Image analysis workflows to reveal the spatial organization of cell nuclei and chromosomes.
Ricardo S RandallClaire JourdainAnna NowickaKateřina KaduchováMichaela KubováMohammad A AyoubVeit SchubertChristophe TatoutIsabelle ColasKalyanikrishna .Sophie DessetSarah MermetAurélia Boulaflous-StevensIvona KubalováTerezie M MandakovaStefan HeckmannMartin A LysakMartina PanattaRaffaella SantoroDaniel SchubertAles PecinkaDevin RouthCélia BarouxPublished in: Nucleus (Austin, Tex.) (2022)
Nucleus, chromatin, and chromosome organization studies heavily rely on fluorescence microscopy imaging to elucidate the distribution and abundance of structural and regulatory components. Three-dimensional (3D) image stacks are a source of quantitative data on signal intensity level and distribution and on the type and shape of distribution patterns in space. Their analysis can lead to novel insights that are otherwise missed in qualitative-only analyses. Quantitative image analysis requires specific software and workflows for image rendering, processing, segmentation, setting measurement points and reference frames and exporting target data before further numerical processing and plotting. These tasks often call for the development of customized computational scripts and require an expertise that is not broadly available to the community of experimental biologists. Yet, the increasing accessibility of high- and super-resolution imaging methods fuels the demand for user-friendly image analysis workflows. Here, we provide a compendium of strategies developed by participants of a training school from the COST action INDEPTH to analyze the spatial distribution of nuclear and chromosomal signals from 3D image stacks, acquired by diffraction-limited confocal microscopy and super-resolution microscopy methods (SIM and STED). While the examples make use of one specific commercial software package, the workflows can easily be adapted to concurrent commercial and open-source software. The aim is to encourage biologists lacking custom-script-based expertise to venture into quantitative image analysis and to better exploit the discovery potential of their images. Abbreviations: 3D FISH: three-dimensional fluorescence in situ hybridization; 3D: three-dimensional; ASY1: ASYNAPTIC 1; CC: chromocenters; CO: Crossover; DAPI: 4',6-diamidino-2-phenylindole; DMC1: DNA MEIOTIC RECOMBINASE 1; DSB: Double-Strand Break; FISH: fluorescence in situ hybridization; GFP: GREEN FLUORESCENT PROTEIN; HEI10: HUMAN ENHANCER OF INVASION 10; NCO: Non-Crossover; NE: Nuclear Envelope; Oligo-FISH: oligonucleotide fluorescence in situ hybridization; RNPII: RNA Polymerase II; SC: Synaptonemal Complex; SIM: structured illumination microscopy; ZMM (ZIP: MSH4: MSH5 and MER3 proteins); ZYP1: ZIPPER-LIKE PROTEIN 1.
Keyphrases
- single molecule
- high resolution
- deep learning
- living cells
- transcription factor
- data analysis
- convolutional neural network
- electronic health record
- energy transfer
- mental health
- healthcare
- endothelial cells
- high throughput
- artificial intelligence
- physical activity
- single cell
- small molecule
- big data
- open label
- genome wide
- label free
- high speed
- binding protein
- systematic review
- machine learning
- squamous cell carcinoma
- locally advanced
- oxidative stress
- dna methylation
- dna damage
- photodynamic therapy
- microbial community
- cell free
- human health
- climate change
- randomized controlled trial
- clinical trial
- protein protein
- cell therapy
- bone marrow
- cell migration
- risk assessment
- circulating tumor
- amino acid
- placebo controlled
- radiation therapy
- rectal cancer