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Center for Computational Systems Medicine
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Protein Summary

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AS Summary

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Protein Functional Features

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Gene Isoform Structures and Expression Levels

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Protein Structures

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pLDDT Score Distribution

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Ramachandran Plot of Protein Structures

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Potential Active Site Information

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Protein Structure and Feature Comparision

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Protein-Protein Interaction

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Related Drugs

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Related Diseases

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Clinically Important Variants

Protein:NEDD4L

Protein Summary

check button Gene summary
Gene name: NEDD4L
ASpdb.0 ID: 23327
Gene
Gene symbol

NEDD4L

Gene ID

23327

Gene nameNEDD4 like E3 ubiquitin protein ligase
SynonymsNEDD4-2|NEDD4.2|PVNH7|RSP5|hNEDD4-2
Cytomap

18q21.31

Type of geneprotein-coding
DescriptionE3 ubiquitin-protein ligase NEDD4-likeHECT-type E3 ubiquitin transferase NED4Lneural precursor cell expressed, developmentally down-regulated 4-like, E3 ubiquitin protein ligaseubiquitin-protein ligase Rsp5
Modification date20240416
UniProtAcc

Q96PU5


check button Gene ontology of this gene with evidence of Inferred from Direct Assay (IDA) from Entrez
PartnerGeneGO IDGO termPubMed ID
GeneNEDD4L

GO:0003254

regulation of membrane depolarization

15217910

GeneNEDD4L

GO:0005886

plasma membrane

22879586

GeneNEDD4L

GO:0006511

ubiquitin-dependent protein catabolic process

21463633

GeneNEDD4L

GO:0015459

potassium channel regulator activity

17289006

GeneNEDD4L

GO:0016567

protein ubiquitination

15217910|18577513|25631046

GeneNEDD4L

GO:0017080

sodium channel regulator activity

11244092

GeneNEDD4L

GO:0019870

potassium channel inhibitor activity

21463633

GeneNEDD4L

GO:0019871

sodium channel inhibitor activity

15217910

GeneNEDD4L

GO:0034765

regulation of monoatomic ion transmembrane transport

17289006

GeneNEDD4L

GO:0042391

regulation of membrane potential

17289006

GeneNEDD4L

GO:0043161

proteasome-mediated ubiquitin-dependent protein catabolic process

21463633

GeneNEDD4L

GO:0060306

regulation of membrane repolarization

21463633

GeneNEDD4L

GO:0070936

protein K48-linked ubiquitination

21463633

GeneNEDD4L

GO:1901016

regulation of potassium ion transmembrane transporter activity

17289006

GeneNEDD4L

GO:1901017

negative regulation of potassium ion transmembrane transporter activity

21463633

GeneNEDD4L

GO:1901380

negative regulation of potassium ion transmembrane transport

21463633

GeneNEDD4L

GO:1902305

regulation of sodium ion transmembrane transport

11244092

GeneNEDD4L

GO:1902306

negative regulation of sodium ion transmembrane transport

15217910

GeneNEDD4L

GO:1903861

positive regulation of dendrite extension

23999003

GeneNEDD4L

GO:2000009

negative regulation of protein localization to cell surface

21463633

GeneNEDD4L

GO:2000650

negative regulation of sodium ion transmembrane transporter activity

15217910



AS Summary

check button Information of the canonical protein with experimentally identified structure from PDB (2023).
UniProt AccFile namePDB IDMethodResolutionChainStartEnd
Q96PU5-1Q96PU5-1_5hpk_A.pdb5HPKX-ray2.43A594969

check button ASpdb's canonical and alternatively spliced isoform information.
accession_idgene_namecanonical_idalternative_idcanonical_lengthalternative_lengthcanonical_startcanonical_endtypeoriginalSEQvariationSEQalternative_startalternative_end
Q96PU5NEDD4LQ96PU5-1Q96PU5-2975911356419Deletionnonenone355355
Q96PU5NEDD4LQ96PU5-1Q96PU5-3975871356459Deletionnonenone355355
Q96PU5NEDD4LQ96PU5-1Q96PU5-49758541121Deletionnonenone00
Q96PU5NEDD4LQ96PU5-1Q96PU5-5975955356375Deletionnonenone355355
Q96PU5NEDD4LQ96PU5-1Q96PU5-6975947116SubstitutionMATGLGEPVYGLSEDEMRRLAFEQ18
Q96PU5NEDD4LQ96PU5-1Q96PU5-6975947356375Deletionnonenone347347
Q96PU5NEDD4LQ96PU5-1Q96PU5-7975967116SubstitutionMATGLGEPVYGLSEDEMRRLAFEQ18
Q96PU5NEDD4LQ96PU5-1Q96PU5-99758341121Deletionnonenone00
Q96PU5NEDD4LQ96PU5-1Q96PU5-9975834356375Deletionnonenone234234

check buttonMultiple sequence alignment of our canonical and alternatively spliced NEDD4L

