Impaired heart contractility in Apelin gene-deficient mice associated with aging and pressure overload

Keiji Kuba; Liyong Zhang; Yumiko Imai; Sara Arab; Manyin Chen; Yuichiro Maekawa; Michael Leschnik; Andreas Leibbrandt; Mato Makovic; Julia Schwaighofer; Nadine Beetz; Renata Musialek; G. Greg Neely; Vukoslav Komnenovic; Ursula Kolm; Bernhard Metzler; Romeo Ricci; Hiromitsu Hara; Arabella Meixner; Mai Nghiem; Xin Chen; Fayez Dawood; Kit Man Wong; Renu Sarao; Eva Cukerman; Akinori Kimura; Lutz Hein; Johann Thalhammer; Peter P. Liu; Josef M. Penninger

doi:10.1161/CIRCRESAHA.107.158659

Impaired heart contractility in Apelin gene-deficient mice associated with aging and pressure overload

Keiji Kuba, Liyong Zhang, Yumiko Imai, Sara Arab, Manyin Chen, Yuichiro Maekawa, Michael Leschnik, Andreas Leibbrandt, Mato Makovic, Julia Schwaighofer, Nadine Beetz, Renata Musialek, G. Greg Neely, Vukoslav Komnenovic, Ursula Kolm, Bernhard Metzler, Romeo Ricci, Hiromitsu Hara, Arabella Meixner, Mai NghiemXin Chen, Fayez Dawood, Kit Man Wong, Renu Sarao, Eva Cukerman, Akinori Kimura, Lutz Hein, Johann Thalhammer, Peter P. Liu, Josef M. Penninger

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

237 Citations (Scopus)

Abstract

Apelin constitutes a novel endogenous peptide system suggested to be involved in a broad range of physiological functions, including cardiovascular function, heart development, control of fluid homeostasis, and obesity. Apelin is also a catalytic substrate for angiotensin-converting enzyme 2, the key severe acute respiratory syndrome receptor. The in vivo physiological role of Apelin is still elusive. Here we report the generation of Apelin gene-targeted mice. Apelin mutant mice are viable and fertile, appear healthy, and exhibit normal body weight, water and food intake, heart rates, and heart morphology. Intriguingly, aged Apelin knockout mice developed progressive impairment of cardiac contractility associated with systolic dysfunction in the absence of histological abnormalities. We also report that pressure overload induces upregulation of Apelin expression in the heart. Importantly, in pressure overload-induced heart failure, loss of Apelin did not significantly affect the hypertrophy response, but Apelin mutant mice developed progressive heart failure. Global gene expression arrays and hierarchical clustering of differentially expressed genes in hearts of banded Apelin and Apelin mice showed concerted upregulation of genes involved in extracellular matrix remodeling and muscle contraction. These genetic data show that the endogenous peptide Apelin is crucial to maintain cardiac contractility in pressure overload and aging.

Original language	English
Pages (from-to)	e32-e42
Journal	Circulation research
Volume	101
Issue number	4
DOIs	https://doi.org/10.1161/CIRCRESAHA.107.158659
Publication status	Published - Aug 2007
Externally published	Yes

All Science Journal Classification (ASJC) codes

Physiology
Cardiology and Cardiovascular Medicine

UN SDGs

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

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10.1161/CIRCRESAHA.107.158659

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Kuba, K., Zhang, L., Imai, Y., Arab, S., Chen, M., Maekawa, Y., Leschnik, M., Leibbrandt, A., Makovic, M., Schwaighofer, J., Beetz, N., Musialek, R., Neely, G. G., Komnenovic, V., Kolm, U., Metzler, B., Ricci, R., Hara, H., Meixner, A., ... Penninger, J. M. (2007). Impaired heart contractility in Apelin gene-deficient mice associated with aging and pressure overload. Circulation research, 101(4), e32-e42. https://doi.org/10.1161/CIRCRESAHA.107.158659

Kuba, K, Zhang, L, Imai, Y, Arab, S, Chen, M, Maekawa, Y, Leschnik, M, Leibbrandt, A, Makovic, M, Schwaighofer, J, Beetz, N, Musialek, R, Neely, GG, Komnenovic, V, Kolm, U, Metzler, B, Ricci, R, Hara, H, Meixner, A, Nghiem, M, Chen, X, Dawood, F, Wong, KM, Sarao, R, Cukerman, E, Kimura, A, Hein, L, Thalhammer, J, Liu, PP & Penninger, JM 2007, 'Impaired heart contractility in Apelin gene-deficient mice associated with aging and pressure overload', Circulation research, vol. 101, no. 4, pp. e32-e42. https://doi.org/10.1161/CIRCRESAHA.107.158659

