Abnormal thymic expression of epithelial cell adhesion molecule (EP-CAM) in New Zealand Black (NZB) mice

New Zealand Black (NZB) mice have been well documented to have a variety of thymic epithelial cell microenvironmental abnormalities, including disruption of corticoepithelial cell networks and medullary cell clusters. These abnormalities of the thymic stromal network are particularly important because similar observations have been noted in other models of murine lupus. Thymic epithelial cells, a key component of the microenvironment, play an important role in selection of the mature T cell receptor repertoire. Recently, a homotypic calcium-independent human and murine epithelial cell adhesion molecule, Ep-CAM, has been described which is located at the thymocyto-cortical cell junction. The function of Ep-CAM is still unclear but its unique location within the thymus suggests that it is critical in the process of providing maturation signals. Consequently, we examined the thymic expression of Ep-CAM in a series of autoimmune prone mice by thymic distribution of Ep-CAM in NZB, NZW, NZB/W, BXSB-Yaa, MRL- lpr/lpr, C3H- gld/gld and the control strains BALB/c, C57BL6, C3H and MRL(+/+), by immunohistology and flow cytometry. Interestingly, NZB mice are similar to control mice from day 4 to 2 weeks of age, having a very low expression of Ep-CAM at the thymocyto-cortical junction. In control strains, there is a marked increased in expression of Ep-CAM beginning at 5 weeks of age. In contrast, NZB mice fail to show significant expression of Ep-CAM even well into adulthood. This abnormality of NZB mice was also noted in NZB/W F1 and BXSB mice, but not MRL- lpr/lpr or C3H- gld/gld mice. Given the potential importance of Ep-CAM in thymic selection, this study provides important evidence that a defective stromal microenvironment is likely to be of etiological significance in the susceptibility of NZB to autoimmune disease.     

Apoptosis and the thymic microenvironment in murine lupus.

The thymus of New Zealand black (NZB) mice undergoes premature involution. In addition, cultured thymic epithelial cells from NZB mice undergo accelerated preprogrammed degeneration. NZB mice also have distinctive and well-defined abnormalities of thymic architecture involving stromal cells, defined by staining with monoclonal antibodies specific for the thymic microenvironment. We took advantage of these findings, as well as our large panel of monoclonal antibodies which recognize thymic stroma, to study the induction of apoptosis in the thymus of murine lupus and including changes of epithelial architecture. We studied NZB, MRL/lpr, BXSB/Yaa, C3H/gld mice and BALB/c and C57BL/6 as control mice. Apoptosis was studied both at basal levels and following induction with either dexamethasone or lipopolysaccharide (LPS). The apoptotic cells were primarily found in the thymic cortex, and the frequency of apoptosis in murine lupus was less than 20% of controls. Moreover, all strains of murine lupus had severe abnormalities of the cortical network. These changes were not accentuated by dexamethasone treatment in cultured thymocytes. However, the thymus in murine lupus was less susceptible to LPS-induced apoptosis than control mice. Finally we note that the number of thymic nurse cells (TNC) was lowest in NZB mice. Our findings demonstrate significant abnormalities in the induction of apoptosis and the formation of TNC-like epithelial cells in SLE mice, and suggest that the abnormalities of the thymic microenvironment have an important role in the pathogenesis of murine lupus.     

Effects of ovariectomy and androgen treatment on the thymic pathology of NZB X SJL mice

Aging (NZB X SJL)F1 (NS) mice provide a unique model of thymic pathology occurring in females but not in males and characterized by the intrathymic accumulation of mature T cells and B cells. Here, we studied the basis for the sex-related difference in the development of this thymic pathology. In the reverse (SJL X NZB)F1 hybrids, a similar pathology was also observed only in females which suggests that its sex-dependency does not involve sex-linked gene(s) but rather hormonal influences. Ovariectomy of NS females reduced but did not prevent the accumulation of T and B cells in the thymus indicating that estrogens play a minimal role in this thymic pathology. In contrast, chronic dihydrotestosterone (DHT)-treatment of females, started at 4 weeks of age, inhibited the development of thymic lesions. Consistently, orchidectomy of NS males induced the appearance of 'female-like' thymic lesions that could be prevented by DHT-treatment. This demonstrates that the absence of thymic disease in NS males primarily reflects an inhibitory action of androgens. Evidence was obtained that androgens also decrease the production of anti-ds DNA antibodies in NS mice.     

