Identification of Histone Lysine Acetoacetylation as a Dynamic Post-Translational Modification Regulated by HBO1

Yan Gao; Xinlei Sheng; Doudou Tan; Sun Joo Kim; Soyoung Choi; Sanjita Paudel; Taeho Lee; Cong Yan; Minjia Tan; Kyu Min Kim; Sam Seok Cho; Sung Hwan Ki; He Huang; Yingming Zhao; Sangkyu Lee

doi:10.1002/advs.202300032

Identification of Histone Lysine Acetoacetylation as a Dynamic Post-Translational Modification Regulated by HBO1

Yan Gao
, Xinlei Sheng
, Doudou Tan
, Sun Joo Kim
, Soyoung Choi
, Sanjita Paudel
, Taeho Lee
, Cong Yan
, Minjia Tan
, Kyu Min Kim
, Sam Seok Cho
, Sung Hwan Ki
, He Huang
, Yingming Zhao
, Sangkyu Lee

Department of Dentistry

Kyungpook National University
The University of Chicago
CAS - Shanghai Institute of Materia Medica
Chosun University
University of Chinese Academy of Sciences
Sungkyunkwan University

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

27 Scopus citations

Abstract

Ketone bodies have long been known as a group of lipid-derived alternative energy sources during glucose shortages. Nevertheless, the molecular mechanisms underlying their non-metabolic functions remain largely elusive. This study identified acetoacetate as the precursor for lysine acetoacetylation (Kacac), a previously uncharacterized and evolutionarily conserved histone post-translational modification. This protein modification is comprehensively validated using chemical and biochemical approaches, including HPLC co-elution and MS/MS analysis using synthetic peptides, Western blot, and isotopic labeling. Histone Kacac can be dynamically regulated by acetoacetate concentration, possibly via acetoacetyl-CoA. Biochemical studies show that HBO1, traditionally known as an acetyltransferase, can also serve as an acetoacetyltransferase. In addition, 33 Kacac sites are identified on mammalian histones, depicting the landscape of histone Kacac marks across species and organs. In summary, this study thus discovers a physiologically relevant and enzymatically regulated histone mark that sheds light on the non-metabolic functions of ketone bodies.

Original language	English
Article number	2300032
Journal	Advanced Science
Volume	10
Issue number	25
DOIs	https://doi.org/10.1002/advs.202300032
State	Published - 5 Sep 2023

Keywords

HBO1
acetoacetate
acetoacetylation
epigenetics
histone marks
novel histone modification

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10.1002/advs.202300032

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title = "Identification of Histone Lysine Acetoacetylation as a Dynamic Post-Translational Modification Regulated by HBO1",

abstract = "Ketone bodies have long been known as a group of lipid-derived alternative energy sources during glucose shortages. Nevertheless, the molecular mechanisms underlying their non-metabolic functions remain largely elusive. This study identified acetoacetate as the precursor for lysine acetoacetylation (Kacac), a previously uncharacterized and evolutionarily conserved histone post-translational modification. This protein modification is comprehensively validated using chemical and biochemical approaches, including HPLC co-elution and MS/MS analysis using synthetic peptides, Western blot, and isotopic labeling. Histone Kacac can be dynamically regulated by acetoacetate concentration, possibly via acetoacetyl-CoA. Biochemical studies show that HBO1, traditionally known as an acetyltransferase, can also serve as an acetoacetyltransferase. In addition, 33 Kacac sites are identified on mammalian histones, depicting the landscape of histone Kacac marks across species and organs. In summary, this study thus discovers a physiologically relevant and enzymatically regulated histone mark that sheds light on the non-metabolic functions of ketone bodies.",

keywords = "HBO1, acetoacetate, acetoacetylation, epigenetics, histone marks, novel histone modification",

author = "Yan Gao and Xinlei Sheng and Doudou Tan and Kim, \{Sun Joo\} and Soyoung Choi and Sanjita Paudel and Taeho Lee and Cong Yan and Minjia Tan and Kim, \{Kyu Min\} and Cho, \{Sam Seok\} and Ki, \{Sung Hwan\} and He Huang and Yingming Zhao and Sangkyu Lee",

note = "Publisher Copyright: {\textcopyright} 2023 The Authors. Advanced Science published by Wiley-VCH GmbH.",

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doi = "10.1002/advs.202300032",

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T1 - Identification of Histone Lysine Acetoacetylation as a Dynamic Post-Translational Modification Regulated by HBO1

AU - Gao, Yan

AU - Sheng, Xinlei

AU - Tan, Doudou

AU - Kim, Sun Joo

AU - Choi, Soyoung

AU - Paudel, Sanjita

AU - Lee, Taeho

AU - Yan, Cong

AU - Tan, Minjia

AU - Kim, Kyu Min

AU - Cho, Sam Seok

AU - Ki, Sung Hwan

AU - Huang, He

AU - Zhao, Yingming

AU - Lee, Sangkyu

PY - 2023/9/5

Y1 - 2023/9/5

N2 - Ketone bodies have long been known as a group of lipid-derived alternative energy sources during glucose shortages. Nevertheless, the molecular mechanisms underlying their non-metabolic functions remain largely elusive. This study identified acetoacetate as the precursor for lysine acetoacetylation (Kacac), a previously uncharacterized and evolutionarily conserved histone post-translational modification. This protein modification is comprehensively validated using chemical and biochemical approaches, including HPLC co-elution and MS/MS analysis using synthetic peptides, Western blot, and isotopic labeling. Histone Kacac can be dynamically regulated by acetoacetate concentration, possibly via acetoacetyl-CoA. Biochemical studies show that HBO1, traditionally known as an acetyltransferase, can also serve as an acetoacetyltransferase. In addition, 33 Kacac sites are identified on mammalian histones, depicting the landscape of histone Kacac marks across species and organs. In summary, this study thus discovers a physiologically relevant and enzymatically regulated histone mark that sheds light on the non-metabolic functions of ketone bodies.

AB - Ketone bodies have long been known as a group of lipid-derived alternative energy sources during glucose shortages. Nevertheless, the molecular mechanisms underlying their non-metabolic functions remain largely elusive. This study identified acetoacetate as the precursor for lysine acetoacetylation (Kacac), a previously uncharacterized and evolutionarily conserved histone post-translational modification. This protein modification is comprehensively validated using chemical and biochemical approaches, including HPLC co-elution and MS/MS analysis using synthetic peptides, Western blot, and isotopic labeling. Histone Kacac can be dynamically regulated by acetoacetate concentration, possibly via acetoacetyl-CoA. Biochemical studies show that HBO1, traditionally known as an acetyltransferase, can also serve as an acetoacetyltransferase. In addition, 33 Kacac sites are identified on mammalian histones, depicting the landscape of histone Kacac marks across species and organs. In summary, this study thus discovers a physiologically relevant and enzymatically regulated histone mark that sheds light on the non-metabolic functions of ketone bodies.

KW - HBO1

KW - acetoacetate

KW - acetoacetylation

KW - epigenetics

KW - histone marks

KW - novel histone modification

UR - https://www.scopus.com/pages/publications/85163683464

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DO - 10.1002/advs.202300032

M3 - Article

C2 - 37382194

AN - SCOPUS:85163683464

SN - 2198-3844

VL - 10

JO - Advanced Science

JF - Advanced Science

IS - 25

M1 - 2300032

ER -

Identification of Histone Lysine Acetoacetylation as a Dynamic Post-Translational Modification Regulated by HBO1

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