We present here a novel chemical method to continuously analyze intracellular AKT signaling activities at single-cell resolution, without genetic manipulations. A pair of cyclic peptide-based fluorescent probes were developed to recognize the phosphorylated Ser474 site and a distal epitope on AKT. A Förster resonance energy transfer signal is generated upon concurrent binding of the two probes onto the same AKT protein, which is contingent upon the Ser474 phosphorylation. Intracellular delivery of the probes enabled dynamic measurements of the AKT signaling activities. We further implemented this detection strategy on a microwell single-cell platform, and interrogated the AKT signaling dynamics in a human glioblastoma cell line. We resolved unique features of the single-cell signaling dynamics following different perturbations. Our study provided the first example of monitoring the temporal evolution of cellular signaling heterogeneities and unveiled biological information that was inaccessible to other methods.
We report on a cyclic peptide that inhibits matrix metalloproteinase-2 (MMP2) activation with a low-nM-level potency. This inhibitor specifically binds to the D 570 -A 583 epitope on proMMP2 and interferes with the protein−protein interaction (PPI) between proMMP2 and tissue inhibitor of metalloproteinases-2 (TIMP2), thereby preventing the TIMP2-assisted proMMP2 activation process. We developed this cyclic peptide inhibitor through an epitope-targeted library screening process and validated its binding to proMMP2. Using a human melanoma cell line, we demonstrated the cyclic peptide's ability to modulate cellular MMP2 activities and inhibit cell migration. These results provide the first successful example of targeting the PPI between proMMP2 and TIMP2, confirming the feasibility of an MMP2 inhibition strategy that has been sought after for 2 decades.
Digitonin allows the delivery of cyclic peptide-based imaging probes into suspension cells. This method enables time-resolved single-cell profiling of AKT signalling activities.
We
present a chemical approach to profile fatty acid uptake in
single cells. We use azide-modified analogues to probe the fatty acid
influx and surface-immobilized dendrimers with dibenzocyclooctyne
(DBCO) groups for detection. A competition between the fatty acid
probes and BHQ2-azide quencher molecules generates fluorescence signals
in a concentration-dependent manner. By integrating this method onto
a microfluidics-based multiplex protein analysis platform, we resolved
the relationships between fatty acid influx, oncogenic signaling activities,
and cell proliferation in single glioblastoma cells. We found that
p70S6K and 4EBP1 differentially correlated with fatty acid uptake.
We validated that cotargeting p70S6K and fatty acid metabolism synergistically
inhibited cell proliferation. Our work provided the first example
of studying fatty acid metabolism in the context of protein signaling
at single-cell resolution and generated new insights into cancer biology.
We present here a cyclic peptide ligand, cy(WQETR), that binds to the terbium ion (Tb3+) and enhances Tb3+ luminescence intensity through the antenna effect.
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