The refined 2.15 A X-ray crystal structure of human liver cathepsin B: the structural basis for its specificity.

From the lysosomal cysteine proteinase cathepsin B, isolated from human liver in its two-chain form, monoclinic crystals were obtained which contain two molecules per asymmetric unit. The molecular structure was solved by a combination of Patterson search and heavy atom replacement methods (simultaneously with rat cathepsin B) and refined to a crystallographic R value of 0.164 using X-ray data to 2.15 A resolution. The overall folding pattern of cathepsin B and the arrangement of the active site residues are similar to the related cysteine proteinases papain, actinidin and calotropin DI. 166 alpha-carbon atoms out of 248 defined cathepsin B residues are topologically equivalent (with an r.m.s. deviation of 1.04 A) with alpha-carbon atoms of papain. However, several large insertion loops are accommodated on the molecular surface and modify its properties. The disulphide connectivities recently determined for bovine cathepsin B by chemical means were shown to be correct. Some of the primed subsites are occluded by a novel insertion loop, which seems to favour binding of peptide substrates with two residues carboxy-terminal to the scissile peptide bond; two histidine residues (His110 and His111) in this "occluding loop' provide positively charged anchors for the C-terminal carboxylate group of such polypeptide substrates. These structural features explain the well-known dipeptidyl carboxypeptidase activity of cathepsin B. The other subsites adjacent to the reactive site Cys29 are relatively similar to papain; Glu245 in the S2 subsite favours basic P2-side chains. The above mentioned histidine residues, but also the buried Glu171 might represent the group with a pKa of approximately 5.5 near the active site, which governs endo- and exopeptidase activity. The "occluding loop' does not allow cystatin-like protein inhibitors to bind to cathepsin B as they do to papain, consistent with the reduced affinity of these protein inhibitors for cathepsin B compared with the related plant enzymes.     

An enormously active and selective azapeptide inhibitor of cathepsin B.

The peptidomimetic Z-Arg-Leu-Arg-Agly-Ile-Val-OMe (where Agly means alpha-aza-glycyl, -NHNHCO-) is the strongest (K(i) = 480 pM) and the most selective inhibitor of cathepsin B to date, being approximately 2310 times as active to cathepsin B as to cathepsin K. In this paper we introduce the peptide and seek to rationalize its structure-activity relationships using molecular dynamics (MD) and NMR. It is shown that the -Agly-moiety restrains the peptide backbone to a bent shape, contrary to its parent peptide (with Gly in position 4), having its backbone extended and flexible. This fold is maintained in the plug covalently bound to the cathepsin B Cys29, in compliance with similar bends already observed in two other azapeptides attached to the active sites of cathepsin B. The MD simulation of the Z-Arg-Leu-Arg-Agly approximately cathepsin B complex suggests that, contrary to other potent inhibitors of cathepsin B, the current double Arg(1)/Arg(3) inhibitor, while maintaining the fold is able to form a unique ion cluster involving both Arg residues on the inhibitor part and two acidic Glu171 and Glu245 on the cathepsin B part, thus enhancing the affinity and subsequently the inhibiting power and selectivity of Z-Arg-Leu-Arg-Agly-Ile-Val-OMe to the observed extreme extent.     

The amino acid sequence of human chorionic gonadotropin. The alpha subunit and beta subunit.

