Lysozyme binds to elastin and protects elastin from elastase-mediated degradation.

Lysozyme has been shown to be associated with damaged elastic fibers in many tissues and organs. To better characterize this interaction, binding of lysozyme to elastin was studied using solution-based binding assays. Under physiologic conditions, radio-labeled lysozyme bound specifically to elastin in a time- and concentration-dependent manner. Binding was reversible and was inhibited by unlabeled human and hen lysozyme but not by other proteins. Lysozyme had no elastolytic activity as assessed by a standard tritium-release assay, but, importantly, prevented the proteolytic degradation of elastin by human leukocyte elastase, pancreatic elastase, thermolysin, and Pseudomonas elastase. A striking feature of lysozyme's anti-elastase activity was that it did not function in the classical sense of inhibiting directly the enzymatic activity of the protease. Instead, by binding to elastin, lysozyme prevented the protease from interacting with the elastin substrate in ways that normally favor proteolysis. These results show that lysozyme binds to the elastin component of elastic fibers and that this interaction has important biological consequences for elastic fiber degradation. By preventing degradation of elastin, lysozyme can function as an important natural inhibitor that exerts a protective effect on elastic fibers at sites of tissue injury.

Microfibril-associated glycoprotein binds to the carboxyl-terminal domain of tropoelastin and is a substrate for transglutaminase.

Microfibril-associated glycoprotein (MAGP) is an integral component of microfibrillar structures that play a critical role in the organization of elastic fibers in the extracellular matrix. To study possible molecular interactions between MAGP and other elastic fiber components, we have generated native MAGP using a baculovirus expression system and tested its ability to associate with tropoelastin and fibrillin. MAGP produced by SF9 cells underwent processing similar to the mammalian protein, including correct cleavage of the signal peptide and sulfation of tyrosine residues. When tested in solid-phase binding assays, native MAGP specifically bound to tropoelastin but not fibrillin-1. Binding to tropoelastin was divalent cation-independent and was completely blocked by reduction and alkylation of either protein. Antibody inhibition studies indicated that the carboxyl terminus of tropoelastin mediated its interaction with MAGP. In addition to binding to elastin, MAGP was also a substrate for transglutaminase, which might explain its propensity to form high molecular weight aggregates that cannot be dissociated with reduction or denaturation. Together, the results of this study provide new insights into the functional relationship between microfibrillar proteins and have important implications for understanding elastic fiber assembly.

The cysteine residues in the carboxy terminal domain of tropoelastin form an intrachain disulfide bond that stabilizes a loop structure and positively charged pocket.

Analysis of purified bovine tropoelastin with Ellman's reagent and [14C]iodoacetamide demonstrated that the only two cysteine residues in the molecule form an intrachain disulfide bond. Molecular modeling suggests that the cysteine residues are juxtaposed as the result of a tight turn that produces an antiparallel beta structure. Protruding from the C-terminal end of the turn is the sequence Arg-Lys-Arg-Lys which forms the floor of a positively charged pocket created by the extension of the arginine and lysine side chains on opposite sides of the peptide chain perpendicular to the plane of the turn. The side chain of a conserved lysine residue in the disulfide-bonded loop forms the top of the pocket. This positively charged pocket may define a binding site for acidic microfibrillar proteins that mediate elastic fiber assembly.