Lenno Krenning

1.7k total citations
20 papers, 1.1k citations indexed

About

Lenno Krenning is a scholar working on Molecular Biology, Cell Biology and Oncology. According to data from OpenAlex, Lenno Krenning has authored 20 papers receiving a total of 1.1k indexed citations (citations by other indexed papers that have themselves been cited), including 18 papers in Molecular Biology, 8 papers in Cell Biology and 6 papers in Oncology. Recurrent topics in Lenno Krenning's work include DNA Repair Mechanisms (9 papers), Microtubule and mitosis dynamics (8 papers) and Cancer-related Molecular Pathways (5 papers). Lenno Krenning is often cited by papers focused on DNA Repair Mechanisms (9 papers), Microtubule and mitosis dynamics (8 papers) and Cancer-related Molecular Pathways (5 papers). Lenno Krenning collaborates with scholars based in Netherlands, United States and Switzerland. Lenno Krenning's co-authors include René H. Medema, Indra A. Shaltiël, Jeroen van den Berg, Wytse Bruinsma, Femke M. Feringa, Dhanya K. Cheerambathur, Julien Espeut, Arshad Desai, Karen Oegema and Marvin E. Tanenbaum and has published in prestigious journals such as Science, Nucleic Acids Research and Nature Communications.

In The Last Decade

Lenno Krenning

19 papers receiving 1.1k citations

Peers — A (Enhanced Table)

Peers by citation overlap · career bar shows stage (early→late) cites · hero ref

Name h Career Trend Papers Cites
Lenno Krenning Netherlands 14 871 274 267 147 87 20 1.1k
Steven D. Cappell United States 16 1.0k 1.2× 372 1.4× 433 1.6× 111 0.8× 88 1.0× 25 1.4k
Stjepan Uldrijan Czechia 18 897 1.0× 144 0.5× 372 1.4× 163 1.1× 72 0.8× 34 1.2k
Lea Guo United States 16 1.1k 1.2× 289 1.1× 198 0.7× 119 0.8× 106 1.2× 21 1.4k
Timothy C. Gahman United States 10 759 0.9× 409 1.5× 175 0.7× 111 0.8× 59 0.7× 14 994
Albert Herms Spain 11 722 0.8× 264 1.0× 149 0.6× 259 1.8× 172 2.0× 13 1.2k
Joachim Bischof Germany 15 587 0.7× 128 0.5× 210 0.8× 82 0.6× 61 0.7× 33 826
Leonardo K. Teixeira Brazil 16 791 0.9× 175 0.6× 281 1.1× 157 1.1× 71 0.8× 21 1.1k
Rose Boutros France 14 1.1k 1.3× 425 1.6× 417 1.6× 169 1.1× 33 0.4× 14 1.3k
Daniel Y.L. Mao Canada 17 1.2k 1.3× 203 0.7× 374 1.4× 154 1.0× 50 0.6× 21 1.4k
Manjari Dimri United States 23 1.1k 1.2× 209 0.8× 364 1.4× 232 1.6× 103 1.2× 35 1.4k

Countries citing papers authored by Lenno Krenning

Since Specialization
Citations

This map shows the geographic impact of Lenno Krenning's research. It shows the number of citations coming from papers published by authors working in each country. You can also color the map by specialization and compare the number of citations received by Lenno Krenning with the expected number of citations based on a country's size and research output (numbers larger than one mean the country cites Lenno Krenning more than expected).

Fields of papers citing papers by Lenno Krenning

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by Lenno Krenning. Nodes represent research fields, and links connect fields that are likely to share authors. Colored nodes show fields that tend to cite the papers produced by Lenno Krenning. The network helps show where Lenno Krenning may publish in the future.

Co-authorship network of co-authors of Lenno Krenning

This figure shows the co-authorship network connecting the top 25 collaborators of Lenno Krenning. A scholar is included among the top collaborators of Lenno Krenning based on the total number of citations received by their joint publications. Widths of edges represent the number of papers authors have co-authored together. Node borders signify the number of papers an author published with Lenno Krenning. Lenno Krenning is excluded from the visualization to improve readability, since they are connected to all nodes in the network.

