{PDOC00204}
{PS00319; APP_CUBD}
{PS00320; APP_INTRA}
{PS51869; APP_E1}
{PS51870; APP_E2}
{BEGIN}
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* APP E1 and E2 domains profiles and CuBD and intracellular domains signatures *
********************************************************************************

Alzheimer's disease  (AD)  is  the most frequent form of progressive dementia,
occurring predominantly  in the elderly population. AD is characterized by the
presence of  amyloid  plaques,  extensive  neuronal death and shrinkage of the
brain. It  is  increasingly  accepted  that  the neurotoxic beta-amyloid or A4
peptide (beta/A4)  is  responsible  for  compromising  neuronal  functions and
triggering cell death. The peptide is derived from the cleavage of the amyloid
precursor protein  (APP)  and  is the main constituent of the amyloid plaques.
APP belongs  to a wider family of APP-like proteins (APLPs) that include APLP1
and APLP2  in  mammals  (see  <PDOC00204>).  These proteins exhibit functional
redundancy to  some  degree  and  can  undergo cleavage, but only APP cleavage
gives rise  to  the  beta/A4  peptide.  APP and APLPs are type-I transmembrane
proteins with  a  large  extracellular  portion, which can be structurally and
functionally subdivided into several domains. At the N-terminus is a cysteine-
rich region,  termed  E1,  consisting of the growth factor like domain (GFLD),
which binds  heparin and can stimulate neurite outgrowth, and a copper-binding
domain (CuBD)  that  binds  Cu and Zn. The E1 domain is followed by an acidic-
rich region  of  sequence,  a Kunitz-type protease inhibitor (KPI) domain (see
<PDOC00252>) and  an  OX2  domain.  Following  these domains is a glycosylated
domain referred  to  as  E2,  a region predicted to adopt no regular secondary
structure and the transmembrane region. The C-terminal cytoplasmic tail may be
involved in  various  cellular  functions,  such  as  transcription signaling,
through interaction with a multitude of proteins. Homo- and heterodimerization
of APP  and  APLPs,  which are enhanced by heparan sulfate binding, may play a
role in signal transduction and cell adhesion.

The E1 domain functions as a rigid functional entity. Two E1 entities dimerize
upon their  interaction  with  heparin, requiring 8-12 sugar rings to form the
heparin-bridged E1  dimer. The two subdomains, GFLD and CuBD, interact tightly
in a  pH-dependent  manner via an evolutionarily conserved interface area (see
<PDB:3KTM>). The  highly  conserved,  well-defined interdomain linker does not
adopt any  standard  secondary  structure  but connects both subdomains like a
zipper and  contributes  to  the mostly hydrophobic interdomain interface area
[1,2]. The  slightly  larger GFLD subdomain consists of a central antiparallel
beta-sheet, one  alpha-helix,  and  a  short  two-stranded  beta-sheet, cross-
connected by three disulfide bridges (see <PDB:1MWP>) [3]. The 65-residue CuBD
subdomain is defined by conserved histidine residues and consists of a central
three-stranded antiparallel  beta-sheet  and  a long alpha-helix, catenated by
three additional disulfide bridges (see <PDB:2FK2>) [4,5,6].

The E2  domain  forms  an antiparallel dimer. E2 dimerization is a dynamic and
reversible process   and   heparin  binding  to  E2  shifts  the  association-
dissociation equilibrium  in  favor  of dimer. The structure of E2 consists of
two coiled-coil  substructures  connected through a continuous helix and bears
an unexpected    resemblance  to the spectrin family of protein structure (see
<PDB:3NYL>). The E2 contains a high affinity heparin binding site [7,8,9].

We have derived  two  patterns specific to these proteins,  the first one is a
perfectly conserved  octapeptide  located  in the CuBD domain; the second is a
conserved octapeptide located at the C-terminal end of the cytoplasmic domain.
We also  developed  two  profiles  covering  respectively the entire E1 and E2
domains.

-Consensus pattern: G-[VT]-[EK]-[FY]-V-C-C-P
-Sequences known to belong to this class detected by the pattern: ALL.
-Other sequence(s) detected in Swiss-Prot: NONE.