Genetic dissection of B cell traits in New Zealand black mice. The expanded population of B cells expressing up-regulated costimulatory molecules shows linkage to Nba2

B cell abnormalities are a prominent feature of the immunologic derangement in NZB and NZB / W mice. We recently demonstrated that these mice have an increased proportion of splenic B cells expressing B7.1 and elevated levels of B7.2 and ICAM-1 that possess the characteristics of marginal zone B cells (CD23(low / -) CD5(-) CD44(hi) CD24(hi) IgD(- / low) IgM(hi)) and are found as early as 4 - 6 weeks of age. These findings suggest that activated B cells in NZB and NZB / W mice could serve a costimulatory function leading to activation of autoreactive T cells. However, it remains unclear whether there is any association between B abnormalities and nephritis in these mice. Here we have used genetic mapping techniques to address this issue. We show that increases in the proportion of B cells expressing costimulatory molecules, serum IgM levels, the number of IgM ELISpots, and IgG anti-single-stranded (ss) DNA antibody production, are significantly associated with a chromosomal region that overlaps with Nba2, a genetic locus previously linked to nephritis. Based on these findings we propose that immune mechanisms leading to polyclonal B cell activation and up-regulation of costimulatory molecules in these mice play a central role in the loss of tolerance that leads to production of pathogenic autoantibodies.     

Comparative immunobiology of thymic DC mRNA in autoimmune-prone mice

New Zealand Black (NZB) mice have multiple defects in both innate and acquired immunity. A fundamental defect, described more than 25 years ago, is premature thymic involution. Subsequent studies have disclosed multiple defects in thymic epithelial cells, and it has been proposed that thymic dendritic cells (DCs) play an important role not only in thymic involution but also in the appearance of immunopathology. However, the number of available thymic DCs makes this population extremely difficult to study. We have taken advantage of our ability to isolate pure populations of thymic DCs and have examined several key mRNA levels of enzymes involved in signal transduction. Our data on NZB mice was compared to that of NZB x NZW F1 (B/WF1), BXSB-Yaa, MRL/lpr, NOD and control mice. Importantly, we demonstrate herein that a common feature in autoimmune-prone mice is an increase of thymic DC c-met mRNA. Indeed, the increase in c-met mRNA levels appeared specific to the thymus and was not noted in the spleen. Additionally, we demonstrate that E-cadherin, a downstream molecule of c-met, is also reduced. Finally, we note that the levels of HGF mRNA are normal in the autoimmune strains examined herein, confirming that the abnormality of c-met mRNA is not due to primary defects in thymic stromal cells. We submit that these results highlight the possibility of a selective defect in thymic DCs which will be a pivotal step in loss of tolerance, and suggest that future studies focus on adoptive cell transfer involving this population.     

Studies on thymus products. IV. Absence of serum `thymic activity'' in adult NZB and (NZB × NZW) F1 mice

New Zealand Black (NZB) mice and (B/W) F1 hybrids have a normal level of serum `thymic activity' (TA) at birth but this level decreases prematurely between the third and sixth weeks of life. At 2 months, NZB and NZ (B/W) F1 mice have no significant TA, whereas TA is still at birth's level in six control mouse strains and remains at this level until the fourth to the sixth month. Six weeks after the decline of serum TA, NZB mice show disappearance of theta-positive lymph node rosette-forming cells (RFC) and 2 weeks later, progressive decrease in spleen RFC sensitivity to anti-theta serum (AΘS) and azathioprine (AZ) as in neonatally thymectomized CBA mice. Normal AZ and AΘS sensitivity of spleen and lymph node RFC is reconstituted by in vitro or in vivo treatment by thymic extracts. The early thymic abnormalities found in NZB mice are in keeping with the thymic medullar epithelium atrophy reported in newborn NZB mice.     

