Abstract is: Nikolaus Rajewsky (born 1968) is a German system biologist at the Max-Delbrück-Center for Molecular Medicine (MDC) and at the Charité in Berlin. He founded and directs the “Berlin Institute for Medical Systems Biology”. (BIMSB, Max-Delbrück-Center for Molecular Medicine). He leads the Rajewsky lab, where he studies how RNA regulates gene expression. He also co-chairs LifeTime, a pan-European research initiative of more than 90 academic institutions and 70 companies, which aims to revolutionize healthcare by mapping, understanding, and targeting cells during disease progression. LifeTime integrates several technologies: single-cell multiomics, machine learning, and personalized disease models such as organoids. Rajewsky has received numerous awards and honors, including the most prestigious German award, the Gottfried Wilhelm Leibniz Prize, endowed with 2.5 million euros by the German Research Foundation (DFG).
| human | Q5 |
| P7902 | Deutsche Biographie (GND) ID | 118058924 |
| P9985 | EMBO member ID | nikolaus-rajewsky |
| P8168 | FactGrid item ID | Q885891 |
| P227 | GND ID | 118058924 |
| P2671 | Google Knowledge Graph ID | /g/120rs3df |
| P1960 | Google Scholar author ID | pNfbA7EAAAAJ |
| P269 | IdRef ID | 203713095 |
| P213 | ISNI | 0000000055333719 |
| P244 | Library of Congress authority ID | n2019184356 |
| P549 | Mathematics Genealogy Project ID | 128267 |
| P4955 | MR Author ID | 366609 |
| P8189 | National Library of Israel J9U ID | 987007419582005171 |
| P691 | NL CR AUT ID | jn19990006813 |
| P496 | ORCID iD | 0000-0002-4785-4332 |
| P214 | VIAF ID | 13094499 |
| P10832 | WorldCat Entities ID | E39PBJghj7xJkx98CBfqDwc9Dq |
| P2002 | X username | n_rajewsky |
| P1556 | zbMATH author ID | rajewsky.nikolaus |
| P512 | academic degree | doctorate | Q849697 |
| P166 | award received | Gottfried Wilhelm Leibniz Prize | Q703205 |
| Berlin Science Award | Q821879 | ||
| EMBO Membership | Q26268243 | ||
| P27 | country of citizenship | Germany | Q183 |
| P184 | doctoral advisor | Johannes Zittartz | Q102124338 |
| P69 | educated at | University of Cologne | Q54096 |
| P108 | employer | New York University | Q49210 |
| Max Delbrück Center for Molecular Medicine | Q1912019 | ||
| Charité | Q162684 | ||
| Medical Library of the Charité – Universitätsmedizin | Q28738830 | ||
| P734 | family name | Rajewsky | Q124286527 |
| Rajewsky | Q124286527 | ||
| Rajewsky | Q124286527 | ||
| P22 | father | Klaus Rajewsky | Q126992 |
| P735 | given name | Nikolaus | Q15728996 |
| Nikolaus | Q15728996 | ||
| P1412 | languages spoken, written or signed | German | Q188 |
| P6104 | maintained by WikiProject | WikiProject Mathematics | Q8487137 |
| P463 | member of | German Academy of Sciences Leopoldina | Q543804 |
| P1559 | name in native language | Nikolaus Rajewsky | |
| P106 | occupation | biologist | Q864503 |
| university teacher | Q1622272 | ||
| P5008 | on focus list of Wikimedia project | WikiProject COVID-19 | Q87748614 |
| P21 | sex or gender | male | Q6581097 |
| P8687 | social media followers | 2106 |
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| Q43061380 | A map of human circular RNAs in clinically relevant tissues. |
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| Q95601375 | Bulk and single-cell gene expression profiling of SARS-CoV-2 infected human cell lines identifies molecular targets for therapeutic intervention |
| Q36376696 | Cell fixation and preservation for droplet-based single-cell transcriptomics |
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| Q34479693 | Cell-type-specific signatures of microRNAs on target mRNA expression |
| Q55269381 | Characterization of Transcription Termination-Associated RNAs: New Insights into their Biogenesis, Tailing, and Expression in Primary Tumors. |
| Q58061949 | Charting a tissue from single-cell transcriptomes |
| Q29871124 | Circ-ZNF609 Is a Circular RNA that Can Be Translated and Functions in Myogenesis |
| Q38881309 | Circular RNAs in the Mammalian Brain Are Highly Abundant, Conserved, and Dynamically Expressed. |
