{"id":6,"date":"2017-08-16T13:42:51","date_gmt":"2017-08-16T13:42:51","guid":{"rendered":"https:\/\/my.vanderbilt.edu\/thefriedmanlab\/publications\/"},"modified":"2023-09-26T21:05:35","modified_gmt":"2023-09-27T02:05:35","slug":"publications","status":"publish","type":"page","link":"https:\/\/my.vanderbilt.edu\/thefriedmanlab\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"

K. Ngo, T.H. Gittens, D.I. Gonzalez, E.A. Hatmaker, S. Plotkin, M. Engle, G.A. Friedman, M. Goldin, R.E. Hoerr, B.F. Eichman, A. Rokas, M.L. Benton, K.L. Friedman\u00a0(2023) A comprehensive map of hotspots of de novo <\/em>telomere addition in Saccharomyces cerevisiae<\/em><\/a>. Genetics 224(2). iyad076. PMID: 37119805.<\/p>\n

R.E. Hoerr, A. Eng, C. Payen, S.C. Di Rienzi, M.K. Raghuraman, M.J. Dunham, B.J. Brewer, K.L. Friedman (2023) Hotspot of de novo<\/em> telomere addition stabilizes linear amplicons in yeast grown in sulfate-limiting conditions<\/a>. Genetics 224(2):iyad010. PMC1021349.<\/p>\n

R.E. Hoerr,* K. Ngo,* K.L. Friedman (2021) When the ends justify the means: regulation of telomere addition at double-strand breaks in yeast<\/a>.\u00a0Front Cell Dev Biol<\/em>\u00a09:655377. PMC8012806 *These authors contributed equally.<\/p>\n

R.T. DeAngelis, J. Taylor, K.L. Friedman (2020) Parental status and biological functioning: findings from the Nashville stress and health study<\/a>. Popul Res Policy Rev. 39(2): 365-373. PMC7954218<\/p>\n

Ngo, E.A. Epum,K.L. Friedman (2020)\u00a0Emerging non-canonical roles for the Rad51-Rad52 interaction in response to double-strand breaks in yeast.<\/a>Curr Genet. \u00a0<\/em>PMID32399607.<\/p>\n

E.A. Epum, M. Mohan, N.P. Ruppe, K.L. Friedman (2020)\u00a0Interaction of yeast Rad51 and Rad52 relieves Rad52-mediated inhibition of de novo telomere addition<\/a>.\u00a0PLoS Genet.<\/em> 16(2)<\/strong>:e1008608. PMID32012161.<\/p>\n

E. O’Brien, L.E. Salay, E.A. Epum,\u00a0K.L. Friedman, W.J. Chazin, J.K. Barton\u00a0(2018)\u00a0Yeast require redox switching in DNA primase.<\/a>\u00a0\u00a0Proc Natl Acad Sci U S A<\/em>. 115<\/strong>:13186-13191. PMC6310810.<\/p>\n

M.J. McFarland, J. Taylor, C.A.S. McFarland, K.L. Friedman\u00a0(2018)\u00a0Perceived Unfair Treatment by Police, Race, and Telomere Length: A Nashville Community-based Sample of Black and White Men.\u00a0<\/a>\u00a0J Health Soc Behav<\/em>.585-600.<\/p>\n

M.D. Schaller, G. McDowell, A. Porter, D. Shippen, K.L. Friedman, M.S. Gentry, T.R. Serio, W.I. Sundquist. (2017)\u00a0What’s in a name?\u00a0<\/a>Elife\u00a0<\/em>6<\/strong>.pii: e32437. PMC5655148.<\/p>\n

C. Obodo, E.A. Epum, M.H. Platts, J. Seloff,\u00a0N.A. Dahlson,\u00a0 S.M. Velkovsky,\u00a0S.R. Paul,\u00a0and K.L. Friedman (2016) Endogenous Hot Spots of De Novo Telomere Addition in the Yeast Genome Contain Proximal Enhancers That Bind Cdc13.<\/a>\u00a0Mol. Cell. Biol. <\/em>36<\/strong>, 1750-1763.<\/p>\n

T.D. Hill, C.G. Ellison, A.M. Burdette, J. Taylor, and K.L. Friedman. (2016) Dimensions of religious involvement and leukocyte telomere length.<\/a> Social Science & Medicine<\/em> 163<\/strong>, 168-75.<\/p>\n

Ning, M.D. Feldkamp, D. Cortez, W.J. Chazin, K.L. Friedman, and E. Fanning (2015) Simian virus Large T antigen interacts with the N-terminal domain of the 70 kD subunit of Replication Protein A in the same mode as multiple DNA damage response factors.<\/a> PLoS One<\/em> 10: <\/strong>e0116093. PMC4337903.<\/p>\n

G.A. Sowd, D. Mody, J. Eggold,\u00a0D. Cortez, K.L. Friedman, and E. Fanning (2014) SV40 utilizes ATM kinase activity to prevent non-homologous end joining of broken viral DNA replication products.<\/a> PLoS Pathog<\/em>.10 :e1004536. PMC4256475.<\/p>\n