The amino acid sequences of both the alpha and beta subunits of human chorionic gonadotropin have been determined. The amino acid sequence of the alpha subunit is: Ala - Asp - Val - Gln - Asp - Cys - Pro - Glu - Cys-10 - Thr - Leu - Gln - Asp - Pro - Phe - Ser - Gln-20 - Pro - Gly - Ala - Pro - Ile - Leu - Gln - Cys - Met - Gly-30 - Cys - Cys - Phe - Ser - Arg - Ala - Tyr - Pro - Thr - Pro-40 - Leu - Arg - Ser - Lys - Lys - Thr - Met - Leu - Val - Gln-50 - Lys - Asn - Val - Thr - Ser - Glu - Ser - Thr - Cys - Cys-60 - Val - Ala - Lys - Ser - Thr - Asn - Arg - Val - Thr - Val-70 - Met - Gly - Gly - Phe - Lys - Val - Glu - Asn - His - Thr-80 - Ala - Cys - His - Cys - Ser - Thr - Cys - Tyr - Tyr - His-90 - Lys - Ser. Oligosaccharide side chains are attached at residues 52 and 78. In the preparations studied approximately 10 and 30% of the chains lack the initial 2 and 3 NH2-terminal residues, respectively. This sequence is almost identical with that of human luteinizing hormone (Sairam, M. R., Papkoff, H., and Li, C. H. (1972) Biochem. Biophys. Res. Commun. 48, 530-537). The amino acid sequence of the beta subunit is: Ser - Lys - Glu - Pro - Leu - Arg - Pro - Arg - Cys - Arg-10 - Pro - Ile - Asn - Ala - Thr - Leu - Ala - Val - Glu - Lys-20 - Glu - Gly - Cys - Pro - Val - Cys - Ile - Thr - Val - Asn-30 - Thr - Thr - Ile - Cys - Ala - Gly - Tyr - Cys - Pro - Thr-40 - Met - Thr - Arg - Val - Leu - Gln - Gly - Val - Leu - Pro-50 - Ala - Leu - Pro - Gin - Val - Val - Cys - Asn - Tyr - Arg-60 - Asp - Val - Arg - Phe - Glu - Ser - Ile - Arg - Leu - Pro-70 - Gly - Cys - Pro - Arg - Gly - Val - Asn - Pro - Val - Val-80 - Ser - Tyr - Ala - Val - Ala - Leu - Ser - Cys - Gln - Cys-90 - Ala - Leu - Cys - Arg - Arg - Ser - Thr - Thr - Asp - Cys-100 - Gly - Gly - Pro - Lys - Asp - His - Pro - Leu - Thr - Cys-110 - Asp - Asp - Pro - Arg - Phe - Gln - Asp - Ser - Ser - Ser - Ser - Lys - Ala - Pro - Pro - Pro - Ser - Leu - Pro - Ser-130 - Pro - Ser - Arg - Leu - Pro - Gly - Pro - Ser - Asp - Thr-140 - Pro - Ile - Leu - Pro - Gln. Oligosaccharide side chains are found at residues 13, 30, 121, 127, 132, and 138. The proteolytic enzyme, thrombin, which appears to cleave a limited number of arginyl bonds, proved helpful in the determination of the beta sequence.     

Characterization of the iron- and 2-oxoglutarate-binding sites of human prolyl 4-hydroxylase.

Prolyl 4-hydroxylase (EC 1.14.11.2), an alpha2beta2 tetramer, catalyzes the formation of 4-hydroxyproline in collagens. We converted 16 residues in the human alpha subunit individually to other amino acids, and expressed the mutant polypeptides together with the wild-type beta subunit in insect cells. Asp414Ala and Asp414Asn inactivated the enzyme completely, whereas Asp414Glu increased the K(m) for Fe2+ 15-fold and that for 2-oxoglutarate 5-fold. His412Glu, His483Glu and His483Arg inactivated the tetramer completely, as did Lys493Ala and Lys493His, whereas Lys493Arg increased the K(m) for 2-oxoglutarate 15-fold. His501Arg, His501Lys, His501Asn and His501Gln reduced the enzyme activity by 85-95%; all these mutations increased the K(m) for 2-oxoglutarate 2- to 3-fold and enhanced the rate of uncoupled decarboxylation of 2-oxoglutarate as a percentage of the rate of the complete reaction up to 12-fold. These and other data indicate that His412, Asp414 and His483 provide the three ligands required for the binding of Fe2+ to a catalytic site, while Lys493 provides the residue required for binding of the C-5 carboxyl group of 2-oxoglutarate. His501 is an additional critical residue at the catalytic site, probably being involved in both the binding of the C-1 carboxyl group of 2-oxoglutarate and the decarboxylation of this cosubstrate.     

Binding studies with mutants of Zif268. Contribution of individual side chains to binding affinity and specificity in the Zif268 zinc finger-DNA complex.

