Neutrophil chemotactic activity of N-terminal peptides from the calpain small subunit

On the basis of previous findings that N-acetyl nonapeptide from the human calpain I large subunit has chemotactic activity for neutrophils, a series of peptides with the N-terminal sequence of the calpain small subunit were synthesized and their chemotactic activity was examined. Potent activity was found in N-acetyl tetra, hepta, octa, nona and a larger peptide of 13 residues, although N-acetyl tripeptide showed only weak activity and N-acetyl penta and hexa peptides showed almost no activity. Since the small subunit is identical in calpains I and II, the results indicate that both calpains could be precursor proteins of chemotactic factors for neutrophils.     

Calcium dependent cysteine proteinase is a precursor of a chemotactic factor for neutrophils

A new chemotactic factor for neutrophils is generated from calcium dependent cysteine proteinase (calpain) I by autodigestion. An active peptide was isolated from the autodigest and its structure was determined to be an acetylated nonapeptide with the sequence: N-acetyl Ser-Glu-Glu-Ile-Ile-Thr-Pro-Val-Tyr. Compared with the entire sequence of human calpain I, the peptide was identical with the N-terminal amino acid sequence of the large subunit deduced from the cDNA sequence, except that the peptide was devoid of a methionine residue and acetylated at the N-terminus. The acetyl nonapeptide was synthesized and its chemotactic activity was reconfirmed. The biological significance and possible role of this calpain derived chemotactic factor in inflammation are discussed.     

Cloning and molecular characterization of calpain, a calcium-activated neutral proteinase, from different strains of Schistosoma japonicum

cDNA coding for calpain of Schistosoma japonicum were cloned and sequenced, and serological basis of host responses to calpain were analyzed. cDNA of calpain from S. japonicum of two different isolates, Yamanashi strain (Sj-J) and Hunan strain (Sj-C), were 2, 468 bp and 2, 465 bp in length, including the same number (2, 274) of open reading frame. Nucleotide sequence and amino acid sequence between the two calpains are 99.1% and 98.8% identity, respectively. Sj-J and Sj-C calpains were considered to be translated as a preproenzyme, and a 746-amino acid mature enzyme contains eight motifs without a signal peptide at the N-terminal based on the deduced amino acid sequences. mRNA for calpain were detectable in different developmental stages, however, sera obtained from mice immunized with recombinant calpain showed enhanced binding to cercarial antigen. Human sera from S. japonicum-infected individuals recognized the large subunit of schistosomal calpain, and light-infected sera showed stronger reactivities to the recombinant calpain than moderate/high infection cases. When we tested synthetic peptides, there were four common human B cell epitopes in schistosomal calpain, all of which are shared with S. mansoni. Together with these results, calpain of S. japonicum seems to be not only a vaccine candidate, but also a target antigen for immunodiagnosis of human schistosomiasis.     

Comparison of tryptic peptides from the heavy and light subunits of calpain I and calpain II by high performance liquid chromatography

Two different forms of Ca2+-dependent cysteine proteinase, low-Ca2+-requiring calpain I and high-Ca2+-requiring calpain II, are known to be heterodimers, each composed of one heavy (called 80K) and one light (called 30K) subunit. The most probable identity of the 30K and the substantial difference between the 80K subunits of porcine calpains I and II were clearly demonstrated by comparing the tryptic peptide maps obtained upon running a high performance liquid chromatography which permitted parallel detection of tryptophan-containing peptides by fluorometry. Comparison of the amino acid compositions of the two 30K and 80K subunits also confirmed this conclusion. The same chromatographical analysis also revealed close structural similarity of the human calpain I 30K subunit, and even some similarity existing between the calpain I 80K subunits of human and porcine origins.     