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title = "Impaired heart contractility in Apelin gene-deficient mice associated with aging and pressure overload",

abstract = "Apelin constitutes a novel endogenous peptide system suggested to be involved in a broad range of physiological functions, including cardiovascular function, heart development, control of fluid homeostasis, and obesity. Apelin is also a catalytic substrate for angiotensin-converting enzyme 2, the key severe acute respiratory syndrome receptor. The in vivo physiological role of Apelin is still elusive. Here we report the generation of Apelin gene-targeted mice. Apelin mutant mice are viable and fertile, appear healthy, and exhibit normal body weight, water and food intake, heart rates, and heart morphology. Intriguingly, aged Apelin knockout mice developed progressive impairment of cardiac contractility associated with systolic dysfunction in the absence of histological abnormalities. We also report that pressure overload induces upregulation of Apelin expression in the heart. Importantly, in pressure overload-induced heart failure, loss of Apelin did not significantly affect the hypertrophy response, but Apelin mutant mice developed progressive heart failure. Global gene expression arrays and hierarchical clustering of differentially expressed genes in hearts of banded Apelin and Apelin mice showed concerted upregulation of genes involved in extracellular matrix remodeling and muscle contraction. These genetic data show that the endogenous peptide Apelin is crucial to maintain cardiac contractility in pressure overload and aging.",

author = "Keiji Kuba and Liyong Zhang and Yumiko Imai and Sara Arab and Manyin Chen and Yuichiro Maekawa and Michael Leschnik and Andreas Leibbrandt and Mato Makovic and Julia Schwaighofer and Nadine Beetz and Renata Musialek and Neely, {G. Greg} and Vukoslav Komnenovic and Ursula Kolm and Bernhard Metzler and Romeo Ricci and Hiromitsu Hara and Arabella Meixner and Mai Nghiem and Xin Chen and Fayez Dawood and Wong, {Kit Man} and Renu Sarao and Eva Cukerman and Akinori Kimura and Lutz Hein and Johann Thalhammer and Liu, {Peter P.} and Penninger, {Josef M.}",

year = "2007",

month = aug,

doi = "10.1161/CIRCRESAHA.107.158659",

language = "English",

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AU - Kuba, Keiji

AU - Zhang, Liyong

AU - Imai, Yumiko

AU - Arab, Sara

AU - Chen, Manyin

AU - Maekawa, Yuichiro

AU - Leschnik, Michael

AU - Leibbrandt, Andreas

AU - Makovic, Mato

AU - Schwaighofer, Julia

AU - Beetz, Nadine

AU - Musialek, Renata

AU - Neely, G. Greg

AU - Komnenovic, Vukoslav

AU - Kolm, Ursula

AU - Metzler, Bernhard

AU - Ricci, Romeo

AU - Hara, Hiromitsu

AU - Meixner, Arabella

AU - Nghiem, Mai

AU - Chen, Xin

AU - Dawood, Fayez

AU - Wong, Kit Man

AU - Sarao, Renu

AU - Cukerman, Eva

AU - Kimura, Akinori

AU - Hein, Lutz

AU - Thalhammer, Johann

AU - Liu, Peter P.

AU - Penninger, Josef M.

PY - 2007/8

Y1 - 2007/8

N2 - Apelin constitutes a novel endogenous peptide system suggested to be involved in a broad range of physiological functions, including cardiovascular function, heart development, control of fluid homeostasis, and obesity. Apelin is also a catalytic substrate for angiotensin-converting enzyme 2, the key severe acute respiratory syndrome receptor. The in vivo physiological role of Apelin is still elusive. Here we report the generation of Apelin gene-targeted mice. Apelin mutant mice are viable and fertile, appear healthy, and exhibit normal body weight, water and food intake, heart rates, and heart morphology. Intriguingly, aged Apelin knockout mice developed progressive impairment of cardiac contractility associated with systolic dysfunction in the absence of histological abnormalities. We also report that pressure overload induces upregulation of Apelin expression in the heart. Importantly, in pressure overload-induced heart failure, loss of Apelin did not significantly affect the hypertrophy response, but Apelin mutant mice developed progressive heart failure. Global gene expression arrays and hierarchical clustering of differentially expressed genes in hearts of banded Apelin and Apelin mice showed concerted upregulation of genes involved in extracellular matrix remodeling and muscle contraction. These genetic data show that the endogenous peptide Apelin is crucial to maintain cardiac contractility in pressure overload and aging.

AB - Apelin constitutes a novel endogenous peptide system suggested to be involved in a broad range of physiological functions, including cardiovascular function, heart development, control of fluid homeostasis, and obesity. Apelin is also a catalytic substrate for angiotensin-converting enzyme 2, the key severe acute respiratory syndrome receptor. The in vivo physiological role of Apelin is still elusive. Here we report the generation of Apelin gene-targeted mice. Apelin mutant mice are viable and fertile, appear healthy, and exhibit normal body weight, water and food intake, heart rates, and heart morphology. Intriguingly, aged Apelin knockout mice developed progressive impairment of cardiac contractility associated with systolic dysfunction in the absence of histological abnormalities. We also report that pressure overload induces upregulation of Apelin expression in the heart. Importantly, in pressure overload-induced heart failure, loss of Apelin did not significantly affect the hypertrophy response, but Apelin mutant mice developed progressive heart failure. Global gene expression arrays and hierarchical clustering of differentially expressed genes in hearts of banded Apelin and Apelin mice showed concerted upregulation of genes involved in extracellular matrix remodeling and muscle contraction. These genetic data show that the endogenous peptide Apelin is crucial to maintain cardiac contractility in pressure overload and aging.

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JO - Circulation Research

JF - Circulation Research

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ER -

Impaired heart contractility in Apelin gene-deficient mice associated with aging and pressure overload

Abstract

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