Gloria G. Glick

2.9k citations

18 papers · 2.2k indexed · h-index 16

Molecular Biology top 5%
Oncology top 5%
Cell Biology top 5%
Cancer Research top 5%
Genetics top 10%

Co-authors: David Cortez Runxiang Zhao Daniel A. Mordes Carol E. Bansbach Stephen J. Elledge Rémy Betous Frank B. Couch Jessica W. Luzwick
Topics: DNA Repair Mechanisms (16 papers)Microtubule and mitosis dynamics (7 papers)Cancer-related Molecular Pathways (6 papers)
Cited by: Molecular Biology Oncology Cell Biology
Journals: Proceedings of the National Academy of Sciences Journal of Biological Chemistry Genes & Development
Partner nations: United States France Australia

In The Last Decade

Gloria G. Glick

18 papers receiving 2.2k citations

Peers

Replace Katherine Minter‐Dykhouse with:

Katherine Minter‐Dykhouse United States

Wojciech Niedźwiedź United Kingdom

Andrea Cocito Italy

Annapaola Franchitto Italy

Scott Davey Canada

Pietro Pichierri Italy

Younghoon Kee United States

Luis Toledo Denmark

Maj‐Britt Rask Denmark

Kelly M. Trujillo United States

Gloria G. Glick relative to Katherine Minter‐Dykhouse United States Katherine Minter‐Dykhouse's profile →

Citations per field

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Katherine Minter‐Dykhouse · 1×

×1.3 2k/2k

MB

×1.1 799/707

ONCOL

×1.1 454/419

CB

×1.0 347/348

CR

×1.4 220/160

GENET

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Countries citing papers authored by Gloria G. Glick

Since Specialization

Citations

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

Fields of papers citing papers by Gloria G. Glick

Since Specialization

Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by Gloria G. Glick. 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 Gloria G. Glick. The network helps show where Gloria G. Glick may publish in the future.

Co-authorship network of co-authors of Gloria G. Glick

This figure shows the co-authorship network connecting the top 25 collaborators of Gloria G. Glick. A scholar is included among the top collaborators of Gloria G. Glick 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 Gloria G. Glick. Gloria G. Glick is excluded from the visualization to improve readability, since they are connected to all nodes in the network.

