Flexibility of the coordination geometry around the cupric ions in Cu(II)-rat dipeptidyl peptidase III is important for the expression of enzyme activity.

Dipeptidyl peptidase III (DPP III), the zinc peptidase, has a unique helix portion in the metal-binding motif (HELLGH). The enzyme activity of the cupric derivative of rat DPP III (Cu(II)-rat DPP III) for Lys-Ala-ß-NA is about 30% of that of the wild-type enzyme. On the other hand, the enzyme activity of Cu(II)-rat del-DPP III, in which Leu453 is deleted from the metal-binding motif, possesses only 1-2% of the enzyme activity of rat del-DPP III. The EPR spectra of Cu(II)-rat DPP III in the presence of various concentrations of the substrate, Lys-Ala-ß-NA, changed dramatically, showing formation of the enzyme-metal-substrate complex. The EPR spectra of Cu(II)-rat del-DPP III did not change in the presence of excess Lys-Ala-ß-NA. The deletion of Leu453 from the HELLGH motif of rat DPP III leads to a complete loss of flexibility in the ligand geometry around the cupric ions. Under the formation of the enzyme-metal-substrate complex, Glu451 of Cu(II)-rat DPP III is sufficiently able to approach the water molecule via a very different orientation from that of the resting state; however, Glu451 of Cu(II)-rat del-DPP III is not able to access the water molecule.

Metal preferences of zinc-binding motif on metalloproteases.

Almost all naturally occurring metalloproteases are monozinc enzymes. The zinc in any number of zinc metalloproteases has been substituted by some other divalent cation. Almost all Co(II)- or Mn(II)-substituted enzymes maintain the catalytic activity of their zinc counterparts. However, in the case of Cu(II) substitution of zinc proteases, a great number of enzymes are not active, for example, thermolysin, carboxypeptidase A, endopeptidase from Lactococcus lactis, or aminopeptidase B, while some do have catalytic activity, for example, astacin (37%) and DPP III (100%). Based on structural studies of various metal-substituted enzymes, for example, thermolysin, astacin, aminopeptidase B, dipeptidyl peptidase (DPP) III, and del-DPP III, the metal coordination geometries of both active and inactive Cu(II)-substituted enzymes are shown to be the same as those of the wild-type Zn(II) enzymes. Therefore, the enzyme activity of a copper-ion-substituted zinc metalloprotease may depend on the flexibility of catalytic domain.

In rat dipeptidyl peptidase III, His568 is essential for catalysis, and Glu5°7 or Glu5¹² stabilizes the coordination bond between His455 or His45° and zinc ion.

Dipeptidyl peptidase (DPP) III is a zinc-dependent exopeptidase that has a unique motif, "HELLGH," as the zinc-binding site. In the present study, a three-dimensional (3D) model of rat DPP III was generated with the X-ray crystal structure of human DPP III (PDB: 3FVY [Dobrovetsky E. et al. (2009) SGC]) as a template. The replacement of the seven charged amino acid residues with a hydrophobic amino acid around the zinc ion did not cause any significant changes in K(m) values or in the substrate specificity. However, the k(cat) values of H568R and H568Y were remarkably reduced, by factors of 50 and 400, respectively. The His568 residue of rat DPP III is essential for enzyme catalysis. The k(cat) values of the mutants E507A and E512A were 2.38 and 3.88 s⁻¹ toward Arg-Arg-NA, and 0.097 and 0.59 s⁻¹ toward Phe-Arg-NA, respectively. These values were markedly lower than those of the wild-type DPP III. Furthermore, the zinc contents of E507A and E512A were 0.29 and 0.08 atom per mol of protein, respectively, and those mutations caused remarkable increases in the dissociation constants of the zinc ions from DPP III by factors of 5 x 10³ to 2 x 104. The 3D model of the catalytic domain of rat DPP III showed that the carboxyl oxygen atoms of Glu5°7 and Glu5¹² form the hydrogen bonds to the nitrogen atoms of His455 and His45°. All of these results showed that Glu5°7 or Glu5¹² stabilizes the coordination bond between the zinc ion and His455 or His45°.

Characterization of the metal-binding site in aminopeptidase B.

