Potential Role of S-Palmitoylation in Cancer Stem Cells of Lung Adenocarcinoma.
- Authors
- Zhang, Yitong; Li, Fenglan; Fu, Kexin; Liu, Xiqing; Lien, I-Chia; Li, Hui
- Year
- 2021
- Journal
- Frontiers in cell and developmental biology
- PMID
- 34621750
- DOI
- 10.3389/fcell.2021.734897
- PMCID
- PMC8490697
S-palmitoylation, catalyzed by a family of 23 zinc finger Asp-His-His-Cys (DHHC) domain-containing (ZDHHC) protein acyltransferases localized on the cell membrane. However, stemness genes modulated by ZDHHCs in lung adenocarcinoma (LUAD) remain to be defined. Previously, we have constructed a network of cancer stem cell genes, including INCENP, based on mRNA stemness indices (mRNAsi) of LUAD. INCENP has the function of a chromosomal passenger complex locating to centromeres, which is performed by the conserved region of its N-terminal domain. INCENP protein with a deletion of the first non-conserved 26 amino acid sequence failed to target centromeres. However, the exact function of the deleted sequence has not been elucidated. To identify novel cancer stem cell-relevant palmitoylated proteins and responsible ZDHHC enzymes in LUAD, we analyzed multi-omics data obtained from the database of The Cancer Genome Atlas (TCGA), Gene Expression Omnibus (GEO), Clinical Proteomic Tumor Analysis Consortium (CPTAC), and the Human Protein Atlas (HPA). ZDHHC5 is distinguished from the ZDHHC family for being up-regulated in mRNA and protein levels and associated with malignant prognosis. ZDHHC5 was positively associated with INCENP, and the correlation score increased with LUAD stages. CSS-Palm results showed Cys was the S-palmitoylation site of INCENP. Interestingly, Cys locates in the 1-26 aa sequence of INCENP, and is a conserved site across species. As INCENP is a nuclear protein, we predicted that the nuclear localization signal of ZDHHC5 was specific to the importin Ξ±Ξ² pathway, and the result of immunofluorescence proves that ZDHHC5 is located in the nucleoplasm, in addition to the plasma membrane. Therefore, our study indicates the S-palmitoylation of INCENP mediated by ZDHHC5 as a potential mechanism of S-palmitoylation to modulate CSCs in LUAD.
General profiling of ZDHHCs family gene expression and survival analysis in LUAD. (A) The heat map shows the RNA-seq results of ZDHHC mRNA in cases from the LUAD data set of TCGA. The LUAD cases are shown separately by clinical stages. The ZDHHCs coding in green indicate lower expression of the LUAD cases than normal tissues, and the red indicates higher expression. The color of scale bar presents high (red) and low (blue) expression, respectively, and the intensity of color indicates the value of mRNA expression. (B) The differential proteomic expression of ZDHHCs in LUAD cases from the CPTAC database. In the bar plot, the length of the bar represents the normalized expression (Z-value) of ZDHHC in LUAD. The color of the bar presents LUAD (red) and normal lung (blue). (C) Heat map of log10 (HR) illustrating the prognosis of ZDHHCs in LUAD patients from the TCGA database. The scale bar presents high (red) and low (blue) risk, respectively, and the intensity indicates the HR. The bounding box around the tiles represent statistically significant cancer types (HR > 1, P < 0.05). HR, hazard ratio; OS, overall survival; DFS, disease free survival. (D) The Venn diagram shows the mapping results of 3 ZDHHC gene sets. Purple, ZDHHCs that are differentially expressed at the mRNA level; red, ZDHHCs that are differentially expressed at the protein level; green, ZDHHCs with prognostic value. *P < 0.05, **P < 0.01, ***P < 0.001.