check button Matched gene isoform IDs with Ensembl and RefSeq of our canonical and alternative spliced genes of NEDD4L
UniProt-idENSGENSTENSP
Q96PU5-1ENSG00000049759.20ENST00000400345.8ENSP00000383199.2
Q96PU5-2ENSG00000049759.20ENST00000356462.10ENSP00000348847.5
Q96PU5-3ENSG00000049759.20ENST00000256830.13ENSP00000256830.8
Q96PU5-4ENSG00000049759.20ENST00000431212.6ENSP00000389406.1
Q96PU5-4ENSG00000049759.20ENST00000456986.5ENSP00000411947.1
Q96PU5-5ENSG00000049759.20ENST00000382850.8ENSP00000372301.3
Q96PU5-6ENSG00000049759.20ENST00000586263.5ENSP00000468546.1
Q96PU5-7ENSG00000049759.20ENST00000357895.9ENSP00000350569.4
Q96PU5-9ENSG00000049759.20ENST00000435432.6ENSP00000393395.1
Q96PU5-9ENSG00000049759.20ENST00000456173.6ENSP00000405440.1
Q96PU5-9ENSG00000049759.20ENST00000674517.1ENSP00000501665.1
Q96PU5-9ENSG00000049759.20ENST00000675502.1ENSP00000502428.1
Q96PU5-9ENSG00000049759.20ENST00000675801.1ENSP00000502688.1
Q96PU5-9ENSG00000049759.20ENST00000675865.1ENSP00000502003.1
Q96PU5-9ENSG00000049759.20ENST00000676226.1ENSP00000502325.1

UniProt-idNM IDNP ID
Q96PU5-1NM_001144967.2NP_001138439.1
Q96PU5-2NM_001243960.1NP_001230889.1
Q96PU5-4NM_001144964.1NP_001138436.1
Q96PU5-4NM_001144965.1NP_001138437.1
Q96PU5-4NM_001144966.2NP_001138438.1
Q96PU5-4XM_017025679.1XP_016881168.1
Q96PU5-5NM_015277.5NP_056092.2
Q96PU5-6NM_001144969.1NP_001138441.1
Q96PU5-7NM_001144968.1NP_001138440.1
Q96PU5-9NM_001144970.2NP_001138442.1
Q96PU5-9NM_001144971.1NP_001138443.1

