Microheterogeneity of rat submaxillary gland kallikrein k10, a member of the kallikrein family

Purification and characterization of active recombinant rat kallikrein rK9

The rat tissue kallikrein rK9 is most abundant in the submandibular gland and the prostate. It has been successfully expressed in the Pichia pastoris yeast expression system. A full-length cDNA coding for the mature rK9 was fused in frame with yeast alpha-factor cDNA. The fusion protein was secreted into the medium with high yield without being processed by the yeast KEX2 signal peptidase. Mature rK9 was efficiently released from the fusion protein by trypsin and was purified to homogeneity by one-step affinity chromatography using soya bean trypsin inhibitor (SBTI) as affinity ligand. The identity of the recombinant enzyme was checked by N-terminal amino acid sequencing, Western blot analysis and kinetic studies. The dual trypsin- and chymotrypsin-like enzymatic specificity of rK9 was assessed by determining specificity constants (k(cat)/K(m)) for the hydrolysis of fluorogenic substrates, the peptide sequences of which were derived from proparathyroid hormone (pro-PTH) and from semenogelin-I. Our results confirmed the presence of an extended binding site in the rK9 active site. We also identified a far more sensitive substrate of this enzyme than those previously described, Abz-VKKRSARQ-EDDnp, which was hydrolysed with a catalytic efficiency k(cat)/K(m) of 420000 M(-1)s(-1). Finally, we showed that four of the five major proteins contained in secretions of rat seminal vesicles were rapidly degraded by recombinant rK9.

Kininogen-derived fluorogenic substrates for investigating the vasoactive properties of rat tissue kallikreins--identification of a T-kinin-releasing rat kallikrein

Peptide substrates with intramolecularly quenched fluorescence that reproduce the rat kininogen sequences at both ends of the bradykinin moiety were synthesized and used to investigate the kinin-releasing properties of five rat tissue kallikreins (rK1, rK2, rK7, rK9, rK10). Substrates derived from rat H- and L-kininogen were cleaved best by rK1, especially that including the N-terminal insertion site of bradykinin, Abz-TSVIRRPQ-EDDnp(Abz = O-aminobenzoyl, EDDnp = ethylenediamine 2,4-dinitrophenyl), which was cleaved at the R-R bond with a k(cat)/Km of 12400 mM(-1) s(-1). Replacement of the P2' residue Pro by Val in Abz-TSVIRRPQ-EDDnp gave a far less specific substrate that was rapidly hydrolysed by all five rat kallikreins and human kallikrein hK1. Peptidyl-N-methyl coumarylamide substrates, which lack prime residues, also had low specificities. The importance of the P2' residue for rK1 specificity was further demonstrated using a human-kininogen-derived substrate that included the N-terminal insertion site of bradykinin (Abz-LMKRP-EDDnp). This was cleaved at the M-K bond by hK1 (kallidin-releasing site), but at the K-R bond (bradykinin-releasing site) by rK1. Competition experiments with Abz-TSVIRRPQ-EDDnp, which is resistant to most kallikreins, and Abz-TSVIRRVQ-EDDnp, a general kallikrein substrate, demonstrated that the former competitively inhibited hydrolysis by rK9 and hK1, with Ki values similar to the Km values for the substrate. Thus Pro in P2' does not prevent the peptide binding to the enzyme active site, but impairs cleavage of the scissile bond. The T-kininogen-derived substrate with the T-kinin C-terminal sequence (Abz-FRLVR-EDDnp) was cleaved by rK10 (k(cat)/Km = 2310 mM(-1) s(-1)) and less rapidly by rK1, rK7 and hK1, at the R-L bond, while that corresponding to the N-terminal (Abz-ALDMMISRP-EDDnp) of T-kinin was resistant to all five kallikreins used, suggesting that none has T-kininogenase activity. But this substrate was hydrolysed by a semipurified sample of submandibular gland extract. Another kallikrein, identified as kallikrein rK3, was isolated from this fraction and shown to hydrolyze Abz-ALDMMISRP-EDDnp; rK3 also specifically released T-kinin from purified T1/T2-kininogen after HPLC fractionation. Injection of purified rK3 and of Abz-ALDMMISRP-EDDnp-cleaving fractions into the circulation of anesthesized rats caused transient falls in blood pressure, as did purified rK1 but none of the other purified rat or human kallikreins. This effect occurred via activation of the kinin system since it was blocked by Hoe140, a kinin receptor antagonist.

