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Abstract

Tetralogy of fallot (TOF) is one of the most prevalent types of congenital heart diseases. As a category of bioactive molecules, peptides have been proved to participate in various biological processes. However, the role of endogenous peptides in the pathogenesis of TOF has not been studied. In this study, we performed a comparative peptidomic profile in the fetal heart of TOF and the control group for the first time by liquid chromatography-tandem mass spectrometry. Our data demonstrated that a total of 201 peptides derived from 176 precursor proteins were differentially expressed in the heart tissues of TOF fetuses compared with normal controls, including 41 upregulated peptides and 160 downregulated peptides. After analyzing the characteristics of these differentially expressed peptides and their precursor proteins, we found that these peptides were potentially involved in different biological processes, especially cardiogenesis and congenital anomaly of the cardiovascular system. Interestingly, we detected several extracellular matrix-derived peptides involved in our differentially expressed peptidomic profile. In summary, our study constructed a comparative peptidomic profile from the heart tissues of TOF fetuses and normal controls, and it identified a series of peptides that could potentially participate in heart development and TOF formation. The emergence of our peptidomics study indicated a new perspective to explore the pathogenesis of abnormal heart morphology, especially TOF.

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References

Apitz

, Webb

G.D.

, and Redington

A.N.

(2009). Tetralogy of fallot. Lancet, 374, 1462–1471.

Baggerman

, Boonen

, Verleyen

, De Loof

, and Schoofs

(2005). Peptidomic analysis of the larval Drosophila melanogaster central nervous system by two-dimensional capillary liquid chromatography quadrupole time-of-flight mass spectrometry. J Mass Spectrom, 40, 250–260.

Bauer

R.C.

, Laney

A.O.

, Smith

, Geffen

, Morrissette

J.J.D.

, Woyciechowski

, et al. (2010). Jagged1 (JAG1) mutations in patients with tetralogy of fallot or pulmonic stenosis. Hum Mutat, 31, 594–601.

Bidlingmaier

, and Freda

P.U.

(2010). Measurement of human growth hormone by immunoassays: current status, unsolved problems and clinical consequences. Growth Horm Igf Res, 20, 19–25.

Boersema

P.J.

, Raijmakers

, Lemeer

, Mohammed

, and Heck

A.J.R.

(2009). Multiplex peptide stable isotope dimethyl labeling for quantitative proteomics. Nat Protoc, 4, 484–494.

Café-Mendes

C.C.

, Ferro

E.S.

, Torrão

A.S.

, Crunfli

, Rioli

, Schmitt

, et al. (2016). Peptidomic analysis of the anterior temporal lobe and corpus callosum from schizophrenia patients. J Proteomics, 151, 97–105.

Cui

X.W.

, Li

, Yang

, You

L.H.

, Wang

, Shi

C.M.

, et al. (2016). Peptidome analysis of human milk from women delivering macrosomic fetuses reveals multiple means of protection for infants. Oncotarget, 7, 63514–63525.

Dallas

D.C.

, Guerrero

, Parker

E.A.

, Robinson

R.C.

, Gan

J.N.

, German

J.B.

, et al. (2015). Current peptidomics: applications, purification, identification, quantification, and functional analysis. Proteomics, 15, 1026–1038.

Deacon

C.F.

, and Holst

J.J.

(2009). Immunoassays for the incretin hormones GIP and GLP-1. Best Pract Res Cl En, 23, 425–432.

10.

Di Meo

, Batruch

, Yousef Arsani

, Pasic Maria

, Diamandis Eleftherios

, and Yousef George

(2017). An integrated proteomic and peptidomic assessment of the normal human urinome. Clin Chem Lab Med, 55, 237–247.

11.

Fomovsky

G.M.

, Thomopoulos

, and Holmes

J.W.

(2010). Contribution of extracellular matrix to the mechanical properties of the heart. J Mol Cell Cardiol, 48, 490–496.

12.

Garg

, Kathiriya

I.S.

, Barnes

, Schluterman

M.K.

, King

I.N.

, Butler

C.A.

, et al. (2003). GATA4 mutations cause human congenital heart defects and reveal an interaction with TBX5. Circulation, 108, 141–142.

13.

Ghorbel

M.T.

, Cherif

, Jenkins

, Mokhtari

, Kenny

, Angelini

G.D.

, et al. (2010). Transcriptomic analysis of patients with tetralogy of Fallot reveals the effect of chronic hypoxia on myocardial gene expression. J Thorac Cardiov Sur, 140, 337–345.

14.

Goldmuntz

, Geiger

, and Benson

D.W.

(2001). NKX2.5 mutations in patients with tetralogy of Fallot. Circulation, 104, 2565–2568.

15.

Greenway

S.C.

, Pereira

A.C.

, Lin

J.C.

, DePalma

S.R.

, Israel

S.J.

, Mesquita

S.M.

, et al. (2009). De novo copy number variants identify new genes and loci in isolated sporadic tetralogy of Fallot. Nat Genet, 41, 931–935.

16.

Grutter

, Alfieri

, and Parisi

(2013). Brain natriuretic peptide level in a small series of children and grown-ups with congenital heart defects with chronic cardiac failure. Cardiol Young, 23, 447–449.

17.

Hayakawa

, Landuyt

, Baggerman

, Cuyvers

, Lavigne

, Luyten

, et al. (2013). Peptidomic analysis of human reflex tear fluid. Peptides, 42, 63–69.

18.

Hoffman

J.I.E.

, and Kaplan

(2002). The incidence of congenital heart disease. J Am Coll Cardiol, 39, 1890–1900.

19.

Hummon

A.B.

, Richmond

T.A.