C. Hawkins and K.L. Friedman (2014) Normal Telomere Length Maintenance in Yeast Requires Nuclear Import of the Ever Shorter Telomeres 1 (Est1) Protein via the Importin Alpha Pathway.<\/a> Eukaryotic Cell<\/em> 13: <\/strong>1036-1050.\u00a0 <\/strong>PMC4135794.<\/p>\n

K. Paeschke, M.L. Bochman, P.D. Garcia, P. Cejka, K.L. Friedman, S.C. Kowalczykowski, and V.A. Zakian (2013) Pif1 family helicases suppress genome instability at G-quadruplex motifs.<\/a> Nature<\/em> 497<\/strong>. 458-462. PMC3680789.<\/p>\n

J.L. Ferguson, W.C.H. Chao, E. Lee and K.L. Friedman (2013) The anaphase promoting complex contributes to the degradation of the S. cerevisiae telomerase recruitment subunit Est1p.<\/a>\u00a0PLoS ONE<\/em> 8<\/strong>(1): e55055. PMC3555863<\/p>\n

R.C.B. Bairley, G. Guillaume, L.R. Vega, and K.L. Friedman (2011) A mutation in the catalytic subunit of yeast telomerase alters primer-template alignment while promoting processivity and protein-DNA binding.<\/a> J. Cell Sci<\/em>., 124<\/strong>. 4241-52. PMID: 22193961<\/p>\n

J.M. Talley, D.C. DeZwaan, L.D. Maness, B.C. Freeman, and K.L. Friedman (2011) Stimulation of yeast telomerase activity by the ever shorter telomere 3 (Est3) subunit is dependent on direct interaction with the catalytic protein Est2.<\/a> J. Biol. Chem. <\/em>286<\/strong>. 26431-26439. PMC3143607<\/p>\n

K.L. Friedman (2011) Telomerase reverse transcriptase and Wnt signaling.<\/a> Mol. Cell. Biol<\/em>. <\/em>31<\/strong>. <\/em>2366-2368. <\/em>PMC3133428<\/p>\n

J.L. Osterhage and K.L. Friedman (2009) Chromosome end maintenance by telomerase.<\/a> J Biol Chem<\/em>. 284<\/strong>. 16061-16065. PMC2713563<\/p>\n

H. Ji, C.J. Adkins, B.R. Cartwright, and K.L. Friedman (2008) Yeast Est2p affects telomere length by influencing association of Rap1p with telomeric chromatin.<\/a> Mol. Cell. Biol.<\/em> 28<\/strong>. 2380-2390.<\/p>\n

J.L. Osterhage, J.M. Talley, and K.L. Friedman (2006) Proteasome-dependent degradation of Est1p regulates the cell cycle-restricted assembly of telomerase in Saccharomyces cerevisiae.<\/a>\u00a0Nat. Struct. Mol. Biol. <\/em>13<\/strong>. 720-728.<\/p>\n

H. Ji, M.H. Platts, L.M. Dharamsi, and K.L. Friedman (2005) Regulation of telomere length by an N-terminal region of the yeast telomerase reverse transcriptase.<\/a> Mol. Cell. Biol<\/em>. 25<\/strong>. 9103-9114.<\/p>\n

 <\/p>\n","protected":false},"excerpt":{"rendered":"

K. Ngo, T.H. Gittens, D.I. Gonzalez, E.A. Hatmaker, S. Plotkin, M. Engle, G.A. Friedman, M. Goldin, R.E. Hoerr, B.F. Eichman, A. Rokas, M.L. Benton, K.L. Friedman\u00a0(2023) A comprehensive map of hotspots of de novo telomere addition in Saccharomyces cerevisiae. Genetics 224(2). iyad076. PMID: 37119805. R.E. Hoerr, A. Eng, C. Payen, S.C. Di Rienzi, M.K. Raghuraman,…<\/p>\n","protected":false},"author":6859,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"footnotes":""},"tags":[],"class_list":["post-6","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/my.vanderbilt.edu\/thefriedmanlab\/wp-json\/wp\/v2\/pages\/6","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/my.vanderbilt.edu\/thefriedmanlab\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/my.vanderbilt.edu\/thefriedmanlab\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/my.vanderbilt.edu\/thefriedmanlab\/wp-json\/wp\/v2\/users\/6859"}],"replies":[{"embeddable":true,"href":"https:\/\/my.vanderbilt.edu\/thefriedmanlab\/wp-json\/wp\/v2\/comments?post=6"}],"version-history":[{"count":9,"href":"https:\/\/my.vanderbilt.edu\/thefriedmanlab\/wp-json\/wp\/v2\/pages\/6\/revisions"}],"predecessor-version":[{"id":65,"href":"https:\/\/my.vanderbilt.edu\/thefriedmanlab\/wp-json\/wp\/v2\/pages\/6\/revisions\/65"}],"wp:attachment":[{"href":"https:\/\/my.vanderbilt.edu\/thefriedmanlab\/wp-json\/wp\/v2\/media?parent=6"}],"wp:term":[{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/my.vanderbilt.edu\/thefriedmanlab\/wp-json\/wp\/v2\/tags?post=6"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}