Complementary substrate specificities of class I and class II collagenases from Clostridium histolyticum

The substrate specificities of three class I (beta, gamma, and eta) and three class II (sigma, epsilon, and zeta) collagenases from Clostridium histolyticum have been investigated by quantitating the kcat/KM values for the hydrolysis of 53 synthetic peptides with collagen-like sequences covering the P3 through P3 subsites of the substrate. For both classes of collagenases, there is a strong preference for Gly in subsites P1' and P3. All six enzymes also prefer substrates that contain Pro and Ala in subsites P2 and P2' and Hyp, Ala, or Arg in subsite P3'. This agrees well with the occupancies of these sites by these residues in type I collagen. However, peptides with Glu in subsites P2 or P2' are not good substrates, even though Glu occurs frequently in these positions in collagen. Conversely, all six enzymes prefer aromatic amino acids in subsite P1, even though such residues do not occur in this position in type I collagen. In general, the class II enzymes have a broader specificity than the class I enzymes. However, they are much less active toward sequences containing Hyp in subsites P1 and P3'. Thus, the two classes of collagenases have similar but complementary sequence specificities. This accounts for the ability of the two classes of enzymes to synergistically digest collagen.     

Preparation and reconstitution with divalent metal ions of class I and class II Clostridium histolyticum apocollagenases

Both gamma- and zeta-collagenases from Clostridium histolyticum are fully and reversibly inhibited by 1,10-phenanthroline at pH 7.5 in the presence of 10 mM CaCl2 with KI values of 0.11 and 0.040 mM, respectively. The inhibition is caused by removal of the single, active-site Zn(II) present in each of these enzymes. The nonchelating analogue 1,5-phenanthroline has no effect on the activity of either enzyme. Dialysis of the enzymes in the presence of 1,10-phenanthroline, followed by back dialysis against buffer containing no chelating agent, gives the respective apocollagenases. Both apoenzymes can be instantaneously and fully reactivated by the addition of 1 equiv of Zn(II). Variable amounts of activity are restored to both apocollagenases by Co(II) and Ni(II) and to gamma-apocollagenase by Cu(II). The activity titration curve for gamma-apocollagenase with Co(II) and Scatchard plots for the reconstitution of gamma-apocollagenase with Cu(II) and Ni(II) and of zeta-apocollagenase with Ni(II) and Co(II) indicate that all activity changes are the result of binding of a single equivalent of these divalent metal ions at the active site of the collagenases. Cd(II) and Hg(II) do not restore measurable activity to either apoenzyme.     

Kinetics of hydrolysis of type I, II, and III collagens by the class I and II Clostridium histolyticum collagenases.

The kinetics of hydrolysis of rat tendon type I, bovine nasal septum type II, and human placental type III collagens by class I and class IIClostridium histolyticum collagenases (CHC) have been investigated. To facilitate this study, radioassays developed previously for the hydrolysis of these [³H]acetylated collagens by tissue collagenases have been adapted for use with the CHC. While the CHC are known to make multiple scissions in these collagens, the assays are shown to monitor the initial proteolytic events. The individual kinetic parametersk _cat andK _M have been determined for the hydrolysis of all three collagens by both class I and class II CHC. The specific activities of these CHC toward fibrillar type I and III collagens have also been measured. In contrast to human tissue collagenases, neither class of CHC exhibits a marked specificity toward any collagen type either in solution or in fibrillar form. The values of the kinetic parametersk _cat andK _M for the CHC are similar in magnitude to those of the human enzymes acting on their preferred substrates. Thus, the widely held view that the CHC are more potent collagenases is not strictly correct. As with the tissue collagenases, the local collagen structure at the cleavage sites is believed to play an important role in determining the rates of the reactions studied.     

