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REVIEW ARTICLE Evolutionary mechanisms acting on proteinase inhibitor variability John T Christeller Horticulture & Food Research Institute of NZ, Palmerston North, New Zealand Keywords evolution; hypervariability; pathogenesis; predation; proteinase inhibitor Correspondence J T Christeller, HortResearch, Private Bag 11030, Palmerston North, New Zealand Tel: +64 6356 8080, ext 7760 E-mail: jchristeller@hortresearch.co.nz (Received 31 May 2005, accepted 15 September 2005) doi:10.1111/j.1742-4658.2005.04975.x The interaction of proteinase inhibitors produced, in most cases, by host organisms and the invasive proteinases of pathogens or parasites or the dietary proteinases of predators, results in an evolutionary ‘arms race’ of rapid and ongoing change in both interacting proteins The importance of these interactions in pathogenicity and predation is indicated by the high level and diversity of observable evolutionary activity that has been found At the initial level of evolutionary change, recruitment of other functional protein-folding families has occurred, with the more recent evolution of one class of proteinase inhibitor from another, using the same mechanism and proteinase contact residues The combination of different inhibitor domains into a single molecule is also observed The basis from which variation is possible is shown by the high rate of retention of gene duplication events and by the associated process of inhibitory domain multiplication At this level of reorganization, mutually exclusive splicing is also observed Finally, the major mechanism by which variation is achieved rapidly is hypervariation of contact residues, an almost ubiquitous feature of proteinase inhibitors The diversity of evolutionary mechanisms in a single class of proteins is unlikely to be common, because few systems are under similar pressure to create variation Proteinase inhibitors are therefore a potential model system in which to study basic evolutionary process such as functional diversification Proteinase inhibitors are a diverse group of proteins that share not only a common biochemical activity, but also the distinguishing feature of rapidly undergoing evolutionary variation Currently, 59 distinct families of proteinase inhibitors have been recognized [1] I use the term ‘family’ in this review to denote these phylogenetic groupings and the term ‘class’ to denote inhibitors that interact with proteinases with mechanistic similarities, i.e the serine-, cysteine-, aspartic and metallo-proteinases Phylogenetic relationships among several of these inhibitor families have been analysed: including the serpin family [2–8], Bowman–Birk [9,10], cereal trypsin ⁄ a-amylase inhibitor [11], proteinase inhibitor I [12], proteinase inhibitor II [13] and cystatin [14,15] Compared with the total number of families that are currently recognized, this represents a very small proportion, although phylogenetic trees for all 5710 families have been constructed (http://merops.sanger ac.uk) These relationships are useful in developing an understanding of when and where the inhibitor class evolved; however, they not provide information on the mechanisms driving gene evolution The focus of many reviews of proteinase inhibitors over the last 25 years has been on classification and structure–function relationships These proteins have not been well recognized as a class of proteins with an interesting evolutionary history The purpose of this review is to summarize, for the first time, information relevant to proteinase inhibitor evolution, much of it collected incidentally, with the express intention of stimulating possible interest in this area Proteinase inhibitors and their binding to proteinases have been extremely well characterized for more than 70 years and I focus only on those inhibitors that have FEBS Journal 272 (2005) 5710–5722 ª 2005 The Horticulture and Food Research Institute J T Christeller the attributes of being involved in protein–protein interactions representing antagonistic interorganism interactions In this review, I draw attention to the evidence that proteinase inhibitor evolution appears to occur by multiple and interacting mechanisms not currently identified for other coevolving molecules and that this feature may be indicative of both a high rate of evolutionary change and the role of protein–protein interactions Both attributes appear necessary, the mechanisms are less apparent in proteinase inhibitors targeted at intraorganism target proteinases than for interorganism interactions, from which the majority of the examples are drawn Proteinase inhibitors, pathogens and pests Evolutionary pressures of various kinds have often been hypothesized to cause active and rapid evolutionary change Various lines of evidence suggest that a major function of proteinase inhibitors is to combat the proteinases of pests and pathogens [16–20] The secreted proteinases of the latter organisms are key components of invasive cocktails, required for entry into the host and rapid utilization of its constituent proteins In these situations, there is clearly evolutionary pressure for the host to respond by evolving new and effective inhibitors This model is often termed the ‘evolutionary arms race’ [21] Consistent with the role of proteinase inhibitors in resistance to invasion is the observation that massive accumulation of proteinase inhibitors occurs in certain tissues and organs that are likely sites of attack First are those tissues whose high nutritional value presents to a pest or pathogen the best possible site for attack, for example, seeds [22], other plant storage organs such as plant tubers [23,24], and the eggs of birds [25] The reproductive strategies of these organisms require that the best possible nutrition be provided in these tissues and they are therefore clearly an attractive food sources for others Proteinase inhibitors from these sources have long been extensively studied and often contain inhibitors of multiple families and classes There appear to be few, if any, studies on the proteinase inhibitors in the eggs of other egg-laying organisms such as fish and insects, or on the proteinase inhibitors of organisms that retain their eggs internally It is possible that the evolution of internal egg-bearing is related to the reduced pest, pathogen and parasite attack that comes with this strategy The second attractive site of attack by invasive organisms is fluids that permit transport of the pathogen throughout the host, for example, mammalian Proteinase inhibitor variability serum, invertebrate haemolymph and plant phloem Indeed, these three fluids are, once again, a rich source of many and varied proteinase inhibitors and have been studied extensively However, caution needs to be applied; the primary role of these inhibitors in blood appears to be regulation of the blood-clotting cascade In insects, proteinase inhibitors in the haemolymph clearly play a part in the immune response, particularly in regulating the activation of prophenoloxidase in response to invasion by pathogens [26] The function of the diverse phloem proteinase inhibitors is unclear [27–30] The third situation that can be identified in which extensive and varied proteinase inhibitor accumulation arises is the reverse situation, where proteinase inhibitors themselves are the pathogenic determinants For example, the salivas of leeches and blood-sucking insects contain multiple inhibitors [31] that inactivate the proteinases of the blood-clotting cascade, thereby preventing blood-clotting and permitting the invader to feed freely Structural gene evolution In this review, the evolutionary mechanisms used by organisms to enhance variation in the structural genes of proteinase inhibitors are discussed This story is but one third of the equation; the other two parts, evolution of cognate proteinases and evolution of the proteinase inhibitor regulatory sequences are not discussed except en passant, partly because of the need to limit the breadth of the review and partly because the identification of the cognate proteinase is, in many cases, yet to be verified and because