenge. The Python programming language provides a powerful and flexible environment for scientific computation. It has a wide range of supporting libraries for image processing but lacks native support for common bioimage formats, and requires specific code to be written to ensure that suitable audit trails are generated and analyses are reproducible. Here we describe the development of a Python tool that: (1) allows users to quickly view and explore microscopy data; (2) generate reproducible analyses, encoding a complete history of image transformations from raw data to final result; and (3) scale up analyses from initial exploration to high throughput processing pipelines, with a minimal amount of extra effort. The tool, jicbioimage, is open source and freely available online a
Ectopic BASL Reveals Tissue Cell Polarity throughout Leaf Development in Arabidopsis thaliana
Tissue-wide polarity fields, in which cell polarity is coordinated across the tissue, have been described for planar organs such as the Drosophila wing and are considered important for coordinating growth and differentiation [1]. In planar plant organs, such as leaves, polarity fields have been identified for subgroups of cells, such as stomatal lineages [2], trichomes [3, 4], serrations [5], or early developmental stages [6]. Here, we show that ectopic induction of the stomatal protein BASL (BREAKING OF ASYMMETRY IN THE STOMATAL LINEAGE) reveals a tissue-wide epidermal polarity field in leaves throughout development. Ectopic GFP-BASL is typically localized toward the proximal end of cells and to one lobe of mature pavement cells, revealing a polarity field that aligns with the proximodistal axis of the leaf (base to tip). The polarity field is largely parallel to the midline of the leaf but diverges in more lateral positions, particularly at later stages in development, suggesting it may be deformed during growth. The polarity field is observed in the speechless mutant, showing that it is independent of stomatal lineages, and is observed in isotropic cells, showing that cell shape anisotropy is not required for orienting polarity. Ectopic BASL forms convergence and divergence points at serrations, mirroring epidermal PIN polarity patterns, suggesting a common underlying polarity mechanism. Thus, we show that similar to the situation in animals, planar plant organs have a tissue-wide cell polarity field, and this may provide a general cellular mechanism for guiding growth and differentiation
Rust expression browser: an open source database for simultaneous analysis of host and pathogen gene expression profiles with expVIP
BackgroundTranscriptomics is being increasingly applied to generate new insight into the interactions between plants and their pathogens. For the wheat yellow (stripe) rust pathogen (Puccinia striiformis f. sp. tritici, Pst) RNA-based sequencing (RNA-Seq) has proved particularly valuable, overcoming the barriers associated with its obligate biotrophic nature. This includes the application of RNA-Seq approaches to study Pst and wheat gene expression dynamics over time and the Pst population composition through the use of a novel RNA-Seq based surveillance approach called "field pathogenomics". As a dual RNA-Seq approach, the field pathogenomics technique also provides gene expression data from the host, giving new insight into host responses. However, this has created a wealth of data for interrogation.ResultsHere, we used the field pathogenomics approach to generate 538 new RNA-Seq datasets from Pst-infected field wheat samples, doubling the amount of transcriptomics data available for this important pathosystem. We then analysed these datasets alongside 66 RNA-Seq datasets from four Pst infection time-courses and 420 Pst-infected plant field and laboratory samples that were publicly available. A database of gene expression values for Pst and wheat was generated for each of these 1024 RNA-Seq datasets and incorporated into the development of the rust expression browser (http://www.rust-expression.com). This enables for the first time simultaneous 'point-and-click' access to gene expression profiles for Pst and its wheat host and represents the largest database of processed RNA-Seq datasets available for any of the three Puccinia wheat rust pathogens. We also demonstrated the utility of the browser through investigation of expression of putative Pst virulence genes over time and examined the host plants response to Pst infection.ConclusionsThe rust expression browser offers immense value to the wider community, facilitating data sharing and transparency and the underlying database can be continually expanded as more datasets become publicly available
A calmodulin-like protein regulates plasmodesmal closure during bacterial immune responses
