A comparison between the binding modes of a substrate and inhibitor to papain as observed in complex crystal structures

On the basis of the crystal structures of papain complexed with the substrate analogue benzyloxycarbonyl-L-phenylalanyl-L-alanine chloromethyl-ketone (Drenth, J., Kalk, K.H., and Swen, H.M. (1976) Biochemistry 15, 3731-3738) and with the inhibitor E-64-c, the binding modes were compared at the atomic level to clarify the functional difference between the substrate and inhibitor. Irrespective of the reverse chemical bonding in the peptide bonds, both the molecules are located at the S subsites of papain with similar interactions. However, the inhibitory activity of E-64-c is characterized by the stereochemical function of a carboxyoxirane ring and the tight binding of the isopentylaminoleucyl side chain to the S subsites.     

The importance of Val-157 hydrophobic interaction for papain inhibitory activity of an epoxysuccinyl amino acid derivative. A structure-activity relationship based on the crystal structure of the papain-E-64-c complex

Based on the crystal structure of the papain-E-64-c complex, 3-dimensional binding modes of a series of epoxysuccinyl amino acid derivatives to the papain active site have been constructed and the structure-inhibitory activity relationship has been analyzed using the accessible surface area and nonbonded energy parameters. The result indicates the importance of the hydrophobic interaction between the amino acid side chain of the inhibitor and the papain Val-157 residue for revealing the potent inhibitory activity.     

Crystal structure of a papain-E-64 complex

E-64 [1-[N-[(L-3-trans-carboxyoxirane-2-carbonyl)-L-leucyl] amino]-4-guanidinobutane] is an irreversible inhibitor of many cysteine proteases. A papain-E-64 complex was crystallized at pH 6.3 by using the hanging drop method. Three different crystal forms grew in 3-7 days; the form chosen for structure analysis has space group P212121, with a = 42.91(4) A, b = 102.02(6) A, c = 49.73(2) A, and Z = 4. Diffraction data were measured to 2.4-A resolution, giving 9367 unique reflections. The papain structure was solved by use of the molecular replacement method, and then the inhibitor was located from a difference electron density map and fitted with the aid of a PS330 computer graphics system. The structure of the complex was refined to R = 23.3%. Our analysis shows that a covalent link is formed between the sulfur of the active-site cysteine 25 and the C-2 atom of the inhibitor. Contrary to earlier predictions, the E-64 inhibitor clearly interacts with the S subsites on the enzyme rather than the S' subsites, and papain's histidine 159 imidazole group plays a binding rather than a catalytic role in the inactivation process.     

Crystal structure of an actinidin-E-64 complex.

E-64, 1-(L-trans-epoxysuccinylleucylamino)-4-guanidinobutane, is a potent and highly selective irreversible inhibitor of cysteine proteases. The crystal structure of a complex of actinidin and E-64 has been determined at 1.86-A resolution by using the difference Fourier method and refined to an R-factor of 14.5%. The electron density map clearly shows that the C2 atom of the E-64 epoxide ring is covalently bonded to the S atom of the active-site cysteine 25. The charged carboxyl group of E-64 forms four H-bonds with the protein and thus may play an important role in favorably positioning the inhibitor molecule for nucleophilic attack by the active-site thiolate anion. The interaction features between E-64 and actinidin are very similar to those seen in the papain-E-64 complex; however, the amino-4-guanidinobutane group orients differently. The crystals of the actinidin-E-64 complex diffracted much better than the papain-E-64 complex, and consequently the present study provides more precise geometrical information on the binding of the inhibitor. Moreover, this study provides yet another confirmation that the binding of E-64 is at the S subsites and not at the S' subsites as has been previously proposed. The original actinidin structure has been revised using the new cDNA sequence information.     

Crystal structure of papain-succinyl-Gln-Val-Val-Ala-Ala-p-nitroanilide complex at 1.7-A resolution: noncovalent binding mode of a common sequence of endogenous thiol protease inhibitors.