Limited proteolysis of type I collagen at hyperreactive sites by class I and II Clostridium histolyticum collagenases: complementary digestion patterns

The initial proteolytic events in the hydrolysis of rat tendon type I collagen by the class I and II collagenases from Clostridium histolyticum have been investigated at 15 degrees C. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis has been used to detect the initial cleavage fragments of both the alpha 1(I) and alpha 2 chains, which migrate at different rates in the buffer system employed. Experiments with the class I collagenases indicate that the first cleavage occurs across all three chains of the triple helix close to the C-terminus to produce fragments whose alpha chains have molecular weights of approximately 88,000. The second cleavage occurs near the N-terminus to reduce the molecular weight of the alpha chains to 80,000. Initial proteolysis by the class II collagenases occurs across all three chains at a site in the interior of the collagen triple helix to give N- and C-terminal fragments with alpha-chain molecular weights of 35,000 and 62,000, respectively. The C-terminal fragment is subsequently cleaved to give fragments with alpha-chain molecular weights of 59,000. These results indicate that type I collagen is degraded at several hyperreactive sites by these enzymes. Thus, initial proteolysis by these bacterial collagenases occurs at specific sites, much like the mammalian collagenases. These results with the individual clostridial collagenases provide an explanation for earlier data which indicated that collagen is degraded sequentially from the ends by a crude clostridial collagenase preparation.     

Mode of hydrolysis of collagen-like peptides by class I and class II Clostridium histolyticum collagenases: evidence for both endopeptidase and tripeptidylcarboxypeptidase activities

The action of three class I (beta, gamma, and eta) and three class II (delta, epsilon, and zeta) collagenases from Clostridium histolyticum on two series of peptides with collagen-like sequences has been examined. The peptides in the first series all contain 4-nitrophenylalanyl-Gly-Pro-Ala in subsites P1 through P3', but each is successively lengthened in the N-terminal direction by addition of an appropriate residue until subsite P5 is occupied. The second group of peptides all have cinnamoyl-Leu in subsites P2 and P1, respectively, but each is successively lengthened in the C-terminal direction by partial additions of the Gly-Pro-Leu triplet until subsite P6' is occupied. N-Terminal elongation causes the kcat/KM values to rise markedly and to level off after occupancy of subsite P6 for the class I enzymes and subsite P3 for the class II enzymes. C-Terminal elongation produces the best substrates for both classes of enzymes when subsites P3' or P4' are occupied by amino acids with free carboxyl groups. The kcat/KM values for the hydrolysis of both Leu-Gly bonds of cinnamoyl-Leu-Gly-Pro-Leu-Gly-Pro-Leu have been measured for both classes of enzymes. Both rates are large, but both classes preferentially hydrolyze the Leu-Gly bond of the C-terminal triplet. Thus, both classes of enzymes exhibit both endopeptidase and tripeptidylcarboxypeptidase activities.     

Inhibition of Clostridium histolyticum collagenases by phosphonamide peptide inhibitors

Several phosphonamide peptides having the general structure R-PO(OH)-Xaa-Yaa-Zaa were synthesized and tested for inhibition of Clostridium histolyticum collagenase. Inhibition was found to depend on the nature of R, Xaa, Yaa and Zaa such that the maximal affinity (Ki = 5 nM) was observed when R = p-nitrophenylethyl, Xaa = Gly, Yaa = Pro and Zaa = 2-aminohexanoic acid; this represents the tightest binding of inhibitor reported to date for any bacterial collagenase. Substitution of the p-nitrophenylethyl by a methyl group led to a 500-fold decrease of the potency, highlighting the existence of optimal interaction between the nitrophenylethyl side chain and one subsite of the enzyme. Replacement of the NH group in glycine residue (Xaa position) by -O- or -N-CH3 produces significantly less potent inhibitors, presumably due in part to the loss of a hydrogen bond between the inhibitor and collagenase active site. These phosphonamidates are thought to be acting as transition-state analogues of the peptide substrate.     