Primary structure of the silk fibroin light chain determined by cDNA sequencing and peptide analysis

A cDNA clone, pFL18, carrying a putative full-length fibroin light chain (L-chain) sequence was isolated and its nucleotide sequence was determined. This revealed the presence of an open reading frame corresponding to a polypeptide with 262 amino acid residues. The sequence was concluded to be that of the L-chain with its signal peptide because corresponding amino acid sequences for the seven tryptic and the four chymotryptic peptides from the purified L-chain were all included and an N-terminal region having typical properties of a signal peptide was present. The N terminus of the mature form of L-chain was identified as N-acetyl serine by analyzing the acyl-dansylhydrazide derived from the N-acyl-amino acid which had been released from the N-terminal blocked chymotryptic peptide by the acylamino acid-releasing enzyme. It was suggested that a signal peptide had cleaved between Pro18 and Ser19, yielding a mature L-chain polypeptide consisting of 244 amino acid residues. The molecular weight of the L-chain was calculated to be 25,800 including the N-acetyl group. The L-chain contained three Cys residues, two of which were suggested to form an intramolecular disulfide linkage, leaving the third one at the most C-terminal position and in a relatively hydrophilic region as the most probable site of disulfide linkage with the fibroin heavy chain.     

Four genes for the calpain family locate on four distinct human chromosomes

Calcium dependent proteases (calpains, CAPNs, E.C.3.4.22.17) constitute a family of proteins which share a homologous cysteine-protease domain (large subunits, L1, L2, and L3) and an E-F hand Ca2(+)-binding domain (L1, L2, L3, and small subunit, S). We have mapped the genes for four calpain proteins (L1, L2, L3, and S) on four distinct human chromosomes by a combination of spot-blot hybridization to flow-sorted chromosomes and Southern hybridization of DNAs from a human x mouse hybrid cell panel. The genes for calpain L1 (CAPN1, large subunit of calpain I), L2 (CAPN2, large subunit of calpain II), L3 (CAPN3, a protein related to the large subunits), and S (CAPN4, a small subunit common to calpains I and II) were assigned to human chromosomes 11, 1, 15, and 19, respectively.     

Specific inhibition of ribonucleotide reductases by peptides corresponding to the C-terminal of their second subunit

Previous studies have shown that herpes virus ribonucleotide reductase can be inhibited by a synthetic nonapeptide whose sequence is identical to the C-terminal of the small subunit of the enzyme. This peptide is able to interfere with normal subunit association that takes place through the C-terminal of the small subunit. In this report, we illustrate that inhibition of ribonucleotide reductases by peptides corresponding to the C-terminal of subunit R2 is also observed for the enzyme isolated from Escherichia coli, hamster, and human cells. The nonapeptide corresponding to the bacterial C-terminal sequence was found to inhibit E. coli enzyme with an IC50 of 400 microM, while this peptide had no effect on mammalian ribonucleotide reductase. A corresponding synthetic peptide derived from the C-terminal of the small subunit of the human enzyme inhibited both human and hamster ribonucleotide reductases with IC50 values of 160 and 120 microM, respectively. However, this peptide had no inhibitory activity against the bacterial enzyme. Equivalent peptides derived from herpes virus ribonucleotide reductase had no effect on either the bacterial or mammalian enzymes. Thus, subunit association at the C-terminal of the small subunit appears to be a common feature of ribonucleotide reductases. In addition, the inhibitory phenomenon observed with peptides corresponding to the C-terminal appears not only to be universal, but also specific to the primary sequence of the enzyme.     