Expression of ZDHHC5 in LUAD. (A) Fold change of ZDHHC5 differential expression in datasets of lung adenocarcinoma from the GEO and TCGA database. (B) Box plot indicates the differential protein expression of ZDHHC5 in the LUAD sample from CPTAC. Z-value, standard deviations from the median across LUAD samples. **P < 0.01, ***P < 0.001. (C) Distribution of ZDHHC5 expression in LUAD across immune subtypes. (D) Box plot showing mRNA expression of ZDHHC5 in LUAD based on TP53 mutation status. (E) Box plot showing the relative transcription of ZDHHC5 in histological subtypes of LUAD patients. LUAD-not otherwise specified (NOS), LUAD mixed subtype (Mixed), lung solid pattern predominant adenocarcinoma (Solid), lung acinar adenocarcinoma (Acinar), lung micropapillary adenocarcinoma (Micropapillary), lung papillary adenocarcinoma (Papillary). (F) Representative immunohistochemistry results of ZDHHC5 in LUAD. We evaluated histological subtypes to address the heterogeneity of ZDHHC5 in growth patterns of LUAD and normal lung tissues. The histological subtype was classified by a clinical pathologist, and semiquantitative estimations of the different histological patterns present in 5% increments according to the 2015 WHO Classification of Lung Tumors. Enteric adenocarcinoma (Enteric); lepidic adenocarcinoma (Lepidic). (G) Forest plot showing adjusted analysis of ZDHHC5 survival probability on OS in LUAD patients from 17 independent studies. The summarized HR is 1.19, P < 0.05. CI, confidence interval. (H) Kaplan-Meier survival curves of OS and DFS were generated for the comparison of ZDHHC5βs prognostic value in the 3 molecular subtypes of LUAD. The threshold of significance is P < 0.05 in Log-rank test. PP, Proximal-proliferative; PI, proximal-inflammatory; TRU, Terminal respiratory unit.
Correlations of ZDHHC5 and INCENP in LUAD. (A) Data for the top 50 positive and negative ZDHHC5 association genes are visualized in heat maps. (B) Venn diagram showing the mapping results of LUAD stemness genes, ZDHHC5 positive and negative expressed genes. (C) The bar plot shows the RNA-seq results of ZDHHC5 and INCENP in A549, HBEC3, and SCLC-21H cell lines from the HPA database. Normalized expression, NX. (D) Correlation analysis of ZDHHC5 and INCENP according to the pathological stages of LUAD cases from TCGA, using Pearsonβs correlation tests. (E) The enriched KEGG pathway result clustered by weighted set cover. In the volcano plots, the intensity of color and jitter size indicates the number of the elements in each pathway. (F) GSEA results of cell cycle (hsa04110). NES, normalized enrichment score.
Palmitoylation sites of INCENP and its function in cancer stem cell. (A) The palmitoylation sites prediction for INCENP was performed by CCS-Palm 4.0, with the INCENP protein sequence. Cysteine, Cys, C. The color presents high (pink), medium (blue) and low (blue) palmitoylation score, respectively. The significant domains were marked pink (6-41, INCENP_N), and blue (825-881, INCENP ARK-bind). The region surrounding Cys15 is shown in detail (bottom). (B) The first 26 amino acid sequences of the INCENP across species. (C) PPI networks of LUAD stemness genes having direct interaction with INCENP.
ZDHHC5 is the only nuclear ZDHHC family member correlated with INCENP. (A) Results of ZDHHCs nuclear localization signals (NLSs) are shown in the heatmap, calculated by cNLS Mapper. The cNLS Mapper scans the protein sequence with a window size of 16 amino acid residues for monopartite NLSs and 26β28 amino acid residues for bipartite NLSs. (B) Immunofluorescence images (HPA) show the subcellular localization of the nuclear ZDHHC proteins (green) with reference DAPI (blue) for the nucleus in cell lines. (C) Pearson correlation analysis of INCENP and ZDHHCs in the LUAD. The color represents the corresponding correlation value. Red, positive association; green, negative association. |Pearson coefficient| > 0.3 and P < 0.05 is significant. *P < 0.05, **P < 0.01, ***P < 0.001.
