APLP2


Amyloid-like protein 2, also known as APLP2, is a protein that in humans is encoded by the APLP2 gene. APLP2 along with APLP1 are important modulators of glucose and insulin homeostasis.

Gene location

The human APLP2 gene is located on the long arm of chromosome 11 at region 2 band 4, from base pair 130, 069, 821 to base pair 130, 144, 811.

Protein structure

APLP2 consists of 763 amino acids, with 31 amino acids making up the signal peptide and 732 amino acids making up the chain of the protein.

Extracellular domain

The extracellular domain contains the E1 domain, E2 domain, and BPTI/Kunitz inhibitor domain. The E1 domain contains two independent folding units, the growth factor-like domain and the copper-binding domain. GFLD has a highly charged basic surface and a highly flexible region consisting of an N-terminal loop formed by a disulphide bridge. CuBD consists of an alpha-helix that is tightly packed on a triple-stranded beta-sheet.
The E2 domain is the largest subdomain of APLP2 and consists of six alpha-helixes. The N-terminal double stranded coiled coil structure of the first monomer of E2 packs against the C-terminal triple stranded coiled coil structure of the second monomer.
The BPTI/Kunitz inhibitor domain is ‘Cys-rich’ and is capable of inhibiting several proteases.
The ectodomain of APLP2 is dimeric and contains multiple binding sites for metal ions and components of the extracellular matrix. These bindings site can bind copper, zinc, collagen and heparan sulfate.

Transmembrane region

The transmembrane region of APLP2 is helical in structure.

Cytoplasmic domain

The cytoplasmic domain contains a YENPTY sequence suggesting a duel function of the domain. The NPxY motif can function as a signal for endocytosis or the sequence can function to mediate binding of various interactive partners.

Function

APLP2 associates with antigen presentation molecules like MHC class I molecules and regulates their surface expression by enhancing endocytosis.
APLP1 and APLP2 double knockout mice display hypoglycemia and hyperinsulinemia indicating that these two proteins are important modulators of glucose and insulin homeostasis. APLP2 has also been shown to regulate development of the brain by regulating migration and differentiation of neural stem cells.
Double mice knock outs of APLP2 and its homologues, APP and APLP1 have shown a strong indication that APLP2 has the key physiological role among the family members. APLP2/APP double knock out mice and APLP2/APLP1 double knock out mice each show a lethal phenotype, whereas APLP1/APP double knock out mice are apparently normal, demonstrating the importance of the APLP2 protein.
APLP2 plays a role in synaptic plasticity, functioning to promote neurite outgrowth, neural cell migration and copper homeostasis. Analysing the neurons and networks of APP/APLP2 double knock out mice using stem cell-derived neurons and slice cultures, shows deficient excitatory synaptic transmission in this genotype. Moreover, APLP2 together with APP has been demonstrated to exhibit presynaptic and postsynaptic functions in synaptogenesis and maintenance of synapses.
APLP2 has shown to act as a cargo receptor in axonal transport for intact proteins.

Clinical significance

APLP2 is part of a family of mammalian membrane proteins along with APLP1 and amyloid precursor protein. Since APP plays a key role in the molecular pathology of Alzheimer’s disease, it has been hypothesized that APLP2 also plays a role in AD pathogenesis. The amyloid β peptide that is present on APP has been shown to cause neurotoxic effects leading to AD. Although the Aβ sequence is not present on APLP2, it has been suggested that APLP2 and APP share a functional redundancy whereby both proteins interplay with one another to exhibit physiological functions to do with synapse formation.

Interactions

APLP2 has been shown to interact with APBB1.