PICOT (GLRX3) is a positive regulator of stress-induced DNA-damage response.
Identifieur interne : 000140 ( Main/Exploration ); précédent : 000139; suivant : 000141PICOT (GLRX3) is a positive regulator of stress-induced DNA-damage response.
Auteurs : Pinakin Pandya [Israël] ; Alex Braiman [Israël] ; Noah Isakov [Israël]Source :
- Cellular signalling [ 1873-3913 ] ; 2019.
Descripteurs français
- KwdFr :
- Altération de l'ADN (effets des médicaments et des substances chimiques), Altération de l'ADN (génétique), Animaux (MeSH), Camptothécine (pharmacologie), Caspase-3 (génétique), Cassures double-brin de l'ADN (effets des radiations), Cellules Jurkat (MeSH), Génome (effets des radiations), Histone (génétique), Humains (MeSH), Lignée cellulaire tumorale (MeSH), Phosphorylation (effets des radiations), Protéines de transport (génétique), Réplication de l'ADN (effets des radiations), Réplication de l'ADN (génétique), Souris (MeSH), Thiorédoxines (génétique), Transduction du signal (effets des radiations).
- MESH :
- effets des médicaments et des substances chimiques : Altération de l'ADN.
- effets des radiations : Cassures double-brin de l'ADN, Génome, Phosphorylation, Réplication de l'ADN, Transduction du signal.
- génétique : Altération de l'ADN, Caspase-3, Histone, Protéines de transport, Réplication de l'ADN, Thiorédoxines.
- pharmacologie : Camptothécine.
- Animaux, Cellules Jurkat, Humains, Lignée cellulaire tumorale, Souris.
English descriptors
- KwdEn :
- Animals (MeSH), Camptothecin (pharmacology), Carrier Proteins (genetics), Caspase 3 (genetics), Cell Line, Tumor (MeSH), DNA Breaks, Double-Stranded (radiation effects), DNA Damage (drug effects), DNA Damage (genetics), DNA Replication (genetics), DNA Replication (radiation effects), Genome (radiation effects), Histones (genetics), Humans (MeSH), Jurkat Cells (MeSH), Mice (MeSH), Phosphorylation (radiation effects), Signal Transduction (radiation effects), Thioredoxins (genetics).
- MESH :
- chemical , genetics : Carrier Proteins, Caspase 3, Histones, Thioredoxins.
- chemical , pharmacology : Camptothecin.
- drug effects : DNA Damage.
- genetics : DNA Damage, DNA Replication.
- radiation effects : DNA Breaks, Double-Stranded, DNA Replication, Genome, Phosphorylation, Signal Transduction.
- Animals, Cell Line, Tumor, Humans, Jurkat Cells, Mice.
Abstract
Protein kinase C (PKC)-interacting cousin of thioredoxin (PICOT; also termed glutaredoxin 3 (Glrx3)) is a ubiquitously expressed protein that possesses an N-terminal monothiol thioredoxin (Trx) domain and two C-terminal tandem copies of a monothiol Glrx domain. It has an overall highly conserved amino acid sequence and is encoded by a unique gene, both in humans and mice, without having other functional gene homologs in the entire genome. Despite being discovered almost two decades ago, the biological function of PICOT remains largely ill-defined and its ramifications are underestimated considering the fact that PICOT-deficiency in mice results in embryonic lethality. Since classical Glrxs are important regulators of the cellular redox homeostasis, we tested whether PICOT participate in the stress-induced DNA-damage response, focusing on nuclear proteins that function as integral components of the DNA repair machinery. Using wild type versus PICOT-deficient (PICOT-KD) Jurkat T cells we found that the anti-oxidant mechanism in PICOT-deficient cells is impaired, and that these cells respond to genotoxic drugs, such as etoposide and camptothecin, by increased caspase-3 activity, a reduced survival and a slower and diminished phosphorylation of the histone protein, H2AX. Nevertheless, the effect of PICOT on the drug-induced phosphorylation of H2AX was independent of the cellular levels of reactive oxygen species. PICOT-deficient cells also demonstrated reduced and slower γH2AX foci formation in response to radiation. Furthermore, immunofluorescence staining using PICOT- and γH2AX-specific Abs followed by confocal microscopy demonstrated partial localization of PICOT at the γH2AX-containing foci at the site of the DNA double strand breaks. In addition, PICOT knockdown resulted in inhibition of phosphorylation of ATR, Chk1 and Chk2 kinases, which play an essential role in the DNA-damage response and serve as upstream regulators of γH2AX. The present data suggest that PICOT protects cells from DNA damage-inducing agents by operating as an upstream positive regulator of ATR-dependent signaling pathways. By promoting the activity of ATR, PICOT indirectly regulates the phosphorylation and activation of Chk1, Chk2, and γH2AX, which are critical components of the DNA damage repair mechanism and thereby attenuate the stress- and replication-induced genome instability.
