Transcriptomic profiling of the canine tachycardia-induced heart failure model: global comparison to human and murine heart failure

Zhong, Gongxun; Xu, Hai; DiSilvestre, Deborah; Halperin, Victoria L.; Tunin, Richard S.; Tian, Yanli; Yu, Wayne; Winslow, Raimond L.; Tomaselli, Gordon F.

doi:10.1016/j.yjmcc.2005.08.002

Cited by 48 publications

(32 citation statements)

References 41 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…In this sense, the reduced expression of both ankrd1 (Zou et al, 1997) and mlc2v (Lyons et al, 1995) in a Nkx2.5-deficient background does not correlate well with the demonstration that ANKRD1/CARP inhibits the mlc2v reporter gene activity in vitro. Moreover, mlc2v was not identified as the gene downregulated in the LV myocardium of MLP-deficient mice (Gao et al, 2006), and no decreased levels of MLC2v and TNNC were detected in MLP -/-hearts characterized by very high levels of ankrd1 expression as compared to controls . In patients, end-stage DCM is associated with a marked activation of the ankrd1 (see Table 2) and selective upregulation (not inhibition) of the mlc2v gene in failing as compared to non-failing LV myocardium (Haase et al, 2002).…”

Section: Ankrd1 As a Negative Regulator Of Cardiac Gene Expression: Imentioning

confidence: 87%

The enigmatic role of the ankyrin repeat domain 1 gene in heart development and disease

Михайлов¹,

Torrado²

2008

Int. J. Dev. Biol.

View full text Add to dashboard Cite

It has been proposed that the ankyrin repeat domain 1 (ANKRD1) factor (also known as CARP) plays a critical role in transcriptional regulation, myofibrillar assembly and stretch sensing during heart development and cardiac insults. ANKRD1/CARP has also been reported to negatively regulate cardiac gene expression in cell-based promoter-reporter assays. Consequently, rapid up-regulation of the ankrd1 gene in myocardium in response to developmental stimuli or pathological insults has tended to be interpreted in the context of the inhibitory effects of ANKRD1 on cardiomyocyte gene expression. Surprisingly, a total ankrd1 knockout resulted in a complete lack of phenotype, suggesting that ANKRD1/CARP is not crucial for regulation of cardiac gene expression in vivo. In this essay, we summarize (1) the accumulated evidence for the apparent multifunctional properties of this enigmatic protein, (2) the distinct chamber-dependent regulation of ankrd1 expression patterns in the heart, both during development and cardiac injury, and (3) ANKRD1 involvement in networks regulating adaptation of the myocardium to stress. Whenever feasible, we present the results obtained in patients together with those obtained in the relevant animal and cellular models. A close examination of the findings still fails to define ANKRD1 as a negative regulator of cardiac gene expression in vivo, but rather indicates that its augmented expression can represent an adaptive response of the myocardium to stress both during development and various heart insults.

show abstract

Section: Ankrd1 As a Negative Regulator Of Cardiac Gene Expression: Imentioning

confidence: 87%

The enigmatic role of the ankyrin repeat domain 1 gene in heart development and disease

Михайлов¹,

Torrado²

2008

Int. J. Dev. Biol.

View full text Add to dashboard Cite

show abstract

“…The present study meets in part those criteria. A microarray analysis on cardiac tissue from dogs with pacing-induced heart failure was performed by Gao et al (7). By employing a less specific human 20K cDNA microarray and by using also existing databases, they compared gene expression profiles of normal and end-stage failing canine hearts as well as human and murine models of heart failure.…”

Section: Discussionmentioning

confidence: 99%

Altered expression of a limited number of genes contributes to cardiac decompensation during chronic ventricular tachypacing in dogs

