All peptides were synthesized by CPC Scientific (Sunnyvale, CA) and reconstituted in dimethylformamide (DMF) unless otherwise specified. Sequences are provided in Supplementary Table S1.
Abstract
Recent years have seen the emergence of conditionally activated diagnostics and therapeutics that leverage protease-cleavable peptide linkers to enhance their specificity for cancer. However, due to a lack of methods to measure and localize protease activity directly within the tissue microenvironment, the design of protease-activated agents has been necessarily empirical, yielding suboptimal results when translated to patients. To address the need for spatially resolved protease activity profiling in cancer, we developed a new class of in situ probes that can be applied to fresh-frozen tissue sections in a manner analogous to immunofluorescence staining. These activatable zymography probes (AZP) detected dysregulated protease activity in human prostate cancer biopsy samples, enabling disease classification. AZPs were leveraged within a generalizable framework to design conditional cancer diagnostics and therapeutics and showcased in the Hi-Myc mouse model of prostate cancer, which models features of early pathogenesis. Multiplexed screening against barcoded substrates yielded a peptide, S16, that was robustly and specifically cleaved by tumor-associated metalloproteinases in the Hi-Myc model. In situ labeling with an AZP incorporating S16 revealed a potential role of metalloproteinase dysregulation in proliferative, premalignant Hi-Myc prostatic glands. Systemic administration of an in vivo imaging probe incorporating S16 perfectly classified diseased and healthy prostates, supporting the relevance of ex vivo activity assays to in vivo translation. We envision AZPs will enable new insights into the biology of protease dysregulation in cancer and accelerate the development of conditional diagnostics and therapeutics for multiple cancer types.
Table S1.
| Name | Sequence | Readout (sample type) |
|---|---|---|
| S1-Q | (5FAM)-GGPQGIWGQ-K(CPQ2)-(PEG2)-C-NH2 | Fluorescence (in vitro / ex vivo) |
| S2-Q | (5FAM)-GGLVPRGSG-K(CPQ2)-(PEG2)-C-NH2 | Fluorescence (in vitro / ex vivo) |
| S3-Q | (5FAM)-GGPVGLIG-K(CPQ2)-(PEG2)-C-NH2 | Fluorescence (in vitro / ex vivo) |
| S4-Q | (5FAM)-GGPLGVRGK-K(CPQ2)-(PEG2)-C-NH2 | Fluorescence (in vitro / ex vivo) |
| S5-Q | (5FAM)-GRQRRALEKG-K(CPQ2)-(PEG2)-GC-NH2 | Fluorescence (in vitro / ex vivo) |
| S6-Q | (5FAM)-GGGSGRSANAKG-K(CPQ2)-(PEG2)-GC-NH2 | Fluorescence (in vitro / ex vivo) |
| S7-Q | (5FAM)-GKPISLISSG-K(CPQ2)-(PEG2)-GC-NH2 | Fluorescence (in vitro / ex vivo) |
| S8-Q | (5FAM)-GILSRIVGGG-K(CPQ2)-(PEG2)-GC-NH2 | Fluorescence (in vitro / ex vivo) |
| S9-Q | (5FAM)-GRPKPVE(Nval)WRKG-K(CPQ2)-(PEG2)-GC-NH2 | Fluorescence (in vitro / ex vivo) |
| S10-Q | (5FAM)-GIQQRSLGGG-K(CPQ2)-(PEG2)-GC-NH2 | Fluorescence (in vitro / ex vivo) |