DOI: 10.1016/j.cellsig.2019.06.005
PubMed: 31176019
Affiliations:
Links toward previous steps (curation, corpus...)
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Electronic address: noah@bgu.ac.il.</nlm:affiliation><country xml:lang="fr" wicri:curation="lc">Israël</country><wicri:regionArea>The Shraga Segal Department of Microbiology, Immunology and Genetics, Faculty of Health Sciences and the Cancer Research Center, Ben Gurion University of the Negev, P.O.B. 653, Beer Sheva 84105</wicri:regionArea><wicri:noRegion>Beer Sheva 84105</wicri:noRegion></affiliation></author></analytic><series><title level="j">Cellular signalling</title><idno type="eISSN">1873-3913</idno><imprint><date when="2019" type="published">2019</date></imprint></series></biblStruct></sourceDesc></fileDesc><profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>Animals (MeSH)</term><term>Camptothecin (pharmacology)</term><term>Carrier Proteins (genetics)</term><term>Caspase 3 (genetics)</term><term>Cell Line, Tumor (MeSH)</term><term>DNA Breaks, Double-Stranded (radiation effects)</term><term>DNA Damage (drug effects)</term><term>DNA Damage (genetics)</term><term>DNA Replication (genetics)</term><term>DNA Replication (radiation effects)</term><term>Genome (radiation effects)</term><term>Histones (genetics)</term><term>Humans (MeSH)</term><term>Jurkat Cells (MeSH)</term><term>Mice (MeSH)</term><term>Phosphorylation (radiation effects)</term><term>Signal Transduction (radiation effects)</term><term>Thioredoxins (genetics)</term></keywords><keywords scheme="KwdFr" xml:lang="fr"><term>Altération de l'ADN (effets des médicaments et des substances chimiques)</term><term>Altération de l'ADN (génétique)</term><term>Animaux (MeSH)</term><term>Camptothécine (pharmacologie)</term><term>Caspase-3 (génétique)</term><term>Cassures double-brin de l'ADN (effets des radiations)</term><term>Cellules Jurkat (MeSH)</term><term>Génome (effets des radiations)</term><term>Histone (génétique)</term><term>Humains (MeSH)</term><term>Lignée cellulaire tumorale (MeSH)</term><term>Phosphorylation (effets des radiations)</term><term>Protéines de transport (génétique)</term><term>Réplication de l'ADN (effets des radiations)</term><term>Réplication de l'ADN (génétique)</term><term>Souris (MeSH)</term><term>Thiorédoxines (génétique)</term><term>Transduction du signal (effets des radiations)</term></keywords><keywords scheme="MESH" type="chemical" qualifier="genetics" xml:lang="en"><term>Carrier Proteins</term><term>Caspase 3</term><term>Histones</term><term>Thioredoxins</term></keywords><keywords scheme="MESH" type="chemical" qualifier="pharmacology" xml:lang="en"><term>Camptothecin</term></keywords><keywords scheme="MESH" qualifier="drug effects" xml:lang="en"><term>DNA Damage</term></keywords><keywords scheme="MESH" qualifier="effets des médicaments et des substances chimiques" xml:lang="fr"><term>Altération de l'ADN</term></keywords><keywords scheme="MESH" qualifier="effets des radiations" xml:lang="fr"><term>Cassures double-brin de l'ADN</term><term>Génome</term><term>Phosphorylation</term><term>Réplication de l'ADN</term><term>Transduction du signal</term></keywords><keywords scheme="MESH" qualifier="genetics" xml:lang="en"><term>DNA Damage</term><term>DNA Replication</term></keywords><keywords scheme="MESH" qualifier="génétique" xml:lang="fr"><term>Altération de l'ADN</term><term>Caspase-3</term><term>Histone</term><term>Protéines de transport</term><term>Réplication de l'ADN</term><term>Thiorédoxines</term></keywords><keywords scheme="MESH" qualifier="pharmacologie" xml:lang="fr"><term>Camptothécine</term></keywords><keywords scheme="MESH" qualifier="radiation effects" xml:lang="en"><term>DNA Breaks, Double-Stranded</term><term>DNA Replication</term><term>Genome</term><term>Phosphorylation</term><term>Signal Transduction</term></keywords><keywords scheme="MESH" xml:lang="en"><term>Animals</term><term>Cell Line, Tumor</term><term>Humans</term><term>Jurkat Cells</term><term>Mice</term></keywords><keywords scheme="MESH" xml:lang="fr"><term>Animaux</term><term>Cellules Jurkat</term><term>Humains</term><term>Lignée cellulaire tumorale</term><term>Souris</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">Protein