Publications

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2019
Schaffer L.V, Millikin R.J, Miller R.M, Anderson L.C, Fellers R.T, Ge Y., Kelleher N.L, LeDuc R.D, Liu X., Payne S.H et al..  2019.  Identification and Quantification of Proteoforms by Mass Spectrometry. Proteomics.
Schaffer L.V, Millikin R.J, Miller R.M, Anderson L.C, Fellers R.T, Ge Y., Kelleher N.L, LeDuc R.D, Liu X., Payne S.H et al..  2019.  Identification and Quantification of Proteoforms by Mass Spectrometry. Proteomics.
Miller R.M, Millikin R.J, Hoffman C.V, Solntsev S.K, Sheynkman G.M, Shortreed M.R, Smith L.M.  2019.  Improved Protein Inference from Multiple Protease Bottom-Up Mass Spectrometry Data. Journal of Proteome Research. 18(9)
Miller R.M, Millikin R.J, Hoffman C.V, Solntsev S.K, Sheynkman G.M, Shortreed M.R, Smith L.M.  2019.  Improved Protein Inference from Multiple Protease Bottom-Up Mass Spectrometry Data. Journal of Proteome Research. 18(9)
Gemperline D.C, Marshall R.S, Lee K.H, Zhao Q.Z, Hu W.M, McLoughlin F., Scalf M., Smith L.M, Vierstra R.D.  2019.  Proteomic analysis of affinity-purified 26S proteasomes identifies a suite of assembly chaperones in Arabidopsis. Journal of Biological Chemistry. 294:17570-17592.
Gemperline D.C, Marshall R.S, Lee K.H, Zhao Q.Z, Hu W.M, McLoughlin F., Scalf M., Smith L.M, Vierstra R.D.  2019.  Proteomic analysis of affinity-purified 26S proteasomes identifies a suite of assembly chaperones in Arabidopsis. Journal of Biological Chemistry. 294:17570-17592.
2018
Guillen-Ahlers H, Rao P.K, Perumalla D.S, Montoya M.J, Jadhav A.YL, Shortreed M.R, Smith L.M, Olivier M.  2018.  Adaptation of Hybridization Capture of Chromatin-associated Proteins for Proteomics to Mammalian Cells. Journal of Visualized Experiments. (136)
Aebersold R., Agar J.N, Amster I.J, Baker M.S, Bertozzi C.R, Boja E.S, Costello C.E, Cravatt B.F, Fenselau C., Garcia B.A et al..  2018.  How many human proteoforms are there? Nature Chemical Biology. 14:206-214.
Aebersold R., Agar J.N, Amster I.J, Baker M.S, Bertozzi C.R, Boja E.S, Costello C.E, Cravatt B.F, Fenselau C., Garcia B.A et al..  2018.  How many human proteoforms are there? Nature Chemical Biology. 14:206-214.
Aebersold R., Agar J.N, Amster I.J, Baker M.S, Bertozzi C.R, Boja E.S, Costello C.E, Cravatt B.F, Fenselau C., Garcia B.A et al..  2018.  How many human proteoforms are there? Nature Chemical Biology. 14:206-214.
Aebersold R., Agar J.N, Amster I.J, Baker M.S, Bertozzi C.R, Boja E.S, Costello C.E, Cravatt B.F, Fenselau C., Garcia B.A et al..  2018.  How many human proteoforms are there? Nature Chemical Biology. 14:206-214.
Aebersold R., Agar J.N, Amster I.J, Baker M.S, Bertozzi C.R, Boja E.S, Costello C.E, Cravatt B.F, Fenselau C., Garcia B.A et al..  2018.  How many human proteoforms are there? Nature Chemical Biology. 14:206-214.
Lu L, Millikin RJ, Solntsev SK, Rolfs Z, Scalf M, Shortreed MR, Smith LM.  2018.  Identification of MS-Cleavable and Noncleavable Chemically Cross-Linked Peptides with MetaMorpheus. Journal of Proteome Research. 17(7):2370-2376.
