Structural basis of inhibition revealed by a 1:2 complex of the two-headed tomato inhibitor-II and subtilisin Carlsberg

Multidomain proteinase inhibitors play critical roles in the defense of plants against predation by a wide range of pests. Despite a wealth of structural information on proteinase-single domain inhibitor interactions, the structural basis of inhibition by multidomain proteinase inhibitors remains poorly understood. Here we report the 2.5-A resolution crystal structure of the two-headed tomato inhibitor-II (TI-II) in complex with two molecules of subtilisin Carlsberg; it reveals how a multidomain inhibitor from the Potato II family of proteinase inhibitors can bind to and simultaneously inhibit two enzyme molecules within a single ternary complex. The N terminus of TI-II initiates the folding of Domain I (Lys-1 to Cys-15 and Pro-84 to Met-123) and then completes Domain II (Ile-26 to Pro-74) before coming back to complete the rest of Domain I (Pro-84 to Met-123). The two domains of TI-II adopt a similar fold and are arranged in an extended configuration that presents two reactive site loops at the opposite ends of the inhibitor molecule. Each subtilisin molecule interacts with a reactive site loop of TI-II through the standard, canonical binding mode. Remarkably, a significant distortion of the active site of subtilisin is induced by the presence of phenylalanine in the P1 position of reactive site loop II of TI-II. The structure of the TI-II.(subtilisin)2 complex provides a molecular framework for understanding how multiple inhibitory domains in a single Potato II type proteinase inhibitor molecule from the Potato II family act to inhibit proteolytic enzymes.     

Crystal structure of bovine trypsin and wheat germ trypsin inhibitor (I-2b) complex (2:1) at 2.3 a resolution

The Bowman-Birk trypsin inhibitor (BBI) from wheat germ (I-2b) consists of 123 amino acid residues with two inhibitory loops. The crystal structure of a bovine trypsin-wheat germ trypsin inhibitor (I-2b) complex (2:1) has been determined at 2.3 A resolution to a final R-factor of 0.177. A distance of 37.2 A between the contiguous contact loops allows them to bind and inhibit two trypsin molecules simultaneously and independently. Each domain shares the same overall fold with 8 kDa BBIs. The five disulfide bridges in each domain are a subset of seven disulfide bridges in the 8 kDa BBIs. I-2b consists of ten beta-strands and the loops connecting these strands but it lacks alpha-helices. The conformations of the contiguous contact loops of I-2b are in a heart-like structure. The reactive sites in both domains, Arg 17 and Lys 76, are located on the loop connecting anti-parallel beta-strands, beta 1/beta 2 and beta 6/beta 7. Strands beta 1 and beta 6 are in direct contact with trypsin molecules and form stable triple stranded beta-sheet structures via hydrogen bonds.     

Insight into the structural basis of the dual inhibitory mode of Lima bean (Phaseolus lunatus) serine protease inhibitor

Bovine pancreatic trypsin was crystallized, in-complex with Lima bean trypsin inhibitor (LBTI) (Phaseolus lunatus L.), in the form of a ternary complex. LBTI is a Bowman–Birk-type bifunctional serine protease inhibitor, which has two independent inhibitory loops. Both of the loops can inhibit trypsin, however, only the hydrophobic loop is specific for inhibiting chymotrypsin. The structure of trypsin incomplex with the LBTI has been solved and refined at 2.25 Å resolution, in the space group P4_1, with R_work/R_free values of 18.1/23.3. The two binding sites of LBTI differ in only two amino acids. Lysine and leucine are the key residues of the two different binding loops positioned at the P1, and involved in binding the S1 binding site of trypsin. The asymmetric unit cell contains two molecules of trypsin and one molecule of LBTI. The key interactions include hydrogen bonds between LBTI and active site residues of trypsin. The 3D structure of the enzyme–inhibitor complex provided details insight into the trypsin inhibition by LBTI. To the best of our knowledge, this is the first report on the structure of trypsin incomplex with LBTI.     

A novel two-chain proteinase inhibitor generated by circularization of a multidomain precursor protein.

Female reproductive tissues of the ornamental tobacco amass high levels of serine proteinase inhibitors (PIs) for protection against pests and pathogens. These PIs are produced from a precursor protein composed of six repeats each with a protease reactive site. Here we show that proteolytic processing of the precursor generates five single-chain PIs and a remarkable two-chain inhibitor formed by disulfide-bond linkage of N- and C-terminal peptide fragments. Surprisingly, PI precursors adopt this circular structure regardless of the number of inhibitor domains, suggesting this bracelet-like conformation is characteristic of the widespread potato inhibitor II (Pot II) protein family.     