check buttonAmino acid sequences of our canonical and alternatively spliced NEDD4L
accession_idProtein sequence
Q96PU5-1MATGLGEPVYGLSEDEGESRILRVKVVSGIDLAKKDIFGASDPYVKLSLYVADENRELALVQTKTIKKTLNPKWNEEFYFRVNPSNHRLL
FEVFDENRLTRDDFLGQVDVPLSHLPTEDPTMERPYTFKDFLLRPRSHKSRVKGFLRLKMAYMPKNGGQDEENSDQRDDMEHGWEVVDSN
DSASQHQEELPPPPLPPGWEEKVDNLGRTYYVNHNNRTTQWHRPSLMDVSSESDNNIRQINQEAAHRRFRSRRHISEDLEPEPSEGGDVP
EPWETISEEVNIAGDSLGLALPPPPASPGSRTSPQELSEELSRRLQITPDSNGEQFSSLIQREPSSRLRSCSVTDAVAEQGHLPPPSAPA
GRARSSTVTGGEEPTPSVAYVHTTPGLPSGWEERKDAKGRTYYVNHNNRTTTWTRPIMQLAEDGASGSATNSNNHLIEPQIRRPRSLSSP
TVTLSAPLEGAKDSPVRRAVKDTLSNPQSPQPSPYNSPKPQHKVTQSFLPPGWEMRIAPNGRPFFIDHNTKTTTWEDPRLKFPVHMRSKT
SLNPNDLGPLPPGWEERIHLDGRTFYIDHNSKITQWEDPRLQNPAITGPAVPYSREFKQKYDYFRKKLKKPADIPNRFEMKLHRNNIFEE
SYRRIMSVKRPDVLKARLWIEFESEKGLDYGGVAREWFFLLSKEMFNPYYGLFEYSATDNYTLQINPNSGLCNEDHLSYFTFIGRVAGLA
VFHGKLLDGFFIRPFYKMMLGKQITLNDMESVDSEYYNSLKWILENDPTELDLMFCIDEENFGQTYQVDLKPNGSEIMVTNENKREYIDL
VIQWRFVNRVQKQMNAFLEGFTELLPIDLIKIFDENELELLMCGLGDVDVNDWRQHSIYKNGYCPNHPVIQWFWKAVLLMDAEKRIRLLQ
Q96PU5-2MATGLGEPVYGLSEDEGESRILRVKVVSGIDLAKKDIFGASDPYVKLSLYVADENRELALVQTKTIKKTLNPKWNEEFYFRVNPSNHRLL
FEVFDENRLTRDDFLGQVDVPLSHLPTEDPTMERPYTFKDFLLRPRSHKSRVKGFLRLKMAYMPKNGGQDEENSDQRDDMEHGWEVVDSN
DSASQHQEELPPPPLPPGWEEKVDNLGRTYYVNHNNRTTQWHRPSLMDVSSESDNNIRQINQEAAHRRFRSRRHISEDLEPEPSEGGDVP
EPWETISEEVNIAGDSLGLALPPPPASPGSRTSPQELSEELSRRLQITPDSNGEQFSSLIQREPSSRLRSCSVTDAVAEQGHLPPLAEDG
ASGSATNSNNHLIEPQIRRPRSLSSPTVTLSAPLEGAKDSPVRRAVKDTLSNPQSPQPSPYNSPKPQHKVTQSFLPPGWEMRIAPNGRPF
FIDHNTKTTTWEDPRLKFPVHMRSKTSLNPNDLGPLPPGWEERIHLDGRTFYIDHNSKITQWEDPRLQNPAITGPAVPYSREFKQKYDYF
RKKLKKPADIPNRFEMKLHRNNIFEESYRRIMSVKRPDVLKARLWIEFESEKGLDYGGVAREWFFLLSKEMFNPYYGLFEYSATDNYTLQ
INPNSGLCNEDHLSYFTFIGRVAGLAVFHGKLLDGFFIRPFYKMMLGKQITLNDMESVDSEYYNSLKWILENDPTELDLMFCIDEENFGQ
TYQVDLKPNGSEIMVTNENKREYIDLVIQWRFVNRVQKQMNAFLEGFTELLPIDLIKIFDENELELLMCGLGDVDVNDWRQHSIYKNGYC
PNHPVIQWFWKAVLLMDAEKRIRLLQFVTGTSRVPMNGFAELYGSNGPQLFTIEQWGSPEKLPRAHTCFNRLDLPPYETFEDLREKLLMA
Q96PU5-3MATGLGEPVYGLSEDEGESRILRVKVVSGIDLAKKDIFGASDPYVKLSLYVADENRELALVQTKTIKKTLNPKWNEEFYFRVNPSNHRLL
FEVFDENRLTRDDFLGQVDVPLSHLPTEDPTMERPYTFKDFLLRPRSHKSRVKGFLRLKMAYMPKNGGQDEENSDQRDDMEHGWEVVDSN
DSASQHQEELPPPPLPPGWEEKVDNLGRTYYVNHNNRTTQWHRPSLMDVSSESDNNIRQINQEAAHRRFRSRRHISEDLEPEPSEGGDVP
EPWETISEEVNIAGDSLGLALPPPPASPGSRTSPQELSEELSRRLQITPDSNGEQFSSLIQREPSSRLRSCSVTDAVAEQGHLPPGAKDS
PVRRAVKDTLSNPQSPQPSPYNSPKPQHKVTQSFLPPGWEMRIAPNGRPFFIDHNTKTTTWEDPRLKFPVHMRSKTSLNPNDLGPLPPGW