mechanisms of promoter evolution are a distinct and new topic entirely The identification of cognate proteinases is often extremely challenging and, where achieved, has led to specific studies on coevolution [19,32,33] The evolution of promoters has clearly occurred with equal rapidity to that of the structural genes For example, orthologues of the proteinase inhibitor I family are known that have constitutive, tuber-specific [34], wounding signalinduced, leaf-specific [35], phloem-specific [36], fruit-specific [37], developmentally regulated [38], ethylene-induced [39] and cell-cycle-specific [40] promoters These processes may be most active in plants because many pests and pathogens use S1 superfamily serine proteinases as pathogenic determinants and these are not common in plants (The Arabidopsis Information Resource, TAIR, database at http://www arabidopsis.org, lists 55 serine proteinases from 546 endopeptidases); thus the problem of isolating serine proteinase inhibitors from plant metabolic and FEBS Journal 272 (2005) 5710–5722 ª 2005 The Horticulture and Food Research Institute 5711 Proteinase inhibitor variability J T Christeller regulatory processes is less critical, a consideration that might slow inhibitor evolution in other organisms In mammals, serpins separate into secreted inhibitors involved in pathogen defence processes and intracellular inhibitors involved in cellular regulation; the former show high rates of evolution, whereas the latter not [8] In the following sections, each distinct evolutionary mechanism is discussed separately, yet it is clear from the examples given that they not act in isolation The first three mechanisms relate to the fundamental evolution of this group of molecules The fourth to the sixth mechanisms appear to establish a higher level of diversity that forms the basis from which the seventh and final mechanism described is fundamental for generation of the large variation observed Recruitment of other protein-folding scaffolds to proteinase inhibitor function It is apparent that recruitment of numerous proteinfolding scaffolds to proteinase inhibitor function has occurred This is clearly seen in the various folds of several proteinase inhibitors First, inhibitory serpins share 30% amino acid sequence homology with ovalbumin, the major storage protein of egg white, and share, with several other noninhibitory proteins, the same basic structure [41] Second, five members of the large cereal a-amylase inhibitor family have developed proteinase inhibitor function, and three of these have lost the former activity during evolution [11] Interestingly, these inhibitors exhibit the same novel backbone structure as is also observed in 2S seed storage proteins and in nonspecific lipid transfer proteins [11,42], suggesting even earlier recruitment of a-amylase inhibitor function Third, equistatin [43,44], fish egg inhibitor [45], saxiphilin [46], testican [47] and p41 major histocompatibility complex fragment [48] are cysteine proteinase inhibitors based on the thyroglobulin fold Fourth, soybean Kunitz inhibitors have homology to noninhibitory proteins sporamin A [49], stress-induced proteins [50], dehydroascorbate reductase [51] and miraculin [52] Finally, it has been suggested that both Bowman–Birk and cystatin inhibitors have evolved from an ancient ribonuclease-like gene [53] Other major plant storage proteins, as well as the cereal a-amylase inhibitor and the soybean Kunitz inhibitor may have been recruited to additional function For example, the Bowman–Birk inhibitors in seeds and proteinase inhibitors I and II in potato tubers are present at such high levels that they 5712 function as storage proteins [23] Possibly their ancestral types, lacking proteinase inhibitor function, have been lost due to the evolutionary advantage of producing dual-function proteins Thus, although we have only identified five examples from 59 known inhibitor classes [1] it is possible that further examples will be identified in the future as additional proteinase inhibitor structures become available Knowledge of the inhibitory mechanism may assist understanding of how the recruitment processes evolved Two of the above example inhibitors are serine proteinase inhibitors that use the ‘standard canonical’ or ‘Laskowski mechanism’ This involves the presence on the surface of the inhibitor of a stabilized loop that can mimic a substrate but which has long residency times in the proteinase active site pocket as a result of that conformational stability The loop also has a protruding amino acid side chain that mimics the proteinase target specificity [54–56] The combination of these features produces a rapid-binding, slow-release specific inhibitor rather than a substrate The distinction may, in fact, not be clear cut, as substrate proteins may, under specific conditions, have inhibitory properties relative to small reporter substrates used to assay proteinases, for example, napins, legumins [57] (W A Laing, HortResearch, personal communication) It seems entirely possible that any surface loop or even stretch of exposed amino acids could evolve inhibitory function by reducing flexibility through evolving intraprotein interactions, creating a loop by insertion of a very few amino acids and mutating a single amino acid to form a P1 bait site residue Evidence for this can be found by inspection of crystal structures of inhibitors and their putative ancestral proteins This is clear for the cereal trypsin ⁄ amylase family in which the structure of the bifunctional ragi inhibitor complex with Tenebrio molitor a-amylase [58] showed that the proteinase binding loop adopts a canonical conformation at the opposite side of the molecule This loop is absent from the a-amylase inhibitor [59] It also appears correct for serpins, because the intact active site loop adopts a distorted helical conformation in the P10–P3¢ region, overlapping a type I b-turn in P2¢–P5¢ [60] compared with an undistorted a-helix for ovalbumin [41] The modification in structure between inhibitory and noninhibitory forms is probably due to the presence of proline residues and a four amino acid insertion at this point in the inhibitor sequence [60] This hypothesis requires that the rapid evolution of proteinase inhibitors began somewhat late in evolutionary history, when many of the major protein folds had already evolved, and that evolution has been from established essential functional proteins to new FEBS Journal 272 (2005) 5710–5722 ª 2005 The Horticulture and Food Research Institute J T Christeller supplementary functions If the stimulus for this to occur is the development of pests and pathogens it supposes that these interactions also were not a feature of early life and, so far as the discussion revolves around multicellular organisms as hosts, this is a reasonable assumption It should be noted, however, that the ‘Laskowski mechanism’ is not a feature of most families of inhibitors that inhibit proteinase classes, i.e inhibitors of metalloproteinases, cysteine proteinases and aspartic proteinases even though these proteinases possess characteristic residues at their active sites (cation, sulfydryl and aspartyl, respectively) Although many of these inhibitors are competitive, binding at the active site to prevent access to substrates, they not mimic a substrate, are not cleaved reversibly and often utilize more than a single exposed loop in their direct active site contacts Of these proteins, only one class, the thyropins, has been identified as recruited structures Change of inhibitory class Recruitment of one family of proteinase inhibitors to inhibit a second class of proteinases is an evolutionary mechanism that can be readily identified and for which several examples are known It is a special case of recruitment of another protein fold where the proteinase inhibitory structure is also recruited, or is likely to have been recruited, and is likely to have occurred more recently This is seen in (a) serine proteinase inhibitors of the serpin family recruited to cysteine proteinase inhibition [61], (b) serine proteinase inhibitor of the serpin family recruited to aspartic proteinase inhibition [3,62], (c) serine proteinase inhibitor of the seed Kunitz family recruited to cysteine proteinase inhibition [63], (d) serine proteinase inhibitor of the seed Kunitz family recruited to aspartic proteinase inhibition [64], (e) serine proteinase inhibitor of the Bowman–Birk class recruited to cysteine proteinase inhibition [65], (f) cysteine proteinase inhibitors of the cystatin family recruited to aspartic proteinase inhibition (W A Laing, unpublished observations), and (g) cysteine proteinase inhibitors of the thyropin class, recruited to aspartic proteinase inhibition [66] This recruitment mechanism is not uncommon, having been identified in six of 59 known inhibitor families to date It is necessary to discuss each case individually, rather than assume that this represents a special and recent example of recruitment of another functional protein as discussed above The serine proteinase inhibitors of the serpin family not operate via the ‘Laskowski mechanism’ However, they have evolved a Proteinase inhibitor variability very effective ‘suicide’ irreversible mechanism in which the inhibitor (following Michelis complex formation) partitions between a tetrahedral stable intermediate and a cleaved, inactive inhibitor [67,68] leading to covalent bond formation via acyl bond formation and a large conformation This is often observed as an SDS-stable product that migrates more slowly during PAGE than the unreacted proteinase and inhibitor It seems that this mechanism has been maintained during evolution to the cysteine inhibitory form because the structure with a reactive site loop remains [69,70], the corresponding thioacyl complex has been detected [71] and the cleavage site remains within the single reactive loop of several dual class inhibitors [72,73] Because the serine proteinase inhibitor molecule is apparently found in a diverse range of organisms: eukarya, bacteria, archaea and viruses [6] it is clearly the ancestral form and appears to have evolved directly to the new class of cysteine proteinase inhibitors found, to date, in mammals and viruses [61] The situation with the aspartic proteinase inhibitors has not yet been resolved with no studies investigating the presence of a covalent bond being reported Interestingly, both these examples of recruitment of function appear to be an old divergence, occurring at a similar time to mammalian divergence [73] although these altered inhibitors have, to date, been reported only from mammals It is also noteworthy that whereas most serpins are secreted, one clade is intracellular and members function as regulators of ‘promiscuous’ proteinases [8], rather than being involved regulation of endogenous cascades or in protection from pathogens Despite extensive studies, we still not know whether the aspartic proteinase inhibitors that have clearly been recruited from standard mechanism Kunitz seed serine inhibitors, have recruited the latter molecules’ serine proteinase inhibitor loop to inhibit aspartic proteinases At least one member of this small family restricted to Solanaceae [64] has the ability to inhibit both classes [74] Clearly, a structure of an inhibitor– aspartic protease complex would be of great interest because successful attempts to determine a cleavage site for this system have not been reported Owing to the very different pH optima for complex formation of the two classes it is difficult to even show whether simultaneous binding of two proteinases is possible Although the active site loop of serine proteinase inhibitors of the seed Kunitz appears to have been disrupted in the cysteine inhibitors of this class [63], there is no information on the mode of interaction of these inhibitors with cysteine proteinases although some members of these inhibitors retain weak antitrypsin and antichymotrypsin activity [75] FEBS Journal 272 (2005) 5710–5722 ª 2005 The Horticulture and Food Research Institute 5713 Proteinase inhibitor variability J T Christeller The cysteine proteinase inhibitor, bromelain inhibitor VI from pineapple, is a double-chain inhibitor that shares similar folding and disulfide bond connectivities with the Bowman–Birk trypsin ⁄ chymotrypsin inhibitor [65] The authors suggested that these inhibitors have evolved from a common ancestor and differentiated in function during a course of molecular evolution However, the B-domain of bromelain inhibitor VI has weak antitryptic activity, suggesting that class conversion is a reasonable alternative The recruitment of a cystatin to aspartic proteinase inhibitor [28,76] is based on sequence homology of around 30% and similarity of around 50% between rice cystatin and squash aspartic proteinase inhibitor (SQAPI) and modelling the later onto the crystal structure of the former (W A Laing, unpublished observations) Inhibition appears to involve the same areas of interaction; mutation and removal of residues at two regions known to be involved in cystatin interactions [77] abolishing aspartic protein inhibition (P Farley, unpublished data) and hypervariability within the small inhibitor family also occurs at these sites and at the third site known to be involved in cystatin interactions (J T Christeller, unpublished observations) The tentative conclusion is that this small family of aspartic proteinase inhibitors, restricted to members of the Cucurbitales (J T Christeller, unpublished data) has evolved directly from the much more widespread cystatin inhibitors Equistatin is a protein consisting of three thyroglobulin domains [44], the N-terminal domain inhibiting cysteine proteinases and the central and C-terminal domains inhibiting aspartic proteinases Equistatin is therefore a member of the thyropin class of inhibitors, of which all other known members are cysteine proteinase inhibitors The published structure of the thyropin p41 fragment shows a wedge shape and three-loop inhibitory structure similar to cystatins, thus suggestive of convergent evolution [78] There is no information on the mode of inhibition of the aspartic proteinase inhibitor variant domains of equistatin Proteinaceous aspartic proteinase inhibitors are very rare in nature and four of the six known families are recruited from other classes, with only two, the yeast inhibitor IA3 [79] and the Ascaris PI-3 inhibitor [80] being uniquely aspartic inhibitor families Both inhibitors are small and have quite idiosyncratic inhibitory mechanisms Thus inhibitor class change appears to be the mechanism of choice for this class of proteinases These observations, combined with their rarity, may indicate that the aspartic class of proteinases have evolved relatively recently, at least to fulfil the function of defence proteins Given the relative rarity of metalloproteinase inhibitors, similar questions may be asked 5714 about the time of their evolution and their recruitment to a defence protein role Domain shuffling Recently, two examples of multidomain proteins have been identified in which different domains with distinct inhibitor classes are fused into a single inhibitor First, testican is a multidomain protein with three domains having homology to different proteinase inhibitors, an N-terminal domain with metalloproteinase inhibitory activity [81], a follistatin-like domain with similarity to Kazal serine proteinase inhibitors although no serine proteinase inhibition has yet been reported and a thyropin domain that inhibits cysteine proteinases [47] Second, the WFIKKN protein [82] has, based on homology, a whey acidic protein metalloproteinase inhibitor module, a follistatin ⁄ Kazal inhibitor module and two Kunitz-type modules One of the latter domains has been shown to inhibit trypsin [83] Although this evolutionary mechanism seems to be uncommon, the existence of this type of domain-shuffling event may indicate the high evolutionary pressure that proteinase inhibitors experience, permitting coordinate expression of proteinase inhibitors against a cocktail of secreted proteinases Gene duplication Gene duplication is a very common feature of proteinase inhibitors Many, if not most, inhibitors are present as small gene families with altered specificities among the paralogues Two features of pathogenicity