Effects of autolysis on properties of mu- and m-calpain

Although the biochemical changes that occur during autolysis of mu- and m-calpain are well characterized, there have been few studies on properties of the autolyzed calpain molecules themselves. The present study shows that both autolyzed mu- and m-calpain lose 50-55% of their proteolytic activity within 5 min during incubation at pH 7.5 in 300 mM or higher salt and at a slower rate in 100 mM salt. This loss of activity is not reversed by dialysis for 18 h against a low-ionic-strength buffer at pH 7.5. Proteolytic activity of the unautolyzed calpains is not affected by incubation for 45 min at ionic strengths up to 1000 mM. Size-exclusion chromatography shows that ionic strengths of 100 mM or above cause dissociation of the two subunits of autolyzed calpains and that the dissociated large subunits (76- or 78-kDa) aggregate to form dimers and trimers, which are proteolytically inactive. Hence, instability of autolyzed calpains is due to aggregation of dissociated heavy chains. Autolysis removes the N-terminal 19 (m-calpain) or 27 (mu-calpain) amino acids from the large subunit and approximately 90 amino acids from the N-terminus of the small subunit. These regions form contacts between the two subunits in unautolyzed calpains, and their removal leaves only contacts between domain IV in the large subunit and domain VI in the small subunit. Although many of these contacts are hydrophobic in nature, ionic-strength-induced dissociation of the two subunits in the autolyzed calpains indicates that salt bridges have an important, possibly indirect, role in the domain IV/domain VI interaction.     

Cross-reactivity of a monoclonal antibody to the catalytic subunit of chicken gizzard desmin-specific calpain

The desmin-specific calpain I from chicken gizzard smooth muscle is a dimer of 83 and 35 kDalton subunits. A monoclonal antibody to the large subunit did not cross-react with chicken gizzard and hamster skeletal muscle calpain II, but it did recognize hamster skeletal muscle desmin-specific calpain I and the denatured calpain II from chicken gizzard smooth muscle. These results indicate that different desmin-specific calpains have similar large subunits which differ significantly from the large subunit of calpain II in the same tissue.     

Role of lysine residue at 7th position of wasp chemotactic peptides

Most of chemotactic peptides isolated from various kinds of wasp venom have lysine residue at 7th (or 8th) position, but only a chemotactic peptide from Icaria sp. has no basic amino acid residues in the sequence. The relation of chemotaxis with other biochemical activities such as superoxide generation and lysosomal enzyme release from guinea pig neutrophils was studied by the use of substitution analogs of Icaria chemotactic peptide at 7th position. Findings revealed two distinct ways of chemoattractant signal transduction in neutrophils.     

Investigation of the structural basis of the interaction of calpain II with phospholipid and with carbohydrate.

Two forms of pig kidney calpain II were isolated, both of which appeared to contain an intact 80 kDa large subunit, but which showed specific proteolytic degradation at the N-terminal end of the 30 kDa small subunit. The structure of each of these molecules was investigated by amino acid sequence analysis. The forms corresponded to molecules with small subunits starting at residue 38 (degraded calpain A) and at residue 62 (degraded calpain B) of the complete sequence. These molecules were tested for their ability to interact with phosphatidylinositol and with carbohydrate (agarose gel-filtration media). Calpain and degraded calpain A, but not degraded calpain B, would interact with phosphatidylinositol. Thus the sequence (G)17TAMRILG (residues 38-61) is essential for the interaction. Neither calpain nor the degraded forms of the enzyme showed specific interaction with carbohydrate.     

Myocardial calpain 2 is inhibited by monoclonal antibodies specific for the small, noncatalytic subunit

Calpains (EC 3.4.22.17) are nonlysosomal intracellular proteinases which require calcium ion for activity. The calpains are heterodimers composed of a large catalytic subunit and a small subunit which may have a regulatory function during the catalytic cycle. However, whether calpains remain in the dimeric form or dissociate upon exposure to calcium is controversial. To resolve this issue, two monoclonal antibodies which specifically recognize the small calpain subunit were prepared using bovine calpain 2 heterodimer as the antigen. Both antibodies, designated P-1 and P-2, were capable of inhibiting bovine or canine calpain 2, and partially purified human erythrocyte calpain 1. However, neither could produce full inhibition. Further studies with P-1 and bovine calpain 2 indicated that the antibody decreased the calcium requirement for the proteinase. The Km for casein was increased and the Vmax was decreased. The addition of P-1 to the assay mixture several minutes after initiation of proteolytic activity resulted in a rapid inhibition. The P-1 antibody was also capable of decreasing the ability of the protein inhibitor of calpains (calpastatin) to inhibit bovine calpain 2. These studies indicate that the small subunit remains bound to the large subunit during catalysis and may influence its activity.     