The Zif268 zinc finger-DNA complex has served as a model system for understanding how Cys2His2 type zinc fingers recognize DNA. Structural studies of the Zif268-DNA complex revealed that residues at four positions in the alpha helix of each zinc finger play key roles in recognition, but there has been no information about the precise contributions of individual residues. Here we report the results of binding studies involving five mutants of Zif268 that have changes in the base-contacting residues of finger one. These studies let us evaluate the contributions that Arg18 (position -1 of the alpha helix), Asp20 (position 2), Glu21 (position 3), and Arg24 (position 6) make to the overall energy of DNA binding. Our results confirm the important role played by these arginines. By comparing the affinities of the wild type and mutant peptides for various sites, we also prove that Asp20 and Glu21 play important roles in determining binding site specificity.     

Proximity between Glu126 and Arg144 in the lactose permease of Escherichia coli.

Evidence has been presented [Venkatesan, P., and Kaback, H. R. (1998) Proc. Natl. Acad. Sci. U.S.A. 95, 9802-9807] that Glu126 (helix IV) and Arg144 (helix V) which are critical for substrate binding in the lactose permease of Escherichia coli are charge paired and therefore in close proximity. To test this conclusion more directly, three different site-directed spectroscopic techniques were applied to permease mutants in which Glu126 and/or Arg144 were replaced with either His or Cys residues. (1) Glu126-->His/Arg144-->His permease containing a biotin acceptor domain was purified by monomeric avidin affinity chromatography, and Mn(II) binding was assessed by electron paramagnetic resonance spectroscopy. The mutant protein binds Mn(II) with a KD of about 40 microM at pH 7.5, while no binding is observed at pH 5.5. In addition, no binding is detected with Glu126-->His or Arg144-->His permease. (2) Permease with Glu126-->Cys/Arg144-->Cys and a biotin acceptor domain was purified, labeled with a thiol-specific nitroxide spin-label, and shown to exhibit spin-spin interactions in the frozen state after reconstitution into proteoliposomes. (3) Glu126-->Cys/Arg144-->Cys permease with a biotin acceptor domain was purified and labeled with a thiol-specific pyrene derivative, and fluorescence spectra were obtained after reconstitution into lipid bilayers. An excimer band is observed with the reconstituted E126C/R144C mutant, but not with either single-Cys mutant or when the single-Cys mutants are mixed prior to reconstitution. The results provide strong support for the conclusion that Glu126 (helix IV) and Arg144 (helix V) are in close physical proximity.     

Fluorogenic peptide substrates for carboxydipeptidase activity of cathepsin B

Cathepsin B is a lysosomal cysteine protease exhibiting mainly dipeptidyl carboxypeptidase activity, which decreases dramatically above pH 5.5, when the enzyme starts acting as an endopeptidase. Since the common cathepsin B assays are performed at pH 6 and do not distinguish between these activities, we synthesized a series of peptide substrates specifically designed for the carboxydipeptidase activity of cathepsin B. The amino-acid sequences of the P(5)-P(1) part of these substrates were based on the binding fragments of cystatin C and cystatin SA, the natural reversible inhibitors of papain-like cysteine protease. The sequences of the P'(1)-P'(2) dipeptide fragments of the substrates were chosen on the basis of the specificity of the S'(1)-S'(2) sites of the cathepsin B catalytic cleft. The rates of hydrolysis by cathepsin B and papain, the archetypal cysteine protease, were monitored by a continuous fluorescence assay based on internal resonance energy transfer from an Edans to a Dabcyl group. The fluorescence energy donor and acceptor were attached to the C- and the N-terminal amino-acid residues, respectively. The kinetics of hydrolysis followed the Michaelis-Menten model. Out of all the examined peptides Dabcyl-R-L-V-G-F- E(Edans) turned out to be a very good substrate for both papain and cathepsin B at both pH 6 and pH 5. The replacement of Glu by Asp turned this peptide into an exclusive substrate for cathepsin B not hydrolyzed by papain. The substitution of Phe by Nal in the original substrate caused an increase of the specificity constant for cathepsin B at pH 5, and a significant decrease at pH 6. The results of kinetic studies also suggest that Arg in position P(4) is not important for the exopeptidase activity of cathepsin B, and that introducing Glu in place of Val in position P(2) causes an increase of the substrate preference towards this activity.     