| Name | Type |
|---|---|
| 17 independent cohorts local | cohort |
| A549 local | cohort |
| acinar local | phenotype |
| Acinar local | phenotype |
| air pollution | drug |
| Bild_2006 local | cohort |
| Borealin local | gene |
| Botling_2013 local | cohort |
| C1 local | phenotype |
| C3 local | other |
| C3 local | phenotype |
| C4 local | other |
| C4 local | phenotype |
| cancer | phenotype |
| Cancer Genome Atlas Research Network local | cohort |
| cancer stem cells local | phenotype |
| Cancer stem cells local | phenotype |
| Cancer treatment resistance local | phenotype |
| cell proliferation | phenotype |
| Cell Type Atlas of the HPA local | cohort |
| cigarettes | phenotype |
| colony formation local | phenotype |
| CPTAC local | cohort |
| CPTAC Confirmatory cohort local | cohort |
| CPTAC Confirmatory/Discovery cohorts local | cohort |
| CPTAC Discovery cohort local | cohort |
| CSCs local | phenotype |
| Cys15 local | variant |
| DAPI | drug |
| deliberation | phenotype |
| Der_2014 local | cohort |
| disease-free survival local | phenotype |
| Disease-free Survival local | phenotype |
| Disease-Free Survival local | phenotype |
| disease progression | phenotype |
| Egfr | gene |
| EGFRβTKI local | drug |
| EGFRβTKI resistance NSCLC cells local | phenotype |
| enteric local | phenotype |
| favorable prognosis local | phenotype |
| GDC local | cohort |
| GEO local | cohort |
| GEO database local | cohort |
| Girard_N_c local | cohort |
| Glioblastoma multiforme local | phenotype |
| glioma | phenotype |
| glioma stem cells | phenotype |
| good prognosis local | phenotype |
| Growth factor local | drug |
| GSC angiogenic potential local | phenotype |
| GSC invasive potential local | phenotype |
| GSC migratory potential local | phenotype |
| GSC self-renewal capacity local | phenotype |
| GSC tumorigenicity local | phenotype |
| HBEC3 local | cohort |
| HBEC lines local | cohort |
| High-Expression Cohort local | cohort |
| Hou_2010 local | cohort |
| HPA antibody local | drug |
| HPA Cell Atlas local | cohort |
| HPA Cell Type Atlas local | cohort |
| HPA database local | cohort |
| HPA Pathology Atlas local | cohort |
| HPA Tissue Atlas local | cohort |
| Human Protein Atlas | cohort |
| I-CL local | cohort |
| IFN-Ξ³ | drug |
| immune subtypes local | phenotype |
| immunomodulators local | drug |
| importin Ξ±Ξ² pathway local | drug |
| INCENP local | gene |
| INCENP_N local | gene |
| intermediate local | phenotype |
| intermediate prognosis local | phenotype |
| Jones_2004 local | cohort |
| Kidney renal clear cell carcinoma local | phenotype |
| kinase fusions local | phenotype |
| KRAS | gene |
| Kuner_2009 local | cohort |
| lepidic local | phenotype |
| Lepidic histomorphology local | phenotype |
| Low-Expression Cohort local | cohort |
| LUAD local | cohort |
| LUAD cohorts (17 independent, 2244 cases) local | cohort |
| lung adenocarcinoma | phenotype |
| lung cancer | phenotype |
| Lung Cancer Explorer local | cohort |
| lung cancer patients | cohort |
| lung cell lines local | cohort |
| Lung squamous cell carcinoma local | phenotype |
| Malignant progression local | phenotype |
| micropapillary local | phenotype |
| mRNAsi index local | drug |
| NCBI GEO local | cohort |
| neural stem cells | cohort |
| neuronal differentiation | phenotype |
| NF1 local | gene |
| non-small cell lung cancer | phenotype |
| normal lung tissue local | cohort |
| normal lung tissue local | phenotype |
| normal samples | cohort |
| Normal stem cells local | phenotype |
| Normal tissue local | phenotype |