Crystal structure of a 16 kDa double-headed Bowman-Birk trypsin inhibitor from barley seeds at 1.9 A resolution.

The Bowman-Birk trypsin inhibitor from barley seeds (BBBI) consists of 125 amino acid residues with two inhibitory loops. Its crystal structure in the free state has been determined by the multiwavelength anomalous diffraction (MAD) method and has been refined to a crystallographic R-value of 19.1 % for 8.0-1.9 A data. This is the first report on the structure of a 16 kDa double-headed Bowman-Birk inhibitor (BBI) from monocotyledonous plants and provides the highest resolution picture of a BBI to date. The BBBI structure consists of 11 beta-strands and the loops connecting these beta-strands but it lacks alpha-helices. BBBI folds into two compact domains of similar tertiary structure. Each domain shares the same overall fold with 8 kDa dicotyledonous BBIs. The five disulfide bridges in each domain are a subset of the seven disulfide bridges in 8 kDa dicotyledonous BBIs. Two buried water molecules form hydrogen bonds to backbone atoms in the core of each domain. One interesting feature of this two-domain inhibitor structure is that the two P1 residues (Arg17 and Arg76) are approximately 40 A apart, allowing the two reactive-site loops to bind to and to inhibit two trypsin molecules simultaneously and independently. The conformations of the reactive-site loops of BBBI are highly similar to those of other substrate-like inhibitors. This structure provides the framework for modeling of the 1:2 complex between BBBI and trypsin.     

The amino acid sequence of the double-headed protein proteinase inhibitor from dog submandibular glands, I. Structural homology to the pancreatic secretory trypsin inhibitors (author's transl)]

The primary structure of the broad specificity proteinase inhibitor from dog submandibular glands was elucidated. The inhibitor consists of a single polypeptide chain of 117 amino acids which is folded into two domains (heads) connected by a peptide of three amino acid residues. Both domains I and II show a clear structural homology to each other as well as to the single-headed pancreatic secretory trypsin inhibitors (Kazal type). The trypsin reactive site (-Cys-Pro-Arg-Leu-His-Glx-Pro-Ile-Cys-) is located in domain I and the chymotrypsin reactive center (-Cys-Thr-Met-Asp-Tyr-Asx-Arg-Pro-Leu-Tyr-Cys-) in domain II, cf. the Figure. The inhibitor is thus double-headed with two independent reactive sites. Whereas head I is responsible for the inhibition of trypsin and plasmin, head II is responsible for the inhibition of chymotrypsin, subtilisin, elastase and probably also Aspergillus oryzae protease and pronase. Remarkably, the structural homology exists also to the single-headed acrosin-trypsin inhibitors from seminal plasma[12] and the Japanese quail inhibitor composed of three domains[13].     

Characterization of potato proteinase inhibitor II reactive site mutants.

Potato proteinase inhibitor II (PI-2) is composed of two sequence repeats. It contains two reactive site domains. We developed an improved protocol for the production of PI-2 using the yeast Pichia pastoris as the expression host. We then assessed the role of its two reactive sites in the inhibition of trypsin and chymotrypsin by mutating each of the two reactive sites in various ways. From these studies it appears that the second reactive site strongly inhibits both trypsin (Ki = 0.4 nM) and chymotrypsin (Ki = 0.9 nM), and is quite robust towards mutations at positions P2 or P1'. In contrast, the first reactive site inhibits only chymotrypsin (Ki = 2 nM), and this activity is very sensitive to mutations. Remarkably, replacing the reactive site amino acids of domain I with those of domain II did not result in inhibitory activities similar to domain II. The fitness for protein engineering of each domain is discussed.     

Comparison of the Predicted Structures of Loops in the ras–SOS Protein Bound to a Single ras-p21 Protein with the Crystallographically Determined Structures in SOS Bound to Two ras-p21 Proteins