and predation may drive this process; first, the presence of multiple attacking organisms with variation in their proteinases and, second, the presence of multiple proteinases in single organisms, for example, secreted aspartic proteinases of Candida number more than 10, whereas the digestive proteinase genes of lepidopteran larvae number in the hundreds Thus gene duplication, coupled with rapid adaptation processes (detailed below) form a mechanism to resist invaders Because there is no evidence that these genes duplicate at higher rates than any others, their fixation in the genome is more likely to be due to rapid adaptation and the selective advantage obtained Fryxell [84] considers that fixation of gene duplication is maintained by coevolution of functionally related gene families His hypothesis seems appropriate for proteinases and their inhibitors Habu et al [85] studied the evolution of duplicated Kunitz inhibitor genes in winged bean and a complex series of gene inactivation and gene conversion events was inferred FEBS Journal 272 (2005) 5710–5722 ª 2005 The Horticulture and Food Research Institute J T Christeller Domain replication and circular permutation Domain replication serves a similar function to gene duplication, both providing a base from which variability can be established Instead of complete gene duplication, including promoter and terminator sequences and possible reintegration at a distinct locus, there is duplication of the inhibitory domain sequence with the domains remaining fused This evolutionary mechanism is very common in many inhibitor gene families and has been well reviewed for some time [1,55,86] Again, it serves the function of not only coordinated expression, but also increased levels of expression The most extreme examples are genes in the proteinase inhibitor II and cystatin families Proteinase inhibitor II family members have been characterized with varying numbers of domains, from one [13,87], two [88], three [89], four [90], six [91] through to eight [92] Many of these proteinase inhibitor II polyproteins are processed proteolytically, displaying the highly unusual phenomenon of cleavage within the domain [93], with the final molecule having N- and C-terminal sections being circularly permutated The final conformation adopted by these domain hybrid molecules is identical to that adopted by single domain versions [87], likely to represent the putative ancestral sequence order [94] A mechanism involving unequal gene cross-over has been proposed to account for this variation by Barta et al [13] who also noted that this may be a scenario to enhance functional diversity against pathogens These multiplication and circular-permutation events have been followed by rapid divergence within single genes to target diverse proteinases Members of the proteinase inhibitor II family have been reported to inhibit chymotrypsin, elastase, oryzin, pronase E, subtilisin and trypsin [95–97] Circular permutation has been observed in other proteins, including proteinases [98,99] The second extreme example occurs in potato tubers where a single 85 kDa polypeptide, potato multicystatin comprises eight tandem cystatin domains, with 53–89% identity of residues, linked by proteolytically sensitive junctions [100,101] Potato multicystatin comprises a family of four to six genes in potato and the pattern of gene expression, as well as the properties of the protein suggest that potato multicystatin has a role in plant defence [101] Although single domain cystatins are most common, a three-domain multicystatin has been isolated from sunflower seeds [102] and kininogens are also three-domain cystatins [103] Proteinase inhibitor variability Mutually exclusive splicing A single serpin gene of Manduca sexta expressed in the haemolymph comprises 10 exons, with the ninth, containing the reactive site loop, existing as 12 variants all positioned between the eighth and tenth exons [103–105] All 12 variants, each possessing a single ninth exon, are found in a M sexta cDNA library, indicating that mutually exclusive exon splicing is occurring The mechanism occurs in many other other genes, being first reported in tropomyosin [106] and includes serpin genes from Bombyx mori [107], Ctenocephalides felis [108], Drosophila melanogaster and Caenorhabditis elegans [109]; albeit with smaller numbers of exclusive exons The only other proteinase inhibitors reported to use alternative splicing are mammalian calpastatins [110] in which the variant exons include the initiation codons It is likely that the evolution of the system occurs by uneven crossover of chromosomes [105] Hypervariability Hypervariability in proteins, which may be defined as enhanced variation among orthologous and paralogous genes at the contact residues, is often proposed as an example of positive Darwinian evolution although this idea remains controversial [111] Hypervariability is virtually a defining feature among proteinase inhibitors and the key mechanism in creating variation Hypervariability in proteinase inhibitors occurs when nucleotides encoding proteinase contact residues within the active site loops in ‘Laskowski mechanism’ inhibitors such as the ovomucoids [112,113] and the aprotinin family [32] and in ‘non-Laskowski (nonstandard)’ inhibitors such as the serpins [17,114,115] mutate and are fixed in the genome at a much higher rate as amino acid variants compared with residues elsewhere in the molecule [32], or, at a nucleotide level, at a rate higher than silent mutations [116] That hypervariation results in functional diversity, although long the predicted outcome, has been demonstrated by Barbour et al [117] The importance of the three preceding mechanisms that act to produce the gene multiplicity needed to generate functional diversity cannot be overemphasized Ohta [33] also concluded that ‘that positive selection operated after duplication to increase functional diversity’ and concluded that mechanistically ‘hypervariability of amino acids at the reactive center is generated by an interaction among natural selection, random genetic drift, point mutation, and gene conversion’ FEBS Journal 272 (2005) 5710–5722 ª 2005 The Horticulture and Food Research Institute 5715 Proteinase inhibitor variability J T Christeller Proteinase inhibitors from classes other than serine proteinase inhibitors have also shown hypervariability, such as cystatins [32] and squash aspartic proteinase inhibitor (SQAPI; J T Christeller, unpublished data) Hypervariability is extremely common among proteinase inhibitors and proteinases [32, 33,118], with only two examples of diversification of proteinase inhibitors without evidence of positive selection have been reported [12,119] Hypervariability appears to be a feature of other pairs of interacting molecules such as resistance genes [120], surface antigens [121], thionins [122] and conotoxins [111,123], but is otherwise rare, in line with the neutral model of evolution [124] These interactions also seem to be examples of the operation of a coevolutionary ‘arms race’ Whether these proteins will also show a similar range of evolutionary mechanisms as proteinase inhibitors in addition to hypervariability is not yet known, although as avirulence genes are being identified, some information on their evolution is being published [125–128] Although the above description completes the specific evolutionary mechanisms currently known to occur in proteinase inhibitors, there are two additional related areas that are relevant to proteinase inhibitor evolution Interaction of proteinase inhibitors with inactive proteinases An emerging story is the possibility of proteinase inhibitor inactivation by inactive variants of proteinases as antagonists Mathialagan and Hansen [62] suggest that the pregnancy-associated glycoproteins that are inactive aspartic proteinases [118] may be the cognate proteinases of uterine serpins The inactive proteinases would act to bind a proportion of the inhibitors, leaving some active proteinases to fulfil the desired function, in a situation where overexpression of active proteinases is itself undesirable A similar role has been suggested for the multigene