| Erratum: Hydrolysis of 2′ 3′-cGAMP by ENPP1 and design of nonhydrolyzable analogs L Li, Q Yin, P Kuss, Z Maliga, JL Millán, H Wu, TJ Mitchison Nature Chemical Biology 11 (9), 741-741, 2015 | 490* | 2015 |
| Hydrolysis of 2′ 3′-cGAMP by ENPP1 and design of nonhydrolyzable analogs L Li, Q Yin, P Kuss, Z Maliga, JL Millán, H Wu, TJ Mitchison Nature chemical biology 10 (12), 1043-1048, 2014 | 490 | 2014 |
| A defined glycosaminoglycan-binding substratum for human pluripotent stem cells JR Klim, L Li, PJ Wrighton, MS Piekarczyk, LL Kiessling Nature methods 7 (12), 989-994, 2010 | 341 | 2010 |
| STING polymer structure reveals mechanisms for activation, hyperactivation, and inhibition SL Ergun, D Fernandez, TM Weiss, L Li Cell 178 (2), 290-301. e10, 2019 | 336 | 2019 |
| SLC19A1 is an importer of the immunotransmitter cGAMP C Ritchie, AF Cordova, GT Hess, MC Bassik, L Li Molecular cell 75 (2), 372-381. e5, 2019 | 310 | 2019 |
| Extracellular cGAMP is a cancer-cell-produced immunotransmitter involved in radiation-induced anticancer immunity JA Carozza, V Böhnert, KC Nguyen, G Skariah, KE Shaw, JA Brown, ... Nature Cancer 1 (2), 184-196, 2020 | 259 | 2020 |
| Defined substrates for human embryonic stem cell growth identified from surface arrays R Derda, L Li, BP Orner, RL Lewis, JA Thomson, LL Kiessling ACS chemical biology 2 (5), 347-355, 2007 | 196 | 2007 |
| STING signaling promotes inflammation in experimental acute pancreatitis Q Zhao, Y Wei, SJ Pandol, L Li, A Habtezion Gastroenterology 154 (6), 1822-1835. e2, 2018 | 191 | 2018 |
| Anticancer flavonoids are mouse-selective STING agonists S Kim, L Li, Z Maliga, Q Yin, H Wu, TJ Mitchison ACS chemical biology 8 (7), 1396-1401, 2013 | 179 | 2013 |
| High-throughput discovery of synthetic surfaces that support proliferation of pluripotent cells R Derda, S Musah, BP Orner, JR Klim, L Li, LL Kiessling Journal of the American Chemical Society 132 (4), 1289-1295, 2010 | 167 | 2010 |
| LRRC8A: C/E heteromeric channels are ubiquitous transporters of cGAMP LJ Lahey, RE Mardjuki, X Wen, GT Hess, C Ritchie, JA Carozza, ... Molecular cell 80 (4), 578-591. e5, 2020 | 152 | 2020 |
| Activation of the STING-dependent type I interferon response reduces microglial reactivity and neuroinflammation V Mathur, R Burai, RT Vest, LN Bonanno, B Lehallier, ME Zardeneta, ... Neuron 96 (6), 1290-1302. e6, 2017 | 147 | 2017 |
| Human SLC46A2 is the dominant cGAMP importer in extracellular cGAMP-sensing macrophages and monocytes AF Cordova, C Ritchie, V Bohnert, L Li ACS central science 7 (6), 1073-1088, 2021 | 113 | 2021 |
| Structure-aided development of small-molecule inhibitors of ENPP1, the extracellular phosphodiesterase of the immunotransmitter cGAMP JA Carozza, JA Brown, V Böhnert, D Fernandez, Y AlSaif, RE Mardjuki, ... Cell chemical biology 27 (11), 1347-1358. e5, 2020 | 88 | 2020 |
| Biochemistry, cell biology, and pathophysiology of the innate immune cGAS–cGAMP–STING pathway C Ritchie, JA Carozza, L Li Annual Review of Biochemistry 91, 599-628, 2022 | 75 | 2022 |
| ENPP1’s regulation of extracellular cGAMP is a ubiquitous mechanism of attenuating STING signaling JA Carozza, AF Cordova, JA Brown, Y AlSaif, V Böhnert, X Cao, ... Proceedings of the National Academy of Sciences 119 (21), e2119189119, 2022 | 66 | 2022 |
| Spatial control of cell fate using synthetic surfaces to potentiate TGF-β signaling L Li, JR Klim, R Derda, AH Courtney, LL Kiessling Proceedings of the National Academy of Sciences 108 (29), 11745-11750, 2011 | 65 | 2011 |
| Structural insights into STING signaling SL Ergun, L Li Trends in Cell Biology 30 (5), 399-407, 2020 | 51 | 2020 |
| G1 dendrimers-mediated evolution of silver nanostructures from nanoparticles to solid spheres L Li, X Cao, F Yu, Z Yao, Y Xie Journal of colloid and interface science 261 (2), 366-371, 2003 | 37 | 2003 |
| Development of one-dimensional nanostructures through the crystallization of amorphous colloids X Cao, L Li, Y Xie Journal of colloid and interface science 273 (1), 175-180, 2004 | 35 | 2004 |
