Abstract
Objectives
Salmonella bacteria can induce the unfolded protein response, a cellular stress response to misfolding proteins within the endoplasmic reticulum. Salmonella can exploit the host unfolded protein response leading to enhanced bacterial replication which was in part mediated by the induction and/or enhanced endo-reticular membrane synthesis. We therefore wanted to establish a quantitative confocal imaging assay to measure endo-reticular membrane expansion following Salmonella infections of host cells.
Data description
High-content screening confocal fluorescence microscopic image set of Salmonella infected HeLa cells is presented. The images were collected with a PerkinElmer Opera LX high-content screening system in seven 96-well plates, 50 field-of-views and DAPI, endoplasmic reticulum tracker channels and Salmonella mCherry protein in each well. Totally 93,300 confocal fluorescence microscopic images were published in this dataset. An ImageJ high-content image analysis workflow was used to extract features. Cells were classified as infected and non-infected, the mean intensity of endoplasmic reticulum tracker under Salmonella bacteria was calculated. Statistical analysis was performed by an R script, quantifying infected and non-infected cells for wild-type and ΔsifA mutant cells. The dataset can be further used by researchers working with big data of endoplasmic reticulum fluorescence microscopic images, Salmonella bacterial infection images and human cancer cells.
Keywords: Salmonella, Unfolded protein response, Endoplasmic reticulum, High-content screening, Image-based screening, Phenotypic screening, Confocal image, Cellular morphology, HeLa
Objective
Salmonella bacterial infections can lead to the development of inflammatory arthritis, known as Reactive Arthritis (ReA) within a subgroup of patients predominantly expressing the Human Leukocyte Antigen (HLA) class I molecule HLA-B27 [1, 2]. ReA is a member of the inflammatory arthritic diseases known as the spondyloarthropathies, which have been proposed to arise from the induction of the unfolded protein response (UPR), a cellular stress response to misfolding proteins within the endoplasmic reticulum (ER). HLA-B27 has been proposed to contribute and/or initiate the UPR [3]. The expression of HLA-B27 can contribute to enhanced Salmonella recovery [4]. We therefore proposed that Salmonella could exploit the UPR environment and induce the UPR. Recently, we have established that following Salmonella infection of host epithelial cells, the unfolded protein response (UPR) is activated. Salmonella exploit the UPR response to enhance bacterial replication, partly through UPR induced lipid biosynthetic pathways [5]. Previously, it has been established that part of the UPR pathway leads to the expansion of ER membranes through the activation and/or regulation of lipid biosynthetic pathways [6]. Therefore, we wanted to establish a confocal imaging method that could quantitatively determine endo-reticular membrane expansion, across a range of Salmonella infection conditions.
The quantification of endo-reticular membrane content was needed in infected cells in order to assess the increase of endo-reticular membranes due to Salmonella infection. ER tracker staining was used for the quantification of endo-reticular membrane content in infected cells.
The image dataset, ImageJ [7] macro and R [8] script presented here can be useful not only for the molecular biologist and biomedical researchers focusing to Salmonella providing them with an open-source software-based data analysis pipeline, but to the wider bioimage analysis community. Thousands of high-quality fluorescence nuclear, ER and Salmonella images can be used by software developers of image processing algorithms.
Data description
The data report here (Table 1) is a high-content screening confocal fluorescence microscopic image set of Salmonella infected HeLa cells and its analysis.
Table 1.
