{PDOC50104}
{PS50104; TIR}
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* TIR domain profile *
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Toll  proteins  or  Toll-like  receptors (TLRs) and the interleukin-1 receptor
(IL-1R)  superfamily  are both involved in innate antibacterial and antifungal
immunity  in  insects as well as in mammals. These receptors share a conserved
cytoplasmic  domain  of approximately 200 amino acids, known as the Toll/IL-1R
homologous  region  (TIR).  The  similarity  between  TLRs  and  IL-1Rs is not
restricted  to  sequence  homology  since  these proteins also share a similar
signaling pathway. They both induce the activation of a Rel type transcription
factor  via an adaptor protein and a protein kinase [1]. Interestingly, MyD88,
a  cytoplasmic  adaptor  protein  found  in  mammals,  contains  a  TIR domain
associated to  a DEATH domain (see <PDOC50017>) [2,3,4]. Besides the mammalian
and  Drosophila  proteins,  a  TIR  domain  is also found in a number of plant
cytoplasmic proteins  implicated  in  host  defense  and  in diverse bacterial
genera (Streptomyces,  Caulobacter,  Rhizobium,  Anabaena,  Synechocystis  and
Bacillus) [5,6].

The TIR  domain  has  been  defined  as  a  scaffold that promotes assembly of
signaling complexes via protein-protein interactions. However, the scaffolding
function may be a recent adaptation. The primordial function of the TIR domain
is a  self-association-dependent  nicotinamide  dinucleotide (NAD(+))-cleaving
enzyme (NADase)  activity that cleaves NAD(+) into nicotinamide (Nam) and ADP-
ribose (ADPR),  cyclic ADPR (cADPR) or variant cADPR (v-cADPR), with catalytic
cleavage executed by a conserved glutamic acid [7,8,9,10].

Structurally, the  TIR  domain  consists  of  a central five-stranded parallel
beta-sheet (betaA-betaE)  surrounded  by  five  helices  (alphaA-alphaE)  with
connecting loop  structures  (see <PDB:1FYV>). The loop regions appear to play
an important   role   in   mediating   the   specificity   of  protein-protein
interactions [9,10,11].  Sequence analyses have revealed the presence of three
highly conserved  regions among the different members of the TIR family: box 1
(FDAFISY), box  2  (GYKLC-RD-PG), and box 3 (a conserved W surrounded by basic
residues). It has been proposed that boxes 1 and 2 are involved in the binding
of proteins  involved  in  signaling,  whereas  box 3 is primarily involved in
directing localization   of   receptor,   perhaps  through  interactions  with
cytoskeletal elements [12].

Some proteins known to contain a TIR domain are listed below:

 - Mammalian  interleukin-1  receptor.  It  is composed of two type I integral
   membrane proteins,   IL-1R  and  IL-1RacP,  that  share  three  Ig  domains
   (extracellular) and one TIR domain (cytoplasmic) [12].
 - Myeloid  differentiation  factor  (MyD88),  a  cytoplasmic protein found in
   mammals. It  also contains a DEATH domain and acts as an adaptor protein in
   IL-1R and TLR mediated signaling [2,3,4].
 - Toll,  from  Drosophila.  The  Toll  signaling  pathway is required for the
   establishment of  the  dorso-ventral axis during embryogenesis and plays an
   important role  in  the  immune  response  against bacteria and fungi. Toll
   contains two  extracellular  LRRs, adjacent cysteine containing motifs, one
   transmembrane domain,  an  intracellular  TIR  domain  and an intracellular
   inhibitory domain [4].
 - Animal SARM1 (sterile alpha and TIR motif containing 1), a NAD(+) hydrolase
   (NADase) required for Wallerian degeneration in axons after nerve injury
   [9].
 - LRR  and  TIR  domains  containing  proteins from plants. These cytoplasmic
   proteins are important in the host response to infection [5].

We developed a profile that covers the entire TIR domain.

-Sequences known to belong to this class detected by the profile: ALL.
-Other sequence(s) detected in Swiss-Prot: NONE.
-Last update: November 2019 / Text and profile revised.

