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.     

Role of calpains in promoting desmin filaments depolymerization and muscle atrophy

Muscle atrophy is an inevitable sequel of fasting, denervation, aging, exposure to microgravity, and many human diseases including, cancer, type-2 diabetes, and renal failure. During atrophy the destruction of the muscle's fundamental contractile machinery, the myofibrils, is accelerated leading to a reduction in muscle mass, weakness, frailty, and physical disability. Recent findings indicate that atrophy can be a major cause of death in affected individuals, and inhibition of muscle wasting is likely to prolong survival. Major advances in our understanding of the mechanisms for myofibril breakdown in atrophy include the discovery of biological pathways and key components that play prominent roles. On fasting or denervation, degradation of myofibrillar proteins requires an initial dissociation of the desmin cytoskeleton, whose integrity is critical for myofibril stability. This loss of desmin filaments involves phosphorylation, ubiquitination, and subsequent depolymerization by calpain-1, and appears to reduce myofibrils integrity and facilitate their destruction. Consequently, depolymerization of desmin filament in atrophy seems to be an early key event for overall proteolysis. A focus of this review is to discuss these new insights and the specific role of calpain-1 in promoting desmin filaments loss, and to highlight important key questions that merit further study.     

Activation of calpains mediates early lung neutrophilic inflammation in ventilator-induced lung injury

Lung inflammatory responses in the absence of infection are considered to be one of primary mechanisms of ventilator-induced lung injury. Here, we determined the role of calpain in the pathogenesis of lung inflammation attributable to mechanical ventilation. Male C57BL/6J mice were subjected to high (28 ml/kg) tidal volume ventilation for 2 h in the absence and presence of calpain inhibitor I (10 mg/kg). To address the isoform-specific functions of calpain 1 and calpain 2 during mechanical ventilation, we utilized a liposome-based delivery system to introduce small interfering RNAs targeting each isoform in pulmonary vasculature in vivo. Mechanical ventilation with high tidal volume induced rapid (within minutes) and persistent calpain activation and lung inflammation as evidenced by neutrophil recruitment, production of TNF-α and IL-6, pulmonary vascular hyperpermeability, and lung edema formation. Pharmaceutical calpain inhibition significantly attenuated these inflammatory responses caused by lung hyperinflation. Depletion of calpain 1 or calpain 2 had a protective effect against ventilator-induced lung inflammatory responses. Inhibition of calpain activity by means of siRNA silencing or pharmacological inhibition also reduced endothelial nitric oxide (NO) synthase (NOS-3)-mediated NO production and subsequent ICAM-1 phosphorylation following high tidal volume ventilation. These results suggest that calpain activation mediates early lung inflammation during ventilator-induced lung injury via NOS-3/NO-dependent ICAM-1 phosphorylation and neutrophil recruitment. Inhibition of calpain activation may therefore provide a novel and promising strategy for the prevention and treatment of ventilator-induced lung injury.     

Role of calpains in diabetes mellitus: a mini review

Type 2 diabetes mellitus (T2DM) is characterized by defects in haepatic glucose production, insulin action and insulin secretion, which can also lead to a variety of secondary disorders. The disease can lead to death without treatment and it has been predicted that T2DM will affect 215 million people world-wide by 2010. T2DM is a multifactorial condition whose precise genetic causes and biochemical defects have not been fully elucidated but at both levels, calpains appear to play a role. Positional cloning studies mapped T2DM susceptibility to CAPN10, the gene encoding the intracellular cysteine protease, calpain 10. Further studies have shown a number of non-coding polymorphisms in CAPN10 to be functionally associated with T2DM whilst the identification of coding polymorphisms, suggested that mutant calpain 10 proteins may also contribute to the disease. The presence of both calpain 10 and its mRNA have been demonstrated in tissues from several mammalian species whilst calpain 10 appears to be associated with pathways involved in glucose metabolism, insulin secretion and insulin action. It appears that other calpains may also participate in these pathways and here we present an overview of recent studies on calpains and their putative role in T2DM.     