A recombinant rat aminopeptidase-B (Ap-B) was expressed as a glutathione S-transferase (GST) fusion protein in Escherichia coli BL21 harboring a plasmid pGEX-Ap-B and was purified by glutathione-Sepharose 4B and Q-Sepharose columns. The metal-substituted derivatives of Ap-B, Co(II)- and Cu(II)-Ap-B contain almost 1 mole of cobalt(II) and copper(II) ions per enzyme molecule, respectively. The specific activity of Co(II)-Ap-B is very similar to that of recombinant Ap-B but that of Cu(II)-Ap-B is very low. The dissociation constants of the zinc ions of recombinant Ap-B and of the cobalt ions of Co(II)-Ap-B calculated from the relationships between the free metal ions and the residual enzyme activities are 3.7(+/-1.0)x10(-13) and 4.7(+/-1.0)x10(-12) M, respectively. The EPR parameters (gperpendicular), g// and A//) of Cu(II)-Ap-B were 2.06, 2.27, and 156x10(-4) cm-1. The A// value and the g// of Cu(II)-Ap-B are very similar to those of Cu(II)-thermolysin or Cu(II)-dipeptidyl peptidase III, in which the coordination geometry is a distorted tetrahedral.

Aspartic acid 405 contributes to the substrate specificity of aminopeptidase B.

Aminopeptidase B (EC 3.4.11.6, ApB) specifically cleaves in vitro the N-terminal Arg or Lys residue from peptides and synthetic derivatives. Ap B was shown to have a consensus sequence found in the metallopeptidase family. We determined the putative zinc binding residues (His324, His328, and Glu347) and the essential Glu325 residue for the enzyme using site-directed mutagenesis (Fukasawa, K. M., et al. (1999) Biochem. J. 339, 497-502). To identify the residues binding to the amino-terminal basic amino acid of the substrate, rat cDNA encoding ApB was cloned into pGEX-4T-3 so that recombinant protein was expressed as a GST fusion protein. Twelve acidic amino acid residues (Glu or Asp) in ApB were replaced with a Gln or Asn using site-directed mutagenesis. These mutants were isolated to characterize the kinetic parameters of enzyme activity toward Arg-NA and compare them to those of the wild-type ApB. The catalytic efficiency (kcat/Km) of the mutant D405N was 1.7 x 10(4) M(-1) s(-1), markedly decreased compared with that of the wild-type ApB (6.2 x 10(5) M(-1) s(-1)). The replacement of Asp405 with an Asn residue resulted in the change of substrate specificity such that the specific activity of the mutant D405N toward Lys-NA was twice that toward Arg-NA (in the case of wild-type ApB; 0.4). Moreover, when Asp405 was replaced with an Ala residue, the kcat/Km ratio was 1000-fold lower than that of the wild-type ApB for hydrolysis of Arg-NA; in contrast, in the hydrolysis of Tyr-NA, the kcat/Km ratios of the wild-type (1.1 x 10(4) M(-1) s(-1)) and the mutated (8.2 x 10(3) M(-1) s(-1)) enzymes were similar. Furthermore, the replacement of Asp-405 with a Glu residue led to the reduction of the kcat/Km ratio for the hydrolysis of Arg-NA by a factor of 6 and an increase of that for the hydrolysis of Lys-NA. Then the kcat/Km ratio of the D405E mutant for the hydrolysis of Lys-NA was higher than that for the hydrolysis of Arg-NA as opposed to that of wild-type ApB. These data strongly suggest that the Asp 405 residue is involved in substrate binding via an interaction with the P1 amino group of the substrate's side chain.

Identification and characterization of two dipeptidyl-peptidase III isoforms in Drosophila melanogaster.

