Isotope-edited proton NMR study on the structure of a pepsin/inhibitor complex

A general approach is illustrated for providing detailed structural information on large enzyme/inhibitor complexes using NMR spectroscopy. The method involves the use of isotopically labeled ligands to simplify two-dimensional NOE spectra of large molecular complexes by isotope-editing techniques. With this approach, the backbone and side-chain conformations (at the P2 and P3 sites) of a tightly bound inhibitor of porcine pepsin have been determined. In addition, structural information on the active site of pepsin has been obtained. Due to the sequence homology between porcine pepsin and human renin, this structural information may prove useful for modeling renin/inhibitor complexes with the ultimate goal of designing more effective renin inhibitors. Moreover, this general approach can be applied to study other biological systems of interest such as other enzyme/inhibitor complexes, ligands bound to soluble receptors, and enzyme/substrate interactions.     

A new selective substrate for cathepsin E based on the cleavage site sequence of alpha2-macroglobulin

Cathepsin E is an intracellular aspartic proteinase of the pepsin family predominantly expressed in cells of the immune system and believed to contribute to homeostasis by participating in host defense mechanisms. Studies on its enzymatic properties, however, have been limited by a lack of sensitive and selective substrates. For a better understanding of the importance of this enzyme in vivo, we designed and synthesized a highly sensitive peptide substrate for cathepsin E based on the sequence of the specific cleavage site of alpha2-macroglobulin. The substrate constructed, MOCAc-Gly-Ser-Pro-Ala-Phe-Leu-Ala-Lys(Dnp)-D-Arg-NH2 [where MOCAc is (7-methoxycoumarin-4-yl)acetyl and Dnp is dinitrophenyl], derived from the cleavage site sequence of human alpha2-macroglobulin, was the most sensitive and selective for cathepsin E, with k(cat)/K(m) values of 8-11 microM(-1) s(-1), whereas it was resistant to hydrolysis by the analogous aspartic proteinases cathepsin D and pepsin, as well as the lysosomal cysteine proteinases cathepsins B, L, and H. The assay allows the detection of a few fmol of cathepsin E, even in the presence of plasma and cell lysate, and gives accurate results over a wide enzyme concentration range. This substrate might represent a useful tool for monitoring and accurately quantifying cathepsin E, even in crude enzyme preparations.     

Crystal structure of an activation intermediate of cathepsin E

Cathepsin E is an intracellular, non-lysosomal aspartic protease expressed in a variety of cells and tissues. The protease has proposed physiological roles in antigen presentation by the MHC class II system, in the biogenesis of the vasoconstrictor peptide endothelin, and in neurodegeneration associated with brain ischemia and aging. Cathepsin E is the only A1 aspartic protease that exists as a homodimer with a disulfide bridge linking the two monomers. Like many other aspartic proteases, it is synthesized as a zymogen which is catalytically inactive towards its natural substrates at neutral pH and which auto-activates in an acidic environment. Here we report the crystal structure of an activation intermediate of human cathepsin E at 2.35A resolution. The overall structure follows the general fold of aspartic proteases of the A1 family, and the intermediate shares many features with the intermediate 2 on the proposed activation pathway of aspartic proteases like pepsin C and cathepsin D. The pro-sequence is cleaved from the protease and remains stably associated with the mature enzyme by forming the outermost sixth strand of the interdomain beta-sheet. However, different from these other aspartic proteases the pro-sequence of cathepsin E remains intact after cleavage from the mature enzyme. In addition, the active site of cathepsin E in the crystal is occupied by N-terminal amino acid residues of the mature protease in the non-primed binding site and by an artificial N-terminal extension of the pro-sequence from a neighboring molecule in the primed site. The crystal structure of the cathepsin E/pro-sequence complex, therefore, provides further insight into the activation mechanism of aspartic proteases.     

