Abstract
Unlike most receptors, Notch serves as both the receiver and direct transducer of signaling events. Activation can be mediated by one of five membrane-bound ligands of either the Delta-like (-1, -2, -4) or Jagged/Serrate (-1, -2) families. Alternatively, dissociation of the Notch heterodimer with consequent activation can also be mediated experimentally by calcium chelators or by mutations that destabilize the Notch1 heterodimer, such as in the human disease T cell acute lymphoblastic leukemia. Here we show that MAGP-2, a protein present on microfibrils, can also interact with the EGF-like repeats of Notch1. Co-expression of MAGP-2 with Notch1 leads to both cell surface release of the Notch1 extracellular domain and subsequent activation of Notch signaling. Moreover, we demonstrate that the C-terminal domain of MAGP-2 is required for binding and activation of Notch1. Based on the high level of homology, we predicted and further showed that MAGP-1 can also bind to Notch1, cause the release of the extracellular domain, and activate signaling. Notch1 extracellular domain release induced by MAGP-2 is dependent on formation of the Notch1 heterodimer by a furin-like cleavage, but does not require the subsequent ADAM metalloprotease cleavage necessary for production of the Notch signaling fragment. Together these results demonstrate for the first time that the microfibrillar proteins MAGP-1 and MAGP-2 can function outside of their role in elastic fibers to activate a cellular signaling pathway.
Highlights
Notch signaling is best known for its role in cell fate determination and is critical for regulating multiple cellular processes in many different tissues, including those of the nervous, hematopoietic, and vascular systems (1)
MAGP-2 Generates a Soluble Form of the Extracellular Domain of Heterodimeric Notch1—We asked what consequence MAGP-2 binding had on the N1 receptor, if MAGP-2 induced release of the N1 extracellular domain (ECD), much like what we reported for Jagged1
We have shown that MAGP-2 binding to either Jagged1 (10) or Notch1 leads to the functional consequence of extracellular domain loss
Summary
Notch signaling is best known for its role in cell fate determination and is critical for regulating multiple cellular processes in many different tissues, including those of the nervous, hematopoietic, and vascular systems (1). At least some of the heterodimerization domain mutations potentiate the dissociation of an engineered soluble form of the heterodimer, mimicking the biological effects of ligand-induced Notch signaling, and constructs encoding just the NTM sequences are constitutively active (8, 9).
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