Role of calpains in diabetes mellitus: A mini review

Type 2 diabetes mellitus (T2DM) is characterized by defects in haepatic glucose production, insulin action and insulin secretion, which can also lead to a variety of secondary disorders. The disease can lead to death without treatment and it has been predicted that T2DM will affect 215 million people world-wide by 2010. T2DM is a multifactorial condition whose precise genetic causes and biochemical defects have not been fully elucidated but at both levels, calpains appear to play a role. Positional cloning studies mapped T2DM susceptibility to CAPN10, the gene encoding the intracellular cysteine protease, calpain 10. Further studies have shown a number of non-coding polymorphisms in CAPN10 to be functionally associated with T2DM whilst the identification of coding polymorphisms, suggested that mutant calpain 10 proteins may also contribute to the disease. The presence of both calpain 10 and its mRNA have been demonstrated in tissues from several mammalian species whilst calpain 10 appears to be associated with pathways involved in glucose metabolism, insulin secretion and insulin action. It appears that other calpains may also participate in these pathways and here we present an overview of recent studies on calpains and their putative role in T2DM. (Mol Cell Biochem 261: 161–167, 2004)     

Role of calpains in diabetes mellitus-induced cataractogenesis: A mini review

Premature visual impairment due to lens opacification is a debilitating characteristic of untreated diabetes. Lens opacification is primarily due to the insolubilization of crystallins, proteins essential for lens optical properties, and recent studies have suggested that a major cause of this insolubilization may be the unregulated proteolysis of crystallins by calpains. These are intracellular cysteine proteases whose activation requires the presence of calcium (Ca²⁺) and elevated levels of lens Ca²⁺ is a condition associated with both diabetic cataractogenesis and other forms of the disorder. A number of calpains have been identified in the lens, including calpain 2, calpain 10 and two isozymes of calpain 3:Lp82 and Lp85. The use of animal hereditary cataract models have suggested that calpain 2 and/or Lp82 may be the major calpains involved in murine cataractogenesis with contributions from calpain 10 and Lp85. However, calpain 2 appears to be the major calpain involved in murine diabetic cataractogenesis and the strongest candidate of the calpains for a role in human types of cataractogenesis. Here, we present an overview of recent evidence on which these observations are based with an emphasis on the ability of calpains to proteolyse lens crystallins and calpain structural features, which appear to be involved in the Ca²⁺-mediated activation of these enzymes. (Mol Cell Biochem 261: 151–159, 2004)     

Hydrophobic association of calpains with subcellular organelles. Compartmentalization of calpains and the endogenous inhibitor calpastatin in tissues

Calpains I and II isolated from diverse tissues possess both Ca2+-independent, and Ca2+-dependent accessible hydrophobic regions. Possible subcellular organelle association of calpains involving these hydrophobic regions was studied. By homogenizing rat tissues directly in Ca2+ (50 microM), about 30-60% of the cytosolic calpain I and II activity reversibly associated with isolated subcellular fractions (microsomal greater than plasma membrane greater than nuclear). After binding to the particulate fraction, calpain II converted to a calpain I-like form exhibiting stronger Ca2+-independent binding to phenyl-Sepharose and a lower Ca2+ requirement for optimal activity. However, it retained its DEAE-cellulose chromatographic pattern, and precipitated with monospecific anti-calpain II antibodies. Although purified calpastatin (endogenous inhibitor) is known to form a Ca2+-dependent complex with calpains, it was not able to reverse the binding of calpains to the particulate fraction upon short incubation. It was, however, effective in blocking calpain binding when the isolated cytosolic fraction or a mixture of purified calpain and calpastatin was preincubated in the presence of Ca2+, and then added to the particulate fraction. Extraction of tissues under controlled conditions revealed that in fact calpains are already loosely associated with subcellular organelles even in the absence of Ca2+. This is the reason why in the crude homogenates with the addition of Ca2+, calpains strongly bind to the particulate fraction without interference by cytosolic calpastatin. Although calpastatin by complexing initially to calpain can prevent the association of this protease with subcellular organelles, it cannot dissociate calpains already bound to these subcellular fractions. By prior Ca2+-independent association with the hydrophobic proteins present in the subcellular fractions, calpains overcome the 3- to 30-fold inhibitory excess of calpastatin in tissues.     