EERIHLDGRTFYIDHNSKITQWEDPRLQNPAITGPAVPYSREFKQKYDYFRKKLKKPADIPNRFEMKLHRNNIFEESYRRIMSVKRPDVL
KARLWIEFESEKGLDYGGVAREWFFLLSKEMFNPYYGLFEYSATDNYTLQINPNSGLCNEDHLSYFTFIGRVAGLAVFHGKLLDGFFIRP
FYKMMLGKQITLNDMESVDSEYYNSLKWILENDPTELDLMFCIDEENFGQTYQVDLKPNGSEIMVTNENKREYIDLVIQWRFVNRVQKQM
NAFLEGFTELLPIDLIKIFDENELELLMCGLGDVDVNDWRQHSIYKNGYCPNHPVIQWFWKAVLLMDAEKRIRLLQFVTGTSRVPMNGFA
Q96PU5-4MERPYTFKDFLLRPRSHKSRVKGFLRLKMAYMPKNGGQDEENSDQRDDMEHGWEVVDSNDSASQHQEELPPPPLPPGWEEKVDNLGRTYY
VNHNNRTTQWHRPSLMDVSSESDNNIRQINQEAAHRRFRSRRHISEDLEPEPSEGGDVPEPWETISEEVNIAGDSLGLALPPPPASPGSR
TSPQELSEELSRRLQITPDSNGEQFSSLIQREPSSRLRSCSVTDAVAEQGHLPPPSAPAGRARSSTVTGGEEPTPSVAYVHTTPGLPSGW
EERKDAKGRTYYVNHNNRTTTWTRPIMQLAEDGASGSATNSNNHLIEPQIRRPRSLSSPTVTLSAPLEGAKDSPVRRAVKDTLSNPQSPQ
PSPYNSPKPQHKVTQSFLPPGWEMRIAPNGRPFFIDHNTKTTTWEDPRLKFPVHMRSKTSLNPNDLGPLPPGWEERIHLDGRTFYIDHNS
KITQWEDPRLQNPAITGPAVPYSREFKQKYDYFRKKLKKPADIPNRFEMKLHRNNIFEESYRRIMSVKRPDVLKARLWIEFESEKGLDYG
GVAREWFFLLSKEMFNPYYGLFEYSATDNYTLQINPNSGLCNEDHLSYFTFIGRVAGLAVFHGKLLDGFFIRPFYKMMLGKQITLNDMES
VDSEYYNSLKWILENDPTELDLMFCIDEENFGQTYQVDLKPNGSEIMVTNENKREYIDLVIQWRFVNRVQKQMNAFLEGFTELLPIDLIK
IFDENELELLMCGLGDVDVNDWRQHSIYKNGYCPNHPVIQWFWKAVLLMDAEKRIRLLQFVTGTSRVPMNGFAELYGSNGPQLFTIEQWG
Q96PU5-5MATGLGEPVYGLSEDEGESRILRVKVVSGIDLAKKDIFGASDPYVKLSLYVADENRELALVQTKTIKKTLNPKWNEEFYFRVNPSNHRLL
FEVFDENRLTRDDFLGQVDVPLSHLPTEDPTMERPYTFKDFLLRPRSHKSRVKGFLRLKMAYMPKNGGQDEENSDQRDDMEHGWEVVDSN
DSASQHQEELPPPPLPPGWEEKVDNLGRTYYVNHNNRTTQWHRPSLMDVSSESDNNIRQINQEAAHRRFRSRRHISEDLEPEPSEGGDVP
EPWETISEEVNIAGDSLGLALPPPPASPGSRTSPQELSEELSRRLQITPDSNGEQFSSLIQREPSSRLRSCSVTDAVAEQGHLPPPSVAY
VHTTPGLPSGWEERKDAKGRTYYVNHNNRTTTWTRPIMQLAEDGASGSATNSNNHLIEPQIRRPRSLSSPTVTLSAPLEGAKDSPVRRAV
KDTLSNPQSPQPSPYNSPKPQHKVTQSFLPPGWEMRIAPNGRPFFIDHNTKTTTWEDPRLKFPVHMRSKTSLNPNDLGPLPPGWEERIHL
DGRTFYIDHNSKITQWEDPRLQNPAITGPAVPYSREFKQKYDYFRKKLKKPADIPNRFEMKLHRNNIFEESYRRIMSVKRPDVLKARLWI
EFESEKGLDYGGVAREWFFLLSKEMFNPYYGLFEYSATDNYTLQINPNSGLCNEDHLSYFTFIGRVAGLAVFHGKLLDGFFIRPFYKMML
GKQITLNDMESVDSEYYNSLKWILENDPTELDLMFCIDEENFGQTYQVDLKPNGSEIMVTNENKREYIDLVIQWRFVNRVQKQMNAFLEG
FTELLPIDLIKIFDENELELLMCGLGDVDVNDWRQHSIYKNGYCPNHPVIQWFWKAVLLMDAEKRIRLLQFVTGTSRVPMNGFAELYGSN
Q96PU5-6MRRLAFEQGESRILRVKVVSGIDLAKKDIFGASDPYVKLSLYVADENRELALVQTKTIKKTLNPKWNEEFYFRVNPSNHRLLFEVFDENR
LTRDDFLGQVDVPLSHLPTEDPTMERPYTFKDFLLRPRSHKSRVKGFLRLKMAYMPKNGGQDEENSDQRDDMEHGWEVVDSNDSASQHQE
ELPPPPLPPGWEEKVDNLGRTYYVNHNNRTTQWHRPSLMDVSSESDNNIRQINQEAAHRRFRSRRHISEDLEPEPSEGGDVPEPWETISE