All Works

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18 of 18 papers shown

#	Work	Indexed citations
1	ETAA1 acts at stalled replication forks to maintain genome integrity 2016 ·Nature Cell Biology ·Thomas E. Bass,Jessica W. Luzwick,Gina M. Kavanaugh,Clinton Carroll,Huzefa Dungrawala,Gloria G. Glick,Michael D. Feldkamp,(unknown),Walter Chazin,David Cortez	178
2	A Synthetic Lethal Screen Identifies DNA Repair Pathways that Sensitize Cancer Cells to Combined ATR Inhibition and Cisplatin Treatments 2015 ·PLoS ONE ·Kareem N. Mohni,Petria S. Thompson,Jessica W. Luzwick,Gloria G. Glick,(unknown),Brian D. Lehmann,Jennifer A. Pietenpol,David Cortez	89
3	A whole genome RNAi screen identifies replication stress response genes 2015 ·DNA repair ·Gina M. Kavanaugh,Fei Ye,Kareem N. Mohni,Jessica W. Luzwick,Gloria G. Glick,David Cortez	11
4	The Replication Checkpoint Prevents Two Types of Fork Collapse without Regulating Replisome Stability 2015 ·Molecular Cell ·Huzefa Dungrawala,Kristie L. Rose,Kamakoti P. Bhat,Kareem N. Mohni,Gloria G. Glick,Frank B. Couch,David Cortez	288
5	SMARCAL1 maintains telomere integrity during DNA replication 2015 ·Proceedings of the National Academy of Sciences ·(unknown),Runxiang Zhao,Gloria G. Glick,Courtney A. Lovejoy,Christine M. Eischen,David Cortez	71
6	Enhancer of Rudimentary Homolog Affects the Replication Stress Response through Regulation of RNA Processing 2015 ·Molecular and Cellular Biology ·Gina M. Kavanaugh,Runxiang Zhao,Yan Guo,Kareem N. Mohni,Gloria G. Glick,(unknown),M. Shane Hutson,Manuel Ascano,David Cortez	21
7	Identification and Characterization of SMARCAL1 Protein Complexes 2013 ·PLoS ONE ·Rémy Betous,Gloria G. Glick,Runxiang Zhao,David Cortez	25
8	ATR phosphorylates SMARCAL1 to prevent replication fork collapse 2013 ·Genes & Development ·Frank B. Couch,Carol E. Bansbach,Robert Driscoll,Jessica W. Luzwick,Gloria G. Glick,Rémy Betous,Clinton Carroll,Sung Yun Jung,Jun Qin,Karlene A. Cimprich,David Cortez	321
9	Thr-1989 Phosphorylation Is a Marker of Active Ataxia Telangiectasia-mutated and Rad3-related (ATR) Kinase 2011 ·Journal of Biological Chemistry ·Edward A. Nam,Runxiang Zhao,Gloria G. Glick,Carol E. Bansbach,David B. Friedman,David Cortez	95
10	The annealing helicase SMARCAL1 maintains genome integrity at stalled replication forks 2009 ·Genes & Development ·Carol E. Bansbach,Rémy Betous,Courtney A. Lovejoy,Gloria G. Glick,David Cortez	197
11	Functional genomic screens identify CINP as a genome maintenance protein 2009 ·Proceedings of the National Academy of Sciences ·Courtney A. Lovejoy,Xin Xu,Carol E. Bansbach,Gloria G. Glick,Runxiang Zhao,Fei Ye,Bianca M. Sirbu,(unknown),Yu Shyr,David Cortez	45
12	TopBP1 activates ATR through ATRIP and a PIKK regulatory domain 2008 ·Genes & Development ·Daniel A. Mordes,Gloria G. Glick,Runxiang Zhao,David Cortez	268
13	The Basic Cleft of RPA70N Binds Multiple Checkpoint Proteins, Including RAD9, To Regulate ATR Signaling 2008 ·Molecular and Cellular Biology ·Xin Xu,Sivaraja Vaithiyalingam,Gloria G. Glick,Daniel A. Mordes,Walter Chazin,David Cortez	140
14	Function of the ATR N-terminal domain revealed by an ATM/ATR chimera 2007 ·Experimental Cell Research ·Xinping Chen,Runxiang Zhao,Gloria G. Glick,David Cortez	14
15	Function of a Conserved Checkpoint Recruitment Domain in ATRIP Proteins 2007 ·Molecular and Cellular Biology ·Heather L. Ball,Mark R. Ehrhardt,Daniel A. Mordes,Gloria G. Glick,Walter Chazin,David Cortez	103
16	Minichromosome maintenance proteins are direct targets of the ATM and ATR checkpoint kinases 2004 ·Proceedings of the National Academy of Sciences ·David Cortez,Gloria G. Glick,Stephen J. Elledge	260
17	Distinct functions of S. pombeRec12 (Spo11) protein and Rec12-dependent crossover recombination (chiasmata) in meiosis I; and a requirement for Rec12 in meiosis II 2002 ·PubMed ·(unknown),Gloria G. Glick,Mari K. Davidson,Wayne P. Wahls	62
18	Reduced expression of the adherens junction protein cadherin-5 in a diabetic retina 2000 ·American Journal of Ophthalmology ·Mari K. Davidson,Patricia K. Russ,Gloria G. Glick,Loren H. Hoffman,Min S. Chang,Frederick R. Haselton	32

About Gloria G. Glick

Gloria G. Glick is a scholar working on Cell Biology, Oncology and Molecular Biology, having authored 18 papers that have together received 2.2k indexed citations. Recurring topics across this work include DNA Repair Mechanisms (16 papers), Microtubule and mitosis dynamics (7 papers) and Cancer-related Molecular Pathways (6 papers). The work is most often cited by research in Molecular Biology (2.1k citations), Oncology (799 citations) and Cell Biology (454 citations). Gloria G. Glick has collaborated with scholars based in United States, France and Australia. Frequent co-authors include David Cortez, Runxiang Zhao, Daniel A. Mordes, Carol E. Bansbach, Stephen J. Elledge, Rémy Betous, Frank B. Couch, Jessica W. Luzwick, Huzefa Dungrawala and Walter Chazin. Their work appears in journals such as Proceedings of the National Academy of Sciences, Journal of Biological Chemistry and Genes & Development.

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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