[Basic carboxypeptidases of blood: significance for coagulology].

This review considers the basic metallocarboxypeptidases of human blood and their role in coagulologic disorders. In includes information on the history of the discovery and biological characteristics of potential enzymes-regulators of the fibrinolytic process: carboxypeptidase U and carboxypeptidase N. Certain attention is paid to the biochemical mechanisms and the main modern concepts of the antifibrinolytic effects of these enzymes.

Binding of carboxypeptidase N to fibrinogen and fibrin.

The ultimate step in the blood coagulation cascade is the formation of fibrin. Several proteins are known to bind to fibrin and may thereby change clot properties or clot function. Our previous studies identified carboxypeptidase N (CPN) as a novel plasma clot component. CPN cleaves C-terminal lysine and arginine residues from several proteins. The activity of CPN is increased upon its proteolysis by several proteases. The aim of this study is to investigate the presence of CPN in a plasma clot in more detail. Plasma clots were formed by adding thrombin, CaCl(2) and aprotinin to citrated plasma. Unbound proteins were washed away and non-covalently bound proteins were extracted and analyzed with 2D gel electrophoresis and mass spectrometry. The identification of CPN as a fibrin clot-bound protein was verified using Western blotting. Clot-bound CPN consisted of the same molecular forms as CPN in plasma and its content was approximately 30 ng/ml plasma clot. Using surface plasmon resonance we showed that CPN can bind to fibrinogen as well as to fibrin. In conclusion, CPN binds to fibrinogen and is present in a fibrin clot prepared from plasma. Because CPN binds to a fibrin clot, there could be a possible role for CPN as a fibrinolysis inhibitor.

Structure and function of human plasma carboxypeptidase N, the anaphylatoxin inactivator.

Human carboxypeptidase N (CPN) was discovered in the early 1960s as a plasma enzyme that inactivates bradykinin and was identified 8 years later as the major "anaphylatoxin inactivator" of blood. CPN plays an important role in protecting the body from excessive buildup of potentially deleterious peptides that normally act as local autocrine or paracrine hormones. This review summarizes the structure, enzymatic properties and function of this important human enzyme, including insights gained by the recent elucidation of the crystal structure of the CPN catalytic subunit and structural modeling of the non-catalytic regulatory 83 kDa subunit. We also discuss its physiological role in cleaving substrates such as kinins, anaphylatoxins, creatine kinase, plasminogen receptors, hemoglobin and stromal cell-derived factor-1alpha (SDF-1alpha).

Crystal structure of the human carboxypeptidase N (kininase I) catalytic domain.

Human carboxypeptidase N (CPN), a member of the CPN/E subfamily of "regulatory" metallo-carboxypeptidases, is an extracellular glycoprotein synthesized in the liver and secreted into the blood, where it controls the activity of vasoactive peptide hormones, growth factors and cytokines by specifically removing C-terminal basic residues. Normally, CPN circulates in blood plasma as a hetero-tetramer consisting of two 83 kDa (CPN2) domains each flanked by a 48 to 55 kDa catalytic (CPN1) domain. We have prepared and crystallized the recombinant C-terminally truncated catalytic domain of human CPN1, and have determined and refined its 2.1 A crystal structure. The structural analysis reveals that CPN1 has a pear-like shape, consisting of a 319 residue N-terminal catalytic domain and an abutting, cylindrically shaped 79 residue C-terminal beta-sandwich transthyretin (TT) domain, more resembling CPD-2 than CPM. Like these other CPN/E members, two surface loops surrounding the active-site groove restrict access to the catalytic center, offering an explanation for why some larger protein carboxypeptidase inhibitors do not inhibit CPN. Modeling of the Pro-Phe-Arg C-terminal end of the natural substrate bradykinin into the active site shows that the S1' pocket of CPN1 might better accommodate P1'-Lys than Arg residues, in agreement with CPN's preference for cleaving off C-terminal Lys residues. Three Thr residues at the distal TT edge of CPN1 are O-linked to N-acetyl glucosamine sugars; equivalent sites in the membrane-anchored CPM are occupied by basic residues probably involved in membrane interaction. In tetrameric CPN, each CPN1 subunit might interact with the central leucine-rich repeat tandem of the cognate CPN2 subunit via a unique hydrophobic surface patch wrapping around the catalytic domain-TT interface, exposing the two active centers.