Absence of thymus crosstalk in the fetus does not preclude hematopoietic induction of a functional thymus in the adult

Cortical and medullary thymic epithelial cells provide essential signals for a normal programme of T‐cell development. Current models of thymus development suggest that thymocyte‐derived signals play an important role in establishing thymic microenvironments, a process termed thymus crosstalk. Studies on CD3εtg26 mice lacking intrathymic T‐cell progenitors provided evidence that normal development of the thymic cortex depends upon thymocyte‐derived signals. Importantly, the reported failure to effectively reconstitute adult CD3εtg26 mice raised the possibility that such crosstalk must occur within a developmental window, and that closure of this window during the postnatal period renders thymic epithelium refractory to crosstalk signals and unable to effectively impose T‐cell selection. We have re‐investigated the timing of provision of crosstalk in relation to development of functional thymic microenvironments. We show that transfer of either fetal precursors or adult T‐committed precursors into adult CD3εtg26 mice initiates key parameters of successful thymic reconstitution including thymocyte development and emigration, restoration of cortical and medullary epithelial architecture, and establishment of thymic tolerance mechanisms including maturation of Foxp3⁺ Treg and autoimmune regulator‐expressing medullary epithelium. Collectively, our data argue against a temporal window of thymocyte crosstalk, and instead demonstrates continued receptiveness of thymic epithelium for the formation of functionally competent thymic microenvironments.     

Immunohistology of T cell differentiation in the thymus of H-Y-specific T cell receptor alpha/beta transgenic mice

We examined the immunohistological aspects of the H-Y specific T cell receptor (TcR) alpha/beta transgene expression in the thymus of male and female transgenic (Tg) mice. Virtually all thymocytes expressed the beta transgene in both the male and female thymus. Expression of accessory molecules (co-receptors) in Tg mice deviated from control mice. In the male Tg thymus, CD8 expression was either low or absent on both cortical and medullary thymocytes. In contrast, in the thymus of female mice, CD8+ cells were found both in the cortex and in the medulla. The majority of medullary thymocytes was bright CD8+. This is in clear contrast to the CD8 distribution in control B6 mice, where only a few percent of medullary cells are CD8+. Similarly, the proportion of cells expressing CD4 antigens was reduced in the cortex and medulla of the thymus from male Tg mice, as compared to the thymus of female Tg mice and B6 control mice. Comparative analysis of the stromal cell types of the thymic microenvironments in the three groups of mice revealed that the cortical thymic microenvironment of male Tg mice differed, compared to that of female Tg mice. In particular, the deep cortex showed a closely packed meshwork of epithelial reticular cells. Moreover, H-2Db molecules (which are the restricting elements for the Tg TcR alpha/beta) were abnormally expressed in the thymic cortex of male mice. The cortical microenvironment in female mice, on the other hand, appeared normal. Together, the data indicate that TcR alpha/beta transgene expression in male mice leads to an aberrant co-receptor expression in both cortical and medullary lymphoid cells as well as an abnormal composition of the cortical microenvironment. Both phenomena may be the consequence of "negative selection" of developing H-Y-specific T cells, as it occurs only in the male Tg thymus. The absence of the H-Y antigen, but presence of the restricting element H-2Db in the thymic cortex of female mice, leads to accumulation of CD8+ in the medulla, a phenomenon interpreted as "positive selection".     

