nELISA: A high-throughput, high-plex platform enables quantitative profiling of the secretome.
Milad DagherGrant OngoNathaniel RobichaudJinglin KongWoojong RhoIvan TeahulosArya TavakoliSamantha BovairdShahem MerjanehAndrew TanKiran EdwardsonChristelle ScheepersAndy NgAndy HajjarAndy LeePhilippe DeCorwin-MartinShafqat RasoolJiaMin HuangYu HanSrinivas Niranj ChandrasekaranLisa MillerMaria Kost-AlimovaAdam SkepnerShantanu SinghJeffrey MunzarAnne E CarpenterDavid JunckerPublished in: bioRxiv : the preprint server for biology (2023)
We present the nELISA, a miniaturised, high-throughput, and high-fidelity protein profiling platform. DNA oligonucleotides are used to pre-colocalize antibody pairs on spectrally encoded microparticles and perform displacement-mediated detection while ensuring spatial separation between non-cognate antibody pairs. Read-out is performed cost-efficiently and at high-throughput using flow cytometry. We assembled an inflammatory panel of 191 targets that were multiplexed without cross-reactivity or impact to performance vs 1-plex signals, with sensitivities as low as 0.1pg/mL and measurements across the platform spanning 8 orders of magnitude. We then performed a large-scale PBMC secretome screen, with cytokines as both perturbagens and read-outs, measuring 7,392 samples and generating ∼1.5M protein datapoints in under a week, a significant advance in throughput compared to other highly multiplexed immunoassays. We uncovered 447 significant cytokine responses, including multiple putatively novel cytokine responses, that were conserved across donors and stimulation conditions. We also validated its use in phenotypic screening, and proposed applications for the nELISA in drug discovery.
Keyphrases
- high throughput
- single cell
- drug discovery
- flow cytometry
- single molecule
- protein protein
- amino acid
- circulating tumor
- binding protein
- clinical trial
- transcription factor
- oxidative stress
- randomized controlled trial
- high resolution
- heat shock
- cell free
- loop mediated isothermal amplification
- kidney transplantation
- sensitive detection
- heat stress
- study protocol