Anna Philpott

6.0k total citations
97 papers, 4.4k citations indexed

About

Anna Philpott is a scholar working on Molecular Biology, Oncology and Cell Biology. According to data from OpenAlex, Anna Philpott has authored 97 papers receiving a total of 4.4k indexed citations (citations by other indexed papers that have themselves been cited), including 82 papers in Molecular Biology, 34 papers in Oncology and 22 papers in Cell Biology. Recurrent topics in Anna Philpott's work include Ubiquitin and proteasome pathways (22 papers), Cancer-related Molecular Pathways (21 papers) and Microtubule and mitosis dynamics (18 papers). Anna Philpott is often cited by papers focused on Ubiquitin and proteasome pathways (22 papers), Cancer-related Molecular Pathways (21 papers) and Microtubule and mitosis dynamics (18 papers). Anna Philpott collaborates with scholars based in United Kingdom, United States and United Arab Emirates. Anna Philpott's co-authors include Gregory H. Leno, Gary S. McDowell, Shin‐ichi Ohnuma, Laura J.A. Hardwick, Ronald A. Laskey, Ann E. Vernon, Christopher J. Hindley, Roberta Azzarelli, William A. Harris and Fahad Ali and has published in prestigious journals such as Nature, Cell and Journal of Biological Chemistry.

In The Last Decade

Anna Philpott

95 papers receiving 4.4k citations

Author Peers

Peers are selected by citation overlap in the author's most active subfields. citations · hero ref

Author Last Decade Papers Cites
Anna Philpott 3.6k 864 862 638 556 97 4.4k
Anne K. Voss 4.1k 1.1× 475 0.5× 433 0.5× 981 1.5× 475 0.9× 113 5.6k
Della Yee 3.4k 1.0× 518 0.6× 301 0.3× 864 1.4× 312 0.6× 36 4.4k
Pierre Savatier 3.4k 1.0× 531 0.6× 283 0.3× 597 0.9× 593 1.1× 62 4.3k
Masanori Taira 5.0k 1.4× 393 0.5× 728 0.8× 957 1.5× 212 0.4× 133 6.0k
Christel Brou 5.4k 1.5× 956 1.1× 745 0.9× 1.5k 2.3× 211 0.4× 49 6.9k
Tewis Bouwmeester 5.2k 1.5× 517 0.6× 1.1k 1.3× 775 1.2× 148 0.3× 59 6.2k
Lídia Pérez 3.6k 1.0× 299 0.3× 679 0.8× 736 1.2× 178 0.3× 25 4.3k
Ritsuko Takada 4.0k 1.1× 361 0.4× 668 0.8× 770 1.2× 230 0.4× 44 4.5k
Daniel B. Constam 3.3k 0.9× 599 0.7× 453 0.5× 620 1.0× 114 0.2× 64 4.4k
Joan Galcerán 3.6k 1.0× 293 0.3× 465 0.5× 633 1.0× 273 0.5× 39 4.4k

Countries citing papers authored by Anna Philpott

Since Specialization
Citations

This map shows the geographic impact of Anna Philpott'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 Anna Philpott with the expected number of citations based on a country's size and research output (numbers larger than one mean the country cites Anna Philpott more than expected).

Fields of papers citing papers by Anna Philpott

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by Anna Philpott. 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 Anna Philpott. The network helps show where Anna Philpott may publish in the future.

