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Difference between revisions of "Iftikar 2013 PLoS One"

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{{Publication
{{Publication
|title=Iftikar FI, Hickey AJ (2013) Do mitochondria limit hot fish hearts? Understanding the role of mitochondrial function with heat stress in ''Notolabrus celidotus''. PLoS One 8: e64120.
|title=Iftikar FI, Hickey AJ (2013) Do mitochondria limit hot fish hearts? Understanding the role of mitochondrial function with heat stress in ''Notolabrus celidotus''. PLoS One 8:e64120.
|info=[http://www.ncbi.nlm.nih.gov/pubmed/23724026 PMID: 23724026 Open Access]
|info=[http://www.ncbi.nlm.nih.gov/pubmed/23724026 PMID: 23724026 Open Access]
|authors=Iftikar FI, Hickey AJ
|authors=Iftikar FI, Hickey AJ
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|journal=PLoS One
|journal=PLoS One
|abstract=Hearts are the first organs to fail in animals exposed to heat stress. Predictions of climate change mediated increases in ocean temperatures suggest that the ectothermic heart may place tight constraints on the diversity and distribution of marine species with cardiovascular systems. For many such species, their upper temperature limits (T<sub>max</sub>) and respective heart failure (HF) temperature (THF) are only a few degrees from current environmental temperatures. While the ectothermic cardiovascular system acts as an ''ecological thermometer'', the exact mechanism that mediates HF remains unresolved. We propose that heat-stressed cardiac mitochondria drive HF. Using a common New Zealand fish, ''Notolabrus celidotus'', we determined the THF (27.5°C). Haemoglobin oxygen saturation appeared to be unaltered in the blood surrounding and within heat stressed hearts. Using high resolution respirometry coupled to fluorimeters, we explored temperature-mediated changes in respiration, ROS and ATP production, and overlaid these changes with THF. Even at saturating oxygen levels several mitochondrial components were compromised before THF. Importantly, the capacity to efficiently produce ATP in the heart is limited at 25°C, and this is prior to the acute THF for ''N. celidotus''. Membrane leakiness increased significantly at 25°C, as did cytochrome c release and permeability to NADH. Maximal flux rates and the capacity for the electron transport system to uncouple were also altered at 25°C. These data indicate that mitochondrial membrane integrity is lost, depressing ATP synthesis capacity and promoting cytochrome c release, prior to THF. Mitochondria can mediate HF in heat stressed hearts in fish and play a significant role in thermal stress tolerance, and perhaps limit species distributions by contributing to HF.
|abstract=Hearts are the first organs to fail in animals exposed to heat stress. Predictions of climate change mediated increases in ocean temperatures suggest that the ectothermic heart may place tight constraints on the diversity and distribution of marine species with cardiovascular systems. For many such species, their upper temperature limits (T<sub>max</sub>) and respective heart failure (HF) temperature (THF) are only a few degrees from current environmental temperatures. While the ectothermic cardiovascular system acts as an ''ecological thermometer'', the exact mechanism that mediates HF remains unresolved. We propose that heat-stressed cardiac mitochondria drive HF. Using a common New Zealand fish, ''Notolabrus celidotus'', we determined the THF (27.5°C). Haemoglobin oxygen saturation appeared to be unaltered in the blood surrounding and within heat stressed hearts. Using high resolution respirometry coupled to fluorimeters, we explored temperature-mediated changes in respiration, ROS and ATP production, and overlaid these changes with THF. Even at saturating oxygen levels several mitochondrial components were compromised before THF. Importantly, the capacity to efficiently produce ATP in the heart is limited at 25°C, and this is prior to the acute THF for ''N. celidotus''. Membrane leakiness increased significantly at 25°C, as did cytochrome c release and permeability to NADH. Maximal flux rates and the capacity for the electron transport system to uncouple were also altered at 25°C. These data indicate that mitochondrial membrane integrity is lost, depressing ATP synthesis capacity and promoting cytochrome c release, prior to THF. Mitochondria can mediate HF in heat stressed hearts in fish and play a significant role in thermal stress tolerance, and perhaps limit species distributions by contributing to HF.
|keywords=New Zealand fish ''Notolabrus celidotus'', temperature, climate change, heart failure
|keywords=New Zealand fish ''Notolabrus celidotus'', Temperature, Climate change, Heart failure, Amplex Red, Magnesium Green
|mipnetlab=NZ Auckland Hickey AJ,
|mipnetlab=NZ Auckland Hickey AJ
}}
}}
== Cited by ==
{{Template:Cited by Cardoso 2021 MitoFit MgG}}
{{Labeling
{{Labeling
|area=Respiration, Comparative MiP;environmental MiP
|area=Respiration, Comparative MiP;environmental MiP
|taxonomic group=Fishes
|injuries=Oxidative stress;RONS
|organism=Fishes
|tissues=Heart
|tissues=Heart
|preparations=Permeabilized tissue
|preparations=Permeabilized tissue
|injuries=RONS; Oxidative Stress
|topics=Substrate, Temperature, Uncoupler
|topics=Substrate, Temperature, Uncoupler
|couplingstates=LEAK, OXPHOS, ETS
|couplingstates=LEAK, OXPHOS, ET
|instruments=Oxygraph-2k, Fluorometry
|pathways=N, CIV, NS, ROX
|instruments=Oxygraph-2k, O2k-Fluorometer
|additional=MgG, AmR, MitoFit 2021 MgG
}}
}}

