The multifaceted character of lymphotoxin ß in inflammatory myopathies and muscular dystrophies.

Lymphotoxin beta (LTß) regulates some inflammatory mechanisms that could be operative in idiopathic inflammatory myopathies (IM). We studied LTß and LTßR in inflammatory myopathies, normal and disease controls with immunohistochemistry, Western blotting and in situ hybridisation. LTß occurs in myonuclei of normal controls, implying its role in normal muscle physiology. LTß is strongly upregulated in regenerating muscle fibres in all myopathies, but not in denervated myofibres. Normal-appearing myofibres in inflammatory myopathies and muscular dystrophies express LTß possibly reflecting early myofibre damage, representing a hitherto undescribed pathologic hallmark. Furthermore, we visualised LTß in several inflammatory cell types in inflammatory myopathies, suggesting its involvement in the different inflammatory mechanisms underlying inflammatory myopathy subgroups.

Lymphotoxin-ß receptor activation by lymphotoxin-α(1)ß(2) and LIGHT promotes tumor growth in an NFκB-dependent manner.

Lymphotoxin beta receptor (LTßR) activation on mouse fibrosarcoma cells (BFS-1) results in enhanced solid tumor growth paralleled by increased angiogenesis induced by the expression of pro-angiogenic CXCL2. In our study, we demonstrate that both functional ligands of the LTßR, namely LTα(1) ß(2) and LIGHT, are involved in the activation of LTßR in solid fibrosarcomas. To identify whether the lymphocyte population is involved in the activation of LTßR in these fibrosarcoma tumors, we used conditional LTß-deficient mice that specifically lack LTß expression either on T cells (T-LTß(-/-)) or on B cells (B-LTß(-/-)). Solid tumor growth was reduced in both mouse strains when compared to tumor growth in wild-type mice, indicating the participation of both T and B host lymphocytes in the activation of LTßR in these tumors. Tumor growth was also reduced in LIGHT-deficient mice, suggesting a contribution of this ligand to the activation of LTßR in BFS-1 fibrosarcomas. LTßR signaling can involve IκBα and/or NFκB-inducing kinase (NIK) for subsequent NFκB activation in different types of cells. Expression of a dominant negative form of IκBα or of a dominant negative mutant of NIK resulted in decreased activation of NFκB signaling and reduced expression of pro-angiogenic CXCL2 in vitro. Moreover, expression of dominant negative form of NIK or an IκBα repressor in these fibrosarcoma cells resulted in reduced solid tumor growth in vivo, suggesting that both IκBα and NIK are involved in pro-angiogenic signaling after LTßR activation. Our data support the idea that the ablation of LTßR signaling should be considered for cancer treatment.

Role of the gut-associated and secondary lymphoid tissue in the induction of chronic colitis.

BACKGROUND: It is well known that enteric bacterial antigens drive the development of chronic colitis in a variety of different mouse models of the inflammatory bowel diseases (IBD). The objective of this study was to evaluate the role of gut-associated lymphoid tissue (GALT; Peyer's patches, isolated lymphoid follicles), mesenteric lymph nodes (MLNs) and spleen in the pathogenesis of chronic colitis in mice. METHODS: Surgical as well as genetic approaches were used to generate lymphopenic mice devoid of one or more of these lymphoid tissues. For the first series of studies, we subjected recombinase activating gene-1-deficient mice (RAG(-/-) ) to sham surgery (Sham), mesenteric lymphadenectomy (MLNx), splenectomy (Splx) or both (MLNx/Splx). In a second series of studies we intercrossed lymphotoxinß-deficient (LTß(-/-) ) mice with RAG(-/-) animals to generate LTß(-/-) x RAG(-/-) offspring that were anticipated to contain functional MLNs but be devoid of GALT and most peripheral lymph nodes. Flow purified naïve (CD4(+) CD45RB(high) ) T-cells were adoptively transferred into the different groups of RAG(-/-) recipients to induce chronic colitis. RESULTS: We found that at 3-5 wks following T-cell transfer, all four of the surgically-manipulated RAG(-/-) groups (Sham, MLNx, Splx and MLNx/Splx) developed chronic colitis that was similar in onset and severity. Flow cytometric analysis revealed no differences among the different groups with respect to surface expression of different gut-homing markers nor were there any differences noted in IFN-γ and IL-17 generation by mononuclear cells isolated among these surgically-manipulated mice. Although we anticipated that LTß(-/-) x RAG(-/-) mice would contain functional MLNs but be devoid of GALT and peripheral lymph nodes (PLNs), we found that LTß(-/-) x RAG(-/-) mice were in fact devoid of MLNs as well as GALT and PLNs. Adoptive transfer of CD45RB(high) T-cells into LTß(-/-) x RAG(-/-) mice or their littermate controls (LTß(+/+) x RAG(-/-) ) induced rapid and severe colitis in both groups. CONCLUSIONS: Taken together, our data demonstrate that: a) neither the GALT, MLNs nor PLNs are required for induction of chronic gut inflammation in this model of IBD and b) T-and/or B-cells may be required for the development of MLNs in LTß(-/-) mice.

Lymphotoxin-alpha 1 beta 2 and LIGHT induce classical and noncanonical NF-kappa B-dependent proinflammatory gene expression in vascular endothelial cells.