Co-authorship network of co-authors of Anna Philpott

This figure shows the co-authorship network connecting the top 25 collaborators of Anna Philpott. A scholar is included among the top collaborators of Anna Philpott 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 Anna Philpott. Anna Philpott 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
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Azzarelli, Roberta, et al.. (2024). Phospho-regulation of ASCL1-mediated chromatin opening during cellular reprogramming. Development. 151(24). 5 indexed citations
3.
Masserdotti, Giacomo, Tatiana Simon, Tamás Schauer, et al.. (2024). Direct neuronal reprogramming of mouse astrocytes is associated with multiscale epigenome remodeling and requires Yy1. Nature Neuroscience. 27(7). 1260–1273. 14 indexed citations
4.
Ferguson, Kirsty M., Evon Poon, Laura M. Woods, et al.. (2023). Palbociclib releases the latent differentiation capacity of neuroblastoma cells. Developmental Cell. 58(19). 1967–1982.e8. 12 indexed citations
5.
Woods, Laura M., Fahad Ali, Igor Chernukhin, et al.. (2022). Elevated ASCL1 activity creates de novo regulatory elements associated with neuronal differentiation. BMC Genomics. 23(1). 255–255. 23 indexed citations
6.
Azzarelli, Roberta, et al.. (2022). ASCL1 phosphorylation and ID2 upregulation are roadblocks to glioblastoma stem cell differentiation. Scientific Reports. 12(1). 2341–2341. 23 indexed citations
7.
Yum, Min Kyu, Seungmin Han, Juergen Fink, et al.. (2021). Tracing oncogene-driven remodelling of the intestinal stem cell niche. Nature. 594(7863). 442–447. 71 indexed citations
8.
Ali, Fahad, Igor Chernukhin, Laura M. Woods, et al.. (2020). Dephosphorylation of the Proneural Transcription Factor ASCL1 Re-Engages a Latent Post-Mitotic Differentiation Program in Neuroblastoma. Molecular Cancer Research. 18(12). 1759–1766. 18 indexed citations
9.
Tomić, Goran, Edward Morrissey, Shani Ben‐Moshe, et al.. (2018). Phospho-regulation of ATOH1 Is Required for Plasticity of Secretory Progenitors and Tissue Regeneration. Cell stem cell. 23(3). 436–443.e7. 69 indexed citations
10.
Azzarelli, Roberta, Steffen Rulands, Sonia Nestorowa, et al.. (2018). Neurogenin3 phosphorylation controls reprogramming efficiency of pancreatic ductal organoids into endocrine cells. Scientific Reports. 8(1). 15374–15374. 18 indexed citations
11.
Wylie, Luke A., et al.. (2015). Ascl1 phospho-status regulates neuronal differentiation in a Xenopus developmental model of neuroblastoma. Disease Models & Mechanisms. 8(5). 429–441. 30 indexed citations
12.
Hardwick, Laura J.A. & Anna Philpott. (2015). Multi-site phosphorylation regulates NeuroD4 activity during primary neurogenesis: a conserved mechanism amongst proneural proteins. Neural Development. 10(1). 15–15. 24 indexed citations
13.
Ali, Fahad, Kevin Cheng, Peter Kirwan, et al.. (2014). The phosphorylation status of Ascl1 is a key determinant of neuronal differentiation and maturation in vivo and in vitro. Development. 141(11). 2216–2224. 76 indexed citations
14.
Hindley, Christopher J., Fahad Ali, Gary S. McDowell, et al.. (2012). Post-translational modification of Ngn2 differentially affects transcription of distinct targets to regulate the balance between progenitor maintenance and differentiation. Development. 139(10). 1718–1723. 70 indexed citations
15.
Ali, Fahad, Gary S. McDowell, Richard W. Deibler, et al.. (2011). Cell cycle-regulated multi-site phosphorylation of Neurogenin 2 coordinates cell cycling with differentiation during neurogenesis. Development. 138(19). 4267–4277. 138 indexed citations
16.
Murai, Kasumi, Anna Philpott, & Philip H. Jones. (2011). Hes6 Is Required for the Neurogenic Activity of Neurogenin and NeuroD. PLoS ONE. 6(11). e27880–e27880. 15 indexed citations
17.
Nguyen, Laurent, Arnaud Besson, Julian Ik‐Tsen Heng, et al.. (2007). p27Kip1 independently promotes neuronal differentiation and migration in the cerebral cortex. SPIRE - Sciences Po Institutional REpository. 6 indexed citations
18.
Nguyen, Laurent, Arnaud Besson, Julian Ik‐Tsen Heng, et al.. (2007). [p27Kip1 independently promotes neuronal differentiation and migration in the cerebral cortex].. PubMed. 162(5-6). 310–4. 7 indexed citations
19.
Cossins, Judy, Ann E. Vernon, Yun Zhang, Anna Philpott, & Philip H. Jones. (2002). Hes6 regulates myogenic differentiation. Development. 129(9). 2195–2207. 60 indexed citations
20.
Ohnuma, Shin‐ichi, et al.. (2002). Co-ordinating retinal histogenesis: early cell cycle exit enhances early cell fate determination in theXenopusretina. Development. 129(10). 2435–2446. 131 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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