Dipeptidyl-peptidase III (DPP III) hydrolyses small peptides with a broad substrate specificity. It is thought to be involved in a major degradation pathway of the insect neuropeptide proctolin. We report the purification and characterization of a soluble DPP III from 40 g Drosophila melanogaster. Western blot analysis with anti-(DPP III) serum revealed the purification of two proteins of molecular mass 89 and 82 kDa. MS/MS analysis of these proteins resulted in the sequencing of 45 and 41 peptide fragments, respectively, confirming approximately 60% of both annotated D. melanogaster DPP III isoforms (CG7415-PC and CG7415-PB) predicted at 89 and 82 kDa. Sequencing also revealed the specific catalytic domain HELLGH in both isoforms, indicating that they are both effective in degrading small peptides. In addition, with a probe specific for D. melanogaster DPP III, northern blot analysis of fruit fly total RNA showed two transcripts at approximately 2.6 and 2.3 kb, consistent with the translation of 89-kDa and 82-kDa DPP III proteins. Moreover, the purified enzyme hydrolyzed the insect neuropeptide proctolin (Km approximately 4 microm) at the second N-terminal peptide bound, and was inhibited by the specific DPP III inhibitor tynorphin. Finally, anti-(DPP III) immunoreactivity was observed in the central nervous system of D. melanogaster larva, supporting a functional role for DPP III in proctolin degradation. This study shows that DPP III is in actuality synthesized in D. melanogaster as 89-kDa and 82-kDa isoforms, representing two native proteins translated from two alternative mRNA transcripts.

The metal-binding motif of dipeptidyl peptidase III directly influences the enzyme activity in the copper derivative of dipeptidyl peptidase III.

The zinc-binding motif (HELLGH) of dipeptidyl peptidase III (DPP III) is different from the common zinc-binding motif (HExxH) of metallopeptidases. To clarify the importance of the zinc-binding motif part of DPP III for enzymatic activity, we measured the recovery of the enzyme activity of apo-Leu(453)-deleted dipeptidyl peptidase III (apo-Leu(453)-del-DPP III), which has a motif (HELGH) like that of the common peptidase (HExxH), in the presence of various metal ions. The enzyme activity of apo-Leu(453)-deleted DPP III could not be recovered by the addition of cupric ions, while apo-DPP III could be easily reactivated by the addition of cupric ions. The visible and electron paramagnetic resonance spectra of the isolated Cu(II)-Leu(453)-del DPP III clearly show that the cupric ions of Cu(II)-Leu(453)-del-DPP III bound to the motif part (HELGH) but did not exhibit any enzyme activity. The motif part of DPP III directly influences the expression of the enzyme activity in the copper derivative of DPP III. The competitive inhibitor that is not at all digested by DPP III, Hisprophen (His-Pro-Phe-His-Leu-d-Leu-Val-Tyr), has been determined. The inhibition constant (K(i)) of Hisprophen for DPP III or Cu(II)-DPP III was 4.1x10(-5) or 3.8x10(-5)M, respectively. In the presence of the competitive peptide inhibitor, Hisprophen, the EPR spectra of Cu(II)-DPP III were completely different from that of Cu(II)-DPP III itself. This result clearly indicates that the metal ions of DPP III are located in the active site and directly interact with the substrate.

Characterization of a functionally expressed dipeptidyl aminopeptidase III from Drosophila melanogaster.

A Drosophila melanogaster cDNA clone (GH01916) encoding a putative 723-residue long (82 kDa) protein (CG 7415) and displaying 50% identity with mammalian cytosolic dipeptidyl aminopeptidase (DPP) III was functionally expressed in Schneider S2 cells. Immunocytochemical studies using anti-(rat liver DPP III) Ig indicated the expression of this putative DPP III at the outer cell membrane and into the cytosol of transfected cells. Two protein bands (82 and 86 kDa) were immunologically detected after PAGE and Western blot of cytosol or membrane prepared from transfected cells. Western blot analysis of partially purified D. melanogaster DPP III confirmed the overexpression of these two protein bands into the cytosol and on the membranes of transfected cells. Despite the identification of six potential glycosylation sites, PAGE showed that these protein bands were not shifted after deglycosylation experiments. The partially purified enzyme hydrolysed the insect myotropic neuropeptide proctolin (Arg-Tyr-Leu-Pro-Thr) at the Tyr-Leu bond (Km approximately 4 micro m). In addition, low concentration of the specific DPP III inhibitor tynorphin prevented proctolin degradation (IC50 = 0.62 +/- 0.15 micro m). These results constitute the first characterization of an evolutionarily conserved insect DPP III that is expressed as a cytosolic and a membrane peptidase involved in proctolin degradation.