Comparative specificity and kinetic studies on porcine calpain I and calpain II with naturally occurring peptides and synthetic fluorogenic substrates

Homogeneous porcine calpain (Ca2+-dependent cysteine proteinase) was found to hydrolyze a variety of peptides and synthetic substrates. Leu-Trp-Met-Arg-Phe-Ala, eledoisin-related peptide, alpha-neoendorphin, angiotensin I, luteinizing hormone-releasing hormone, neurotensin, dynorphin, glucagon, and oxidized insulin B chain were cleaved with a general preference for a Tyr, Met, or Arg residue in the P1 position preceded by a Leu or Val residue in the P2 position. No great difference in specificity was found between low-Ca2+-requiring calpain I and high-Ca2+-requiring calpain II. 4-Methylcoumaryl-7-amide (MCA) derivatives having a Leu(or Val)-Met(or Tyr)-MCA or a Leu-Lys-MCA sequence were also cleaved by either calpain I or calpain II with preference for Leu over Val by a factor of 9 to 16. Calpains I and II showed similar but not identical kinetic behavior for individual substrates. The Km and kcat values ranged from 0.23 to 7.08 mM and 0.062 to 0.805 s-1 for the calpains, while kcat/Km values for the calpains were only 1/433 to 1/5 of those for papain with a given substrate. With succinyl-Leu-Met(or Tyr)-MCA, calpains I and II were half-maximally activated at 12 and 260 microM Ca2+, respectively, and competitively inhibited by leupeptin (Ki = 0.32 microM for I and 0.43 microM for II) or antipain (Ki = 1.41 microM for I and 1.45 microM for II). Thus, this is the first report describing the specificity and kinetics of calpains I and II.     

Kinin release from kininogens by calpains

During the investigation of inhibitory activity of kininogens toward calpains [EC 3.4.22.17], we found that lysyl-bradykinin was liberated from both high molecular weight (HMW) and low molecular weight (LMW) kininogens by the action of the calpains. The kinin liberation occurred in a limited range of calpain to kininogen molar ratios of 0.5:1 to 8:1, and in that condition calpains were simultaneously inhibited 20 to 80% by kininogens. The maximum level of kinin release from HMW and LMW kininogens by calpain I was about 25% and that by calpain II was 20%. These results suggest that in case of inflammation the kininogens play two physiologically distinct roles by interaction with calpains: to release lysyl-bradykinin and to inhibit proteinase activity of calpains derived from the damaged tissues.     

Ca²+-induced release of mitochondrial m-calpain from outer membrane with binding of calpain small subunit and Grp75

Although mitochondrial μ- and m-calpains play significant roles in apoptotic cell death, their activating mechanisms have not been determined. The purpose of this study was to determine the core factors that are involved in activating mitochondrial outer membrane (OM)-bound calpains. To accomplish this, we solubilized OM-bound calpains and separated them by DEAE-Sepharose column chromatography, and identified them by immunoblots. We also determined the core factors that activated the OM-bound calpains and release them from the OM by calpain assays, immunoprecipitations, and immunoblots. The OM-bound m-calpain large subunit was not associated with the small subunit or with Grp75 chaperone. Free calpain small subunit was located in the IMS and caused the release of the OM-bound m-calpain large subunit from the OM together with Grp75, ATP, and Ca2+. Our results showed that the activating mechanism of mitochondrial OM-bound m-calpain and the release of mitochondrial m-calpain from the OM have important implications in facilitating apoptotic cell death.     