-Consensus pattern: G-Y-E-N-P-T-Y-[KRS]
-Sequences known to belong to this class detected by the pattern: ALL.
-Other sequence(s) detected in Swiss-Prot: NONE.

-Sequences known to belong to this class detected by the profile: ALL.
-Other sequence(s) detected in Swiss-Prot: NONE.

-Sequences known to belong to this class detected by the profile: ALL.
-Other sequence(s) detected in Swiss-Prot: NONE.

-Last update: July 2018 / Pattern and text revised; profiles added.

[ 1] Dahms S.O., Hoefgen S., Roeser D., Schlott B., Guehrs K.-H., Than M.E.
     "Structure and biochemical analysis of the heparin-induced E1 dimer of
     the amyloid precursor protein."
     Proc. Natl. Acad. Sci. U. S. A. 107:5381-5386(2010).
     PubMed=20212142; DOI=10.1073/pnas.0911326107
[ 2] Hoefgen S., Dahms S.O., Oertwig K., Than M.E.
     "The amyloid precursor protein shows a pH-dependent conformational
     switch in its E1 domain."
     J. Mol. Biol. 427:433-442(2015).
     PubMed=25528641; DOI=10.1016/j.jmb.2014.12.005
[ 3] Rossjohn J., Cappai R., Feil S.C., Henry A., McKinstry W.J.,
     Galatis D., Hesse L., Multhaup G., Beyreuther K., Masters C.L.,
     Parker M.W.
     "Crystal structure of the N-terminal, growth factor-like domain of
     Alzheimer amyloid precursor protein."
     Nat. Struct. Biol. 6:327-331(1999).
     PubMed=10201399; DOI=10.1038/7562
[ 4] Kong G.K.-W., Adams J.J., Harris H.H., Boas J.F., Curtain C.C.,
     Galatis D., Masters C.L., Barnham K.J., McKinstry W.J., Cappai R.,
     Parker M.W.
     "Structural studies of the Alzheimer's amyloid precursor protein
     copper-binding domain reveal how it binds copper ions."
     J. Mol. Biol. 367:148-161(2007).
     PubMed=17239395; DOI=10.1016/j.jmb.2006.12.041
[ 5] Barnham K.J., McKinstry W.J., Multhaup G., Galatis D., Morton C.J.,
     Curtain C.C., Williamson N.A., White A.R., Hinds M.G., Norton R.S.,
     Beyreuther K., Masters C.L., Parker M.W., Cappai R.
     "Structure of the Alzheimer's disease amyloid precursor protein copper
     binding domain. A regulator of neuronal copper homeostasis."
     J. Biol. Chem. 278:17401-17407(2003).
     PubMed=12611883; DOI=10.1074/jbc.M300629200
[ 6] Leong S.L., Young T.R., Barnham K.J., Wedd A.G., Hinds M.G., Xiao Z.,
     Cappai R.
     "Quantification of copper binding to amyloid precursor protein domain
     2 and its Caenorhabditis elegans ortholog. Implications for biological
     function."
     Metallomics 6:105-116(2014).
     PubMed=24276282; DOI=10.1039/c3mt00258f
[ 7] Wang Y., Ha Y.
     "The X-ray structure of an antiparallel dimer of the human amyloid
     precursor protein E2 domain."
     Mol. Cell 15:343-353(2004).
     PubMed=15304215; DOI=10.1016/j.molcel.2004.06.037
[ 8] Lee S., Xue Y., Hu J., Wang Y., Liu X., Demeler B., Ha Y.
     "The E2 domains of APP and APLP1 share a conserved mode of
     dimerization."
     Biochemistry 50:5453-5464(2011).
     PubMed=21574595; DOI=10.1021/bi101846x
[ 9] Xue Y., Lee S., Ha Y.
     "Crystal structure of amyloid precursor-like protein 1 and heparin
     complex suggests a dual role of heparin in E2 dimerization."
     Proc. Natl. Acad. Sci. U. S. A. 108:16229-16234(2011).
     PubMed=21930949; DOI=10.1073/pnas.1103407108

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