| Q27860510 | Combinatorial microRNA target predictions |
| Q38285571 | Competition between target sites of regulators shapes post-transcriptional gene regulation. |
| Q24794169 | Computational detection of genomic cis-regulatory modules applied to body patterning in the early Drosophila embryo |
| Q46941595 | Conservation of mRNA and protein expression during development of C. elegans. |
| Q24800955 | Conservation of regulatory elements between two species of Drosophila |
| Q37162242 | Conserved functional antagonism of CELF and MBNL proteins controls stem cell-specific alternative splicing in planarians |
| Q91172384 | Context-specific regulation of cell survival by a miRNA-controlled BIM rheostat |
| Q42410972 | Correlating gene expression variation with cis-regulatory polymorphism in Saccharomyces cerevisiae |
| Q24598325 | De novo assembly and validation of planaria transcriptome by massive parallel sequencing and shotgun proteomics |
| Q38351806 | Decay rates of human mRNAs: correlation with functional characteristics and sequence attributes |
| Q33569209 | Deciphering the porcine intestinal microRNA transcriptome |
| Q112312966 | Defective metabolic programming impairs early neuronal morphogenesis in neural cultures and an organoid model of Leigh syndrome |
| Q28275278 | Discovering microRNAs from deep sequencing data using miRDeep |
| Q35443883 | DoRiNA 2.0--upgrading the doRiNA database of RNA interactions in post-transcriptional regulation |
| Q41901163 | Epigenetic dynamics of monocyte-to-macrophage differentiation |
| Q39183286 | Epigenomic Profiling of Human CD4(+) T Cells Supports a Linear Differentiation Model and Highlights Molecular Regulators of Memory Development |
| Q121294994 | Establishment of gastrointestinal assembloids to study the interplay between epithelial crypts and their mesenchymal niche |
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| Q36056550 | Extensive identification and analysis of conserved small ORFs in animals |
| Q92432913 | FLAM-seq: full-length mRNA sequencing reveals principles of poly(A) tail length control |
| Q91362841 | Gene expression cartography |
| Q36049563 | Gene expression of pluripotency determinants is conserved between mammalian and planarian stem cells. |
| Q34332382 | Global characterization of the oocyte-to-embryo transition in Caenorhabditis elegans uncovers a novel mRNA clearance mechanism |
| Q37245059 | High-resolution profiling and discovery of planarian small RNAs. |
| Q92095446 | Human muscle-derived CLEC14A-positive cells regenerate muscle independent of PAX7 |
| Q35814981 | Identification and Characterization of Circular RNAs As a New Class of Putative Biomarkers in Human Blood |
| Q37360742 | Identification of LIN28B-bound mRNAs reveals features of target recognition and regulation. |
| Q90133800 | Identification of proteins and miRNAs that specifically bind an mRNA in vivo |
| Q34323853 | Identification of small ORFs in vertebrates using ribosome footprinting and evolutionary conservation. |
| Q35659976 | In vivo and transcriptome-wide identification of RNA binding protein target sites |
| Q35819673 | Insm1 cooperates with Neurod1 and Foxa2 to maintain mature pancreatic β-cell function |
| Q28301622 | Integrative analysis of the Caenorhabditis elegans genome by the modENCODE project |
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| Q38629841 | Loss of a mammalian circular RNA locus causes miRNA deregulation and affects brain function |
| Q57198168 | MiR-150 Controls B Cell Differentiation by Targeting the Transcription Factor c-Myb |
| Q24811302 | MicroRNA profiling of the murine hematopoietic system |
| Q37855201 | MicroRNAs and the Operon paper |
| Q42043603 | Mixed messages: Re-initiation factors regulate translation of animal mRNAs |
| Q34624769 | Modules, networks and systems medicine for understanding disease and aiding diagnosis. |
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| Q34332378 | Paternal RNA contributions in the Caenorhabditis elegans zygote |
| Q50617301 | Paternal diet defines offspring chromatin state and intergenerational obesity. |
