FoxO4 activity is regulated by phosphorylation and the cellular environment during dehydration in the African clawed frog, Xenopus laevis

The African clawed frog, Xenopus laevis, is capable of enduring seasonal bouts of severe dehydration stress resulting from transcriptional regulation that facilitates a pro-survival response. Previous studies have shown that dehydration increases antioxidant gene expression in this amphibian. As Fox...

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Published inBiochimica et biophysica acta. General subjects Vol. 1862; no. 8; pp. 1721 - 1728
Main Authors Zhang, Yichi, Luu, Bryan E., Storey, Kenneth B.
Format Journal Article
LanguageEnglish
Published Netherlands Elsevier B.V 01.08.2018
Subjects
amphibians
Animals
antioxidant genes
Antioxidants - metabolism
binding capacity
Dehydration
Dehydration - physiopathology
DNA
DNA - metabolism
DPI-ELISA
Environment
environmental factors
Forkhead box O
Forkhead Transcription Factors - metabolism
gene expression
Gene Expression Regulation, Enzymologic
Myogenin
Phosphorylation
protein content
Proto-Oncogene Proteins c-akt - metabolism
Signal Transduction
skeletal muscle
temperature
transcription (genetics)
transcription factors
Transcription, Genetic
urea
Western blotting
Xenopus laevis
Xenopus laevis - growth & development
Xenopus laevis - metabolism
Xenopus Proteins - metabolism
Myogenin
DPI-ELISA
Dehydration
Xenopus laevis
Western blotting
Forkhead box O
Online AccessGet full text
ISSN0304-4165
1872-8006
DOI10.1016/j.bbagen.2018.05.002

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Abstract The African clawed frog, Xenopus laevis, is capable of enduring seasonal bouts of severe dehydration stress resulting from transcriptional regulation that facilitates a pro-survival response. Previous studies have shown that dehydration increases antioxidant gene expression in this amphibian. As FoxO4 is known to regulate several antioxidant genes, we sought to understand how differential phosphorylation and environmental factors (urea, temperature) may contribute to its transcriptional regulation during dehydration exposure. Immunoblotting was used to quantify relative amount of total FoxO4, of phosphorylated FoxO4, and of the factors in the Ras-Ral pathway that regulate FoxO4 activity in X. laevis skeletal muscle during dehydration. DNA-protein interaction (DPI)-ELISA was used to measure transcription factor-binding to their consensus sequences in the promoters of target genes. Environmental DPI-ELISA was used to assess the effect of the cellular environment on transcription factor binding. FoxO4 protein levels do not change during dehydration, but FoxO4-binding to DNA increases with higher dehydration. The Ras-Ral pathway does not appear to be involved in regulating FoxO4 during dehydration, but Akt-mediated FoxO4 phosphorylation at Ser-193 decreases during high dehydration exposure, which is indicative of increased FoxO4 activity. Further assessment indicated that FoxO4-DNA binding affinity is drastically affected by environmental changes in urea and temperature. FoxO4 plays an important role during dehydration stress in X. laevis, and its activity could be regulated through Akt-mediated phosphorylation, and changes in temperature or urea. Dehydration triggers regulatory mechanisms of transcription by inducing differential phosphorylation and changes to urea in X. laevis. •Dehydration triggers a change in the phosphorylation status and activation of FoxO4 through an Akt-mediated mechanism•The elevation in X. laevis urea levels during dehydration may affect FoxO4-DNA binding affinity.•DNA-protein interaction ELISA (DPI-ELISA) can be modified to study the effect of environmental factors on transcription factor-binding to DNA.
AbstractList The African clawed frog, Xenopus laevis, is capable of enduring seasonal bouts of severe dehydration stress resulting from transcriptional regulation that facilitates a pro-survival response. Previous studies have shown that dehydration increases antioxidant gene expression in this amphibian. As FoxO4 is known to regulate several antioxidant genes, we sought to understand how differential phosphorylation and environmental factors (urea, temperature) may contribute to its transcriptional regulation during dehydration exposure. Immunoblotting was used to quantify relative amount of total FoxO4, of phosphorylated FoxO4, and of the factors in the Ras-Ral pathway that regulate FoxO4 activity in X. laevis skeletal muscle during dehydration. DNA-protein interaction (DPI)-ELISA was used to measure transcription factor-binding to their consensus sequences in the promoters of target genes. Environmental DPI-ELISA was used to assess the effect of the cellular environment on transcription factor binding. FoxO4 protein levels do not change during dehydration, but FoxO4-binding to DNA increases with higher dehydration. The Ras-Ral pathway does not appear to be involved in regulating FoxO4 during dehydration, but Akt-mediated FoxO4 phosphorylation at Ser-193 decreases during high dehydration exposure, which is indicative of increased FoxO4 activity. Further assessment indicated that FoxO4-DNA binding affinity is drastically affected by environmental changes in urea and temperature. FoxO4 plays an important role during dehydration stress in X. laevis, and its activity could be regulated through Akt-mediated phosphorylation, and changes in temperature or urea. Dehydration triggers regulatory mechanisms of transcription by inducing differential phosphorylation and changes to urea in X. laevis.
