Genetically encoded fluorescent sensors for visualizing polyamine levels, uptake, and distribution.
Ryo TamuraJialin ChenMarijke De JaegerJacqueline F MorrisDavid A ScottPeter VangheluweLoren L LoogerPublished in: bioRxiv : the preprint server for biology (2024)
Polyamines are abundant and physiologically essential biomolecules that play a role in numerous processes, but are disrupted in diseases such as cancer, and cardiovascular and neurological disorders. Despite their importance, measuring free polyamine concentrations and monitoring their metabolism and uptake in cells in real-time remains impossible due to the lack of appropriate biosensors. Here we engineered, characterized, and validated the first genetically encoded biosensors for polyamines, named iPASnFRs. We demonstrate the utility of iPASnFR for detecting polyamine import into mammalian cells, to the cytoplasm, mitochondria, and the nucleus. We demonstrate that these sensors are useful to probe the activity of polyamine transporters and to uncover biochemical pathways underlying the distribution of polyamines amongst organelles. The sensors powered a high-throughput small molecule compound library screen, revealing multiple compounds in different chemical classes that strongly modulate cellular polyamine levels. These sensors will be powerful tools to investigate the complex interplay between polyamine uptake and metabolic pathways, address open questions about their role in health and disease, and enable screening for therapeutic polyamine modulators.
Keyphrases
- small molecule
- high throughput
- low cost
- healthcare
- living cells
- public health
- quantum dots
- induced apoptosis
- papillary thyroid
- cell death
- squamous cell carcinoma
- signaling pathway
- young adults
- cell proliferation
- minimally invasive
- endoplasmic reticulum stress
- risk assessment
- label free
- subarachnoid hemorrhage
- squamous cell
- endoplasmic reticulum
- pi k akt
- childhood cancer