kinase C (PKC)-interacting cousin of thioredoxin (PICOT; also termed glutaredoxin 3 (Glrx3)) is a ubiquitously expressed protein that possesses an N-terminal monothiol thioredoxin (Trx) domain and two C-terminal tandem copies of a monothiol Glrx domain. It has an overall highly conserved amino acid sequence and is encoded by a unique gene, both in humans and mice, without having other functional gene homologs in the entire genome. Despite being discovered almost two decades ago, the biological function of PICOT remains largely ill-defined and its ramifications are underestimated considering the fact that PICOT-deficiency in mice results in embryonic lethality. Since classical Glrxs are important regulators of the cellular redox homeostasis, we tested whether PICOT participate in the stress-induced DNA-damage response, focusing on nuclear proteins that function as integral components of the DNA repair machinery. Using wild type versus PICOT-deficient (PICOT-KD) Jurkat T cells we found that the anti-oxidant mechanism in PICOT-deficient cells is impaired, and that these cells respond to genotoxic drugs, such as etoposide and camptothecin, by increased caspase-3 activity, a reduced survival and a slower and diminished phosphorylation of the histone protein, H2AX. Nevertheless, the effect of PICOT on the drug-induced phosphorylation of H2AX was independent of the cellular levels of reactive oxygen species. PICOT-deficient cells also demonstrated reduced and slower γH2AX foci formation in response to radiation. Furthermore, immunofluorescence staining using PICOT- and γH2AX-specific Abs followed by confocal microscopy demonstrated partial localization of PICOT at the γH2AX-containing foci at the site of the DNA double strand breaks. In addition, PICOT knockdown resulted in inhibition of phosphorylation of ATR, Chk1 and Chk2 kinases, which play an essential role in the DNA-damage response and serve as upstream regulators of γH2AX. The present data suggest that PICOT protects cells from DNA damage-inducing agents by operating as an upstream positive regulator of ATR-dependent signaling pathways. By promoting the activity of ATR, PICOT indirectly regulates the phosphorylation and activation of Chk1, Chk2, and γH2AX, which are critical components of the DNA damage repair mechanism and thereby attenuate the stress- and replication-induced genome instability.</div></front></TEI><pubmed><MedlineCitation Status="MEDLINE" Owner="NLM"><PMID Version="1">31176019</PMID><DateCompleted><Year>2020</Year><Month>08</Month><Day>20</Day></DateCompleted><DateRevised><Year>2020</Year><Month>08</Month><Day>20</Day></DateRevised><Article PubModel="Print-Electronic"><Journal><ISSN IssnType="Electronic">1873-3913</ISSN><JournalIssue CitedMedium="Internet"><Volume>62</Volume><PubDate><Year>2019</Year><Month>10</Month></PubDate></JournalIssue><Title>Cellular signalling</Title><ISOAbbreviation>Cell Signal</ISOAbbreviation></Journal><ArticleTitle>PICOT (GLRX3) is a positive regulator of stress-induced DNA-damage response.</ArticleTitle><Pagination><MedlinePgn>109340</MedlinePgn></Pagination><ELocationID EIdType="pii" ValidYN="Y">S0898-6568(19)30130-5</ELocationID><ELocationID EIdType="doi" ValidYN="Y">10.1016/j.cellsig.2019.06.005</ELocationID><Abstract><AbstractText>Protein kinase C (PKC)-interacting cousin of thioredoxin (PICOT; also termed glutaredoxin 3 (Glrx3)) is a ubiquitously expressed protein that possesses an N-terminal monothiol thioredoxin (Trx) domain and two C-terminal tandem copies of a monothiol Glrx domain. It has an overall highly conserved amino acid sequence and is encoded by a unique gene, both in humans and mice, without having other functional gene homologs in the entire genome. Despite being discovered almost two decades ago, the biological function of PICOT remains largely ill-defined and its ramifications are underestimated considering the fact that PICOT-deficiency in mice results in embryonic lethality. Since classical Glrxs are important regulators of the cellular redox homeostasis, we tested whether PICOT participate in the stress-induced DNA-damage response, focusing on nuclear proteins that function as integral components of the DNA repair