The aged thymus shows normal recruitment of lymphohematopoietic progenitors but has defects in thymic epithelial cells

Aging is associated with reduced numbers of all thymocyte sub-populations, including early T-cell progenitors. However, it is unclear if this is due to inadequate recruitment of lymphohematopoietic progenitor cells (LPCs) to the aged thymus or to abnormal development of T cells within the thymus. We found that LPCs from young mice were recruited equally well to the thymi of young or aged mice and that thymic stromal cells (TSCs) from young and old mice expressed similar levels of P-selectin and CCL25, which are believed to mediate recruitment of LPCs to the adult thymus. However, the number of recruited thymocytes in old thymus was markedly reduced after two weeks, indicating that T-cell development or proliferation is defective in the aged thymus. We also found that LPCs from aged and young mice have similar capacities to seed a fetal thymus that was transplanted under the kidney capsule. Thymic epithelial cells (TECs) in aged mice had lower proliferative capacity and higher rate of apoptosis, compared with findings in young animals. In addition, immunofluorescence staining with antibodies to cortical and medullary TECs revealed that aged thymi had a disorganized thymic stromal architecture, combined with reduced cellularity of the medulla, and apoptosis of thymocyte sub-populations in the medullary microenvironment was increased, compared with that in young mice. We conclude that aging does not impair recruitment of LPCs to the thymus, but is characterized by abnormalities in thymic epithelial architecture, especially medullary TEC function that may provide sub-optimal support for thymic development of LPCs.     

Disorganization and restoration of thymic medullary epithelial cells in T cell receptor-negative scid mice: evidence that receptor-bearing lymphocytes influence maturation of the thymic microenvironment

In order to assess the possible role of lymphoid cells in the development of thymic epithelium, we compared the organization and maturation of thymic epithelium in scid mice lacking T cell receptor (TcR)-positive cells with that in scid mice containing TcR+ cells. Immunohistologic examination revealed that thymi from TcR- scid mice were deficient in thymic medullary epithelial cells recognized by the monoclonal antibody ER-TR5, and that the few thymic medullary epithelial cells present were not organized into discrete medullary areas. In contrast, thymi from scid mice containing TcR+ cells possessed ER-TR5+ thymic medullary epithelial cells and these cells were organized normally into discrete medullary regions. Thus, normal organization and maturation of thymic medullary epithelial cells did not occur in the absence of TcR+ cells, but did occur upon introduction of TcR+ cells. We conclude that lympho-stromal cell interactions in the thymus are not unidirectional, and that a symbiotic relationship exists between maturing epithelial cells and developing lymphocytes.     

Bone marrow cells from young and old New Zealand black mice can reconstitute B lymphocytes in severe combined immunodeficient recipients

The formation of B lymphocytes in young New Zealand Black (NZB) mice proceeds at an accelerated rate, resulting in a deficiency of B lineage progenitors in mice of 15 weeks of age and older. Multiple studies have indicated that intrinsic defects in B lineage cells as well as in the hemopoietic microenvironment in which they develop contribute to these cellular abnormalities. To determine whether the B-cell hyperactivity observed in young mice could be observed in a normal environment, bone marrow cells from young (4 weeks or less) NZB donors were transplanted into Severe Combined Immunodeficient (SCID) mice that have a marked deficiency of lymphocytes but an apparently normal hemopoietic microenvironment. Engraftment of donor lymphoid cells can occur without pretransplant conditioning regimens, thus minimizing the chances of transferring microenvironmental elements. Marrow from young NZB donors reconstituted surface IgM-expressing B cells and CFU-B (B-cell colony-forming unit) in the marrow of SCID mouse recipients to levels comparable to that observed with donor NZB.xid marrow. The latter mice carry the xid gene that ameliorates the defects exhibited by B lineage cells of NZB mice. Both the number of surface IgM-expressing B cells and CFU-B were higher in the spleen of SCID mice that received NZB grafts than marrow cells from donor BALB/c or NZB.xid mice. Marrow from young NZB donors also reconstituted Thy-1, L3T4 and Lyt2-expressing cells in the spleen to levels higher than observed with young NZB.xid donor cells. The transplantation of marrow from 6-month-old NZB donors made it possible to test whether B lineage cells were present in that tissue and could mediate reconstitution in the normal SCID environment. Marrow from old NZB donors did reconstitute B cells in the marrow and spleen of SCID recipients. The level of reconstitution was comparable to that mediated by young BALB/c cells and twice that of old NZB.xid donor cells. The absolute number of splenic CFU-B was also higher in recipients of old NZB marrow as compared to young BALB/c cells. Old NZB.xid donor marrow reconstituted splenic Thy-1, L3T4 and Lyt2 T cells to levels less than observed with NZB donor cells. Analysis of serum Ig in recipients of old NZB cells indicated higher levels of total IgM as compared to mice engrafted with NZB.xid cells, and anti-single stranded DNA antibodies were detected.     