families of inactivated serine and cysteine proteases in Sarcoptes scabiei [129,130], i.e antagonists of host proteinase inhibitors Both stories may represent an adaptation to the parasitic interactions involved in pregnancy and scabies infection This system may operate elsewhere For example, there are inactive proteinase cDNAs in insect midgut, both induced [131] and constitutively expressed [132] If these transcripts are translated and are active in binding proteinase inhibitors, then they may have a role in insect resistance [132] and in explaining the patterns of adaptation observed when insects are fed diets containing proteinase inhibitors [133–135] This inundative strategy, a biochemical 5716 ‘male sterile technique’, may be relatively uncommon because it requires additional resources in terms of protein synthesis However, it also presents a new challenge for proteinase inhibitor evolution because the mechanisms described above operate on the evolving proteinase specificity and structural changes rather than the cryptic changes occurring in proteinase inactivation Proteinase inhibitors and parasitism Our discussion so far has described the various evolutionary mechanisms that have been observed in proteinase inhibitors in their coevolutionary variation with cognate proteinases The examples used exclusively illustrate the concept of a causal relationship between this process and successful plant predation and pathogenesis It is reasonable to interpret parasitism as a less extreme form of pathogenesis or predation in which the host is maintained in a live state The literature on the determinants for successfully establishing a parasitic relationship includes many examples in which proteinases have been implicated These include: (a) stressinduced ClpP of Listeria monocytogenes and its crucial role in intracellular survival of this pathogen [136], (b) inactivation of serine proteases in the Scabies mite [129], (c) mycoparasitism of Agaricus bisporus [137], (d) phytoplasma virulence [138], (e) serine proteinase inhibitors may play a role in the tick larvae fixation and feeding processes [139], (f) Trypanosoma cruzi infection [140], and (g) hookworm adaptation [141] It is therefore possible that in these situations the same causal relationship exists between proteinase–proteinase inhibitor evolution and parasitism However, the existence of proteinase inhibitors, let alone variation and adaptation, has not been demonstrated in all these parasitic relationships We can speculate that this relationship has more far-reaching implications Parasitism has been implicated as a driving force in the development of sex [141–143] If this is true then perhaps proteinase inhibitor evolution is even more important they previously recognized Conclusion The evolutionary pressure surrounding the interaction of proteinases and their inhibitors in an antagonist environment seems to be immense The impression left by the survey presented here is that inhibitors are using virtually every trick in the evolutionary book, and sometimes in combination, to create variation and that the various mechanisms occurring so in a random fashion Whether there are new inhibitors and FEBS Journal 272 (2005) 5710–5722 ª 2005 The Horticulture and Food Research Institute J T Christeller adaptive mechanisms yet to be discovered does not diminish this already impressive list It is probable that proteinase inhibitors are one of the most actively evolving proteins and that they deserve further consideration as model systems to study important evolutionary phenomena Acknowledgements I would like to thank W A Laing (HortResearch, Auckland, New Zealand) for reading the manuscript The project was supported by funding from the Public Good Science Fund, administered by the New Zealand Foundation for Research, Science and Technology (Contract C06X0207) References Rawlings ND, Tolle DP & Barrett AJ (2004) Evolutionary families of peptidase inhibitors Biochem J 378, 705–716 Marshall CJ (1993) Evolutionary relationships among the serpins Phil Trans R Soc Lond Series B Biol Sci 342, 101–119 Peltier MR, Raley LC, Liberles DA, Benner SA & Hansen PJ (2000) Evolutionary history of the uterine serpins J Exp Zool 288, 165–174 Atchley WR, Lokot T, Wollenberg K, Dress A & Ragg H (2001) Phylogenetic analyses of amino acid variation in the serpin proteins Mol Biol Evol 18, 1502–1511 Irving JA, Pike RN, Lesk AM & Whisstock JC (2000) Phylogeny of the serpin superfamily: implications of patterns of amino acid conservation for structure and function Genome Res 10, 1845–1864 Irving JA, Steenbakkers PJ, Lesk AM, Op den Camp HJ, Pike RN & Whisstock JC (2002) Serpins in prokaryotes Mol Biol Evol 19, 1881–1890 Van Gent D, Sharp P, Morgan K & Kalsheker N (2003) Serpins: structure, function and molecular evolution Int J Biochem Cell Biol 35, 1536–1547 Silverman GA, Whisstock JC, Askew DJ, Pak SC, Luke CJ, Cataltepe S, Irving JA & Bird PI (2004) Human clade B serpins (ov-serpins) belong to a cohort of evolutionarily dispersed intracellular proteinase inhibitor clades that protect cells from promiscuous proteolysis Cell Mol Life Sci 61, 301–325 Mello MO, Tanaka AS & Silva-Filho MC (2003) Molecular evolution of Bowman–Birk type proteinase inhibitors in flowering plants Mol Phylogenet Evol 27, 103–112 10 Prakash B, Selvaraj S, Murthy MR, Sreerama YN, Rao DR & Gowda LR (1996) Analysis of the amino acid sequences of plant Bowman–Birk inhibitors J Mol Evol 42, 560–569 Proteinase inhibitor variability 11 Behnke CA, Yee VC, Trong IL, Pedersen LC, Stenkamp RE, Kim SS, Reeck GR & Teller DC (1998) Structural determinants of the bifunctional corn Hage˚ man factor inhibitor: X-ray crystal structure at 1.95 A resolution Biochemistry 37, 15277–15288 12 Beuning LL, Spriggs TW & Christeller JT (1994) Evolution of the proteinase inhibitor I family and apparent lack of hypervariability in the proteinase contact loop J Mol Evol 39, 644–654 13 Barta E, Pintar A & Pongor S (2002) Repeats with variations: accelerated evolution of the Pin2 family of proteinase inhibitors Trends Genet 18, 600–603 14 Rawlings ND & Barrett AJ (1990) Evolution of proteins of the cystatin superfamily J Mol Evol 30, 60–71 15 Margis R, Reis EM & Villeret V (1998) Structural and phylogenetic relationships among plant and animal cystatins Arch Biochem Biophys 359, 24–30 16 Green TR & Ryan CA (1972) Wound-induced proteinase inhibitors in plant leaves: a possible defense mechansism against insects Science 175, 776–777 17 Hill E & Hastie ND (1987) Accelerated evolution in the reactive centre regions of serine protease inhibitors Nature 326, 96–99 18 Tiffin P & Gaut BS (2001) Molecular evolution of the wound-induced serine protease inhibitor wip1 in Zea and related genera Mol Biol Evol 18, 2092–2101 19 Lopes AR, Juliano MA, Juliano L & Terra WR (2004) Coevolution of insect trypsins and inhibitors Arch Insect Biochem Physiol 55, 140–152 20 Travis J, Potempa J & Maeda H (1995) Are bacterial proteinases pathogenic factors? Trends Microbiol 3, 405–407 21 Bush AO, Fernandez JC, Esch GW & Seed JR (2001) Parasitism: The Diversity and Ecology of Animal Parasites Cambridge University Press, Cambridge 22 Birk Y (1996) Protein proteinase inhibitors in legume seeds – overview Arch Latinoamericanos Nutricion 44, 26S–30S 23 Pouvreau L, Gruppen H, Piersma SR, van den Broek LA, van Koningsveld GA & Voragen AG (2001) Relative abundance and inhibitory distribution of protease inhibitors in potato juice from cv Elkana J Agric Food Chem 49, 2864–2874 24 Xie ZW, Luo MJ, Xu WF & Chi CW (1997) Two reactive site locations and structure–function study of the arrowhead proteinase inhibitors, A and B, using mutagenesis Biochemistry 36, 5846–5852 25 Saxena I & Tayyab S (1997) Protein proteinase inhibitors from avian egg whites Cell Mol Life Sci 53, 13– 23 26 Zhu Y, Wang Y, Gorman MJ, Jiang H & Kanost MR (2003) Manduca sexta serpin-3 regulates prophenoloxidase activation in response to infection by inhibiting prophenoloxidase-activating proteinases J Biol Chem 278, 46556–46564 FEBS Journal 272 (2005) 5710–5722 ª 2005 The Horticulture and Food Research Institute 5717 Proteinase inhibitor variability J T Christeller 27 Murray C & Christeller JT (1995) Purification of a trypsin inhibitor (PFTI) from pumpkin fruit phloem exudate and isolation of putative trypsin and chymotrypsin inhibitor cDNA clones Biol Chem HoppeSeyler 376, 281–287 28 Christeller JT, Farley PC, Ramsay R, Sullivan PA & Laing WA (1998) Purification, characterization and cloning of an aspartic proteinase inhibitor from squash phloem exudate Eur J Biochem 254, 160–167 29 Yoo BC, Aoki K, Xiang Y, Campbell LR, Hull RJ, Xoconostle-Cazares B, Monzer J, Lee JY, Ullman DE & Lucas WJ (2000) Characterization of Cucurbita maxima phloem serpin-1 (CmPS-1) A developmentally regulated elastase inhibitor J Biol Chem 275, 35122– 35128 30 Xu ZF, Qi WQ, Ouyang XZ, Yeung E & Chye ML (2001) A proteinase inhibitor II of Solanum americanum is expressed in phloem Plant Mol Biol 47, 727– 738 31 Dodt J, Otte M, Strube KH & Friedrich T (1996) Thrombin inhibitors of bloodsucking animals Semin Thromb Hemostat 22, 203–208 32 Creighton TE & Darby NJ (1989) Functional evolutionary divergence of proteolytic enzymes and their inhibitors Trends Biochem Sci 14, 319–324 33 Ohta T (1994) On hypervariability at the reactive center of proteolytic enzymes and their inhibitors J Mol Evol 39, 614–619 34 Melville JC & Ryan CA (1972) Chymotrypsin inhibitor I from potatoes Large-scale preparation and characterization of its subunit components J Biol Chem 247, 3445–3453 35 Lee JS, Brown WE, Graham JS, Pearce G, Fox EA, Dreher TW, Ahern KG, Pearson GD & Ryan CA (1986) Molecular characterization and phylogenetic studies of a wound-inducible proteinase inhibitor I gene in Lycopersicon species Proc Natl Acad Sci USA 83, 7277–7281 36 Dannenhoffer JM, Suhr RC & Thompson GA (2001) Phloem-specific expression of the pumpkin fruit trypsin inhibitor Planta 212, 155–162 37 Wingate VP & Ryan CA (1991) A novel fruit-expressed trypsin inhibitor I gene from a wild species of tomato J Biol Chem 266, 5814–5818 38 Wingate VP, Broadway RM & Ryan CA (1989) Isolation and characterization of a novel, developmentally regulated proteinase inhibitor I protein and cDNA from the fruit of a wild species of tomato J Biol Chem 264, 17734–17738 39 Margossian LJ, Federman AD, Giovannoni JJ & Fischer RL (1988) Ethylene-regulated expression of a tomato fruit ripening gene encoding a proteinase inhibitor I with a glutamic residue at the reactive site Proc Natl Acad Sci USA 85, 8012–8016 5718 40 Criqui MC, Plesse B, Durr A, Marbach J, Parmentier Y, Jamet E & Fleck J (1992) Characterization of genes expressed in mesophyll protoplasts of Nicotiana sylvestris before the re-initiation of the DNA replicational activity Mech Dev 38, 121–132 41 Stein PE, Leslie AG, Finch JT, Turnell WG, McLaughlin PJ & Carrell RW (1990) Crystal structure of ovalbumin as a model for the reactive centre of serpins Nature 347, 99–102 42 Bernhard WR & Somerville CR (1989) Coidentity of putative amylase inhibitors from barley and finger millet with phospholipid transfer proteins inferred from amino acid sequence homology Arch Biochem Biophys 269, 695–697 43 Lenarcic B, Ritonja A, Strukelj B, Turk B & Turk V (1997) Equistatin, a new inhibitor of cysteine proteinases from Actinia equina, is structurally related to thyroglobulin type-1 domain J Biol Chem 272, 13899– 13903 44 Strukelj B, Lenarcic B, Gruden K, Pungercar J, Rogelj B, Turk V, Bosch D & Jongsma MA (2000) Equistatin, a protease inhibitor from the sea anemone Actinia equina, is composed of three structural and functional domains Biochem Biophys Res Commun 269, 732–736 45 Yamashita M & Konagaya S (1996) A novel cysteine protease inhibitor of the egg of chum salmon, containing a cysteine-rich thyroglobulin-like motif J Biol Chem 271, 1282–1284 46 Lenarcic B, Krishnan G, Borukhovich R, Ruck B, Turk V & Moczydlowski (2000) Saxiphilin, a saxitoxinbinding protein with two thyroglobulin type domains, is an inhibitor of papain-like cysteine proteinases J Biol Chem 275, 15572–15577 47 Bocock JP, Edgell CJ, Marr HS & Erickson AH (2003) Human proteoglycan testican-1 inhibits the lysosomal cysteine protease cathepsin L Eur J Biochem 270, 4008–4015 48 Bevec T, Stoka V, Pungercic G, Dolenc I & Turk V (1996) Major histocompatibility complex class II-associated p41 invariant chain fragment is a strong inhibitor of lysosomal cathepsin L J Exp Med 183, 1331– 1338 49 Yeh KW, Chen JC, Lin MI, Chen YM & Lin CY (1997) Functional activity of sporamin from sweet potato (Ipomoea batatas Lam.): a tuber storage protein with trypsin inhibitory activity Plant Mol Biol 33, 565–570 50 Lopez F, Vansuyt G, Derancourt J, Fourcroy P & Casse-Delbart F (1994) Identification by 2D-page analysis of salt-stress induced proteins in radish (Raphanus sativus) Cell Mol Biol (Noisy-le-Grand) 40, 85–90 51 Trumper S, Follmann H & Haberlein I (1994) A noveldehydroascorbate reductase from spinach chloroplasts FEBS Journal 272 (2005) 5710–5722 ª 2005 The Horticulture and Food Research Institute J T Christeller 52 53 54 55 56 57 58 59 60 61 62 63 64 homologous to plant trypsin inhibitor FEBS Lett 352, 159–162 Theerasilp S, Hitotsuya H, Nakajo S, Nakaya K, Nakamura Y & Kurihara Y (1989) Complete amino acid sequence and structure characterization of the taste-modifying protein, miraculin J Biol Chem 264, 6655–6659 Saitoh E, Isemura S, Sanada K & Ohnishi K (1992) Characterization of two members (CST4 and CST5) of the cystatin gene family and molecular evolution of cystatin genes Agents Actions Suppl 38, 340–348 Bode W & Huber R (1992) Natural protein proteinase inhibitors and their interaction with proteinases Eur J Biochem 204, 433–451 Laskowski M & Kato I (1980) Protein inhibitors of proteinases Annu Rev Biochem 49, 593–626 Laskowski M & Qasim MA (2000) What can the structures of enzyme–inhibitor complexes tell us about the structures of enzyme–substrate complexes? Biochim Biophys Acta 1477, 324–337 Svendsen IB, Nicolova D, Goshev I & Genov N (1989) Isolation and characterization of a trypsin inhibitor from the seeds of kohlrabi (Brassica napus var rapifera) belonging to the napin family of storage proteins Carlsberg Res Commun 54, 231–239 Strobl S, Maskos K, Wiegand G, Huber R, GomisRuth FX & Glockshuber R (1998) A novel strategy for inhibition of alpha-amylases: yellow meal worm alphaamylase in complex with the Ragi bifunctional inhibi˚ tor at 2.5 A resolution Structure 6, 911–921 Oda Y, Matsunaga T, Fukuyama K, Miyazaki T & Morimoto T (1997) Tertiary and quaternary structures of 0.19 alpha-amylase inhibitor from wheat kernel ˚ determined by X-ray analysis at 2.06 A resolution Biochemistry 36, 13503–13511 Wei A, Rubin H, Cooperman BS & Christianson DW (1994) Crystal structure of an uncleaved serpin reveals the conformation of an inhibitory reactive loop Nat Struct Biol 1, 251–258 Komiyama T, Ray CA, Pickup DJ, Howard AD, Thornberry NA, Peterson EP & Salvesen G (1994) Inhibition of interleukin-1 beta converting enzyme by the cowpox virus serpin CrmA An example of crossclass inhibition J Biol Chem 269, 19331–19337 Mathialagan N & Hansen TR (1996) Pepsin-inhibitory activity of the uterine serpins Proc Natl Acad Sci USA 93, 13653–13658 Krizaj I, Drobnic-Kosorok M, Brzin J, Jerala R & Turk V (1993) The primary structure of inhibitor of cysteine proteinases from potato FEBS Lett 333, 15– 20 Strukelj B, Pungercar J, Mesko P, Barlic-Maganja D, Gubensek F, Kregar I & Turk V (1992) Characterization of aspartic proteinase inhibitors from potato at Proteinase inhibitor variability 65 66 67 68 69 70 71 72 73 74 75 76 the gene, cDNA and protein levels Biol Chem HoppeSeyler 373, 477–482 Hatano K, Kojima M, Tanokura M & Takahashi K (1996) Solution structure of bromelain inhibitor IV from pineapple stem: structural similarity with Bowman–Birk trypsin ⁄ chymotrypsin inhibitor from soybean Biochemistry 35, 5379–5384 Lenarcic B & Turk V (1999) Thyroglobulin type-1 domains in equistatin inhibit both papain-like cysteine proteinases and cathepsin D J Biol Chem 274, 563– 566 Potempa J, Korzus E & Travis J (1994) The serpin superfamily of proteinase inhibitors: structure, function and regulation J Biol Chem 269, 15957–15960 Gettins PG (2002) Serpin structure, mechanism, and function Chem Rev 102, 4751–4804 Simonovic M, Gettins PGW & Volz K (2000) Crystal