The primary structure of the COOH-terminal half of cholera toxin subunit A1 containing the ADP-ribosylation site

The sequence of 96 amino acid residues from the COOH-terminus of the active subunit of cholera toxin, A₁, has been determined as PheAsnValAsnAspVal LeuGlyAlaTyrAlaProHisProAsxGluGlu GluValSerAlaLeuGlyGly IleProTyrSerGluIleTyrGlyTrpTyrArg ValHisPheGlyValLeuAsp GluGluLeuHisArgGlyTyrArgAspArgTyr TyrSerAsnLeuAspIleAla ProAlaAlaAspGlyTyrGlyLeuAlaGlyPhe ProProGluHisArgAlaTrp ArgGluGluProTrpIleHisHisAlaPro ProGlyCysGlyAsnAlaProArg(OH). This is the largest fragment obtained by BrCN cleavage of the subunit A₁ (M_r 23,000), and has previously been indicated to contain the active site for the adenylate cyclase-stimulating activity. Unequivocal identification of the COOH-terminal structure was achieved by separation and analysis of the terminal peptide after the specific chemical cleavage at the only cysteine residue in A₁ polypeptide. The site of self ADP-ribosylation in the A₁ subunit [C. Y. Lai, Q.-C. Xia, and P. T. Salotra (1983) Biochem. Biophys. Res. Commun.116, 341–348] has now been identified as Arg-50 of this peptide, 46 residues removed from the COOH-terminus. The cysteine that forms disulfide bridge to A₂ subunit in the holotoxin is at position 91.     

Carboxy-monopeptidase substrate specificity of human cathepsin X

Cathepsin X is a papain-like cysteine protease with restricted positional specificity, acting primarily as a carboxy-monopeptidase. We mapped the specificities at the S2, S1, and S1' subsites of human cathepsin X by systematically and independently substituting the P2, P1, and P1' positions of the carboxy-monopeptidase substrate Abz-FRF(4NO(2)) with natural amino acids. Human cathepsin X has broad S2, S1, and S1' specificities within two orders of magnitude in k(cat)/K(M), excluding proline that is not tolerated at these subsites. Glycine is not favored in S2, but is among the preferred residues in S1 and S1', which highlights S2 as the affinity-determinant subsite. The presence of peculiar residues at several binding site positions (Asp76, His234, Asn75, and Glu72) does not translate into a markedly different sequence specificity profile relative to other human cathepsins. These findings suggest that a specific function of human cathepsin X is unlikely to result from sequence specificity, but rather from a combination of its unique positional specificity and the co-localization of enzyme and substrate in a specific cellular environment.     

Manipulating conformational equilibria in the lactose permease of Escherichia coli.

A mechanism proposed for lactose/H(+) symport by the lactose permease of Escherichia coli indicates that lactose permease is protonated prior to ligand binding. Moreover, in the ground state, the symported H(+) is shared between His322 (helix X) and Glu269 (helix VIII), while Glu325 (helix X) is charge-paired with Arg302 (helix IX). Substrate binding at the outer surface between helices IV (Glu126) and V (Arg144, Cys148) induces a conformational change that leads to transfer of the H(+) to Glu325 and reorientation of the binding site to the inner surface. After release of substrate, Glu325 is deprotonated on the inside due to re-juxtapositioning with Arg302. The conservative mutation Glu269-->Asp causes a 50-100-fold decrease in substrate binding affinity and markedly reduced active lactose transport, as well as decreased rates of equilibrium exchange and efflux. Gly-scanning mutagenesis of helix VIII was employed systematically with mutant Glu269-->Asp in an attempt to rescue function, and two mutants with increased activity are identified and characterized. Mutant Thr266-->Gly/Met267-->Gly/Glu269-->Asp binds ligand with increased affinity and catalyzes active lactose transport with a marked increase in rate; however, little improvement in efflux or equilibrium exchange is observed. In contrast, mutant Gly262-->Ala/Glu269-->Asp exhibits no improvement in ligand binding but a small increase in the rate of active transport; however, an increase in the steady-state level of accumulation, as well as efflux and equilibrium exchange is observed. Remarkably, when the two sets of mutations are combined, all translocation reactions are rescued to levels approximating those of wild-type permease. The findings support the contention that Glu269 plays a pivotal role in the mechanism of lactose/H(+) symport. Moreover, the results suggest that the two classes of mutants rescue activity by altering the equilibrium between outwardly and inwardly facing conformations of the permease such that impaired protonation and/or H(+) transfer is enhanced from one side of the membrane or the other. When the two sets of mutants are combined, the equilibrium between outwardly and inwardly facing conformations and thus protonation and H(+) transfer are restored.     