Overview of data files
| Label | Name of data file/data set | File types (file extension) | Data repository and identifier (DOI or accession number) |
|---|---|---|---|
| Plate [1–7] _365nm.zip_ | DAPI channel, 365 nm excitation wavelength, 16 bit pixel depth confocal fluorescence microscopic images, stacks of 96 well plates (7 files) | Image stacks saved in LZW compressed, native ImageJ .zip format that can be opened with ImageJ after renaming the extension from .zip_ to .zip | Harvard Dataverse [10] |
| Plate [1–7] _488nm.zip_ | ER tracker channel, 488 nm laser excitation wavelength, 16 bit pixel depth confocal fluorescence microscopic images, stacks of 96 well plates (7 files) | Image stacks saved in LZW compressed, native ImageJ .zip format that can be opened with ImageJ after renaming the extension from .zip_ to .zip | Harvard Dataverse 10.7910/DVN/FYGHFO |
| Plate [1–7] _561nm.zip_ | mCherry Salmonella channel, 561 nm laser excitation wavelength, 16 bit pixel depth confocal fluorescence microscopic images, stacks of 96 well plates (7 files) | Image stacks saved in LZW compressed, native ImageJ .zip format that can be opened with ImageJ after renaming the extension from .zip_ to .zip | Harvard Dataverse 10.7910/DVN/FYGHFO |
| ST_exp60_confocal_infection_plates.xls | Plate layout including ERT concentrations | MS Excel file (.xls) | Harvard Dataverse 10.7910/DVN/FYGHFO |
| Plate 2_Thr = 235.tif.zip_ | Segmented 8 bit pixel depth binary images, stacks of 96 well plates | Image stacks saved in LZW compressed, native ImageJ .zip format that can be opened with ImageJ after renaming the extension from .zip_ to .zip | Harvard Dataverse 10.7910/DVN/FYGHFO |
| Plate 3_Thr = 180.tif.zip_ | Same as above | Same as above | Same as above |
| Plate 4_Thr228-7275.tif.zip_ | Same as above | Same as above | Same as above |
| Plate 5_Thr = 270.tif.zip_ | Same as above | Same as above | Same as above |
| Plate 6_Thr = 197_sizefiltered_250px- = 26um2-.tif.zip_ | Same as above | Same as above | Same as above |
| Plate 7_Thr = 177_sizefiltered_250px- = 26um2-.tif.zip_ | Same as above | Same as above | Same as above |
| ImageJ_macro_ijm.txt | ImageJ macro file | Text file (.txt) | Harvard Dataverse 10.7910/DVN/FYGHFO |
| Infected_cell_ER_signal_Plate 2–7.zip_ | Table containing extracted features as a result of image analysis | LZW compressed (.zip) Comma Separated Value (.csv) text files that can be opened for further processing with R or MS Excel after renaming the extension from .zip_ to .zip and uncompress | Harvard Dataverse 10.7910/DVN/FYGHFO |
| Plates 2–3.R | R script | Text file (.txt) | Harvard Dataverse 10.7910/DVN/FYGHFO |
| Plates 4–5.R | R script | Text file (.txt) | Harvard Dataverse 10.7910/DVN/FYGHFO |
| Plates 6–7.R | R script | Text file (.txt) | Harvard Dataverse 10.7910/DVN/FYGHFO |
Plate layouts
Plate 1: A non-infected control plate was used, which contained HeLa cells were not infected with Salmonella enterica and were stained with varying endoplasmic reticulum (ER) tracker (ERT) concentrations.
Plates 2–7: HeLa cells were infected with either wild-type Salmonella enterica or the isogenic S. enterica Typhimurium ΔsifA mutant using various multiplicity of infections (MOI) and were fixed 4, 16 or 24 h post infection.
Image acquisition equipment and experimental setup
Confocal fluorescence microscopy images were acquired during a high-content screening session. Opera LX (PerkinElmer) confocal microscope was used for imaging (40 × air objective, NA = 0.6). Exposure times were used as follows: 100 ms for the DAPI-stained nuclear channel (365 nm excitation wavelength), 2000 ms for the ER tracker channel (488 nm laser excitation wavelength), 2000 ms for the Salmonella that constitutively expressed the mCherry fluorescent protein (561 nm laser excitation wavelength). 2 by 2 camera pixels were binned (integrated) resulting in a pixel size of 0.323 × 0.323 μm. 50 field-of-view (FoV) images were acquired in each well, 4800 per 96-well plate.
Image processing and data analysis
The image processing software was performed with ImageJ and the statistical data was analyzed with R.
The 561 nm channel image stacks were segmented using the highest pixel intensity of a given image stack as higher threshold value. The lower threshold was specified manually based on visual inspection in order to exclude the out of focus pixels. Size filter of 26 μm2 (250 pixel) was applied to plate 6 and 7 because of the presence of Salmonella Containing Vesicles containing large numbers of bacteria. The segmentation resulted in the binary mask of the Salmonella bacteria particles and the mean intensity of ER tracker pixels in 488 nm channel was measured under each cell. Cells were labeled as either “infected” or “non-infected” based on the presence or absence of Salmonella bacteria particles. Each cell with its fluorescence values can be correlated with its image based on their well position identifier (label column) in the extracted feature measurement file and the plate layout file.