Succinyl-Gln-Val-Val-Ala-Ala-p-nitroanilide corresponding to a common sequence of endogenous thiol protease inhibitors is a noncompetitive reversible inhibitor of papain. In order to elucidate the binding mode of the inhibitor at the atomic level, its complex with papain was crystallized at ca. pH 7.0 using the hanging drop method, and the crystal structure was analyzed at 1.7-A resolution. The crystal has space group P2(1)2(1)2(1), with a = 43.09, b = 102.32, c = 49.69 A, and Z = 4. A total of 47,215 observed reflections were collected on the imaging plates using the same single crystal, and 19,833 unique reflections with Fo > sigma (Fo) were used for structure determination and refinement. The papain structure was determined by use of the atomic coordinates of papain previously reported, and then refined by the X-PLOR program. The inhibitor molecule was located on a difference Fourier map and fitted into the electron density with the aid of computer graphics. The complex structure was finally refined to R = 19.6% including 118 solvent molecules. The X-ray analysis of the complex crystal shows that the inhibitor is located at the R-domain side, not in the center of the binding site created by the R- and L-domains of papain. Such a binding mode of the inhibitor explains well the biological behavior that the inhibitor exhibits against papain. Comparison with the structure of papain-stefin B complex indicates that the structure of the Gln-Val-Val-Ala-Gly sequence itself is not necessarily the essential requisite for inhibitory activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Protease inhibitors prevent the development of human rotavirus-induced diarrhea in suckling mice.

Oral inoculation of human rotavirus MO strain (serotype 3) into 5-day-old BALB/c mice caused gastroenteritis characterized by diarrhea (90% on the average, on day 2). Using this animal model, preventive effect of antiviral agents on the development of rotavirus-induced diarrhea was examined. The infectivity of human rotavirus was enhanced by treatment with protease in vitro. A cysteine protease inhibitor, E-64-c, was given orally at 12 hr and 24 hr after MO infection. Oral administration of 0.3 mg of E-64-c decreased the diarrhea ratio to 17.5% on day 2 and to 10% on day 3. Oral administration of 0.15 mg of cysteine protease inhibitor, ovocystatin, completely prevented the diarrhea on day 2. Serine protease inhibitor, aprotinin (0.15 mg x 2), also prevented the diarrhea on day 2 to 14.3%. These protease inhibitors were nontoxic in vitro and to suckling mice. The histopathological changes in the small intestine due to infection recovered 2 days after MO infection in mice treated with E-64-c and ovocystatin. These results suggest that protease inhibitors are protective agents for human rotavirus infection by inhibiting proteases required for viral replication.     

The effect of an in vivo-injected thiol protease inhibitor, E-64-c, on the calcium-induced degeneration of myofilaments

The role of intracellular calcium-dependent proteinase(s) has been investigated in intact rat muscle. When calcium ions were introduced into intact muscle in vitro with ionophore A23187, Z-line loss and concomitant release of alpha-actinin into the medium were observed. The calcium-induced release of alpha-actinin was not diminished in the muscle with in vivo-injection of a thiol protease inhibitor, E-64-c. Intramuscular concentrations of E-64-c were also measured after pulse labeling with [3H]E-64-c followed by subcellular fractionation. Most of the inhibitor was localized in the cytosol, not in the lysosome. Therefore, we conclude that cytosolic as well as lysosomal proteinases in muscle are not inhibited by the in vivo labeling of the protease inhibitor (10 mg/kg).     

Structural basis of the unusual stability and substrate specificity of ervatamin C, a plant cysteine protease from Ervatamia coronaria

Ervatamin C is an unusually stable cysteine protease from the medicinal plant Ervatamia coronaria belonging to the papain family. Though it cleaves denatured natural proteins with high specific activity, its activity toward some small synthetic substrates is found to be insignificant. The three-dimensional structure and amino acid sequence of the protein have been determined from X-ray diffraction data at 1.9 A (R = 17.7% and R(free) = 19.0%). The overall structure of ervatamin C is similar to those of other homologous cysteine proteases of the family, folding into two distinct left and right domains separated by an active site cleft. However, substitution of a few amino acid residues, which are conserved in the other members of the family, has been observed in both the domains and also at the region of the interdomain cleft. Consequently, the number of intra- and interdomain hydrogen-bonding interactions is enhanced in the structure of ervatamin C. Moreover, a unique disulfide bond has been identified in the right domain of the structure, in addition to the three conserved disulfide bridges present in the papain family. All these factors contribute to an increase in the stability of ervatamin C. In this enzyme, the nature of the S2 subsite, which is the primary determinant of specificity of these proteases, is similar to that of papain, but at the S3 subsite, Ala67 replaces an aromatic residue, and has the effect of eliminating sufficient hydrophobic interactions required for S3-P3 stabilization. This provides the possible explanation for the lower activity of ervatamin C toward the small substrate/inhibitor. This substitution, however, does not affect the binding of denatured natural protein substrates to the enzyme significantly, as there exist a number of additional interactions at the enzyme-substrate interface outside the active site cleft.     