The African clawed frog, Xenopus laevis, is capable of enduring seasonal bouts of severe dehydration stress resulting from transcriptional regulation that facilitates a pro-survival response. Previous studies have shown that dehydration increases antioxidant gene expression in this amphibian. As FoxO4 is known to regulate several antioxidant genes, we sought to understand how differential phosphorylation and environmental factors (urea, temperature) may contribute to its transcriptional regulation during dehydration exposure. Immunoblotting was used to quantify relative amount of total FoxO4, of phosphorylated FoxO4, and of the factors in the Ras-Ral pathway that regulate FoxO4 activity in X. laevis skeletal muscle during dehydration. DNA-protein interaction (DPI)-ELISA was used to measure transcription factor-binding to their consensus sequences in the promoters of target genes. Environmental DPI-ELISA was used to assess the effect of the cellular environment on transcription factor binding. FoxO4 protein levels do not change during dehydration, but FoxO4-binding to DNA increases with higher dehydration. The Ras-Ral pathway does not appear to be involved in regulating FoxO4 during dehydration, but Akt-mediated FoxO4 phosphorylation at Ser-193 decreases during high dehydration exposure, which is indicative of increased FoxO4 activity. Further assessment indicated that FoxO4-DNA binding affinity is drastically affected by environmental changes in urea and temperature. FoxO4 plays an important role during dehydration stress in X. laevis, and its activity could be regulated through Akt-mediated phosphorylation, and changes in temperature or urea. Dehydration triggers regulatory mechanisms of transcription by inducing differential phosphorylation and changes to urea in X. laevis. •Dehydration triggers a change in the phosphorylation status and activation of FoxO4 through an Akt-mediated mechanism•The elevation in X. laevis urea levels during dehydration may affect FoxO4-DNA binding affinity.•DNA-protein interaction ELISA (DPI-ELISA) can be modified to study the effect of environmental factors on transcription factor-binding to DNA.
The African clawed frog, Xenopus laevis, is capable of enduring seasonal bouts of severe dehydration stress resulting from transcriptional regulation that facilitates a pro-survival response. Previous studies have shown that dehydration increases antioxidant gene expression in this amphibian. As FoxO4 is known to regulate several antioxidant genes, we sought to understand how differential phosphorylation and environmental factors (urea, temperature) may contribute to its transcriptional regulation during dehydration exposure.BACKGROUNDThe African clawed frog, Xenopus laevis, is capable of enduring seasonal bouts of severe dehydration stress resulting from transcriptional regulation that facilitates a pro-survival response. Previous studies have shown that dehydration increases antioxidant gene expression in this amphibian. As FoxO4 is known to regulate several antioxidant genes, we sought to understand how differential phosphorylation and environmental factors (urea, temperature) may contribute to its transcriptional regulation during dehydration exposure.Immunoblotting was used to quantify relative amount of total FoxO4, of phosphorylated FoxO4, and of the factors in the Ras-Ral pathway that regulate FoxO4 activity in X. laevis skeletal muscle during dehydration. DNA-protein interaction (DPI)-ELISA was used to measure transcription factor-binding to their consensus sequences in the promoters of target genes. Environmental DPI-ELISA was used to assess the effect of the cellular environment on transcription factor binding.METHODSImmunoblotting was used to quantify relative amount of total FoxO4, of phosphorylated FoxO4, and of the factors in the Ras-Ral pathway that regulate FoxO4 activity in X. laevis skeletal muscle during dehydration. DNA-protein interaction (DPI)-ELISA was used to measure transcription factor-binding to their consensus sequences in the promoters of target genes. Environmental DPI-ELISA was used to assess the effect of the cellular environment on transcription factor binding.FoxO4 protein levels do not change during dehydration, but FoxO4-binding to DNA increases with higher dehydration. The Ras-Ral pathway does not appear to be involved in regulating FoxO4 during dehydration, but Akt-mediated FoxO4 phosphorylation at Ser-193 decreases during high dehydration exposure, which is indicative of increased FoxO4 activity. Further assessment