Automatic identification and clustering of chromosome phenotypes in a genome wide RNAi screen by time-lapse imaging.

High-throughput time-lapse microscopy is an excellent way of studying gene function by collecting time-resolved image data of the cellular responses to gene perturbations. With the increase in both data amount and complexity, computational methods capable of dealing with large image data sets are required. While image processing methods have been successfully applied to endpoint assays in the past, the analysis of complex time-resolved read-outs was so far still too immature to be applied on a large-scale. Here, we present a complete computational processing pipeline for such screens. By automatic image processing and machine learning, a quantitative description of phenotypic dynamics is obtained from the raw bitmaps. In order to visualize the resulting phenotypes in their temporal context, we introduce Event Order Maps allowing a concise representation of the major tendencies of causes and consequences of phenotypic classes. In order to cluster the phenotypic kinetics, we propose a novel technique based on trajectory representation of multidimensional time series. We demonstrate the use of these methods applying them on a genome wide RNAi screen by time-lapse microscopy.

[1]  J. Serra,et al.  Contrasts and activity lattice , 1989 .

[2]  Charles Y. Tao,et al.  A Support Vector Machine Classifier for Recognizing Mitotic Subphases Using High-Content Screening Data , 2007, Journal of biomolecular screening.

[3]  Douglas A. Creager,et al.  The Open Microscopy Environment (OME) Data Model and XML file: open tools for informatics and quantitative analysis in biological imaging , 2005, Genome Biology.

[4]  Polina Golland,et al.  Scoring diverse cellular morphologies in image-based screens with iterative feedback and machine learning , 2009, Proceedings of the National Academy of Sciences.

[5]  M V Boland,et al.  Automated recognition of patterns characteristic of subcellular structures in fluorescence microscopy images. , 1998, Cytometry.

[6]  Anne E Carpenter,et al.  CellProfiler: image analysis software for identifying and quantifying cell phenotypes , 2006, Genome Biology.

[7]  R. Durbin,et al.  Phenotypic profiling of the human genome by time-lapse microscopy reveals cell division genes , 2010, Nature.

[8]  Michael Hahsler,et al.  Getting Things in Order: An Introduction to the R Package seriation , 2008 .

[9]  Tomaso A. Poggio,et al.  A general framework for object detection , 1998, Sixth International Conference on Computer Vision (IEEE Cat. No.98CH36271).

[10]  M. Wand Local Regression and Likelihood , 2001 .

[11]  H. Erfle,et al.  High-throughput RNAi screening by time-lapse imaging of live human cells , 2006, Nature Methods.

[12]  Pierre Soille,et al.  Morphological Image Analysis: Principles and Applications , 2003 .

[13]  Chris Allan,et al.  Open tools for storage and management of quantitative image data. , 2008, Methods in cell biology.

[14]  Lani F. Wu,et al.  Multidimensional Drug Profiling By Automated Microscopy , 2004, Science.

[15]  Xiaobo Zhou,et al.  Automated segmentation, classification, and tracking of cancer cell nuclei in time-lapse microscopy , 2006, IEEE Transactions on Biomedical Engineering.

[16]  Jean Serra,et al.  Image Analysis and Mathematical Morphology , 1983 .

[17]  Richard J. Prokop,et al.  A survey of moment-based techniques for unoccluded object representation and recognition , 1992, CVGIP Graph. Model. Image Process..

[18]  Brian Everitt,et al.  Cluster analysis , 1974 .

[19]  C. Conrad,et al.  Automatic identification of subcellular phenotypes on human cell arrays. , 2004, Genome research.

[20]  Lani F. Wu,et al.  Image-based multivariate profiling of drug responses from single cells , 2007, Nature Methods.

[21]  Chih-Jen Lin,et al.  LIBSVM: A library for support vector machines , 2011, TIST.

[22]  Jae-Gil Lee,et al.  Trajectory clustering: a partition-and-group framework , 2007, SIGMOD '07.

[23]  D. Sabatini,et al.  Microarrays of cells expressing defined cDNAs , 2001, Nature.

[24]  Anne E Carpenter,et al.  Dynamic proteomics in individual human cells uncovers widespread cell-cycle dependence of nuclear proteins , 2006, Nature Methods.

[25]  Holger Erfle,et al.  siRNA cell arrays for high-content screening microscopy. , 2004, BioTechniques.

[26]  Robert M. Haralick,et al.  Textural Features for Image Classification , 1973, IEEE Trans. Syst. Man Cybern..

[27]  Xiaobo Zhou,et al.  A computerized cellular imaging system for high content analysis in Monastrol suppressor screens , 2006, J. Biomed. Informatics.

[28]  R. Murphy,et al.  Automated subcellular location determination and high-throughput microscopy. , 2007, Developmental cell.

[29]  Tommi S. Jaakkola,et al.  Fast optimal leaf ordering for hierarchical clustering , 2001, ISMB.

[30]  Kendall Preston,et al.  Multicomputers and Image Processing: Algorithms and Programs , 1982 .

[31]  Fernand Meyer Automatic screening of cytological specimens , 1986 .

[32]  Xiaobo Zhou,et al.  Integrated Algorithms for Image Analysis and Classification of Nuclear Division for High-Content Cell-Cycle Screening , 2006, Int. J. Comput. Intell. Appl..

[33]  Paul T. Jackway,et al.  Statistical geometric features-extensions for cytological texture analysis , 1996, Proceedings of 13th International Conference on Pattern Recognition.

[34]  Stephen T. C. Wong,et al.  Cellular Phenotype Recognition for High-Content RNA Interference Genome-Wide Screening , 2008, Journal of biomolecular screening.

[35]  R Eils,et al.  Automated classification of mitotic phenotypes of human cells using fluorescent proteins. , 2008, Methods in cell biology.

[36]  Meng Wang,et al.  Novel cell segmentation and online SVM for cell cycle phase identification in automated microscopy , 2008, Bioinform..