Chemokine receptor CXCR5 supports solitary intestinal lymphoid tissue formation, B cell homing, and induction of intestinal IgA responses.

Solitary intestinal lymphoid tissue (SILT) comprises a spectrum of phenotypically diverse lymphoid aggregates interspersed throughout the small intestinal mucosa. Manifestations of SILT range from tiny lymphoid aggregates almost void of mature lymphocytes to large structures dominated by B cells. Large SILT phenotypically resemble a single Peyer's patch follicle, suggesting that SILT might contribute to intestinal humoral immune responses. In this study, we track the fate of individual SILT in vivo over time and analyze SILT formation and function in chemokine receptor CXCR5-deficient mice. We show that, in analogy to Peyer's patches, formation of SILT is invariantly determined during ontogeny and depends on CXCR5. Young CXCR5-deficient mice completely lack SILT, suggesting that CXCR5 is essential for SILT formation during regular postnatal development. However, microbiota and other external stimuli can induce the formation of aberrant SILT distinguished by impaired development of B cell follicles in CXCR5-deficient mice. Small intestinal transplantation and bone marrow transplantation reveal that defect follicle formation is due to impaired B cell homing. Moreover, oral immunization with cholera toxin or infection with noninvasive Salmonella fail to induce efficient humoral immune responses in CXCR5-deficient mice. Bone marrow transplantation of CXCR5-deficient recipients with wild-type bone marrow rescued B cell follicle formation in SILT but failed to restore full humoral immune responses. These results reveal an essential role of CXCR5 in Peyer's patch and SILT development and function and indicate that SILT do not fully compensate for the lack of Peyer's patches in T cell-dependent humoral immune responses.

Mesenteric lymph nodes confine dendritic cell-mediated dissemination of Salmonella enterica serovar Typhimurium and limit systemic disease in mice.

In humans with typhoid fever or in mouse strains susceptible to Salmonella enterica serovar Typhimurium (S. Typhimurium) infection, bacteria gain access to extraintestinal tissues, causing severe systemic disease. Here we show that in the gut-draining mesenteric lymph nodes (MLN), the majority of S. Typhimurium-carrying cells show dendritic-cell (DC) morphology and express the DC marker CD11c, indicating that S. Typhimurium bacteria are transported to the MLN by migratory DCs. In vivo FLT-3L-induced expansion of DCs, as well as stimulation of DC migration by Toll-like receptor agonists, results in increased numbers of S. Typhimurium bacteria reaching the MLN. Conversely, genetically impaired DC migration in chemokine receptor CCR7-deficient mice reduces the number of S. Typhimurium bacteria reaching the MLN. This indicates that transport of S. Typhimurium from the intestine into the MLN is limited by the number of migratory DCs carrying S. Typhimurium bacteria. In contrast, modulation of DC migration does not affect the number of S. Typhimurium bacteria reaching systemic tissues, indicating that DC-bound transport of S. Typhimurium does not substantially contribute to systemic S. Typhimurium infection. Surgical removal of the MLN results in increased numbers of S. Typhimurium bacteria reaching systemic sites early after infection, thereby rendering otherwise resistant mice susceptible to fatal systemic disease development. This suggests that the MLN provide a vital barrier shielding systemic compartments from DC-mediated dissemination of S. Typhimurium. Thus, confinement of S. Typhimurium in gut-associated lymphoid tissue and MLN delays massive extraintestinal dissemination and at the same time allows for the establishment of protective adaptive immune responses.

Dynamics and function of solitary intestinal lymphoid tissue.

Peyer's patches are the most prominent organized lymphoid tissue in the intestine and are generally considered to serve as an anatomical platform for the efficient induction of intestinal immune responses. However, besides Peyer's patches, phenotypically diverse, small-sized lymphoid structures are present, which mostly based on their phenotypical differences, have been assigned different names and putative functions. We have recently challenged this view and suggested that these structures represent different manifestations of the very same type of tissue, which we have termed solitary intestinal lymphoid tissue (SILT). A particular hallmark of SILT is its enormous plasticity, reflecting environmental stimuli such as the intestinal microflora. The functional role of SILT has largely been ignored for many years. However, recent reports indicate that SILT serves as port of entry for intestinal antigens and enteropathogens and is involved in the induction of intestinal immune responses. This review focuses on illuminating the concept of SILT and discusses its putative role in mucosal immune responses.

Elucidating the functional anatomy of secondary lymphoid organs.

Functional anatomy offers an attempt to exploit anatomical information as a platform from which to decipher mechanistic details of complex or multistep immunological processes. Immune function depends on structural organization, therefore this approach contributes to a comprehensive understanding of the immune system. Major advances in functional anatomy require progress in both experimental techniques and analytical equipment - largely synonymous to refinement of the anatomist's favorite tool, the microscope. Here, we describe how currently available techniques co-operate to gain new insights into the biology of secondary lymphoid organs.

Transcription factors Nkx3.1 and Nkx3.2 (Bapx1) play an overlapping role in sclerotomal development of the mouse.