L-trans-Epoxysuccinyl-leucylamido(4-guanidino)butane (E-64) and its analogues as inhibitors of cysteine proteinases including cathepsins B, H and L.

1. L-trans-Epoxysuccinyl-leucylamido(4-guanidino)butane (E-64) at a concentration of 0.5 mM had no effect on the serine proteinases plasma kallikrein and leucocyte elastase or the metalloproteinases thermolysin and clostridial collagenase. In contrast, 10 muM-E-64 rapidly inactivated the cysteine proteinases cathepsins B, H and L and papain (t0.5 = 0.1-17.3s). The streptococcal cysteine proteinase reacted much more slowly, and there was no irreversible inactivation of clostripain. The cysteine-dependent exopeptidase dipeptidyl peptidase I was very slowly inactivated by E-64. 2. the active-site-directed nature of the interaction of cathepsin B and papain with E-64 was established by protection of the enzyme in the presence of the reversible competitive inhibitor leupeptin and by the stereospecificity for inhibition by the L as opposed to the D compound. 3. It was shown that the rapid stoichiometric reaction of the cysteine proteinases related to papain can be used to determine the operational molarity of solutions of the enzymes and thus to calibrate rate assays. 4. The apparent second-order rate constants for the inactivation of human cathepsins B and H and rat cathepsin L by a series of structural analogues of E-64 are reported, and compared with those for some other active-site-directed inhibitors of cysteine proteinases. 5. L-trans-Epoxysuccinyl-leucylamido(3-methyl)butane (Ep-475) was found to inhibit cathepsins B and L more rapidly than E-64. 6. Fumaryl-leucylamido(3-methyl)butane (Dc-11) was 100-fold less reactive than the corresponding epoxide, but was nevertheless about as effective as iodoacetate.     

Crystal structure of human cathepsin S.

We have determined the 2.5 A structure (Rcryst = 20.5%, Rfree = 28.5%) of a complex between human cathepsin S and the potent, irreversible inhibitor 4-morpholinecarbonyl-Phe-hPhe-vinyl sulfone-phenyl. Noncrystallographic symmetry averaging and other density modification techniques were used to improve electron density maps which were nonoptimal due to systematically incomplete data. Methods that reduce the number of parameters were implemented for refinement. The refined structure shows cathepsin S to be similar to related cysteine proteases such as papain and cathepsins K and L. As expected, the covalently-bound inhibitor is attached to the enzyme at Cys 25, and enzyme binding subsites S3-S1' are occupied by the respective inhibitor substituents. A somewhat larger S2 pocket than what is found in similar enzymes is consistent with the broader specificity of cathepsin S at this site, while Lys 61 in the S3 site may offer opportunities for selective inhibition of this enzyme. The presence of Arg 137 in the S1' pocket, and proximal to Cys 25 may have implications not only for substrate specificity C-terminal to the scissile bond, but also for catalysis.     

Interaction of the cysteine proteinase inhibitor chicken cystatin with papain

The two forms of chicken cystatin, with different isoelectric points, that have been described previously were indistinguishable in analyses of amino- and carboxy-terminal residues, amino acid composition, and peptide maps. The two forms thus are highly similar and most likely differ only in an amide group or in a small charged substituent. The binding of either cystatin form to highly purified, active papain was accompanied by the same pronounced changes in near-ultraviolet circular dichroism, ultraviolet absorption, and fluorescence emission. These changes were compatible with perturbations of the environment of aromatic residues in one or both proteins of the complex, arising from local interactions or from a conformational change. Modification of the single tryptophan residue of cystatin, at position 104, with N-bromosuccinimide resulted in considerably smaller spectroscopic changes on binding of the inhibitor to papain, indicating that the environment of this residue is affected by the binding. Analogous modification of Trp-69 and Trp-177 of papain markedly affected the fluorescence changes observed on binding of cystatin to the enzyme, similarly suggesting that these two residues of papain are involved in the interaction. The fluorescence increase of papain at alkaline pH, arising from Trp-177 and due to deprotonization of the adjacent His-159, was abolished on binding of cystatin to the enzyme, further supporting the proposal that this region of papain participates in the interaction with the inhibitor. A stoichiometry of binding of either cystatin form to papain of 1:1 and a lower limit for the binding constant of 10(9) M-1 were determined by titrations monitored by either the ultraviolet absorption or fluorescence changes induced by the interaction.     