Plants sense microbial signatures via activation of pattern recognition receptors (PPRs), which trigger a range of cellular defences. One response is the closure of plasmodesmata, which reduces symplastic connectivity and the capacity for direct molecular exchange between host cells. Plasmodesmal flux is regulated by a variety of environmental cues but the downstream signalling pathways are poorly defined, especially the way in which calcium regulates plasmodesmal closure. Here, we identify that closure of plasmodesmata in response to bacterial flagellin, but not fungal chitin, is mediated by a plasmodesmal-localized Ca2+ -binding protein Calmodulin-like 41 (CML41). CML41 is transcriptionally upregulated by flg22 and facilitates rapid callose deposition at plasmodesmata following flg22 treatment. CML41 acts independently of other defence responses triggered by flg22 perception and reduces bacterial infection. We propose that CML41 enables Ca2+ -signalling specificity during bacterial pathogen attack and is required for a complete defence response against Pseudomonas syringae.Bo Xu, Cecilia Cheval, Anuphon Laohavisit, Bradleigh Hocking, David Chiasson, Tjelvar S. G. Olsson, Ken Shirasu, Christine Faulkner and Matthew Gilliha
jicbioimage: a tool for automated and reproducible bioimage analysis
There has been steady improvement in methods for capturing bioimages. However analysing these images still remains a challenge. The Python programming language provides a powerful and flexible environment for scientific computation. It has a wide range of supporting libraries for image processing but lacks native support for common bioimage formats, and requires specific code to be written to ensure that suitable audit trails are generated and analyses are reproducible. Here we describe the development of a Python tool that: (1) allows users to quickly view and explore microscopy data; (2) generate reproducible analyses, encoding a complete history of image transformations from raw data to final result; and (3) scale up analyses from initial exploration to high throughput processing pipelines, with a minimal amount of extra effort. The tool, jicbioimage, is open source and freely available online at http://jicbioimage.readthedocs.io
hypocotyl3.czi
<div>---</div><div>Experiment Date: 28 Jan 2016</div><div>Experiment Commentary: Confocal microscopy image of hypocotyl. Cell walls stained using FM4-64 [5ug/ml]. Nucelus marked using 35s::GFP:eIF3a (see reference for more detail).</div><div>Device: Zeiss LSM780</div><div>Species: Arabidopsis thaliana (Thale cress)</div><div>Organ/tissue type: Hypocotyl</div><div>Imaging probes: FM4-64 + GFP-nucleus</div><div>Objective Lens: x40/1.2 water</div
Subpocket Analysis Method for Fragment-Based Drug Discovery
Although two binding sites might be dissimilar overall,
they might
still bind the same fragments if they share suitable subpockets. Information
about shared subpockets can be therefore used in fragment-based drug
design to suggest new fragments or to replace existing fragments within
an already known compound. A novel computational method called SubCav
is described which allows the similarity searching and alignment of
subpockets from a PDB-wide database against a user-defined query.
The method is based on pharmacophoric fingerprints combined with a
subpocket alignment algorithm. SubCav was shown to be effective in
producing reasonable alignments for subpockets with low sequence similarity
and be able to retrieve relevant subpockets from a large database
of structures including those with different folds. It can also be
used to analyze subpockets inside a protein family to facilitate drug
design and to rationalize compound selectivity
Subpocket Analysis Method for Fragment-Based Drug Discovery
Although two binding sites might be dissimilar overall,
they might
still bind the same fragments if they share suitable subpockets. Information
about shared subpockets can be therefore used in fragment-based drug
design to suggest new fragments or to replace existing fragments within
an already known compound. A novel computational method called SubCav
is described which allows the similarity searching and alignment of
subpockets from a PDB-wide database against a user-defined query.
The method is based on pharmacophoric fingerprints combined with a
subpocket alignment algorithm. SubCav was shown to be effective in
producing reasonable alignments for subpockets with low sequence similarity
and be able to retrieve relevant subpockets from a large database
of structures including those with different folds. It can also be
used to analyze subpockets inside a protein family to facilitate drug
design and to rationalize compound selectivity
Subpocket Analysis Method for Fragment-Based Drug Discovery
Although two binding sites might be dissimilar overall,
they might
still bind the same fragments if they share suitable subpockets. Information
about shared subpockets can be therefore used in fragment-based drug
design to suggest new fragments or to replace existing fragments within
an already known compound. A novel computational method called SubCav
is described which allows the similarity searching and alignment of
subpockets from a PDB-wide database against a user-defined query.
The method is based on pharmacophoric fingerprints combined with a
subpocket alignment algorithm. SubCav was shown to be effective in
producing reasonable alignments for subpockets with low sequence similarity
and be able to retrieve relevant subpockets from a large database
of structures including those with different folds. It can also be
used to analyze subpockets inside a protein family to facilitate drug
design and to rationalize compound selectivity