| S11-Q | (5FAM)-GGVPRGG-K(CPQ2)-(PEG2)-GC-NH2 | Fluorescence (in vitro / ex vivo) |
| S12-Q | (5FAM)-GSGSKIIGGG-K(CPQ2)-(PEG2)-GC-NH2 | Fluorescence (in vitro / ex vivo) |
| S13-Q | (5FAM)-GAANLTRG-K(CPQ2)-(PEG2)-GC-NH2 | Fluorescence (in vitro / ex vivo) |
| S14-Q | (5FAM)-GLAQAPhe(homo)RSG-K(CPQ2)-(PEG2)-GC-NH2 | Fluorescence (in vitro / ex vivo) |
| S15-Q | (5FAM)-GSPLAQAVRSSG-K(CPQ2)-(PEG2)-GC-NH2 | Fluorescence (in vitro / ex vivo) |
| S16-Q | (5FAM)-GPVPLSLVMG-K(CPQ2)-(PEG2)-GC-NH2 | Fluorescence (in vitro / ex vivo) |
| S17-Q | (5FAM)-GSQPRIVGGG-K(CPQ2)-(PEG2)-GC-NH2 | Fluorescence (in vitro / ex vivo) |
| S19-Q | (5FAM)-GGLGPKGQTG-K(CPQ2)-(PEG2)-C-NH2 | Fluorescence (in vitro / ex vivo) |
| S20-Q | (5FAM)-GGQTCKCSCK-K(CPQ2)-(PEG2)-C-NH2 | Fluorescence (in vitro / ex vivo) |
| S1-M | e(+2G)(+6V)ndneeG(+10F)(+1F)s(+1A)r-ANP-GGPQGIWGQGC | LC-MS/MS (in vitro / ex vivo) |
| S2-M | eG(+6V)ndneeGF(+1F)s(+1A)r-ANP-GGLVPRGSGGC | LC-MS/MS (in vitro / ex vivo) |
| S3-M | e(+3G)(+1V)ndneeGFFs(+4A)r-ANP-GGPVGLIGGC | LC-MS/MS (in vitro / ex vivo) |
| S4-M | e(+2G)Vndnee(+2G)FFs(+4A)r-ANP-GGPLGVRGKGC | LC-MS/MS (in vitro / ex vivo) |
| S5-M | e(+3G)(+1V)ndneeG(+10F)FsAr-ANP-GRQRRALEKGC | LC-MS/MS (in vitro / ex vivo) |
| S6-M | e(+2G)Vndnee(+2G)F(+10F)sAr-ANP-GGGSGRSANAKGC | LC-MS/MS (in vitro / ex vivo) |
| S7-M | e(+2G)(+6V)ndneeGFFsAr-ANP-GKPISLISSGC | LC-MS/MS (in vitro / ex vivo) |
| S8-M | eGVndneeGF(+10F)s(+4A)r-ANP-GILSRIVGGGC | LC-MS/MS (in vitro / ex vivo) |
| S9-M | eG(+6V)ndneeG(+10F)Fs(+4A)r-ANP-GRPKPVE(Nval)WRKGC | LC-MS/MS (in vitro / ex vivo) |
| S10-M | e(+3G)(+1V)ndnee(+2G)(+10F)Fs(+4A)r-ANP-GIQQRSLGGGC | LC-MS/MS (in vitro / ex vivo) |
| S11-M | e(+2G)Vndnee(+3G)(+10F)(+1F)s(+4A)r-ANP-GGVPRGGC | LC-MS/MS (in vitro / ex vivo) |
| S12-M | eGVndneeG(+10F)(+10F)sAr-ANP-GSGSKIIGGGC | LC-MS/MS (in vitro / ex vivo) |
| S13-M | e(+2G)(+6V)ndnee(+3G)(+10F)(+1F)s(+4A)r-ANP-GAANLTRGC | LC-MS/MS (in vitro / ex vivo) |
| S14-M | eG(+6V)ndneeG(+10F)(+10F)sAr-ANP-GLAQAPhe(homo)RSGC | LC-MS/MS (in vitro / ex vivo) |
| S15-M | e(+3G)(+1V)ndnee(+2G)(+10F)(+10F)sAr-ANPGSPLAQAVRSSGC | LC-MS/MS (in vitro / ex vivo) |
| S16-M | e(+2G)VndneeG(+10F)(+10F)s(+4A)r-ANP-GPVPLSLVMGC | LC-MS/MS (in vitro / ex vivo) |
| S17-M | eGVndnee(+2G)(+10F)(+10F)s(+4A)r-ANP-GSQPRIVGGGC | LC-MS/MS (in vitro / ex vivo) |
| S19-M | e(+2G)(+6V)ndnee(+3G)(+1F)(+1F)s(+1A)r-ANPGGLGPKGQTGGC | LC-MS/MS (in vitro / ex vivo) |
| S20-M | eG(+6V)ndnee(+3G)(+1F)Fs(+4A)r-ANP-GGQTCKCSCKGC | LC-MS/MS (in vitro / ex vivo) |
| S1-Z | U-eeeeeeee-X-GGPQGIWGQG-rrrrrrrrr-X-K(Cy3)-NH2 | Fluorescence (in situ) |
| S2-Z | U-eeeeeeee-X-GGLVPRGSGG-rrrrrrrrr-X-K(Cy5)-NH2 | Fluorescence (in situ) |
| S3-Z | U-eeeeeeee-X-GGPVGLIGG-rrrrrrrrr-X-K(5FAM)-NH2 | Fluorescence (in situ) |
| S4-Z | U-eeeeeeee-X-GPLGVRGKG-rrrrrrrrr-X-K(5FAM)-NH2 | Fluorescence (in situ) |
| S5-Z | U-eeeeeeee-X-GRQRRALEKG-rrrrrrrrr-X-K(Cy3)-NH2 | Fluorescence (in situ) |
