Increase of Intracellular Zinc Levels Rather Than Zinc Influx Inhibits Interleukin‐2 Production in Zinc Supplemented Jurkat Cells

ABSTRACT The essential trace element zinc is a well‐known modulator of T cell activation. There have been contradictory findings for the impact of zinc supplementation on T cell activation. In our study, we aimed to analyze IL‐2 production in Jurkat T cells during zinc supplementation in response to...

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Published inCell biochemistry and function Vol. 43; no. 7; pp. e70098 - n/a
Main Authors Sobernig, Christian M., Fischer, Henrike J., Rink, Lothar, Jakobs, Jana
Format Journal Article
LanguageEnglish
Published England Wiley Subscription Services, Inc 01.07.2025
John Wiley and Sons Inc
Subjects
Acetic acid
Calcimycin
Calcimycin - pharmacology
Calcium influx
Cell activation
Humans
IL‐2
Interleukin-2 - biosynthesis
Intracellular
Jurkat Cells
Lymphocytes
Lymphocytes T
mitogens
NF-AT protein
Phytohemagglutinins - pharmacology
Pyrithione
Stimulation
T cells
Tetradecanoylphorbol Acetate - pharmacology
Trace elements
Zinc
Zinc - metabolism
Zinc - pharmacology
calcimycin
IL‐2
T cells
zinc
mitogens
Online AccessGet full text
ISSN0263-6484
1099-0844
1099-0844
DOI10.1002/cbf.70098

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Abstract ABSTRACT The essential trace element zinc is a well‐known modulator of T cell activation. There have been contradictory findings for the impact of zinc supplementation on T cell activation. In our study, we aimed to analyze IL‐2 production in Jurkat T cells during zinc supplementation in response to different stimuli. We found that zinc strongly suppresses IL‐2 production in Jurkat cells stimulated with phorbol 12‐myristate 13‐acetate (PMA)/calcimycin or phytohemagglutinin (PHA)/calcimycin. In contrast, zinc had no impact on IL‐2 production after PHA stimulation alone, suggesting the inhibitory zinc‐effect was linked to high calcium influx. To distinguish if the observed IL‐2 suppression is due to either potential competing effects of zinc influx or simple elevation of intracellular zinc levels, we pretreated the Jurkat cells with the zinc ionophore pyrithione for an increase of intracellular zinc before the stimulation. It was sufficient to suppress IL‐2 expression even when the cells were not further supplemented with zinc during stimulation. We propose that zinc's inhibitory effects on phosphatases stabilize the phosphorylated NFAT and thus block IL‐2 expression. Our findings underline the importance of a balanced zinc status for proper immune functions and suggest a supporting effect of zinc during immunosuppressive treatments. Summary Zinc is a critical trace element involved in immune regulation. Our study shows that increased intracellular zinc levels suppress IL‐2 production in Jurkat T cells in a stimulus‐dependent manner. This effect is linked to calcium‐mediated signaling and may result from zinc‐induced inhibition of phosphatases, leading to persistent NFAT phosphorylation and thus to reduced transcription of IL‐2. These findings provide new insights into the molecular mechanisms by which zinc modulates T cell function and suggest that intracellular zinc homeostasis is a key factor in immune regulation, with potential implications for immunosuppressive strategies.
AbstractList The essential trace element zinc is a well‐known modulator of T cell activation. There have been contradictory findings for the impact of zinc supplementation on T cell activation. In our study, we aimed to analyze IL‐2 production in Jurkat T cells during zinc supplementation in response to different stimuli. We found that zinc strongly suppresses IL‐2 production in Jurkat cells stimulated with phorbol 12‐myristate 13‐acetate (PMA)/calcimycin or phytohemagglutinin (PHA)/calcimycin. In contrast, zinc had no impact on IL‐2 production after PHA stimulation alone, suggesting the inhibitory zinc‐effect was linked to high calcium influx. To distinguish if the observed IL‐2 suppression is due to either potential competing effects of zinc influx or simple elevation of intracellular zinc levels, we pretreated the Jurkat cells with the zinc ionophore pyrithione for an increase of intracellular zinc before the stimulation. It was sufficient to suppress IL‐2 expression even when the cells were not further supplemented with zinc during stimulation. We propose that zinc's inhibitory effects on phosphatases stabilize the phosphorylated NFAT and thus block IL‐2 expression. Our findings underline the importance of a balanced zinc status for proper immune functions and suggest a supporting effect of zinc during immunosuppressive treatments. Zinc is a critical trace element involved in immune regulation. Our study shows that increased intracellular zinc levels suppress IL‐2 production in Jurkat T cells in a stimulus‐dependent manner. This effect is linked to calcium‐mediated signaling and may result from zinc‐induced inhibition of phosphatases, leading to persistent NFAT phosphorylation and thus to reduced transcription of IL‐2. These findings provide new insights into the molecular mechanisms by which zinc modulates T cell function and suggest that intracellular zinc homeostasis is a key factor in immune regulation, with potential implications for immunosuppressive strategies.