Amino acid sequence of a protease inhibitor isolated from Sarcophaga bullata determined by mass spectrometry.

The amino acid sequence of a protease inhibitor isolated from the hemolymph of Sarcophaga bullata larvae was determined by tandem mass spectrometry. Homology considerations with respect to other protease inhibitors with known primary structures assisted in the choice of the procedure followed in the sequence determination and in the alignment of the various peptides obtained from specific chemical cleavage at cysteines and enzyme digests of the S. bullata protease inhibitor. The resulting sequence of 57 residues is as follows: Val Asp Lys Ser Ala Cys Leu Gln Pro Lys Glu Val Gly Pro Cys Arg Lys Ser Asp Phe Val Phe Phe Tyr Asn Ala Asp Thr Lys Ala Cys Glu Glu Phe Leu Tyr Gly Gly Cys Arg Gly Asn Asp Asn Arg Phe Asn Thr Lys Glu Glu Cys Glu Lys Leu Cys Leu.     

Studies on the aminopeptidase activity of rat cathepsin H.

Three synthetic substrates H-Arg-NH-Mec, Bz-Arg-NH-Mec and H-Cit-NH-Mec (Bz, Benzoyl; NH-Mec, 4-methylcoumaryl-7-amide; Cit, citrulline) were used to characterize specificity requirements for the P1-S1 interaction of cathepsin H from rat liver. From rapid equilibrium kinetic studies it was shown that Km, kcat and the specificity constants kcat/Km are quite similar for substrates with a free alpha-amino group. In contrast, a 25-fold decrease of kcat/Km was observed for the N-terminal-blocked substrate Bz-Arg-NH-Mec. The activation energies for H-Arg-NH-Mec and Bz-Arg-NH-Mec were determined to be 37 kJ/mol and 55 kJ/mol, respectively, and the incremental binding energy delta delta Gb of the charged alpha-amino group was estimated to -8.1 kJ/mol at pH 6.8. The shown preference of cathepsin H for the unblocked substrates H-Arg-NH-Mec and H-Cit-NH-Mec was further investigated by inspection of the pH dependence of kcat/Km. The curves of the two substrates with a charged alpha-amino group showed identical bell-shaped profiles which both exhibit pKa1 and pKa2 values of 5.5 and 7.4, respectively, at 30 degrees C. The residue with a pKa1 of 5.5 in the acid limb of the activity profile of H-Arg-NH-Mec was identified by its ionization enthalpy delta Hion = 21 kJ/mol as a beta-carboxylate or gamma-carboxylate of the enzyme, whereas the residue with a pKa2 of 7.4 was assigned to the free alpha-amino group of the substrate with a delta Hion of 59 kJ/mol. Bz-Arg-NH-Mec showed a different pH-activity profile with a pKa1 of 5.4 and a pKa2 of 6.6 at 30 degrees C. Cathepsin H exhibits no preference for a basic P1 side chain as has been shown by the similar kinetics of H-Arg-NH-Mec and the uncharged, isosteric substrate H-Cit-NH-Mec. In summary, specific interactions of an anionic cathepsin H active site residue with the charged alpha-amino group of substrates caused transition state stabilization which proves the enzyme to act preferentially as an aminopeptidase.     