We have previously computed the structures of three loops, residues 591–596, 654–675 and 742–751, in the ras-p21 protein-binding domain (residues 568–1044) of the guanine nucleotide-exchange-promoting SOS protein that were crystallographically undefined when one molecule of ras-p21 (unbound to nucleotide) binds to SOS. Based on our computational results, we synthesized three peptides corresponding to sequences of each of these three loops and found that all three peptides strongly inhibit ras-p21 signaling. More recently, a new crystal structure of SOS has been determined in which this protein binds to two molecules of ras-p21, one unbound to GTP and one bound to GTP. In this structure, the 654–675 loop and residues 742–743 and 750–751 are now crystallographically defined. We have superimposed our energy-minimized structure of the ras-binding domain of SOS bound to one molecule of ras-p21 on the X-ray structure for SOS bound to two molecules of ras-p21. We find that, while the two structures are superimposable, there are large deviations of the residues 673 and 676 and 741 and 752, flanking the two loop segments. This suggests that the binding of the extra ras-p21 molecule, which is far from each of the three loops, induces conformational changes in these domains and further supports their role in signal transduction. In spite of these differences, we have superimposed our computed structures for the loop residues on those from the more recent X-ray structure. Our structure for the 654–675 segment is an anti-parallel beta-sheet with a reverse turn at residues 663–665; in the X-ray structure residues 655–662 adopt an alpha-helical conformation; on the other hand, our computed structure for residues 663–675 superimpose on the X-ray structure for these residues. We further find that our computed structures for residues 742–743 and 750–751 are superimposable on the X-ray structure for these residues.     

All four internally repetitive domains of pig calpastatin possess inhibitory activities against calpains I and II

Complementary DNA portions coding for each domain (domain L and internally repetitive domains, domains 1-4, each composed of approximately 140 amino acid residues) of pig calpastatin were subcloned into E. coli plasmids to express the respective portions of the proteinase inhibitor gene in bacteria. Cell extracts of E. coli harboring recombinant plasmids were assayed for calpain inhibition. All four internally repetitive domains showed inhibitory activities, essentially similar to one another, against calpains I and II. No inhibition was observed in the case of the N-terminal non-homologous domain (domain L). These results support our previous conclusion that the repetitive region is a functional unit of the proteinase inhibitor.     

Proteinase binding and inhibition by the monomeric alpha-macroglobulin rat alpha 1-inhibitor-3

The inhibitory capacity of the alpha-macroglobulins resides in their ability to entrap proteinase molecules and thereby hinder the access of high molecular weight substrates to the proteinase active site. This ability is thought to require at least two alpha-macroglobulin subunits, yet the monomeric alpha-macroglobulin rat alpha 1-inhibitor-3 (alpha 1I3) also inhibits proteinases. We have compared the inhibitory activity of alpha 1I3 with the tetrameric human homolog alpha 2-macroglobulin (alpha 2M), the best known alpha-macroglobulin, in order to determine whether these inhibitors share a common mechanism. alpha 1I3, like human alpha 2M, prevented a wide variety of proteinases from hydrolyzing a high molecular weight substrate but allowed hydrolysis of small substrates. In contrast to human alpha 2M, however, the binding and inhibition of proteinases was dependent on the ability of alpha 1I3 to form covalent cross-links to proteinase lysine residues. Low concentrations of proteinase caused a small amount of dimerization of alpha 1I3, but no difference in inhibition or receptor binding was detected between purified dimers or monomers. Kininogen domains of 22 and 64 kDa were allowed to react with alpha 1I3- or alpha 2M-bound papain to probe the accessibility of the active site of this proteinase. alpha 2M-bound papain was completely protected from reaction with these domains, whereas alpha 1I3-bound papain reacted with them but with affinities several times weaker than uncomplexed papain. Cathepsin G and papain antisera reacted very poorly with the enzymes when they were bound by alpha 1I3, but the protection provided by human alpha 2M was slightly better than the protection offered by the monomeric rat alpha 1I3. Our data indicate that the inhibitory unit of alpha 1I3 is a monomer and that this protein, like the multimeric alpha-macroglobulins, inhibits proteinases by steric hindrance. However, binding of proteinases by alpha 1I3 is dependent on covalent crosslinks, and bound proteinases are more accessible, and therefore less well inhibited, than when bound by the tetrameric homolog alpha 2M. Oligomerization of alpha-macroglobulin subunits during the evolution of this protein family has seemingly resulted in a more efficient inhibitor, and we speculate that alpha 1I3 is analogous to an evolutionary precursor of the tetrameric members of the family exemplified by human alpha 2M.     