The essential trace element zinc is a well-known modulator of T cell activation. There have been contradictory findings for the impact of zinc supplementation on T cell activation. In our study, we aimed to analyze IL-2 production in Jurkat T cells during zinc supplementation in response to different stimuli. We found that zinc strongly suppresses IL-2 production in Jurkat cells stimulated with phorbol 12-myristate 13-acetate (PMA)/calcimycin or phytohemagglutinin (PHA)/calcimycin. In contrast, zinc had no impact on IL-2 production after PHA stimulation alone, suggesting the inhibitory zinc-effect was linked to high calcium influx. To distinguish if the observed IL-2 suppression is due to either potential competing effects of zinc influx or simple elevation of intracellular zinc levels, we pretreated the Jurkat cells with the zinc ionophore pyrithione for an increase of intracellular zinc before the stimulation. It was sufficient to suppress IL-2 expression even when the cells were not further supplemented with zinc during stimulation. We propose that zinc's inhibitory effects on phosphatases stabilize the phosphorylated NFAT and thus block IL-2 expression. Our findings underline the importance of a balanced zinc status for proper immune functions and suggest a supporting effect of zinc during immunosuppressive treatments.
The essential trace element zinc is a well‐known modulator of T cell activation. There have been contradictory findings for the impact of zinc supplementation on T cell activation. In our study, we aimed to analyze IL‐2 production in Jurkat T cells during zinc supplementation in response to different stimuli. We found that zinc strongly suppresses IL‐2 production in Jurkat cells stimulated with phorbol 12‐myristate 13‐acetate (PMA)/calcimycin or phytohemagglutinin (PHA)/calcimycin. In contrast, zinc had no impact on IL‐2 production after PHA stimulation alone, suggesting the inhibitory zinc‐effect was linked to high calcium influx. To distinguish if the observed IL‐2 suppression is due to either potential competing effects of zinc influx or simple elevation of intracellular zinc levels, we pretreated the Jurkat cells with the zinc ionophore pyrithione for an increase of intracellular zinc before the stimulation. It was sufficient to suppress IL‐2 expression even when the cells were not further supplemented with zinc during stimulation. We propose that zinc's inhibitory effects on phosphatases stabilize the phosphorylated NFAT and thus block IL‐2 expression. Our findings underline the importance of a balanced zinc status for proper immune functions and suggest a supporting effect of zinc during immunosuppressive treatments. Zinc is a critical trace element involved in immune regulation. Our study shows that increased intracellular zinc levels suppress IL‐2 production in Jurkat T cells in a stimulus‐dependent manner. This effect is linked to calcium‐mediated signaling and may result from zinc‐induced inhibition of phosphatases, leading to persistent NFAT phosphorylation and thus to reduced transcription of IL‐2. These findings provide new insights into the molecular mechanisms by which zinc modulates T cell function and suggest that intracellular zinc homeostasis is a key factor in immune regulation, with potential implications for immunosuppressive strategies.
ABSTRACT The essential trace element zinc is a well‐known modulator of T cell activation. There have been contradictory findings for the impact of zinc supplementation on T cell activation. In our study, we aimed to analyze IL‐2 production in Jurkat T cells during zinc supplementation in response to different stimuli. We found that zinc strongly suppresses IL‐2 production in Jurkat cells stimulated with phorbol 12‐myristate 13‐acetate (PMA)/calcimycin or phytohemagglutinin (PHA)/calcimycin. In contrast, zinc had no impact on IL‐2 production after PHA stimulation alone, suggesting the inhibitory zinc‐effect was linked to high calcium influx. To distinguish if the observed IL‐2 suppression is due to either potential competing effects of zinc influx or simple elevation of intracellular zinc levels, we pretreated the Jurkat cells with the zinc ionophore pyrithione for an increase of intracellular zinc before the stimulation. It was sufficient to suppress IL‐2 expression even when the cells were not further supplemented with zinc during stimulation. We propose that zinc's inhibitory effects on phosphatases stabilize the phosphorylated NFAT and thus block IL‐2 expression. Our findings underline the importance of a balanced zinc status for proper immune functions and suggest a supporting effect of zinc during immunosuppressive treatments. Summary Zinc is a critical trace element involved in immune regulation. Our study shows that increased intracellular zinc levels suppress IL‐2 production in Jurkat T cells in a stimulus‐dependent manner. This effect is linked to calcium‐mediated signaling and may result from zinc‐induced inhibition of phosphatases, leading to persistent NFAT phosphorylation and thus to reduced transcription of IL‐2. These findings provide new insights into the molecular mechanisms by which zinc modulates T cell function and suggest that intracellular zinc homeostasis is a key factor in immune regulation, with potential implications for immunosuppressive strategies.