EVNIAGDSLGLALPPPPASPGSRTSPQELSEELSRRLQITPDSNGEQFSSLIQREPSSRLRSCSVTDAVAEQGHLPPPSVAYVHTTPGLP
SGWEERKDAKGRTYYVNHNNRTTTWTRPIMQLAEDGASGSATNSNNHLIEPQIRRPRSLSSPTVTLSAPLEGAKDSPVRRAVKDTLSNPQ
SPQPSPYNSPKPQHKVTQSFLPPGWEMRIAPNGRPFFIDHNTKTTTWEDPRLKFPVHMRSKTSLNPNDLGPLPPGWEERIHLDGRTFYID
HNSKITQWEDPRLQNPAITGPAVPYSREFKQKYDYFRKKLKKPADIPNRFEMKLHRNNIFEESYRRIMSVKRPDVLKARLWIEFESEKGL
DYGGVAREWFFLLSKEMFNPYYGLFEYSATDNYTLQINPNSGLCNEDHLSYFTFIGRVAGLAVFHGKLLDGFFIRPFYKMMLGKQITLND
MESVDSEYYNSLKWILENDPTELDLMFCIDEENFGQTYQVDLKPNGSEIMVTNENKREYIDLVIQWRFVNRVQKQMNAFLEGFTELLPID
LIKIFDENELELLMCGLGDVDVNDWRQHSIYKNGYCPNHPVIQWFWKAVLLMDAEKRIRLLQFVTGTSRVPMNGFAELYGSNGPQLFTIE
Q96PU5-7MRRLAFEQGESRILRVKVVSGIDLAKKDIFGASDPYVKLSLYVADENRELALVQTKTIKKTLNPKWNEEFYFRVNPSNHRLLFEVFDENR
LTRDDFLGQVDVPLSHLPTEDPTMERPYTFKDFLLRPRSHKSRVKGFLRLKMAYMPKNGGQDEENSDQRDDMEHGWEVVDSNDSASQHQE
ELPPPPLPPGWEEKVDNLGRTYYVNHNNRTTQWHRPSLMDVSSESDNNIRQINQEAAHRRFRSRRHISEDLEPEPSEGGDVPEPWETISE
EVNIAGDSLGLALPPPPASPGSRTSPQELSEELSRRLQITPDSNGEQFSSLIQREPSSRLRSCSVTDAVAEQGHLPPPSAPAGRARSSTV
TGGEEPTPSVAYVHTTPGLPSGWEERKDAKGRTYYVNHNNRTTTWTRPIMQLAEDGASGSATNSNNHLIEPQIRRPRSLSSPTVTLSAPL
EGAKDSPVRRAVKDTLSNPQSPQPSPYNSPKPQHKVTQSFLPPGWEMRIAPNGRPFFIDHNTKTTTWEDPRLKFPVHMRSKTSLNPNDLG
PLPPGWEERIHLDGRTFYIDHNSKITQWEDPRLQNPAITGPAVPYSREFKQKYDYFRKKLKKPADIPNRFEMKLHRNNIFEESYRRIMSV
KRPDVLKARLWIEFESEKGLDYGGVAREWFFLLSKEMFNPYYGLFEYSATDNYTLQINPNSGLCNEDHLSYFTFIGRVAGLAVFHGKLLD
GFFIRPFYKMMLGKQITLNDMESVDSEYYNSLKWILENDPTELDLMFCIDEENFGQTYQVDLKPNGSEIMVTNENKREYIDLVIQWRFVN
RVQKQMNAFLEGFTELLPIDLIKIFDENELELLMCGLGDVDVNDWRQHSIYKNGYCPNHPVIQWFWKAVLLMDAEKRIRLLQFVTGTSRV
Q96PU5-9MERPYTFKDFLLRPRSHKSRVKGFLRLKMAYMPKNGGQDEENSDQRDDMEHGWEVVDSNDSASQHQEELPPPPLPPGWEEKVDNLGRTYY
VNHNNRTTQWHRPSLMDVSSESDNNIRQINQEAAHRRFRSRRHISEDLEPEPSEGGDVPEPWETISEEVNIAGDSLGLALPPPPASPGSR
TSPQELSEELSRRLQITPDSNGEQFSSLIQREPSSRLRSCSVTDAVAEQGHLPPPSVAYVHTTPGLPSGWEERKDAKGRTYYVNHNNRTT
TWTRPIMQLAEDGASGSATNSNNHLIEPQIRRPRSLSSPTVTLSAPLEGAKDSPVRRAVKDTLSNPQSPQPSPYNSPKPQHKVTQSFLPP
GWEMRIAPNGRPFFIDHNTKTTTWEDPRLKFPVHMRSKTSLNPNDLGPLPPGWEERIHLDGRTFYIDHNSKITQWEDPRLQNPAITGPAV
PYSREFKQKYDYFRKKLKKPADIPNRFEMKLHRNNIFEESYRRIMSVKRPDVLKARLWIEFESEKGLDYGGVAREWFFLLSKEMFNPYYG
LFEYSATDNYTLQINPNSGLCNEDHLSYFTFIGRVAGLAVFHGKLLDGFFIRPFYKMMLGKQITLNDMESVDSEYYNSLKWILENDPTEL
DLMFCIDEENFGQTYQVDLKPNGSEIMVTNENKREYIDLVIQWRFVNRVQKQMNAFLEGFTELLPIDLIKIFDENELELLMCGLGDVDVN
DWRQHSIYKNGYCPNHPVIQWFWKAVLLMDAEKRIRLLQFVTGTSRVPMNGFAELYGSNGPQLFTIEQWGSPEKLPRAHTCFNRLDLPPY