structure of viral serpin crmA provides insights into its mechanism of cysteine proteinase inhibition Protein Sci 29, 1423–1427 Irving JA, Pike RN, Dai W, Bromme D, Worrall DM, Silverman GA, Coetzer TH, Dennison C, Bottomley SP & Whisstock JC (2002) Evidence that serpin architecture intrinsically supports papain-like cysteine protease inhibition: engineering alpha (1)-antitrypsin to inhibit cathepsin proteases Biochemistry 41, 4998– 5004 Schick C, Pemberton PA, Shi GP, Kamachi Y, Cataltepe S, Bartuski AJ, Gornstein ER, Bromme D, Chapman HA & Silverman GA (1998) Cross-class inhibition of the cysteine proteinases cathepsins K, L, and S by the serpin squamous cell carcinoma antigen 1: a kinetic analysis Biochemistry 37, 5258–5266 Nawata S, Nakamura K, Tanaka T, Numa F, Suminami Y, Tsunaga N, Kakegawa H, Katunuma N & Kato H (1997) Electrophoretic analysis of the ‘crossclass’ interaction between novel inhibitory serpin, squamous cell carcinoma antigen-1 and cysteine proteinases Electrophoresis 18, 784–789 Al-Khunaizi M, Luke CJ, Askew YS, Pak SC, Askew DJ, Cataltepe S, Miller D, Mills DR, Tsu C, Bromme D, et al (2002) The serpin SQN-5 is a dual mechanistic-class inhibitor of serine and cysteine proteinases Biochemistry 41, 3189–3199 Mares M, Meloun B, Pavlik M, Kostka V & Baudys M (1989) Primary structure of cathepsin D inhibitor from potatoes and its structure relationship to soybean trypsin inhibitor family FEBS Lett 251, 94–98 Brzin J, Popovic T, Drobnic-Kosorok M, Kotnik M & Turk V (1988) Inhibitors of cysteine proteinases from potato Biol Chem Hoppe-Seyler 369, 233–238 Farley PC, Christeller JT, Sullivan ME, Sullivan PA & Laing WA (2002) Analysis of the interaction between the aspartic peptidase inhibitor SQAPI and aspartic FEBS Journal 272 (2005) 5710–5722 ª 2005 The Horticulture and Food Research Institute 5719 Proteinase inhibitor variability 77 78 79 80 81 82 83 84 85 86 87 88 J T Christeller peptidases using surface plasmon resonance J Mol Recog 15, 135–144 Bode W, Engh R, Musil D, Thiele U, Huber R, Kar˚ shikov A, Brzin J, Kos J & Turk V (1988) The 2.0 A X-ray crystal structure of chicken egg white cystatin and its possible mode of interaction with cysteine proteinases EMBO J 7, 2593–2599 Guncar G, Pungercic G, Klemencic I, Turk V & Turk D (1999) Crystal structure of MHC class II-associated p41, Ii fragment bound to cathepsin L reveals the structural basis for differentiation between cathepsins L and S EMBO J 18, 793–803 Li M, Phylip LH, Lees WE, Winther JR, Dunn BM, Wlodawer A, Kay J & Gustchina A (2000) The aspartic proteinase from Saccharomyces cerevisiae folds its own inhibitor into a helix Nat Struct Biol 7, 113–117 Ng KK, Petersen JF, Cherney MM, Garen C, Zalatoris JJ, Rao-Naik C, Dunn BM, Martzen MR, Peanasky RJ & James MN (2000) Structural basis for the inhibition of porcine pepsin by Ascaris pepsin inhibitor-3 Nat Struct Biol 7, 653–657 Nakada M, Yamada A, Takino T, Miyamori H, Takahashi T, Yamashita J & Sato H (2001) Suppression of membrane-type matrix metalloproteinase (MMP)-mediated MMP-2 activation and tumor invasion by testican and its splicing variant gene product, N-Tes Cancer Res 61, 8896–8902 Trexler M, Banyai L & Patthy L (2001) A human protein containing multiple types of protease-inhibitory modules Proc Natl Acad Sci USA 98, 3705–3709 Nagy A, Trexler M & Patthy L (2003) Expression, purification and characterization of the second Kunitztype protease inhibitor domain of the human WFIKKN protein Eur J Biochem 270, 2101–2107 Fryxell KJ (1996) The coevolution of gene family trees Trends Genet 12, 364–369 Habu Y, Peyachoknagul S, Sakata Y & Fukusawa K (1997) Evolution of a multigene family that encodes the Kunitz chymotrypsin inhibitor in winged bean: a possible intermediate in the generation of a new gene with a distinct pattern of expression Mol Gen Genet 254, 73–80 Gojobori T & Ikeo K (1994) Molecular evolution of serine protease and its inhibitor with special reference to domain evolution Phil Trans R Soc Lond Series B Biol Sci 344, 411–415 Antcheva N, Pintar A, Patthy A, Simoncsits A, Barta E, Tchorbanov B & Pongor S (2001) Proteins of circularly permuted sequence present within the same organism: the major serine proteinase inhibitor from Capsicum annuum seeds Protein Sci 10, 2280–2290 Keil M, Sanchez-Serrano J, Schell J & Willmitzer L (1986) Primary structure of a proteinase inhibitor II gene from potato (Solanum tuberosum) Nucleic Acids Res 14, 5641–5650 5720 89 Taylor BH, Young RJ & Scheuring CF (1993) Induction of a proteinase II-class gene by auxin in tomato roots J Mol Biol 23, 1005–1014 90 Miller EA, Lee MC, Atkinson AH & Anderson MA (2000) Identification of a novel four-domain member of the proteinase inhibitor II family from the stigmas of Nicotiana alata Plant Mol Biol 42, 329–333 91 Atkinson AH, Heath RL, Simpson RJ, Clarke AE & Anderson MA (1993) Proteinase inhibitors in Nicotiana alata stigmas are derived from a precursor protein which is processed into five homologous inhibitors Plant Cell 5, 203–213 92 Choi D, Park JA, Seo YS, Chun YJ & Kim WT (2000) Structure and stress-related expression of two cDNAs encoding proteinase inhibitor II of Nicotiana glutinosa L Biochim Biophys Acta 1492, 211–215 93 Lee MC, Scanlon MJ, Craik DJ & Anderson MA (1999) A novel two-chain proteinase inhibitor generated by circularization of a multidomain precursor protein Nat Struct Biol 6, 526–530 94 Scanlon MJ, Lee MC, Anderson MA & Craik DJ (1999) Structure of a putative ancestral protein encoded by a single sequence repeat from a multidomain proteinase inhibitor gene from Nicotiana alata Struct Fold Design 7, 793–802 95 Plunkett G, Senear DF, Zuroske G & Ryan CA (1982) Proteinase inhibitors I and II from leaves of wounded tomato plants: purification and properties Arch Biochem Biophys 213, 463–472 96 Pearce G, Sy L, Russell C, Ryan CA & Hass GM (1982) Isolation and characterization from potato tubers of two polypeptide inhibitors of serine proteinases Arch Biochem Biophys 213, 456–462 97 Antcheva N, Patthy A, Athanasiadis A, Tchorbanov B, Zakhariev S & Pongor S (1996) Primary structure and specificity of a serine proteinase inhibitor from paprika (Capsicum annuum) seeds Biochim Biophys Acta 1298, 95–101 98 Lindqvist Y & Schneider G (1997) Circular permutations of natural protein sequences: structural evidence Curr Opin Struct Biol 7, 422–427 99 Ponting CP & Russell RB (1995) Swaposins: circular permutations within genes encoding saposin homologues Trends Biochem Sci 20, 179–180 100 Walsh TA & Strickland JA (1993) Proteolysis of the 85-kilodalton crystalline cysteine proteinase inhibitor from potato releases functional cystatin domains Plant Physiol 103, 1227–1234 101 Waldron C, Wegrich LM, Merlo PA & Walsh TA (1993) Characterization of a genomic sequence coding for potato multicystatin, an eight-domain cysteine proteinase inhibitor Plant Mol Biol 23, 801–812 102 Kouzuma Y, Inanaga H, Doi-Kawano K, Yamasaki N & Kimura M (2000) Molecular cloning and functional expression of cDNA encoding the cysteine proteinase FEBS Journal 272 (2005) 5710–5722 ª 2005 The Horticulture and Food Research Institute J T Christeller 103 104 105 106 107 108 109 110 111 112 113 114 inhibitor with three cystatin domains from sunflower seeds J Biochem (Tokyo) 128, 161–166 Salvesen G, Parkes C, Abrahamson M, Grubb A & Barrett AJ (1986) Human low-Mr kininogen contains three copies of a cystatin sequence that are divergent in structure and in inhibitory activity for cysteine proteinases Biochem J 234, 429–434 Jiang H, Wang Y & Kanost MR (1994) Mutually exclusive exon use and reactive center diversity in insect serpins J Biol Chem 269, 55–58 Jiang H, Wang Y, Huang Y, Mulnix AB, Kadel J, Cole K & Kanost MR (1996) Organization of serpin gene-1 from Manduca sexta Evolution of a family of alternate exons encoding the reactive site loop J Biol Chem 271, 28017–28023 Medford RM, Nguyen HT, Destree AT, Summers E & Nadal-Ginard B (1984) A novel mechanism of alternative RNA splicing for the developmentally regulated generation of troponin T isoforms from a single gene Cell 38, 409–421 Sasaki T (1991) Patchwork-structure serpins from silkworm (Bombyx mori) larval hemolymph Eur J Biochem 