Abstract
Proteolytic processing of the amyloid precursor protein (APP) generates large soluble APP derivatives, β-amyloid (Aβ) peptides, and APP intracellular domain. Expression of the extracellular sequences of APP or its Caenorhabditis elegans counterpart has been shown to be sufficient in partially rescuing the CNS phenotypes of the APP-deficient mice and the lethality of the apl-1 null C. elegans, respectively, leaving open the question as what is the role of the highly conserved APP intracellular domain? To address this question, we created an APP knock-in allele in which the mouse Aβ sequence was replaced by the human Aβ. A frameshift mutation was introduced that replaced the last 39 residues of the APP sequence. We demonstrate that the C-terminal mutation does not overtly affect APP processing and amyloid pathology. In contrast, crossing the mutant allele with APP-like protein 2 (APLP2)-null mice results in similar neuromuscular synapse defects and early postnatal lethality as compared with mice doubly deficient in APP and APLP2, demonstrating an indispensable role of the APP C-terminal domain in these development activities. Our results establish an essential function of the conserved APP intracellular domain in developmental regulation, and this activity can be genetically uncoupled from APP processing and Aβ pathogenesis.
Highlights
Proteolytic processing of the amyloid precursor protein (APP) generates large soluble APP derivatives, -amyloid (A) peptides, and APP intracellular domain
Expression of the extracellular sequences of APP or its Caenorhabditis elegans counterpart has been shown to be sufficient in partially rescuing the CNS phenotypes of the APP-deficient mice and the lethality of the apl-1 null C. elegans, respectively, leaving open the question as what is the role of the highly conserved APP intracellular domain? To address this question, we created an APP knock-in allele in which the mouse A sequence was replaced by the human A
Generation and Expression Analysis of APP/hA/mutC Knock-in Animals—To investigate the role of the highly conserved APP C-terminal domain in survival, neuromuscular synapse development, and amyloid pathology in vivo, we created a knock-in allele in which the mouse A was replaced by the human A sequence with simultaneous introduction of the Swedish/London/Arctic familial Alzheimer disease (FAD) mutations
Summary
APLP1/APLP2, or missing all three APP members are early postnatal lethal [9, 10]. Our analysis of APP/APLP2 double knock-out mice identified an essential role for the APP family of proteins in the patterning of neuromuscular junction (NMJ) [11]. Further investigation of neuromuscular synapse and central synaptogenesis support the notion that APP is a synaptic adhesion protein, and that the synaptogenic function requires full-length APP [12, 13]. The early postnatal lethality and the diffused synaptic distribution of the NMJ present in the APP/ APLP2 double knock-out animals provide sensitive and specific readouts for us to definitely determine the role of the APP C-terminal domain in vivo. The C-terminal domain is dispensable for APP processing, secretion, and amyloidogenesis
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