Protein Functional Features

check buttonMain function of this protein. (from UniProt)
NEDD4L (go to UniProt):Q96PU5

check buttonRetention analysis result of protein across 39 protein features of UniProt such as six molecule processing features, 13 region features, four site features, six amino acid modification features, two natural variation features, five experimental info features, and 3 secondary structure features. Here, because of limited space for viewing, we only show the protein feature retention information belong to the 13 regional features. All retention annotation result can be downloaded at

download page

* Minus value of BPloci means that the break pointn is located before the CDS.
- Retained protein feature among the 13 regional features.
Accession_idSubsectionStartEndFuncitonal featureSplicing information
Q96PU5Domain4126Note=C2;Ontology_term=ECO:0000255;evidence=ECO:0000255|PROSITE-ProRule:PRU00041Type=Deletion;Start=1;End=121
Q96PU5Domain4126Note=C2;Ontology_term=ECO:0000255;evidence=ECO:0000255|PROSITE-ProRule:PRU00041Type=Substitution;Start=1;End=16
Q96PU5Domain4126Note=C2;Ontology_term=ECO:0000255;evidence=ECO:0000255|PROSITE-ProRule:PRU00041Type=Substitution;Start=1;End=16
Q96PU5Domain4126Note=C2;Ontology_term=ECO:0000255;evidence=ECO:0000255|PROSITE-ProRule:PRU00041Type=Deletion;Start=1;End=121
Q96PU5Domain385418Note=WW 2;Ontology_term=ECO:0000255;evidence=ECO:0000255|PROSITE-ProRule:PRU00224Type=Deletion;Start=356;End=419
Q96PU5Domain385418Note=WW 2;Ontology_term=ECO:0000255;evidence=ECO:0000255|PROSITE-ProRule:PRU00224Type=Deletion;Start=356;End=459
Q96PU5Region349393Note=Disordered;Ontology_term=ECO:0000256;evidence=ECO:0000256|SAM:MobiDB-liteType=Deletion;Start=356;End=419
Q96PU5Region349393Note=Disordered;Ontology_term=ECO:0000256;evidence=ECO:0000256|SAM:MobiDB-liteType=Deletion;Start=356;End=459
Q96PU5Region349393Note=Disordered;Ontology_term=ECO:0000256;evidence=ECO:0000256|SAM:MobiDB-liteType=Deletion;Start=356;End=375
Q96PU5Region349393Note=Disordered;Ontology_term=ECO:0000256;evidence=ECO:0000256|SAM:MobiDB-liteType=Deletion;Start=356;End=375
Q96PU5Region349393Note=Disordered;Ontology_term=ECO:0000256;evidence=ECO:0000256|SAM:MobiDB-liteType=Deletion;Start=356;End=375
Q96PU5Region424496Note=Disordered;Ontology_term=ECO:0000256;evidence=ECO:0000256|SAM:MobiDB-liteType=Deletion;Start=356;End=459
Q96PU5Compositional bias424455Note=Polar residues;Ontology_term=ECO:0000256;evidence=ECO:0000256|SAM:MobiDB-liteType=Deletion;Start=356;End=459


Gene Isoform Structures and Expression Levels for NEDD4L

check buttonGene structures of our canonical and alternative spliced genes of NEDD4L
* Click on the image to open the UCSC genome browser with custom track showing this image in a new window.
gene isoform structure of NEDD4L

check button Expression levels of gene isoforms across GTEx.
gtex expression

check button Expression levels of gene isoforms across TCGA.
tcga expression


Protein Structures

check button PDB and CIF files of the predicted protein structures
* Here we show the 3D structure of the proteins using Mol*. AlphaFold produces a per-residue confidence score (pLDDT) between 0 and 100. Model confidence is shown from the pLDDT values per residue. pLDDT corresponds to the model’s prediction of its score on the local Distance Difference Test. It is a measure of local accuracy (from AlphfaFold website). To color code individual residues, we transformed individual PDB files into CIF format.
3D view using mol* of Q96PU5-1
3D view using mol* of Q96PU5-2
3D view using mol* of Q96PU5-3
3D view using mol* of Q96PU5-4
3D view using mol* of Q96PU5-5
3D view using mol* of Q96PU5-6
3D view using mol* of Q96PU5-7
3D view using mol* of Q96PU5-9


pLDDT Score Distribution

check button pLDDT score distribution of the predicted protein structures from AlphaFold2
* AlphaFold produces a per-residue confidence score (pLDDT) between 0 and 100.
pLDDT distribution across the protein length of Q96PU5-1
all structure
pLDDT distribution across the protein length of Q96PU5-2
all structure
pLDDT distribution across the protein length of Q96PU5-3
all structure
pLDDT distribution across the protein length of Q96PU5-4
all structure
pLDDT distribution across the protein length of Q96PU5-5
all structure
pLDDT distribution across the protein length of Q96PU5-6
all structure
pLDDT distribution across the protein length of Q96PU5-7
all structure
pLDDT distribution across the protein length of Q96PU5-9
all structure


Ramachandran Plot of Protein Structures


check button Ramachandran plot of the torsional angles - phi (φ)and psi (ψ) - of the residues (amino acids) contained in this protein peptide.
Ramachandran plot of Q96PU5-1
all structure
Ramachandran plot of Q96PU5-2
all structure
Ramachandran plot of Q96PU5-5
all structure
Ramachandran plot of Q96PU5-7
all structure
Ramachandran plot of Q96PU5-9
all structure

