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1

Innate immunity: cells, receptors, and signaling pathways

100%
Blach-Olszewska Z.
Archivum Immunologiae et Therapiae Experimentalis
|
2005
|
vol. 53
|
issue 3
245-253
EN
Essential differences between the innate and acquired branches of immunity are described. These differences concern the detection system (receptors and pathogen structures) and the cells engaged in both systems as well as the effectory mechanisms. In contrast to those of the acquired system, receptors of the innate system, which developed during evolution, recognize unchanged structures on large groups of pathogens (e.g. lipopolysaccharide in Gram-negative bacteria). Two lineages, natural killer (NK) and dendritic cells (DCs), play important roles in the innate system. Phenotypic and functional differentiation is observed among NKs and DCs, so each of their sublineages plays a different role in the innate system. Every lineage of cells of the innate immune system express different stimulatory and sometimes also inhibitory receptors on their surfaces (e.g. NK cells). Among the stimulatory are Toll-like receptors (TLRs), mannose and scavenger receptors, and the stimulatory receptors of NK cells. All TLRs show similarity in structure and in the kind of molecules involved in intracellular signaling. The immune reactions of the innate system involve cytokine-dependent resistance of cells against infection with pathogen, production of cytokines (tumor necrosis factor, interferons, interleukins, chemokines) and MHC-independent killing. Although these reactions protect the host from invasion by microorganisms, they can also be responsible for significant tissue damage or may stimulate the development of autoimmunity. Therefore innate immunity must be under rigorous control. The possible regulatory mechanisms of innate immunity are discussed.
2

Immune phenomena in echinoderms

86%
Glinski Z., Jarosz J.
Archivum Immunologiae et Therapiae Experimentalis
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2000
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vol. 48
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issue 3
189-193
EN
Advances in biochemistry and molecular biology have made it possible to identify a number of mechanisms active in the immune phenomena of echinoderms. It is obvious that echinoderms have the ability to distinguish between different foreign objects (pathologically changed tissues, microorganisms, parasites, grafts) and to express variable effector mechanisms which are elicited specifically and repeatably after a variety of non-self challenges. The molecular and biochemical basis for the expression of these variable defense mechanisms and the specific signals which elicit one type of effector mechanism are not, however, yet well known. The high capacity of coelomocytes to phagocytose, entrap and encapsulate invading microorganisms is a valid immune cell-mediated mechanism of echinoderms. The entrapped bacteria, discharged cellular materials and disintegrating granular cells are compacted and provoke the cellular encapsulation reaction. Moreover, humoral-based reactions form an integral part of the echinoderm defense system against microbial invaders. Factors such as lysozyme, perforins (hemolysins) vitellogenin and lectins are normal constituents of hemolymph, while cytokines are synthesized by echinoderms in response to infection.
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