machinery. Using wild type versus PICOT-deficient (PICOT-KD) Jurkat T cells we found that the anti-oxidant mechanism in PICOT-deficient cells is impaired, and that these cells respond to genotoxic drugs, such as etoposide and camptothecin, by increased caspase-3 activity, a reduced survival and a slower and diminished phosphorylation of the histone protein, H2AX. Nevertheless, the effect of PICOT on the drug-induced phosphorylation of H2AX was independent of the cellular levels of reactive oxygen species. PICOT-deficient cells also demonstrated reduced and slower γH2AX foci formation in response to radiation. Furthermore, immunofluorescence staining using PICOT- and γH2AX-specific Abs followed by confocal microscopy demonstrated partial localization of PICOT at the γH2AX-containing foci at the site of the DNA double strand breaks. In addition, PICOT knockdown resulted in inhibition of phosphorylation of ATR, Chk1 and Chk2 kinases, which play an essential role in the DNA-damage response and serve as upstream regulators of γH2AX. The present data suggest that PICOT protects cells from DNA damage-inducing agents by operating as an upstream positive regulator of ATR-dependent signaling pathways. By promoting the activity of ATR, PICOT indirectly regulates the phosphorylation and activation of Chk1, Chk2, and γH2AX, which are critical components of the DNA damage repair mechanism and thereby attenuate the stress- and replication-induced genome instability.</AbstractText><CopyrightInformation>Copyright © 2019 Elsevier Inc. All rights reserved.</CopyrightInformation></Abstract><AuthorList CompleteYN="Y"><Author ValidYN="Y"><LastName>Pandya</LastName><ForeName>Pinakin</ForeName><Initials>P</Initials><AffiliationInfo><Affiliation>The Shraga Segal Department of Microbiology, Immunology and Genetics, Faculty of Health Sciences and the Cancer Research Center, Ben Gurion University of the Negev, P.O.B. 653, Beer Sheva 84105, Israel.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Braiman</LastName><ForeName>Alex</ForeName><Initials>A</Initials><AffiliationInfo><Affiliation>The Shraga Segal Department of Microbiology, Immunology and Genetics, Faculty of Health Sciences and the Cancer Research Center, Ben Gurion University of the Negev, P.O.B. 653, Beer Sheva 84105, Israel.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Isakov</LastName><ForeName>Noah</ForeName><Initials>N</Initials><AffiliationInfo><Affiliation>The Shraga Segal Department of Microbiology, Immunology and Genetics, Faculty of Health Sciences and the Cancer Research Center, Ben Gurion University of the Negev, P.O.B. 653, Beer Sheva 84105, Israel.. Electronic address: noah@bgu.ac.il.</Affiliation></AffiliationInfo></Author></AuthorList><Language>eng</Language><PublicationTypeList><PublicationType UI="D016428">Journal Article</PublicationType><PublicationType UI="D013485">Research Support, Non-U.S. Gov't</PublicationType></PublicationTypeList><ArticleDate DateType="Electronic"><Year>2019</Year><Month>06</Month><Day>05</Day></ArticleDate></Article><MedlineJournalInfo><Country>England</Country><MedlineTA>Cell Signal</MedlineTA><NlmUniqueID>8904683</NlmUniqueID><ISSNLinking>0898-6568</ISSNLinking></MedlineJournalInfo><ChemicalList><Chemical><RegistryNumber>0</RegistryNumber><NameOfSubstance UI="D002352">Carrier Proteins</NameOfSubstance></Chemical><Chemical><RegistryNumber>0</RegistryNumber><NameOfSubstance UI="C404105">GLRX3 protein, human</NameOfSubstance></Chemical><Chemical><RegistryNumber>0</RegistryNumber><NameOfSubstance UI="C468783">H2AX protein, human</NameOfSubstance></Chemical><Chemical><RegistryNumber>0</RegistryNumber><NameOfSubstance UI="D006657">Histones</NameOfSubstance></Chemical><Chemical><RegistryNumber>52500-60-4</RegistryNumber><NameOfSubstance UI="D013879">Thioredoxins</NameOfSubstance></Chemical><Chemical><RegistryNumber>EC 3.4.22.