The Effect of Cytokines on the Activation-Induced Apoptosis of B Cells in Autoimmune NZB X NZW F1 Mice

Programmed cell death (apoptosis) is an essential process in the development of various tissues and its involvement has been proposed for the elimination of self-reactive immature T and B lymphocytes when self antigens are first encountered. In order to further investigate the role of apoptosis in the pathogenesis of autoimmune disease, the apoptosis of lipopolysaccharide (LPS)-activated B cells, peritoneal cells from NZB x NZW F1 (NZB/W F1) mice and nonautoimmune BALB/c mice were assayed using an in vitro culture system. Splenic B cells were isolated and then stimulated with LPS before further activated with crosslinking antimu antibody. In addition, the apoptosis of peritoneal cells induced by crosslinking antimu antibody was also analyzed. The data revealed that the specific apoptosis of both activated B cells and peritoneal cells induced by crosslinking antimu antibody was very similar comparing NZB/W F1 and nonautoimmune BALB/c mice. This activation-induced B-cells apoptosis could be rescued, however, with the addition of cytokines such as interleukin (IL)-5 or IL-10, to the culture. The results suggest that there is no endogenous defect in the apoptosis of activated B cells for autoimmune NZB/W F1 comparing nonautoimmune BALB/c mice. Notably, however, abnormally high levels of the type 2 T helper (Th2)-related cytokines such as IL-5 or IL-10 may play an important role in the abnormal expansion of activated B cells in autoimmune NZB/W F1 mice.     

An Ig mu-heavy chain transgene inhibits systemic lupus erythematosus immunopathology in autoimmune (NZB x NZW)F1 mice.

Intrinsic defects in the B lymphoid lineage are involved in predisposition for systemic lupus erythematosus in (NZB x NZW)F(1) (NZB/W) mice. In addition, a contribution of CD4(+) T cells has been shown to be crucial for the development of fatal glomerulonephritis. To further dissect the role of B and T cells in lupus immunopathology we used Ig mu-heavy chain (muHC) transgenic (Tg) NZB/W mice that we recently established to study mechanisms of B cell tolerance. The Tg NZB/W mice have a very restricted B cell repertoire and only a very minor population of B cells having endogenously rearranged muHC Ig loci are able to undergo isotype switch. Here we analyzed the influence of the restricted B cell repertoire on the development of IgG anti-DNA antibodies and glomerulonephritis as well as the hyperactivation of T(h) cells. IgG anti-DNA antibodies developed delayed but consistently in the Tg NZB/W mice, suggesting that a strong selective mechanism for the development of these autoantibodies is operative. Despite significant autoantibody titers in Tg NZB/W mice, very little immune deposits in the glomeruli and no evidence for renal inflammation were found. The Tg mice have a significantly prolonged survival time and most of the Tg mice lived much longer than 1 year. Interestingly, the generalized T cell activation that normally correlates and coincides with the progression of the disease in NZB/W mice is strongly reduced in older Tg animals. The absence of IgG3 anti-DNA antibodies and the strong reduction of IgG2a anti-DNA antibodies in the Tg mice suggests that particularly the activation of T(h)1 cells is inhibited. This result shows that a significant restriction in the B cell repertoire prevents hyperactivation of T(h) cells and supports the model that T cell hyperactivation in NZB/W mice is secondary to specific interactions with a subpopulation of presumably autoreactive B lymphocytes.     