All Works

20 of 20 papers shown
1.
Menegakis, Apostolos, Claire Vennin, Jonathan Ient, et al.. (2024). A novel lineage-tracing tool reveals that hypoxic tumor cells drive tumor relapse after radiotherapy. Radiotherapy and Oncology. 202. 110592–110592.
2.
Feringa, Femke M., Bram van den Broek, Michaël Schubert, et al.. (2023). MND1 enables homologous recombination in somatic cells primarily outside the context of replication. Molecular Oncology. 17(7). 1192–1211. 8 indexed citations
3.
Pogacar, Ziva, Jackie Johnson, Lenno Krenning, et al.. (2022). Indisulam synergizes with palbociclib to induce senescence through inhibition of CDK2 kinase activity. PLoS ONE. 17(9). e0273182–e0273182. 12 indexed citations
4.
Krenning, Lenno, Tesa Severson, Xabier Vergara, et al.. (2022). Double-strand break toxicity is chromatin context independent. Nucleic Acids Research. 50(17). 9930–9947. 16 indexed citations
5.
García‐Santisteban, Iraia, et al.. (2021). Sustained CHK2 activity, but not ATM activity, is critical to maintain a G1 arrest after DNA damage in untransformed cells. BMC Biology. 19(1). 35–35. 12 indexed citations
6.
Menegakis, Apostolos, Rob Klompmaker, Claire Vennin, et al.. (2021). Resistance of Hypoxic Cells to Ionizing Radiation Is Mediated in Part via Hypoxia-Induced Quiescence. Cells. 10(3). 610–610. 30 indexed citations
7.
Hornsveld, Marten, Femke M. Feringa, Lenno Krenning, et al.. (2021). A FOXO-dependent replication checkpoint restricts proliferation of damaged cells. Cell Reports. 34(4). 108675–108675. 15 indexed citations
8.
Shaltiël, Indra A., et al.. (2021). Combined Inactivation of Pocket Proteins and APC/CCdh1 by Cdk4/6 Controls Recovery from DNA Damage in G1 Phase. Cells. 10(3). 550–550. 1 indexed citations
9.
Jost, Marco, Yuwen Chen, Luke A. Gilbert, et al.. (2020). Pharmaceutical-Grade Rigosertib Is a Microtubule-Destabilizing Agent. Molecular Cell. 79(1). 191–198.e3. 24 indexed citations
10.
Hornsveld, Marten, Femke M. Feringa, Lenno Krenning, et al.. (2020). A FOXO-Dependent Replication Checkpoint Restricts Proliferation of Damaged Cells. SSRN Electronic Journal. 1 indexed citations
11.
Battich, Nico, Joep Beumer, Buys de Barbanson, et al.. (2020). Sequencing metabolically labeled transcripts in single cells reveals mRNA turnover strategies. Science. 367(6482). 1151–1156. 86 indexed citations
12.
Krenning, Lenno, Jeroen van den Berg, & René H. Medema. (2019). Life or Death after a Break: What Determines the Choice?. Molecular Cell. 76(2). 346–358. 61 indexed citations
13.
Feringa, Femke M., Jonne A. Raaijmakers, Michael A. Hadders, et al.. (2018). Persistent repair intermediates induce senescence. Nature Communications. 9(1). 3923–3923. 45 indexed citations
14.
García‐Santisteban, Iraia, et al.. (2018). Chromosomes trapped in micronuclei are liable to segregation errors. Journal of Cell Science. 131(13). 62 indexed citations
15.
Jost, Marco, Yuwen Chen, Luke A. Gilbert, et al.. (2017). Combined CRISPRi/a-Based Chemical Genetic Screens Reveal that Rigosertib Is a Microtubule-Destabilizing Agent. Molecular Cell. 68(1). 210–223.e6. 156 indexed citations
16.
Feringa, Femke M., Lenno Krenning, André Koch, et al.. (2016). Hypersensitivity to DNA damage in antephase as a safeguard for genome stability. Nature Communications. 7(1). 12618–12618. 23 indexed citations
17.
Shaltiël, Indra A., Lenno Krenning, Wytse Bruinsma, & René H. Medema. (2015). The same, only different – DNA damage checkpoints and their reversal throughout the cell cycle. Journal of Cell Science. 128(4). 607–20. 228 indexed citations
18.
Krenning, Lenno, Femke M. Feringa, Indra A. Shaltiël, Jeroen van den Berg, & René H. Medema. (2014). Transient Activation of p53 in G2 Phase Is Sufficient to Induce Senescence. Molecular Cell. 55(1). 59–72. 153 indexed citations
19.
Espeut, Julien, Dhanya K. Cheerambathur, Lenno Krenning, Karen Oegema, & Arshad Desai. (2012). Microtubule binding by KNL-1 contributes to spindle checkpoint silencing at the kinetochore. The Journal of Cell Biology. 196(4). 469–482. 115 indexed citations
20.
Álvarez‐Fernández, Mónica, Vincentius A. Halim, Lenno Krenning, et al.. (2010). Recovery from a DNA‐damage‐induced G2 arrest requires Cdk‐dependent activation of FoxM1. EMBO Reports. 11(6). 452–458. 48 indexed citations

Rankless uses publication and citation data sourced from OpenAlex, an open and comprehensive bibliographic database. While OpenAlex provides broad and valuable coverage of the global research landscape, it—like all bibliographic datasets—has inherent limitations. These include incomplete records, variations in author disambiguation, differences in journal indexing, and delays in data updates. As a result, some metrics and network relationships displayed in Rankless may not fully capture the entirety of a scholar's output or impact.

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