indicated that FoxO4-DNA binding affinity is drastically affected by environmental changes in urea and temperature.RESULTSFoxO4 protein levels do not change during dehydration, but FoxO4-binding to DNA increases with higher dehydration. The Ras-Ral pathway does not appear to be involved in regulating FoxO4 during dehydration, but Akt-mediated FoxO4 phosphorylation at Ser-193 decreases during high dehydration exposure, which is indicative of increased FoxO4 activity. Further assessment indicated that FoxO4-DNA binding affinity is drastically affected by environmental changes in urea and temperature.FoxO4 plays an important role during dehydration stress in X. laevis, and its activity could be regulated through Akt-mediated phosphorylation, and changes in temperature or urea.CONCLUSIONFoxO4 plays an important role during dehydration stress in X. laevis, and its activity could be regulated through Akt-mediated phosphorylation, and changes in temperature or urea.Dehydration triggers regulatory mechanisms of transcription by inducing differential phosphorylation and changes to urea in X. laevis.GENERAL SIGNIFICANCEDehydration triggers regulatory mechanisms of transcription by inducing differential phosphorylation and changes to urea in X. laevis.
The African clawed frog, Xenopus laevis, is capable of enduring seasonal bouts of severe dehydration stress resulting from transcriptional regulation that facilitates a pro-survival response. Previous studies have shown that dehydration increases antioxidant gene expression in this amphibian. As FoxO4 is known to regulate several antioxidant genes, we sought to understand how differential phosphorylation and environmental factors (urea, temperature) may contribute to its transcriptional regulation during dehydration exposure.Immunoblotting was used to quantify relative amount of total FoxO4, of phosphorylated FoxO4, and of the factors in the Ras-Ral pathway that regulate FoxO4 activity in X. laevis skeletal muscle during dehydration. DNA-protein interaction (DPI)-ELISA was used to measure transcription factor-binding to their consensus sequences in the promoters of target genes. Environmental DPI-ELISA was used to assess the effect of the cellular environment on transcription factor binding.FoxO4 protein levels do not change during dehydration, but FoxO4-binding to DNA increases with higher dehydration. The Ras-Ral pathway does not appear to be involved in regulating FoxO4 during dehydration, but Akt-mediated FoxO4 phosphorylation at Ser-193 decreases during high dehydration exposure, which is indicative of increased FoxO4 activity. Further assessment indicated that FoxO4-DNA binding affinity is drastically affected by environmental changes in urea and temperature.FoxO4 plays an important role during dehydration stress in X. laevis, and its activity could be regulated through Akt-mediated phosphorylation, and changes in temperature or urea.Dehydration triggers regulatory mechanisms of transcription by inducing differential phosphorylation and changes to urea in X. laevis.
Author Storey, Kenneth B.
Zhang, Yichi
Luu, Bryan E.
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Keywords Myogenin
DPI-ELISA
Dehydration
Xenopus laevis
Western blotting
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Snippet The African clawed frog, Xenopus laevis, is capable of enduring seasonal bouts of severe dehydration stress resulting from transcriptional regulation that...
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SubjectTerms amphibians
Animals
antioxidant genes
Antioxidants - metabolism
binding capacity
Dehydration
Dehydration - physiopathology
DNA
DNA - metabolism
DPI-ELISA
Environment
environmental factors
Forkhead box O
Forkhead Transcription Factors - metabolism
gene expression
Gene Expression Regulation, Enzymologic
Myogenin
Phosphorylation
protein content
Proto-Oncogene Proteins c-akt - metabolism
Signal Transduction
skeletal muscle
temperature
transcription (genetics)
transcription factors
Transcription, Genetic
urea
Western blotting
Xenopus laevis
Xenopus laevis - growth & development
Xenopus laevis - metabolism
Xenopus Proteins - metabolism
Title FoxO4 activity is regulated by phosphorylation and the cellular environment during dehydration in the African clawed frog, Xenopus laevis
URI https://dx.doi.org/10.1016/j.bbagen.2018.05.002
https://www.ncbi.nlm.nih.gov/pubmed/29746959
https://www.proquest.com/docview/2038263322
https://www.proquest.com/docview/2131862947
Volume 1862
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