[ 1] Takeuchi O., Kawai T., Sanjo H., Copeland N.G., Gilbert D.J.,
     Jenkins N.A., Takeda K., Akira S.
     "TLR6: A novel member of an expanding toll-like receptor family."
     Gene 231:59-65(1999).
     PubMed=10231569
[ 2] Mitcham J.L., Parnet P., Bonnert T.P., Garka K.E., Gerhart M.J.,
     Slack J.L., Gayle M.A., Dower S.K., Sims J.E.
     "T1/ST2 signaling establishes it as a member of an expanding
     interleukin-1 receptor family."
     J. Biol. Chem. 271:5777-5783(1996).
     PubMed=8621445
[ 3] Muzio M., Ni J., Feng P., Dixit V.M.
     "IRAK (Pelle) family member IRAK-2 and MyD88 as proximal mediators of
     IL-1 signaling."
     Science 278:1612-1615(1997).
     PubMed=9374458
[ 4] Anderson K.V.
     "Toll signaling pathways in the innate immune response."
     Curr. Opin. Immunol. 12:13-19(2000).
     PubMed=10679407
[ 5] Van der Biezen E.A., Jones J.D.
     "Plant disease-resistance proteins and the gene-for-gene concept."
     Trends. Biochem. Sci. 23:454-456(1998).
     PubMed=9868361; DOI=10.1016/s0968-0004(98)01311-5
[ 6] Spear A.M., Loman N.J., Atkins H.S., Pallen M.J.
     "Microbial TIR domains: not necessarily agents of subversion?"
     Trends. Microbiol. 17:393-398(2009).
     PubMed=19716705; DOI=10.1016/j.tim.2009.06.005
[ 7] Kopp E.B., Medzhitov R.
     "The Toll-receptor family and control of innate immunity."
     Curr. Opin. Immunol. 11:13-18(1999).
     PubMed=10047546
[ 8] Essuman K., Summers D.W., Sasaki Y., Mao X., Yim A.K.Y., DiAntonio A.,
     Milbrandt J.
     "TIR Domain Proteins Are an Ancient Family of NAD(+)-Consuming
     Enzymes."
     Curr. Biol. 28:421-430.e4(2018).
     PubMed=29395922; DOI=10.1016/j.cub.2017.12.024
[ 9] Horsefield S., Burdett H., Zhang X., Manik M.K., Shi Y., Chen J.,
     Qi T., Gilley J., Lai J.-S., Rank M.X., Casey L.W., Gu W.,
     Ericsson D.J., Foley G., Hughes R.O., Bosanac T., von Itzstein M.,
     Rathjen J.P., Nanson J.D., Boden M., Dry I.B., Williams S.J.,
     Staskawicz B.J., Coleman M.P., Ve T., Dodds P.N., Kobe B.
     "NAD(+) cleavage activity by animal and plant TIR domains in cell
     death pathways."
     Science 365:793-799(2019).
     PubMed=31439792; DOI=10.1126/science.aax1911
[10] Wan L., Essuman K., Anderson R.G., Sasaki Y., Monteiro F., Chung E.-H.,
     Osborne Nishimura E., DiAntonio A., Milbrandt J., Dangl J.L.,
     Nishimura M.T.
     "TIR domains of plant immune receptors are NAD(+)-cleaving enzymes
     that promote cell death."
     Science 365:799-803(2019).
     PubMed=31439793; DOI=10.1126/science.aax1771
[11] Xu Y., Tao X., Shen B., Horng T., Medzhitov R., Manley J.L., Tong L.
     "Structural basis for signal transduction by the Toll/interleukin-1
     receptor domains."
     Nature 408:111-115(2000).
     PubMed=11081518; DOI=10.1038/35040600
[12] Slack J.L., Schooley K., Bonnert T.P., Mitcham J.L., Qwarnstrom E.E.,
     Sims J.E., Dower S.K.
     "Identification of two major sites in the type I interleukin-1
     receptor cytoplasmic region responsible for coupling to
     pro-inflammatory signaling pathways."
     J. Biol. Chem. 275:4670-4678(2000).
     PubMed=10671496

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