Eosinophils isolated by magnetic cell sorting respond poorly to lipid chemoattractants.

BACKGROUND: Eosinophils play an important role in allergic inflammation. In vitro methods to isolate human eosinophils for the study of chemotactic responses are essential in understanding the mechanisms involved in tissue eosinophilia. OBJECTIVE: We compared LTB4 and PAF-induced chemotactic responses of eosinophils isolated by the standard Percoll (positive selection) versus the magnetic cell separation systems (MACS) (negative selection) technique. METHODS: Discontinuous Percoll gradients were preceded by dextran and Ficoll-Paque steps, and followed by gelatin wash and red blood cell (RBC) lysis. MACS isolation included Percoll 1.090 g/mL layering and RBC lysis; incubation with CD16 antibody conjugated to magnetic beads (to bind neutrophils); and isolation of eluate from column positioned in magnet. RESULTS: Percoll-isolated eosinophils migrated to the lipid mediators, LTB4 and PAF, in a dose-responsive fashion. Although MACS isolation provided a greater number and higher purity of eosinophils, these eosinophils migrated less to LTB4 and PAF. Neither dextran sedimentation, dextran and Ficoll-Paque, nor dextran Ficoll-Paque and Percoll prior to MACS isolation reversed the decreased chemotactic responses observed with MACS isolated eosinophils. Further, Percoll-isolated eosinophils further purified with CD16 MicroBeads did not respond as well to LTB4 or PAF. CONCLUSIONS: The technique used to isolate eosinophils clearly affects the chemotactic responsiveness of this cell to LTB4 and PAF. Since several in vivo studies suggest that LTB4 and PAF are eosinophil chemoattractants, Percoll isolation of these cells might be more appropriate for studies involving eosinophil chemotactic responses to these lipid mediators.

Isolation technique alters eosinophil migration response to IL-8.

Disparate reports exist on the eosinophil chemotactic capacity of interleukin-8 (IL-8). We hypothesized that the difference is due to the methods used to purify eosinophils. We therefore compared the eosinophilotactic capacity of IL-8 on human cells isolated by Percoll (positive selection) vs. magnetic cell separation system (MACS) (negative selection). Discontinuous Percoll gradients were preceded by dextran and Ficoll-Paque steps, and followed by gelatin wash and red blood cell (RBC) lysis. MACS isolation included: Percoll 1.090 g/ml layering and RBC lysis; incubation with CD16 antibody conjugated to magnetic beads (to bind neutrophils); and isolation of eluate from column positioned in magnet. Percoll isolated eosinophils migrated to IL-8 in a dose-responsive fashion. Although MACS isolation provided a greater number and higher purity of eosinophils, these eosinophils did not migrate to IL-8. Neither dextran sedimentation, Ficoll-Paque and Percoll prior to, nor Percoll discontinuous gradients subsequent to, MACS isolation reversed the negative chemotactic response. Moreover, Percoll-isolated eosinophils further purified with CD16 MicroBeads no longer chemotactically responded to IL-8. This inhibition was not due to change in eosinophil purity, a loss of eosinophil adhesion molecules or activation markers, the presence of a soluble neutrophil or eosinophil inhibitor or the effect of the magnet. Thus, the technique used to isolate eosinophils clearly affects the chemotactic responsiveness of this cell to IL-8. Since several in vivo studies suggest that IL-8 is an eosinophil chemoattractant, Percoll isolation of these cells might be more appropriate for studies involving eosinophil chemotactic responses to IL-8.

Effect of melatonin on pituitary secretion of prolactin in vitro during delayed implantation and the periimplantation period in the spotted skunk.

The pars tuberalis of the western spotted skunk is the only region of the brain known to bind 2-[125I]iodomelatonin, thus suggesting that this region of the pituitary might be essential in mediating the effects of melatonin in this species. Female skunks were killed during short- and long-day photoperiods. Hemisections of the adenohypophysis, with and without the pars tuberalis were cultured in the presence and absence of 10 nM melatonin to determine whether the pars tuberalis mediates the previously observed suppressive effects of melatonin on the seasonal increase in plasma prolactin levels in this species. Pituitaries obtained during long-day photoperiods secreted significantly more prolactin than those obtained during the short-day photoperiod. Melatonin had no effect on pituitary response to gonadotropin releasing hormone and failed to inhibit prolactin secretion during the 48 h culture period. However, melatonin significantly reduced the inhibitory effects of dopamine on prolactin secretion. The latter response was observed in both photoperiods and in the presence and absence of the pars tuberalis. These results suggest that the pars tuberalis does not mediate the inhibitory effect of melatonin on prolactin secretion in the absence of the hypothalamus.

Changes in concentration of adenosine triphosphate and adenosine diphosphate in individual preimplantation sheep embryos.

Concentrations of ATP and ADP were measured in 156 sheep embryos by means of an ultramicrofluorescence assay. Stages of preimplantation development measured included unfertilized oocytes through blastocyst-stage embryos. ATP concentrations remained constant through the 8-cell stage; then ATP decreased significantly (p < 0.025) at the morula stage and remained low through the blastocyst stage. ADP concentrations did not change throughout the embryonic stages measured. Decreased levels of ATP with constant levels of ADP caused the ATP:ADP ratio to decrease significantly (p < 0.025) between the 8-cell and morula stages. We suggest that the increase in glucose uptake by sheep embryos observed at the morula stage of development may be due, in part, to a decrease in the ATP:ADP ratio.