However, in vivo phagocytosis may be accomplished in the LO LO h

However, in vivo phagocytosis may be accomplished in the LO. LO has been proposed as the principal tissue for the removal of foreign material from the hemolymph. Foreign material present in the hemolymph is agglutinated, phagocyted and degraded in LO. Engulfed material is then destroyed in the LOS (7,8). The LO is invaded by hemocytes, and it has been suggested that this invasion is responsible for the immune related activities within the LO (9). Although the identification of crustacean hemocytes is essential to elucidate their specific immune reactions (10), characterization of hemocyte subpopulations remains uncertain. On the basis of their morphology and presence

of granules, hemocytes are usually classified into three subpopulations; LGH, SGH, and HH (10,11). However, different criteria exist about the nature of HH. According to Hose et al. (12) and Gargioni selleck compound and Barraco (10), HH constitute a differentiated cell subpopulation, characterized by the presence of cytoplasmic glycoprotein deposits and striated granules. Other authors consider HH as undifferentiated hemocytes, precursors of SGH (13) or LGH and SGH (14). Rodríguez et al. (15) identified three monoclonal antibodies (MABs), which could be used as hemocyte subpopulation markers. Antigenic

characterization of shrimp hemocytes separated by isopycnic centrifugation on a discontinuous percoll gradient, showed that 40E2 MAB exhibited specific labeling of LGH, 40E10 MAB recognized vesicles present in SGH and 41B12 MAB labeled vesicles NVP-LDE225 in vivo of hyaline hemocytes (16,17). By western blot and ELISA, Astemizole the MAB 41B12 recognized α2-macroglobulin of crayfish, human, and Farfantepenaeus paulensis (15,17,18). Interestingly Perazzolo et al. (18) reported cellular localization of α2-macroglobulin in granules of LGH. Hemocytes subpopulations involved in the clearance process at the LO require

further studies. Based on PO activity assays, several authors reported the presence of SGH and LGH in the LO and LOS. In addition, van de Braak et al. (19) and Shao et al. (20) reported by ultrastructure the presence of SGH-like cells in the LO. Shao et al. (20) considered the presence of SGH in LO during the infection process to be due to light PO activity in the stromal matrix of LO. Anggraeny and Owens (21) observed low PO activity solely in the LOS and indicated that spent LGH and SGH form spheroids. Winotaphan et al. (22) and van de Braak et al. (23), restrict the presence of HH in the LO to being precursors of granular hemocyte, indicating that LO can be a place of hemocyte differentiation. In this study we used MABs 41B12, 40E10 and 40E2 in order to better understand the role of hemocyte subpopulations involved in the immune process occurring in the LO of L. vannamei.

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