Latest revision as of 15:41, 25 January 2021

Publications in the MiPMap
Iftikar FI, Hickey AJ (2013) Do mitochondria limit hot fish hearts? Understanding the role of mitochondrial function with heat stress in Notolabrus celidotus. PLoS One 8:e64120.

» PMID: 23724026 Open Access

Iftikar FI, Hickey AJ (2013) PLoS One

Abstract: Hearts are the first organs to fail in animals exposed to heat stress. Predictions of climate change mediated increases in ocean temperatures suggest that the ectothermic heart may place tight constraints on the diversity and distribution of marine species with cardiovascular systems. For many such species, their upper temperature limits (Tmax) and respective heart failure (HF) temperature (THF) are only a few degrees from current environmental temperatures. While the ectothermic cardiovascular system acts as an ecological thermometer, the exact mechanism that mediates HF remains unresolved. We propose that heat-stressed cardiac mitochondria drive HF. Using a common New Zealand fish, Notolabrus celidotus, we determined the THF (27.5°C). Haemoglobin oxygen saturation appeared to be unaltered in the blood surrounding and within heat stressed hearts. Using high resolution respirometry coupled to fluorimeters, we explored temperature-mediated changes in respiration, ROS and ATP production, and overlaid these changes with THF. Even at saturating oxygen levels several mitochondrial components were compromised before THF. Importantly, the capacity to efficiently produce ATP in the heart is limited at 25°C, and this is prior to the acute THF for N. celidotus. Membrane leakiness increased significantly at 25°C, as did cytochrome c release and permeability to NADH. Maximal flux rates and the capacity for the electron transport system to uncouple were also altered at 25°C. These data indicate that mitochondrial membrane integrity is lost, depressing ATP synthesis capacity and promoting cytochrome c release, prior to THF. Mitochondria can mediate HF in heat stressed hearts in fish and play a significant role in thermal stress tolerance, and perhaps limit species distributions by contributing to HF. Keywords: New Zealand fish Notolabrus celidotus, Temperature, Climate change, Heart failure, Amplex Red, Magnesium Green

O2k-Network Lab: NZ Auckland Hickey AJ


Cited by

  • Cardoso et al (2021) Magnesium Green for fluorometric measurement of ATP production does not interfere with mitochondrial respiration. Bioenerg Commun 2021.1. doi:10.26124/bec:2021-0001


Labels: MiParea: Respiration, Comparative MiP;environmental MiP 

Stress:Oxidative stress;RONS  Organism: Fishes  Tissue;cell: Heart  Preparation: Permeabilized tissue 

Regulation: Substrate, Temperature, Uncoupler  Coupling state: LEAK, OXPHOS, ET  Pathway: N, CIV, NS, ROX  HRR: Oxygraph-2k, O2k-Fluorometer 

MgG, AmR, MitoFit 2021 MgG