Phenotypic characterization of equine monocyte-derived dendritic cells generated ex vivo utilizing commercially available serum-free medium

Assessing the effects of ex vivo hormonal exposure on oxidative responses in equine leukocytes: A preliminary study

Breed differences exist between horses and ponies in circulating concentrations of several hormones, notably ACTH and insulin. These hormones regulate stress and metabolic responses, but in other species, they also impact leukocyte oxidant responses. The effects of these hormones on equine leukocytes have not been evaluated to date. If equine leukocytes are similarly regulated, breed differences in increased plasma hormone concentrations or altered sensitivity to them at the leukocyte level could result in breed-related differences in oxidant responses or oxidative status. The objective of this study was therefore to determine the effects of ex vivo exposure to adrenocorticotropic hormone (ACTH), α-melanocyte stimulating hormone (α-MSH), insulin, or leptin on reactive oxygen species (ROS) production from leukocytes isolated from horses and ponies. We hypothesized that ACTH, α-MSH, insulin, and leptin would alter oxidant responses from equine leukocytes in a breed specific manner. Blood was collected from 10 apparently healthy Quarter horses and seven Welsh ponies for isolation of neutrophils and peripheral blood mononuclear cells (PBMCs) via density gradient centrifugation. Cells were incubated with media (negative control), microbial antigens (positive control), or ACTH, α-MSH, leptin, or insulin for two hours. Induced ROS production was quantified with a previously validated fluorometric assay. Data was compared within groups by comparing a stimulant within a group (horses or ponies) to baseline, between groups by comparing horse response to pony response, and among stimulants using one- and two-way, repeated measures ANOVA (P<0.05). There was no significant effect of breed on basal, microbial-induced, or hormone-induced ROS production from neutrophils (P=0.465) or PBMCs (P=0.749), but in neutrophils, a significant interaction between breed and stimulant was present (P=0.037). ROS production from PBMCs from horses after hormone exposure did not differ from cells exposed to media only (P=0.1520-0.8180). Similarly, neither leptin nor insulin exposure significantly induced ROS production from PBMCs from ponies (P= 0.2645 and 0.4678 respectively), but exposure to ACTH or α-MSH induced a significant increase in ROS production (P=0.0441 and 0.0440 respectively) compared to unstimulated cells. Hormones that vary in availability among breeds may induce ex vivo pro-oxidant responses in equine leukocytes, but specific effects are breed-, leukocyte type-, and hormone-dependent. Breed differences in hormonally induced leukocyte ROS production may warrant further investigation in the context of circulating oxidative stress and how this might relate to future disease risk.

The effect of foal or adult horse plasma on equine monocyte-derived dendritic cell phenotype and function

Immunological and endocrine immaturity in foals increases foal morbidity and mortality from bacterial sepsis. Dendritic cells (DC) are critical in activating the adaptive immune response, but foal DC are phenotypically and functionally different than those of adult horses. Age-related variations in availability of some soluble plasma factors, such as hormones, might govern some age-related differences in DC function. Effects of exposure to plasma factors on equine DC phenotype and function have not been described. We hypothesized that exposure to plasma from foals or adult horses would differentially impact monocyte-derived DC (MoDC) phenotype and function. Eight healthy adult horses and 8 healthy foals were divided into pairs of one adult horse and one foal. Blood was collected from each pair for MoDC generation when foals were 1 and 30 days of age. MoDC from horses and foals were then exposed to killed whole-cell bacteria in the presence of their own age-matched plasma, plasma from the opposite-aged animal in the pair, and serum-free medium alone (control). Expression of DC-relevant surface markers (MHC class-II, CD86, and CD14) and endocytosis capability were measured by flow cytometry. Supernatant cytokine concentrations (IL-4, IL-17, IFN-γ, and IL-10) were quantified with a validated bead-based immunoassay. Data were analyzed using linear mixed-effects and Tobit regression models (P < 0.05). The percentage of MoDC expressing surface markers MHC class-II and CD86 was reduced in MoDC derived from 1-day-old foals in comparison to adult horse MoDC when cultured in medium alone or with either source of plasma (P = 0.0001). Foal and adult horse MoDC cultured in either source of plasma expressed more CD86 and less CD14 than cells cultured in serum-free medium alone (P ≤ 0.02). Adult horse and foal MoDC exposed to bacterial antigen in the presence of 1-day-old foal plasma secreted less IL-10 (P ≤ 0.0008) compared to those cultured in adult horse plasma. Endogenous production of IL-17 by MoDC from foals at day 1 of age cultured in adult plasma was increased compared to foal MoDC cultured in serum-free medium (P = 0.004). Phagocytosis of killed, labeled Staphylococcus aureus was reduced when MoDC generated from foals or adult horses were exposed to plasma from foals at day 1 or 30 of age (P ≤ 0.03). Age-related variation in soluble plasma factors appear to regulate equine MoDC function, but specific plasma factors capable of regulating MoDC phenotype or function were not defined in this study.