Interaction of chicken cystatin with inactivated papains.

Papain which was inactivated by covalent attachment of small substituents to the active-site cysteine, up to the size of a carbamoylmethyl group, bound with high affinity to chicken cystatin (Kd less than approximately 15 pM), although less tightly than did active papain (Kd approximately 60 fM). However, as the size of the substituent was increased further, the affinity decreased appreciably, generally in proportion to the size of the inactivating group. For instance the dissociation constants for papain inactivated with N-ethylmaleimide and [N-(L-3-trans-carboxyoxiran-2-carbonyl)-L-leucyl]-amido-(4-guanido )butane were 0.17 and approximately 10 microM respectively. The spectroscopic changes accompanying the reaction of all but the most weakly binding (Kd greater than or equal to 2 microM) inactivated papains with cystatin were similar to those induced by the active enzyme. Interactions involving the reactive cysteine residue of papain are thus not crucial for high-affinity binding of the enzyme to cystatin, in accordance with a recently proposed model for the enzyme-inhibitor complex, based on computer docking experiments. In this model there is sufficient space around the reactive cysteine in the complex for a small inactivating group, explaining the tight binding of papains with such substituents. However, larger inactivating groups cannot be accommodated in this space and therefore must displace the inhibitor out of the tight fit with the enzyme, in agreement with the observed decrease in binding affinity with increasing size of bulkier substituents. The kinetics of binding of cystatin to inactivated papains were compatible with simple, reversible, bimolecular reactions, having association rate constants of (7-9) x 10(6) M-1 s-1 at pH 7.4, 25 degrees C, similar to what was shown previously for the binding of cystatin to active papain. The rate of association of the inhibitor with either active or inactivated papain thus appears to be primarily diffusion-controlled. The decreasing affinity of cystatin for papains inactivated with groups of increasing size was shown to be due to progressively higher dissociation rate constants, consistent with the greater impairment of fit between the binding regions of the two molecules.     

Inhibition mechanism of cathepsin L-specific inhibitors based on the crystal structure of papain-CLIK148 complex

Papain was used as an experimental model structure to understand the inhibition mechanism of newly developed specific inhibitors of cathepsin L, the papain superfamily. Recently, we developed a series of cathepsin L-specific inhibitors which are called the CLIK series [(1999) FEBS Lett. 458, 6-10]. Here, we report the complex structure of papain with CLIK148, which is a representative inhibitor from the CLIK series. The inhibitor complex structure was solved at 1.7 A resolution with conventional R 0.177. Unlike other epoxisuccinate inhibitors (E64, CA030, and CA074), CLIK148 uses both prime and nonprime sites, which are important for the specific inhibitory effect on cathepsin L. Also, the specificity for cathepsin L could be explained by the existence of Phe in the P2 site and hydrophobic interaction of N-terminal pyridine ring.     

Urethanyl-3-amidinophenylalanine derivatives as inhibitors of factor Xa. X-ray crystal structure of a trypsin/inhibitor complex and modeling studies

Hydrophobic urethanyl derivatives of 3-amidinophenylalanine methyl ester were found to be relatively potent and selective factor Xa inhibitors. These compounds consist of the arginine-mimetic 3-benzamidino group as P1 residue and of hydrophobic residues as potential interaction partners for the S3/S4 aryl binding site of the enzyme. Attempts to possibly identify their binding mode to factor Xa via the X-ray crystal structure of a trypsin/inhibitor complex and analogy modeling on the crystal structure of factor Xa failed. However, synthesis of enantiomerically pure (R)- and (S)-derivatives, combined with modeling experiments, led to an hypothetical non-substrate like binding mode, which was fully confirmed by the remarkably enhanced inhibitory potency of derivatives in which the methyl ester was replaced by arylamides for interactions with the S3/S4 enzyme binding subsites. With adamantyloxycarbonyl-(R)-3-amidinophenylalanine-phenethylamide+ ++ a nanomolar inhibiton was obtained, thus indicating this new class of factor Xa inhibitors as a highly promising lead structure.     