Kinetics of hydrolysis of type I,II, and III collagens by the class I and IIClostridium histolyticum collagenases

The kinetics of hydrolysis of rat tendon type I, bovine nasal septum type II, and human placental type III collagens by class I and class IIClostridium histolyticum collagenases (CHC) have been investigated. To facilitate this study, radioassays developed previously for the hydrolysis of these [³H]acetylated collagens by tissue collagenases have been adapted for use with the CHC. While the CHC are known to make multiple scissions in these collagens, the assays are shown to monitor the initial proteolytic events. The individual kinetic parametersk _cat andK _M have been determined for the hydrolysis of all three collagens by both class I and class II CHC. The specific activities of these CHC toward fibrillar type I and III collagens have also been measured. In contrast to human tissue collagenases, neither class of CHC exhibits a marked specificity toward any collagen type either in solution or in fibrillar form. The values of the kinetic parametersk _cat andK _M for the CHC are similar in magnitude to those of the human enzymes acting on their preferred substrates. Thus, the widely held view that the CHC are more potent collagenases is not strictly correct. As with the tissue collagenases, the local collagen structure at the cleavage sites is believed to play an important role in determining the rates of the reactions studied.     

Substrate recognition by the collagen-binding domain of Clostridium histolyticum class I collagenase

Clostridium histolyticum type I collagenase (ColG) has a segmental structure, S1+S2+S3a+S3b. S3a and S3b bound to insoluble collagen, but S2 did not, thus indicating that S3 forms a collagen-binding domain (CBD). Because S3a+S3b showed the most efficient binding to substrate, cooperative binding by both domains was suggested for the enzyme. Monomeric (S3b) and tandem (S3a+S3b) CBDs bound to atelocollagen, which contains only the collagenous region. However, they did not bind to telopeptides immobilized on Sepharose beads. These results suggested that the binding site(s) for the CBD is(are) present in the collagenous region. The CBD bound to immobilized collagenous peptides, (Pro-Hyp-Gly)(n) and (Pro-Pro-Gly)(n), only when n is large enough to allow the peptides to have a triple-helical conformation. They did not bind to various peptides with similar amino acid sequences or to gelatin, which lacks a triple-helical conformation. The CBD did not bind to immobilized Glc-Gal disaccharide, which is attached to the side chains of hydroxylysine residues in the collagenous region. These observations suggested that the CBD specifically recognizes the triple-helical conformation made by three polypeptide chains in the collagenous region.     

Relationship between the individual collagenases of Clostridium histolyticum: evidence for evolution by gene duplication

The relationship between the six collagenases (alpha, beta, gamma, delta, epsilon, and zeta) isolated and characterized in the preceding papers [Bond, M.D., & Van Wart, H.E. (1984) Biochemistry (preceding two papers in this issue)] has been investigated. Chemical modification reactions establish that all six enzymes contain essential carboxyl, tyrosine, and lysine residues. Circular dichroism spectra of the peptide bond region show that the secondary structures of the collagenases are very similar. Ouchterlony double-immunodiffusion experiments carried out with antiserum prepared against beta-collagenase indicate that all six collagenases are cross-reactive. Reverse-phase high-pressure liquid chromatography elution profiles of tryptic digests of these collagenases and sodium dodecyl sulfate electrophoresis gels of the peptides formed on reaction with cyanogen bromide have been obtained. The results indicate that the class I collagenases have extensive sequence homology with each other and that the class II collagenases have extensive sequence homology with each other but that the enzymes in the two classes have substantially different sequences. In addition, the data show that beta-collagenase probably consists of domains that have homologous amino acid sequences, which may have arisen by full or partial intragenic gene duplication. This may account for the unusually high molecular weight of this and the other collagenases. Finally, on the basis of the similarities between the collagenases in the two classes, it is suggested that one class evolved from the other by gene duplication followed by independent evolution by point mutations to yield enzymes with different substrate specificities.     

Specific cleavage of reduced and S-carboxamidomethylated neurophysin II by the collagenase of Clostridium histolyticum.

