Detail Information of Post-Translational Modifications

General Information of Drug Transporter (DT)
DT ID DTD0338 Transporter Info
Gene Name SLC39A10
Transporter Name Zinc transporter ZIP10
Gene ID
57181
UniProt ID
Q9ULF5
Post-Translational Modification of This DT
Overview of SLC39A10 Modification Sites with Functional and Structural Information
Sequence
PTM type
X-N-glycosylation X-O-glycosylation X-Phosphorylation X-S-palmitoylation X-Ubiquitination X: Amino Acid

N-glycosylation

  Asparagine

           4 PTM Phenomena Related to This Residue Click to Show/Hide the Full List

  PTM Phenomenon 1

 Have the potential to influence SLC39A10 [1]

Role of PTM

 Potential impacts

Modified Residue

 Asparagine

Modified Location

 139

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 N-linked Glycosylation at SLC39A10 Asparagine 139 has the potential to affect its expression or activity.

  PTM Phenomenon 2

 Have the potential to influence SLC39A10 [1]

Role of PTM

 Potential impacts

Modified Residue

 Asparagine

Modified Location

 198

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 N-linked Glycosylation at SLC39A10 Asparagine 198 has the potential to affect its expression or activity.

  PTM Phenomenon 3

 Have the potential to influence SLC39A10 [1]

Role of PTM

 Potential impacts

Modified Residue

 Asparagine

Modified Location

 218

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 N-linked Glycosylation at SLC39A10 Asparagine 218 has the potential to affect its expression or activity.

  PTM Phenomenon 4

 Have the potential to influence SLC39A10 [1]

Role of PTM

 Potential impacts

Modified Residue

 Asparagine

Modified Location

 339

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 N-linked Glycosylation at SLC39A10 Asparagine 339 has the potential to affect its expression or activity.

O-glycosylation

  Serine

           1 PTM Phenomena Related to This Residue Click to Show/Hide the Full List

  PTM Phenomenon 1

 Have the potential to influence SLC39A10 [1]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 210

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 O-linked Glycosylation at SLC39A10 Serine 210 has the potential to affect its expression or activity.

  Threonine

           1 PTM Phenomena Related to This Residue Click to Show/Hide the Full List

  PTM Phenomenon 1

 Have the potential to influence SLC39A10 [1]

Role of PTM

 Potential impacts

Modified Residue

 Threonine

Modified Location

 248

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 O-linked Glycosylation at SLC39A10 Threonine 248 has the potential to affect its expression or activity.

Phosphorylation

  Serine

         14 PTM Phenomena Related to This Residue Click to Show/Hide the Full List

  PTM Phenomenon 1

 Have the potential to influence SLC39A10 [2]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 323

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Serine 323 has the potential to affect its expression or activity.

  PTM Phenomenon 2

 Have the potential to influence SLC39A10 [3] , [4]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 353

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Serine 353 has the potential to affect its expression or activity.

  PTM Phenomenon 3

 Have the potential to influence SLC39A10 [4]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 356

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Serine 356 has the potential to affect its expression or activity.

  PTM Phenomenon 4

 Have the potential to influence SLC39A10 [4]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 373

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Serine 373 has the potential to affect its expression or activity.

  PTM Phenomenon 5

 Have the potential to influence SLC39A10 [5] , [6]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 539

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Serine 539 has the potential to affect its expression or activity.

  PTM Phenomenon 6

 Have the potential to influence SLC39A10 [7] , [8]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 546

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Serine 546 has the potential to affect its expression or activity.

  PTM Phenomenon 7

 Have the potential to influence SLC39A10 [9] , [10]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 556

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Serine 556 has the potential to affect its expression or activity.

  PTM Phenomenon 8

 Have the potential to influence SLC39A10 [3] , [11]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 570

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Serine 570 has the potential to affect its expression or activity.