| NSCLC | phenotype |
| NSCLC cell lines local | cohort |
| NSCLC cohort (194 patients) local | cohort |
| OCLR algorithm local | drug |
| Okayama_2012 local | cohort |
| order | phenotype |
| ovarian cancer | phenotype |
| overall survival | phenotype |
| p16 methylation local | phenotype |
| palmitate | drug |
| palmitoylation local | drug |
| Palmitoylation local | drug |
| papillary local | phenotype |
| Papillary local | phenotype |
| PI local | cohort |
| PP local | cohort |
| relapse | phenotype |
| Rousseaux_2013 local | cohort |
| Sato_2013 local | cohort |
| Schabath_2016 local | cohort |
| sex | phenotype |
| Shedden_2008 local | cohort |
| Single Cell Type Atlas local | cohort |
| smoking habits local | phenotype |
| solid local | phenotype |
| solid architecture local | phenotype |
| S-palmitoylation local | drug |
| Staaf_2012 local | cohort |
| Stem-like properties local | phenotype |
| Stemness index (mRNAsi) local | phenotype |
| STK11 | gene |
| Survivin local | gene |
| Systemic disease local | phenotype |
| Takeuchi_2006 local | cohort |
| Tang_2013 local | cohort |
| TCGA | cohort |
| TCGA Consortium local | cohort |
| TCGA database local | cohort |
| TCGA_LUAD_2016 local | cohort |
| TGF-Ξ² | drug |
| The Cancer Genome Atlas | cohort |
| TISIDB local | cohort |
| Tomida_2009 local | cohort |
| TP53 | gene |
| TRU local | cohort |
| TRU subtype local | phenotype |
| tumor dedifferentiation local | phenotype |
| tumor-infiltrating lymphocytes local | phenotype |
| UALCAN3 local | drug |
| WGCNA local | drug |
| WHO classification 2015 local | cohort |
| Wikerson_2012 local | cohort |
| women who never smoked local | phenotype |
| worse prognosis | phenotype |
| ZDHHC local | gene |
| ZDHHC12 local | gene |
| ZDHHC14 local | gene |
| ZDHHC15 local | gene |
| ZDHHC16 local | gene |
| ZDHHC17 local | gene |
| ZDHHC18 local | gene |
| ZDHHC23 local | gene |
| ZDHHC5 | gene |
| ZDHHC8 | gene |
| ZDHHC family local | gene |
| ZDHHC proteins local | gene |
| ZDHHCs local | gene |
| ZDHHCs protein local | gene |
| Zhu_2010 local | cohort |
No uploaded files.
| Citation | PMID | DOI | Status |
|---|---|---|---|
| AinszteinA. M.Kandels-LewisS. E.MackayA. M.EarnshawW. C. (1998). INCENP centromere and spindle targeting: identification of essential conserved motifs and involvement of heterochromatin protein HP1. J. Cell Biol. 143 1763β1774. 10.1083/jcb.143.7.1763 9864353PMC2175214 | β | β | β |
| AliA.LevantiniE.TeoJ. T.GoggiJ.ClohessyJ. G.WuC. S. (2018). Fatty acid synthase mediates EGFR palmitoylation in EGFR mutated non-small cell lung cancer. EMBO Mol. Med. 10:e8313. 10.15252/emmm.201708313 29449326PMC5840543 | β | β | β |
| BeckerM.StolzA.ErtychN.BastiansH. (2010). Centromere localization of INCENP-Aurora B is sufficient to support spindle checkpoint function. Cell Cycle 9 1360β1372. 10.4161/cc.9.7.11177 20372054 | β | β | β |
| CaiL.LinS.GirardL.ZhouY.YangL.CiB. (2019). LCE: an open web portal to explore gene expression and clinical associations in lung cancer. Oncogene 38 2551β2564. 10.1038/s41388-018-0588-2 30532070PMC6477796 | β | β | β |
| Cancer Genome Atlas Research Network (2014). Comprehensive molecular profiling of lung adenocarcinoma. Nature 511 543β550. 10.1038/nature13385 25079552PMC4231481 | β | β | β |
| ChanP.HanX.ZhengB.DeRanM.YuJ.JarugumilliG. K. (2016). Autopalmitoylation of TEAD proteins regulates transcriptional output of the Hippo pathway. Nat. Chem. Biol. 12 282β289. 10.1038/nchembio.2036 26900866PMC4798901 | β | β | β |