Purified collagenase of Clostridium histolyticum was shown to cleave reduced and S-carboxamidomethylated bovine neurophysin between Cys-13 and Gly-14. The scission resulted in formation of two separable fragments: a smaller peptide arising from residues 1 through 13, and a larger peptide comprising the remainder of the residues of the protein. By dansylation procedures, the smaller peptide was shown to have amino-terminal alanine as expected from the sequence of neurophysin II, and the larger peptide had amino-terminal glycine as anticipated. These results show that collagenase indeed cleaves bovine neurophysin II in accord with the specificity postulated for that enzyme, i.e., scission between -X-Gly- in a sequence of -Pro-X-Gly-Pro-Y-. This result, obtained with a non-collagenous protein substrate, is further confirmation of the specificity of collagenase as established by its action on collagens and on synthetic oligopeptides.     

Octahedral metal coordination in the active site of glyoxalase I as evidenced by the properties of Co(II)-glyoxalase I

Co(II)-glyoxalase I has been prepared by reactivation of apoenzyme from human erythrocytes with Co2+. The visible absorption spectrum showed maxima at 493 and 515 nm and shoulders at 465 and 615 nm. The absorption coefficients at 493 and 515 nm were 35 and 33 M-1 cm-1/cobalt ion, respectively; i.e. 70 and 66 M-1 cm-1 for the dimeric metalloprotein. The product of the enzymatic reaction, S-D-lactoylglutathione, although binding to Co(II)-glyoxalase I, had no demonstrable effect on the visible absorption spectrum, indicating binding outside the first coordination sphere of the metal. The EPR spectrum at 3.9 K was characterized by g1 approximately 6.6, g2 approximately 3.0, and g3 approximately 2.5, and eight hyperfine lines with A1 = 0.025 cm-1. Binding of the strong competitive inhibitor S-p-bromobenzylglutathione to Co(II)-glyoxalase I gave three g values: 6.3, 3.4, and 2.5, indicating a conformational change affecting the environment of the metal ion. Both optical and EPR spectra strongly suggest a high spin Co2+ with octahedral coordination in the active site of the enzyme. The similarities in kinetic properties between native Zn(II)-glyoxalase I and enzyme substituted with Mg2+, Mn2+, or Co2+ is consistent with the view that these enzyme forms have the same metal coordination in the protein.     

Inhibition of collagenase from Clostridium histolyticum by phosphoric and phosphonic amides

Di- and tripeptides with sequences present in collagen that are known to occupy the S1' through S3' subsites at the active site of the collagenase from Clostridium histolyticum do not themselves inhibit this zinc protease. Thus glycylproline, glycylprolylalanine, and their C-terminal amides are not inhibitors. N alpha-Phosphorylglycylproline, N alpha-phosphorylglycyl-L-prolyl-L-alanine, and their C-terminal amides are weak inhibitors with IC50's (concentration causing half-maximal inhibition) of 4.6, 0.8, 3, and 1.5 mM, respectively. Extension of glycyl-L-prolyl-L-alanine to L-leucyl-glycyl-L-prolyl-L-alanine gives a tetrapeptide known to occupy the S1, S1', S2', and S3' subsites of collagenase when present in collagen but that still does not itself inhibit the enzyme. (Isoamylphosphonyl)glycyl-L-prolyl-L-alanine, a peptide containing a tetrahedral phosphorus atom at the position of the amide carbonyl carbon of the L-leucylglycyl amide bond of the parent tetrapeptide, inhibits collagenase with an IC50 of 16 microM, at least 1000-fold more potent than the parent peptide. Substitution of the two-carbon ethyl chain of alanine for the five-carbon isoamyl chain of leucine increases the IC50 to 46 microM. Substitution of the n-decyl chain for the isoamyl chain does not change the IC50. (Isoamylphosphonyl)glycyl-glycyl-L-proline contains a tripeptide that does not occupy the S1' through S3' subsites of collagenase when this peptide is present in collagen and thus has an IC50 of 4.4 mM. (Isoamylphosphonyl)glycyl-L-prolyl-L-alanine may be an analogue of the tetrahedral transition state for the hydrolysis of the natural collagen substrate.(ABSTRACT TRUNCATED AT 250 WORDS)     