Multiple proteolytic action of rat liver cathepsin B: specificities and pH-dependences of the endo- and exopeptidase activities.

Dipeptidylcarboxypeptidase, endopeptidase, and carboxypeptidase activities of rat liver cathepsin B were investigated using soluble denatured protein substrates, reduced and S-(3-trimethylammonio)propylated proteins and their derivatives. It was found that the soluble denatured proteins were degraded mainly by the dipeptidylcarboxypeptidase activity and in a few cases by the endopeptidase and carboxypeptidase activities. The eipeptidylcarboxypeptidase activity showed broad substrate specificity with broad pH optimum at 4-6. A peptide having the alpha-carboxyl group amidated with methylamine could also be a good substrate for this activity. These results suggest that this activity is dependent not upon the dissociated alpha-carboxyl group at the P2' site but upon the hydrogen-bonding abilities of the alpha-imino moiety and the protonated or amidated alpha-carboxyl moiety at P2'. On the other hand, the endopeptidase and carboxypeptidase activities were observed in a few cases, suggesting that special amino acid sequences in the substrates are responsible for these activities. These activities showed sharp pH optima at 6 and seemed to prefer basic amino acid residues at P1 site. Therefore, we suppose that cathepsin B has a carboxyl group with a pKa of about 5.5 at the S1 subsite which more effectively interacts with a positive charge at the P1 site of the substrate at pH 6 than at pH 5. Based on these results, a model of the binding subsites of this enzyme is proposed.     

从织锦芋螺中克隆α芋螺毒素序列

为了从我国南海产织锦芋螺（Ｃｏｎｕｓｔｅｘｔｉｌｅ）中分离新的毒素序列并研究其应用价值,进行了织锦芋螺毒素基因的分离工作．从织锦芋螺毒管中提取ｍＲＮＡ,以Ａ族芋螺毒素的信号肽编码部分和３′端非翻译部分的保守序列为引物,通过ＲＴ－ＰＣＲ扩增和序列分析方法获得新的芋螺毒素序列．结果得到两种不同的α芋螺毒素序列,两者都属于α４／７亚型芋螺毒素,预测其成熟肽序列分别为Ｐｒｏ－Ｇｌｕ－Ｃｙｓ－Ｃｙｓ－Ｓｅｒ－Ａｓｐ－Ｐｒｏ－Ａｒｇ－Ｃｙｓ－Ａｓｎ－Ｓｅｒ－Ｓｅｒ－Ｈｉｓ－Ｐｒｏ－Ｇｌｕ－Ｌｅｕ－Ｃｙｓ－Ｇｌｙ（Ｃ端Ｇｌｙ可能被酰胺化）和Ｐｒｏ－Ｇｌｕ－Ｃｙｓ－Ｃｙｓ－Ｓｅｒ－Ｈｉｓ－Ｐｒｏ－Ａｌａ－Ｃｙｓ－Ａｓｎ－Ｖａｌ－Ａｓｐ－Ｈｉｓ－Ｐｒｏ－Ｇｌｕ－Ｉｌｅ－Ｃｙｓ－Ａｒｇ．采用传统的生化分离手段尚未从织锦芋螺中获得过α芋螺毒素序列,这两种α芋螺毒素作用的种属特异性、受体类型特异性和在小细胞肺癌的诊断和治疗中的应用价值有待进一步研究     

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.     

The primary structure of the β-subunit of protocatechuate 3,4-dioxygenase from Pseudomonas aeruginosa

