Abstract
Fluorescent liposomal nanovesicles (liposomes) are commonly used for lipid research and/or signal enhancement. However, the problem of self-quenching with conventional fluorescent liposomes limits their applications because these liposomes must be lysed to detect the fluorescent signals. Here, we developed a nonquenched fluorescent (NQF)1 liposome by optimizing the proportion of sulforhodamine B (SRB) encapsulant and lissamine rhodamine B-dipalmitoyl phosphatidylethanol (LRB-DPPE) on a liposomal surface for signal amplification. Our study showed that 0.3% of LRB-DPPE with 200 μm of SRB provided the maximal fluorescent signal without the need to lyse the liposomes. We also observed that the NQF liposomes largely eliminated self-quenching effects and produced greatly enhanced signals than SRB-only liposomes by 5.3-fold. To show their application in proteomics research, we constructed NQF liposomes that contained phosphatidylinositol 3,5-bisphosphate (PI(3,5)P2) and profiled its protein interactome using a yeast proteome microarray. Our profiling led to the identification of 162 PI(3,5)P2-specific binding proteins (PI(3,5)P2-BPs). We not only recovered many proteins that possessed known PI(3,5)P2-binding domains, but we also found two unknown Pfam domains (Pfam-B_8509 and Pfam-B_10446) that were enriched in our dataset. The validation of many newly discovered PI(3,5)P2-BPs was performed using a bead-based affinity assay. Further bioinformatics analyses revealed that the functional roles of 22 PI(3,5)P2-BPs were similar to those associated with PI(3,5)P2, including vesicle-mediated transport, GTPase, cytoskeleton, and kinase. Among the 162 PI(3,5)P2-BPs, we found a novel motif, HRDIKP[ES]NJLL that showed statistical significance. A docking simulation showed that PI(3,5)P2 interacted primarily with lysine or arginine side chains of the newly identified PI(3,5)P2-binding kinases. Our study showed that this new tool would greatly benefit profiling lipid-protein interactions in high-throughput studies.
Highlights
IntroductionOur study showed that this new tool would greatly benefit profiling lipid–protein interactions in high-throughput studies
Higher concentrations of sulforhodamine B (SRB) caused the fluorescent signal to decrease as a result of self-quenching
Liposomes are one of the most common tools used in signal amplification and lipid research
Summary
Our study showed that this new tool would greatly benefit profiling lipid–protein interactions in high-throughput studies. High concentrations of fluorophores often lead to self-quenching, and as a result, the fluorescent signals cannot be detected without first lysing the liposomes [1,2,3,4]. This issue has limited their applications for real-time detection and high-density chip assays. To solve this problem, we developed a novel non-quenched fluorescent (NQF) liposome with the capability of signal amplification. We used sulforhodamine B (SRB) as an encapsulant and incorporated lissamine rhodamine B-dipalmitoyl phosphatidylethanol (LRB-DPPE) within the liposomal bilayer
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