Molecular markers of serine protease evolution.

The evolutionary history of serine proteases can be accounted for by highly conserved amino acids that form crucial structural and chemical elements of the catalytic apparatus. These residues display non- random dichotomies in either amino acid choice or serine codon usage and serve as discrete markers for tracking changes in the active site environment and supporting structures. These markers categorize serine proteases of the chymotrypsin-like, subtilisin-like and alpha/beta-hydrolase fold clans according to phylogenetic lineages, and indicate the relative ages and order of appearance of those lineages. A common theme among these three unrelated clans of serine proteases is the development or maintenance of a catalytic tetrad, the fourth member of which is a Ser or Cys whose side chain helps stabilize other residues of the standard catalytic triad. A genetic mechanism for mutation of conserved markers, domain duplication followed by gene splitting, is suggested by analysis of evolutionary markers from newly sequenced genes with multiple protease domains.

Sequence determinants of function and evolution in serine proteases.

Serine proteases of the chymotrypsin family have maintained a common fold over an evolutionary span of more than one billion years. Notwithstanding modest changes in sequence, this class of enzymes has developed a wide variety of substrate specificities and important biological functions such as fibrinolysis, blood coagulation, and complement activation. Recently it has become apparent that the protease domain, especially its C-terminal sequence, accounts fully for this functional diversity and is the most important element in shaping serine protease evolution.

The C-terminal sequence encodes function in serine proteases.

Serine proteases of the chymotrypsin family have maintained a common fold over an evolutionary span of more than one billion years. Notwithstanding modest changes in sequence, this class of enzymes has developed a wide variety of substrate specificities and important biological functions. Remarkably, the C-terminal portion of the sequence in the protease domain accounts fully for this functional diversity. This portion is often encoded by a single exon and contains most of the residues forming the contact surface in the active site for the P1-P3 residues of the substrate, as well as domains responsible for the modulation of catalytic activity. The evolution of serine proteases was therefore driven by optimization of contacts made with the unprimed subsites of the substrate and targeted a relatively short portion of the sequence toward the C-terminal end. The dominant role of the C-terminal sequence should facilitate the identification of function in newly discovered genes belonging to this class of enzymes.

Conserved water molecules in the specificity pocket of serine proteases and the molecular mechanism of Na+ binding.

Conservation of clusters of buried water molecules is a structural motif present throughout the serine protease family. Frequently, these clusters are shaped as water channels forming extensive hydrogen-bonding networks linked to the protein backbone. The most conspicuous example is the water channel present in the specificity pocket of trypsin and thrombin. In thrombin, other vitamin K-dependent proteases, and some complement factors, Na+ binds in this water channel and enhances allosterically the catalytic activity of the enzyme, whereas digestive and fibrinolytic proteases are devoid of such regulation. A comparative analysis of proteases with and without Na+ binding capability reveals the role of the water channel in maintaining the structural organization of the specificity pocket and in Na+ coordination. This enables the formulation of a molecular mechanism for Na+ binding in thrombin and leads to the identification of the structural changes necessary to engineer a functional Na+ site and enhanced catalytic activity in trypsin and other proteases.