Potential Active Site Information


check button The potential binding sites of these proteins were identified using SiteMap, a module of the Schrodinger suite.
UniProt-idSite scoreSizeD scoreVolumeExposureEnclosureContactPhobicPhilicBalanceDon/AccResidues
Q96PU5-11.0961791.054390.6770.4170.8411.120.6251.1980.5220.65597,598,601,605,608,647,648,649,659,660,661,664,66
5,668,669,720,721,722,723,724,725,726,850,851,903,
905,907,909,910,911,915,916,917,918,919,921,944
Q96PU5-21.168991.042156.0650.3170.9541.2841.0221.4290.7150.744533,537,541,601,604,657,659,660,661,662,786,787,83
5,839,841,843,844,845,846,847,851,852,853,880
Q96PU5-31.1361390.865214.0320.3220.9011.2330.661.8880.3490.95235,36,37,38,39,40,42,65,67,68,96,97,98,99,100,103,
667,668,669,670,672,673,674,683,703
Q96PU5-41.1591260.963186.2490.3150.9361.3190.4111.6510.2490.624476,480,483,484,544,547,548,599,600,602,603,604,60
5,607,729,730,733,778,782,784,785,786,787,788,789,
790,794,795,796,797,823
Q96PU5-51.1041110.903211.9740.4030.8531.1990.5941.6830.3530.83236,37,38,39,42,67,68,96,97,98,99,100,743,751,752,7
53,754,756,757,758,767,775,787
Q96PU5-61.1631151.017179.3890.320.9411.2460.7931.4960.530.634569,573,577,633,637,640,692,693,695,696,697,698,82
2,823,826,877,881,882,883,887,888,889,890,891,916

Q96PU5-71.141990.865174.5870.3930.9141.2760.4771.8970.2520.61627,28,29,30,31,32,34,57,59,60,88,89,90,91,92,95,75
5,763,764,765,766,768,769,770,779,799
Q96PU5-91.1721001.097149.8910.3290.9551.3061.1871.2770.930.639456,460,464,524,527,580,582,583,584,585,709,710,71
3,762,764,766,768,769,770,774,775,776,777,803

Protein Structure and Feature Comparision


check button Protein Structure Comparision Using Template Modeling Scores (TM-score).
all structure

check button Protein Structure Comparision Visualization with mol*. between Canonical predicted structure (AF2)(orange) vs Canonical validated structure (PDB)(green)
3D view using mol* of Q96PU5-1_Q96PU5-1_5hpk_A.pdb

check button Protein Structure Comparision Visualization with mol*. between Canonical validated structure (PDB)(orange) vs Alternative predicted structure (AF2)(green)
3D view using mol* of Q96PU5-1_5hpk_A_Q96PU5-2.pdb
3D view using mol* of Q96PU5-1_5hpk_A_Q96PU5-3.pdb
3D view using mol* of Q96PU5-1_5hpk_A_Q96PU5-4.pdb
3D view using mol* of Q96PU5-1_5hpk_A_Q96PU5-5.pdb
3D view using mol* of Q96PU5-1_5hpk_A_Q96PU5-6.pdb
3D view using mol* of Q96PU5-1_5hpk_A_Q96PU5-7.pdb
3D view using mol* of Q96PU5-1_5hpk_A_Q96PU5-9.pdb

check button Protein Structure Comparision Visualization with mol*. between Canonical predicted structure (AF2)(orange) vs Alternative predicted structure (AF2)(green)
3D view using mol* of Q96PU5-1_Q96PU5-2.pdb
3D view using mol* of Q96PU5-1_Q96PU5-3.pdb
3D view using mol* of Q96PU5-1_Q96PU5-4.pdb
3D view using mol* of Q96PU5-1_Q96PU5-5.pdb
3D view using mol* of Q96PU5-1_Q96PU5-6.pdb
3D view using mol* of Q96PU5-1_Q96PU5-7.pdb
3D view using mol* of Q96PU5-1_Q96PU5-9.pdb

check button Protein Feature Comparison of the protein sequendary structures among the protiens.
./stats/secondary_structure/figure/Q96PU5-1_vs_Q96PU5-2.png
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./stats/secondary_structure/figure/Q96PU5-1_vs_Q96PU5-3.png
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./stats/secondary_structure/figure/Q96PU5-1_vs_Q96PU5-9.png
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check button Protein Feature Comparison of the relative accessible surface area (ASA) among the protiens.
./stats/relative_asa/Q96PU5-1_vs_Q96PU5-2.png
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./stats/relative_asa/Q96PU5-1_vs_Q96PU5-3.png
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./stats/relative_asa/Q96PU5-1_vs_Q96PU5-9.png
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Protein-Protein Interaction


check button Interactors from UniProt.
Accession_idSubsectionStartEndFuncitonal featureSplicing information


check button Interactors from STRING.
Gene nameInteractors


Related Drugs to NEDD4L


check button Drugs targeting this gene/protein.
(DrugBank)
UniProt accessionGene nameDrugBank IDDrug nameDrug groupActions