| ChenX.HaoA.LiX.YeK.ZhaoC.YangH. (2020a). Activation of JNK and p38 MAPK Mediated by ZDHHC17 Drives Glioblastoma Multiforme Development and Malignant Progression. Theranostics 10 998β1015. 10.7150/thno.40076 31938047PMC6956818 | β | β | β |
| ChenX.HuL.YangH.MaH.YeK.ZhaoC. (2019). DHHC protein family targets different subsets of glioma stem cells in specific niches. J. Exp. Clin. Cancer Res. 38:25. 10.1186/s13046-019-1033-2 30658672PMC6339410 | β | β | β |
| ChenX.LiH.FanX.ZhaoC.YeK.ZhaoZ. (2020b). Protein Palmitoylation Regulates Cell Survival by Modulating XBP1 Activity in Glioblastoma Multiforme. Mol. Ther. Oncolytics 17 518β530. 10.1016/j.omto.2020.05.007 33024813PMC7525067 | β | β | β |
| ChenX.MaH.WangZ.ZhangS.YangH.FangZ. (2017). EZH2 Palmitoylation Mediated by ZDHHC5 in p53-Mutant Glioma Drives Malignant Development and Progression. Cancer Res. 77 4998β5010. 10.1158/0008-5472.CAN-17-1139 28775165 | β | β | β |
| Codony-ServatJ.Codony-ServatC.CardonaA. F.GimΓ©nez-CapitΓ‘nA.DrozdowskyjA.BerenguerJ. (2019). Cancer Stem Cell Biomarkers in EGFR-Mutation-Positive Non-Small-Cell Lung Cancer. Clin. Lung Cancer 20 167β177. 10.1016/j.cllc.2019.02.005 30885551 | β | β | β |
| DunphyJ. T.LinderM. E. (1998). Signalling functions of protein palmitoylation. Biochim. Biophys. Acta 1436 245β261. 10.1016/s0005-2760(98)00130-19838145 | β | β | β |
| FukataY.BredtD. S.FukataM. (2006). βProtein Palmitoylation by DHHC Protein Family,β in The Dynamic Synapse: Molecular Methods in Ionotropic Receptor Biology, eds KittlerJ. T.MossS. J. (Boca Raton: CRC Press), 83β88. | β | β | β |
| JiangH.ZhangX.ChenX.AramsangtienchaiP.TongZ.LinH. (2018). Protein lipidation: occurrence, mechanisms, biological functions, and enabling technologies. Chem. Rev. 118 919β988. 10.1021/acs.chemrev.6b00750 29292991PMC5985209 | β | β | β |
| KleinU. R.NiggE. A.GrunebergU. (2006). Centromere targeting of the chromosomal passenger complex requires a ternary subcomplex of Borealin, Survivin, and the N-terminal domain of INCENP. Mol. Biol. Cell 17 2547β2558. 10.1091/mbc.e05-12-1133 16571674PMC1474794 | β | β | β |
| KoP. J.DixonS. J. (2018). Protein palmitoylation and cancer. EMBO Rep. 19:e46666. 10.15252/embr.201846666 30232163PMC6172454 | β | β | β |
| KuhnE.MorbiniP.CancellieriA.DamianiS.CavazzaA.CominC. E. (2018). Adenocarcinoma classification: patterns and prognosis. Pathologica 110 5β11.30259909 | β | β | β |
| Lanyon-HoggT.FaronatoM.SerwaR. A.TateE. W. (2017). Dynamic protein acylation: new substrates, mechanisms, and drug targets. Trends Biochem. Sci. 42 566β581. 10.1016/j.tibs.2017.04.004 28602500 | β | β | β |
| LeΓ£oR.DomingosC.FigueiredoA.HamiltonR.TaboriU.Castelo-BrancoP. (2017). Cancer Stem Cells in Prostate Cancer: implications for Targeted Therapy. Urol. Int. 99 125β136. 10.1159/000455160 28142149 | β | β | β |
| LiuZ.LiuC.XiaoM.HanY.ZhangS.XuB. (2020). Bioinformatics Analysis of the Prognostic and Biological Significance of ZDHHC-Protein Acyltransferases in Kidney Renal Clear Cell Carcinoma. Front. Oncol. 10:565414. 10.3389/fonc.2020.565414 33364189PMC7753182 | β | β | β |
| LiY.MartinB. R.CravattB. F.HofmannS. L. (2012). DHHC5 protein palmitoylates flotillin-2 and is rapidly degraded on induction of neuronal differentiation in cultured cells. J. Biol. Chem. 287 523β530. 10.1074/jbc.M111.306183 22081607PMC3249106 | β | β | β |
| Lortet-TieulentJ.SoerjomataramI.FerlayJ.RutherfordM.WeiderpassE.BrayF. (2014). International trends in lung cancer incidence by histological subtype: adenocarcinoma stabilizing in men but still increasing in women. Lung Cancer 84 13β22. 10.1016/j.lungcan.2014.01.009 24524818 | β | β | β |