The relationship between the flexibility of proteins and their conformational states on forming protein-protein complexes with an application to protein-protein docking

We investigate the extent to which the conformational fluctuations of proteins in solution reflect the conformational changes that they undergo when they form binary protein-protein complexes. To do this, we study a set of 41 proteins that form such complexes and whose three-dimensional structures are known, both bound in the complex and unbound. We carry out molecular dynamics simulations of each protein, starting from the unbound structure, and analyze the resulting conformational fluctuations in trajectories of 5 ns in length, comparing with the structure in the complex. It is found that fluctuations take some parts of the molecules into regions of conformational space close to the bound state (or give information about it), but at no point in the simulation does each protein as whole sample the complete bound state. Subsequent use of conformations from a clustered MD ensemble in rigid-body docking is nevertheless partially successful when compared to docking the unbound conformations, as long as the unbound conformations are themselves included with the MD conformations and the whole globally rescored. For one key example where sub-domain motion is present, a ribonuclease inhibitor, principal components analysis of the MD was applied and was also able to produce conformations for docking that gave enhanced results compared to the unbound. The most significant finding is that core interface residues show a tendency to be less mobile (by size of fluctuation or entropy) than the rest of the surface even when the other binding partner is absent, and conversely the peripheral interface residues are more mobile. This surprising result, consistent across up to 40 of the 41 proteins, suggests different roles for these regions in protein recognition and binding, and suggests ways that docking algorithms could be improved by treating these regions differently in the docking process.     

Mechanism of domain closure of Sec7 domains and role in BFA sensitivity

Activation of small G proteins of the Arf family is initiated by guanine nucleotide exchange factors whose catalytic Sec7 domain stimulates the dissociation of the tightly bound GDP nucleotide. The exchange reaction involves distinct sequential steps that can be trapped by the noncompetitive inhibitor brefeldin A, by mutation of an invariant catalytic glutamate, or by removal of guanine nucleotides. Arf-GDP retains most characteristics of its GDP-bound form at the initial low-affinity Arf-GDP-Sec7 step. It then undergoes large conformational changes toward its GTP-bound form at the next step, and eventually dissociates GDP to form a nucleotide-free high-affinity Arf-Sec7 complex at the last step. Thus, Arf proteins evolve through different conformations that must be accommodated by Sec7 domains in the course of the reaction. Here the contribution of the flexibility of Sec7 domains to the exchange reaction was investigated with the crystal structure of the unbound Sec7 domain of yeast Gea2. Comparison with Gea2 in complex with nucleotide-free Arf1 Delta 17 [Goldberg, J. (1998) Cell 95, 237-248] reveals that Arf induces closure of the two subdomains that form the sides of its active site. Several residues that determine sensitivity to brefeldin A are involved in interdomain and local movements, pointing to the importance of the flexibility of Sec7 domains for the inhibition mechanism. Altogether, this suggests a model for the initial steps of the exchange reaction where Arf docks onto the C-terminal domain of the Sec7 domain before closure of the N-terminal domain positions the catalytic glutamate to complete the reaction.     

Crystal structures of transhydrogenase domain I with and without bound NADH

Transhydrogenase (TH) is a dimeric integral membrane enzyme in mitochondria and prokaryotes that couples proton translocation across a membrane with hydride transfer between NAD(H) and NADP(H) in soluble domains. Crystal structures of the NAD(H) binding alpha1 subunit (domain I) of Rhodospirillum rubrum TH have been determined at 1.8 A resolution in the absence of dinucleotide and at 1.9 A resolution with NADH bound. Each structure contains two domain I dimers in the asymmetric unit (AB and CD); the dimers are intimately associated and related by noncrystallographic 2-fold axes. NADH binds to subunits A and D, consistent with the half-of-the-sites reactivity of the enzyme. The conformation of NADH in subunits A and D is very similar; the nicotinamide is in the anti conformation, the A-face is exposed to solvent, and both N7 and O7 participate in hydrogen bonds. Comparison of subunits A and D to six independent copies of the subunit without bound NADH reveals multiple conformations for residues and loops surrounding the NADH site, indicating flexibility for binding and release of the substrate (product). The NADH-bound structure is also compared to the structures of R. rubrum domain I with NAD bound (PDB code 1F8G) and with NAD bound in complex with domain III of TH (PDB code 1HZZ). The NADH- vs NAD-bound domain I structures reveal conformational differences in conserved residues in the NAD(H) binding site and in dinucleotide conformation that are correlated with the net charge, i.e., oxidation state, of the nicotinamides. The comparisons illustrate how nicotinamide oxidation state can affect the domain I conformation, which is relevant to the hydride transfer step of the overall reaction.     

