Supraphysiologic Administration of GDF11 Induces Cachexia in Part by Upregulating GDF15

被引：62

作者：

Jones, Juli E. ^{[1
]}

Cadena, Samuel M. ^{[1
]}

Gong, Chenguang ^{[1
]}

Wang, Xiaomei ^{[1
]}

Chen, Zhiping ^{[1
]}

Wang, Sharon X. ^{[1
]}

Vickers, Chad ^{[1
]}

Chen, Hong ^{[1
]}

Lach-Trifilieff, Estelle ^{[2
]}

Hadcock, John R. ^{[1
]}

Glass, David J. ^{[1
]}

机构：

[1] Novartis Inst Biomed Res, 181 Massachusetts Ave, Cambridge, MA 02139 USA

[2] Novartis Inst Biomed Res, CH-4005 Basel, Switzerland

来源：

CELL REPORTS | 2018年 / 22卷 / 06期

关键词：

TGF-BETA SUPERFAMILY; DIFFERENTIATION FACTOR 11; SKELETAL-MUSCLE; WEIGHT-LOSS; MASS; MYOSTATIN; RECEPTOR; AGE; IDENTIFICATION; HYPERTROPHY;

D O I：

10.1016/j.celrep.2018.01.044

中图分类号：

Q2 [细胞生物学];

学科分类号：

071009 ; 090102 ;

摘要：

The age-related effects of GDF11 have been a subject of controversy. Here, we find that elevated GDF11 causes signs of cachexia in mice: reduced food intake, body weight, and muscle mass. GDF11 also elicited a significant elevation in plasma Activin A, previously shown to contribute to the loss of skeletal muscle. The effects of GDF11 on skeletal muscle could be reversed by administration of antibodies to the Activin type II receptors. In addition to the effects on muscle, GDF11 increased plasma GDF15, an anorectic agent. The anorexia, but not the muscle loss, could be reversed with a GDF15-neutralizing antibody. GDF15 upregulation is due to GDF11-induced recruitment of SMAD2/3 to the GDF15 promoter. Inhibition of GDF15 can restore appetite but cannot restore the GDF11-induced loss of muscle mass, which requires blockade of ActRII signaling. These findings are relevant for treatment of cachexia.

引用

页码：1522 / 1530

页数：9

共 50 条

[31] Mitochondrial stress and GDF15 in the pathophysiology of sepsis
Fujita, Yasunori
Ito, Masafumi
Ohsawa, Ikuroh
ARCHIVES OF BIOCHEMISTRY AND BIOPHYSICS, 2020, 696
[32] Crystal structure of human GDF11
Padyana, Anil K.
Vaidialingam, Bhamini
Hayes, David B.
Gupta, Priyanka
Franti, Michael
Farrow, Neil A.
ACTA CRYSTALLOGRAPHICA SECTION F-STRUCTURAL BIOLOGY COMMUNICATIONS, 2016, 72 : 160 - 164
[33] GDF11 induces mild hepatic fibrosis independent of metabolic health
Frohlich, Jan
Kovacovicova, Kristina
Mazza, Tommaso
Emma, Maria R.
Cabibi, Daniela
Foti, Michelangelo
Sobolewski, Cyril
Oben, Jude A.
Peyrou, Marion
Villarroya, Francesc
Soresi, Maurizio
Rezzani, Rita
Ello, Meichiorre Cery
Bonomini, Francesca
Alisi, Anna
Vinciguerra, Manlio
AGING-US, 2020, 12 (20): : 20024 - 20046
[34] GDF11: a New Member of TGF-β Superfamily
Li Qian
Hao Zhi-Ming
PROGRESS IN BIOCHEMISTRY AND BIOPHYSICS, 2015, 42 (07) : 616 - 623
[35] Exogenous GDF11 induces cardiac and skeletal muscle dysfunction and wasting
Teresa A. Zimmers
Yanling Jiang
Meijing Wang
Tiffany W. Liang
Joseph E. Rupert
Ernie D. Au
Francesco E. Marino
Marion E. Couch
Leonidas G. Koniaris
Basic Research in Cardiology, 2017, 112
[36] GDF15 mediates the metabolic effects of PPARβ/δ by activating AMPK
Aguilar-Recarte, David
Barroso, Emma
Guma, Anna
Pizarro-Delgado, Javier
Pena, Lucia
Ruart, Maria
Palomer, Xavier
Wahli, Walter
Vazquez-Carrera, Manuel
CELL REPORTS, 2021, 36 (06):
[37] Senescent Fibroblast-Derived GDF15 Induces Skin Pigmentation
Kim, Yeongeun
Kang, Bogyeong
Kim, Jin Cheol
Park, Tae Jun
Kang, Hee Young
JOURNAL OF INVESTIGATIVE DERMATOLOGY, 2020, 140 (12) : 2478 - +
[38] GDF11 Does Not Rescue Aging-Related Pathological Hypertrophy
Smith, Shavonn C.
Zhang, Xiaoxiao
Zhang, Xiaoying
Gross, Polina
Starosta, Timothy
Mohsin, Sadia
Franti, Michael
Gupta, Priyanka
Hayes, David
Myzithras, Maria
Kahn, Julius
Tanner, James
Weldon, Steven M.
Khalil, Ashraf
Guo, Xinji
Sabri, Abdelkarim
Chen, Xiongwen
MacDonnell, Scott
Houser, Steven R.
CIRCULATION RESEARCH, 2015, 117 (11) : 926 - 932
[39] Progress in the relationship between GDF11 and depression
Jin, Xiang
Guan, Wei
LIFE SCIENCES, 2024, 341
[40] GDF11 is increased in patients with aplastic anemia
Dong, Xifeng
Han, Yu
Abeysekera, Iruni Roshanie
Shao, Zonghong
Wang, Huaquan
HEMATOLOGY, 2019, 24 (01) : 331 - 336

← 1 2 3 4 5 →