Amino acid sequence of porcine spleen cathepsin D light chain

The complete amino acid sequence of the light chain of cathepsin D from porcine spleen has been determined. The light chain consists of a single polypeptide chain with 97 amino acid residues. The sequence is: (formula; see text) The molecular weight of the light chain was calculated from this sequence to be 10,548 (without carbohydrates). A single disulfide bond links two half-cystine residues between positions 46 and 53. A cysteine residue is located at position 27. The light chain sequence is extensively homologous to the NH2-terminal sequence of other aspartyl proteases. It shows a 59% identity with the sequence of mouse submaxillary gland renin and a 49% identity with that of porcine pepsin. A single glycosylation site is located at residue 70 of the cathepsin D light chain. This site corresponds to position 67 of pepsin by homology. The active site aspartyl residue, corresponding to Asp-32 of pepsin, is located at residue 33 in the cathepsin D light chain.     

Revised 2.3 A structure of porcine pepsin: evidence for a flexible subdomain

A revised three-dimensional crystal structure of ethanol-inhibited porcine pepsin refined to an R-factor of 0.171 at 2.3 A resolution is presented and compared to the refined structures of the fungal aspartic proteinases: penicillopepsin, rhizopuspepsin, and endothiapepsin. Pepsin is composed of two nearly equal N and C domains related by an intra dyad. The overall polypeptide fold and active site structures are homologous for pepsin and the fungal enzymes. The weak inhibition of pepsin by ethanol can be explained by the presence of one or more ethanol molecules, in the vicinity of the active site carboxylates, which slightly alter the hydrogen-bonding network and which may compete with substrate binding in the active site. Structural superposition analysis showed that the N domains aligned better than the C-domains for pepsin and the fungal aspartic proteinases: 107-140 C alpha pairs aligned to 0.72-0.85 A rms for the N domains; 64-95 C alpha pairs aligned to 0.78-1.03 A rms for the C domains. The major structural difference between pepsin and the fungal enzymes concerns a newly described subdomain whose conformation varies markedly among these enzyme structures. The subdomain in pepsin comprises nearly 100 residues and is composed of two contiguous segments within the C domain (residues 192-212 and 223-299). the subdomain is connected, or "hinged," to a mixed beta-sheet that forms one of the structurally invariant, active site psi-loops. Relative subdomain displacements as large as a 21.0 degrees rotation and a 5.9 A translation were observed among the different enzymes. There is some suggestion in pepsin that the subdomain may be flexible and perhaps plays a structural role in mediating substrate binding, determining the substrate specificity, or in the activation of the zymogen.     

Molecular and crystal structures of monoclinic porcine pepsin refined at 1.8 A resolution

The molecular structure of the archetypal aspartic proteinase, porcine pepsin (EC 3.4.23.1), has been refined using data collected from a single monoclinic crystal on a twin multiwire detector system to 1.8 A resolution. The current crystallographic R-factor (= sigma parallel to Fo/-/Fc parallel to/sigma/Fo/) is 0.174 for the 20,519 reflections with /Fo/ greater than or equal to 3 sigma (Fo) in the range 8.0 to 1.8 A (/Fo/ and /Fc/ are the observed and calculated structure factor amplitudes respectively). The refinement has shown conclusively that there are only 326 amino acid residues in porcine pepsin. Ile230 is not present in the molecule. The two catalytic residues Asp32 and Asp215 have dispositions in porcine pepsin very similar to the dispositions of the equivalent residues in the other aspartic proteinases of known structure. A bound solvent molecule is associated with both carboxyl groups at the active site. No bound ethanol molecule could be identified conclusively in the structure. The average thermal motion parameter of the residues that comprise the C-terminal domain of pepsin is approximately twice that of the residues in the N-terminal domain. Comparisons of the tertiary structure of pepsin with porcine pepsinogen, penicillopepsin, rhizopus pepsin and endothia pepsin reveal that the N-terminal domains are topographically more similar than the conformationally flexible C-terminal domains. The conformational differences may be modeled as rigid-body movements of "reduced" C-terminal domains (residues 193 to 212 and 223 to 298 in pepsin numbering). A similar movement of the C-terminal domain of endothia pepsin has been observed upon inhibitor binding. A phosphoryl group covalently attached to Ser68 O gamma has been identified in the electron density map of porcine pepsin. The low pKa1 value for this group, coupled with unusual microenvironments for several of the aspartyl carboxylate groups, ensures a net negative charge on porcine pepsin in a strongly acid medium. Thus, there is a structural explanation for the very early observations of "anodic migration" of porcine pepsin at pH 1. In the crystals, the molecules are packed tightly into a monoclinic unit cell. There are 190 direct contacts (less than or equal to 4.0 A) between a central pepsin molecule and the five unique symmetry-related molecules surrounding it in the crystalline lattice. The tight packing in this cell makes pepsin's active site and binding cleft relatively inaccessible to substrate analogs or inhibitors.     

