TY - JOUR
T1 - HIF-1 is required for heat acclimation in the nematode Caenorhabditis elegans
AU - Treinin, Millet
AU - Shliar, Judith
AU - Jiang, Huaqi
AU - Powell-Coffman, Jo Anne
AU - Bromberg, Zohar
AU - Horowitz, Michal
PY - 2003/10
Y1 - 2003/10
N2 - Chronic exposure to environmental-heat improves tolerance via heat acclimation (AC). Our previous data on mammals indicate that reprogramming the expression of genes coding for stress proteins and energy-metabolism enzymes plays a major role. Knowledge of pathways leading to AC is limited. For their identification, we established a Caenorhabditis elegans AC model and tested mutants in which signaling pathways pertinent to acclimatory responses are mutated. AC attained by maintaining adult C. elegans at 25°C for 18 h enhanced heat endurance of wild-type worms subjected to heat stress (35°C) and conferred protection against hypoxia and cadmium. Survival curves demonstrated that both daf-2 (insulin receptor pathway) showing enhanced heat tolerance and daf-16 loss-of-function (a transcription factor mediating DAF-2 signaling) mutants benefit from AC, suggesting that the insulin receptor pathway does not mediate AC. In contrast, the hif-1 (hypoxia inducible factor) loss-of-function strain did not show acclimation, and non-acclimated vhl-1 and egl-9 mutants (overexpressing HIF-1) had greater heat endurance than the wild type. Like mammals, HIF-1 and HSP72 levels increased in the wild-type AC nematodes. HSP72 upregulation in AC hif-1 mutants was also observed; however, it was insufficient to improve heat/stress tolerance, suggesting that HIF-1 upregulation is essential for acclimation, whereas HSP72 upregulation in the absence of HIF-1 is inadequate. We conclude that HIF-1 upregulation is both an evolutionarily conserved and a necessary component of heat acclimation. The known targets of HIF-1 imply that metabolic adaptations are essential for AC-dependent tolerance to heat and heavy metals, in addition to their known role in hypoxic adaptation.
AB - Chronic exposure to environmental-heat improves tolerance via heat acclimation (AC). Our previous data on mammals indicate that reprogramming the expression of genes coding for stress proteins and energy-metabolism enzymes plays a major role. Knowledge of pathways leading to AC is limited. For their identification, we established a Caenorhabditis elegans AC model and tested mutants in which signaling pathways pertinent to acclimatory responses are mutated. AC attained by maintaining adult C. elegans at 25°C for 18 h enhanced heat endurance of wild-type worms subjected to heat stress (35°C) and conferred protection against hypoxia and cadmium. Survival curves demonstrated that both daf-2 (insulin receptor pathway) showing enhanced heat tolerance and daf-16 loss-of-function (a transcription factor mediating DAF-2 signaling) mutants benefit from AC, suggesting that the insulin receptor pathway does not mediate AC. In contrast, the hif-1 (hypoxia inducible factor) loss-of-function strain did not show acclimation, and non-acclimated vhl-1 and egl-9 mutants (overexpressing HIF-1) had greater heat endurance than the wild type. Like mammals, HIF-1 and HSP72 levels increased in the wild-type AC nematodes. HSP72 upregulation in AC hif-1 mutants was also observed; however, it was insufficient to improve heat/stress tolerance, suggesting that HIF-1 upregulation is essential for acclimation, whereas HSP72 upregulation in the absence of HIF-1 is inadequate. We conclude that HIF-1 upregulation is both an evolutionarily conserved and a necessary component of heat acclimation. The known targets of HIF-1 imply that metabolic adaptations are essential for AC-dependent tolerance to heat and heavy metals, in addition to their known role in hypoxic adaptation.
KW - Cross-tolerance
KW - HIF-1
KW - HSP72
KW - Heat acclimation
UR - http://www.scopus.com/inward/record.url?scp=0043128522&partnerID=8YFLogxK
U2 - 10.1152/physiolgenomics.00179.2002
DO - 10.1152/physiolgenomics.00179.2002
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C2 - 12686697
AN - SCOPUS:0043128522
SN - 1531-2267
VL - 14
SP - 17
EP - 24
JO - Physiological Genomics
JF - Physiological Genomics
ER -