Marie-Claude Gagnerault

Pancreatic Lymph Nodes Are Required for Priming of β Cell Reactive T Cells in NOD Mice

Nonobese diabetic (NOD) mice develop spontaneous autoimmune diabetes that results from the destruction of insulin secreting β cells by diabetogenic T cells. The time and location of the encounter of autoantigen(s) by naive autoreactive T cells in normal NOD mice are still elusive. To address these issues, we analyzed diabetes development in mice whose spleen or pancreatic lymph nodes (panLNs) had been removed. Excision of panLNs (panLNx) at 3 wk protected mice against insulin autoantibodies (IAAs), insulitis, and diabetes development almost completely, but had no effect when performed at 10 wk. The protection afforded by panLNx at weaning was not due to modifications of the immune system, the absence of autoreactive T cells, or the increase in the potency of regulatory T cells. That panLNs are dispensable during adult life was confirmed by the capacity of 10-wk-old panLNx irradiated recipients to develop diabetes upon transfer of diabetogenic T cells. In contrast, splenectomy had no effect at any age. Partial excision of mesenteric LN at 3 wk did not prevent accelerated diabetes by cyclophosphamide as panLNx did. Thus, in normal NOD mice, autoreactive T cell initial priming occurs in LNs draining the target organ of the disease from 3 wk of age.

In vivo effects of growth hormone on thymus function in aging mice

It is well demonstrated that the normal functioning of the thymus gland is under neuroendocrine control. Thus, steroid, thyroid, and pituitary hormones can affect distinct structural and/or functional thymic parameters. Particularly growth hormone (GH) was shown to be capable of restoring some thymus functions in old individuals. This prompted us to carry out a multiparametric analysis of the thymus in young, middle-aged, and old mice, subjected to GH treatment lasting 3 or 6 weeks. For that, we treated animals with daily injections of ovine GH (2 micrograms/g BW). Although the general microarchitecture of the thymus remained unchanged following in vivo GH treatment, there was a clearcut increase in thymulin production, independent of the age group analyzed. Regarding the lymphoid compartment, we could not find evidence of changes in total thymocyte numbers nor in the subsets phenotypically defined by the expression of CD3, CD4, and CD8 antigens. Nonetheless, in GH-treated middle-aged and old mice, the concanavalin A-dependent proliferative response of thymocytes, as well as IL-6 production were enhanced compared to age-matched controls. These findings support the notion that GH has a pleiotropic effect upon the thymus, functionally affecting both microenvironmental and lymphoid compartments of the organ.

Specific binding sites for growth hormone in cultured mouse thymic epithelial cells

Growth Hormones bound specifically to murine Thymic epithelial cells, which represent the major component of thymic micro-environment and can be modulated by pituitary hormones. The Kds found with human growth hormone and bovine growth hormone were 0.14 and 0.27 nM with a Bmax 0.56 and 0.35 fmol/10(6) cells respectively. Competition experiment analysis showed ED50 of 0.24 nM for hGH, 0.46 nM for rGH, 0.71 nM for bGH, 11.8 nM for hPRL and 11.2 nM for oPRL. No specific binding of [125I]-oPRL was observed under the same conditions. Both hPRL and bGH showed a negative regulatory effect on the number of the hGH binding sites when incubated with the culture for three days. The presence of GH receptors on Thymic epithelial cells provides biochemical evidence for the effect of GH on thymic function.

Growth Hormone (GH) and Prolactin Receptors in Human Peripheral Blood Mononuclear Cells: Relation with Age and GH-Binding Protein

GH receptors (GHRs) and PRL receptors (PRLRs) were studied in human peripheral blood mononuclear cells (PBMC) using flow cytometry, biotinylated anti-GH receptor monoclonal antibody 10B8, and biotinylated human PRL. Variations of GHR and PRLR expression and the relationship of plasma GHBP and GH receptor in PBMC subsets were examined as a function of age and sex. By double immunofluorescence staining, we show that about 30% of total cells express GH receptors, with a low expression in T cells, whereas almost all B cells and monocytes are GH receptor positive. Four age groups were defined among the 64 normal volunteers, aged 12 to 85 yr, who were included in the study. The percentage of PBMC expressing GH receptors is significantly lower in group 2 (20–40 yr) than in group 1 (12–20 yr) and group 4 (>60 yr). In T cells, monocytes and B cells, no significant changes are detected in either the percentage of GH receptor positive cells or in the GH receptor level per cell. The level of PRLRs expressed in PBMC i...