  PTM Phenomenon 9

 Have the potential to influence SLC39A10 [3] , [11]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 573

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Serine 573 has the potential to affect its expression or activity.

  PTM Phenomenon 10

 Have the potential to influence SLC39A10 [3] , [12]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 591

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Serine 591 has the potential to affect its expression or activity.

  PTM Phenomenon 11

 Have the potential to influence SLC39A10 [10]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 608

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Serine 608 has the potential to affect its expression or activity.

  PTM Phenomenon 12

 Have the potential to influence SLC39A10 [10]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 610

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Serine 610 has the potential to affect its expression or activity.

  PTM Phenomenon 13

 Have the potential to influence SLC39A10 [10]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 648

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Serine 648 has the potential to affect its expression or activity.

  PTM Phenomenon 14

 Have the potential to influence SLC39A10 [10]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 651

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Serine 651 has the potential to affect its expression or activity.

  Threonine

         11 PTM Phenomena Related to This Residue Click to Show/Hide the Full List

  PTM Phenomenon 1

 Have the potential to influence SLC39A10 [4]

Role of PTM

 Potential impacts

Modified Residue

 Threonine

Modified Location

 357

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Threonine 357 has the potential to affect its expression or activity.

  PTM Phenomenon 2

 Have the potential to influence SLC39A10 [3] , [4]

Role of PTM

 Potential impacts

Modified Residue

 Threonine

Modified Location

 361

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Threonine 361 has the potential to affect its expression or activity.

  PTM Phenomenon 3

 Have the potential to influence SLC39A10 [13] , [14]

Role of PTM

 Potential impacts

Modified Residue

 Threonine

Modified Location

 536

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Threonine 536 has the potential to affect its expression or activity.

  PTM Phenomenon 4

 Have the potential to influence SLC39A10 [3] , [6]

Role of PTM

 Potential impacts

Modified Residue

 Threonine

Modified Location

 540

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Threonine 540 has the potential to affect its expression or activity.

  PTM Phenomenon 5

 Have the potential to influence SLC39A10 [3] , [14]

Role of PTM

 Potential impacts

Modified Residue

 Threonine

Modified Location

 553

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Threonine 553 has the potential to affect its expression or activity.

  PTM Phenomenon 6

 Have the potential to influence SLC39A10 [3] , [15]

Role of PTM

 Potential impacts

Modified Residue

 Threonine

Modified Location

 567

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Threonine 567 has the potential to affect its expression or activity.

  PTM Phenomenon 7

 Have the potential to influence SLC39A10 [3] , [16]

Role of PTM

 Potential impacts

Modified Residue

 Threonine

Modified Location

 580

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Threonine 580 has the potential to affect its expression or activity.

  PTM Phenomenon 8

 Have the potential to influence SLC39A10 [3] , [17]

Role of PTM

 Potential impacts

Modified Residue

 Threonine

Modified Location

 583

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Threonine 583 has the potential to affect its expression or activity.

  PTM Phenomenon 9

 Have the potential to influence SLC39A10 [10]

Role of PTM

 Potential impacts

Modified Residue

 Threonine

Modified Location

 615

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Threonine 615 has the potential to affect its expression or activity.

  PTM Phenomenon 10

 Have the potential to influence SLC39A10 [18]

Role of PTM

 Potential impacts

Modified Residue

 Threonine

Modified Location

 634

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Threonine 634 has the potential to affect its expression or activity.

  PTM Phenomenon 11

 Have the potential to influence SLC39A10 [19]

Role of PTM

 Potential impacts

Modified Residue

 Threonine

Modified Location

 750

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Threonine 750 has the potential to affect its expression or activity.

  Tyrosine

           7 PTM Phenomena Related to This Residue Click to Show/Hide the Full List

  PTM Phenomenon 1

 Have the potential to influence SLC39A10 [3] , [4]

Role of PTM

 Potential impacts

Modified Residue

 Tyrosine

Modified Location

 346

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Tyrosine 346 has the potential to affect its expression or activity.