Quantitative evaluation of each catalytic subsite of cathepsin B for inhibitory activity based on inhibitory activity-binding mode relationship of epoxysuccinyl inhibitors by X-ray crystal structure analyses of complexes

To quantitatively estimate the inhibitory effect of each substrate-binding subsite of cathepsin B (CB), a series of epoxysuccinyl derivatives with different functional groups bound to both carbon atoms of the epoxy ring were synthesized, and the relationship between their inhibitory activities and binding modes at CB subsites was evaluated by the X-ray crystal structure analyses of eight complexes. With the common reaction in which the epoxy ring of inhibitor was opened to form a covalent bond with the SgammaH group of the active center Cys29, the observed binding modes of the substituents of inhibitors at the binding subsites of CB enabled the quantitative assessment of the inhibitory effect of each subsite. Although the single blockage of S1' or S2' subsite exerts only the inhibitory effect of IC50 = approximately 24 microM (k2 = approximately 1250 M(-1) s(-1)) or approximately 15 microM (k2 = approximately 1800 M(-1) s(-1)), respectively, the synchronous block of both subsites leads to IC50 = approximately 23 nM (k2 = 153,000 - 185,000 M(-1) s(-1)), under the condition that (i) the inhibitor possesses a P1' hydrophobic residue such as Ile and a P2' hydrophobic residue such as Ala, Ile or Pro, and (ii) the C-terminal carboxyl group of a P2' residue is able to form paired hydrogen bonds with the imidazole NH of His110 and the imidazole N of His111 of CB. The inhibitor of a Pn' > or = 3' substituent was not potentiated by collision with the occluding loop. On the other hand, it was suggested that the inhibitory effects of Sn subsites are independent of those of Sn' subsites, and the simultaneous blockage of the funnel-like arrangement of S2 and S3 subsites leads to the inhibition of IC50 = approximately 40 nM (k2 = approximately 66,600 M(-1) s(-1)) regardless of the lack of Pn' substituents. Here we present a systematic X-ray structure-based evaluation of structure-inhibitory activity relationship of each binding subsite of CB, and the results provide the structural basis for designing a more potent CB-specific inhibitor.     

Location of the binding site for chloride ion activation of cathepsin C.

Cathepsin C, a tetrameric lysosomal dipeptidyl-peptide hydrolase, is activated by chloride ion. The activation is shown here to be specific and pH-dependent, dissociation constants for chloride being lower at low pH. Bound chloride decreases the Km for the hydrolysis of chromophore labelled substrates without any significant change in Vmax, confirming its involvement in substrate binding. Determination of the kinetic parameters of chloride activation, using unlabelled substrates, has enabled its site of action to be located. The lower Km for the hydrolysis of simple amide substrates in the presence of Cl- shows that the S sites are involved. Possible involvement of the S' sites is excluded by the finding that the Km for the nucleophile in the transferase reaction is unaffected by chloride. The rates of inhibition by E-64 and iodoacetate are both chloride-dependent and, from the structure of the papain-E-64 complex, it is concluded that chloride binds close to the S2 site. The binding of guanidinium ion, a positively charged inhibitor, to the S site is dependent on chloride. Based on these results, a model is proposed to explain the chloride activation of cathepsin C. The possible physiological role of chloride in the regulation of proteolysis in the lysosome is discussed.     

Effects of selective inhibition of cathepsin B and general inhibition of cysteine proteinases on lysosomal proteolysis in rat liver in vivo and in vitro.

Intraperitoneal administration of N-(L-trans-propylcarbamoyloxirane-2-carbonyl)-L-isoleucyl-L-prolin e (CA-074) to rats at a dose of 4 mg/100 g greatly inhibited cathepsin-B activity in both liver and kidney for at least 4 h. Its inhibitory effect was selective for cathepsin-B activity in the liver but not in the kidney. The effects of selective inhibition of cathepsin-B activity by CA-074 treatment, and general inhibition of cysteine proteinases by N-(L-3-trans-carboxyoxirane-2-carbonyl)-L-leucyl-3-methylbutylamid e (E-64-c) on the degradation of fluorescein isothiocyanate (FITC)-labeled asialofetuin in liver lysosomes, were examined in vivo. Undegraded or partially degraded FITC-labeled asialofetuin and its FITC-labeled degradation products were both found in the lysosomes and were easily separated by Sephadex G-25' column chromatography. The FITC-labeled degradation products were mainly lysine with an FITC-labeled epsilon-amino group. Accumulation of undegraded or partially degraded FITC-labeled asialofetuin in the lysosomes was marked after E-64-c treatment, but slight after CA-074 treatment. Under the marked inhibition of general lysosomal cysteine-proteinase activity by E-64-c or marked selective inhibition of cathepsin-B activity by CA-074 in vitro, degradation of FITC-labeled asialofetuin by disrupted lysosomes was analyzed on the basis of measurement of FITC-labeled degradation products by Sephadex G-25 column chromatography. It was suppressed markedly but incompletely by E-64-c as well as by CA-074, but more weakly than by E-64-c. These results shows that E-64-sensitive cysteine proteinases are important in lysosomal protein degradation, but cathepsin B has only a role in part and that an E-64-resistant proteinase(s) may also be important.     