Plasmin alters the activity and quaternary structure of human plasma carboxypeptidase N.

Human CPN (carboxypeptidase N) is a tetrameric plasma enzyme containing two glycosylated 83 kDa non-catalytic/regulatory subunits that carry and protect two active catalytic subunits. Because CPN can regulate the level of plasminogen binding to cell surface proteins, we investigated how plasmin cleaves CPN and the consequences. The products of hydrolysis were analysed by activity assays, Western blotting, gel filtration and sequencing. When incubated with intact CPN tetramer, plasmin rapidly cleaved the 83 kDa subunit at the Arg457-Ser458 bond near the C-terminus to produce fragments of 72 and 13 kDa, thereby releasing an active 142 kDa heterodimer, and also cleaved the active subunit, decreasing its size from 55 kDa to 48 kDa. Further evidence for the heterodimeric form of CPN was obtained by re-complexing the non-catalytic 72 kDa fragment with recombinant catalytic subunit or by immunoprecipitation of the catalytic subunit after plasmin treatment of CPN using an antibody specific for the 83 kDa subunit. Upon longer incubation, plasmin cleaved the catalytic subunit at Arg218-Arg219 to generate fragments of 27 kDa and 21 kDa, held together by non-covalent bonds, that were more active than the native enzyme. These data show that plasmin can alter CPN structure and activity, and that the C-terminal 13 kDa fragment of the CPN 83 kDa subunit is a docking peptide that is necessary to maintain the stable active tetrameric form of human CPN in plasma.

Characterization of mouse carboxypeptidase N small active subunit gene structure.

Carboxypeptidase N (CPN) is a plasma zinc metalloprotease comprised of two small subunits that have enzymatic activity, and two large subunits, which protect the enzyme from degradation. CPN cleaves the carboxyl-terminal amino acids arginine and lysine from biologically active peptides such as complement anaphylatoxins, kinins, and fibrinopeptides. To delineate the murine CPN small subunit coding region, gene structure, and chromosome location, cDNA and genomic clones were isolated, characterized, and used in Northern and fluorescence in situ hybridization analyses. The results from this study demonstrate that the murine CPN small subunit gene is a single copy gene of approximately 29 kb that is transcribed in the liver into a 1793-bp mRNA with an open reading frame of 1371 nucleotides encoding 457 aa. The gene contains nine exons ranging in size from 455 bp (exon 1) to 100 bp (exon 7), and eight introns ranging in size from 6.2 kb (intron 2) to 1.4 kb (intron 4). All intron/exon junctions follow the normal consensus rule. The mouse CPN small subunit gene localized to chromosomal band 19D2, which is syntenic to human chromosome 10q23-25. Primer extension experiments using mouse liver mRNA indicate one major transcriptional initiation site and three minor sites. Sequence analysis of the 5'-flanking region indicated a TATA-less promoter and numerous transcription factor binding sites, which may confer liver-specific expression of the CPN small subunit gene.

[Basic (cleaving arginine and lysine residues) metallocarboxypeptidase of mammalian tissue: structure, properties and function]. / Osnovnye (otshchepliaiushchie ostatki arginina i lizina) metallokarboksipeptidazy tkanei mlekopitaiushchikh: struktura, svoistva i funktsii.

The structure, physical, chemical and catalitical properties, functions and biological role of mammalian basic carboxypeptidases are observing. On the strength of the genetic and filogenic research data it is supposed the existence of a family of basic metal-dependent carboxypeptidases and the plan of it evolution is proposed. The connections between structure, localisation and function of this enzyme are discussed.

Immobilized carboxypeptidase N. A potent bioreactor and specific adsorbent for peptides.

Carboxypeptidase N-Sepharose was prepared by covalent immobilization of purified human plasma carboxypeptidase N. More than 98% of the carboxypeptidase N was immobilized; 42% of the applied activity can be detected on the support. The column has excellent capabilities to quantitatively remove carboxy-terminal basic amino acids from peptides, as is demonstrated using the synthetic peptide substrate hippuryl-L-arginine and the nonapeptide bradykinin, and remains stable for several months. In contrast with apocarboxypeptidase B-Sepharose, apocarboxypeptidase N-Sepharose poorly binds its substrates.