| MaccalliC.RasulK. I.ElawadM.FerroneS. (2018). The role of cancer stem cells in the modulation of anti-tumor immune responses. Semin. Cancer Biol. 53 189β200. 10.1016/j.semcancer.2018.09.006 30261276PMC8668198 | β | β | β |
| MaltaT. M.SokolovA.GentlesA. J.BurzykowskiT.PoissonL.WeinsteinJ. N. (2018). Machine Learning Identifies Stemness Features Associated with Oncogenic Dedifferentiation. Cell 173 338β354.e15. 10.1016/j.cell.2018.03.034 29625051PMC5902191 | β | β | β |
| MiyataT.YoshimatsuT.SoT.OyamaT.UramotoH.OsakiT. (2015). Cancer stem cell markers in lung cancer. Pers. Med. Univ. 4 40β45. 10.1016/j.pmu.2015.03.007 | β | β | β |
| PercherancierY.PlanchenaultT.Valenzuela-FernandezA.VirelizierJ. L.Arenzana-SeisdedosF.BachelerieF. (2001). Palmitoylation-dependent control of degradation, life span, and membrane expression of the CCR5 receptor. J. Biol. Chem. 276 31936β31944. 10.1074/jbc.M104013200 11390405 | β | β | β |
| RenJ.WenL.GaoX.JinC.XueY.YaoX. (2008). CSS-Palm 2.0: an updated software for palmitoylation sites prediction. Protein Eng. Des. Sel. 21 639β644. 10.1093/protein/gzn039 18753194PMC2569006 | β | β | β |
| ReshM. D. (2017). Palmitoylation of proteins in cancer. Biochem. Soc. Trans. 45 409β416. 10.1042/BST20160233 28408481 | β | β | β |
| RiccioA. (2010). Dynamic epigenetic regulation in neurons: enzymes, stimuli and signaling pathways. Nat. Neurosci. 13 1330β1337. 10.1038/nn.2671 20975757 | β | β | β |
| RuB.WongC. N.TongY.ZhongJ. Y.ZhongS. S. W.WuW. C. (2019). TISIDB: an integrated repository portal for tumor-immune system interactions. Bioinformatics 35 4200β4202. 10.1093/bioinformatics/btz210 30903160 | β | β | β |
| Ruiz-CorderoR.DevineW. P. (2020). Targeted Therapy and Checkpoint Immunotherapy in Lung Cancer. Surg. Pathol. Clin. 13 17β33. 10.1016/j.path.2019.11.002 32005431 | β | β | β |
| SheddenK.TaylorJ. M.EnkemannS. A.TsaoM. S.YeatmanT. J.GeraldW. L. (2008). Gene expression-based survival prediction in lung adenocarcinoma: a multi-site, blinded validation study. Nat. Med. 14 822β827. 10.1038/nm.1790 18641660PMC2667337 | β | β | β |
| SokolovA.PaullE. O.StuartJ. M. (2016). ONE-CLASS DETECTION OF CELL STATES IN TUMOR SUBTYPES. Pac. Symp. Biocomput. 21 405β416. 10.1142/9789814749411_003726776204PMC4856035 | β | β | β |
| SpinelliM.FuscoS.GrassiC. (2018). Nutrient-Dependent Changes of Protein Palmitoylation: impact on Nuclear Enzymes and Regulation of Gene Expression. Int. J. Mol. Sci. 19:3820. 10.3390/ijms19123820 30513609PMC6320809 | β | β | β |
| SubramanianA.TamayoP.MoothaV. K.MukherjeeS.EbertB. L.GilletteM. A. (2005). Gene set enrichment analysis: a knowledge-based approach for interpreting genome-wide expression profiles. Proc. Natl. Acad. Sci. U. S. A. 102 15545β15550. 10.1073/pnas.0506580102 16199517PMC1239896 | β | β | β |
| ThorssonV.GibbsD. L.BrownS. D.WolfD.BortoneD. S.Ou YangT. H. (2018). The Immune Landscape of Cancer. Immunity 48 812β830.e14. 10.1016/j.immuni.2018.03.023 29628290PMC5982584 | β | β | β |
| ThulP. J.Γ kessonL.WikingM.MahdessianD.GeladakiA.Ait BlalH. (2017). A subcellular map of the human proteome. Science 356:eaal3321. 10.1126/science.aal3321 28495876 | β | β | β |
| TianH.LuJ. Y.ShaoC.HuffmanK. E.CarstensR. M.LarsenJ. E. (2015). Systematic siRNA Screen Unmasks NSCLC Growth Dependence by Palmitoyltransferase DHHC5. Mol. Cancer Res. 13 784β794. 10.1158/1541-778625573953PMC4398612 | β | β | β |
