Localization of glandular kallikrein in nasal mucosa of allergic and nonallergic individuals

Kallikrein cascade and cytokines in inflamed joints

Rheumatoid arthritis is a chronic multi-system disease of unknown aetiology. The current hypothesis is that an unknown antigen triggers an autoimmune response in a genetically susceptible individual. The predominant pathological change is that of an inflammatory synovitis, characterised by cellular infiltrates and angiogenesis, with subsequent bone and cartilage destruction. These pathological changes are as a result of the activation of a variety of cells, inflammatory mediators, and effector molecules. The pro-inflammatory kinins and cytokines appear to play a central role in the pathogenesis of rheumatoid arthritis. Sufficient evidence exists that establishes a key role for the kallikrein-kinin cascade in inflamed joints. In addition, there appears to be an inter-relationship between cytokines and kinins in the inflammatory process. Kinins induce the release of cytokines, and cytokines have been shown to augment the effects of kinins. This may lead to an enhancement and perpetuation of the inflammatory process. In this review, we report a first study, correlating markers of disease with the kallikrein-kinin cascade and with cytokines.

The kinin system in rhinitis and asthma

The past decade has seen renewed interest in the potential role of kinins in airway diseases. The correlation between kinin generation and symptoms of inflammation, together with the demonstration that administration of kinins to the airway mucosa can induce relevant symptoms, provides strong circumstantial support for a role of kinins in the pathogenesis of airway diseases, such as allergic and viral rhinitis and asthma. Definitive studies of the effects of blockade of kinin actions on symptomatic responses, however, are still needed. The effects of kinins in the airways, and the mechanisms by which they exert their actions clearly vary depending on the presence of inflammation in the airways. Although a growing body of evidence implicates activation of sensory nerves as an important component of kinin effects in inflamed airways, the components of inflammation that modify the response of these sensory nerves, the mechanisms by which neuronal responsiveness alters, and the degree of selectivity of neuronal activation to bradykinin are all topics that require further delineation.

Distribution of tissue kallikreins in lower vertebrates: potential physiological roles for fish kallikreins

Fish skeletal muscle prokallikrein was purified from black sea bass, Centropritis striata, and used for the production of polyclonal antiserum. Tissue proteins from primitive fish and teleosts, an alligator, and an insectivore were resolved by sodium dodecylsulfate-polyacrylamide gel electrophoresis, Western blotted, and probed with fish muscle prokallikrein antiserum. A recurring theme was the presence of approximately 36 and 72 kDa kallikrein-like proteins in skeletal muscle, heart, gill, kidney, and spleen of higher teleosts and in selected tissues of sturgeon, shark, alligator, and mole. The presence of immunoreactive kallikreins in osmoregulatory organs such as the gills of teleosts and the rectal gland of sharks signifies a potential role for these proteins in osmoregulation. Black sea bass, rock bass, and sturgeon contained many immunoreactive kallikreins in their swimbladders, which implicates a role for kallikreins in the regulation of blood flow and vascular permeability to facilitate gas exchange within the bladder. Kallikreins were consistently identified in skeletal muscle and heart of all the species evaluated and may regulate local blood flow, muscle contraction or relaxation, or participate in various transport processes. The antiserum to fish prokallikrein recognized immunoreactive kallikreins from pancreatic tissues from fish and lower vertebrates, but not from the pyloric caecum of sea bass. The wide distribution of tissue kallikrein in lower vertebrates suggests that it may participate in a variety of physiological functions.

Tissue kallikrein activity and kinin release in human endothelial cells

The kininogenase, tissue kallikrein (EC 3.4.21.8), has been identified in different blood vessels. The enzyme was mainly found in vascular smooth muscle cells. It is not known whether it is present and functionally active in vascular endothelial cells. The following study investigates the presence of tissue kallikrein in endothelial cells from human umbilical veins and pulmonary arteries. Tissue kallikrein was demonstrated in three ways: 1) by immunostaining in endothelial cells; 2) by measurement of tissue kallikrein activity using a colorimetric assay; 3) by the measurement of kinin release in intact and homogenised endothelial cells with a radioimmunoassay. Immunostaining demonstrated the presence of tissue kallikrein in endothelial cells from human umbilical veins and endothelial cells from human pulmonary arteries. Tissue kallikrein-like activity, measured by the degradation of D-Val-cyclohexyl-Ala-Arg-4-nitraniline, was 3.57 +/- 0.5 mU/10(6) endothelial cells from human umbilical veins and 7.52 +/- 0.84 mU/10(6) endothelial cells from human pulmonary arteries. Intracellular kinin concentrations were 424 +/- 83 pg/10(6) cells in endothelial cells from human umbilical veins and 576 +/- 146 pg/10(6) cells in endothelial cells from human pulmonary arteries, and they increased in a time-dependent manner after homogenisation. The increase was abolished by aprotinin (1000 kIU), an inhibitor of tissue kallikrein in both cell types. Addition of exogenous kallikrein (5 mU) to homogenised cells led to a five fold increase of kinin concentrations after five minutes, indicating a sufficient resource of cellular kininogen. Removal of extracellularly bound kininogen by washing with dextran sulphate (100 mg/l) resulted in an approximately 75% reduction of the cellular kinin release.(ABSTRACT TRUNCATED AT 250 WORDS)

Localization of immunoreactive tissue kallikrein in human trachea

Tissue kallikrein is the major kininogenase detected in bronchoalveolar lavage fluids from asthmatics and may play a particularly important role in kinin generation during asthma. The present study was undertaken to determine the source of tissue kallikrein in the human lower airways. Specific antisera to human tissue kallikrein were used to localize this enzyme by immunocytochemistry in human trachea. Immunoreactive tissue kallikrein was localized in submucosal glands of the lamina propria but was not detected in epithelial cells or goblet cells. Specific staining for tissue kallikrein was not detected in all cells of the submucosal glands but was restricted to cells forming demilunes in the distal portions of the glands. When consecutive serial sections of submucosal glands were alternately stained using antiserum to tissue kallikrein and a periodic acid Schiff stain (to detect mucus), it was revealed that immunoreactive tissue kallikrein was present only in serous cells and not in mucus cells. The localization of tissue kallikrein to the serous cells of submucosal glands should facilitate studies to regulate the release of this enzyme. Regulation of tissue kallikrein release may provide a mechanism to reduce kinin generation during asthma.

Tryptase and histamine as markers to evaluate mast cell activation during the responses to nasal challenge with allergen, cold, dry air, and hyperosmolar solutions

We have used assays for histamine and for the specific mast cell enzyme, tryptase, to examine the response of the nasal mucosa to provocation with several different stimuli and to evaluate the reliability of histamine as a marker of mast cell activation. High levels of histamine detected in baseline lavages of some subjects are not associated with any detectable tryptase, suggesting they are not mast cell derived. During pronounced immediate allergic responses, however, mast cell degranulation clearly occurs, and a striking correlation between histamine and tryptase is observed. This correlation is weaker when a more modest allergic response is induced, possibly reflecting differential diffusion of the two mediators across the epithelium. Provocation of susceptible individuals with cold, dry air leads to increased recoveries of both histamine and tryptase, confirming that mast cell degranulation occurs during this reaction. Although hyperosmolarity of the nasal mucosa may contribute to mast cell degranulation induced by cold, dry air, a brief exposure of the nasal cavity to hyperosmolar mannitol was not associated with measurable production of tryptase. The combined use of histamine and tryptase measurements can therefore provide useful evidence regarding the role of mast cell activation in the pathogenesis of inflammatory responses.