The complete amino acid sequence of the β-subunit of protocatechuate 3,4-dioxygenase was determined. The β-subunit contained four methionine residues. Thus, five peptides were obtained after cleavage of the carboxymethylated β-subunit with cyanogen bromide, and were isolated on Sephadex G-75 column chromatography. The amino acid sequences of the cyanogen bromide peptides were established by characterization of the peptides obtained after digestion with trypsin, chymotrypsin, thermolysin, or Staphylococcus aureus protease. The major sequencing techniques used were automated and manual Edman degradations. The five cyanogen bromide peptides were aligned by means of the amino acid sequences of the peptides containing methionine purified from the tryptic hydrolysate of the carboxymethylated β-subunit. The amino acid sequence of all the 238 residues was as follows: ProAlaGlnAspAsnSerArgPheValIleArgAsp ArgAsnTrpHis ProLysAlaLeuThrPro-Asp — TyrLysThrSerIleAlaArg SerProArgGlnAla LeuValSerIleProGlnSer — IleSerGluThrThrGly ProAsnPheSerHisLeu GlyPheGlyAlaHisAsp-His — AspLeuLeuLeuAsnPheAsn AsnGlyGlyLeu ProIleGlyGluArgIle-Ile — ValAlaGlyArgValValAsp GlnTyrGlyLysPro ValProAsnThrLeuValGluMet — TrpGlnAlaAsnAla GlyGlyArgTyrArg HisLysAsnAspArgTyrLeuAlaPro — LeuAspProAsn PheGlyGlyValGly ArgCysLeuThrAspSerAspGlyTyrTyr — SerPheArg ThrIleLysProGlyPro TyrProTrpArgAsnGlyProAsnAsp — TrpArgProAla HisIleHisPheGlyIle SerGlyProSerIleAlaThr-Lys — LeuIleThrGlnLeuTyr PheGluGlyAspPro LeuIleProMetCysProIleVal — LysSerIleAlaAsn ProGluAlaValGlnGln LeuIleAlaLysLeuAspMetAsnAsn — AlaAsnProMet AsnCysLeuAlaTyr ArgPheAspIleValLeuArgGlyGlnArgLysThrHis PheGluAsnCys. The sequence published earlier in summary form (Iwaki et al., 1979, J. Biochem.86, 1159–1162) contained a few errors which are pointed out in this paper.     

The active site architecture of Pisum sativum beta-carbonic anhydrase is a mirror image of that of alpha-carbonic anhydrases

We have determined the structure of the beta-carbonic anhydrase from the dicotyledonous plant Pisum sativum at 1.93 A resolution, using a combination of multiple anomalous scattering off the active site zinc ion and non-crystallographic symmetry averaging. The mol- ecule assembles as an octamer with a novel dimer of dimers of dimers arrangement. Two distinct patterns of conservation of active site residues are observed, implying two potentially mechanistically distinct classes of beta-carbonic anhydrases. The active site is located at the interface between two monomers, with Cys160, His220 and Cys223 binding the catalytic zinc ion and residues Asp162 (oriented by Arg164), Gly224, Gln151, Val184, Phe179 and Tyr205 interacting with the substrate analogue, acetic acid. The substrate binding groups have a one to one correspondence with the functional groups in the alpha-carbonic anhydrase active site, with the corresponding residues being closely superimposable by a mirror plane. Therefore, despite differing folds, alpha- and beta-carbonic anhydrase have converged upon a very similar active site design and are likely to share a common mechanism.     

Probing the sweet determinants of brazzein: wild-type brazzein and a tasteless variant, brazzein-ins(R18a-I18b), exhibit different pH-dependent NMR chemical shifts

Brazzein is a small, intensely sweet protein. As a probe of the functional properties of its solvent-exposed loop, two residues (Arg-Ile) were inserted between Leu18 and Ala19 of brazzein. Psychophysical testing demonstrated that this mutant is totally tasteless. NMR chemical shift mapping of differences between this mutant and brazzein indicated that residues affected by the insertion are localized to the mutated loop, the region of the single alpha-helix, and around the Cys16-Cys37 disulfide bond. Residues unaffected by this mutation included those near the C-terminus and in the loop connecting the alpha-helix and the second beta-strand. In particular, several residues of brazzein previously shown to be essential for its sweetness (His31, Arg33, Glu41, Arg43, Asp50, and Tyr54) exhibited negligible chemical shift changes. Moreover, the pH dependence of the chemical shifts of His31, Glu41, Asp50, and Tyr54 were unaltered by the insertion. The insertion led to large chemical shift and pKa perturbation of Glu36, a residue shown previously to be important for brazzein's sweetness. These results serve to refine the known sweetness determinants of brazzein and lend further support to the idea that the protein interacts with a sweet-taste receptor through a multi-site interaction mechanism, as has been postulated for brazzein and other sweet proteins (monellin and thaumatin).     