| TravisW. D.BrambillaE.NicholsonA. G.YatabeY.AustinJ. H. M.BeasleyM. B. (2015). The 2015 World Health Organization Classification of Lung Tumors: impact of Genetic, Clinical and Radiologic Advances Since the 2004 Classification. J. Thorac. Oncol. 10 1243β1260. 10.1097/JTO.0000000000000630 26291008 | β | β | β |
| UhlenM.ZhangC.LeeS.SjΓΆstedtE.FagerbergL.BidkhoriG. (2017). A pathology atlas of the human cancer transcriptome. Science 357:eaan2507. 10.1126/science.aan2507 28818916 | β | β | β |
| UhlΓ©nM.BjΓΆrlingE.AgatonC.SzigyartoC. A.AminiB.AndersenE. (2005). A human protein atlas for normal and cancer tissues based on antibody proteomics. Mol. Cell Proteomics 4 1920β1932. 10.1074/mcp.M500279-MCP200 16127175 | β | β | β |
| UhlΓ©nM.FagerbergL.HallstrΓΆmB. M.LindskogC.OksvoldP.MardinogluA. (2015). Proteomics. Tissue-based map of the human proteome. Science 347:1260419. 10.1126/science.1260419 25613900 | β | β | β |
| VaderG.KauwJ. J.MedemaR. H.LensS. M. (2006). Survivin mediates targeting of the chromosomal passenger complex to the centromere and midbody. EMBO Rep. 7 85β92. 10.1038/sj.embor.7400562 16239925PMC1369225 | β | β | β |
| VasaikarS. V.StraubP.WangJ.ZhangB. (2018). LinkedOmics: analyzing multi-omics data within and across 32 cancer types. Nucleic Acids Res. 46 D956βD963. 10.1093/nar/gkx1090 29136207PMC5753188 | β | β | β |
| WadowskaK.Bil-LulaI.TrembeckiΕΕliwiΕska-MossoΕM. (2020). Genetic Markers in Lung Cancer Diagnosis: a Review. Int. J. Mol. Sci. 21:4569. 10.3390/ijms21134569 32604993PMC7369725 | β | β | β |
| WilsonJ. P.RaghavanA. S.YangY. Y.CharronG.HangH. C. (2011). Proteomic analysis of fatty-acylated proteins in mammalian cells with chemical reporters reveals S-acylation of histone H3 variants. Mol. Cell Proteomics 10:M110.001198. 10.1074/mcp.M110.001198 21076176PMC3047146 | β | β | β |
| XiaR.ChenS.ChenY.ZhangW.ZhuR.DengA. (2015). A chromosomal passenger complex protein signature model predicts poor prognosis for non-small-cell lung cancer. Onco Targets Ther. 8 721β726. 10.2147/OTT.S81328 25897247PMC4396580 | β | β | β |
| YuanM.ChenX.SunY.JiangL.XiaZ.YeK. (2020). ZDHHC12-mediated claudin-3 S-palmitoylation determines ovarian cancer progression. Acta Pharm. Sin. B. 10 1426β1439. 10.1016/j.apsb.2020.03.008 32963941PMC7488353 | β | β | β |
| ZhangY.TsengJ. T.LienI. C.LiF.WuW.LiH. (2020). mRNAsi Index: machine Learning in Mining Lung Adenocarcinoma Stem Cell Biomarkers. Genes 11:257. 10.3390/genes11030257 32121037PMC7140876 | β | β | β |
In this knowledge base
| Title | Year | PMID |
|---|---|---|
| Genome-wide analyses identify 30 loci associated with obsessive-compulsive disorder. | 2025 | 40360802 |
External
| Title | Authors | Journal | Year | Link |
|---|---|---|---|---|
| A comprehensive analysis of palmitoylation related genes in lung adenocarcinoma. | Jiang J et al. | β | 2026 | β |
| Development and Assessment of a Novel Palmitoylation-Related lncRNA Signature for Prognosis and Immune Landscape in Hepatocellular Carcinoma. | He Z et al. | β | 2026 | β |
| Prognostic value of palmitoylation-regulated mechanisms in glioblastoma: integrated multi-omics analysis via least absolute shrinkage and selection operator (LASSO) regression and single-cell sequencing. | Ji Y et al. | β | 2026 | β |
| Causal relationship between palmitoylation genes mediated by immune cell phenotypes and oral cancer: A Mendelian randomized study. | Jiang ZH et al. | β | 2025 | β |
| Genome-wide analyses identify 30 loci associated with obsessive-compulsive disorder. | Strom NI et al. | β | 2025 | β |
| Identification of selective plant-derived natural carotenoid and flavonoids as the potential inhibitors of DHHC-mediated protein <i>S-</i>palmitoylation: an <i>in silico</i> study. | Chaturvedi S et al. | β | 2025 | β |
