Role of His-224 in the anomalous pH dependence of human stromelysin-1.

A plot of the pH dependence of kcat/KM for human stromelysin-1 (HS) exhibits a narrow range of maximal activity extending from pH 5.75 to 6.25 and a broad shoulder in the pH range of 7.5-8.5. In contrast, the pH profiles that have been reported for other members of the matrix metalloproteinase (MMP) family are bell-shaped and exhibit neutral pH optima. We hypothesized that the anomalous pH dependence of HS reflects the ionization of His-224, a residue located in a flexible loop that contributes to the S1' binding pocket of the enzyme. HS is the only known MMP that has a histidine in this position. To test this hypothesis, the H224Q mutant of the short form (lacking the C-terminal hemopexin-like domain) of HS (sHS) has been prepared and studied. The pH profile of H224Q sHS is bell-shaped and similar to those reported for other MMPs. Although H224Q and wild-type sHS possess similar activities at pH <6, the kcat/KM of H224Q sHS is more than 5-fold greater than that of the wild-type enzyme at pH >7. These data strongly suggest that the deprotonation of His-224 attenuates the activity of HS, thereby accounting for its low pH optimum and the characteristic shoulder in its pH profile. This attenuation of activity appears to be predominantly a KM effect, reflecting a decrease in the affinity of the enzyme for the peptide substrate.

Understanding the P1' specificity of the matrix metalloproteinases: effect of S1' pocket mutations in matrilysin and stromelysin-1.

Matrilysin (MAT) prefers leucine over residues that have aromatic side chains at the P1' position of peptide and protein substrates, while stromelysin (HFS) has a broader specificity. The X-ray structures of these enzymes show that their respective S1' subsites differ primarily due to the amino acids present at positions 214 and 215. To examine the role that these residues play in determining P1' specificity, the amino acids at these positions in matrilysin have been replaced by those found in stromelysin (MAT: Y214L, MAT:A215V, and MAT:Y214L/A215V). The specificity and activity of MAT:A215V are similar to those of wild type matrilysin. Both MAT:Y214L and MAT:Y214L/A215V, however, have P1' specificities that are more similar to stromelysin than matrilysin. Specifically, these enzymes exhibit an 8- to 9-fold reduction in kcat/KM toward a peptide substrate with Leu in subsite P1' relative to wild type matrilysin. This is predominantly the result of an approximate 5-fold decrease in kcat. The KM values only partially increase toward the value observed for stromelysin. Studies of the pre-steady-state reaction of wild type and mutant matrilysin with substrates with Leu and Tyr residues in the P1' position confirm that the KM values for these reactions reflect KD values for substrate binding. Thus, replacement of a single tyrosine residue in the S1' pocket of matrilysin by leucine alters its P1' specificity to resemble that of stromelysin. In contrast, alteration of the S1' subsite of stromelysin (HFS:L214Y/V215A) to resemble matrilysin increases activity (i.e., higher kcat/KM) toward peptide substrates with both leucine and residues with aromatic side chains in the P1' position with only a partial increase in specificity for Leu. These increases in activity are the result of decreases in the KM values for these reactions.

Purification of human matrilysin produced in Escherichia coli and characterization using a new optimized fluorogenic peptide substrate.

Human promatrilysin (matrix metalloproteinase-7) has been produced in Escherichia coli as an N-terminal fusion protein with ubiquitin. The insoluble product was solubilized, refolded, and activated with amino-phenylmercuric acetate. Activation of the fusion protein demonstrated kinetics and intermediates that were very similar to those observed during activation of promatrilysin produced in Chinese Hamster Ovary (CHO) cells. Following activation, matrilysin was purified to > 95% homogeneity using a Sepharose-Pro-Leu-Gly-NHOH affinity column. The matrilysin purified by this procedure is indistinguishable from the enzyme purified from CHO cells with respect to the kinetic parameters for hydrolysis of a peptide substrate and the ability to obtain diffraction quality crystals in the presence of an inhibitor of the enzyme. Additionally, to facilitate detailed kinetic analyses of matrilysin, a new fluorogenic peptide substrate with the optimized sequence Dnp-Arg-Pro-Leu-Ala-Leu-Trp-Arg-Ser (Dnp, dinitrophenyl) has been synthesized. This peptide is the best substrate developed for matrilysin thus far with Km and kcat values of 26 microM and 5.0 s-1, respectively.