Application of free energy simulations to the binding of a transition-state-analogue inhibitor to HIV protease.

Free energy simulations (slow-change method) have been used to estimate quantitatively the ratio of the binding constants of (S) and (R) isomers of a novel HIV protease inhibitor, JG365. As a starting geometry, we used the X-ray crystallographic structure of a complex of HIV protease and JG365 provided by A. Wlodawer. According to our results the (S) configuration, i.e. the form previously identified experimentally, binds considerably more tightly to the protease (delta delta G degrees = 2.9 kcal/mol). When the (S) inhibitor is bound, there is a very strong preference for protonation of the Asp125 (rather than the Asp25) residue of the protease. This study is the first to apply a new method for quantitatively assessing the precision of free energies calculated by the slow-change method.     

Importance of the second binding loop and the C-terminal end of cystatin B (stefin B) for inhibition of cysteine proteinases.

The importance of residues in the second hairpin loop and the C-terminal end of mammalian cystatin B for binding of proteinases was elucidated by mutagenesis of the bovine inhibitor. Bovine cystatin B was modeled onto the crystal structure of the human inhibitor in complex with papain with minimal structural changes. Substitution of the two deduced contact residues in the second hairpin loop, Leu-73 and His-75, with Gly resulted in appreciably reduced affinities for papain and cathepsins H and B. These losses indicated that the two residues together contribute 20-30% of the free energy of binding of cystatin B to these enzymes and that Leu-73 is responsible for most of this contribution. In contrast, the small decrease in the affinity for cathepsin L suggested that the second hairpin loop is less important for inhibition of this proteinase. Replacement of the contact residue in the C-terminal end, Tyr-97, with Ala resulted in losses in affinity for papain and cathepsins L and H that were consistent with Tyr-97 contributing 6-12% of the energy of binding of cystatin B to these enzymes. However, this substitution minimally affected the affinity for cathepsin B, indicating that the C-terminal end is of limited importance for binding of this proteinase. All affinity decreases were due predominantly to increased dissociation rate constants. These results show that both the second hairpin loop and the C-terminal end of cystatin B contribute to anchoring the inhibitor to target proteinases, each of the two regions interacting with a different domain of the enzyme. However, the relative contributions of these two interactions vary with the proteinase.     

Enzymatic and Structural Characterization of the Major Endopeptidase in the Venus Flytrap Digestion Fluid

Carnivorous plants primarily use aspartic proteases during digestion of captured prey. In contrast, the major endopeptidases in the digestive fluid of the Venus flytrap (Dionaea muscipula) are cysteine proteases (dionain-1 to -4). Here, we present the crystal structure of mature dionain-1 in covalent complex with inhibitor E-64 at 1.5 Å resolution. The enzyme exhibits an overall protein fold reminiscent of other plant cysteine proteases. The inactive glycosylated pro-form undergoes autoprocessing and self-activation, optimally at the physiologically relevant pH value of 3.6, at which the protective effect of the pro-domain is lost. The mature enzyme was able to efficiently degrade a Drosophila fly protein extract at pH 4 showing high activity against the abundant Lys- and Arg-rich protein, myosin. The substrate specificity of dionain-1 was largely similar to that of papain with a preference for hydrophobic and aliphatic residues in subsite S₂ and for positively charged residues in S₁. A tentative structure of the pro-domain was obtained by homology modeling and suggested that a pro-peptide Lys residue intrudes into the S₂ pocket, which is more spacious than in papain. This study provides the first analysis of a cysteine protease from the digestive fluid of a carnivorous plant and confirms the close relationship between carnivorous action and plant defense mechanisms.