Effects of growth hormone and thyroxine on thymulin secretion in aging rats

It is well-established that the activity of the endocrine thymus is under neuroendocrine control. In particular, growth hormone (GH) and thyroxine (T4) have been shown to be capable of reconstituting thymus function in hormone-deficient animals. It was therefore of interest to assess the effect of combined administration of ovine GH (0.1 mg/100 g BW/day) and T4 (10 micrograms/100 g BW/day) on serum thymulin levels in young (5 months), old (21 months) and senescent (29-30 months) male Sprague-Dawley rats. Age-matched controls received 0.1 mg bovine serum albumin/100 g BW daily during the same period (14 days). Prolactin (Prl), GH, T4 and triiodothyronine (T3) were measured in serum by radioimmunoassay, whereas serum thymulin was determined by rosette bioassay. As expected, GH and T4 were lower in the old and senescent controls whereas serum Prl displayed a slight age-related increase. No age changes were detected in serum T3. Hormone-treated animals showed supraphysiologic levels of both T4 and T3, but serum levels were comparable among the three treated age groups for each thyroid hormone. Endogenous GH levels were moderately elevated in the treated rats. In the control rats serum thymulin showed a marked reduction from 5 to 21 months of age but no further reduction was observed between 21 and 29-30 months. Hormone treatment induced a mean relative increase (% increase relative to age-matched controls) in serum thymulin of 44, 38 and 48% in young, old and senescent rats, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Autoimmunity during Thymectomy-Induced Lymphopenia: Role of Thymus Ablation and Initial Effector T Cell Activation Timing in Nonobese Diabetic Mice

Autoimmune diseases develop in selected normal mouse strains when thymectomy (Tx) is performed at 3 days of age (d3-Tx). Insufficient T cell regulation after Tx may result from a defect in regulatory T (Treg) cells or from an augmented effector T (Teff) cell number/pathogenicity. We have previously shown that Tx at 3 wk (wk3-Tx), the age of massive islet Ag release, accelerates diabetes onset. We now have determined diabetes incidence in d3-Tx nonobese diabetic mice and compared the frequency and function of their Teff and Treg cells with those of wk3-Tx mice. We found that d3-Tx had no effect on diabetes incidence, but induced gastritis. After day 3 and week 3 Tx, Treg cells were fully competent and their frequency increased. The number of diabetogenic T cells was greatly amplified after wk3-Tx and likely overcame Treg cell control, leading to an early tolerance breakdown. By contrast, in d3-Tx mice, activation concerned few cells and Teff cell amplification remained controlled. This suggests that Tx enhances autoimmunity when it coincides with the first encounter of autoreactive T cells with their cognate Ag. The relationship between Tx-induced lymphopenia, tissue remodeling, and autoimmunity is discussed.

Lymph Node T-Cells Do Not Optimally Transfer Diabetes in NOD Mice

The nonobese diabetic mouse in a model of spontaneous development of autoimmune type I diabetes. The disease can be induced in young, irradiated recipients by injecting splenic T-cells from diabetic donors. The adoptive transfer of diabetes requires the presence of both CD4+ and CD8+ splenic T-cell subsets. To test whether diabetogenic cells distribute in other lymphoid organs of diabetic mice, we first analyzed lymph node cells. Lymph node cells were much less efficient in transferring diabetes than splenocytes. This inefficacious transfer was not attributable to the absence of hematopoietic precursors or a lack of macrophages. Lymph node cells did not protect from the transfer of diabetes by splenocytes, indicating the absence of suppressor cells. Although CD8+ lymph node T-cells seemed functionally comparable to CD8+ splenocytes, CD4+ lymph node T-cells failed to cooperate with CD8+ splenocytes to transfer diabetes. Our study suggests that diabetogenic cells are not evenly distributed in the different lymphoid organs. This may reflect a differential migration pattern of pathogenic T-cells in this animal model.