| S6-Z | U-eeeeeeee-X-GSGRSANAG-rrrrrrrrr-X-K(Cy5)-NH2 | Fluorescence (in situ) |
| S7-Z | U-eeeeeeee-X-GKPISLISSG-rrrrrrrrr-X-K(5FAM)-NH2 | Fluorescence (in situ) |
| S8-Z | U-eeeeeeee-X-GILSRIVGGG-rrrrrrrrr-X-K(5FAM)-NH2 | Fluorescence (in situ) |
| S9-Z | U-eeeeeeee-X-GRPKPVE(Nval)WRKG-rrrrrrrrr-X-K(5FAM)-NH2 | Fluorescence (in situ) |
| S10-Z | U-eeeeeeee-X-GIQQRSLGGG-rrrrrrrrr-X-K(5FAM)-NH2 | Fluorescence (in situ) |
| S11-Z | U-eeeeeeee-X-GGGVPRGGG-rrrrrrrrr-X-K(5FAM)-NH2 | Fluorescence (in situ) |
| S12-Z | U-eeeeeeee-X-GSGSKIIGGG-rrrrrrrrr-X-K(Cy3)-NH2 | Fluorescence (in situ) |
| S13-Z | U-eeeeeeee-X-GGAANLTRGG-rrrrrrrrr-X-K(Cy3)-NH2 | Fluorescence (in situ) |
| S14-Z | U-eeeeeeee-X-GLAQAPhe(homo)RSG-rrrrrrrrr-X-K(Cy3)-NH2 | Fluorescence (in situ) |
| S15-Z | U-eeeeeeee-X-GSPLAQAVRSSG-rrrrrrrrr-X-K(Cy3)-NH2 | Fluorescence (in situ) |
| S16-Z | U-eeeeeeee-X-GPVPLSLVMG-rrrrrrrrr-X-K(5FAM)-NH2 | Fluorescence (in situ) |
| S17-Z | U-eeeeeeee-X-GSQPRIVGGG-rrrrrrrrr-X-K(Cy5)-NH2 | Fluorescence (in situ) |
| S18-Z | U-eeeeeeee-X-GGGHARLVHVG-rrrrrrrrr-X-K(Cy3)-NH2 | Fluorescence (in situ) |
| S19-Z | U-eeeeeeee-X-GGLGPKGQTGG-rrrrrrrrr-X-K(Cy3)-NH2 | Fluorescence (in situ) |
| S20-Z | U-eeeeeeee-X-GGQTCKCSCKG-rrrrrrrrr-X-K(Cy5)-NH2 | Fluorescence (in situ) |
| dS6-Z | U-eeeeeeee-X-GsGrsanaG-rrrrrrrrr-X-K(Cy5)-NH2 | Fluorescence (in situ) |
| S6-QZ | (QSY21)-eeeeeeeee-c-o-GSGRSANAG-rrrrrrrrr-K(Cy5)-NH2 | Fluorescence (in situ) |
| dS6-QZ | (QSY21)-eeeeeeeee-c-o-GsGrsanaG-rrrrrrrrr-K(Cy5)-NH2 | Fluorescence (in situ) |
| dS16-Z | U-eeeeeeee-X-GpvplslvmG-rrrrrrrrr-X-K(5FAM)-NH2 | Fluorescence (in situ) |
| S16-QZ | (QSY21)-eeeeeeeee-c-o-GPVPLSLVMG-rrrrrrrrr-K(Cy5)-NH2 | Fluorescence (in situ / in vivo) |
| dS16-QZ | (QSY21)-eeeeeeeee-c-o-GpvplslvmG-rrrrrrrrr-K(Cy5)-NH2 | Fluorescence (in situ / in vivo) |
| S16 | GPVPLSLVMG | Cleavage motif |
| polyR | rrrrrrrrr-X-K(Cy7)-NH2 | Fluorescence (in situ) |
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Press Releases, Industry News, Articles, and Technical Content
Solid-phase peptide synthesis (SPPS) has many advantages over liquid-phase peptide synthesis (LPPS) for preparing and manufacturing synthetic peptides. Except the synthesis of short peptide sequences (i.e., less than five amino acid residues), SPPS is faster, more efficient, and more economical than liquid-phase peptide synthesis (LPPS). Some of the advantages of SPPS include: (1) Excess reagents and products can be easily washed away, (2) using excess reagents to increase reaction rates and drive reactions to completion, (3) intermediates do not require isolation or characterization, (4) access to a broader range of solvents with low volatility and high polarity, (5) tethered peptide provides a ‘pseudo-dilute’ microenvironment, which can inhibit intermolecular reactions, making some modifications easier to accomplish, and (6) compatibility with automated synthesis technology.
