Our ability to connect genotypic variation to biologically important phenotypes has been seriously limited by the gap between live-cell microscopy and library-scale genomic engineering. Here, we show how in situ genotyping of a library of strains after time-lapse imaging in a microfluidic device overcomes this problem. We determine how 235 different CRISPR interference knockdowns impact the coordination of the replication and division cycles of Escherichia coli by monitoring the location of replication forks throughout on average >500 cell cycles per knockdown. Subsequent in situ genotyping allows us to map each phenotype distribution to a specific genetic perturbation to determine which genes are important for cell cycle control. The single-cell time-resolved assay allows us to determine the distribution of single-cell growth rates, cell division sizes and replication initiation volumes. The technology presented in this study enables genome-scale screens of most live-cell microscopy assays.
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The code used to analyze the DuMPLING microscopy images and generate figures associated with the DuMPLING experiments is provided as Supplementary Software.
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This work was supported by the Knut and Alice Wallenberg Foundation (2017.0291 and 2016.0077), the European Research Council (616047) and the Swedish Research Council (VR)(642-2013-7841 and 2016-06213). We are grateful to I. Barkefors for help with the manuscript and figures, to P. Karempudi for making microfluidic molds and to the Dan Andersson lab for kindly sharing E. coli strains.
The DuMPLING technology is patented with European patent no. EP3167061 (B1).
Peer review information Rita Strack was the primary editor on this article and managed its editorial process and peer review in collaboration with the rest of the editorial team.
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Integrated supplementary information
Image adapted from (Baltekin et al. 201713). The holes punched in the PDMS before bonding it to the PDMS are 2.0 (media in, front channel), 7.0 and 8.0 (waste port, front channel), 5.1 and 5.2 (waste port, back channel), 2.1 and 2.2 (cell loading or waste port, front channel).
Identical line style indicates three replicate cultures from three different colonies of the same plasmid construct in the test strain. No sgRNA: Negative sgRNA control plasmid pGuide-empty. lacY sgRNA: sgRNA against lacY from plasmid pGuide-P1-lacY. Glucose or lactose was used as supplemental carbon source and dCas9 expression/CRISPRi was induced with aTc (+ aTc). This assay was carried out once.
Supplementary Fig. 3 Comparison of relative abundances of genotypes in DuMPLING and NGS experiments.
Horizontal axis: Relative abundance of each strain as measured by next generation sequencing. (Raw sequence counts given in Supplementary Table 2) Vertical Axis: Relative abundance of each strain in the microfluidic chip. (The number of measurements for each genotype is equal to its number of traps as given in Supplementary Table 1.) Colors of dots indicate the growth rate of each genotype as estimated by NGS.
Histogram of average cell pixel intensity per trap after background reduction in logarithmic scale. The lower intensity fluorescence peaks are fitted to Gaussians (solid red line) and genotypes are determined when the probe fluorescence signal reaches above 7 times the standard deviations (dashed red lines) of the fitted Gaussians. See the Image analysis subsection on Genotyping in the Methods for details of how to determine genotypes.
A. (left) Fork distribution plot of ref strain (same data as Fig. 3e). Horizontal is SeqA-YFP cluster location along the long axis of the cell, vertical is cell size, color indicates the probability of finding a SeqA-YFP foci at a given position along the cell long axis for a given cell size. Initiation size (red dashed line) corresponds to the average of individually tracked replication forks. (right) Estimating initiation size (dashed red line) by fitting an error function (solid red line) to bulk data (blue squares) from the regions |x|>0.44 μm in the forkplot. B. (left) Same as Fig. 2c. (right) Estimating initiation size (dashed red line) by fitting a Gaussian (solid red line) to the relative histogram of single cell initiation sizes. C. Same as Fig. 3f in main text.