Ojaimi

Qanud

Hintze

et al. 2007

Physiological Genomics

View full text Add to dashboard Cite

Ojaimi C, Qanud K, Hintze TH, Recchia FA. Altered expression of a limited number of genes contributes to cardiac decompensation during chronic ventricular tachypacing in dogs. Physiol Genomics 29: 76 -83, 2007. First published December 12, 2006; doi:10.1152/physiolgenomics.00159.2006.-Our aim was to determine the changes in the gene expression profile occurring during the transition from compensated dysfunction (CD) to decompensated heart failure (HF) in pacing-induced dilated cardiomyopathy. Twelve chronically instrumented dogs underwent left ventricular pacing at 210 beats/min for 3 wk and at 240 beats thereafter, and four normal dogs were used as control. The transition from CD to HF occurred between the 3rd and 4th wk of pacing, with end-stage HF at 28 Ϯ 1 days. RNA was extracted from left ventricular tissue at control and 3 and 4 wk of pacing (n ϭ 4) and tested with the Affymetrix Canine Array. We found 509 genes differentially expressed in CD vs. control (P Յ 0.05, fold change ՆϮ2), with 362 increasing and 147 decreasing; 526 genes were differentially expressed in HF vs. control (P Յ 0.05; fold change ՆϮ2), with 439 increasing and 87 decreasing. To better understand the transition, we compared gene alterations at 3 vs. 4 wk pacing and found that only 30 genes differed (P Յ 0.05; fold change of Ϯ2). We conclude that a number of processes including normalization of gene regulation during decompensation, appearance of new upregulated genes and maintenance of gene expression all contribute to the transition to overt heart failure with an unexpectedly small number of genes differentially regulated. heart failure; pacing dog; microarray OVER THE PAST YEARS OTHER authors and we have used chronically instrumented dogs with high-frequency cardiac pacing to study pathophysiological and molecular mechanisms related to the development of dilated cardiomyopathy. This model of congestive heart failure is characterized by a very predictable evolution and reproduces many key features of the human disease, including progressive ventricular chambers dilation and wall thinning, decreased contractility, neurohormonal activation, beta adrenergic desensitization, and altered metabolism (19). In particular, we could determine functional and metabolic changes occurring only between the 3rd and 4th wk of pacing, i.e., during the transition from compensated to decompensated failure (25). The marked cardiac functional impairment and systemic deterioration observed during this relatively short phase of transition suggests the occurrence of profound molecular alterations. Their identification would provide notable insights in the pathophysiology and clinical management of heart failure. Unfortunately, given the complexity of the heart failure syndrome, such molecular changes are likely very numerous and interrelated, while most studies have been focused on single or selected groups of molecules, due to the limitations of the classical methods of analysis.More recently, global gene transcript profiling has emerged as a powerful tool f...

show abstract

“…Cardiac chamber-specific gene expression patterns exist throughout development 17 diseased 21,22 myocardium. Cardiac overexpression of junctin, an integral membrane protein colocalizing with ryanodine receptors and calsequestrin, causes markedly enlarged, severely fibrotic atria with much more limited ventricular fibrosis.…”

Section: Evidence For Differential Atrial-ventricular Fibrotic Remodementioning

confidence: 99%

Differential Behaviors of Atrial Versus Ventricular Fibroblasts

et al. 2008

View full text Add to dashboard Cite

Background-In various heart disease paradigms, atria show stronger fibrotic responses than ventricles. The possibility that atrial and ventricular fibroblasts respond differentially to pathological stimuli has not been examined. Methods and Results-We compared various morphological, secretory, and proliferative response indexes of canine atrial versus ventricular fibroblasts. Cultured atrial fibroblasts showed faster cell surface area increases, distinct morphology at confluence, and greater ␣-smooth muscle actin expression than ventricular fibroblasts. Atrial fibroblast proliferation ([ 3 H]thymidine incorporation) responses were consistently greater for a range of growth factors, including fetal bovine serum, platelet-derived growth factor (PDGF), basic fibroblast growth factor, angiotensin II, endothelin-1, and transforming growth factor-␤ 1 . Normal atrial tissue showed larger myofibroblast density compared with ventricular tissue, and the difference was exaggerated by congestive heart failure. Congestive heart failure atria showed larger fractions of fibroblasts in mitotic phases compared with ventricles and displayed enhanced gene expression of fibroblast-selective markers (collagen-1, collagen-3, fibronectin-1). Gene microarrays revealed 225 differentially expressed transcript probe sets between paired atrial and ventricular fibroblast samples, including extracellular matrix (eg, fibronectin, laminin, fibulin), cell signaling (PDGF, PDGF receptor, angiopoietin, vascular endothelial growth factor), structure (keratin), and metabolism (xanthine dehydrogenase) genes, identifying PDGF as a candidate contributor to atrial-ventricular fibroblast differences. PDGF receptor gene expression was greater in normal atrium compared with ventricle, and congestive heart failure differentially enhanced atrial versus ventricular PDGF and PDGF receptor gene expression. PDGF receptor protein expression and ␣-smooth muscle actin protein expression were enhanced in isolated congestive heart failure fibroblasts. The PDGF receptor tyrosine kinase inhibitor AG1295 eliminated fetal bovine serum-and transforming growth factor-␤ 1 -stimulated atrial-ventricular fibroblast proliferative response differences. Conclusions-Atrial

show abstract

Transcriptomic profiling of the canine tachycardia-induced heart failure model: global comparison to human and murine heart failure

Cited by 48 publications

References 41 publications

The enigmatic role of the ankyrin repeat domain 1 gene in heart development and disease

The enigmatic role of the ankyrin repeat domain 1 gene in heart development and disease

Altered expression of a limited number of genes contributes to cardiac decompensation during chronic ventricular tachypacing in dogs

Differential Behaviors of Atrial Versus Ventricular Fibroblasts

Contact Info

Product

Resources

About