Teri S. Wong

Dietary lutein stimulates immune response in the canine

The possible immuno-modulatory action of dietary lutein in dogs is not known. Female Beagle dogs (17-18-month old; 11.4+/-0.4kg body weight) were supplemented daily with 0, 5, 10 or 20mg lutein for 12 weeks. Delayed-type hypersensitivity (DTH) response to saline, phytohemagglutinin (PHA) and a polyvalent vaccine was assessed on Weeks 0, 6 and 12. Blood was sampled on Weeks 0, 2, 4, 8 and 12 to assess (1) lymphocyte proliferative response to PHA, concanavalin A (Con A), and pokeweed mitogen (PWM), (2) changes in peripheral blood mononuclear cell (PBMC) populations, (3) interleukin-2 (IL-2) production and (4) IgG and IgM production. After the completion of 12-week study, we continued to collect the blood weekly up to 17 weeks to evaluate the changes in immunoglobulin production upon first and second antigenic challenges on Weeks 13 and 15. Plasma lutein+zeaxanthin was undetectable in unsupplemented dogs but concentrations increased (P<0.05) rapidly on Week 2 in lutein-supplemented dogs. Thereafter, concentrations generally continued to increase in dose-dependent manner, albeit at a much slower rate. Dogs fed lutein had heightened DTH response to PHA and vaccine by Week 6. Dietary lutein increased (P<0.05) lymphocyte proliferative response to all three mitogens and increased the percentages of cells expressing CD5, CD4, CD8 and major histocompatibility complex class II (MHC II) molecules. The production of IgG increased (P<0.05) in lutein-fed dogs after the second antigenic challenge. Lutein did not influence the expression of CD21 lymphocyte marker, plasma IgM or IL-2 production. Therefore, dietary lutein stimulated both cell-mediated and humoral immune responses in the domestic canine.

Modulation of humoral and cell-mediated immune responses by dietary lutein in cats.

The immuno-modulatory role of dietary lutein in domestic cats is unknown. Female Tabby cats (10-month old; n=56) were supplemented daily for 12 weeks with 0, 1, 5 or 10mg lutein. Blood was collected on Weeks 0, 2, 4, 8 and 12 to assess the following: (1) mitogen-induced peripheral blood mononuclear cells (PBMCs) proliferation, (2) changes in PBMC subpopulations, (3) interleukin-2 (IL-2) production and (4) plasma immunoglobulin (Ig)G production. In addition, delayed-type hypersensitivity (DTH) response to concanavalin A (Con A) or a polyvalent vaccine was performed on Weeks 0, 6 and 12. Dietary lutein increased plasma lutein concentrations in a dose-dependent manner (p<0.001) and concentrations had not reached steady state after 12 weeks of feeding in cats given 5 or 10mg lutein. Concentrations of plasma retinol and alpha-tocopherol were not influenced by diet. The DTH response to vaccine but not to Con A increased (p<0.05) in a dose-dependent manner on Week 6. Compared to control, cats fed lutein also showed enhanced Con A- and pokeweed mitogen-stimulated PBMCs proliferation. Dietary lutein also increased the percentages of CD4+ and CD21+ lymphocytes on Week 12 but had no significant effect on pan T, CD8 and MHC class II markers. Plasma IgG was higher (p<0.05) in cats fed 10mg lutein on Weeks 8 and 12. These results support the immuno-modulatory action of lutein in domestic cats.

Dietary Lutein But Not Astaxanthin or β-Carotene Increases pim-1 Gene Expression in Murine Lymphocytes