The occluding loop in cathepsin B defines the pH dependence of inhibition by its propeptide

Papain-like proenzymes are prone to autoprocess under acidic pH conditions. Similarly, peptides derived from the proregion of cathepsin B are potent pH-dependent inhibitors of that enzyme; i.e., at pH 6.0 the inhibition of human cathepsin B by its propeptide is defined by slow binding kinetics with a Ki of 3.7 nM and at pH 4.0 by classical kinetics with a Ki of 82 nM. This pH dependency is essentially eliminated either by the removal of a portion of the enzyme's occluding loop through deletion mutagenesis or by the mutation of either residue Asp22 or His110 to alanine; e.g., the mutant enzyme His110Ala is inhibited by its propeptide with Ki's of 2.0 +/- 0.3 nM at pH 4.0 and 1.1 +/- 0.2 nM at pH 6.0. For the His110Ala mutant the inhibition also displays slow binding kinetics at both pH 4.0 and pH 6.0. As shown by the crystal structure of mature cathepsin B [Musil, D., et al. (1991) EMBO J. 10, 2321-2330] Asp22 and His110 form a salt bridge in the mature enzyme, and it has been shown that this bridge stabilizes the occluding loop in its closed position [N?gler, D. K., et al. (1997) Biochemistry 36, 12608-12615]. Thus the pH dependency of propeptide binding can be explained on the basis of a competitive binding between the occluding loop and the propeptide. At low pH, when the Asp22-His110 pair forms a salt bridge stabilizing the occluding loop in its closed conformation, the loop more effectively competes with the propeptide than at higher pH where deprotonation of His110 and the concomitant destruction of the Asp22-His110 salt bridge results in a destabilization of the closed form of the loop. The rate of autocatalytic processing of procathepsin B to cathepsin B correlates with the affinity of the enzyme for its propeptide rather than with its catalytic activity, thus suggesting a possible influence of occluding loop stability on the rate of processing.     

Crystallographic and kinetic investigations on the mechanism of 6-pyruvoyl tetrahydropterin synthase

The enzyme 6-pyruvoyl tetrahydropterin synthase (PTPS) catalyses the second step in the de novo biosynthesis of tetrahydrobiopterin, the conversion of dihydroneopterin triphosphate to 6-pyruvoyl tetrahydropterin. The Zn and Mg-dependent reaction includes a triphosphate elimination, a stereospecific reduction of the N5-C6 double bond and the oxidation of both side-chain hydroxyl groups. The crystal structure of the inactive mutant Cys42Ala of PTPS in complex with its natural substrate dihydroneopterinetriphosphate was determined at 1.9 A resolution. Additionally, the uncomplexed enzyme was refined to 2.0 A resolution. The active site of PTPS consists of the pterin-anchoring Glu A107 neighboured by two catalytic motifs: a Zn(II) binding site and an intersubunit catalytic triad formed by Cys A42, Asp B88 and His B89. In the free enzyme the Zn(II) is in tetravalent co-ordination with three histidine ligands and a water molecule. In the complex the water is replaced by the two substrate side-chain hydroxyl groups yielding a penta-co-ordinated Zn(II) ion. The Zn(II) ion plays a crucial role in catalysis. It activates the protons of the substrate, stabilizes the intermediates and disfavours the breaking of the C1'C2' bond in the pyruvoyl side-chain. Cys A42 is activated by His B89 and Asp B88 for proton abstraction from the two different substrate side-chain atoms C1', and C2'. Replacing Ala A42 in the mutant structure by the wild-type Cys by modelling shows that the C1' and C2' substrate side-chain protons are at equal distances to Cys A42 Sgamma. The basicity of Cys A42 may be increased by a catalytic triad His B89 and Asp B88. The active site of PTPS seems to be optimised to carry out proton abstractions from two different side-chain C1' and C2' atoms, with no obvious preference for one of them. Kinetic studies with dihydroneopterin monophosphate reveal that the triphosphate moiety of the substrate is necessary for enzyme specifity.