Refined structure of porcine pepsinogen at 1.8 A resolution

The molecular structure of porcine pepsinogen at 1.8 A resolution has been determined by a combination of molecular replacement and multiple isomorphous phasing techniques. The resulting structure was refined by restrained-parameter least-squares methods. The final R factor [formula: see text] is 0.164 for 32,264 reflections with I greater than or equal to sigma (I) in the resolution range of 8.0 to 1.8 A. The model consists of 2785 protein atoms in 370 residues, a phosphoryl group on Ser68 and 238 ordered water molecules. The resulting molecular stereochemistry is consistent with a well-refined crystal structure with co-ordinate accuracy in the range of 0.10 to 0.15 A for the well-ordered regions of the molecule (B less than 15 A2). For the enzyme portion of the zymogen, the root-mean-square difference in C alpha atom co-ordinates with the refined porcine pepsin structure is 0.90 A (284 common atoms) and with the C alpha atoms of penicillopepsin it is 1.63 A (275 common atoms). The additional 44 N-terminal amino acids of the prosegment (Leu1p to Leu44p, using the letter p after the residue number to distinguish the residues of the prosegment) adopt a relatively compact structure consisting of a long beta-strand followed by two approximately orthogonal alpha-helices and a short 3(10)-helix. Intimate contacts, both electrostatic and hydrophobic interactions, are made with residues in the pepsin active site. The N-terminal beta-strand, Leu1p to Leu6p, forms part of the six-stranded beta-sheet common to the aspartic proteinases. In the zymogen the first 13 residues of pepsin, Ile1 to Glu13, adopt a completely different conformation from that of the mature enzyme. The C alpha atom of Ile1 must move approximately 44 A in going from its position in the inactive zymogen to its observed position in active pepsin. Electrostatic interactions of Lys36pN and hydrogen-bonding interactions of Tyr37pOH, and Tyr90H with the two catalytic aspartate groups, Asp32 and Asp215, prevent substrate access to the active site of the zymogen. We have made a detailed comparison of the mammalian pepsinogen fold with the fungal aspartic proteinase fold of penicillopepsin, used for the molecular replacement solution. A structurally derived alignment of the two sequences is presented.     

Analysis of binding interactions of pepsin inhibitor-3 to mammalian and malarial aspartic proteases

