The role of soil microorganisms in plant mineral nutrition—current knowledge and future directions R Jacoby, M Peukert, A Succurro, A Koprivova, S Kopriva Frontiers in plant science 8, 1617, 2017 | 1439 | 2017 |
Sulfur assimilation in photosynthetic organisms: molecular functions and regulations of transporters and assimilatory enzymes H Takahashi, S Kopriva, M Giordano, K Saito, R Hell Annual review of plant biology 62 (1), 157-184, 2011 | 881 | 2011 |
The response of diatom central carbon metabolism to nitrogen starvation is different from that of green algae and higher plants NL Hockin, T Mock, F Mulholland, S Kopriva, G Malin Plant physiology 158 (1), 299-312, 2012 | 411 | 2012 |
Control of sulphate assimilation and glutathione synthesis: interaction with N and C metabolism S Kopriva, H Rennenberg Journal of experimental botany 55 (404), 1831-1842, 2004 | 411 | 2004 |
Regulation of Sulfate Assimilation in Arabidopsis and Beyond S Kopriva Annals of botany 97 (4), 479-495, 2006 | 371 | 2006 |
Nitrate–NRT1. 1B–SPX4 cascade integrates nitrogen and phosphorus signalling networks in plants B Hu, Z Jiang, W Wang, Y Qiu, Z Zhang, Y Liu, A Li, X Gao, L Liu, Y Qian, ... Nature plants 5 (4), 401-413, 2019 | 351 | 2019 |
Regulation of sulfate assimilation by nitrogen in Arabidopsis A Koprivova, M Suter, RO den Camp, C Brunold, S Kopriva Plant Physiology 122 (3), 737-746, 2000 | 351 | 2000 |
Regulation of sulfate uptake and assimilation—the same or not the same? JC Davidian, S Kopriva Molecular plant 3 (2), 314-325, 2010 | 336 | 2010 |
Flux control of sulphate assimilation in Arabidopsis thaliana: adenosine 5’-phosphosulphate reductase is more susceptible than ATP sulphurylase to negative control by thiols P Vauclare, S Kopriva, D Fell, M Suter, L Sticher, P Von Ballmoos, ... Plant J 31, 729-740, 2002 | 323* | 2002 |
Transporters in plant sulfur metabolism T Gigolashvili, S Kopriva Frontiers in Plant Science 5, 442, 2014 | 286 | 2014 |
Root-secreted coumarins and the microbiota interact to improve iron nutrition in Arabidopsis CJ Harbort, M Hashimoto, H Inoue, Y Niu, R Guan, AD Rombolà, ... Cell host & microbe 28 (6), 825-837. e6, 2020 | 275 | 2020 |
Targeted knockouts of Physcomitrella lacking plant‐specific immunogenic N‐glycans A Koprivova, C Stemmer, F Altmann, A Hoffmann, S Kopriva, G Gorr, ... Plant biotechnology journal 2 (6), 517-523, 2004 | 265 | 2004 |
Disruption of Adenosine-5′-Phosphosulfate Kinase in Arabidopsis Reduces Levels of Sulfated Secondary Metabolites SG Mugford, N Yoshimoto, M Reichelt, M Wirtz, L Hill, ST Mugford, ... The Plant Cell 21 (3), 910-927, 2009 | 237 | 2009 |
Interplay of SLIM1 and miR395 in the regulation of sulfate assimilation in Arabidopsis CG Kawashima, CA Matthewman, S Huang, BR Lee, N Yoshimoto, ... The Plant Journal 66 (5), 863-876, 2011 | 227 | 2011 |
Natural variation for sulfate content in Arabidopsis thaliana is highly controlled by APR2 O Loudet, V Saliba-Colombani, C Camilleri, F Calenge, V Gaudon, ... Nature genetics 39 (7), 896-900, 2007 | 205 | 2007 |
Hydrogen sulfide in plants: from dissipation of excess sulfur to signaling molecule A Calderwood, S Kopriva Nitric oxide 41, 72-78, 2014 | 202 | 2014 |
Pinpointing secondary metabolites that shape the composition and function of the plant microbiome RP Jacoby, A Koprivova, S Kopriva Journal of Experimental Botany 72 (1), 57-69, 2021 | 178 | 2021 |
Sulfur nutrition: impacts on plant development, metabolism, and stress responses S Kopriva, M Malagoli, H Takahashi Journal of Experimental Botany 70 (16), 4069-4073, 2019 | 172 | 2019 |
Root-specific camalexin biosynthesis controls the plant growth-promoting effects of multiple bacterial strains A Koprivova, S Schuck, RP Jacoby, I Klinkhammer, B Welter, L Leson, ... Proceedings of the National Academy of Sciences 116 (31), 15735-15744, 2019 | 172 | 2019 |
Arabidopsis root growth dependence on glutathione is linked to auxin transport A Koprivova, ST Mugford, S Kopriva Plant cell reports 29, 1157-1167, 2010 | 164 | 2010 |