Literature for peptidase C01.060: cathepsin B

(References are filtered for relevance to Localization. To remove the filter click here. See explanation.)

2019
1. Ni,Y., Hai,Z., Zhang,T., Wang,Y., Yang,Y., Zhang,S. and Liang,G.
   Cathepsin B turning bioluminescence "on" for tumor imaging
   Anal Chem91, 14834-14837. PubMed  Europe PubMed DOI  L
2. Poreba,M., Groborz,K., Vizovisek,M., Maruggi,M., Turk,D., Turk,B., Powis,G., Drag,M. and Salvesen,G.S.
   Fluorescent probes towards selective cathepsin B detection and visualization in cancer cells and patient samples
   Chem Sci10, 8461-8477. PubMed  Europe PubMed DOI  L
3. Wang,Q., Yu,L., Wong,R.C.H. and Lo,P.C.
   Construction of cathepsin B-responsive fluorescent probe and photosensitizer using a ferrocenyl boron dipyrromethene dark quencher
   Eur J Med Chem179, 828-836. PubMed  Europe PubMed DOI  A  L
4. Wang,S., Vigliarolo,B.G., Chowdhury,M.A., Nyarko,J.N.K., Mousseau,D.D. and Phenix,C.P.
   Design and synthesis of fluorogenic substrate-based probes for detecting cathepsin B activity
   Bioorg Chem92, 103194-103194. PubMed  Europe PubMed DOI  A  L
2018
5. Ryan,L.S. and Lippert,A.R.
   Ultrasensitive chemiluminescent detection of cathepsin B: insights into the new frontier of chemiluminescent imaging
   Angew Chem Int Ed Engl57, 622-624. PubMed  Europe PubMed DOI  L
2017
6. Chen,X., Lee,D., Yu,S., Kim,G., Lee,S., Cho,Y., Jeong,H., Nam,K.T. and Yoon,J.
   In vivo near-infrared imaging and phototherapy of tumors using a cathepsin B-activated fluorescent probe
   Biomaterials122, 130-140. PubMed  Europe PubMed DOI  L
7. Kramer,L., Renko,M., Zavrsnik,J., Turk,D., Seeger,M.A., Vasiljeva,O., Grutter,M.G., Turk,V. and Turk,B.
   Non-invasive in vivo imaging of tumour-associated cathepsin B by a highly selective inhibitory DARPin
   Theranostics7, 2806-2821. PubMed  Europe PubMed DOI  L
8. Roth-Konforti,M.E., Bauer,C.R. and Shabat,D.
   Unprecedented sensitivity in a probe for monitoring cathepsin B: chemiluminescence microscopy cell-imaging of a natively expressed enzyme
   Angew Chem Int Ed Engl56, 15633-15638. PubMed  Europe PubMed DOI  A  L
2016
9. Hingorani,D.V., Montano,L.A., Randtke,E.A., Lee,Y.S., Cardenas-Rodriguez,J. and Pagel,M.D.
   A single diamagnetic catalyCEST MRI contrast agent that detects cathepsin B enzyme activity by using a ratio of two CEST signals
   Contrast Media Mol Imaging11, 130-138. PubMed  Europe PubMed DOI  L
10. Wang,Y., Li,J., Feng,L., Yu,J., Zhang,Y., Ye,D. and Chen,H.Y.
    Lysosome-targeting fluorogenic probe for cathepsin B imaging in living cells
    Anal Chem88, 12403-12410. PubMed  Europe PubMed DOI  L
11. Withana,N.P., Garland,M., Verdoes,M., Ofori,L.O., Segal,E. and Bogyo,M.
    Labeling of active proteases in fresh-frozen tissues by topical application of quenched activity-based probes
    Nat Protoc11, 184-191. PubMed  Europe PubMed DOI  L
12. Withana,N.P., Ma,X., McGuire,H.M., Verdoes,M., van der Linden,W.A., Ofori,L.O., Zhang,R., Li,H., Sanman,L.E., Wei,K., Yao,S., Wu,P., Li,F., Huang,H., Xu,Z., Wolters,P.J., Rosen,G.D., Collard,H.R., Zhu,Z., Cheng,Z. and Bogyo,M.