Insights into the catalytic mechanism and active-site environment of Comamonas testosteroni delta 5-3-ketosteroid isomerase as revealed by site-directed mutagenesis of the catalytic base aspartate-38.

Delta 5-3-Ketosteroid isomerase (KSI) of Comamonas testosteroni catalyzes the isomerization of a wide variety of delta 5(6) and delta 5(10) steroids through the formation of an enzyme bound dienol(ate) intermediate. Asp-38 has been strongly implicated in catalysis, apparently serving as a proton shuttle. In this paper the results of a detailed kinetic characterization of the KSI mutants D38E and D38H are presented. Both mutants retain significant activity, with kcat and kcat/Km values 10(3)-10(4) times greater than the D38N mutant. The results allow for a qualitative assessment of the sensitivity of the enzymes catalytic capability to the positioning and chemical nature of the catalytic base. The near identity of the ratios of kcat5-AND/kcat5,10-EST is most easily explained by a mechanism in which the second chemical step, reketonization of the intermediate dienol(ate), is not significantly rate determining. The pH dependence of the rate constants for the D38E and D38H mutants is found to be consistent with earlier proposals that an as yet unidentified titrating functional group is present in the active site and indicates that the electrostatic environment of residue 38 is hydrophobic and positively charged.

Extent of proton transfer in the transition states of the reaction catalyzed by the delta 5-3-ketosteroid isomerase of Comamonas (Pseudomonas) testosteroni: site-specific replacement of the active site base, aspartate 38, by the weaker base alanine-3-sulfinate.

Previous studies of the mechanism of the steroid isomerase of Comamonas (Pseudomonas) testosteroni have identified aspartate 38 as the proton porter which transfers the substrate's 4 beta proton to the 6 beta position of the product. Consequently, aspartate 38 functions as a base in the deprotonation of the substrate to form a dienol or dienolate intermediate, which then undergoes reprotonation from protonated aspartate 38 at C-6 beta to give the product. We have tried to characterize the transition states for the proton transfers by altering the pKa' of aspartate 38 and then determining the effect of the alteration on the kinetics of the enzyme. Alteration of the pKa' was accomplished by replacement of the carboxyl carbon of aspartate 38 by sulfur, a change which converts the carboxylate group to the much less basic sulfinate group. Employing Brønsted catalysis theory as applied to the individual steps of the isomerase mechanism, we find that in the enolization step of the reaction proton transfer to aspartate 38 is well advanced in the transition state. In the subsequent ketonization step, proton transfer from aspartate 38 has barely started when that transition state is reached. A series of mutant KSIs with alternative bases at position 38 have been constructed using a combination of site-directed mutagenesis and chemical modification: Asp-38 to Glu (D38E), His (D38H), and S-(carboxymethyl)cysteine (D38CMC). While the D38H and D38E mutants both retain significant isomerase activity, D38CMC is essentially inert. From the results of kinetic experiments it is possible to get a qualitative idea of the sensitivity of the enzyme's catalytic ability to the location of the base responsible for proton transfer.

Reconstruction of male external genitalia with elephantiasis.

The surgical rehabilitation of a patient with severely deformed and functionally disabled genitalia due to long-standing lymphedema and infection is described and illustrated. The term "elephantiasis" has been applied to such gross lesions. Appropriate surgery to the penis, scrotum, and perineum has yielded a gratifying result. The principles and techniques of the surgical approach in such an undertaking are presented and discussed.