Abstract
Induced pluripotent stem cell (iPSC) technology is revolutionizing cell biology. However, the variability between individual iPSC lines and the lack of efficient technology to comprehensively characterize iPSC-derived cell types hinder its adoption in routine preclinical screening settings. To facilitate the validation of iPSC-derived cell culture composition, we have implemented an imaging assay based on cell painting and convolutional neural networks to recognize cell types in dense and mixed cultures with high fidelity. We have benchmarked our approach using pure and mixed cultures of neuroblastoma and astrocytoma cell lines and attained a classification accuracy above 96%. Through iterative data erosion we found that inputs containing the nuclear region of interest and its close environment, allow achieving equally high classification accuracy as inputs containing the whole cell for semi-confluent cultures and preserved prediction accuracy even in very dense cultures. We then applied this regionally restricted cell profiling approach to evaluate the differentiation status of iPSC-derived neural cultures, by determining the ratio of postmitotic neurons and neural progenitors. We found that the cell-based prediction significantly outperformed an approach in which the time in culture was used as classification criterion (96% vs. 86%, resp.). In mixed iPSC-derived neuronal cultures, microglia could be unequivocally discriminated from neurons, regardless of their reactivity state. A tiered strategy, allowed for discriminating microglial cell states as well, albeit with lower accuracy. Thus, morphological single cell profiling provides a means to quantify cell composition in complex mixed neural cultures and holds promise for use in quality control of iPSC-derived cell culture models.
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
e-mail:
sarah.debeuckeleer{at}uantwerpen.be
tim.vandelooverbosch{at}uantwerpen.be
johanna.vandendaele{at}uantwerpen.be
peter.ponsaerts{at}uantwerpen.be
winnok.devos{at}uantwerpen.be
We have carefully analyzed the reviewers' comments and deduced that the work could benefit from a better description of the operational window and a clearer validation of the nculeocentric profiling approach. Therefore, we have now performed additional experiments to address the main comments. To prove the sensitivity of our approach, we have included predictions using cells types and cell states with more subtle differences. In addition, we have benchmarked our nucleocentric analysis by illustrating the prediction performance across a range of crop sizes. In doing so, we could conclude that there is an optimal nucleocentric size where precision and recall are balanced. To further convince the reviewers of our conclusions, we have added additional GradCAM images and performed several control experiments to rule out bias introduced by the background or the segmentation performance.
https://figshare.com/articles/dataset/Nucleocentric-Profiling/27141441?file=49522557
Abbreviations
- BrdU
- Bromodeoxyuridine
- CNN
- convolutional neural network
- CP
- cell painting
- DAPI
- 4’,6-diamidino-2-fenylindool
- DIV
- days in vitro
- EdU
- 5-ethynyl-2’-deoxyuridine
- ER
- endoplasmic reticulum
- Grad-CAM
- Gradient-weighted Class Activation Mapping
- IF
- immunofluorescence
- iPSC
- induced pluripotent stem cell
- NPC
- neural progenitor cell
- RF
- random forest
- ROI
- region of interest
- TUBB3
- beta-III-tubulin
- UMAP
- Uniform Manifold Approximation and Projection