Leduc R.D, Schwammle V., Shortreed M.R, Cesnik A.J, Solntsev S.K, Shaw J.B, Martin M.J, Vizcaino J.A, Alpi E., Danis P. et al..  2018.  ProForma: A Standard Proteoform Notation. Journal of Proteome Research. 17:1321-1325.
Rytz T.C, Miller M.J, McLoughlin F., Augustine R.C, Marshall R.S, Juan Y.T, Charng Y.Y, Scalf M., Smith L.M, Vierstra R.D.  2018.  SUMOylome Profiling Reveals a Diverse Array of Nuclear Targets Modified by the SUMO Ligase SIZ1 during Heat Stress. Plant Cell. 30:1077-1099.
Rytz T.C, Miller M.J, McLoughlin F., Augustine R.C, Marshall R.S, Juan Y.T, Charng Y.Y, Scalf M., Smith L.M, Vierstra R.D.  2018.  SUMOylome Profiling Reveals a Diverse Array of Nuclear Targets Modified by the SUMO Ligase SIZ1 during Heat Stress. Plant Cell. 30:1077-1099.
Rytz T.C, Miller M.J, McLoughlin F., Augustine R.C, Marshall R.S, Juan Y.T, Charng Y.Y, Scalf M., Smith L.M, Vierstra R.D.  2018.  SUMOylome Profiling Reveals a Diverse Array of Nuclear Targets Modified by the SUMO Ligase SIZ1 during Heat Stress. Plant Cell. 30:1077-1099.
Millikin R.J, Solntsev S.K, Shortreed M.R, Smith L.M.  2018.  Ultrafast Peptide Label-Free Quantification with FlashLFQ. Journal of Proteome Research. 17:386-391.
2016
Guillen-Ahlers H., Rao P.K, Levenstein M.E, Kennedy-Darling J., Perumalla D.S, Jadhav A.Y, Glenn J.P, Ludwig-Kubinski A., Drigalenko E., Montoya M.J et al..  2016.  HyCCAPP as a tool to characterize promoter DNA-protein interactions in Saccharomyces cerevisiae. Genomics. 107:267-273.
Chen X., Lu L., Mayer K.S, Scalf M., Qian S., Lomax A., Smith L.M, Zhong X..  2016.  POWERDRESS interacts with HISTONE DEACETYLASE 9 to promote aging in Arabidopsis. Elife. 5
2014
Jagtap P.D, Johnson J.E, Onsongo G., Sadler F.W, Murray K., Wang Y.B, Shenykrnan G.M, Bandhakavi S., Smith L.M, Griffin T.J.  2014.  Flexible and Accessible Workflows for Improved Proteogenomic Analysis Using the Galaxy Framework. Journal of Proteome Research. 13:5898-5908.
Rhoads T.W, Rose C.M, Bailey D.J, Riley N.M, Molden R.C, Nestler A.J, Merrill A.E, Smith L.M, Hebert A.S, Westphall M.S et al..  2014.  Neutron-Encoded Mass Signatures for Quantitative Top-Down Proteomics. Analytical Chemistry. 86:2314-2319.
Rhoads T.W, Rose C.M, Bailey D.J, Riley N.M, Molden R.C, Nestler A.J, Merrill A.E, Smith L.M, Hebert A.S, Westphall M.S et al..  2014.  Neutron-Encoded Mass Signatures for Quantitative Top-Down Proteomics. Analytical Chemistry. 86:2314-2319.
2013
Miller M.J, Scalf M., Rytz T.C, Hubler S.L, Smith L.M, Vierstra R.D.  2013.  Quantitative Proteomics Reveals Factors Regulating RNA Biology as Dynamic Targets of Stress-induced SUMOylation in Arabidopsis. Molecular & Cellular Proteomics. 12:449-463.
2011
Wu C.H, Chen S.Y, Shortreed M.R, Kreitinger G.M, Yuan Y., Frey B.L, Zhang Y., Mirza S., Cirillo L.A, Olivier M. et al..  2011.  Sequence-Specific Capture of Protein-DNA Complexes for Mass Spectrometric Protein Identification. Plos One. 6

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