Peter R. Eriksson

1.1k total citations
21 papers, 818 citations indexed

About

Peter R. Eriksson is a scholar working on Molecular Biology, Plant Science and Immunology. According to data from OpenAlex, Peter R. Eriksson has authored 21 papers receiving a total of 818 indexed citations (citations by other indexed papers that have themselves been cited), including 20 papers in Molecular Biology, 9 papers in Plant Science and 1 paper in Immunology. Recurrent topics in Peter R. Eriksson's work include Genomics and Chromatin Dynamics (18 papers), RNA Research and Splicing (11 papers) and Fungal and yeast genetics research (7 papers). Peter R. Eriksson is often cited by papers focused on Genomics and Chromatin Dynamics (18 papers), RNA Research and Splicing (11 papers) and Fungal and yeast genetics research (7 papers). Peter R. Eriksson collaborates with scholars based in United States, Germany and Ireland. Peter R. Eriksson's co-authors include David J. Clark, David J. Stillman, Yaxin Yu, Răzvan V. Chereji, Josefina Ocampo, Dwaipayan Ganguli, Susan Ruone, Aileen E. Olsen, Paul D. Kaufman and Melissa D. Adams and has published in prestigious journals such as Nucleic Acids Research, Journal of Biological Chemistry and Nature Communications.

In The Last Decade

Peter R. Eriksson

20 papers receiving 812 citations

Peers

Peter R. Eriksson
Christophe Normand France
Maria Jessica Bruzzone Switzerland
Alberto Moldón Spain
Magdalena Strzelecka United States
Deborah Thurtle-Schmidt United States
Kristi E. Miller United States
Elliot A. Hershberg United States
Shawna Miles United States
Tim Humphrey United Kingdom
Shinya Takahata Japan
Christophe Normand France
Peter R. Eriksson
Citations per year, relative to Peter R. Eriksson Peter R. Eriksson (= 1×) peers Christophe Normand

Countries citing papers authored by Peter R. Eriksson

Since Specialization
Citations

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

Fields of papers citing papers by Peter R. Eriksson

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by Peter R. Eriksson. 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 Peter R. Eriksson. The network helps show where Peter R. Eriksson may publish in the future.