| Interplay of disulfidptosis and the tumor microenvironment across cancers: implications for prognosis and therapeutic responses. | Xu S et al. | β | 2025 | β |
| Kinesin genes KIF4A, KIF20A and KIF11 as prognostic biomarkers in lung adenocarcinoma by integrative bioinformatic analysis and experimental validation. | Wang H et al. | β | 2025 | β |
| Multi-omics-based construction of a palmitoylation-driven prognostic model reveals tumor immune phenotypes in osteosarcoma. | Chen J et al. | β | 2025 | β |
| Palmitoylation in cancer: decoding its roles in signal transduction, tumor immunity, and emerging therapeutic opportunities. | Lu Q et al. | β | 2025 | β |
| Palmitoylation in cardiovascular diseases: Molecular mechanism and therapeutic potential. | Wang R et al. | β | 2025 | β |
| Recent advances in S-palmitoylation and its emerging roles in human diseases. | Shang J et al. | β | 2025 | β |
| [Research Progress and Applications of ZDHHC-mediated Protein Palmitoylation β©in the Development and Immune Escape of Non-small Cell Lung Cancer]. | Chen W et al. | β | 2025 | β |
| Restoration of Osimertinib sensitivity in lung cancer through BRD4 inhibitor-mediated depalmitoylation of mutant EGFR via APT1. | Zhou W et al. | β | 2025 | β |
| S100P is a core gene for diagnosing and predicting the prognosis of sepsis. | Shen YZ et al. | β | 2025 | β |
| Straight A's: protein acylation in the S-activation and autophagic degradation of NOD-like receptors. | Martin NR et al. | β | 2025 | β |
| The cancer stem cells characteristics analysis of LGR5β+βcells that influence lung cancer risk by using single cell RNA-seq analysis. | Wen G et al. | β | 2025 | β |
| The role of protein S-acylation in vascular injury associated with metabolic disorders. | Wang Y et al. | β | 2025 | β |
| ZDHHC5 as a central regulator in a palmitoylation-associated prognostic model for lung adenocarcinoma: insights from pan-cancer and experimental analyses. | Wu S et al. | β | 2025 | β |
| ABHD7-mediated depalmitoylation of lamin A promotes myoblast differentiation. | Shen Y et al. | β | 2024 | β |
| Design, synthesis and biological activity evaluation of novel covalent S-acylation inhibitors. | Yu W et al. | β | 2024 | β |
| Genome-wide analyses identify 30 loci associated with obsessive-compulsive disorder | Strom NI et al. | β | 2024 | β |
| Inhibition of palmitoyltransferase ZDHHC12 sensitizes ovarian cancer cells to cisplatin through ROS-mediated mechanisms. | Zhang X et al. | β | 2024 | β |
| Recapitulating the potential contribution of protein S-palmitoylation in cancer. | Chaturvedi S et al. | β | 2024 | β |
| C-Phycocyanin Ameliorates the Senescence of Mesenchymal Stem Cells through ZDHHC5-Mediated Autophagy via PI3K/AKT/mTOR Pathway. | Liu G et al. | β | 2023 | β |
| Involvement of ZDHHC9 in lung adenocarcinoma: regulation of PD-L1 stability via palmitoylation. | Li Z et al. | β | 2023 | β |
| ZDHHC11B is decreased in lung adenocarcinoma and inhibits tumorigenesis via regulating epithelial-mesenchymal transition. | Dai H et al. | β | 2023 | β |
| Hypomethylation-induced prognostic marker zinc finger DHHC-type palmitoyltransferase 12 contributes to glioblastoma progression. | Lu F et al. | β | 2022 | β |
| Post-Translational Modifications by Lipid Metabolites during the DNA Damage Response and Their Role in Cancer. | Zhu G et al. | β | 2022 | β |
| PRDX6: A protein bridging S-palmitoylation and diabetic neuropathy. | Cao Y et al. | β | 2022 | β |