The nematode Ascaris suum primarily infects pigs, but also causes disease in humans. As part of its survival mechanism in the intestinal tract of the host, the worm produces a number of protease inhibitors, including pepsin inhibitor-3 (PI3), a 17 kDa protein. Recombinant PI3 expressed in E. coli has previously been shown to be a competitive inhibitor of a subgroup of aspartic proteinases: pepsin, gastricsin and cathepsin E. The previously determined crystal structure of the complex of PI3 with porcine pepsin (p. pepsin) showed that there are two regions of contact between PI3 and the enzyme. The first three N-terminal residues (QFL) bind into the prime side of the active site cleft and a polyproline helix (139-143) in the C-terminal domain of PI3 packs against residues 289-295 that form a loop in p. pepsin. Mutational analysis of both inhibitor regions was conducted to assess their contributions to the binding affinity for p. pepsin, human pepsin (h. pepsin) and several malarial aspartic proteases, the plasmepsins. Overall, the polyproline mutations have a limited influence on the Ki values for all the enzymes tested, with the values for p. pepsin remaining in the low-nanomolar range. The largest effect was seen with a Q1L mutant, with a 200-fold decrease in Ki for plasmepsin 2 from Plasmodium falciparum (PfPM2). Thermodynamic measurements of the binding of PI3 to p. pepsin and PfPM2 showed that inhibition of the enzymes is an entropy-driven reaction. Further analysis of the Q1L mutant showed that the increase in binding affinity to PfPM2 was due to improvements in both entropy and enthalpy.     

Catalytic properties and chemical composition of pepsins from Atlantic cod (Gadus morhua)

1. Three pepsins were purified from the gastric mucosa of Atlantic cod (Gadus morhua). 2. The enzymes, called Pepsin I and Pepsin IIa and b, had isoelectric points 6.9, 4.0 and 4.1, respectively, and digested hemoglobin at a maximal rate at a pH of approximately 3. 3. They resembled bovine cathepsin D in being unable to digest the mammalian pepsin substrate N-acetyl-L-phenylalanyl-3,5-diiodo-L-tyrosine. 4. Specificity constants (kcat/Km) for the cod pepsins were lower than for porcine pepsin, and they expressed higher substrate affinity and physiological efficiency at pH 3.5 than at pH 2. 5. The cod pepsins are glycoproteins, and their amino acid composition resembles that of porcine cathepsin D more than that of porcine pepsin. 6. The N-terminal sequence of Atlantic cod pepsins is substantially different from that of porcine pepsin. This indicates a significant evolutionary gap between fish and mammalian pepsins.     

Crystal structure of human procathepsin X: a cysteine protease with the proregion covalently linked to the active site cysteine

Human cathepsin X is one of many proteins discovered in recent years through the mining of sequence databases. Its sequence shows clear homology to cysteine proteases from the papain family, containing the characteristic residue patterns, including the active site. However, the proregion of cathepsin X is only 38 residues long, the shortest among papain-like enzymes, and the cathepsin X sequence has an atypical insertion in the regions proximal to the active site. This protein was recently expressed and partially characterized biochemically. Unlike most other cysteine proteases from the papain family, procathepsin X is incapable of autoprocessing in vitro but can be processed under reducing conditions by exogenous cathepsin L. Atypically, the mature enzyme is primarily a carboxypeptidase and has extremely poor endopeptidase activity. We have determined the three-dimensional structure of the procathepsin X at 1.7 A resolution. The overall structure of the mature enzyme is characteristic for enzymes of the papain superfamily, but contains several novel features. Most interestingly, the short proregion binds to the enzyme with the aid of a covalent bond between the cysteine residue in the proregion (Cys10p) and the active site cysteine residue (Cys31). This is the first example of a zymogen in which the inhibition of enzyme's proteolytic activity by the proregion is achieved through a reversible covalent modification of the active site nucleophile. Such mode of binding requires less contact area between the proregion and the enzyme than observed in other procathepsins, and no auxiliary binding site on the enzyme surface is used. A three-residue insertion in a highly conserved region, just prior to the active site cysteine residue, confers a significantly different shape on the S' subsites, compared to other proteases from papain family. The 3D structure provides an explanation for the rather unusual carboxypeptidase activity of this enzyme and confirms the predictions based on homology modeling. Another long insertion in the cathepsin X amino acid sequence forms a beta-hairpin pointing away from the active site. This insertion, thought to be an equivalent of cathepsin B occluding loop, is located on the side of the protein, distant from the substrate binding site.     