Characterization of Ca2+-dependent neutral protease (calpain) from human blood flukes, Schistosoma mansoni

Calcium-dependent, neutral cysteine-proteases (calpain) were purified from human blood flukes, Schistosoma mansoni. The electrophoretic mobilities, Western blot analyses and high specificity to peptide inhibitors confirmed the presence of both calpain I and II in the purified preparation. The schistosome calpains were localized in the surface syncytial epithelium and underlying musculature. Using peptide inhibitors, calpain was shown to function as a mediator of the surface membrane synthetic process. Since there was also no immunological cross-reactivity between vertebrate and schistosome calpains using antibodies affinity-purified from native and recombinant schistosome calpains, this protease may be usefully investigated as forming the basis of a molecular vaccine against schistosomiasis.     

Drosophila Calpain B is monomeric and autolyzes intramolecularly

Drosophila calpains, Calpain A and Calpain B, show typical calpain domain structures similar to mammalian calpains. However, the small subunit of mammalian calpains, shown to be essential in both genetic and biochemical aspects, is absent in Drosophila calpains and is not required for enzymatic activity. How they compensate for the lack of small subunit is mostly unknown. Here we conducted experiments using recombinant Drosophila Calpain B for further characterization of the enzyme with particular focuses on two issues: possibility of homodimerization and mode of autolysis. The native molecular weight of Calpain B indicates that the active enzyme is primarily monomeric. Co-expression of two recombinant Calpain B proteins each with a unique affinity tag and a subsequent single round of affinity tag purification resulted in isolation of only one recombinant calpain type, suggesting there is no homodimeric interaction. Also the C-termini of Drosophila calpains lack many of the key hydrophobic residues considered to be important in the dimerization of mammalian calpains. Further, initial autolysis of Calpain B seems to occur intramolecularly, which supports the monomeric nature of Drosophila calpains. These results strongly suggest that dimerization is not an essential requirement for Drosophila calpains.     

Interaction of human calpains I and II with high molecular weight and low molecular weight kininogens and their heavy chain: mechanism of interaction and the role of divalent cations

Calpain I prepared from human erythrocytes was half-maximally and maximally activated at 23 and 35 microM calcium ion, and two preparations of calpain II from human liver and kidney were half-maximally activated at 340 and 220 microM calcium ion and maximally activated at 900 microM calcium ion, respectively. High molecular weight (HMW) and low molecular weight (LMW) kininogens isolated from human plasma and the heavy chain prepared from these proteins inhibited calpain I as well as calpain II. The molar ratios of calpains to HMW kininogen to give complete inhibition of calpains were 1.4 for calpain I and 2.0 for calpain II, and those of calpains to heavy chain were 0.40-0.66 for calpain I and 0.85 for calpain II. LMW kininogen did not completely inhibit the calpains even with an excess amount of kininogen. The apparent binding ratio of calpain to HMW kininogen estimated from the disc gel electrophoretic analysis, however, was found to be 2:1, whereas those of calpain to LMW kininogen and of calpain to heavy chain were found to be 1:1. Calpains and kininogens failed to form complexes in the absence of calcium ion. In the presence of calcium ion, however, they formed the complexes, which were dissociable by the addition of ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid. The minimum concentrations of calcium ion required to induce complex formation between calpain I and kininogens and calpain II and kininogens were 70 and 100 microM, respectively. Some other divalent cations such as Mn2+, Sr2+, and Ba2+ were also able to induce the complex formation between calpains and kininogens.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparison of calpain I and calpain II from carp muscle

1. The content of calpain II is 3.4 times more than that of calpain I when estimated by the elution profiles from a column of DEAE-cellulose. 2. Calpain I required 1 mM Ca2+ and calpain II required 5 mM Ca2+ to show the full activities. These data demonstrated that Ca2+-sensitivities of both calpains were lower than those of mammalian calpains, respectively. 3. The optimum caseinolytic activity was pH 7.2 for calpain I and pH 7.5 for calpain II. 4. The molecular weight of calpain I was estimated to be 110 k and that of calpain II to be 120 k by gel filtration. 5. Calpain I was much more heat-stable than calpain II around 50-60 degrees C. 6. Both calpains were sensitive to calpastatin, an endogenous inhibitor for calpain.