Modest cortex and promiscuous medulla for thymic repertoire formation

Recent advances in the understanding of medullary thymic epithelial cell biology, and especially of their promiscuous gene expression, have highlighted the indispensable role of thymic medulla in shaping a self-tolerant T-cell repertoire. Additionally, our recent results have shown that cortical thymic epithelial cells possess a unique proteasome (the so-called thymoproteasome), which seems to possess limited protein degradation capability for generating peptides that are loaded onto class I major histocompatibility complex molecules. We discuss here the unique role of thymoproteasomes in the development and repertoire formation of CD8+ T cells, focusing on the stepwise and contrasting roles of cortical epithelial cells and medullary epithelial cells. These results could offer fundamental new insights into the molecular mechanisms of T-cell repertoire selection.     

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B cell abnormality and autoimmune disorders

Various abnormalities have been described in B cells from patients with systemic autoimmune diseases such as systemic lupus erythematosus (SLE) and lupus-prone mice. Many of the abnormalities do not appear to be connected with the pathogenesis of the disease. However, various animal models developing lupus-like disease including both spontaneous mutants such as (NZB × NZW)F1 and MRL/lpr and mice generated by transgenic or knockout technology such as Bim-deficient and CD40L-transgenic mice show defect in apoptosis of mature B cells induced by ligation of the B cell antigen receptor (BCR). BCR-mediated apoptosis appears to be involved in deletion of self-reactive B cells. Thus, defect in BCR-mediated apoptosis is a widely observed B cell abnormality in lupus-prone mice and may play a role in the pathogenesis of systemic autoimmune diseases by abrogating deletion of self-reactive B cells.     

Age- and sex-dependent thymic abnormalities in NZB × SJL F1 hybrid mice

The cellular organization of the thymus was investigated in 3- and 12-month-old NZB × SJL F₁ hybrid (NS) mice. Age-dependent alterations were demonstrated which differed strikingly according to the sex of the animals. In female mice, marked abnormalities of the thymus developed during ageing. They consisted of a more or less pronounced hypertrophy accompanied by histological changes and modifications in the nature of the lymphocyte populations. Three types of qualitative changes were found at 12 months of age: (1) depletion of cortical thymocytes as evidenced by histology, by the evaluation of peanut-agglutinin (PNA) binding and by cell electrophoresis; (2) hyperplasia of the medullary lymphoid tissue, probably reflecting the expansion of a population of mature T lymphocytes. This was further suggested by a rise (up to 60%) in the frequency of lymphocytes lacking both PNA receptor and B cell markers, by an increased proportion (57%) of high electrophoretic mobility (EPM) lymphocytes and by an augmentation of in vitro reactivities to phytohaemagglutinin (PHA) and, although to a lesser extent, to concanavalin A (Con A). (3) The appearance of significant numbers of B lymphocytes (up to 20%) as assessed by surface immunoglobulin (sIg) and complement receptor (CR) detection which was accompanied by a vigorous responsiveness of thymus cells to lipopolysaccharide (LPS). None of these abnormalities was seen in the male mice. Instead, the thymus of NS males displayed a nearly normal age-related involution without major change in the proportions of its lymphocyte subpopulations. NS mice thus provide an interesting model of thymic disease influenced by sex-linked factors.     

B cell abnormality and autoimmune disorders

Various abnormalities have been described in B cells from patients with systemic autoimmune diseases such as systemic lupus erythematosus (SLE) and lupus-prone mice. Many of the abnormalities do not appear to be connected with the pathogenesis of the disease. However, various animal models developing lupus-like disease including both spontaneous mutans such as (NZB x NZW)F1 and MRL/lpr and mice generated by transgenic or knockout technology such as Bim-deficient and CD40L-transgenic mice show defect in apoptosis of mature B cells induced by ligation of the B cell antigen receptor (BCR). BCR-mediated apoptosis appears to be involved in deletion of self-reactive B cells. Thus, defect in BCR-mediated apoptosis is a widely observed B cell abnormality in lupus-prone mice and may play a role in the pathogenesis of systemic autoimmune diseases by abrogating deletion of self-reactive B cells.