Cleavage specificities of aspartic proteinases toward oxidized insulin B chain at different pH values

The cleavage specificities of typical aspartic proteinases: pepsin A, gastricsin, cathepsin D and rhizopuspepsin, were examined at different pH values with oxidized insulin B chain as a substrate with special attention to the specificities near neutral pH. Significant differences in relative specificity for scissile bonds were observed between pH 2.0 and 5.5-6.5, which may be partly related with the changes in dissociation states of the His and Glu residues in the substrate and the ionizable residues in the active site of each enzyme.     

Exploring the binding preferences/specificity in the active site of human cathepsin E

Aspartic proteinases are produced in the human body by a variety of cells. Some of these proteins, examples of which are pepsin, gastricsin, and renin, are secreted and exert their effects in the extracellular spaces. Cathepsin D and cathepsin E on the other hand are intracellular enzymes. The least characterized of the human aspartic proteinases is cathepsin E. Presented here are results of studies designed to characterize the binding specificities in the active site of human cathepsin E with comparison to othermechanistically similar enzymes. A peptide series based on Lys-Pro-Ala-Lys-Phe*Nph-Arg-Leu was generatedto elucidate the specificity in the individual binding pockets with systematic substitutions in the P_5? P₂ and P₂′-P₃′ based on charge, hydrophobicity, and hydrogen bonding. Also, to explore the S₂ binding preferences, asecond series of peptides based on Lys-Pro-Ile-Glu-Phe*Nph-Arg-Leu was generated with systematic replacements in the P₂ position. Kinetic parameters were determined forboth sets of peptides. The results were correlated to a rule-based structural model of human cathepsin E, constructed on the known three-dimensional structures of several highly homologous aspartic proteinases; porcine pepsin, bovine chymosin, yeast proteinase A, human cathepsin D, andmouse and human renin. Important specificity-determining interactions were found in the S₃ (Glu13) and S₂ (Thr-222, Gln-287, Leu-289, Ile-300)subsites. © 1995 Wiley-Liss, Inc.     

Purification and properties of cathepsin D from porcine spleen.

Cathepsin D was purified from porcine spleen to near homogeneity as determined by gel electrophoresis. The isolation scheme involved an acid precipitation of tissue extract, DEAE-cellulose and Sephadex G-200 chromatography, and isoelectric focusing. The end product represented about a 1000-fold purification and about a 10% recovery. The purified enzyme was the major isoenzyme, which represented 60% of cathepsin D present in porcine spleen. Two minor isoenzymes of cathepsin D were present in small amounts. The purified enzyme resembled porcine pepsin in molecular weight (35,000), amino acid composition, and inactivation by specific pepsin inactivators. The pH activity curve of the purified enzyme showed two optima near pH 3 and 4. The relative activities at these optimal pH values were affected by salt concentration. Experimental evidence indicated that the two-optima phenomenon is a property of a single enzyme species.     

Characterization of recombinant rat cathepsin B and nonglycosylated mutants expressed in yeast. New insights into the pH dependence of cathepsin B-catalyzed hydrolyses.

The cysteine proteinase rat cathepsin B was expressed in yeast in an active form and was found to be heterogeneously glycosylated at the consensus sequence for N-linked oligosaccharide substitution. Purified enzyme fractions containing the highest levels of glycosylation were shown to have reduced activity. A glycosylation minus mutant constructed by site-directed mutagenesis (by changing the Ser to Ala in the consensus sequence) was still secreted by the yeast and was shown to be functionally identical with purified rat liver cathepsin B. Recombinant cathepsin B was used to further characterize the pH dependence of cathepsin B-catalyzed hydrolyses using 7-amido-4-methylcoumarin (AMC) and p-nitroaniline (pNA) substrates with arginine as the P1, and either arginine or phenylalanine as the P2 residue. The AMC and pNA groups give insights into the leaving group binding site (P') of cathepsin B. These studies show for the first time that at least seven dissociable groups are involved in substrate binding and hydrolysis in cathepsin B activity. Two of these groups, with pKa values of 6.9 and 7.7 in the recombinant enzyme, are in the leaving group binding site and are most likely His110 and His111. The same groups in rat liver cathepsin B have higher pKa values than in recombinant cathepsin B, but have identical function in the two enzymes. Two other groups are probably the active site Cys29 and His199 with pKa values of 3.6 and 8.6, respectively. A group with a pKa of 5.1 interacts with substrates containing Arg at P2, and the group is most likely Glu245. The remaining two groups, one with a pKa of about 4.9 and the other about 5.3, are most likely carboxyl residues possibly interacting with Arg at P1 in the substrate. The possible candidates on the basis of the x-ray structure are Asp22, Asp69, Glu171, and Glu122, all found within a 13 A radius from the active site thiol of Cys29.     