Bradykinin and kininogens in bovine milk

Two peptides exhibiting kinin activity in an isolated rat uterus assay were purified from pasteurized skim bovine milk. The amino acid sequence of the more prominent peptide was found to be that of bradykinin. Partially purified kinin preparations were also obtained from N-tosyl-L-phenylalanyl chloromethyl ketone-treated trypsin digests of non-fat dry milk and insoluble lactalbumin. The application of fast atom bombardment/mass spectrometry permitted detection of the bradykinin protonated molecular ion in each of these samples. Collision-activated decomposition of the ion of m/z 1061 confirmed it to be the protonated molecular ion of bradykinin. Fast atom bombardment/mass spectrometry analysis further confirmed the occurrence of bradykinin in a pancreatic kallikrein digest of a partially purified bovine milk kininogen preparation. In apparent contrast with bovine plasma kininogens, the forms of kininogen which occur in milk include a high Mr kininogen (Mr greater than 68,000) and a low Mr kininogen (Mr 16,000-17,000). Kinin formation from the high Mr kininogen is catalyzed by porcine pancreatic kallikrein or trypsin.     

Role of IL-18 in acute lung inflammation.

We have examined the role of IL-18 after acute lung inflammation in rats caused by intrapulmonary deposition of IgG immune complexes. Constitutive IL-18 mRNA and protein expression (precursor form, 26 kDa) were found in normal rat lung, whereas in inflamed lungs, IL-18 mRNA was up-regulated; in bronchoalveolar (BAL) fluids, the 26-kDa protein form of IL-18 was increased at 2-4 h in inflamed lungs and remained elevated at 24 h, and the "mature" protein form of IL-18 (18 kDa) appeared in BAL fluids 1-8 h after onset of inflammation. ELISA studies confirmed induction of IL-18 in inflamed lungs (in lung homogenates and in BAL fluids). Prominent immunostaining for IL-18 was found in alveolar macrophages from inflamed lungs. When rat lung macrophages, fibroblasts, type II cells, and endothelial cells were cultured in vitro with LPS, only the first two produced IL-18. Intratracheal administration of rat recombinant IL-18 in the lung model caused significant increases in lung vascular permeability and in BAL content of neutrophils and in BAL content of TNF-alpha, IL-1beta, and cytokine-induced neutrophil chemoattractant, whereas intratracheal instillation of anti-IL-18 greatly reduced these changes and prevented increases in BAL content of IFN-gamma. Intratracheal administration of the natural antagonist of IL-18, IL-18 binding protein, resulted in suppressed lung vascular permeability and decreased BAL content of neutrophils, cytokines, and chemokines. These findings suggest that endogenous IL-18 functions as a proinflammatory cytokine in this model of acute lung inflammation, serving as an autocrine activator to bring about expression of other inflammatory mediators.     

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)     

Induction of C-reactive protein, serum amyloid P component, and kininogens in the submandibular and lacrimal glands of rats with experimentally induced inflammation.

The mRNAs for acute-phase proteins and kininogens were found to be increased in the submandibular gland (SMG) and extraorbital and intraorbital lacrimal gland (ELG and ILG) in response to experimentally induced inflammation in rats; i.e., 24 hours after subcutaneous injection of turpentine oil, mRNAs for C-reactive protein (CRP), serum amyloid P component (SAP), and H- and T-kininogens were induced in the SMG, ELG, and ILG of rats, whereas these mRNAs were not detected in the same tissues of normal control rats. The induction of mRNAs for these inflammatory proteins by turpentine oil was preceded by a transient increase in the level of mRNA for tumor necrosis factor-alpha (TNF-alpha) at 6 hours after subcutaneous injection of the oil. This was confirmed by injection of another inflammation inducer, lipopolysaccharide (LPS), which induced the TNF-alpha mRNA in the same way at 6 hours as turpentine oil did. The up-regulation of acute-phase proteins including kininogens in the SMG, ELG, and ILG suggest the existence of a strict defense system in the exocrine glands.     