A novel double-headed proteinaceous inhibitor for metalloproteinase and serine proteinase

A novel proteinaceous inhibitor for the metalloproteinase of Streptomyces caespitosus has been isolated from the culture supernatant of Streptomyces sp. I-355. It was named ScNPI (Streptomyces caespitosus neutral proteinase inhibitor). ScNPI exhibited strong inhibitory activity toward ScNP with a K(i) value of 1.6 nm. In addition, ScNPI was capable of inhibiting subtilisin BPN' (K(i) = 1.4 nm) (EC ). The scnpi gene consists of two regions, a signal peptide (28 amino acid residues) and a mature region (113 amino acid residues, M(r) = 11,857). The deduced amino acid sequence of scnpi showed high similarity to those of Streptomyces subtilisin inhibitor (SSI) and its homologues. The reactive site of ScNPI for inhibition of subtilisin BPN' was identified to be Met(71)-Tyr(72) bond by specific cleavage. To identify the reactive site for ScNP, Tyr(33) and Tyr(72), which are not conserved among other SSI family inhibitors but are preferable amino acid residues for ScNP, were replaced separately by Ala. The Y33A mutant retained inhibitory activity toward subtilisin BPN' but did not show any inhibitory activity toward ScNP. Moreover, a dimer of ternary complexes among ScNPI, ScNP, and subtilisin BPN' was formed to give the 2:2:2 stoichiometry. These results strongly indicate that ScNPI is a double-headed inhibitor that has individual reactive sites for ScNP and subtilisin BPN'.     

The crystal structure of staphylococcal enterotoxin H: implications for binding properties to MHC class II and TcR molecules

The X-ray structure of the superantigen staphylococcal enterotoxin H (SEH) has been determined at 1.69 A resolution. In this paper we present two structures of zinc-free SEH (apoSEH) and one zinc-loaded form of SEH (ZnSEH). SEH exhibits the conventional superantigen (SAg) fold with two characteristic domains. In ZnSEH one zinc ion per SEH molecule is bound to the C-terminal beta-sheet in the region implicated for major histocompatibility complex class II (MHC class II) binding in SEA, SED and SEE. Surprisingly, the zinc ion has only two ligating amino acid residues His206 and Asp208. The other ligands to the zinc ion are two water molecules. An extensive packing interaction between two symmetry-related molecules in the crystal, 834 A(2)/molecule, forms a cavity that buries the zinc ions of the molecules. This dimer-like interaction is found in two crystal forms. Nevertheless, zinc-dependent dimerisation is not observed in solution, as seen in the case of SED. A unique feature of SEH as compared to other staphylococcal enterotoxins is a large negatively charged surface close to the Zn(2+) site. The interaction of SEH with MHC class II is the strongest known among the staphylococcal enterotoxins. However, SEH seems to lack a SEB-like MHC class II binding site, since the side-chain properties of structurally equivalent amino acid residues in SEH and those in SEB-binding MHC class II differ dramatically. There is also a structural flexibility between the domains of SEH. The domains of two apoSEH structures are related by a 5 degrees rotation leading to at most 3 A difference in C(alpha) positions. Since the T-cell receptor probably interacts with both domains, SEH by this rotation may modulate its binding to different TcR Vbeta-chains.     

Chemical modification of proteins by "smart" polymers

The modification of proteinase inhibitor ovomucoid from duck eggs white by poly-N,N-diethylacrylamide having a low critical solution temperature (LCST) have been studied. Modification of free amino groups of lysine and N-terminal residue of ovomucoid is resulted in a significant decrease in the activity of the inhibitor toward trypsin and small decrease in the activity toward α-chymotrypsin. At heating of the solution of modified ovomucoid above the LCST transformation of the antitryptic centers of ovomucoid in antichymotryptic centers was observed. It was shown that this phenomenon is due to the hydrophobization the lysine residues localized in the reactive centers of the inhibitor while maintaining the structure of the "linkage loops". Therefore the α-chymotrypsine molecules began to interact with these residues, mistaking them for the residues of hydrophobic amino acids of antichymotryptic centers.     