Structures at the proteolytic processing region of cathepsin D

The amino acid sequences at the "proteolytic processing regions" of cathepsin Ds have been determined for the enzymes from cows, pigs, and rats in order to deduce the sites of cleavage as well as the function of the proteolytic processing of cathepsin D. For bovine cathepsin D, the "processing region" sequence was determined from a peptide isolated from the single-chain enzyme. The COOH-terminal sequence of the light chain and the NH2-terminal sequence of the heavy chain were also determined. The processing region sequence of porcine cathepsin D was determined from its cDNA structure, and the same structure from rat cathepsin D was determined from the peptide sequence of the single-chain rat enzyme. From sequence homology to other aspartic proteases whose x-ray crystallographic structures are known, such as pepsinogen and penicillopepsin, it is clear that the processing regions are insertions to form an extended beta-hairpin loop between residues 91 and 92 (porcine pepsin numbers). However, the sizes of the processing regions of cathepsin Ds from different species are considerably different. For the enzymes from rats, cows, pigs, and human, the sizes of the processing regions are 6, 9, 9, and 11 amino acid residues, respectively. The amino acid sequences within the processing regions are considerably different. In addition, the proteolytic processing sites were found to be completely different in the bovine and porcine cathepsin Ds. While in the porcine enzyme, an Asn-Ser bond and a Gly-Val bond are cleaved to release 5 residues as a consequence of the processing; in the bovine enzyme, two Ser-Ser bonds are cleaved to release 2 serine residues. These findings would argue that the in vivo proteolytic processing of the cathepsin D single chain is probably not carried out by a specific "processing protease." Model building of the cathepsin D processing region conformation was conducted utilizing the homology between procathepsin D and porcine pepsinogen. The beta-hairpin structure of the processing region was found to (i) interact with the activation peptide of the procathepsin D in a beta-structure and (ii) place the Cys residue in the processing region within disulfide linkage distance to Cys-27 of cathepsin D light chain. These observations support the view that the processing region of cathepsin D may function to stabilize the conformation of procathepsin D and may play a role in its activation.     

Synthesis, purification, and active site mutagenesis of recombinant porcine pepsinogen

