# A framework to integrate live-cell imaging with single-cell sequencing and learn how cells adapt to new environments

> **NIH NIH R03** · H. LEE MOFFITT CANCER CTR & RES INST · 2023 · $81,686

## Abstract

Abstract
Exposing cancer cells to a new environment typically influences their growth. For some cells, a moderate growth
inhibition is followed by adaptation and return to normal growth rates. Others initially experience a near-complete
cytostatic phenotype, only to explode in their growth during later generations, reaching growth rates well beyond
baseline. This implies that one can reach opposite conclusions about the relative fitness of two cell lineages, solely
depending on timing of measurement. This has implications for the time window of therapeutic success, in light of
the fact that virtually all pre-clinical drug screening studies measure growth rate at a single, well defined timepoint
– typically 72 hours after exposure. Despite this shortcoming, measurements of cell fitness at multiple timepoints
are impractical for large-scale studies. Our long-term goal is the development of a new class of temporal biomarkers
that extrapolate from a cell's transcriptome how fit its descendants will be over multiple generations. As a next
step towards this goal we propose a feasibility study to collect training data of su!cient temporal reach and cellular
resolution to evaluate the predictability of cell fitness. With a broad record of integrating various omics- and imaging
platforms and as the developers of widely deployed drug response metrics, our team brings complementary expertise
to integrate live-cell imaging with single cell sequencing for deep learning. We will record how cells divide, migrate and
die, linking the recorded phenotypic di"erences between cells to di"erences between their transcriptomes. Aim 1 will
use live-cell imaging to characterize the cell cycle of cancer cell clones as they adapt to new environments. Hereby
we define a growth condition as the combination between founding cell and micro-environment. We hypothesize that
time emphasizes di"erences between growth conditions, i.e. that cell cycle progression profiles from distinct growth
conditions diverge as their cells converge on a specific path of adaptation. This temporal evolution of cell adaptation will
inform which generation is optimal for single-cell RNA sequencing, namely when cell counts are su!ciently high, but the
path of adaptation is not yet phenotypically evident. In aim 2 we will test the potential of the transcriptome to predict
this path. To achieve this we will use a three-layered approach to map sequenced- and imaged cells in-silico. Hereby
biological variability – emerging from multiple growth conditions – acts as an additional barcode during sequencing. This
linking will not only match the sequenced cell's transcriptome to the one phenotype of the corresponding imaged cell,
but also to adaptive phenotypes of all its ancestors. The outcome of these two aims will be training data to learn: (i)
whether a snapshot of a transcriptome has the potential to forecast speed and success rate of cell cycle progression; (ii)
the temporal limitations of such predictions and (i...

## Key facts

- **NIH application ID:** 10530677
- **Project number:** 5R03CA259873-02
- **Recipient organization:** H. LEE MOFFITT CANCER CTR & RES INST
- **Principal Investigator:** Noemi Andor
- **Activity code:** R03 (R01, R21, SBIR, etc.)
- **Funding institute:** NIH
- **Fiscal year:** 2023
- **Award amount:** $81,686
- **Award type:** 5
- **Project period:** 2021-12-01 → 2024-11-30

## Primary source

NIH RePORTER: https://reporter.nih.gov/project-details/10530677

## Citation

> US National Institutes of Health, RePORTER application 10530677, A framework to integrate live-cell imaging with single-cell sequencing and learn how cells adapt to new environments (5R03CA259873-02). Retrieved via AI Analytics 2026-05-25 from https://api.ai-analytics.org/grant/nih/10530677. Licensed CC0.

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