Activation of the classical and noncanonical NF-kappaB pathways by ligation of the lymphotoxin (LT)-beta receptor (LTbetaR) plays a crucial role in lymphoid organogenesis and in the generation of ectopic lymphoid tissue at sites of chronic inflammation. Within these microenvironments, LTbetaR signaling regulates the phenotype of the specialized high endothelial cells. However, the direct effects of LTbetaR ligation on endothelial cells remain unclear. We therefore questioned whether LTbetaR ligation could directly activate endothelial cells and regulate classical and noncanonical NF-kappaB-dependent gene expression. We demonstrate that the LTbetaR ligands LIGHT and LTalpha1beta2 activate both NF-kappaB pathways in HUVECs and human dermal microvascular endothelial cells (HDMEC). Classical pathway activation was less robust than TNF-induced signaling; however, only LIGHT and LTalpha1beta2 and not TNF activated the noncanonical pathway. LIGHT and LTalpha1beta2 induced the expression of classical NF-kappaB-dependent genes in HUVEC, including those encoding the adhesion molecules E-selectin, ICAM-1, and VCAM-1. Consistent with this stimulation, LTbetaR ligation up-regulated T cell adhesion to HUVEC. Furthermore, the homeostatic chemokine CXCL12 was up-regulated by LIGHT and LTalpha1beta2 but not TNF in both HUVEC and HDMEC. Using HUVEC retrovirally transduced with dominant negative IkappaB kinase alpha, we demonstrate that CXCL12 expression is regulated by the noncanonical pathway in endothelial cells. Our findings therefore demonstrate that LTbetaR ligation regulates gene expression in endothelial cells via both NF-kappaB pathways and we identify CXCL12 as a bona fide noncanonical NF-kappaB-regulated gene in these cells.

Lymphotoxin alpha beta 2 (membrane lymphotoxin) is critically important for resistance to Leishmania major infection in mice.

Although the essential role of TNF-alpha in the control of intracellular pathogens including Leishmania major is well established, it is uncertain whether the related cytokine lymphotoxin alphabeta2 (LTalpha1beta2, membrane lymphotoxin) plays any role in this process. In this study, we investigated the contribution of membrane lymphotoxin in host response to L. major infection by using LTbeta-deficient (LTbeta(-/-)) mice on the resistant C57BL/6 background. Despite mounting early immune responses comparable to those of wild-type (WT) mice, LTbeta(-/-) mice developed chronic nonhealing cutaneous lesions due to progressive and unresolving inflammation that is accompanied by uncontrolled parasite proliferation. This chronic disease was associated with striking reduction in IL-12 and Ag-specific IFN-gamma production by splenocytes from infected mice. Consistent with defective cellular immune response, infected LTbeta(-/-) mice had significantly low Ag-specific serum IgG1 and IgG2a levels compared with WT mice. Although administration of rIL-12 to L. major-infected LTbeta(-/-) mice caused complete resolution of chronic lesions, it only partially (but significantly) reduced parasite proliferation. In contrast, blockade of LIGHT signaling in infected LTbeta(-/-) mice resulted in acute and progressive lesion development, massive parasite proliferation, and dissemination to the visceral organs. Although infected LTbeta(-/-) WT bone marrow chimeric mice were more resistant than LTbeta(-/-) mice, they still had reduced ability to control parasites and showed defective IL-12 and IFN-gamma production compared with infected WT mice. These results suggest that membrane lymphotoxin plays critical role in resistance to L. major by promoting effective T cell-mediated anti-Leishmania immunity.

Lymphotoxin-beta regulates periderm differentiation during embryonic skin development.

Lymphotoxin-beta (LTbeta) is a key regulator of immune system development, but also affects late stages in hair development. In addition, high expression of LTbeta at an early stage in epidermis hinted at a further function in hair follicle induction or epithelial development. We report that hair follicles were normally induced in LTbeta(-/-) skin, but the periderm detached from the epidermis earlier, accompanied by premature appearance of keratohyalin granules. Expression profiling revealed dramatic down-regulation of a gene cluster encoding periderm-specific keratin-associated protein 13 and four novel paralogs in LTbeta(-/-) skin prior to periderm detachment. Epidermal differentiation markers, including small proline-rich proteins, filaggrins and several keratins, were also affected, but transiently in LTbeta(-/-) skin at the time of abnormal periderm detachment. As expected, Tabby mice, which lack the EDA gene, the putative upstream regulator of LTbeta in skin, showed similar though milder periderm histopathology and alterations in gene expression. Overall, LTbeta shows a primary early function in periderm differentiation, with later transient effects on epidermal and hair follicle differentiation.

Distinct roles of lymphotoxin-beta signaling and the homeodomain transcription factor Nkx2.3 in the ontogeny of endothelial compartments in spleen.

The formation of peripheral lymphoid tissues is indispensable for the efficient recognition and elimination of external antigens by lymphoid and accessory cells of the adaptive immune system. The spleen is structurally arranged around various vascular beds with distinct endothelial phenotypes. Using immunohistochemistry, we investigated the postnatal developmental characteristics of the marginal sinus and its relationship with various red-pulp sinus subsets. We also determined the importance of the lymphotoxin beta receptor (LT beta R) and the role of the Nkx2.3 transcription factor for the formation of the splenic vasculature. Both the administration of soluble LT beta R-Ig fusion protein to neonates and the deletion of LT beta R or downstream signaling components (RelB and p52) of the NF-kappaB family inhibited the phenotypic maturation of marginal sinus but had no effect on the vascular compartmentalization of the red pulp. The integrity of the marginal sinus and the proper vascular segregation of the red pulp appeared to be controlled by Nkx2.3, as Nkx2.3-deficient mice exhibited an abnormal distribution of IBL-7/1(hi)/IBL-9/2(-) sinuses and a lack of IBL-7/1(lo)/IBL-9/2(+) vessels. Our data suggest that phenotypic heterogeneity among different vascular elements within distinct anatomical regions of the spleen differentially depends on developmental factors such as lymphotoxin signaling or Nkx2.3, whereas the marginal sinus is controlled by both pathways.