Trapping open and closed forms of FitE—A group III periplasmic binding protein

Periplasmic binding proteins (PBPs) are essential components of bacterial transport systems, necessary for bacterial growth and survival. The two‐domain structures of PBPs are topologically classified into three groups based on the number of crossovers or hinges between the globular domains: group I PBPs have three connections, group II have two, and group III have only one. Although a large number of structures for group I or II PBPs are known, fewer group III PBPs have been structurally characterized. Group I and II PBPs exhibit significant domain motions during transition from the unbound to ligand‐bound form, however, no large conformational changes have been observed to date in group III PBPs. We have solved the crystal structure of a periplasmic binding protein FitE, part of an iron transport system, fit, recently identified in a clinical E. coli isolate. The structure, determined at 1.8 Å resolution, shows that FitE is a group III PBP containing a single α‐helix bridging the two domains. Among the individual FitE molecules present in two crystal forms we observed three different conformations (open, closed, intermediate). Our crystallographic and molecular dynamics results strongly support the notion that group III PBPs also adopt the same Venus flytrap mechanism as do groups I and II PBPs. Unlike other group III PBPs, FitE forms dimers both in solution and in the crystals. The putative siderophore binding pocket is lined with arginine residues, suggesting an anionic nature of the iron‐containing siderophore. Proteins 2009. © 2008 Wiley‐Liss, Inc.     

Reactive site mutants of recombinant protein C inhibitor

Protein C inhibitor (PCI) is a heparin-binding serine proteinase inhibitor (serpin) which is thought to be a physiological regulator of activated protein C (APC). The residues F353-R354-S355 (P2-P1-P1′) constitute part of the reactive site loop of PCI with the R-S peptide bond being cleaved by the proteinase. Changing the reactive site P1 and P2 residues to those of either proteinase nexin-1, α₁-proteinase inhibitor or heparin cofactor II resulted in a decrease in inhibitory activity towards thrombin and APC. Changing the P2 residue F353 → P generated a rPCI which was a better thrombin inhibitor, but was 10-fold less active with APC. While these results support the concept that the P1 and P2 residues are important in the specificity of PCI, they suggest that the reactive site residues are not the only determinant of serpin specificity. Kinetic analysis of the rPCI variants was consistent with PCI operating by a mechanism similar to that proposed for other serpins. In this model an intermediary complex forms between inhibitor and proteinase that can proceed to either cleavage of the inhibitor as substrate or formation of an inactive complex.     

Crystal structure of the Bowman-Birk inhibitor from barley seeds in ternary complex with porcine trypsin

The structure and function of Bowman-Birk inhibitors (BBIs) from dicotyledonous plants such as soybean have been studied extensively. In contrast, relatively little is known about the BBIs from monocotyledonous plants such as barley, which differ from dicot BBIs in size and tertiary structure. The BBI from barley seeds (BBBI) consists of 125 amino acid residues with two separate inhibitory loops. Previously we determined the high-resolution structure of a 16 kDa BBBI in the free state. The BBBI folds into two compact domains (N and C domain) with tertiary structures that are similar to that of the 8 kDa BBI from dicots. Here we report the structure of a 1:2 complex between BBBI and porcine pancreatic trypsin (PPT) at 2.2 A resolution. This structure confirms that several regions, including the inhibitory loops in the free BBBI structure, show exceptionally low temperature factors and a distorted conformation due to crystalline packing in the lattice. Extensive analysis of the interaction between BBBI and trypsin, and comparison with other known canonical inhibitor-protease complexes, reveals that the mode of interaction between BBBI and PPT is similar to that of known serine protease inhibitors, as expected; however, several unique features are also identified in the primary binding sites near the inhibitory loops as well as in additional binding sites. The carboxy-terminal tail of the inhibitor extends into the interface between the two trypsin molecules and interacts with both of them simultaneously. The longest distance between the two P1 residues (Arg17 and Arg76) in the complex structure is approximately 34 A, which is shorter than in the free inhibitor, but it is still possible for BBBI to bind and inhibit two trypsin molecules simultaneously and independently.     

Kinetic mechanism of chicken liver xanthine dehydrogenase.

Human inter-alpha-trypsin inhibitor (I alpha I) is a plasma proteinase inhibitor active against cathepsin G, leucocyte elastase, trypsin and chymotrypsin. It owes its broad inhibitory specificity to tandem Kunitz-type inhibitory domains within an N-terminal region. Sequence studies suggest that the reactive-centre residues critical for inhibition are methionine and arginine. Reaction of I alpha I with the arginine-modifying reagent butane-2,3-dione afforded partial loss of inhibitory activity against both cathepsin G and elastase but complete loss of activity against trypsin and chymotrypsin. Reaction of I alpha I with the methionine-modifying reagent cis-dichlorodiammineplatinum(II) resulted in partial loss of activity against cathepsin G and elastase but did not affect inhibition of either trypsin or chymotrypsin. Employment of both reagents eliminated inhibition of cathepsin G and elastase. These findings suggest that both cathepsin G and elastase are inhibited at either of the reactive centres of I alpha I. Trypsin and chymotrypsin, however, appear to be inhibited exclusively at the arginine reactive centre.