Mitochondrial mRNA translation initiation contributes to oxidative metabolism in the myocardia of aged, obese mice

Mitochondrial mRNA translation initiation contributes to oxidative metabolism in the myocardia of aged, obese mice

Being both advanced in age and obese each contribute to cardiac hypertrophy in a unique manner. Electron transport complexes I and IV are implicated in deficient electron transport during cardiomyopathies and contain the majority of protein subunits that are transcribed and translated by machinery l...

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Veröffentlicht in:Experimental gerontology 2019-07, Vol.121, p.62-70
Hauptverfasser: Lee, David E., Perry, Richard A., Brown, Jacob L., Rosa-Caldwell, Megan E., Brown, Lemuel A., Haynie, Wesley S., Rajaram, Narasimhan, Washington, Tyrone A., Greene, Nicholas P.
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Sprache:eng
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Aging - physiology
Animals
Bioenergetics
Body Weight - physiology
Cardiac hypertrophy
Down-Regulation - genetics
Hypoxia-reoxygenation
Male
Mice, Inbred C57BL
Mice, Obese
Mitochondria, Heart - physiology
Mitochondrial Proteins - genetics
Mitochondrial quality
Myocardium - metabolism
Obesity - metabolism
Optical redox imaging
Oxidation-Reduction
RNA, Messenger - physiology
RNA, Mitochondrial - physiology
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container_end_page 70
container_issue
container_start_page 62
container_title Experimental gerontology
container_volume 121
creator Lee, David E.
Perry, Richard A.
Brown, Jacob L.
Rosa-Caldwell, Megan E.
Brown, Lemuel A.
Haynie, Wesley S.
Rajaram, Narasimhan
Washington, Tyrone A.
Greene, Nicholas P.
description Being both advanced in age and obese each contribute to cardiac hypertrophy in a unique manner. Electron transport complexes I and IV are implicated in deficient electron transport during cardiomyopathies and contain the majority of protein subunits that are transcribed and translated by machinery localized within the mitochondria. To assess myocardial mt-mRNA translation factors in relation to mitochondrial content and mtDNA-encoded protein using a mouse model of aged obesity and to test the relationship of mt-mRNA translation initiation factor 2 (mtIF2) to oxidative capacity and the cellular oxidation-reduction (redox) state in cardiomyocytes. Male C56BL/6 J mice fed lean or high fat diet were aged to either ~3 months or ~22 months, the heart was excised and analyzed using immunoblot and qPCR to assess differences in mitochondrial mRNA translation machinery. Using H9c2 cardiomyocytes, mtIF2 was knocked-down and oxidative metabolic characteristics assessed including oxidation/reduction state, bioenergetic flux, and hypoxic resistance was tested. Aged, obese mouse hearts were ~40% larger than young, lean controls and contained ~50% less mtIF2 protein alongside ~25–50% lower content of Cytb, a protein encoded by mtDNA. Reducing the level of mtIF2 by shRNA is associated with ~15–20% lower content of OXPHOS complex I and IV, ~30% lower optical redox ratio, ~40% oxygen reserve capacity, and ~20% less cell survival following hypoxia. We present evidence of altered mt-mRNA translation during cardiac hypertrophy in aged obesity. We build on these results by demonstrating the necessity of mtIF2 in maintaining oxidative characteristics of cardiac muscle cells. •Despite being larger, the hearts of aged, obese mice show reduced mtIF2 protein.•In culture, mtIF2 reduction reduced oxidative capacity of cardiomyocytes.•Cardiomyocytes with less mtIF2 have increased susceptibility to hypoxic stress.
doi_str_mv 10.1016/j.exger.2019.03.009
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Aged, obese mouse hearts were ~40% larger than young, lean controls and contained ~50% less mtIF2 protein alongside ~25–50% lower content of Cytb, a protein encoded by mtDNA. Reducing the level of mtIF2 by shRNA is associated with ~15–20% lower content of OXPHOS complex I and IV, ~30% lower optical redox ratio, ~40% oxygen reserve capacity, and ~20% less cell survival following hypoxia. We present evidence of altered mt-mRNA translation during cardiac hypertrophy in aged obesity. 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Electron transport complexes I and IV are implicated in deficient electron transport during cardiomyopathies and contain the majority of protein subunits that are transcribed and translated by machinery localized within the mitochondria. To assess myocardial mt-mRNA translation factors in relation to mitochondrial content and mtDNA-encoded protein using a mouse model of aged obesity and to test the relationship of mt-mRNA translation initiation factor 2 (mtIF2) to oxidative capacity and the cellular oxidation-reduction (redox) state in cardiomyocytes. Male C56BL/6 J mice fed lean or high fat diet were aged to either ~3 months or ~22 months, the heart was excised and analyzed using immunoblot and qPCR to assess differences in mitochondrial mRNA translation machinery. Using H9c2 cardiomyocytes, mtIF2 was knocked-down and oxidative metabolic characteristics assessed including oxidation/reduction state, bioenergetic flux, and hypoxic resistance was tested. Aged, obese mouse hearts were ~40% larger than young, lean controls and contained ~50% less mtIF2 protein alongside ~25–50% lower content of Cytb, a protein encoded by mtDNA. Reducing the level of mtIF2 by shRNA is associated with ~15–20% lower content of OXPHOS complex I and IV, ~30% lower optical redox ratio, ~40% oxygen reserve capacity, and ~20% less cell survival following hypoxia. We present evidence of altered mt-mRNA translation during cardiac hypertrophy in aged obesity. We build on these results by demonstrating the necessity of mtIF2 in maintaining oxidative characteristics of cardiac muscle cells. •Despite being larger, the hearts of aged, obese mice show reduced mtIF2 protein.•In culture, mtIF2 reduction reduced oxidative capacity of cardiomyocytes.•Cardiomyocytes with less mtIF2 have increased susceptibility to hypoxic stress.</abstract><cop>England</cop><pub>Elsevier Inc</pub><pmid>30928679</pmid><doi>10.1016/j.exger.2019.03.009</doi><tpages>9</tpages></addata></record>
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source MEDLINE; Access via ScienceDirect (Elsevier)
subjects Aging - physiology
Animals
Bioenergetics
Body Weight - physiology
Cardiac hypertrophy
Down-Regulation - genetics
Hypoxia-reoxygenation
Male
Mice, Inbred C57BL
Mice, Obese
Mitochondria, Heart - physiology
Mitochondrial Proteins - genetics
Mitochondrial quality
Myocardium - metabolism
Obesity - metabolism
Optical redox imaging
Oxidation-Reduction
RNA, Messenger - physiology
RNA, Mitochondrial - physiology
title Mitochondrial mRNA translation initiation contributes to oxidative metabolism in the myocardia of aged, obese mice
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