Publications

Publications by Emanuel Rosonina
Underlines indicate authors that are/were Rosonina Lab students.
See list on PubMed

Preprints

  1. Sri Theivakadadcham, V.S., and Rosonina, E. (2019). Ethanol stress stimulates sumoylation of transcription factor Cst6 which restricts expression of its target genes. bioRxiv 758607; doi: https://doi.org/10.1101/758607

Published

  1. McNeil, J.B., Lee, S.-K., Oliinyk, A., Raina, S., Garg, J., Moallem, M., Urquhart-Cox, V., Fillingham, J., Cheung, P., and Rosonina, E. (2024) 1,10-phenanthroline inhibits sumoylation and reveals that yeast SUMO modifications are highly transient. EMBO Reports. 25:68-81. (Available online)
  2. Moallem, M., Akhter, A., Burke, G.L., Babu, J., Bergey, B.G., McNeil, J.B., Baig, M.S., and Rosonina, E. (2023) Sumoylation is largely dispensable for normal growth but facilitates heat tolerance in yeast. Molecular and Cellular Biology 43:64-84. (Available online)
  3. Baig, M.S., Dou, Y., Bergey, B.G., Bahar, R., Burgener, J.M., Moallem, M., McNeil, J.B., Akhter, A., Burke, G.L., Sri Theivakadadcham, V.S., Richard, P., D’Amours, D., and Rosonina, E. (2021) Dynamic sumoylation of promoter-bound general transcription factors facilitates transcription by RNA polymerase II. PLOS Genetics 17(9):e1009828. (Available online)
  4. Richard, P., and Rosonina, E. (2021) Regulating autophagy: a novel role for SETX (Senataxin). Neural Regeneration Research 16(10): 2008-2009. (Available online)
  5. Rosonina, E. (2019). A conserved role for transcription factor sumoylation in binding-site selection. Current Genetics 65:1307-1312. (Available online)
  6. Sri Theivakadadcham, V.S., Bergey, B.G., and Rosonina, E. (2019) Sumoylation of DNA-bound transcription factor Sko1 prevents its association with nontarget promoters. PLOS Genetics 15(2): e1007991. (Available online)
  7. Rosonina, E., Akhter, A., Dou, Y., Babu, J., and Sri Theivakadadcham, V.S. (2017). Regulation of transcription factors by sumoylation. Transcription 8:220-231. (Available online)
  8. Akhter, A., and Rosonina, E. (2016). Chromatin association of Gcn4 is limited by post-translational modifications triggered by its DNA-binding in Saccharomyces cerevisiaeGenetics 204:1433-1445. (Available online)
  9. Ng, C.H., Akhter, A., Yurko, N., Burgener, J.M., Rosonina, E., and Manley, J.L. (2015) Sumoylation controls the timing of Tup1-mediated transcriptional deactivation. Nature Communications 6:6610.
    Featured in Science 2.0, Phys.org, Genetics Literacy Project, News-Medical.net, News Codex, 2015 Tech, Scikon, and other popular science news sites.
  10. Rosonina, E., Yurko, N.M., and Manley, J.L. (2014) Threonine-4 of the budding yeast RNAP II CTD couples transcription with Htz1-mediated chromatin remodeling. PNAS USA 111:11924-11931.
  11. Rosonina, E., Duncan, S.M., and Manley, J.L. (2012) Sumoylation of transcription factor Gcn4 facilitates its Srb10-mediated clearance from promoters in yeast. Genes & Development 26: 350-355.
  12. Garcia, A., Rosonina, E., Manley, J.L., Calvo, O. (2010) Sub1 globally regulates RNA polymerase II CTD phosphorylation. Molecular and Cellular Biology 30: 5180-5193.
  13. Rosonina, E., Duncan, S.M., and Manley, J.L. (2010) SUMO functions in constitutive transcription and during activation of inducible genes in yeast. Genes & Development 24: 1242-1252.
    Recommended by Faculty of 1000
  14. Rosonina, E., and Manley, J.L. (2010) Alternative Polyadenylation Blooms. Developmental Cell 18: 172-174.
  15. LeBel, C., Rosonina, E., Sealey, D.C.F., Pryde, F., Lydall, D., Maringele, L., and Harrington, L. (2009) Telomere maintenance and survival in Saccharomyces cerevisiae in the absence of telomerase and RAD52. Genetics 182: 671-684.
  16. Rosonina, E., Willis, I.M., and Manley, J.L. (2009) Sub1 functions in osmoregulation and in transcription by both RNA polymerases II and III. Molecular and Cellular Biology 29: 2308-2321.
    Recommended by Faculty of 1000
  17. Rosonina, E., Kaneko, S., and Manley, J.L. (2006) Terminating the transcript: breaking up is hard to do. Genes & Development 20: 1050-1056.
  18. Rosonina, E., and Manley, J.L. (2005) From transcription to mRNA: PAF provides a new path. Molecular Cell 20: 167-168.
  19. Rosonina, E., Ip, J.Y.Y., Calarco, J.A., Bakowski, M.A., Emili, A., McCracken, S., Tucker, P., Ingles, C.J., and Blencowe, B.J. (2005) Role for PSF in mediating transcriptional activator-dependent stimulation of pre-mRNA processing in vivo. Molecular and Cellular Biology 25: 6734-6746.
  20. Rosonina, E., and Blencowe, B.J. (2004) Analysis of the requirement for RNA polymerase II CTD heptapeptide repeats in pre-mRNA splicing and 3′-end cleavage. RNA 10: 581-589.
  21. Rosonina, E., Bakowski, M.A., McCracken, S., and Blencowe, B.J. (2003) Transcriptional activators control splicing and 3´-end cleavage levels. Journal of Biological Chemistry 278: 43034-43040.
  22. Rosonina, E., and Blencowe, B.J. (2002) Gene expression: The close coupling of transcription and splicing. Current Biology 12: R319-R321.
  23. McGarvey, T., Rosonina, E., McCracken, S., Li, Q., Arnaout, R., Mientjes, E., Nickerson, J.A., Awrey, D., Greenblatt, J., Grosveld, G., and Blencowe, B.J. (2000) The acute myeloid leukemia-associated protein, DEK, forms a splicing-dependent interaction with exon-product complexes. Journal of Cell Biology 150: 309-320.
  24. Blencowe, B.J., Bauren, G., Eldridge, A.G., Issner, R., Nickerson, J.A., Rosonina, E., and Sharp, P.A. (2000) The SRm160/300 splicing coactivator subunits. RNA 6: 111-20.
  25. Blencowe, B.J., Bowman, J.A.L., McCracken, S., and Rosonina, E. (1999) SR-related proteins and the processing of messenger RNA. Biochemistry and Cell Biology 77: 1-15.
  26. McCracken, S., Rosonina, E., Fong, N., Sikes, M., Beyer, A., O'Hare, K., Shuman, S., and Bentley, D. (1998) Role of RNA Polymerase II Carboxy-terminal Domain in coordinating Transcription with RNA Processing. Cold Spring Harbor Symposia on Quantitative Biology, Volume LXIII.
  27. McCracken, S., Fong, N., Rosonina, E., Yankulov, K., Brothers, G., Siderovski, D., Hessel, A., Foster, S., Shuman, S., and Bentley, D.L. (1997) 5′-Capping enzymes are targeted to pre-mRNA by binding to the phosphorylated carboxy-terminal domain of RNA polymerase II. Genes & Development 11: 3306-3318.