Kallikrein and kallikrein-like proteinases: purification and determination by chromatographic and electrophoretic methods

Kallikreins and kallikrein-like enzymes make up a family of serine proteinases present in tissues and body fluids of mammals and in some snake venoms. This review deals with the procedures of purification, detection and determination of these enzymes by chromatographic and electrophoretic methods. The procedures are reported in tables, described and discussed with the aim of illustrating the state-of-the-art of research in the field.

Disparate tissue-specific expression of members of the tissue kallikrein multigene family of the rat

To understand the regulatory diversity of the rat family of linked kallikrein genes, we have assayed the expression of family members in 20 major organs. Reverse transcription-polymerase chain reaction analysis using primers and hybridization probes specific for each of the 10 expressed kallikrein genes showed that no two family members share the same organ-specific pattern of expression. The only common site of expression for all 10 known active genes is the submandibular gland. The presence of the mRNA for at least one family member is detected in 19 of these 20 organs (liver excepted), from as few as three organs to as many as 18 for individual family members. For individual genes there can be more than a 10(5)-fold variation in mRNA levels among organs, from a limit of detection of slightly less than 1 mRNA molecule/10 cells to more than 10,000 mRNA molecules/cell. Despite high sequence conservation and close linkage, the members of this family are expressed in very different and complex patterns. A gradient of diversity of expression corresponds to the order of the genes within the kallikrein family locus.

Substrate specificity of tissue kallikreins: importance of an extended interaction site

The contribution of an extended interaction site in tissue kallikreins to their substrate specificity was investigated using peptides of increasing length and with different amino acids in positions P5 and P6. These substrates were constructed from a consensus dodecapeptide sequence (VASPFRSYDLDA) deduced from the hydrolysis of short synthetic peptide substrates, and from the identification of the cleavage sites in reduced-pyridylethylated lysozyme by 6 rat tissue kallikreins. Though the specificity constant kcat/Km generally increases with increasing the peptide substrate length on its N-terminal end, individual residues at P4-P6 may specifically alter this value for specific kallikreins. A seryl residue at P4 induces a 20-fold decrease in the specificity constant with rK2 and rK9, but it slightly improves this value for rK1 and rK10. A tryptophan in P6 is unfavourable for both rK1 and rK2 but not for rK9 and rK10, whereas a negatively charged residue has a negative effect for all four kallikreins. This demonstrates the importance of an extended interaction site in kallikreins, and suggests that the differing specificities of individual kallikreins are partly due to the presence of proteinase subsites which accommodate residues remote from the scissile bond in the substrate. These sites could be located in variable loops that surround the kallikrein active sites, and correspond to regions of lower structural similarity. Molecular modeling studies indicate that loop 4 may contribute to the P4-P7 specificity of kallikreins.

Purification of enzymes of the kallikrein gene family (rK8 and rK9) from the rat prostate

The rat kallikrein family consists of multiple closely related proteins. A method for demonstration and identification of kallikrein-like proteins has been developed based on their differences in isoelectric point and their immunological similarity. The method, which involved separation in flat-bed isoelectro-focusing gels (pH range 3-9) and detection by immunoblotting using polyclonal antiserum against one of the family members, has been used in the present study to detect kallikrein-like proteins in the rat prostate. Nine immunoreactive kallikrein-like protein bands were detected with pI ranging from 5.30 to 8.35. Of these, six were completely purified and three were partially purified. Two proteins (pI 5.30 and 6.75-6.90) corresponded to protein bands in gels of rat submandibular-gland extracts, and were identified by partial amino acid sequence analysis as rK8 and rK9 respectively. In addition, sequence analysis revealed complete sequence similarity between rK9 and the immunoreactive prostate proteins with pI 7.15, 7.25, 7.50 and 8.27. On the basis of this finding and immunological and biochemical characterization, we concluded that all the kallikrein-like proteins detected, except for rK8, represented isoenzymes of rK9. The molecular masses of the prostate rK9 isoenzymes (24,600-29,300 Da) were close to that of submandibular-gland rK9 (24,600 Da), although differences were observed after reduction with mercaptoethanol. The prostate rK9 isoenzymes were, like submandibular-gland rK9, inhibited by soya-bean trypsin inhibitor but not by aprotinin, and were classified as serine proteases as they were inhibited by phenylmethanesulphonyl fluoride. rK8 (28,700 Da) showed no activity with any of the substrates tested, and its inhibitory profile could therefore not be studied. No other enzymes of the kallikrein family were found in the rat prostate.

