Microfibril-associated glycoprotein 4 forms octamers that mediate interactions with elastogenic proteins and cells

Abstract

AbstractMicrofibrillar-associated protein 4 (MFAP4) is a 36-kDa extracellular glycoprotein with critical roles in human pathologies, including fibrosis in several organ systems, chronic obstructive pulmonary disease, and cardiovascular disorders. In elastic tissues such as arteries, lungs, and skin, MFAP4 associates with microfibrils and elastic fibres, which are the central extracellular fibres affected in thoracic aneurysms. MFAP4 directly interacts with elastogenic proteins, including fibrillin-1 and tropoelastin, and with cells via integrins. MFAP4 multimerisation represents a critical hallmark required for its physiological and pathological properties. However, molecular details and functional consequences of MFAP4 multimerisation are lacking.Here we present a cryo-electron microscopy structure of human MFAP4. In the presence of calcium, MFAP4 assembles as an octamer with D2 point group symmetry, where two sets of homodimers constitute the top and bottom halves of each octamer. Each of the homodimers is linked together by an inter-molecular disulfide bond. An engineered C34S missense mutation in MFAP4 prevented disulfide-bond formation between monomers, but the mutant formed octamers similar to wild type MFAP4. The atomic model, built into the 3.55 Å cryo-EM map, suggests that several salt-bridges are important for interactions within and between homodimers, while non-polar interactions are important for octamer halves to assemble. In the absence of calcium, MFAP4 dissociates into tetramers, representing the top/bottom halves of the octamers. Binding studies with elastogenic proteins, including fibrillin-1, tropoelastin, LTBP4, and small fibulins showed that MFAP4 has multiple surfaces for protein-protein interactions, which depend upon the higher-order assembly of MFAP4. While the disulfide-bond mediated by C34S contributes little to those protein interactions, it modulated cell interaction. When MFAP4 forms assemblies with fibrillin-1, it abrogates MFAP4 interactions with cells. Overall, the study provides detailed molecular structure-function relationships of MFAP4 interactions with elastogenic proteins and cells.