, Verleyen

, Baggerman

, Huybrechts

, Ewing

M.A.

, et al. (2006). From the genome to the proteome: uncovering peptides in the Apis brain. Science, 314, 647–649.

20.

Hynes

R.O.

(2009). The extracellular matrix: not just pretty fibrils. Science, 326, 1216–1219.

21.

Ivanov

V.T.

, and Yatskin

O.N.

(2005). Peptidomics: a logical sequel to proteomics. Expert Rev Proteomic, 2, 463–473.

22.

Ivy

D.D.

, Kinsella

J.P.

, Wolfe

R.R.

, and Abman

S.H.

(1996). Atrial natriuretic peptide and nitric oxide in children with pulmonary hypertension after surgical repair of congenital heart disease. Am J Cardiol, 77, 102–105.

23.

H.S.

, and Dixon

I.M.C.

(1996). Extracellular matrix and cardiovascular diseases. Can J Cardiol, 12, 1259–1267.

24.

Karamlou

, McCrindle

B.W.

, and Williams

W.G.

(2006). Surgery insight: late complications following repair of tetralogy of Fallot and related surgical strategies for management. Nat Clin Pract Card, 3, 611–622.

25.

Kassiri

, and Khokha

(2005). Myocardial extra-cellular matrix and its regulation by metalloproteinases and their inhibitors. Thromb Haemost, 93, 212–219.

26.

Kramer

, Green

, Pollard

, and Tugendreich

(2014). Causal analysis approaches in Ingenuity Pathway Analysis. Bioinformatics, 30, 523–530.

27.

, Wu

L.J.

, Gu

, Chen

Y.M.

, Zhang

Q.J.

, Li

, et al. (2016). Peptidomic analysis of amniotic fluid for identification of putative bioactive peptides in ventricular septal defect. Cell Physiol Biochem, 38, 1999–2014.

28.

Lone

A.M.

, Kim

Y.G.

, and Saghatelian

(2013). Peptidomics methods for the identification of peptidase-substrate interactions. Curr Opin Chem Biol, 17, 83–89.

29.

Maduna

, and Lelievre

(2016). Neuropeptides shaping the central nervous system development: spatiotemporal actions of VIP and PACAP through complementary signaling pathways. J Neurosci Res, 94, 1472–1487.

30.

Meek

C.L.

, Lewis

H.B.

, Reimann

, Gribble

F.M.

, and Park

A.J.

(2016). The effect of bariatric surgery on gastrointestinal and pancreatic peptide hormones. Peptides, 77, 28–37.

31.

Merscher

, Funke

, Epstein

J.A.

, Heyer

, Puech

, Lu

M.M.

, et al. (2001). TBX1 is responsible for cardiovascular defects in Velo-Cardio-Facial/DiGeorge syndrome. Cell, 104, 619–629.

32.

Mihardja

S.S.

, Gao

D.W.

, Sievers

R.E.

, Fang

Q.Z.

, Feng

J.J.

, Wang

J.M.

, et al. (2010). Targeted in vivo extracellular matrix formation promotes neovascularization in a rodent model of myocardial infarction. PLoS One 5, e10384.

33.

Narayana

J.L.

, and Chen

J.Y.

(2015). Antimicrobial peptides: possible anti-infective agents. Peptides, 72, 88–94.

34.

Petricoin

E.F.

, Belluco

, Araujo

R.P.

, and Liotta

L.A.

(2006). The blood peptidome: a higher dimension of information content for cancer biomarker discovery. Nat Rev Cancer, 6, 961–967.

35.

Schulte

, Tammen

, Selle

, and Schulz-Knappe

(2005). Peptides in body fluids and tissues as markers of disease. Expert Rev Mol Diagn, 5, 145–157.

36.

Schulz-Knappe

, Zucht

H.D.

, Heine

, Jurgens

, Hess

, and Schrader

(2001). Peptidomics: the comprehensive analysis of peptides in complex biological mixtures. Comb Chem High T Scr, 4, 207–217.

37.

Soloviev

, and Finch

(2006). Peptidomics: bridging the gap between proteome and metabolome. Proteomics, 6, 744–747.

38.

Sugimoto

, Masutani

, Seki

, Kajino

, Fujieda

, and Senzaki

(2009). High serum levels of procollagen type III N-terminal amino peptide in patients with congenital heart disease. Heart, 95, 2023–2028.

39.

Svensson

, Skold

, Svenningsson

, and Andren

P.E.

(2003). Peptidomics-based discovery of novel neuropeptides. J Proteome Res, 2, 213–219.

40.

Tinoco

A.D.

, and Saghatelian

(2011). Investigating endogenous peptides and peptidases using peptidomics. Biochemistry, 50, 7447–7461.

41.

Wan

, Cui

X.W.

, Zhang

, Fu

Z.Y.

, Guo

X.R.

, Sun

L.Z.

, et al. (2013). Peptidome analysis of human skim milk in term and preterm milk. Biochem Bioph Res Co, 438, 236–241.

42.

Xia

, Hong

H.F.

, Ye

L.C.

, Wang

Y.L.

, Chen

H.W.

, and Liu

J.F.

(2013). Label-free quantitative proteomic analysis of right ventricular remodeling in infant Tetralogy of Fallot patients. J Proteomics, 84, 78–91.

43.

Zhu

P.H.

, Bowden

, Du

, and Marshall

J.G.

(2011). Mass spectrometry of peptides and proteins from human blood. Mass Spectrom Rev, 30, 685–732.

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Peptidomic Analysis of Fetal Heart Tissue for Identification of Endogenous Peptides Involved in Tetralogy of Fallot

Abstract

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