In order to carry out studies on structure and function relationships of porcine pepsinogen using site-directed mutagenesis approaches, the cDNA of this zymogen was cloned, sequenced, expressed in Escherichia coli, and the protein refolded, and purified to homogeneity. Porcine pepsinogen cDNA, obtained from a lambda gt10 cDNA library of porcine stomach contains 1364 base pairs. It contains leader, pro, and pepsin regions of 14, 44, and 326 residues, respectively. In addition, it also contains 5'- and 3'-untranslated regions. Four differences are present between the sequence deduced from the cDNA and the pepsinogen sequence determined previously by protein chemistry methods. Residues P19 (in the pro region) and 263 are asparagines in the cDNA sequence instead of aspartic acids. Isoleucine 230 is not present in the cDNA sequence and residue 242 is a tyrosine in the cDNA instead of an aspartic acid. Porcine pepsinogen cDNA was placed under the control of a tac promoter in a plasmid and expressed in E. coli. The synthesis of pepsinogen was optimized to about 50 mg/liter of culture. The recombinant (r-) pepsinogen, which was insoluble, was recovered by centrifugation, washed, dissolved in 6 M urea in Tris-HCl, pH 8, and refolded by rapid dilution. r-pepsinogen was purified to homogeneity after chromatography on Sephacryl S-300 and fast protein liquid chromatography on a monoQ column. r-pepsinogen contains an additional methionine residue at the NH2 terminus as compared to native (n-) pepsinogen. However, r- and n-pepsinogens are indistinguishable in their intramolecular activation constants. After activation, r- and n-pepsins have the same NH2-terminal sequences as well as Km values. Based on these data, r-pepsinogen was judged suitable for mutagenesis studies. A mutant pepsinogen (D32A) with the active site aspartic acid changed to an alanine was produced and purified. D32A-pepsinogen did not convert to pepsin in acid solution but it bound to pepstatin with an apparent KD of about 5 x 10(-10) M. D32A-pepsinogen possesses no detectable proteolytic activity. These results indicate that (i) intramolecular pepsinogen activation is accomplished by the pepsin active site, and (ii) unlike subtilisin (Carter, P., and Wells, J. A. (1988) Nature 332, 564-568), the active site mutant of pepsin is not enzymically active.     

Crystal structure of Escherichia coli malate dehydrogenase. A complex of the apoenzyme and citrate at 1.87 A resolution.

The crystal structure of malate dehydrogenase from Escherichia coli has been determined with a resulting R-factor of 0.187 for X-ray data from 8.0 to 1.87 A. Molecular replacement, using the partially refined structure of porcine mitochondrial malate dehydrogenase as a probe, provided initial phases. The structure of this prokaryotic enzyme is closely homologous with the mitochondrial enzyme but somewhat less similar to cytosolic malate dehydrogenase from eukaryotes. However, all three enzymes are dimeric and form the subunit-subunit interface through similar surface regions. A citrate ion, found in the active site, helps define the residues involved in substrate binding and catalysis. Two arginine residues, R81 and R153, interacting with the citrate are believed to confer substrate specificity. The hydroxyl of the citrate is hydrogen-bonded to a histidine, H177, and similar interactions could be assigned to a bound malate or oxaloacetate. Histidine 177 is also hydrogen-bonded to an aspartate, D150, to form a classic His.Asp pair. Studies of the active site cavity indicate that the bound citrate would occupy part of the site needed for the coenzyme. In a model building study, the cofactor, NAD, was placed into the coenzyme site which exists when the citrate was converted to malate and crystallographic water molecules removed. This hypothetical model of a ternary complex was energy minimized for comparison with the structure of the binary complex of porcine cytosolic malate dehydrogenase. Many residues involved in cofactor binding in the minimized E. coli malate dehydrogenase structure are homologous to coenzyme binding residues in cytosolic malate dehydrogenase. In the energy minimized structure of the ternary complex, the C-4 atom of NAD is in van der Waals' contact with the C-3 atom of the malate. A catalytic cycle involves hydride transfer between these two atoms.     