Neuroendocrine control of thymic hormonal production. II. Stimulatory effects of endogenous opioids on thymulin production by cultured human and murine thymic epithelial cells.

Data have now accumulated to strongly demonstrate that several neuropeptides, including endogenous opioids, can have immunomodulatory functions. Most of the studies have so far focused on the direct action of these substances on lymphocytes. We decided to investigate whether thymic epithelial cells (TEC) - the major component of the thymic microenvironment - could also be modulated by endogenous opioids. Primary cultures of human and murine TEC were subjected to several opioids (alpha-beta- or gamma-endorphins, as well as met- or leuenkephalins) applied in concentrations ranging from 10(-6) to 10(-9) M. On the following days we measured the levels of thymulin (a chemically-defined thymic hormone known to stimulate some steps of T-cell differentiation) in the culture supernatants, as well as the numbers of thymulin containing cells, evaluated by immunofluorescence with an anti-thymulin monoclonal antibody. After treatment of TEC cultures with beta-endorphin or leu-enkephalin a significant increase in the levels of thymulin in the culture media was observed, paralleled by a rise in the percentage of thymulin containing cells. In addition, this stimulatory effect was dose-dependent. Preincubation of the opioids with the specific antibodies abrogated the opioid-induced stimulatory effect on TEC. Moreover, naloxone, an opioid receptor antagonist, blocked the effect of beta-endorphin on thymulin production, suggesting that the effect of this neuropeptide on epithelial cells was mediated by an opioid receptor. Importantly, no effect on thymulin production was observed with the other opioids used, whatever the dose. These results suggest that, at least in vitro, beta-endorphin and leu-enkephalin stimulate the hormonal function of the thymic epithelium. These findings lead to the general concept that the modulatory role of endogenous opioids on the immune system is not restricted to lymphocytes but can also take place at the level of cells belonging to T-cell differentiating microenvironments.

Modifications of the Expression of Homing and Adhesion Molecules in Infiltrated Islets of Langerhans in Nod Mice

The NOD mouse is an experimental model for human autoimmune type I diabetes, in which lymphocyte infiltration (insulitis) into the islets of Langerhans develops from 3-5 weeks of age in both sexes while overt diabetes occurs predominantly in females from 12 weeks of age1. The central role of T cells in insulin-secreting beta cell destruction has been widely documented 2–5. However, the mechanisms of lymphocyte infiltration are still unclear.

Strain-Dependent Migration of CD4 and CD8 Lymphocyte Subsets to Lymph Nodes in NOD (Nonobese Diabetic) and Control Mice

Subpopulations of lymphoid cells were compared with respect to their ability to migrate into peripheral lymphoid organs of nonobese diabetic (NOD) mice and various strains of control mice. In short-term, in vivo homing studies, no major differences in the pattern of homing of B and T cells were observed among all mouse strains studied. On the other hand, CD4 cells localized consistently more efficiently than CD8 cells in both PP and LN of adult NOD and BALB/c mice, whereas both populations migrated roughly equivalently in LN of adult DBA/2, CBA, and C57BL/6 mice. No age-dependent differences in the homing of CD4 and CD8 cells were observed in BALB/c mice. On the contrary, in 2-week-old NOD mice, CD4 and CD8 cells migrated equally well. The preferential entry of CD4 cells in adult NOD and BALB/c did not result from increased blood transit time of CD8 cells. On the other hand, the preferential migration of CD8 cells was observed in the liver, whereas the two T-cell subsets migrated equally well in the lungs. The differences in the homing characteristics of CD4 and CD8 cells among NOD, BALB/c, and C57BL/6 mice were not related to modifications in the level of expression of adhesion molecules such as MEL-14, LFA-1, and Pgp-1.