Detail Information of Post-Translational Modifications

General Information of Drug Transporter (DT)
DT ID DTD0331 Transporter Info
Gene Name SLC38A4
Transporter Name Sodium-coupled neutral amino acid transporter 4
Gene ID
55089
UniProt ID
Q969I6
Post-Translational Modification of This DT
Overview ofSLC38A4 Modification Sites with Functional and Structural Information
Sequence
PTM type
X-N-glycosylation X-Phosphorylation X-Phosphorylation X: Amino Acid

N-glycosylation

  Asparagine

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

  PTM Phenomenon1

 Have the potential to influence SLC38A4 [1]

Role of PTM

 Potential impacts

Modified Residue

 Asparagine

Modified Location

 260

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 N-linked Glycosylation at SLC38A4 Asparagine 260 has the potential to affect its expression or activity.

  PTM Phenomenon2

 Have the potential to influence SLC38A4 [1]

Role of PTM

 Potential impacts

Modified Residue

 Asparagine

Modified Location

 264

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 N-linked Glycosylation at SLC38A4 Asparagine 264 has the potential to affect its expression or activity.

  PTM Phenomenon3

 Have the potential to influence SLC38A4 [2]

Role of PTM

 Potential impacts

Modified Residue

 Asparagine

Modified Location

 276

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 N-linked Glycosylation at SLC38A4 Asparagine 276 has the potential to affect its expression or activity.

Phosphorylation

  Serine

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

  PTM Phenomenon1

 Have the potential to influence SLC38A4 [3], [4]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 17

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC38A4 Serine 17 has the potential to affect its expression or activity.

  PTM Phenomenon2

 Have the potential to influence SLC38A4 [3], [5]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 18

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC38A4 Serine 18 has the potential to affect its expression or activity.

  PTM Phenomenon3

 Have the potential to influence SLC38A4 [3], [5]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 19

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC38A4 Serine 19 has the potential to affect its expression or activity.

  PTM Phenomenon4

 Have the potential to influence SLC38A4 [3], [5]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 22

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC38A4 Serine 22 has the potential to affect its expression or activity.

  PTM Phenomenon5

 Have the potential to influence SLC38A4 [5], [6]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 26

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC38A4 Serine 26 has the potential to affect its expression or activity.

  PTM Phenomenon6

 Have the potential to influence SLC38A4 [5]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 33

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC38A4 Serine 33 has the potential to affect its expression or activity.

  PTM Phenomenon7

 Have the potential to influence SLC38A4 [7]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 40

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC38A4 Serine 40 has the potential to affect its expression or activity.

  PTM Phenomenon8

 Have the potential to influence SLC38A4 [8], [9]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 49

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC38A4 Serine 49 has the potential to affect its expression or activity.

  PTM Phenomenon9

 Have the potential to influence SLC38A4 [10]

Role of PTM

 Potential impacts

Modified Residue

 Serine

Modified Location

 214

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC38A4 Serine 214 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 Phenomenon1

 Have the potential to influence SLC38A4 [4], [8]

Role of PTM

 Potential impacts

Modified Residue

 Threonine

Modified Location

 47

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC38A4 Threonine 47 has the potential to affect its expression or activity.

  Tyrosine

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

  PTM Phenomenon1

 Have the potential to influence SLC38A4 [5], [6]

Role of PTM

 Potential impacts

Modified Residue

 Tyrosine

Modified Location

 27

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC38A4 Tyrosine 27 has the potential to affect its expression or activity.

  PTM Phenomenon2

 . [11]

Role of PTM

 Potential impacts

Modified Residue

 Tyrosine

Modified Location

 313

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC38A4 Tyrosine 313 has the potential to affect its expression or activity.

  PTM Phenomenon3

 . [11]

Role of PTM

 Potential impacts

Modified Residue

 Tyrosine

Modified Location

 313

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC38A4 Tyrosine 313 has the potential to affect its expression or activity.

  PTM Phenomenon4

 . [11]

Role of PTM

 Potential impacts

Modified Residue

 Tyrosine

Modified Location

 313

Experimental Method

 Co-Immunoprecipitation

Detailed Description

 Phosphorylation at SLC38A4 Tyrosine 313 has the potential to affect its expression or activity.
References
1 Membrane topological structure of neutral system N/A amino acid transporter 4 (SNAT4) protein. J Biol Chem. 2011 Nov 4;286(44):38086-38094.
2 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: S38A4_HUMAN)
3 In situ sample processing approach (iSPA) for comprehensive quantitative phosphoproteome analysis. J Proteome Res. 2014 Sep 5;13(9):3896-904.
4 Non-alcoholic fatty liver disease phosphoproteomics: A functional piece of the precision puzzle. Hepatol Res. 2017 Dec;47(13):1469-1483.
5 An enzyme assisted RP-RPLC approach for in-depth analysis of human liver phosphoproteome. J Proteomics. 2014 Jan 16;96:253-62.
6 Systematic analysis of protein phosphorylation networks from phosphoproteomic data. Mol Cell Proteomics. 2012 Oct;11(10):1070-83.
7 An Impaired Respiratory Electron Chain Triggers Down-regulation of the Energy Metabolism and De-ubiquitination of Solute Carrier Amino Acid Transporters. Mol Cell Proteomics. 2016 May;15(5):1526-38.
8 p38-MK2 signaling axis regulates RNA metabolism after UV-light-induced DNA damage. Nat Commun. 2018 Mar 9;9(1):1017.
9 Global Analyses of Selective Insulin Resistance in Hepatocytes Caused by Palmitate Lipotoxicity. Mol Cell Proteomics. 2018 May;17(5):836-849.
10 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.
11 ActiveDriverDB: human disease mutations and genome variation in post-translational modification sites of proteins. Nucleic Acids Res. 2018;46(D1):D901-D910.

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