The essential trace element zinc is a well-known modulator of T cell activation. There have been contradictory findings for the impact of zinc supplementation on T cell activation. In our study, we aimed to analyze IL-2 production in Jurkat T cells during zinc supplementation in response to different stimuli. We found that zinc strongly suppresses IL-2 production in Jurkat cells stimulated with phorbol 12-myristate 13-acetate (PMA)/calcimycin or phytohemagglutinin (PHA)/calcimycin. In contrast, zinc had no impact on IL-2 production after PHA stimulation alone, suggesting the inhibitory zinc-effect was linked to high calcium influx. To distinguish if the observed IL-2 suppression is due to either potential competing effects of zinc influx or simple elevation of intracellular zinc levels, we pretreated the Jurkat cells with the zinc ionophore pyrithione for an increase of intracellular zinc before the stimulation. It was sufficient to suppress IL-2 expression even when the cells were not further supplemented with zinc during stimulation. We propose that zinc's inhibitory effects on phosphatases stabilize the phosphorylated NFAT and thus block IL-2 expression. Our findings underline the importance of a balanced zinc status for proper immune functions and suggest a supporting effect of zinc during immunosuppressive treatments.The essential trace element zinc is a well-known modulator of T cell activation. There have been contradictory findings for the impact of zinc supplementation on T cell activation. In our study, we aimed to analyze IL-2 production in Jurkat T cells during zinc supplementation in response to different stimuli. We found that zinc strongly suppresses IL-2 production in Jurkat cells stimulated with phorbol 12-myristate 13-acetate (PMA)/calcimycin or phytohemagglutinin (PHA)/calcimycin. In contrast, zinc had no impact on IL-2 production after PHA stimulation alone, suggesting the inhibitory zinc-effect was linked to high calcium influx. To distinguish if the observed IL-2 suppression is due to either potential competing effects of zinc influx or simple elevation of intracellular zinc levels, we pretreated the Jurkat cells with the zinc ionophore pyrithione for an increase of intracellular zinc before the stimulation. It was sufficient to suppress IL-2 expression even when the cells were not further supplemented with zinc during stimulation. We propose that zinc's inhibitory effects on phosphatases stabilize the phosphorylated NFAT and thus block IL-2 expression. Our findings underline the importance of a balanced zinc status for proper immune functions and suggest a supporting effect of zinc during immunosuppressive treatments.
Author Jakobs, Jana
Sobernig, Christian M.
Rink, Lothar
Fischer, Henrike J.
AuthorAffiliation 1 Institute of Immunology Medical Faculty RWTH Aachen University Aachen
AuthorAffiliation_xml – name: 1 Institute of Immunology Medical Faculty RWTH Aachen University Aachen
Author_xml – sequence: 1
  givenname: Christian M.
  surname: Sobernig
  fullname: Sobernig, Christian M.
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  givenname: Henrike J.
  orcidid: 0000-0002-3022-908X
  surname: Fischer
  fullname: Fischer, Henrike J.
  organization: Medical Faculty RWTH Aachen University
– sequence: 3
  givenname: Lothar
  orcidid: 0000-0002-5658-2893
  surname: Rink
  fullname: Rink, Lothar
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  organization: Medical Faculty RWTH Aachen University
– sequence: 4
  givenname: Jana
  orcidid: 0000-0003-3005-0466
  surname: Jakobs
  fullname: Jakobs, Jana
  organization: Medical Faculty RWTH Aachen University
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Issue 7
Keywords calcimycin
IL‐2
T cells
zinc
mitogens
Language English
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Snippet ABSTRACT The essential trace element zinc is a well‐known modulator of T cell activation. There have been contradictory findings for the impact of zinc...
The essential trace element zinc is a well‐known modulator of T cell activation. There have been contradictory findings for the impact of zinc supplementation...
The essential trace element zinc is a well-known modulator of T cell activation. There have been contradictory findings for the impact of zinc supplementation...
SourceID pubmedcentral
proquest
pubmed
crossref
wiley
SourceType Open Access Repository
Aggregation Database
Index Database
Publisher
StartPage e70098
SubjectTerms Acetic acid
Calcimycin
Calcimycin - pharmacology
Calcium influx
Cell activation
Humans
IL‐2
Interleukin-2 - biosynthesis
Intracellular
Jurkat Cells
Lymphocytes
Lymphocytes T
mitogens
NF-AT protein
Phytohemagglutinins - pharmacology
Pyrithione
Stimulation
T cells
Tetradecanoylphorbol Acetate - pharmacology
Trace elements
Zinc
Zinc - metabolism
Zinc - pharmacology
Title Increase of Intracellular Zinc Levels Rather Than Zinc Influx Inhibits Interleukin‐2 Production in Zinc Supplemented Jurkat Cells
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fcbf.70098
https://www.ncbi.nlm.nih.gov/pubmed/40605399
https://www.proquest.com/docview/3233873704
https://www.proquest.com/docview/3226717551
https://pubmed.ncbi.nlm.nih.gov/PMC12223474
Volume 43
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