Lo, J.H., Hao, L., Muzumdar, M.D., Raghavan, S., Kwon, E.J., Pulver, E.M., Hsu, F., Aguirre, A.J., Wolpin, B.M., Fuchs, C.S. and Hahn, W.C. Molecular Cancer Therapeutics 17, no. 11 (2018): 2377-2388.
pTP-TAMRA-iRGD (CH3(CH)15-[GWTLNSAGYLLGKINLKALAALAKKIL-GGK(TAMRA)GGCRGDKGPDC, Cys-Cys bridge]) used in all figures except Fig. S1 was synthesized by CPC Scientific.
Ng, Ee Xien, Myat Noe Hsu, Guoyun Sun, and Chia-Hung Chen. Methods in Enzymology 628 (2019): 59-94.
The peptide sequences of the four FRET-based substrates ([..] CPC Scientific) are as follows: UV: AlexaFluor405-Leu-Ala-Gln-Ala-HompheArg-Ser-Lys (QSY35)-NH2; Blue: Dabcyl-Gly-Pro-Leu-Gly-Met-Arg-Gly-Lys (5-FAM)-NH2; Green: QSY7-Ala-Pro-Phe-Glu..
West, J.A., Tsakmaki, A., Huang, J.H., Ghosh, S.S., Parkes, D.G., Wismann, P., Rigbolt, K.T., Pedersen, P.J., Pavlidis, P., Maggs, D. and Lopez-Talavera, J.C. bioRxiv (2019) 822122.
- Fractyl Laboratories Inc, Lexington, MA, 02421, USA
- Diabetes Research Group, School of Life Course Sciences, Faculty of Life Science and Medicine, King’s College London, London, WC2R 2LS, England, UK
[..] infusion of vehicle 2 via osmotic minipump; (2) glucagon-like peptide-1 receptor (GLP-1R) agonist (0.2 mg/kg liraglutide, SC, QD, Victoza (Novo Nordisk, Bagsværd, Denmark) and continuous infusion of vehicle 2 via osmotic minipump; (3) vehicle 1 (SC, QD) and continuous infusion of a glucose-dependent insulinotropic polypeptide receptor (GIPR) antagonist (∼4.5 mg/kg/day / 56.8 nmol/kg/h GIP[3-30]NH2, CPC Scientific Inc, Sunnyvale, CA, USA) via osmotic minipump;
Artur Javmen, Vladimir Y. Toshchakov, et al. Journal of Leukocyte Biology (2019).
All CPDPs included the N‐terminal Antennapedia homeodomain sequence RQIKIWFQNRRMKWKK.38 The Cy3‐labeled peptides were produced by CPC Scientific (Sunnyvale, CA, USA). The Cy3 label was placed at the peptide N‐terminus..
Gilles, Maud-Emmanuelle, Slack, Frank J, et al. Oncotarget, 2019, Vol. 10, (No. 51), pp: 5349-5358
"Tandem peptide (pTP-iRGD: CH3(CH)15-GWTLNSAGYLLGKINLKALAALAKKIL-GGK(TAMRA)GGCRGDKGPDC, Cys-Cys bridge) was synthesized by CPC Scientific."
Garner, Thomas P., Dulguun Amgalan, Denis E. Reyna, Sheng Li, Richard N. Kitsis, and Evripidis Gavathiotis. Nature Chemical Biology 15, no. 4 (2019): 322.
"Hydrocarbon-stapled peptides corresponding to the BH3 domain of BIM, BIM SAHBA2: N-acetylated- and FITC-Ahx-EIWIAQELRS5IGDS5FNAYYA-CONH2, where S5 represents the non-natural amino acid inserted for olefin metathesis, were synthesized, purified at >95% purity by CPC Scientific Inc. and characterized as previously described."
Gibbs, Ebrima, Judith M. Silverman, Beibei Zhao, Xubiao Peng, Jing Wang, Cheryl L. Wellington, Ian R. Mackenzie, Steven S. Plotkin, Johanne M. Kaplan, and Neil R. Cashman. Scientific Reports 9, no. 1 (2019): 1-14.
The conformational epitope was synthesized as a cyclic peptide with additional N-terminal residues CG and a C-terminal G to recapitulate the predicted structure of HHQK on AβO. Peptide synthesis was performed by CPC Scientific Inc. (Sunnyvale CA, USA) [..] Cyclization was performed via a head-to-tail (C-G) amide bond and c[CGHHQKG] was then conjugated to either keyhole limpet hemocyanin (KLH) or bovine serum albumin (BSA) via maleimide-based coupling.
SUNNYVALE, US. and Hangzhou, China, June 24th, 2019 /CPCNewswire/ — CPC Scientific Inc. and its affiliate Chinese Peptide Company, a public Hangzhou-based CDMO (Stock Symbol: 002390) is pleased to announce today that their GMP manufacturing facility, has successfully passed its inspection by the competent authority of Germany as an“active substance manufacturer that has been inspected […]