Related Diseases to NEDD4L


check button Previous studies relating to the alternative splicing of NEDD4L and disease information from the MeSH term (PubMed)
GenePMIDTitleAbstractMeSH IDMeSH term
NEDD4L24711643Identifying biological pathways that underlie primordial short stature using network analysis.Mutations in CUL7, OBSL1 and CCDC8, leading to disordered ubiquitination, cause one of the commonest primordial growth disorders, 3-M syndrome. This condition is associated with i) abnormal p53 function, ii) GH and/or IGF1 resistance, which may relate to failure to recycle signalling molecules, and iii) cellular IGF2 deficiency. However the exact molecular mechanisms that may link these abnormalities generating growth restriction remain undefined. In this study, we have used immunoprecipitation/mass spectrometry and transcriptomic studies to generate a 3-M 'interactome', to define key cellular pathways and biological functions associated with growth failure seen in 3-M. We identified 189 proteins which interacted with CUL7, OBSL1 and CCDC8, from which a network including 176 of these proteins was generated. To strengthen the association to 3-M syndrome, these proteins were compared with an inferred network generated from the genes that were differentially expressed in 3-M fibroblasts compared with controls. This resulted in a final 3-M network of 131 proteins, with the most significant biological pathway within the network being mRNA splicing/processing. We have shown using an exogenous insulin receptor (INSR) minigene system that alternative splicing of exon 11 is significantly changed in HEK293 cells with altered expression of CUL7, OBSL1 and CCDC8 and in 3-M fibroblasts. The net result is a reduction in the expression of the mitogenic INSR isoform in 3-M syndrome. From these preliminary data, we hypothesise that disordered ubiquitination could result in aberrant mRNA splicing in 3-M; however, further investigation is required to determine whether this contributes to growth failure.D004392Dwarfism
NEDD4L24711643Identifying biological pathways that underlie primordial short stature using network analysis.Mutations in CUL7, OBSL1 and CCDC8, leading to disordered ubiquitination, cause one of the commonest primordial growth disorders, 3-M syndrome. This condition is associated with i) abnormal p53 function, ii) GH and/or IGF1 resistance, which may relate to failure to recycle signalling molecules, and iii) cellular IGF2 deficiency. However the exact molecular mechanisms that may link these abnormalities generating growth restriction remain undefined. In this study, we have used immunoprecipitation/mass spectrometry and transcriptomic studies to generate a 3-M 'interactome', to define key cellular pathways and biological functions associated with growth failure seen in 3-M. We identified 189 proteins which interacted with CUL7, OBSL1 and CCDC8, from which a network including 176 of these proteins was generated. To strengthen the association to 3-M syndrome, these proteins were compared with an inferred network generated from the genes that were differentially expressed in 3-M fibroblasts compared with controls. This resulted in a final 3-M network of 131 proteins, with the most significant biological pathway within the network being mRNA splicing/processing. We have shown using an exogenous insulin receptor (INSR) minigene system that alternative splicing of exon 11 is significantly changed in HEK293 cells with altered expression of CUL7, OBSL1 and CCDC8 and in 3-M fibroblasts. The net result is a reduction in the expression of the mitogenic INSR isoform in 3-M syndrome. From these preliminary data, we hypothesise that disordered ubiquitination could result in aberrant mRNA splicing in 3-M; however, further investigation is required to determine whether this contributes to growth failure.D006130Growth Disorders
NEDD4L24711643Identifying biological pathways that underlie primordial short stature using network analysis.Mutations in CUL7, OBSL1 and CCDC8, leading to disordered ubiquitination, cause one of the commonest primordial growth disorders, 3-M syndrome. This condition is associated with i) abnormal p53 function, ii) GH and/or IGF1 resistance, which may relate to failure to recycle signalling molecules, and iii) cellular IGF2 deficiency. However the exact molecular mechanisms that may link these abnormalities generating growth restriction remain undefined. In this study, we have used immunoprecipitation/mass spectrometry and transcriptomic studies to generate a 3-M 'interactome', to define key cellular pathways and biological functions associated with growth failure seen in 3-M. We identified 189 proteins which interacted with CUL7, OBSL1 and CCDC8, from which a network including 176 of these proteins was generated. To strengthen the association to 3-M syndrome, these proteins were compared with an inferred network generated from the genes that were differentially expressed in 3-M fibroblasts compared with controls. This resulted in a final 3-M network of 131 proteins, with the most significant biological pathway within the network being mRNA splicing/processing. We have shown using an exogenous insulin receptor (INSR) minigene system that alternative splicing of exon 11 is significantly changed in HEK293 cells with altered expression of CUL7, OBSL1 and CCDC8 and in 3-M fibroblasts. The net result is a reduction in the expression of the mitogenic INSR isoform in 3-M syndrome. From these preliminary data, we hypothesise that disordered ubiquitination could result in aberrant mRNA splicing in 3-M; however, further investigation is required to determine whether this contributes to growth failure.D009123Muscle Hypotonia


Clinically important variants in NEDD4L


check button (ClinVar, 04/20/2024)
accession_iduniprot_idgene_nameTypeVariantClinical_significance