Increased vascular permeability leading to vascular leakage is a central feature of all inflammatory reactions and is critical for the formation of an inflammatory exudate. The leakage occurs because of gap formation between endothelial cells and breakdown of the basement membrane barriers. The present study aimed to investigate the role of gelatinase B [matrix metalloproteinase 9 (MMP-9)], known to be involved in neutrophil exudation, in changes of vascular permeability at the early stages of acute zymosan peritonitis. We show that although MMP-9 is being released already within the first minutes of peritonitis, its lack, induced pharmacologically or genetically, does not decrease but rather increases vasopermeability. In mice treated with an inhibitor of gelatinases (A and B), a tendency to increased vasopermeability existed, and in MMP-9-/- mice [knockout (KO)], the difference was statistically significant in comparison with their controls. Moreover, in intact KO mice, significantly augmented production of prostaglandin E(2) (PGE(2)) of cyclooxygenase 1 (COX-1) origin was detected, and depletion of peritoneal macrophages, but not mast cells, decreased vasopermeability in KO mice. Thus, the increase of vasopermeability observed on KO mice is a result of the increased production of COX-1-derived PGE(2) by peritoneal macrophages. We conclude that genetic deficiency in gelatinase B might lead to the development of a compensatory mechanism involving the COX pathway.
Peritoneal inflammation is a convenient model for comparisons of modulatory effects of morphine in phylogenetically distant vertebrates. Both in salmon and mice morphine injected intraperitoneally together with an irritant (thioglycollate) significantly inhibits inflammation as estimated by the number of peritoneal leukocytes. The low number of exudate cells in morphine-treated animals seems to be compensated by their high activity, as evidenced by the enhanced phorbol myristate acetate-induced respiratory burst. The morphine-inhibited influx of leukocytes into the irritated peritoneal cavity correlates with the morphine-lowered level of plasma chemotactic factors both in fish and mice. It implies that morphine impairs the level of plasma chemotactic factor either directly (affecting their release from the resident peritoneal cells) or indirectly (decreasing the number of inflammatory leukocytes by inhibition of their migration from hemopoietic sites). The inhibitory effects of morphine on both the cell number and chemoattractant level are completely reversed by the naltrexone pretreatment, which implicates the involvement of opioid receptors.
Supravital species identification of morphologically similar syntopic earthworms inhabiting dung and compost heaps or those from commercial cultures is difficult. The aim of the studies was to find out non-invasive species-specific markers for proper segregation of earthworm species from a dense mixed colony of waste decomposers. Worms were segregated according to external characteristics into Eisenia andrei, Eisenia fetida, and Dendrobaena veneta, and left for reproduction and analysis of non-invasively retrieved coelomocyte-containing coelomic fluid and/or species-specific partial sequences of cytochrome c oxidase subunit I (COI) gene in DNA extracted from amputated tail tips of adults and their offspring. Flow cytometric analysis of coelomocyte samples revealed that amount of nuclear DNA increases in order D. veneta ≪ E. andrei < E. fetida, and intensity of eleocyte-derived fluorescence is lower in D. veneta than in Eisenia spp. Spectrofluorimetry of coelomocyte lysates revealed that the amount of eleocyte-stored riboflavin is significantly lower in coelomocyte lysates from D. veneta than from Eisenia spp., and the emission peak of X-fluorophore is much more distinct in D. veneta than in Eisenia spp. Coelomic fluid of E. andrei exhibits a very distinct spectra of MUG fluorophore which are absent in D. veneta and in the majority of E. fetida, while some E. fetida possess MUG-like fluorophore. Sequences of the COI gene in the DNA of the worms from the mixed colony and their offspring confirmed species identity. In conclusion, species-specific coelomocyte-derived markers may be a useful complement to morphological and DNA-based taxonomy during studies on syntopic earthworms.
Immunocompetent cells of earthworms (coelomocytes) contain adherent amoebocytes and large eleocytes (chloragocytes); the latter are filled with numerous granules. We have previously shown that eleocytes of several (but not all) earthworm species exhibit strong autofluorescence detectable by fluorescent microscopy and flow cytometry. In the present article, the molecular origin of eleocytes autofluorescence was elucidated in coelomocytes expelled via dorsal pores in the integument of Eisenia fetida subjected to electric shock (1 min at 4.5 V). Spectrofluorometry (excitation and emission spectra and fluorescence lifetime), together with HPLC analysis of coelomocyte suspensions and supernatants, indicated that riboflavin but not FMN (flavin mononucleotide) or FAD (flavin-adenine dinucleotide) is the main fluorophore responsible for eleocyte fluorescence in this species. Additionally, lipofuscins are suspected to participate in this phenomenon.
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