| Foxa1 and Foxa2 are essential for sexual dimorphism in liver cancer Z Li, G Tuteja, J Schug, KH Kaestner Cell 148 (1), 72-83, 2012 | 414 | 2012 |
| Cell-specific determinants of peroxisome proliferator-activated receptor γ function in adipocytes and macrophages MI Lefterova, DJ Steger, D Zhuo, M Qatanani, SE Mullican, G Tuteja, ... Molecular and cellular biology 30 (9), 2078-2089, 2010 | 242 | 2010 |
| Foxa2 and H2A. Z mediate nucleosome depletion during embryonic stem cell differentiation Z Li, P Gadue, K Chen, Y Jiao, G Tuteja, J Schug, W Li, KH Kaestner Cell 151 (7), 1608-1616, 2012 | 229 | 2012 |
| SnapShot: forkhead transcription factors I G Tuteja, KH Kaestner Cell 130 (6), 1160. e1-1160. e2, 2007 | 218 | 2007 |
| TissueEnrich: Tissue-specific gene enrichment analysis A Jain, G Tuteja Bioinformatics 35 (11), 1966-1967, 2018 | 199 | 2018 |
| Foxa1 and Foxa2 regulate bile duct development in mice Z Li, P White, G Tuteja, N Rubins, S Sackett, KH Kaestner The Journal of clinical investigation 119 (6), 1537-1545, 2009 | 155 | 2009 |
| Extracting transcription factor targets from ChIP-Seq data G Tuteja, P White, J Schug, KH Kaestner Nucleic acids research 37 (17), e113-e113, 2009 | 132 | 2009 |
| Bisphenol A and bisphenol S disruptions of the mouse placenta and potential effects on the placenta–brain axis J Mao, A Jain, ND Denslow, MZ Nouri, S Chen, T Wang, N Zhu, J Koh, ... Proceedings of the National Academy of Sciences 117 (9), 4642-4652, 2020 | 115 | 2020 |
| CRTC2 (TORC2) contributes to the transcriptional response to fasting in the liver but is not required for the maintenance of glucose homeostasis J Le Lay, G Tuteja, P White, R Dhir, R Ahima, KH Kaestner Cell metabolism 10 (1), 55-62, 2009 | 107 | 2009 |
| The nucleosome map of the mammalian liver Z Li, J Schug, G Tuteja, P White, KH Kaestner Nature structural & molecular biology 18 (6), 742-746, 2011 | 99 | 2011 |
| Combined analysis of dissimilar promoter accessibility and gene expression profiles identifies tissue-specific genes and actively repressed networks RR Starks, A Biswas, A Jain, G Tuteja Epigenetics & chromatin 12, 1-16, 2019 | 75 | 2019 |
| Species-specific strategies underlying conserved functions of metabolic transcription factors RE Soccio, G Tuteja, LJ Everett, Z Li, MA Lazar, KH Kaestner Molecular endocrinology 25 (4), 694-706, 2011 | 64 | 2011 |
| Early onset preeclampsia in a model for human placental trophoblast MA Sheridan, Y Yang, A Jain, AS Lyons, P Yang, SR Brahmasani, A Dai, ... Proceedings of the National Academy of Sciences 116 (10), 4336-4345, 2019 | 60 | 2019 |
| Cis-regulatory modules in the mammalian liver: composition depends on strength of Foxa2 consensus site G Tuteja, ST Jensen, P White, KH Kaestner Nucleic acids research 36 (12), 4149-4157, 2008 | 46 | 2008 |
| Deciphering transcriptional regulation in human embryonic stem cells specified towards a trophoblast fate A Jain, T Ezashi, RM Roberts, G Tuteja Scientific reports 7 (1), 17257, 2017 | 38 | 2017 |
| Changes in the enhancer landscape during early placental development uncover a trophoblast invasion gene-enhancer network G Tuteja, T Chung, G Bejerano Placenta 37, 45-55, 2016 | 35 | 2016 |
| The enhancer landscape during early neocortical development reveals patterns of dense regulation and co-option AM Wenger, SL Clarke, JH Notwell, T Chung, G Tuteja, H Guturu, ... PLoS genetics 9 (8), e1003728, 2013 | 34 | 2013 |
| PESNPdb: a comprehensive database of SNPs studied in association with pre-eclampsia G Tuteja, E Cheng, H Papadakis, G Bejerano Placenta 33 (12), 1055-1057, 2012 | 28 | 2012 |
| PlacentaCellEnrich: A tool to characterize gene sets using placenta cell-specific gene enrichment analysis A Jain, G Tuteja Placenta 103, 164-171, 2021 | 25 | 2021 |
| Comparative analysis of the transcriptome and proteome during mouse placental development M Abdulghani, G Song, H Kaur, JW Walley, G Tuteja Journal of proteome research 18 (5), 2088-2099, 2019 | 24 | 2019 |