The class II aminoacyl-tRNA synthetases and their active site: Evolutionary conservation of an ATP binding site

Previous sequence analyses have suggested the existence of two distinct classes of aminoacyl-tRNA synthetase. The partition was established on the basis of exclusive sets of sequence motifs (Eriani et al. [1990] Nature 347:203–306). X-ray studies have now well defined the structural basis of the two classes: the class I enzymes share with dehydrogenases and kinases the classic nucleotide binding fold called the Rossmann fold, whereas the class II enzymes possess a different fold, not found elsewhere, built around a six-stranded antiparallel -sheet. The two classes of synthetases catalyze the same global reaction that is the attachment of an amino acid to the tRNA, but differ as to where on the terminal adenosine of the tRNA the amino acid is placed: class I enzymes act on the 2 hydroxyl whereas the class II enzymes prefer the 3 hydroxyl group. The three-dimensional structure of aspartyl-tRNA synthetase from yeast, a typical class II enzyme, is described here, in relation to its function. The crucial role of the sequence motifs in substrate binding and enzyme structure is high-lighted. Overall these results underline the existence of an intimate evolutionary link between the aminoacyl-tRNA synthetases, despite their actual structural diversity.Based on a presentation made at a workshop— Aminoacyl-tRNA Synthetases and the Evolution of the Genetic Code—held at Berkeley, CA, July 17–20, 1994 Correspondence to: G. Eriani     

Probing the active site of cellodextrin phosphorylase from Clostridium stercorarium: kinetic characterization, ligand docking, and site-directed mutagenesis

Cellodextrin phosphorylase from Clostridium stercorarium has been recombinantly expressed in Escherichia coli for the first time. Kinetic characterization of the purified enzyme has revealed that aryl and alkyl β-glucosides can be efficiently glycosylated, an activity that has not yet been described for this enzyme class. To obtain a better understanding of the factors that determine the enzyme's specificity, homology modeling and ligand docking were applied. Residue W168 has been found to form a hydrophobic stacking interaction with the substrate in subsite +2, and its importance has been examined by means of site-directed mutagenesis. The mutant W168A retains about half of its catalytic activity, indicating that other residues also contribute to the binding affinity of subsite +2. Finally, residue D474 has been identified as the catalytic acid, interacting with the glycosidic oxygen between subsites -1 and +1. Mutating this residue results in complete loss of activity. These results, for the first time, provide an insight in the enzyme-substrate interactions that determine the activity and specificity of cellodextrin phosphorylases.     

Discrimination of cognate and noncognate substrates at the active site of class II lysyl-tRNA synthetase

Within the two unrelated aminoacyl-tRNA synthetase classes, lysyl-tRNA synthetase (LysRS) is the only example known to exist in both classes. To probe the role of the amino acids responsible for L-lysine binding in the active site of the class II LysRS (LysRS2), we studied the lysS-encoded Escherichia coli protein. On the basis of the structure of L-lysine complexed with E. coli LysRS2 (lysS), residues implicated in amino acid recognition and discrimination were systematically replaced. Steady-state kinetic parameters for these variants showed reductions in the catalytic efficiency (k(cat)/K(M)) of 1-3 orders of magnitude, allowing the assignment of specific roles for key residues in the active site of LysRS2. To further investigate the role of each residue in discrimination against noncognate amino acids, steady-state kinetic parameters were determined for the nonprotein amino acid S-(2-aminoethyl)-L-cysteine, a potent inhibitor of LysRS2. While a number of variants showed reductions of several hundred-fold in efficiency of S-(2-aminoethyl)-L-cysteine utilization, this was uniformly accompanied by similar reductions in the efficiency of lysine utilization. Thus, manipulation of the amino acid binding site only allowed up to a 4-fold improvement in S-(2-aminoethyl)-L-cysteine discrimination. This is in contrast to the highly effective discrimination against S-(2-aminoethyl)-L-cysteine by class I LysRS and correlates with the fundamentally different roles of conserved aromatic residues in the two LysRS active sites. This now provides a mechanistic basis for the proposal that differences in amino acid discrimination have been pivotal in the evolution of two unrelated LysRSs.     