The homeobox containing transcription factors Nkx3.1 and Nkx3.2 (Bapx1) are transiently coexpressed in somites during early embryonic mouse development. Targeted disruption of the Nkx3.2 (Bapx1) gene in mice results in limited defects of chondrocranial bones and the axial skeleton, particularly pronounced in cervical vertebrae. In contrast, inactivation of the Nkx3.1 gene causes no apparent skeletal phenotype despite its early expression in sclerotomal cells. These observations suggested that both genes might fulfill partially overlapping functions during development of the vertebral column. To test this hypothesis we have generated Nkx3.1/Nkx3.2 double homozygous mutants. The simultaneous loss of both genes caused embryonic lethality between E12.5 and E17.5. Double mutants exhibited enhanced defects of vertebrae compared with Bapx1-deficient animals. In vertebral anlagen sclerotomal cells condensing around the notochord were almost completely lost during early embryogenesis of double null mutants. Defects appeared most severe in the cranial region and less prominent in thoracic and lumbar regions. The reduction of chondrogenic cells resulted in the incomplete formation of vertebral bodies, missing major parts of their ventro-medial aspects. The enhanced skeletal phenotype of double null mutants compared to the single Bapx1 mutation demonstrates that Nkx3.1 contributes to the formation of the axial skeleton in addition to the Bapx1 gene. Moreover, both genes seem to collaborate in a yet unknown vital function in the mouse embryo.

Solitary intestinal lymphoid tissue provides a productive port of entry for Salmonella enterica serovar Typhimurium.

Oral infection of mice with Salmonella enterica serovar Typhimurium results in the colonization of Peyer's patches, triggering a vigorous inflammatory response and immunopathology at these sites. Here we demonstrate that in parallel to Peyer's patches a strong inflammatory response occurs in the intestine, resulting in the appearance of numerous inflammatory foci in the intestinal mucosa. These foci surround small lymphoid cell clusters termed solitary intestinal lymphoid tissue (SILT). Salmonella can be observed inside SILT at early stages of infection, and the number of infected structures matches the number of inflammatory foci arising at later time points. Infection leads to enlargement and morphological destruction of SILT but does not trigger de novo formation of lymphoid tissue. In conclusion, SILT, a lymphoid compartment mostly neglected in earlier studies, represents a major site for Salmonella invasion and ensuing mucosal pathology.

Enhanced FTY720-mediated lymphocyte homing requires G alpha i signaling and depends on beta 2 and beta 7 integrin.

The immunomodulatory drug FTY720 interferes with sphingosine-1-phosphate (S1P) receptor signaling leading to lymphocyte retention in secondary lymphoid organs and consequently to profound lymphopenia in the peripheral blood. The molecular mechanisms transduced by S1P receptors upon being triggered by its native ligand, S1P, or by FTY720, are largely unknown. In this study we analyze the role of beta2 and beta7 integrin and their ligands ICAM-1, VCAM-1, and MadCAM-1 on lymphocyte homing in the presence of FTY720. We demonstrate that this drug facilitates homing of lymphocytes single-deficient of either beta2 or beta7 integrin but not of beta2-deficient lymphocytes, which in addition were blocked by anti-beta7 integrin Abs. Enhanced lymphocyte homing is preceded by increased adherence of integrin-deficient as well as wild-type lymphocytes to high endothelial venules (HEV) in FTY720-treated animals. Elevated adherence to HEV requires intact lymphocyte Galphai signaling that cannot be stably imprinted on lymphocytes even after prolonged exposure to FTY720. Thus, FTY720 influences lymphocyte homeostasis not only by suppressing lymphocyte egress from lymph nodes but also by facilitating lymphocyte homing across HEV in an integrin-dependent fashion.

Adaptation of solitary intestinal lymphoid tissue in response to microbiota and chemokine receptor CCR7 signaling.

Besides Peyer's patches, solitary intestinal lymphoid tissue (SILT) provides a structural platform to efficiently initiate immune responses in the murine small intestine. SILT consists of dynamic lymphoid aggregates that are heterogeneous in size and composition, ranging from small clusters of mostly lineage-negative cells known as cryptopatches to larger isolated lymphoid follicles rich in B cells. In this study, we report that in chemokine receptor CCR7-deficient mice SILT is enlarged, although unchanged in frequency and cellular composition compared with wild-type mice. This phenotype is conferred by bone marrow-derived cells and is independent of the presence of intestinal bacteria. Remarkably, particularly small-sized SILT predominates in germfree wild-type mice. Colonization of wild-type mice with commensal bacteria provokes an adjustment of the spectrum of SILT to that observed under specific pathogen-free conditions by the conversion of pre-existing lymphoid structures into larger-sized SILT. In conclusion, our findings establish that intestinal microbes influence the manifestation of gut-associated lymphoid tissues and identify CCR7 signaling as an endogeneous factor that controls this process.

Cryptopatches and isolated lymphoid follicles: dynamic lymphoid tissues dispensable for the generation of intraepithelial lymphocytes.

In comparison to secondary lymphoid organs, gut-associated lymphoid tissues such as isolated lymphoid follicles (ILF) and cryptopatches (CP) have been less intensively studied. To gain a better insight into processes regulating organization and function of these structures, which are believed to participate in immune responses and extrathymic T cell development, we characterized the lymphoid structures of the murine small intestine in more detail. The size and cellular composition of small intestinal lymphoid aggregations were analyzed in C57BL/6 and BALB/c wild-type and lymphotoxin (LT)-deficient mice, by flow cytometry, histology and automated multi-color immunofluorescence microscopy evaluating large coherent areas of the intestine. These evaluations demonstrate that aggregated lymphoid structures in the small intestine vary in size and cellular composition, with a majority of structures not matching the current definitions of CP or ILF. Accordingly, significant variations depending on species, age and mouse strain were observed. Furthermore, small bowel transplantation revealed a rapid exchange of B but not T cells between host and grafted tissue. Moreover, LT-deficient animals lack any intestinal lymphoid aggregations yet possess the complete panel of intraepithelial lymphocytes (IEL). In summary, our observations disclose intestinal lymphoid aggregations as dynamic structures with a great deal of inborn plasticity and demonstrate their dispensability for the generation of IEL.