202, 255–261 Brandt KS, Silver GM, Becher AM, Gaines PJ, Maddux JD, Jarvis EE & Wisnewski N (2004) Isolation, characterization, and recombinant expression of multiple serpins from the cat flea, Ctenocephalides felis Arch Insect Biochem Physiol 55, 200–214 Kruger O, Ladewig J, Koster K & Ragg H (2002) Widespread occurrence of serpin genes with multiple reactive centre-containing exon cassettes in insects and nematodes Gene 293, 97–105 Takano J, Watanabe M, Hitomi K & Maki M (2000) Four types of calpastatin isoforms with distinct aminoterminal sequences are specified by alternative first exons and differentially expressed in mouse tissues J Biochem (Tokyo) 128, 83–92 Conticello SG, Gilad Y, Avidan N, Ben-Asher E, Levy Z & Fainzilber M (2001) Mechanisms for evolving hypervariability: the case of conopeptides Mol Biol Evol 18, 120–131 Laskowski M Jr, Kato I, Kohr WJ, Park SJ, Tashiro M & Whatley HE (1987) Positive Darwinian selection in evolution of protein inhibitors of serine proteinases Cold Spring Harbor Symp Quant Biol 52, 545–553 Laskowski M Jr, Kato I, Ardelt W, Cook J, Denton A, Empie MW, Kohr WJ, Park SJ, Parks K, Schatzley BL, et al (1987) Ovomucoid third domains from 100 avian species: isolation, sequences, and hypervariability of enzyme-inhibitor contact residues Biochemistry 26, 202–221 Carrel RW, Pemberton PA & Boswell DR (1987) The serpins: evolution and adaptation in a family of protease inhibitors Cold Spring Harbor Symp Quant Biol 52, 527–535 Proteinase inhibitor variability 115 Goodwin RL, Baumann H & Berger FG (1996) Patterns of divergence during evolution of a1-proteinase inhibitors in mammals Mol Biol Evol 13, 346–358 116 Borriello F & Krauter KS (1991) Multiple murine alpha 1-protease inhibitor genes show unusual evolutionary divergence Proc Natl Acad Sci USA 88, 9417–9421 117 Barbour KW, Goodwin RL, Guillonneau F, Wang Y, Baumann H & Berger FG (2002) Functional diversification during evolution of the murine alpha (1)-proteinase inhibitor family: role of the hypervariable reactive center loop Mol Biol Evol 19, 718–727 118 Xie S, Green J, Bixby JB, Szafranska B, DeMartini JC, Hecht S & Roberts RM (1997) The diversity and evolutionary relationships of the pregnancy-associated glycoproteins, an aspartic proteinase subfamily consisting of many trophoblast-expressed genes Proc Natl Acad Sci USA 94, 12809–12816 119 Claus MJ & Mitchell-Olds T (2003) Population genetics of tandem trypsin inhibitor genes in Arabidopsis species with contrasting ecology and life history Mol Ecol 12, 1287–1299 120 Meyers BC, Shen KA, Rohani P, Gaut BS & Michelmore RW (1998) Receptor-like genes in the major resistance locus of lettuce are subject to divergent selection Plant Cell 10, 1833–1846 121 Rasmussen M, Eden A & Bjorck L (2000) SclA, a novel collagen-like surface protein of Streptococcus pyogenes Infect Immun 68, 6370–6377 122 Castagnaro A, Marana C, Carbonero P & GarciaOlmedo F (1992) Extreme divergence of a novel wheat thionin generated by a mutational burst specifically affecting the mature protein domain of the precursor J Mol Biol 224, 1003–1009 123 Mebs D (2001) Toxicity in animals Trends in evolution? Toxicon 39, 87–96 124 Kimura M (1983) The Neutral Theory of Evolution Cambridge University Press, Cambridge 125 Allen RL, Bittner-Eddy PD, Grenville-Briggs LJ, Meitz JC, Rehmany AP, Rose LE & Beynon JL (2004) Host– parasite coevolutionary conflict between Arabidopsis and downy mildew Science 306, 1957–1960 126 Hammond-Kosack KE & Jones JD (1997) Plant disease resistance genes Annu Rev Plant Physiol Plant Mol Biol 48, 575–607 127 Malcuit I, de Jong W, Baulcombe DC, Shields DC & Kavanagh TA (2000) Acquisition of multiple virulence ⁄ avirulence determinants by potato virus X (PVX) has occurred through convergent evolution rather than through recombination Virus Genes 20, 165–172 128 Yang Y & Gabriel DW (1995) Intragenic recombination of a single plant pathogen gene provides a mechanism for the evolution of new host specificities J Bacteriol 177, 4963–4968 FEBS Journal 272 (2005) 5710–5722 ª 2005 The Horticulture and Food Research Institute 5721 Proteinase inhibitor variability J T Christeller 129 Holt DC, Fischer K, Allen GE, Wilson D, Wilson P, Slade R, Currie BJ, Walton SF & Kemp DJ (2003) Mechanisms for a novel immune evasion strategy in the scabies mite Sarcoptes scabiei: a multigene family of inactivated serine proteases J Invest Dermatol 121, 1419–1424 130 Holt DC, Fischer K, Pizzutto SJ, Currie BJ, Walton SF & Kemp DJ (2003) A multigene family of inactivated cysteine proteases in Sarcoptes scabiei J Invest Dermatol 123, 240–241 131 Bown DP, Wilkinson HS & Gatehouse JA (1997) Differentially regulated inhibitor-sensitive and insensitive protease genes from the phytophagous insect pest, Helicoverpa armigera, are members of complex multigene families Insect Biochem Mol Biol 27, 625–638 132 Mazumdar-Leighton S, Babu CR & Bennett J (2000) Identification of novel serine proteinase gene transcripts in the midguts of two tropical insect pests, Scirpophaga incertulas (Wk.) and Helicoverpa armigera (Hb.) Insect Biochem Mol Biol 30, 57–68 133 Jongsma MA, Bakker PL, Peters J, Bosch D & Stiekema WJ (1995) Adaptation of Spodoptera exigua larvae to plant proteinase inhibitors by induction of gut proteinase activity insensitive to inhibition Proc Natl Acad Sci USA 92, 8041–8045 134 Gatehouse LN, Shannon AL, Burgess EP & Christeller JT (1997) Characterization of major midgut proteinase cDNAs from Helicoverpa armigera larvae and changes in gene expression in response to four proteinase inhibitors in the diet Insect Biochem Mol Biol 27, 929–944 135 Markwick NP, Laing WA, Christeller JT, McHenry JZ & Newton MR (1998) Overproduction of digestive enzymes compensates for inhibitory effects of protease and a-amylase inhibitors fed to three species of leafrollers (Lepidoptera: Tortricidae) J Econ Entomol 91, 1265–1276 5722 136 Gaillot O, Pellegrini E, Bregenholt S, Nair S & Berche P (2000) The ClpP serine protease is essential for the intracellular parasitism and virulence of Listeria monocytogenes Mol Microbiol 35, 1286–1294 137 Williams J, Clarkson JM, Mills PR & Cooper RM (2003) Saprotrophic and mycoparasitic components of aggressiveness of Trichoderma harzianum groups toward the commercial mushroom Agaricus bisporus Appl Environ Microbiol 69, 4192–4199 138 Davis RE, Jomantiene R, Zhao Y & Dally EL (2003) Folate biosynthesis pseudogenes, PsifolP and PsifolK, and an O-sialoglycoprotein endopeptidase gene homolog in the phytoplasma genome DNA Cell Biol 22, 697–706 139 Andreotti R, Gomes A, Malavazi-Piza KC, Sasaki SD, Sampaio CA & Tanaka AS (2002) BmTI antigens induce a bovine protective immune response against Boophilus microplus tick Int Immunopharmacol 2, 557– 563 140 Soeiro Mde N, Paiva MM, Waghabi MC, Meirelles Mde N, Lorent K, Henriques-Pons A, Coutinho CM, Van Leuven F & Araujo-Jorge TC (2000) Trypanosoma cruzi: acute infection affects expression of alpha-2macroglobulin and A2MR ⁄ LRP receptor differently in C3H and C57BL ⁄ mice Exp Parasitol 96, 97–107 141 Hotez PJ, Trang NL, McKerrow JH & Cerami A (1985) Isolation and characterization of a proteolytic enzyme from the adult hookworm Ancylostoma caninum J Biol Chem 260, 7343–7348 142 Lively CM (1987) Evidence from a New Zealand snail for the maintenance of sex by parasitism Nature 328, 519–521 143 Lively CM & Dybdahl MF (2000) Parasite adaptation to locally common host genotypes Nature 405, 679– 681 FEBS Journal 272 (2005) 5710–5722 ª 2005 The Horticulture and Food Research Institute ... range of evolutionary mechanisms as proteinase inhibitors in addition to hypervariability is not yet known, although as avirulence genes are being identified, some information on their evolution is... description completes the specific evolutionary mechanisms currently known to occur in proteinase inhibitors, there are two additional related areas that are relevant to proteinase inhibitor evolution... occurring in proteinase inactivation Proteinase inhibitors and parasitism Our discussion so far has described the various evolutionary mechanisms that have been observed in proteinase inhibitors

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