The statistical data analysis was conducted by R scripts designed to process 4 h (plates 2–3), 16 h (plates 4–5) and 24 h (plates 6–7) post-infection together respectively and are available in the dataset of this paper. The workflow separated the intensity values infected and non-infected cells into separate files. This design provides the advantage that the high-throughput workflow can be done by a powerful R script, while flexibility is given to perform the significance test with any statistical application. Initially, the ImageJ macro-generated result files from multiple FoVs were opened. The script automatically opens all of the generated.csv files in a specific folder. Consecutively, the infected and non-infected cells for wild-type and ΔsifA mutant cells were identified and saved into separate text files respectively. That result was used for significance test, reported in Ref. [5].
Limitations
Camera binning, integration of 2 by 2 pixels was used in order to maximize signal strength. That resulted in the fourfold increase of signal. However, the effective resolution of the microscope’s CCD camera was reduced accordingly to 671 × 497 pixels.
The described implementation of the image processing pipeline required a PC that is equipped with enough RAM memory (e.g. 32 GB) where a channel of a plate’s stack can be loaded and processed.
Infections were performed at 60–80% confluency and therefore cell density was not uniform in every FoVs. This limitation was addressed during image processing by analyzing FoVs with higher mean intensities in their nuclear channel.
The method has only been tested in a single cell line. The HeLa cell line was chosen on the basis that HeLa cells do not express Toll Like Receptor (TLR) ligands. HeLa cells along with other epithelial cell lines such as 293T were assay for TLR activation using a TLR-NF-kB reporter. HeLa cells demonstrated a lack of TLR expression. The reasoning behind using a TLR negative cell line is that it has been previously reported that TLR engagement can activate the UPR activated transcription factor XBP-1 [9] which can affect lipid and ER membrane biosynthesis. We therefore required conditions which would best dissect impact of Salmonella on the UPR and ER membrane synthesis, without additional TLR mediated effects. Therefore, for our analysis to be extended into further cell types, the potential contribution of innate receptor engagement to UPR induction and ER biosynthesis must be taken into account.
Acknowledgements
We thank Robin Ketteler for helpful suggestions regarding high-content screening.
Abbreviations
- ER
endoplasmic reticulum
- ERT
endoplasmic reticulum tracker
- UPR
unfolded protein response
- MOI
multiplicity of infections
- OME
open microscopy environment
- FoV
field-of-view
- Thr
threshold
Authors’ contributions
JKV wrote the manuscript, acquired the high-content screening images, designed and implemented the high-content image processing and statistical analysis algorithms. ANA contributed to the planning, designing of experiments, interpretation of data and writing the manuscript. SJP contributed to the data interpretation, experimental design and writing of the manuscript. SJP contributed to the biochemical analysis of the cell lines employed throughout the study. All authors have read and approved the manuscript.
Funding
This work was supported by the Medical Research Council Core funding the MRC LMCB (MC_U12266B) (JKV) and the EU FP7 Marie-Curie International Reintegration Grant PIRG08-GA-2010-276811 (JKV). ANA was funded by ARUK Fellowships Non-Clinical Career Development Fellowship Ref No: 18440. ANA and SJP were also in part funded by ARUK (Grant 21261).
Availability of data and materials
The data described in this Data Note can be freely and openly accessed on Harvard Dataverse 10.7910/DVN/FYGHFO. Please see Table 1 and reference list for details and links to the data.
Ethics approval and consent to participate
Not applicable.
Consent for publication
Not applicable.
Competing interests
The authors declare that they have no competing interests.
Footnotes
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Contributor Information
Antony N. Antoniou, Email: antony.antoniou@northumbria.ac.uk
Simon J. Powis, Email: sjp10@st-andrews.ac.uk
Janos Kriston-Vizi, Email: j.kriston@ucl.ac.uk.
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Associated Data
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Data Availability Statement
The data described in this Data Note can be freely and openly accessed on Harvard Dataverse 10.7910/DVN/FYGHFO. Please see Table 1 and reference list for details and links to the data.