Co-authorship network of co-authors of Peter R. Eriksson

This figure shows the co-authorship network connecting the top 25 collaborators of Peter R. Eriksson. A scholar is included among the top collaborators of Peter R. Eriksson 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 Peter R. Eriksson. Peter R. Eriksson 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.
Xu, Zhuwei, et al.. (2025). Nucleosome dynamics render heterochromatin accessible in living human cells. Nature Communications. 16(1). 4577–4577. 2 indexed citations
2.
Xu, Zhuwei, et al.. (2025). Sir proteins impede, but do not prevent, access to silent chromatin in living Saccharomyces cerevisiae. bioRxiv (Cold Spring Harbor Laboratory).
3.
Xu, Zhuwei, et al.. (2025). The ISW1 and CHD1 chromatin remodelers suppress global nucleosome dynamics in living yeast cells. Science Advances. 11(31). eadw7108–eadw7108. 1 indexed citations
4.
Eriksson, Peter R., et al.. (2024). The yeast genome is globally accessible in living cells. Nature Structural & Molecular Biology. 32(2). 247–256. 5 indexed citations
5.
Eriksson, Peter R. & David J. Clark. (2021). The yeast ISW1b ATP-dependent chromatin remodeler is critical for nucleosome spacing and dinucleosome resolution. Scientific Reports. 11(1). 4195–4195. 15 indexed citations
6.
Chereji, Răzvan V., et al.. (2019). Accessibility of promoter DNA is not the primary determinant of chromatin-mediated gene regulation. Genome Research. 29(12). 1985–1995. 45 indexed citations
7.
Ocampo, Josefina, Răzvan V. Chereji, Peter R. Eriksson, & David J. Clark. (2019). Contrasting roles of the RSC and ISW1/CHD1 chromatin remodelers in RNA polymerase II elongation and termination. Genome Research. 29(3). 407–417. 41 indexed citations
8.
Mehta, Gunjan, David A. Ball, Peter R. Eriksson, et al.. (2018). Single-Molecule Analysis Reveals Linked Cycles of RSC Chromatin Remodeling and Ace1p Transcription Factor Binding in Yeast. Molecular Cell. 72(5). 875–887.e9. 53 indexed citations
9.
Ouda, Ryota, Mira C. Patel, Mahesh Bachu, et al.. (2018). SPT6 interacts with NSD2 and facilitates interferon‐induced transcription. FEBS Letters. 592(10). 1681–1692. 7 indexed citations
10.
Ocampo, Josefina, Răzvan V. Chereji, Peter R. Eriksson, & David J. Clark. (2016). The ISW1 and CHD1 ATP-dependent chromatin remodelers compete to set nucleosome spacingin vivo. Nucleic Acids Research. 44(10). 4625–4635. 97 indexed citations
11.
Eriksson, Peter R., Dwaipayan Ganguli, V. Nagarajavel, & David J. Clark. (2012). Regulation of Histone Gene Expression in Budding Yeast. Genetics. 191(1). 7–20. 72 indexed citations
12.
Eriksson, Peter R., Dwaipayan Ganguli, & David J. Clark. (2010). Spt10 and Swi4 Control the Timing of Histone H2A/H2B Gene Activation in Budding Yeast. Molecular and Cellular Biology. 31(3). 557–572. 27 indexed citations
13.
Mendiratta, Geetu, Peter R. Eriksson, & David J. Clark. (2007). Cooperative binding of the yeast Spt10p activator to the histone upstream activating sequences is mediated through an N-terminal dimerization domain. Nucleic Acids Research. 35(3). 812–821. 11 indexed citations
14.
Mendiratta, Geetu, Peter R. Eriksson, Chang-Hui Shen, & David J. Clark. (2006). The DNA-binding Domain of the Yeast Spt10p Activator Includes a Zinc Finger That Is Homologous to Foamy Virus Integrase. Journal of Biological Chemistry. 281(11). 7040–7048. 23 indexed citations
15.
Eriksson, Peter R., Debabrata Biswas, Yaxin Yu, James McD. Stewart, & David J. Stillman. (2004). TATA-Binding Protein Mutants That Are Lethal in the Absence of the Nhp6 High-Mobility-Group Protein. Molecular and Cellular Biology. 24(14). 6419–6429. 33 indexed citations
16.
Eriksson, Peter R., Lance R. Thomas, Andrew Thorburn, & David J. Stillman. (2004). pRS yeast vectors with a LYS2 marker. BioTechniques. 36(2). 212–213. 12 indexed citations
17.
Biswas, Debabrata, Anthony N. Imbalzano, Peter R. Eriksson, Yaxin Yu, & David J. Stillman. (2004). Role for Nhp6, Gcn5, and the Swi/Snf Complex in Stimulating Formation of the TATA-Binding Protein-TFIIA-DNA Complex. Molecular and Cellular Biology. 24(18). 8312–8321. 37 indexed citations
18.
Yu, Yaxin, Peter R. Eriksson, Leena T. Bhoite, & David J. Stillman. (2003). Regulation of TATA-Binding Protein Binding by the SAGA Complex and the Nhp6 High-Mobility Group Protein. Molecular and Cellular Biology. 23(6). 1910–1921. 47 indexed citations
19.
Formosa, Tim, Susan Ruone, Melissa D. Adams, et al.. (2002). Defects in SPT16 or POB3 (yFACT) in Saccharomyces cerevisiae Cause Dependence on the Hir/Hpc Pathway: Polymerase Passage May Degrade Chromatin Structure. Genetics. 162(4). 1557–1571. 174 indexed citations
20.
Yu, Yaxin, Peter R. Eriksson, & David J. Stillman. (2000). Architectural Transcription Factors and the SAGA Complex Function in Parallel Pathways To Activate Transcription. Molecular and Cellular Biology. 20(7). 2350–2357. 64 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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