Interleukin-1 receptor accessory protein - Q9NPH3 (IL1AP_HUMAN)

 

Protein Feature View of PDB entries mapped to a UniProtKB sequence  

  • Number of PDB entries for Q9NPH3: 2
 
Function
Coreceptor for IL1RL2 in the IL-36 signaling system (By similarity). Coreceptor with IL1R1 in the IL-1 signaling system. Associates with IL1R1 bound to IL1B to form the high affinity interleukin-1 receptor complex which mediates interleukin-1-dependent activation of NF-kappa-B and other pathways. Signaling involves the recruitment of adapter molecules such as TOLLIP, MYD88, and IRAK1 or IRAK2 via the respective TIR domains of the receptor/coreceptor subunits. Recruits TOLLIP to the signaling complex. Does not bind to interleukin-1 alone; binding of IL1RN to IL1R1, prevents its association with IL1R1 to form a signaling complex. The cellular response is modulated through a non-signaling association with the membrane IL1R2 decoy receptor. Coreceptor for IL1RL1 in the IL-33 signaling system. Can bidirectionally induce pre- and postsynaptic differentiation of neurons by trans-synaptically binding to PTPRD. UniProt
Pathway Maps
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Subunit Structure
The interleukin-36 receptor complex is a heterodimer of IL1RL2 and IL1RAP; the association is inhibited by IL36RN (By similarity). The interleukin-1 receptor complex is a heterodimer of IL1R1 and IL1RAP. Associates with IL1R2 to form a non-signaling interleukin-1 receptor complex. Isoform 4 interacts with IL1R1 in a interleukin-1-dependent manner. Interacts with IL-33-bound IL1RL1 to form the minimal interleukin-33 signaling complex with a 1:1:1 stoichiometry. Interacts with KIT (independently of stimulation with KITLG/SCF). A mast cell-specific KITLG/SCF-induced interleukin-33 signaling complex contains IL1RL1, IL1RAP, KIT and MYD88 (By similarity). Interacts (via the first immunoglobilin domain) with PTPRD (via the third immunoglobilin domain); induces pre- and postsynaptic differentiation of neurons. UniProt
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Data in orange originates from the SCOP   (version 1.75) and SCOPe   (version 2.04) classifications.
Data in grey has been calculated using BioJava  . Protein disorder predictions are based on JRONN (Troshin, P. and Barton, G. J. unpublished), a Java implementation of RONN  
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Data in lilac represent the genomic exon structure projected onto the UniProt sequence.
Data in blue originates from PDB
  • Secstruc: Secondary structure projected from representative PDB entries onto the UniProt sequence.
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Validation Track

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The PDB to UniProt mapping is based on the data provided by the EBI SIFTS project. See also Velankar et al., Nucleic Acids Research 33, D262-265 (2005).
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