Correlation plots for normalized average growth rate (Pearson correlation = 0.86, n=215 different strains where growth rates were estimated in both run 1 and run 2), normalized average birth size (Pearson correlation = 0.78, n=215 different strains where birth sizes were estimated in both run 1 and run 2) and normalized average initiation size (Pearson correlation = 0.74, n=191 different strains where initiation sizes were estimated in both run 1 and run 2) between duplicate experiments. Deviations by more than 0.1 from the straight line where run 1 = run 2 are indicated by names. The number of data points used to estimate each average in the three different panels is given in Supplementary Table 1. Reference control strain (ref) is indicated with red dots.
Supplementary Figs. 1–12 and Notes 1–4.
Example of time-lapse fluorescence imaging; one position with segmented cell outlines (yellow) and detected SeqA-YFP clusters (red). The video is truncated in time compared with the complete experiment.
Collage of time-lapse phase contrast imaging; from 1/3 of the positions in one experiment. The video is truncated in time compared with the complete experiment.
Collage of time-lapse fluorescence imaging; from 1/3 of the positions in one experiment. The video is truncated in time compared with the complete experiment.
Fluorescence time-lapse imaging of three cell traps genotyped as ref traps; images are overlaid with segmented cell outlines (yellow) and detected SeqA-YFP clusters (red). There is 2 min between fluorescence images in the experiment. The video playback rate is 7 fps.
Fluorescence time-lapse imaging of three cell traps genotyped as dedD traps; images are overlaid with segmented cell outlines (yellow) and detected SeqA-YFP clusters (red). There is 2 min between fluorescence images in the experiment. The video playback rate is 7 fps.
Fluorescence time-lapse imaging of three cell traps genotyped as hda traps; images are overlaid with segmented cell outlines (yellow) and detected SeqA-YFP clusters (red). There is 2 min between fluorescence images in the experiment. The video playback rate is 7 fps.
Fluorescence time-lapse imaging of three cell traps genotyped as clpP traps; images are overlaid with segmented cell outlines (yellow) and detected SeqA-YFP clusters (red). There is 2 min between fluorescence images in the experiment. The video playback rate is 7 fps.
Time-lapse phase contrast imaging of three traps with single-gene clpP knockdown cells; there is 5 min between phase contrast images in the experiment. The video playback is at 7 fps.
Time-lapse phase contrast imaging of three traps with single-gene clpP knockout cells; there is 5 min between phase contrast images in the experiment. The video playback is at 7 fps.
DuMPLING data and statistics; estimates of mean and CV of growth rate, birth size and initiation size for each genotype in two replicates of the DuMPLING microscopy experiments (shown in two different tabs, ‘run 1’ and ‘run 2’). Each estimate is normalized to the ref strain in each experiment. The table also includes the number of data points used in each estimate (N cells) and the number of traps (N traps) that each detected genotype occupies. For initiation size bulk, the column ‘N cell detections’ implies the total number of detected SeqA-YFP foci used in fitting the initiation size.
NGS statistics; the number of occurrences of each strain before (t = 0) and after (t = 12 h) pooled competition is indicated, as well as the corresponding fractional abundances calculated from the numbers of occurrences. The resulting changes in relative abundance and relative fitness are also given, calculated as described in Supplementary Note 3.
Comparison of DuMPLING experiments with single-gene knockdown and knockouts; for nine selected genotypes. Table includes normalized means, normalized CV and the number of data points used to estimate these (N cells).
List of genes in each of the transcriptional units of the CRISPRi target genes in the DuMPLING library; the table also includes genes in each transcriptional unit that have been reported essential.
Sequences of CRISPRi spacers, barcodes and oligonucleotides; for each genotype in the DuMPLING library.
Strains used in this study; includes genotypes and description.
Compressed file with all software used to derive and analyze the DuMPLING data.
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Camsund, D., Lawson, M.J., Larsson, J. et al. Time-resolved imaging-based CRISPRi screening. Nat Methods 17, 86–92 (2020). https://doi.org/10.1038/s41592-019-0629-y
Nature Methods (2020)
Microbiology and Molecular Biology Reviews (2020)
Nucleic Acids Research (2020)
ACS Synthetic Biology (2020)