Discovering Targets of Non-enzymatic Acylation by Thioester Reactivity Profiling

Rhushikesh A. Kulkarni; Andrew J. Worth; Thomas T. Zengeya; Jonathan H. Shrimp; Julie M. Garlick; Allison M. Roberts; David C. Montgomery; Carole Sourbier; Benjamin K. Gibbs; Clementina Mesaros; Yien Che Tsai; Sudipto Das; King C. Chan; Ming Zhou; Thorkell Andresson; Allan M. Weissman; W. Marston Linehan; Ian A. Blair; Nathaniel W. Snyder; Jordan L. Meier

doi:10.1016/j.chembiol.2017.01.002

Discovering Targets of Non-enzymatic Acylation by Thioester Reactivity Profiling

Rhushikesh A. Kulkarni
, Andrew J. Worth
, Thomas T. Zengeya
, Jonathan H. Shrimp
, Julie M. Garlick
, Allison M. Roberts
, David C. Montgomery
, Carole Sourbier
, Benjamin K. Gibbs
, Clementina Mesaros
, Yien Che Tsai
, Sudipto Das
, King C. Chan
, Ming Zhou
, Thorkell Andresson
, Allan M. Weissman
, W. Marston Linehan
, Ian A. Blair
, Nathaniel W. Snyder
, Jordan L. Meier

Research output: Contribution to journal › Article › peer-review

83 Scopus citations

Abstract

Non-enzymatic protein modification driven by thioester reactivity is thought to play a major role in the establishment of cellular lysine acylation. However, the specific protein targets of this process are largely unknown. Here we report an experimental strategy to investigate non-enzymatic acylation in cells. Specifically, we develop a chemoproteomic method that separates thioester reactivity from enzymatic utilization, allowing selective enrichment of non-enzymatic acylation targets. Applying this method to cancer cell lines identifies numerous candidate targets of non-enzymatic acylation, including several enzymes in lower glycolysis. Functional studies highlight malonyl-CoA as a reactive thioester metabolite that can modify and inhibit glycolytic enzyme activity. Finally, we show that synthetic thioesters can be used as novel reagents to probe non-enzymatic acylation in living cells. Our studies provide new insights into the targets and drivers of non-enzymatic acylation, and demonstrate the utility of reactivity-based methods to experimentally investigate this phenomenon in biology and disease.

Original language	English
Pages (from-to)	231-242
Number of pages	12
Journal	Cell Chemical Biology
Volume	24
Issue number	2
DOIs	https://doi.org/10.1016/j.chembiol.2017.01.002
State	Published - Feb 16 2017
Externally published	Yes

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

Keywords

Warburg effect
acetylation
acylation
epigenetics
glycolysis
malonylation
metabolism
non-enzymatic
reactivity-based protein profiling
thioester

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10.1016/j.chembiol.2017.01.002

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Kulkarni, R. A., Worth, A. J., Zengeya, T. T., Shrimp, J. H., Garlick, J. M., Roberts, A. M., Montgomery, D. C., Sourbier, C., Gibbs, B. K., Mesaros, C., Tsai, Y. C., Das, S., Chan, K. C., Zhou, M., Andresson, T., Weissman, A. M., Linehan, W. M., Blair, I. A., Snyder, N. W., & Meier, J. L. (2017). Discovering Targets of Non-enzymatic Acylation by Thioester Reactivity Profiling. Cell Chemical Biology, 24(2), 231-242. https://doi.org/10.1016/j.chembiol.2017.01.002

@article{83c3ce28aacb45a2bf7026aea65da885,

title = "Discovering Targets of Non-enzymatic Acylation by Thioester Reactivity Profiling",

abstract = "Non-enzymatic protein modification driven by thioester reactivity is thought to play a major role in the establishment of cellular lysine acylation. However, the specific protein targets of this process are largely unknown. Here we report an experimental strategy to investigate non-enzymatic acylation in cells. Specifically, we develop a chemoproteomic method that separates thioester reactivity from enzymatic utilization, allowing selective enrichment of non-enzymatic acylation targets. Applying this method to cancer cell lines identifies numerous candidate targets of non-enzymatic acylation, including several enzymes in lower glycolysis. Functional studies highlight malonyl-CoA as a reactive thioester metabolite that can modify and inhibit glycolytic enzyme activity. Finally, we show that synthetic thioesters can be used as novel reagents to probe non-enzymatic acylation in living cells. Our studies provide new insights into the targets and drivers of non-enzymatic acylation, and demonstrate the utility of reactivity-based methods to experimentally investigate this phenomenon in biology and disease.",

keywords = "Warburg effect, acetylation, acylation, epigenetics, glycolysis, malonylation, metabolism, non-enzymatic, reactivity-based protein profiling, thioester",