Immunological characterization of rat kininogens with monoclonal antibodies to T-kininogen. Distinction between the different domains of T-kininogen and the multiple rat kininogens.

A panel of 16 monoclonal antibodies (mAb) were produced against rat T-kininogen to characterize this family of proteins. These mAbs bound 125I-T-kininogen by radioimmunoassay as well as reacting strongly with immobilized T-kininogen in an enzyme-linked immunosorbent assay (ELISA). The reactivity of these antibodies with proteolytic fragments of T-kininogen demonstrated the recognition of several different epitopes. One antibody was specific for the domain 1 of the heavy chain and/or the light chain, twelve antibodies were specific for domain 2 and three antibodies were specific for domain 3. All monoclonal antibodies recognized the two forms of T-kininogen encoded by the two different T-kininogen genes, TI and TII kininogen, except antibody TK 16-3.1 which uniquely reacted with TII kininogen. Two antibodies recognizing domain 2 cross-reacted with the high-molecular-mass kininogen (H-kininogen), whereas all the other monoclonal antibodies were specific to T-kininogen and did not recognize the heavy chain of H-kininogen. None of the antibodies tested altered the thiol protease inhibitory activity of T-kininogen, its partial proteolysis by rat mast cell chymase or the hydrolysis of H-kininogen by rat urinary kallikrein. The use of these antibodies in the development of sensitive ELISA to measure T-kininogen levels in plasma, urine, liver microsomes and hepatocytes is described. Two different forms of T-kininogen were distinguished by these monoclonal antibodies in Western blotting using rat plasma. The localization of T-kininogen was defined using these monoclonal antibodies by immunohistochemistry in rat liver hepatocytes and rat kidney.     

Properties of chemically oxidized kininogens

Kininogens are multifunctional proteins involved in a variety of regulatory processes including the kinin-formation cascade, blood coagulation, fibrynolysis, inhibition of cysteine proteinases etc. A working hypothesis of this work was that the properties of kininogens may be altered by oxidation of their methionine residues by reactive oxygen species that are released at the inflammatory foci during phagocytosis of pathogen particles by recruited neutrophil cells. Two methionine-specific oxidizing reagents, N-chlorosuccinimide (NCS) and chloramine-T (CT), were used to oxidize the high molecular mass (HK) and low molecular mass (LK) forms of human kininogen. A nearly complete conversion of methionine residues to methionine sulfoxide residues in the modified proteins was determined by amino acid analysis. Production of kinins from oxidized kininogens by plasma and tissue kallikreins was significantly lower (by at least 70%) than that from native kininogens. This quenching effect on kinin release could primarily be assigned to the modification of the critical Met-361 residue adjacent to the internal kinin sequence in kininogen. However, virtually no kinin could be formed by human plasma kallikrein from NCS-modified HK. This observation suggests involvement of other structural effects detrimental for kinin production. Indeed, NCS-oxidized HK was unable to bind (pre)kallikrein, probably due to the modification of methionine and/or tryptophan residues at the region on the kininogen molecule responsible for the (pro)enzyme binding. Tests on papain inhibition by native and oxidized kininogens indicated that the inhibitory activity of kininogens against cysteine proteinases is essentially insensitive to oxidation.     

Role of microglia in CNS inflammation

There is increasing confusion about the meaning of the terms inflammation, neuroinflammation, and microglial inflammation. We aim in this review to achieve greater clarity regarding these terms, which are essential for our understanding of the role of microglia in CNS inflammatory conditions. The important concept of sterile inflammation is explained against the backdrop of classical inflammation, and its key differences from what researchers refer to when they use the terms neuroinflammation and microglial inflammation are illustrated. We propose to replace the term "neuroinflammation" with "microglial activation" or "CNS pseudo-inflammation", if microglial activation does not suffice. In addition, we recommend abandoning the terms "microglial inflammation" and "inflamed microglia" because of the lack of a clear concept behind them.