-</RegistryNumber><NameOfSubstance UI="D053148">Caspase 3</NameOfSubstance></Chemical><Chemical><RegistryNumber>XT3Z54Z28A</RegistryNumber><NameOfSubstance UI="D002166">Camptothecin</NameOfSubstance></Chemical></ChemicalList><CitationSubset>IM</CitationSubset><MeshHeadingList><MeshHeading><DescriptorName UI="D000818" MajorTopicYN="N">Animals</DescriptorName></MeshHeading><MeshHeading><DescriptorName UI="D002166" MajorTopicYN="N">Camptothecin</DescriptorName><QualifierName UI="Q000494" MajorTopicYN="N">pharmacology</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D002352" MajorTopicYN="N">Carrier Proteins</DescriptorName><QualifierName UI="Q000235" MajorTopicYN="Y">genetics</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D053148" MajorTopicYN="N">Caspase 3</DescriptorName><QualifierName UI="Q000235" MajorTopicYN="N">genetics</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D045744" MajorTopicYN="N">Cell Line, Tumor</DescriptorName></MeshHeading><MeshHeading><DescriptorName UI="D053903" MajorTopicYN="N">DNA Breaks, Double-Stranded</DescriptorName><QualifierName UI="Q000528" MajorTopicYN="N">radiation effects</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D004249" MajorTopicYN="N">DNA Damage</DescriptorName><QualifierName UI="Q000187" MajorTopicYN="Y">drug effects</QualifierName><QualifierName UI="Q000235" MajorTopicYN="N">genetics</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D004261" MajorTopicYN="N">DNA Replication</DescriptorName><QualifierName UI="Q000235" MajorTopicYN="N">genetics</QualifierName><QualifierName UI="Q000528" MajorTopicYN="Y">radiation effects</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D016678" MajorTopicYN="N">Genome</DescriptorName><QualifierName UI="Q000528" MajorTopicYN="N">radiation effects</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D006657" MajorTopicYN="N">Histones</DescriptorName><QualifierName UI="Q000235" MajorTopicYN="Y">genetics</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D006801" MajorTopicYN="N">Humans</DescriptorName></MeshHeading><MeshHeading><DescriptorName UI="D019169" MajorTopicYN="N">Jurkat Cells</DescriptorName></MeshHeading><MeshHeading><DescriptorName UI="D051379" MajorTopicYN="N">Mice</DescriptorName></MeshHeading><MeshHeading><DescriptorName UI="D010766" MajorTopicYN="N">Phosphorylation</DescriptorName><QualifierName UI="Q000528" MajorTopicYN="N">radiation effects</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D015398" MajorTopicYN="N">Signal Transduction</DescriptorName><QualifierName UI="Q000528" MajorTopicYN="N">radiation effects</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D013879" MajorTopicYN="N">Thioredoxins</DescriptorName><QualifierName UI="Q000235" MajorTopicYN="N">genetics</QualifierName></MeshHeading></MeshHeadingList><KeywordList Owner="NOTNLM"><Keyword MajorTopicYN="Y">DNA-damage response</Keyword><Keyword MajorTopicYN="Y">GLRX3</Keyword><Keyword MajorTopicYN="Y">Genotoxic stress</Keyword><Keyword MajorTopicYN="Y">H2AX</Keyword><Keyword MajorTopicYN="Y">PICOT</Keyword></KeywordList></MedlineCitation><PubmedData><History><PubMedPubDate PubStatus="received"><Year>2019</Year><Month>04</Month><Day>07</Day></PubMedPubDate><PubMedPubDate PubStatus="revised"><Year>2019</Year><Month>05</Month><Day>15</Day></PubMedPubDate><PubMedPubDate PubStatus="accepted"><Year>2019</Year><Month>06</Month><Day>04</Day></PubMedPubDate><PubMedPubDate PubStatus="pubmed"><Year>2019</Year><Month>6</Month><Day>9</Day><Hour>6</Hour><Minute>0</Minute></PubMedPubDate><PubMedPubDate PubStatus="medline"><Year>2020</Year><Month>8</Month><Day>21</Day><Hour>6</Hour><Minute>0</Minute></PubMedPubDate><PubMedPubDate PubStatus="entrez"><Year>2019</Year><Month>6</Month><Day>9</Day><Hour>6</Hour><Minute>0</Minute></PubMedPubDate></History><PublicationStatus>ppublish</PublicationStatus><ArticleIdList><ArticleId IdType="pubmed">31176019</ArticleId><ArticleId IdType="pii">S0898-6568(19)30130-5</ArticleId><ArticleId IdType="doi">10.1016/j.cellsig.2019.06.005</ArticleId></ArticleIdList></PubmedData></pubmed><affiliations><list><country><li>Israël</li></country></list><tree><country name="Israël"><noRegion><name sortKey="Pandya, Pinakin" sort="Pandya, Pinakin" uniqKey="Pandya P" first="Pinakin" last="Pandya">Pinakin Pandya</name></noRegion><name sortKey="Braiman, Alex" sort="Braiman, Alex" uniqKey="Braiman A" first="Alex" last="Braiman">Alex Braiman</name><name sortKey="Isakov, Noah" sort="Isakov, Noah" uniqKey="Isakov N" first="Noah" last="Isakov">Noah 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