Detail Information of Post-Translational Modifications

General Information of Drug Transporter (DT)
DT ID DTD0294 Transporter Info
Gene Name SLC35B3
Transporter Name Adenosine 3'-phospho 5'-phosphosulfate transporter 2
Gene ID
51000
UniProt ID
Q9H1N7
Post-Translational Modification of This DT
Overview of SLC35B3 Modification Sites with Functional and Structural Information
Sequence
PTM type
X-N-glycosylation X-Phosphorylation X: Amino Acid

N-glycosylation

  Asparagine

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

  PTM Phenomenon 1

 Have the potential to influence SLC35B3 [1]

Role of PTM

 Potential impacts

Modified Residue

 Asparagine

Modified Location

 12

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 N-linked Glycosylation at SLC35B3 Asparagine 12 has the potential to affect its expression or activity.

  PTM Phenomenon 2

 Have the potential to influence SLC35B3 [1]

Role of PTM

 Potential impacts

Modified Residue

 Asparagine

Modified Location

 71

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 N-linked Glycosylation at SLC35B3 Asparagine 71 has the potential to affect its expression or activity.

  PTM Phenomenon 3

 Have the potential to influence SLC35B3 [1]

Role of PTM

 Potential impacts

Modified Residue

 Asparagine

Modified Location

 254

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 N-linked Glycosylation at SLC35B3 Asparagine 254 has the potential to affect its expression or activity.

Phosphorylation

  Serine

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

  PTM Phenomenon 1

 Have the potential to influence SLC35B3 [2] , [3]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 45

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC35B3 Serine 45 has the potential to affect its expression or activity.

  PTM Phenomenon 2

 Have the potential to influence SLC35B3 [2] , [4]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 56

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC35B3 Serine 56 has the potential to affect its expression or activity.

  PTM Phenomenon 3

 Have the potential to influence SLC35B3 [5] , [6]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 380

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC35B3 Serine 380 has the potential to affect its expression or activity.

  PTM Phenomenon 4

 Have the potential to influence SLC35B3 [5] , [7]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 388

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC35B3 Serine 388 has the potential to affect its expression or activity.

  PTM Phenomenon 5

 Have the potential to influence SLC35B3 [8]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 394

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC35B3 Serine 394 has the potential to affect its expression or activity.

  Threonine

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

  PTM Phenomenon 1

 Have the potential to influence SLC35B3 [9]

Role of PTM

 Potential impacts

Modified Residue

 Threonine

Modified Location

 47

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC35B3 Threonine 47 has the potential to affect its expression or activity.

  PTM Phenomenon 2

 Have the potential to influence SLC35B3 [8]

Role of PTM

 Potential impacts

Modified Residue

 Threonine

Modified Location

 396

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC35B3 Threonine 396 has the potential to affect its expression or activity.

  Tyrosine

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

  PTM Phenomenon 1

 Have the potential to influence SLC35B3 [9] , [10]

Role of PTM

 Potential impacts

Modified Residue

 Tyrosine

Modified Location

 43

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC35B3 Tyrosine 43 has the potential to affect its expression or activity.

  PTM Phenomenon 2

 Have the potential to influence SLC35B3 [5] , [11]

Role of PTM

 Potential impacts

Modified Residue

 Tyrosine

Modified Location

 382

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC35B3 Tyrosine 382 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: S35B3_HUMAN)
2 Proteogenomic integration reveals therapeutic targets in breast cancer xenografts. Nat Commun. 2017 Mar 28;8:14864.
3 Offline pentafluorophenyl (PFP)-RP prefractionation as an alternative to high-pH RP for comprehensive LC-MS/MS proteomics and phosphoproteomics. Anal Bioanal Chem. 2017 Jul;409(19):4615-4625.
4 Protein kinase C-alpha interaction with F0F1-ATPase promotes F0F1-ATPase activity and reduces energy deficits in injured renal cells. J Biol Chem. 2015 Mar 13;290(11):7054-66.
5 An Augmented Multiple-Protease-Based Human Phosphopeptide Atlas. Cell Rep. 2015 Jun 23;11(11):1834-43.
6 Global phosphoproteome analysis of human bone marrow reveals predictive phosphorylation markers for the treatment of acute myeloid leukemia with quizartinib. Leukemia. 2014 Mar;28(3):716-9.
7 Determination of Site-Specific Phosphorylation Ratios in Proteins with Targeted Mass Spectrometry. J Proteome Res. 2018 Apr 6;17(4):1654-1663.
8 iTRAQ labeling is superior to mTRAQ for quantitative global proteomics and phosphoproteomics. Mol Cell Proteomics. 2012 Jun;11(6):M111.014423.
9 Deep Phosphotyrosine Proteomics by Optimization of Phosphotyrosine Enrichment and MS/MS Parameters. J Proteome Res. 2017 Feb 3;16(2):1077-1086.
10 An integrated strategy for highly sensitive phosphoproteome analysis from low micrograms of protein samples. Analyst. 2018 Jul 23;143(15):3693-3701.
11 Ultra-deep tyrosine phosphoproteomics enabled by a phosphotyrosine superbinder. Nat Chem Biol. 2016 Nov;12(11):959-966.

If you find any error in data or bug in web service, please kindly report it to Dr. Yin and Dr. Li.