On the specificity of carboxypeptidase N, a comparative study.

The structure of the enzymatically active subunit of human plasma carboxypeptidase N was modeled based on the homology with bovine carboxypeptidase A. The active site of carboxypeptidase N is well conserved in comparison with carboxypeptidase A. From a comparison of energetically favorable binding sites for different atomic probe groups a hypothesis for the differences in substrate specificity between carboxypeptidases A and N was derived. Small synthetic peptide substrates were synthesized to confirm this hypothesis. This study shows that even with very low homology model building by homology can be employed to build models of sufficient quality to aid in drug design.

[Properties of basic (splitting off arginine and lysine residues) carboxypeptidases and their role in the functioning of biologically active peptides]. / Svoistva osnovnykh (otshchepliaiushchikh ostatki arginina i lizina) karboksipeptidaz i ikh rol' v funktsionirovanii biologicheski aktivnykh peptidov.

Properties of carboxypeptidases that cleaved arginine and lysine from C-terminus of peptides are considered. Their role in processing, modulation and inactivation of active peptides are discussed. Mechanisms of regulation of carboxypeptidase H activity are considered.

[Purification and physico-chemical properties of soluble carboxypeptidase N from cat brain gray matter]. / Ochistka i fiziko-khimicheskie svoistva rastvorimoi karboksipeptidazyN iz serogo veshchestva golovnogo mozga koshki.

Using affinity chromatography on diasorb-L-arginine and polyacrylamide gel electrophoresis, soluble carboxypeptidase H (E. C. 3.4.17.10) has been isolated from cat brain cortex and purified 598-fold with a 16% yield. The enzyme has a molecular mass of 50 kDa, consists of one polypeptide chain, and displays the maximum activity at pH 5.6. Carboxypeptidase H is a thiol-dependent metalloenzyme and contains a Zn2+ ion in its active center. The Km and V values for dansyl-Phe-Leu-Arg are 100 +/- 5 microM and 12.5 +/- 1.4 microM/min/mg of protein, respectively. The existence of two forms of soluble carboxypeptidase differing in isoelectric points and pH optima has been demonstrated. The enzyme with a pI of 4.8 has a pH optimum at 5.5-5.6, while that with a pI of 5.25-at 6.0.

Structural features of two kininase I-type enzymes revealed by molecular cloning.

Kininase I-type carboxypeptidases remove a single C-terminal Arg residue from kinins. The circulating kininase I (carboxypeptidase N) contains two types of subunits: a 50 kDa catalytic subunit and an 83 kDa carrier subunit which protects the active subunit in blood. The 83 kDa subunit contains 12 leucine-rich tandem repeats, similar in sequence to other proteins with binding functions. Human carboxypeptidase M is a widely distributed "tissue kininase I" bound to plasma membranes. It has 41% sequence identity with the 50 kDa subunit of carboxypeptidase N and may regulate the activity of kinins and other peptides at the cell surface.

Comparative molecular modeling of the active subunit of human kininase I.

The structure of the enzymatically active subunit of human plasma carboxypeptidase N was determined by computer aided model building by homology using the structural coordinates from carboxypeptidase A. The active site of carboxypeptidase N has been well conserved in comparison with carboxypeptidase A. Differences in substrate specificity can be explained by the comparison of energetically favorable binding sites for different atomic probe groups.

A new latent arginine esteropeptidase from human submaxillary gland.

One of the arginine esteropeptidases in human submaxillary gland was purified from microsomal membranes. The enzyme is inactive in membranes and requires trypsin treatment for its full activation. The trypsin-activated enzyme was purified to homogeneity. Its molecular weight was determined to be 94,000 by SDS-polyacrylamide gel electrophoresis. Among various substrates examined, the obtained enzyme exhibited high specific activities toward Tos-Arg-OMe (esterolysis) and D-Ile-Pro-Arg-pNA (amidolysis). The enzyme was inhibited by some serine proteinase inhibitors, whereas inhibitors of other types of proteinases did not affect or only scarcely affected it. The enzyme appears to be distinct from other arginine esteropeptidases previously described.