Discrimination of cognate and noncognate substrates at the active site of class I lysyl-tRNA synthetase

The aminoacyl-tRNA synthetases are divided into two unrelated structural classes, with lysyl-tRNA synthetase (LysRS) being the only enzyme represented in both classes. On the basis of the structure of l-lysine complexed with Pyrococcus horikoshii class I LysRS (LysRS1) and homology to glutamyl-tRNA synthetase (GluRS), residues implicated in amino acid recognition and noncognate substrate discrimination were systematically replaced in Borrelia burgdorferi LysRS1. The catalytic efficiency of steady-state aminoacylation (k(cat)/K(M)) with lysine by LysRS1 variants fell by 1-4 orders of magnitude compared to that of the wild type. Disruption of putative hydrogen bonding interactions through replacement of G29, T31, and Y269 caused up to 1500-fold reductions in k(cat)/K(M), similar to changes previously observed for comparable variants of class II LysRS (LysRS2). Replacements of W220 and H242, both of which are implicated in hydrophobic interactions with the side chain of lysine, resulted in more dramatic changes with up to 40000-fold reductions in k(cat)/K(M) observed. This indicates that the more compact LysRS1 active site employs both electrostatic and hydrophobic interactions during lysine discrimination, explaining the ability of LysRS1 to discriminate against noncognate substrates accepted by LysRS2. Several of the LysRS1 variants were found to be more specific than the wild type with respect to noncognate amino acid recognition but less efficient in cognate aminoacylation. This indicates that LysRS1 compromises between efficient catalysis and substrate discrimination, in contrast to LysRS2 which is considerably more effective in catalysis but is less specific than its class I counterpart.     

Identification of an active site ligand for a group I ribozyme catalytic metal ion

The transition state of the group I intron self-splicing reaction is stabilized by three metal ions. The functional groups within the intron substrates (guanosine and an oligoribonucleotide mimic of the 5'-exon) that coordinate these metal ions have been systematically defined through a series of metal ion specificity switch experiments. In contrast, the catalytic metal ligands within the ribozyme active site are unknown. In an effort to identify them, stereospecific (R(P) or S(P)) single-site phosphorothioate substitutions were introduced at five phosphates predicted to be in the vicinity of the catalytic center (A207, C208, A304, U305, and A306) within the Tetrahymena intron. Of the 10 ribozymes that were studied, four phosphorothioate substitutions (A207 S(P), C208 S(P), A306 R(P), and A306 S(P)) exhibited a significant reduction in the cleavage rate. Only the effect of the C208 S(P) phosphorothioate substitution could be significantly rescued by the addition of a thiophilic metal ion, either Mn(2+) or Zn(2+), when tested with an all-oxy substrate. The effect was not rescued with Cd(2+). To determine if one of the catalytic metal ions is coordinated to the C208 pro-S(P) oxygen, the phosphorothioate-substituted ribozymes were also assayed using oligonucleotide substrates with a 3'-phosphorothiolate or an S(P) phosphorothioate substitution at the scissile phosphate. This resulted in a second metal specificity switch, in that Mn(2+) or Zn(2+) no longer rescued the C208 S(P) ribozyme, but Cd(2+) provided efficient rescue in the context of either sulfur-containing substrate. The 3'-oxygen and the pro-S(P) oxygen of the scissile phosphate are both known to coordinate the same metal ion, M(A), which stabilizes the negative charge on the leaving group 3'-oxygen in the transition state. Taken together, these data suggest that metal M(A) is coordinated to the C208 pro-S(P) phosphate oxygen, which constitutes the first functional link between a specific catalytic metal ion and a particular functional group within the group I ribozyme active site.