Selective processing of submandibular rat 1 protein at dibasic cleavage sites. Salivary and bloodstream secretion products

The amino acid sequence of submandibular rat 1 (SMR1) protein, deduced from its cDNA sequence, led to the prediction that the SMR1 gene encodes a hormone-like precursor [Rosinski-Chupin, I., Tronik, D. & Rougeon, F. (1988) Proc. Natl Acad. Sci. USA 85, 8553-8557]. SMR1 contains an N-terminal putative secretory signal sequence and a tetrapeptide (QHNP), located between dibasic amino acids which constitute the most common signal for prohormone processing. We have isolated and characterized from the male rat submandibular gland and its secretions three structurally related peptides, namely an undecapeptide (VRGPRRQHNPR), a hexapeptide (RQHNPR) and a pentapeptide (QHNPR) generated from SMR1 by selective proteolytic cleavages at pairs of arginine residues. The biosynthesis of these peptides is subjected to distinct regulatory pathways depending on the organ, sex and age of the rat. Furthermore, the peptides are differentially distributed in the submandibular gland and in resting or epinephrine-elicited submandibular salivary secretions, suggesting distinct proteolytic pathways for their maturation. The undecapeptide is generated in the gland of both male and female rats, but under basal conditions it is only released into the saliva in male animals. The hexapeptide is produced in large amounts in the gland of adult male rats and released into the saliva in both resting and stimulated conditions. The pentapeptide appears only in the male saliva and is present mostly under stimulated conditions. In addition, administration of epinephrine induces the release of the hexapeptide from the submandibular gland into the bloodstream. The evidence indicates that the rat submandibular gland can function as a dual exocrine and endocrine organ for the SMR1-derived hexapeptide, as has been reported for nerve growth factor, epidermal growth factor, renin and kallikrein. Although the biological activities of the SMR1-derived peptides are not yet known, their high production and adrenergic-induced release only into the saliva and bloodstream of adult male rats, suggest a physiological involvement in some male-specific processes.

Inhibition of rat tissue kallikrein gene family members by rat kallikrein-binding protein and alpha 1-proteinase inhibitor

The regulation of tissue kallikrein activity by plasma serine proteinase inhibitors (serpins) was investigated by measuring the association rate constants of six tissue-kallikrein family members isolated from the rat submandibular gland, with rat kallikrein-binding protein (rKBP) and alpha 1-proteinase inhibitor (alpha 1-PI). Both these serpins inhibited kallikreins rK2, rK7, rK8, rK9 and rK10 with association rate constants in the 10(3)-10(4) M-1.s-1 range, whereas only 'true' tissue kallikrein rK1 was not susceptible to alpha 1-PI. This results in slow inhibition of rK1 by plasma serpins, which could explain why this kallikrein is the only member of the gene family identified so far that induces a transient decrease in blood pressure when injected in minute amounts into the circulation.

New specific assays for tonin and tissue kallikrein activities in rat submandibular glands. Assays reveal differences in the effects of sympathetic and parasympathetic stimulation on proteinases in saliva

At least fourteen separate bands of proteinase activity, labelled A-N, were identified by an enzyme overlay membrane technique, using oligopeptide-7-amino-4-trifluoromethylcoumarin (AFC) substrates in rat submandibular gland extracts fractionated on pH 4-6.5 isoelectric focusing gels. The proteinases were eluted into an ammonium bicarbonate buffer pH 9.8 containing 0.1% Triton X-100 and the relative contribution of each band to total activity evaluated using D-Val-Leu-Arg-AFC (DVLR-AFC) and Z-Val-Lys-Lys-Arg-AFC (ZVKKR-AFC) as substrates. Immunoblotting of band eluants run on sodium dodecyl sulphate gels with antibodies showed that band A was identical with tonin and bands K-N contained tissue kallikrein. Tonin was found to hydrolyse ZVKKR-AFC but not DVLR-AFC. Estimates of the Km values of tissue kallikrein for DVLR-AFC and tonin for ZVKKR-AFC were found to be similar (approx. 20 microM) yet the former enzyme hydrolysed its substrate five times faster. Tonin was inhibited by soybean trypsin inhibitor (SBTI) but not by aprotinin. Tissue kallikrein, on the other hand, was inhibited by aprotinin but was considerably more resistant to inhibition by SBTI. In tissue extracts 95% of the ZVKKR-AFC lytic activity in the presence of 1 microM aprotinin is due to tonin and a similar percentage of the DVLR-AFC hydrolysing activity in the presence of 10 microM SBTI is due to tissue kallikrein. These findings were used for the specific measurement of these two proteinases in submandibular gland extracts and in saliva without prior purification. Using these inhibitor based assays we revealed qualitative differences in the composition of proteinases secreted into saliva during parasympathetic versus sympathetic stimulation of the submandibular gland. The distribution of proteinases in sympathetic saliva is very similar to that found in submandibular extracts but on parasympathetic stimulation, although much less proteinase is released, the contributions of the more acidic isomers of tissue kallikrein are increased and that of tonin and other proteinases dramatically decreased. The data suggest that parasympathetic and sympathetic nerves induce proteinase secretion via different pathways.