  PTM Phenomenon 2

 Have the potential to influence SLC39A10 [4]

Role of PTM

 Potential impacts

Modified Residue

 Tyrosine

Modified Location

 347

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Tyrosine 347 has the potential to affect its expression or activity.

  PTM Phenomenon 3

 Have the potential to influence SLC39A10 [4]

Role of PTM

 Potential impacts

Modified Residue

 Tyrosine

Modified Location

 362

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Tyrosine 362 has the potential to affect its expression or activity.

  PTM Phenomenon 4

 Have the potential to influence SLC39A10 [4]

Role of PTM

 Potential impacts

Modified Residue

 Tyrosine

Modified Location

 369

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Tyrosine 369 has the potential to affect its expression or activity.

  PTM Phenomenon 5

 Have the potential to influence SLC39A10 [16] , [17]

Role of PTM

 Potential impacts

Modified Residue

 Tyrosine

Modified Location

 596

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Tyrosine 596 has the potential to affect its expression or activity.

  PTM Phenomenon 6

 Have the potential to influence SLC39A10 [19]

Role of PTM

 Potential impacts

Modified Residue

 Tyrosine

Modified Location

 734

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Tyrosine 734 has the potential to affect its expression or activity.

  PTM Phenomenon 7

 Have the potential to influence SLC39A10 [19]

Role of PTM

 Potential impacts

Modified Residue

 Tyrosine

Modified Location

 743

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC39A10 Tyrosine 743 has the potential to affect its expression or activity.

S-palmitoylation

  Cystine

           1 PTM Phenomena Related to This Residue Click to Show/Hide the Full List

  PTM Phenomenon 1

 Have the potential to influence SLC39A10 [20]

Role of PTM

 Potential impacts

Modified Residue

 Cystine

Modified Location

 435

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 S-palmitoylation at SLC39A10 Cystine 435 has the potential to affect its expression or activity.

Ubiquitination

  Glutamicacid

           1 PTM Phenomena Related to This Residue Click to Show/Hide the Full List

  PTM Phenomenon 1

 Have the potential to influence SLC39A10 [21] , [22]

Role of PTM

 Potential impacts

Modified Residue

 Glutamicacid

Modified Location

 83

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Ubiquitination at SLC39A10 Glutamicacid 83 has the potential to affect its expression or activity.

  Lysine

           5 PTM Phenomena Related to This Residue Click to Show/Hide the Full List

  PTM Phenomenon 1

 Have the potential to influence SLC39A10 [21] , [22]

Role of PTM

 Potential impacts

Modified Residue

 Lysine

Modified Location

 50

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Ubiquitination at SLC39A10 Lysine 50 has the potential to affect its expression or activity.

  PTM Phenomenon 2

 Have the potential to influence SLC39A10 [21] , [22]

Role of PTM

 Potential impacts

Modified Residue

 Lysine

Modified Location

 66

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Ubiquitination at SLC39A10 Lysine 66 has the potential to affect its expression or activity.

  PTM Phenomenon 3

 Have the potential to influence SLC39A10 [21] , [22]

Role of PTM

 Potential impacts

Modified Residue

 Lysine

Modified Location

 390

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Ubiquitination at SLC39A10 Lysine 390 has the potential to affect its expression or activity.

  PTM Phenomenon 4

 Have the potential to influence SLC39A10 [21] , [22]

Role of PTM

 Potential impacts

Modified Residue

 Lysine

Modified Location

 533

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Ubiquitination at SLC39A10 Lysine 533 has the potential to affect its expression or activity.

