Gene expression and phenotypic characterization of mouse heart after chronic constant or intermittent hypoxia

doi:10.1152/physiolgenomics.00217.2004

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Gene expression and phenotypic characterization of mouse heart after chronic constant or intermittent hypoxia

Chenhao Fan ¹, Dumitru A. Iacobas ², Dan Zhou ¹, Qiaofang Chen ¹, James K. Lai ³, Orit Gavrialov ¹ and Gabriel G. Haddad ¹^,2

¹ Departments of Pediatrics
² Neuroscience, Albert Einstein College of Medicine, Bronx, New York
³ Department of Pharmaceutical Sciences, Idaho State University College of Pharmacy, Pocatello, Idaho

Chronic constant hypoxia (CCH), such as in pulmonary diseasesor high altitude, and chronic intermittent hypoxia (CIH), suchas in sleep apnea, can lead to major changes in the heart. Molecularmechanisms underlying these cardiac alterations are not wellunderstood. We hypothesized that changes in gene expressioncould help to delineate such mechanisms. The current study useda neonatal mouse model in CCH or CIH combined with cDNA microarraysto determine changes in gene expression in the CCH or CIH mouseheart. Both CCH and CIH induced substantial alterations in geneexpression. In addition, a robust right ventricular hypertrophyand cardiac enlargement was found in CCH- but not in CIH-treatedmouse heart. On one hand, upregulation in RNA and protein levelsof eukaryotic translation initiation factor-2 ${alpha}$ and -4E (eIF-2 ${alpha}$ and eIF-4E) was found in CCH, whereas eIF-4E was downregulatedin 1- and 2-wk CIH, suggesting that eIF-4E is likely to playan important role in the cardiac hypertrophy observed in CCH-treatedmice. On the other hand, the specific downregulation of heartdevelopment-related genes (e.g., notch gene homolog-1, MAD homolog-4)and the upregulation of proteolysis genes (e.g., calpain-5)in the CIH heart can explain the lack of hypertrophy in CIH.Interestingly, apoptosis was enhanced in CCH but not CIH, andthis was correlated with an upregulation of proapoptotic genesand downregulation of anti-apoptotic genes in CCH. In summary,our results indicate that 1) the pattern of gene response toCCH is different from that of CIH in mouse heart, and 2) theidentified expression differences in certain gene groups arehelpful in dissecting mechanisms responsible for phenotypesobserved.

patterns of hypoxia; cardiac hypertrophy; cDNA microarray; apoptosis; initiation factors

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