Protein Elastase

Cotton is a much weaker ion exchanger than the DEAE or SP supports described earlier. In its underivatized state, cotton is hydrophilic and nonionic. We have confirmed this by packing underivatized cotton into an empty HPLC column, then introducing proteins. Elastase did not bind, even under weak buffer conditions. However, when cotton was derivatized with an elastase-recognition-sequence, elastase was retained. 

FIGURE 16.16 Comparison of the amino acid sequences of chymotrypsinogen, trypsino-gen, and elastase. Each circle represents one amino acid. Nmnbering is based on the sequence of chymotrypsinogen. Filled circles indicate residues that are identical in all three proteins. Disnlfide bonds are indicated in yellow. The positions of the three catalytically important active-site residues (His, Asp °-, and Ser ) are indicated. 

There are other substrates for the E. coli Met(0) peptide reductase, one of which is Met(0)-a-l-PI. The native protein is the major serum elastase inhibitor that functions by forming a binary complex with elastase which inhibits its activity. Met(0)-a-l-PI, on the other hand, which can be formed by treatment of the protein with TV-chlorosuccinimide, cannot form a complex with elastase and therefore is not able to inhibit elastase activity117,118. Table 6 shows, however, that when Met(0)-a-l-PI is incubated in the presence of Met(0)-peptide reductase and dithiothreitol the protein regains its ability to form a complex with elastase and inhibit elastase activity119. Similar to results found with Met(0)-L12 reduced thioredoxin could replace the dithiothreitol as reductant in the enzymatic reaction. 

In the past number of years a number of studies have shown that in a variety of diseases there is a significant oxidation of Met residues to Met(O) in specific proteins that results in a loss of biological activity. These diseases include cataracts, rheumatoid arthritis, adult respiratory distress syndrome and emphysema. The most convincing evidence that Met(O) in proteins may be involved in the etiology of a pathological condition comes from studies with a-l-PI. It is well accepted that a-l-PI is inactivated upon oxidation of its Met residues. A decreased activity of a-l-PI in lung tissue that would result in an increased elastase activity has been associated with pulmonary emphysema. In patients who have a... 

In rheumatoid arthritis the damage that is found in joints may also be a result of the inactivation of a-l-PI due to the oxidation of an essential methionine(s) residue in this protein. It has been found that a-l-PI purified from the synovial fluid of patients with rheumatoid arthritis contained four Met(O) residues and was not able to form a binary complex with elastase . It is probable that the presence of the Met(O) residues in a-l-PI from these patients results from a high level of oxidants produced by neutrophils in the inflammed joint. 

Alpha-l-antiprotease (ai-AP) limits tissue damage arising from the actions of the leucocyte protease, elastase (Carrell and Travis, 1985), and there is much evidence available for the oxidative inactivation of this protein by oxygen-derived free-radical species and hypochlorous acid/hypochlorite anion (HOCl/OCP). The mechanism of this inactivation appears to involve the oxidation of a critical methionine residue (Met-358) to its corresponding sulphoxide and methionine sulphoxide has been detected in ai-AP samples isolated from the lungs of cigarette smokers (Carp et al., 1982) and rheumatoid synovial fluids (Wong and Travis, 1980). 

A major problem in unfolding studies of large proteins is irreversibility. In a study of elastase temperature-induced denaturation, second-derivative FTIR show a distinct loss of several sharp amide V features (dominant /3-sheet components and growth in broadened bands at 1645 and 1668 cm-1 (Byler et al., 2000). These features persisted on cooling, indicating lack of reversibility, a feature common to longer multidomain proteins. A graphic example of this is seen in the triosephosphate... 

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