Characterization of a new kallikrein-like enzyme (KLP-S3) of the rat submandibular gland

The submandibular gland of the rat contains several enzymes belonging to the kallikrein family. These include tissue kallikrein, antigen gamma (T-kininogenase), esterase B and tonin. In the present study, a new member of this family, which we have named KLP-S3, was identified and purified from the submandibular gland. KLP-S3 was classified as a kallikrein-like enzyme on the basis of its immunological similarity to other kallikrein-like enzymes and its showing 70% and 73% identity in partial amino acid sequence with tissue kallikrein and tonin respectively. Furthermore, the 44 sequenced amino acid residues showed complete correspondence to the mRNA S3 of the kallikrein gene family, which was the rationale for the name kallikrein-like protein (KLP) S3. KLP-S3 consisted of three isoenzymes with pI 6.75, 6.90 and 6.95, which significantly differed from those of other kallikrein-like enzymes. In conjunction with its immunological relationship to kallikrein, this parameter (pI) was considered robust enough to identify the enzyme during purification, since a specific physiological substrate for KLP-S3 has yet to be identified. In SDS/PAGE the three isoenzymes ran as one band with a molecular mass of 25,800 Da, which after reduction with 2-mercaptoethanol was split into two chains with molecular masses of 16,500 and 13,300 Da. In common with other kallikrein-like enzymes, KLP-S3 was inhibited by phenylmethanesulphonyl fluoride, and was thus classified as a serine protease. It was also inhibited by soya-bean trypsin inhibitor but not by aprotinin. It showed weak reactivity against the chromogenic substrates S2288, S2266, S2366 and S2302 (D-Ile-Pro-Arg 4-nitroanilide, D-Val-Leu-Arg 4-nitroanilide, Glu-Pro-Arg 4-nitroanilide and D-Pro-Phe-Arg 4-nitroanilide respectively) and did not cleave rat T-kininogen or dog high-molecular-mass/low-molecular-mass kininogen. Its specific angiotensin II-generating activity (angiotensin I as substrate) was 0.04% of that of rat tonin. KLP-S3 (1-100 nM) induced a statistically significant angiotensin-independent contraction of isolated rat aorta rings. The maximum contraction was 15% of the response to the alpha-adrenoceptor agonist phenylephrine (1 microM). The concentration of KLP-S3 in the rat submandibular gland was by single radial immunodiffusion estimated to be 47 +/- 3 micrograms/mg of protein.

Identification of proteins of the kallikrein family by isoelectrofocusing and immunoblotting

We have found that kallikrein-like proteins differ in their isoelectric point but share antigenic determinants. For identification of kallikrein-like proteins an initial separation was carried out in flat-bed isoelectrofocusing gels. The kallikrein-like nature was demonstrated by an immunological similarity to kallikrein-like proteins by immunoblotting using antiserum against a kallikrein family member for staining. We used this system to identify different kallikrein-like proteins during purification of both known as well as new enzymes.

Functional diversity of proteinases encoded by genes of the rat tissue kallikrein family

A group of proteinases closely related to tissue kallikrein was purified from the rat submandibular gland. Physicochemical characterization of these proteinases, including amino terminal sequencing, allowed correlation with the genes of the rat kallikrein family. In spite of their similar structure, these proteinases have different substrate specificities and different susceptibilities to inhibitors which suggest that they do not share the same biological function. Kallikrein-like proteinases also have restricted specificities that are probably related to their extended substrate binding site. This makes them good candidates for processing inactive protein or peptide precursors into biologically active peptides. A general approach to identifying the putative biological substrates of individual proteinases based on analysis of the specific cleavage of synthetic and natural peptide substrates by kallikrein-related proteinases is described.