This study investigates the effect of dietary carotenoids on pim-1 gene expression in mouse splenocytes. Female BALB/c mice were fed 0%, 0.02%, or 0.4% astaxanthin, beta-carotene, and lutein for two weeks. Plasma and liver were obtained for the analysis of carotenoids. Splenocytes were isolated and cultured in the presence of concanavalin A, and the level of pim-1 mRNA was determined by Northern blot analysis. None of the carotenoids were detectable in the plasma and liver of unsupplemented mice. In plasma the concentration of astaxanthin (4.9-54.7 mumol/l) was dramatically higher than that of lutein (1.4-2.0 mumol/l) and beta-carotene (0.1-0.7 mumol/l). Carotenoid uptake by the spleen but not the liver reflected that observed in plasma. In mice fed 0.4% of each carotenoid, the absolute concentration of the carotenoid in the liver was highest for astaxanthin (24 nmol/g) followed by beta-carotene (7.5 nmol/g) and lutein (1.58 nmol/g). Mice fed lutein showed a dose-related increase in pim-1 mRNA expression. The steady-state level of pim-1 mRNA in mice fed 0.4% lutein was sixfold higher than in mice fed 0.02% lutein. In contrast, dietary astaxanthin and beta-carotene did not affect pim-1 expression. Therefore, an increase in pim-1 mRNA was observed in splenocytes stimulated with concanavalin A in lutein-fed mice. This appears to be a unique effect of lutein and may be associated with its antitumor activity observed in vivo.

Influence of blood monocytes and lymphocytes on progesterone production by granulosa cells from small and large follicles in the pig.

ABSTRACT: The objectives of this study were 1) to determine the influence of lymphocytes and monocytes on progesterone secretion by porcine granulosa cells in culture, and 2) to compare the responses of granulosa cells obtained from small versus large follicles. Granulosa cells were cocultured with lymphocytes, monocytes, and unfractionated mononuclear cells in serum‐free culture medium. Progesterone content of media and cellular DNA were determined after 6, 12, and 24 hrs of culture. Progesterone production by granulosa cells alone or in coculture with erythrocytes increased (P < .001) up to 12 hrs and plateaued thereafter. Cells from large follicles produced approximately two‐fold (P < .01) more progesterone as compared to those isolated from small follicles. Cell numbers, as indicated by DNA, did not change with time in any of the cultures. Lymphocytes stimulated (P < .05) progesterone production by granulosa cells from large follicles but not from small follicles. Similar results were seen when unfractionated mononuclear cells were co‐cultured with granulosa cells. Monocytes stimulated progesterone production by granulosa cells from both large and small follicles. Lymphocytes and monocytes influence steroid secretion by granulosa cells in the pig in vitro. These effects are not mediated through cell proliferation and are influenced by follicle size.

Porcine Lymphocytes Secrete a Bioactive and Immunoreactive LH‐like Factor in Response to LHRH and Concanavalin A

ABSTRACT: Lymphocyte conditioned medium (CM) was prepared by incubating 0 (cell‐free control) or 4 × 106 lymphocytes/ml in serum‐supplemented RPMI containing 0, 10−9, 10−7, and 10−5 M luteinizing hormone releasing hormone (LHRH), 10−5 M LHRH antagonist (LHRHA), or 10−7 M LHRH + 10−5 M LHRHA. Treatments were applied with and without 10 μg/ml concanavalin A (con A), and media were analyzed for LH. Aliquots of the CM from cultures incubated for 48 h were later applied to porcine granulosa cell cultures (suspended to 1.25 × 105 cells in 450 μl). Thereafter, 50 μl of CM were added to granulosa cell cultures. Media were collected after 12, 24, and 48 h and progesterone determined. Immunoreactive LH increased with time of incubation in lymphocyte CM but not cell‐free CM. LH content of lymphocyte CM increased as LHRH concentration increased. LHRHA significantly reduced the amount of LH measured. The presence of con A in the medium resulted in maximal concentrations of LH, irrespective of dose of LHRH or LHRHA. Cell‐free CM containing LHRH, LHRHA, and/or con A did not affect progesterone production by granulosa cells at any of the time periods. Lymphocyte CM containing LHRH caused a dose‐dependent increase in progesterone production at 48 h. This stimulation was blocked by lymphocyte CM containing LHRHA. Lymphocyte CM containing con A also stimulated progesterone production at all of the LHRH concentrations studied. This response was not inhibited by lymphocyte CM containing the LHRHA. Therefore, LHRH and con A stimulate porcine lymphocytes to produce a factor that resembles LH and that stimulates progesterone production by granulosa cells in vitro. The stimulation due to con A appears to be nonspecific while that of LHRH is a specific and dose‐dependent response.