Mark A. Rocco, Ph.D.
Affiliations: | 2011 | Cornell University, Ithaca, NY, United States |
Area:
Biomedical Engineering, Microbiology Biology, Molecular BiologyGoogle:
"Mark Rocco"Parents
Sign in to add mentorMatthew P. DeLisa | grad student | 2011 | Cornell | |
(Twin-arginine translocase mutations that suppress folding quality control and permit export of misfolded substrate proteins.) |
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Publications
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Taw MN, Boock JT, Sotomayor B, et al. (2022) Twin-arginine translocase component TatB performs folding quality control via a chaperone-like activity. Scientific Reports. 12: 14862 |
Taw MN, Li M, Kim D, et al. (2021) Engineering a Supersecreting Strain of by Directed Coevolution of the Multiprotein Tat Translocation Machinery. Acs Synthetic Biology |
Lee HC, Portnoff AD, Rocco MA, et al. (2014) An engineered genetic selection for ternary protein complexes inspired by a natural three-component hitchhiker mechanism. Scientific Reports. 4: 7570 |
Rocco MA, Waraho-Zhmayev D, DeLisa MP. (2012) Twin-arginine translocase mutations that suppress folding quality control and permit export of misfolded substrate proteins. Proceedings of the National Academy of Sciences of the United States of America. 109: 13392-7 |
Karlsson AJ, Lim HK, Xu H, et al. (2012) Engineering antibody fitness and function using membrane-anchored display of correctly folded proteins. Journal of Molecular Biology. 416: 94-107 |
Huber D, Rajagopalan N, Preissler S, et al. (2011) SecA interacts with ribosomes in order to facilitate posttranslational translocation in bacteria. Molecular Cell. 41: 343-53 |
Fisher AC, Rocco MA, DeLisa MP. (2011) Genetic selection of solubility-enhanced proteins using the twin-arginine translocation system. Methods in Molecular Biology (Clifton, N.J.). 705: 53-67 |
Rocco MA, Kim JY, Burns A, et al. (2009) Site-specific labeling of surface proteins on living cells using genetically encoded peptides that bind fluorescent nanoparticle probes. Bioconjugate Chemistry. 20: 1482-9 |