  PTM Phenomenon 5

 Have the potential to influence SLC39A10 [21] , [22]

Role of PTM

 Potential impacts

Modified Residue

 Lysine

Modified Location

 562

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Ubiquitination at SLC39A10 Lysine 562 has the potential to affect its expression or activity.
References
1 dbPTM in 2022: an updated database for exploring regulatory networks and functional associations of protein post-translational modifications. Nucleic Acids Res. 2022 Jan 7;50(D1):D471-D479. (ID: S39AA_HUMAN)
2 Phosphoproteome profiling revealed abnormally phosphorylated AMPK and ATF2 involved in glucose metabolism and tumorigenesis of GH-PAs. J Endocrinol Invest. 2019 Feb;42(2):137-148.
3 Robust, Reproducible, and Economical Phosphopeptide Enrichment Using Calcium Titanate. J Proteome Res. 2019 Mar 1;18(3):1411-1417.
4 Characterization of native protein complexes and protein isoform variation using size-fractionation-based quantitative proteomics. Mol Cell Proteomics. 2013 Dec;12(12):3851-73.
5 Targeting CDK2 overcomes melanoma resistance against BRAF and Hsp90 inhibitors. Mol Syst Biol. 2018 Mar 5;14(3):e7858.
6 An orthogonal proteomic survey uncovers novel Zika virus host factors. Nature. 2018 Sep;561(7722):253-257.
7 TiO2 with Tandem Fractionation (TAFT): An Approach for Rapid, Deep, Reproducible, and High-Throughput Phosphoproteome Analysis. J Proteome Res. 2018 Jan 5;17(1):710-721.
8 CEP128 Localizes to the Subdistal Appendages of the Mother Centriole and Regulates TGF-beta/BMP Signaling at the Primary Cilium. Cell Rep. 2018 Mar 6;22(10):2584-2592.
9 Proteogenomic integration reveals therapeutic targets in breast cancer xenografts. Nat Commun. 2017 Mar 28;8:14864.
10 Defeating Major Contaminants in Fe3+- Immobilized Metal Ion Affinity Chromatography (IMAC) Phosphopeptide Enrichment. Mol Cell Proteomics. 2018 May;17(5):1028-1034.
11 MASTL overexpression promotes chromosome instability and metastasis in breast cancer. Oncogene. 2018 Aug;37(33):4518-4533.
12 Global phosphoproteomic analysis reveals ARMC10 as an AMPK substrate that regulates mitochondrial dynamics. Nat Commun. 2019 Jan 10;10(1):104.
13 Capillary Zone Electrophoresis-Tandem Mass Spectrometry for Large-Scale Phosphoproteomics with the Production of over 11,000 Phosphopeptides from the Colon Carcinoma HCT116 Cell Line. Anal Chem. 2019 Feb 5;91(3):2201-2208.
14 UniProt: a worldwide hub of protein knowledge. Nucleic Acids Res. 2019 Jan 8;47(D1):D506-D515.
15 p38-MK2 signaling axis regulates RNA metabolism after UV-light-induced DNA damage. Nat Commun. 2018 Mar 9;9(1):1017.
16 Proteotype profiling unmasks a viral signalling network essential for poxvirus assembly and transcriptional competence. Nat Microbiol. 2018 May;3(5):588-599.
17 Phosphoproteomic screening identifies physiological substrates of the CDKL5 kinase. EMBO J. 2018 Dec 14;37(24):e99559.
18 Ischemia in tumors induces early and sustained phosphorylation changes in stress kinase pathways but does not affect global protein levels. Mol Cell Proteomics. 2014 Jul;13(7):1690-704.
19 Phosphoproteomics study on the activated PKC-induced cell death. J Proteome Res. 2013 Oct 4;12(10):4280-301.
20 Selective Enrichment and Direct Analysis of Protein S-Palmitoylation Sites. J Proteome Res. 2018 May 4;17(5):1907-1922.
21 A proteome-wide, quantitative survey of in vivo ubiquitylation sites reveals widespread regulatory roles. Mol Cell Proteomics. 2011 Oct;10(10):M111.013284.
22 Systematic and quantitative assessment of the ubiquitin-modified proteome. Mol Cell. 2011 Oct 21;44(2):325-40.

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