Roles of Tyr13 and Phe219 in the unique substrate specificity of pepsin B

Pepsin B is known to be distributed throughout mammalia, including carnivores. In this study, the proteolytic specificity of canine pepsin B was clarified with 2 protein substrates and 37 synthetic octapeptides and compared with that of human pepsin A. Pepsin B efficiently hydrolyzed gelatin but very poorly hydrolized hemoglobin. It was active against only a group of octapeptides with Gly at P2, such as KPAGF/LRL and KPEGF/LRL (arrows indicate cleavage sites). In contrast, pepsin A hydrolyzed hemoglobin but not gelatin and showed high activity against various types of octapeptides, such as KPAEF/FRL and KPAEF/LRL. The specificity of pepsin B is unique among pepsins, and thus, the enzyme provides a suitable model for analyzing the structure and function of pepsins and related aspartic proteinases. Because Tyr13 and Phe219 in/around the S2 subsites (Glu/Ala13 and Ser219 are common in most pepsins) appeared to be involved in the specificity of pepsin B, site-directed mutagenesis was undertaken to replace large aromatic residues with small residues and vice versa. The Tyr13Ala/Phe219Ser double mutant of pepsin B was found to demonstrate broad activity against hemoglobin and various octapeptides, whereas the reverse mutant of pepsin A had significantly decreased activity. According to molecular modeling of pepsin B, Tyr13 OH narrows the substrate-binding space and a peptide with Gly at P2 might be preferentially accommodated because of its high flexibility. The hydroxyl can also make a hydrogen bond with nitrogen of a P3 residue and fix the substrate main chain to the active site, thus restricting the flexibility of the main chain and strengthening preferential accommodation of Gly at P2. The phenyl moiety of Phe219 is bulky and narrows the S2 substrate space, which also leads to a preference for Gly at P2, while lowering the catalytic activity against other peptide types without making a hydrogen-bonding network in the active site.     

Crystal structure of porcine mitochondrial NADP+-dependent isocitrate dehydrogenase complexed with Mn2+ and isocitrate. Insights into the enzyme mechanism

The crystal structure of porcine heart mitochondrial NADP+-dependent isocitrate dehydrogenase (IDH) complexed with Mn2+ and isocitrate was solved to a resolution of 1.85 A. The enzyme was expressed in Escherichia coli, purified as a fusion protein with maltose binding protein, and cleaved with thrombin to yield homogeneous enzyme. The structure was determined by multiwavelength anomalous diffraction phasing using selenium substitution in the form of selenomethionine as the anomalous scatterer. The porcine NADP+-IDH enzyme is structurally compared with the previously solved structures of IDH from E. coli and Bacillus subtilis that share 16 and 17% identity, respectively, with the mammalian enzyme. The porcine enzyme has a protein fold similar to the bacterial IDH structures with each monomer folding into two domains. However, considerable differences exist between the bacterial and mammalian forms of IDH in regions connecting core secondary structure. Based on the alignment of sequence and structure among the porcine, E. coli, and B. subtilis IDH, a putative phosphorylation site has been identified for the mammalian enzyme. The active site, including the bound Mn2+-isocitrate complex, is highly ordered and, therefore, mechanistically informative. The consensus IDH mechanism predicts that the Mn2+-bound hydroxyl of isocitrate is deprotonated prior to its NADP+-dependent oxidation. The present crystal structure has an active site water that is well positioned to accept the proton and ultimately transfer the proton to solvent through an additional bound water.     

Oestrogen-induced expression of a novel liver-specific aspartic proteinase in Danio rerio (zebrafish)

Aspartic proteinases are a group of endoproteolytic proteinases active at acidic pH and characterized by the presence of two aspartyl residues in the active site. They include related paralogous proteins such as cathepsin D, cathepsin E and pepsin. Although extensively investigated in mammals, aspartic proteinases have been less studied in other vertebrates. In a previous work, we cloned and sequenced a DNA complementary to RNA encoding an enzyme present in zebrafish liver. The sequence resulted to be homologous to a novel form of aspartic proteinase firstly described by us in Antarctic fish. In zebrafish, the gene encoding this enzyme is expressed only in the female liver, in contrast with cathepsin D that is expressed in all the tissues examined independently of the sex. For this reason we have termed the new enzyme liver-specific aspartic proteinase (LAP).Northern blot analyses indicate that LAP gene expression is under hormonal control. Indeed, in oestrogen-treated male fish, cathepsin D expression was not enhanced in the various tissues examined, but the LAP gene product appeared exclusively in the liver. Our results provide evidence for an oestrogen-induced expression of LAP gene in liver. We postulate that the sexual dimorphic expression of the LAP gene may be related to the reproductive process.