Publications

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Journal Article
Smith L.M.  1991.  High-speed DNA sequencing by capillary gel electrophoresis. Nature. 349:812-813.
Luckey JA, Drossman H, Kostichka T, Smith L.M.  1993.  High-speed DNA sequencing by capillary gel electrophoresis. Methods in Enzymology. 218:154-72.
Drossman H., Luckey J.A, Kostichka A.J, Dcunha J., Smith L.M.  1990.  High-speed separations of DNA sequencing reactions by capillary electrophoresis. Analytical Chemistry. 62:900-903.
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.
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.
Cesnik A.J, Shortreed M.R, Sheynkman G.M, Frey B.L, Smith L.M.  2016.  Human Proteomic Variation Revealed by Combining RNA-Seq Proteogenomics and Global Post-Translational Modification (G-PTM) Search Strategy. Journal of Proteome Research. 15:800-808.
Cesnik A.J, Shortreed M.R, Sheynkman G.M, Frey B.L, Smith L.M.  2016.  Human Proteomic Variation Revealed by Combining RNA-Seq Proteogenomics and Global Post-Translational Modification (G-PTM) Search Strategy. Journal of Proteome Research. 15:800-808.
Cesnik A.J, Shortreed M.R, Sheynkman G.M, Frey B.L, Smith L.M.  2016.  Human Proteomic Variation Revealed by Combining RNA-Seq Proteogenomics and Global Post-Translational Modification (G-PTM) Search Strategy. Journal of Proteome Research. 15:800-808.
Dai Y.L, Millikin R.J, Rolfs Z., Shortreed M.R, Smith L.M.  2022.  A Hybrid Spectral Library and Protein Sequence Database Search Strategy for Bottom-Up and Top-Down Proteomic Data Analysis. Journal of Proteome Research. 21:2609-2618.
Dai Y.L, Millikin R.J, Rolfs Z., Shortreed M.R, Smith L.M.  2022.  A Hybrid Spectral Library and Protein Sequence Database Search Strategy for Bottom-Up and Top-Down Proteomic Data Analysis. Journal of Proteome Research. 21:2609-2618.
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.
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.
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.
Gillmor S.D, Thiel A.J, Strother T.C, Smith L.M, Lagally M.G.  2000.  Hydrophilic/hydrophobic patterned surfaces as templates for DNA arrays. Langmuir. 16:7223-7228.
Gillmor S.D, Thiel A.J, Strother T.C, Smith L.M, Lagally M.G.  2000.  Hydrophilic/hydrophobic patterned surfaces as templates for DNA arrays. Langmuir. 16:7223-7228.
Olson CN, Galloway MM, Yu G, Hedman CJ, Lockett MR, Yoon T.P, Stone EA, Smith L.M, Keutsch F.N.  2011.  Hydroxycarboxylic Acid-Derived Organosulfates: Synthesis, Stability, and Quantification in Ambient Aerosol. Environmental Science & Technology. 45:6468-6474.
Olson CN, Galloway MM, Yu G, Hedman CJ, Lockett MR, Yoon T.P, Stone EA, Smith L.M, Keutsch F.N.  2011.  Hydroxycarboxylic Acid-Derived Organosulfates: Synthesis, Stability, and Quantification in Ambient Aerosol. Environmental Science & Technology. 45:6468-6474.
Spiniello M., Knoener R.A, Steinbrink M.I, Yang B., Cesnik A.J, Buxton K.E, Scalf M., Jarrard D.F, Smith L.M.  2018.  HyPR-MS for multiplexed discovery of MALAT1, NEAT1, and NORAD lncRNA protein interactomes. Journal of Proteome Research. 17(9):3022-3038.
Spiniello M., Knoener R.A, Steinbrink M.I, Yang B., Cesnik A.J, Buxton K.E, Scalf M., Jarrard D.F, Smith L.M.  2018.  HyPR-MS for multiplexed discovery of MALAT1, NEAT1, and NORAD lncRNA protein interactomes. Journal of Proteome Research. 17(9):3022-3038.
Spiniello M., Knoener R.A, Steinbrink M.I, Yang B., Cesnik A.J, Buxton K.E, Scalf M., Jarrard D.F, Smith L.M.  2018.  HyPR-MS for multiplexed discovery of MALAT1, NEAT1, and NORAD lncRNA protein interactomes. Journal of Proteome Research. 17(9):3022-3038.

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