author = "Kulkarni, \{Rhushikesh A.\} and Worth, \{Andrew J.\} and Zengeya, \{Thomas T.\} and Shrimp, \{Jonathan H.\} and Garlick, \{Julie M.\} and Roberts, \{Allison M.\} and Montgomery, \{David C.\} and Carole Sourbier and Gibbs, \{Benjamin K.\} and Clementina Mesaros and Tsai, \{Yien Che\} and Sudipto Das and Chan, \{King C.\} and Ming Zhou and Thorkell Andresson and Weissman, \{Allan M.\} and Linehan, \{W. Marston\} and Blair, \{Ian A.\} and Snyder, \{Nathaniel W.\} and Meier, \{Jordan L.\}",

note = "Publisher Copyright: {\textcopyright} 2017",

year = "2017",

month = feb,

day = "16",

doi = "10.1016/j.chembiol.2017.01.002",

language = "English",

volume = "24",

pages = "231--242",

journal = "Cell Chemical Biology",

issn = "2451-9456",

publisher = "Elsevier Ltd.",

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}

Kulkarni, RA, Worth, AJ, Zengeya, TT, Shrimp, JH, Garlick, JM, Roberts, AM, Montgomery, DC, Sourbier, C, Gibbs, BK, Mesaros, C, Tsai, YC, Das, S, Chan, KC, Zhou, M, Andresson, T, Weissman, AM, Linehan, WM, Blair, IA, Snyder, NW & Meier, JL 2017, 'Discovering Targets of Non-enzymatic Acylation by Thioester Reactivity Profiling', Cell Chemical Biology, vol. 24, no. 2, pp. 231-242. https://doi.org/10.1016/j.chembiol.2017.01.002

TY - JOUR

T1 - Discovering Targets of Non-enzymatic Acylation by Thioester Reactivity Profiling

AU - Kulkarni, Rhushikesh A.

AU - Worth, Andrew J.

AU - Zengeya, Thomas T.

AU - Shrimp, Jonathan H.

AU - Garlick, Julie M.

AU - Roberts, Allison M.

AU - Montgomery, David C.

AU - Sourbier, Carole

AU - Gibbs, Benjamin K.

AU - Mesaros, Clementina

AU - Tsai, Yien Che

AU - Das, Sudipto

AU - Chan, King C.

AU - Zhou, Ming

AU - Andresson, Thorkell

AU - Weissman, Allan M.

AU - Linehan, W. Marston

AU - Blair, Ian A.

AU - Snyder, Nathaniel W.

AU - Meier, Jordan L.

PY - 2017/2/16

Y1 - 2017/2/16

N2 - Non-enzymatic protein modification driven by thioester reactivity is thought to play a major role in the establishment of cellular lysine acylation. However, the specific protein targets of this process are largely unknown. Here we report an experimental strategy to investigate non-enzymatic acylation in cells. Specifically, we develop a chemoproteomic method that separates thioester reactivity from enzymatic utilization, allowing selective enrichment of non-enzymatic acylation targets. Applying this method to cancer cell lines identifies numerous candidate targets of non-enzymatic acylation, including several enzymes in lower glycolysis. Functional studies highlight malonyl-CoA as a reactive thioester metabolite that can modify and inhibit glycolytic enzyme activity. Finally, we show that synthetic thioesters can be used as novel reagents to probe non-enzymatic acylation in living cells. Our studies provide new insights into the targets and drivers of non-enzymatic acylation, and demonstrate the utility of reactivity-based methods to experimentally investigate this phenomenon in biology and disease.

AB - Non-enzymatic protein modification driven by thioester reactivity is thought to play a major role in the establishment of cellular lysine acylation. However, the specific protein targets of this process are largely unknown. Here we report an experimental strategy to investigate non-enzymatic acylation in cells. Specifically, we develop a chemoproteomic method that separates thioester reactivity from enzymatic utilization, allowing selective enrichment of non-enzymatic acylation targets. Applying this method to cancer cell lines identifies numerous candidate targets of non-enzymatic acylation, including several enzymes in lower glycolysis. Functional studies highlight malonyl-CoA as a reactive thioester metabolite that can modify and inhibit glycolytic enzyme activity. Finally, we show that synthetic thioesters can be used as novel reagents to probe non-enzymatic acylation in living cells. Our studies provide new insights into the targets and drivers of non-enzymatic acylation, and demonstrate the utility of reactivity-based methods to experimentally investigate this phenomenon in biology and disease.

KW - Warburg effect

KW - acetylation

KW - acylation

KW - epigenetics

KW - glycolysis

KW - malonylation

KW - metabolism

KW - non-enzymatic

KW - reactivity-based protein profiling

KW - thioester

UR - https://www.scopus.com/pages/publications/85011304711

U2 - 10.1016/j.chembiol.2017.01.002

DO - 10.1016/j.chembiol.2017.01.002

M3 - Article

C2 - 28163016

AN - SCOPUS:85011304711

SN - 2451-9456

VL - 24

SP - 231

EP - 242

JO - Cell Chemical Biology

JF - Cell Chemical Biology

IS - 2

ER -

Discovering Targets of Non-enzymatic Acylation by Thioester Reactivity Profiling

Abstract

UN SDGs

Keywords

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