| Q52807093 | Post-transcriptional Regulation by 3' UTRs Can Be Masked by Regulatory Elements in 5' UTRs. |
| Q34063477 | Probabilistic clustering of sequences: inferring new bacterial regulons by comparative genomics |
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| Q33944218 | RNA-binding protein RBM20 represses splicing to orchestrate cardiac pre-mRNA processing |
| Q38370576 | RNA-bioinformatics: Tools, services and databases for the analysis of RNA-based regulation |
| Q33455484 | Reexamining microRNA site accessibility in Drosophila: a population genomics study |
| Q90785662 | Roles of Long Noncoding RNAs and Circular RNAs in Translation |
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| Q50097460 | Single-Molecule Fluorescence In Situ Hybridization (FISH) of Circular RNA CDR1as. |
| Q90950243 | Single-cell RNA-sequencing of herpes simplex virus 1-infected cells connects NRF2 activation to an antiviral program |
| Q114061458 | Single-cell transcriptomics reveals common epithelial response patterns in human acute kidney injury |
| Q92984592 | Spatiotemporal m(i)RNA Architecture and 3' UTR Regulation in the C. elegans Germline |
| Q27318426 | The CCR4-NOT complex mediates deadenylation and degradation of stem cell mRNAs and promotes planarian stem cell differentiation |
| Q48144423 | The Drosophila embryo at single-cell transcriptome resolution. |
| Q104450645 | The Human Cell Atlas White Paper |
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| Q24299494 | The SNF2-like helicase HELLS mediates E2F3-dependent transcription and cellular transformation |
| Q92470758 | The Translational Landscape of the Human Heart |
| Q35003675 | The evolution of DNA regulatory regions for proteo-gamma bacteria by interspecies comparisons |
| Q38336299 | The impact of miRNA target sites in coding sequences and in 3'UTRs |
| Q33593704 | The landscape of C. elegans 3'UTRs |
| Q47097104 | The oncogenic role of circPVT1 in head and neck squamous cell carcinoma is mediated through the mutant p53/YAP/TEAD transcription-competent complex. |
| Q102146338 | The transcriptome dynamics of single cells during the cell cycle |
| Q89810253 | Tracing tumorigenesis in a solid tumor model at single-cell resolution |
| Q24803742 | Transcriptional control in the segmentation gene network of Drosophila |
| Q52894285 | Transcriptome-wide analysis of regulatory interactions of the RNA-binding protein HuR. |
| Q33551532 | Translation of CircRNAs |
| Q35681731 | Translational regulation shapes the molecular landscape of complex disease phenotypes. |
| Q34273614 | Unambiguous identification of miRNA:target site interactions by different types of ligation reactions |
| Q45325452 | Widespread activation of antisense transcription of the host genome during herpes simplex virus 1 infection. |
| Q27860886 | Widespread changes in protein synthesis induced by microRNAs |
| Q34439445 | circBase: a database for circular RNAs. |
| Q52779294 | circRNA biogenesis competes with pre-mRNA splicing. |
| Q24623158 | doRiNA: a database of RNA interactions in post-transcriptional regulation |
| Q39865491 | miR-148a is upregulated by Twist1 and T-bet and promotes Th1-cell survival by regulating the proapoptotic gene Bim. |
| Q35633577 | miRDeep2 accurately identifies known and hundreds of novel microRNA genes in seven animal clades |
| Q24811535 | microRNA target predictions across seven Drosophila species and comparison to mammalian targets |
| Q35567426 | microRNAs regulate cell-to-cell variability of endogenous target gene expression in developing mouse thymocytes. |
| Q102124338 | Johannes Zittartz | doctoral student | P185 |
| Q126992 | Klaus Rajewsky | child | P40 |
| Q108419021 | ISMB 2019 | speaker | P823 |
| Egyptian Arabic (arz / Q29919) | نيكولاس راجوسكى | wikipedia |
| Nikolaus Rajewsky | wikipedia | |
| Nikolaus Rajewsky | wikipedia | |
| Persian (fa / Q9168) | نیکلاس رایفسکی | wikipedia |
| Раевский, Николаус | wikipedia | |
| Ніколаус Раєвський | wikipedia |
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