    Non-invasive imaging of idiopathic pulmonary fibrosis using cathepsin protease probes
    Sci Rep6, 19755-19755. PubMed  Europe PubMed DOI  L
2015
13. Ofori,L.O., Withana,N.P., Prestwood,T.R., Verdoes,M., Brady,J.J., Winslow,M.M., Sorger,J. and Bogyo,M.
    Design of protease activated optical contrast agents that exploit a latent lysosomotropic effect for use in fluorescence-guided surgery
    ACS Chem Biol10, 1977-1988. PubMed  Europe PubMed DOI  L
14. Ramalho,S.D., Sharma,R., White,J.K., Aggarwal,N., Chalasani,A., Sameni,M., Moin,K., Vieira,P.C., Turro,C., Kodanko,J.J. and Sloane,B.F.
    Imaging sites of inhibition of proteolysis in pathomimetic human breast cancer cultures by light-activated ruthenium compound
    PLoS ONE10, e0142527-e0142527. PubMed  Europe PubMed DOI  L
15. Yhee,J.Y., Kim,Y.J., Ryu,J.H., Yoon,H.Y., Chang,H., Park,J.H., Lee,H., Jang,H.S., Jeong,U., Kim,K. and Kang,S.W.
    Cathepsin B imaging to predict quality of engineered cartilage
    Macromol Biosci15, 1224-1232. PubMed  Europe PubMed DOI  L
2014
16. Kisin-Finfer,E., Ferber,S., Blau,R., Satchi-Fainaro,R. and Shabat,D.
    Synthesis and evaluation of new NIR-fluorescent probes for cathepsin B: ICT versus FRET as a turn-ON mode-of-action
    Bioorg Med Chem Lett24, 2453-2458. PubMed  Europe PubMed DOI  A  L
17. Ryu,J.H., Na,J.H., Ko,H.K., You,D.G., Park,S., Jun,E., Yeom,H.J., Seo,D.H., Park,J.H., Jeong,S.Y., Kim,I.S., Kim,B.S., Kwon,I.C., Choi,K. and Kim,K.
    Non-invasive optical imaging of cathepsin B with activatable fluorogenic nanoprobes in various metastatic models
    Biomaterials35, 2302-2311. PubMed  Europe PubMed DOI  L
2011
18. Baudy,A.R., Sali,A., Jordan,S., Kesari,A., Johnston,H.K., Hoffman,E.P. and Nagaraju,K.
    Non-invasive optical imaging of muscle pathology in mdx mice using cathepsin caged near-infrared imaging
    Mol Imaging Biol13, 462-470. PubMed  Europe PubMed DOI  L
19. Ryu,J.H., Kim,S.A., Koo,H., Yhee,J.Y., Lee,A., Na,J.H., Youn,I., Choi,K., Kwon,I.C., Kim,B.S. and Kim,K.
    Cathepsin B-sensitive nanoprobe for in vivo tumor diagnosis
    J Mater Chem21, 17631-17634. DOI  L
2009
20. Cavallo-Medved,D., Rudy,D., Blum,G., Bogyo,M., Caglic,D. and Sloane,B.F.
    Live-cell imaging demonstrates extracellular matrix degradation in association with active cathepsin B in caveolae of endothelial cells during tube formation
    Exp Cell Res315, 1234-1246. PubMed  Europe PubMed DOI  L
21. Kim,D.E., Kim,J.Y., Schellingerhout,D., Shon,S.M., Jeong,S.W., Kim,E.J. and Kim,W.K.
    Molecular imaging of cathepsin B proteolytic enzyme activity reflects the inflammatory component of atherosclerotic pathology and can quantitatively demonstrate the antiatherosclerotic therapeutic effects of atorvastatin and glucosamine
    Mol Imaging8, 291-301. PubMed  Europe PubMed DOI  L
22. Pratt,M.R., Sekedat,M.D., Chiang,K.P. and Muir,T.W.
    Direct measurement of cathepsin B activity in the cytosol of apoptotic cells by an activity-based probe
    Chem Biol16, 1001-1012. PubMed  Europe PubMed DOI  L