In the 1960s, the sequence similarity of several proteases indicated that they were evolutionarily related.[8] These were grouped into the chymotrypsin-like serine proteases[9] (now called the S1 family). As the structures of these, and other proteases were solved by X-ray crystallography in the 1970s and 80s, it was noticed that several viral proteases such as Tobacco Etch Virus protease showed structural homology despite no discernible sequence similarity and even a different nucleophile.[2][10][11] Based on structural homology, a superfamily was defined and later named the PA clan (by the MEROPS classification system). As more structures are solved, more protease families have been added to the PA clan superfamily.[12][13]
The P refers to Proteases of mixed nucleophile. The A indicates that it was the first such clan to be identified (there also exist the PB, PC, PD and PE clans).[1]
Above, sequence conservation of 250 members of the PA protease clan (superfamily). Below, sequence conservation of 70 members of the C04 protease family. Arrows indicate catalytic triad residues. Aligned on the basis of structure by DALI
Surface structure of TEV protease. The C-terminal extension only present in viral members of the PA clan of chymotrypsin-like proteases as (a) surface with loop in blue (b) secondary structure and (c)b-factor putty (wider regions indicate greater flexibility) for the structure of TEV protease. Substrate in black, active site triad in red. The final 15 amino acids (222-236) of the enzyme C-terminus are not visible in the structure as they are too flexible. (PDB: 1lvm, 1lvb)
Despite retaining as little as 10% sequence identity, PA clan members isolated from viruses, prokaryotes and eukaryotes show structural homology and can be aligned by structural similarity (e.g. with DALI).[3]
PA clan proteases all share a core motif of two β-barrels with covalent catalysis performed by an acid-histidine-nucleophile catalytic triad motif. The barrels are arranged perpendicularly beside each other with hydrophobic residues holding them together as the core scaffold for the enzyme. The triad residues are split between the two barrels so that catalysis takes place at their interface.[14]
In addition to the double β-barrel core, some viral proteases (such as TEV protease) have a long, flexible C-terminal loop that forms a lid that completely covers the substrate and create a binding tunnel. This tunnel contains a set of tight binding pockets such that each side chain of the substrate peptide (P6 to P1’) is bound in a complementary site (S6 to S1’) and specificity is endowed by the large contact area between enzyme and substrate.[11] Conversely, cellular proteases that lack this loop, such as trypsin have broader specificity.
Structural homology indicates that the PA clan members are descended from a common ancestor of the same fold. Although PA clan proteases use a catalytic triad perform 2-step nucleophilic catalysis,[7] some families use serine as the nucleophile whereas others use cysteine.[2] The superfamily is therefore an extreme example of divergent enzyme evolution since during evolutionary history, the core catalytic residue of the enzyme has switched in different families.[15] In addition to their structural similarity, directed evolution has been shown to be able to convert a cysteine protease into an active serine protease.[16] All cellular PA clan proteases are serine proteases, however there are both serine and cysteine protease families of viral proteases.[7] The majority are endopeptidases, with the exception being the S46 family of exopeptidases.[17][18]
In addition to divergence in their core catalytic machinery, the PA clan proteases also show wide divergent evolution in function. Members of the PA clan can be found in eukaryotes, prokaryotes and viruses and encompass a wide range of functions. In mammals, some are involved in blood clotting (e.g. thrombin) and so have high substrate specificity as well as digestion (e.g. trypsin) with broad substrate specificity. Several snake venoms are also PA clan proteases, such as pit viperhaemotoxin and interfere with the victim's blood clotting cascade. Additionally, bacteria such as Staphylococcus aureus secrete exfoliative toxin which digest and damage the host's tissues. Many viruses express their genome as a single, massive polyprotein and use a PA clan protease to cleave this into functional units (e.g. polio, norovirus, and TEV proteases).[19][20]
There are also several pseudoenzymes in the superfamily, where the catalytic triad residues have been mutated and so function as binding proteins.[21] For example, the heparin-binding protein Azurocidin has a glycine in place of the nucleophile and a serine in place of the histidine.[22]
Within the PA clan (P=proteases of mixed nucleophiles), families are designated by their catalytic nucleophile (C=cysteine proteases, S=serine proteases). Despite the lack of sequence homology for the PA clan as a whole, individual families within it can be identified by sequence similarity.
^de Haën C, Neurath H, Teller DC (February 1975). "The phylogeny of trypsin-related serine proteases and their zymogens. New methods for the investigation of distant evolutionary relationships". Journal of Molecular Biology. 92 (2): 225–59. doi:10.1016/0022-2836(75)90225-9. PMID1142424.
^Lesk AM, Fordham WD (May 1996). "Conservation and variability in the structures of serine proteinases of the chymotrypsin family". Journal of Molecular Biology. 258 (3): 501–37. doi:10.1006/jmbi.1996.0264. PMID8642605.