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¹ Howard Hughes Medical Institute and Department of Microbiology and Immunology, University of California San Francisco, San Francisco, CA 94143
² Nuffield Department of Medicine, Oxford University, John Radcliffe Hospital, Headington, Oxford OX3 9DU, United Kingdom

Address correspondence to Jason G. Cyster, Department of Microbiology and Immunology, University of California San Francisco, 513 Parnassus Ave., San Francisco, CA 94143-0414. Phone: 415-502-6427; Fax: 415-502-8424; E-mail: cyster{at}itsa.ucsf.edu

	Abstract

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The factors regulating growth and patterning of the spleen are poorly defined. We demonstrate here that spleens from B cell–deficient mice have 10-fold reduced expression of the T zone chemokine, CCL21, a threefold reduction in T cell and dendritic cell (DC) numbers, and reduced expression of the T zone stromal marker, gp38. Using cell transfer and receptor blocking approaches, we provide evidence that B cells play a critical role in the early postnatal development of the splenic T zone. This process involves B cell expression of lymphotoxin (LT)1ß2, a cytokine that is required for expression of CCL21 and gp38. Introduction of a B cell specific LT transgene on to the LT-deficient background restored splenic CCL21 and gp38 expression, DC numbers, and T zone size. This work also demonstrates that the role of B cells in T zone development is distinct from the effect of B cells on splenic T cell numbers, which does not require LT1ß2. Therefore, B cells influence spleen T zone development by providing: (a) signals that promote T cell accumulation, and: (b) signals, including LT1ß2, that promote stromal cell development and DC accumulation. Defects in these parameters may contribute to the immune defects associated with B cell deficiency in mice and humans.

Key Words: lymphotoxin • SLC • BLC • stromal cell • dendritic cell

	Introduction

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The spleen participates in immune responses against many types of pathogens and it is also involved in autoimmune diseases and lymphoid malignancies (1). Within the spleen, lymphocytes are organized as sheathes around arterioles, with the T zone located centrally (also called the periarteriolar lymphoid sheath or PALS) and the B cells distributed around the T zone in tightly packed follicles. The spleen contains an additional population of B cells in a compartment that surrounds the follicles, known as the marginal zone (2). Antigen-presenting dendritic cells (DCs)^* are prevalent in marginal zones, T cell zones, and in the bridging channels between these two compartments (3). The T zones, follicles, and marginal zones of the spleen are commonly referred to as the white pulp cords and they account for approximately half of the splenic tissue (1). The remainder of the spleen, termed red pulp, contains large numbers of macrophages, vascular cells, and transiting blood cells. This compartment functions in red cell and immune complex clearance and leukocyte exit.

Current understanding of the factors that cause growth and patterning of lymphoid organs is limited. Within the B and T cell areas there are specialized chemokine-producing stromal cells, believed to be of mesenchymal origin, that help organize the tissue (4, 5). Follicular stromal cells produce CXCL13 (BLC), a ligand for CXCR5, and both CXCR5 and CXCL13 are necessary for formation of B cell follicles (6, 7). A subset of follicular stromal cells, known as follicular DCs (FDCs), express complement and Fc receptors and are able to trap immune complexes for presentation to B cells. Normal expression of CXCL13 and development of FDCs is dependent on signals provided by B cells (8–10). Recent studies indicated that maturation of FDCs depends on a positive feedback loop between CXCL13 and the cytokine lymphotoxin (LT)1ß2, where CXCL13 mediates recruitment of CXCR5-expressing B cells and induces them to express LT1ß2 (7). LT1ß2 causes growth and maturation of the follicular stromal cells, leading to increased expression of CXCL13 and upregulation of FDC markers (7). Stromal cells within T cell areas produce the CC chemokines, CCL21 (SLC) and CCL19 (ELC) (11). In mice lacking lymphoid CCL21 and CCL19 (11, 12), or in animals deficient in the common CCL21 and CCL19 receptor, CCR7 (13), there is a severe paucity of T cells and DCs within splenic T zones, while follicles continue to develop. Expression of these chemokines is also dependent on LT1ß2 (14). However, the cell types acting as a source of LT1ß2 in T zone stromal cell development have not been defined.

We demonstrate here that splenic expression of CCL21 is dependent on the presence of B cells but not T cells, whereas expression in lymph nodes is B cell independent. By immunohistochemistry, B cell–deficient spleens have a three- to fivefold reduction in the area stained by CD3 and by the T zone stromal cell marker, gp38 (15). In addition to the role of LT1ß2 in promoting T zone chemokine expression, we find that LT1ß2 is required for T zone gp38 expression. Bone marrow transfer and LTßR-Ig blocking experiments indicate a developmentally fixed role for B cells and LT1ß2 in promoting splenic T zone development. We show that the expression of LT1ß2 on B cells is sufficient to restore splenic DC numbers in LT-deficient mice. The presence of normal numbers of splenic T cells in LT-deficient mice (16–19) demonstrates that B cell regulation of splenic T cell numbers is mediated by LT1ß2-independent pathways. These findings indicate a prominent role for B cells in providing LT1ß2 and other signals needed for development of T zones and accumulation of DCs and T cells in the spleen.

	Materials and Methods

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Mice.
C57BL/6 (B6) µMT (BCR^-/-), B6 TCRß^-/-^-/- (TCR^-/-), B6/129 LT^-/-, and B6 recombination activating gene (RAG)-1^-/- mice were from The Jackson Laboratory. For generation of bone marrow chimeras, 1–5 x 10⁶ total bone marrow cells were intravenously injected into lethally irradiated recipient mice (1,100 rads). Recipient mice were given antibiotic water (polymyxin B, 110 mg/liter and neomycin, 1.1 g/liter) during the 6–10-wk reconstitution period, before analysis. For splenocyte transfers, cell enumeration experiments and DC analysis, cells were prepared by gently pressing the spleen through a 70-µM mesh cell strainer (Fisher Scientific). Red blood cells was lysed and cells were resuspended in serum-free DMEM containing antibiotics. In some cases, spleen cell suspensions were prepared using collagenase and EDTA, as previously described (20). 2 x 10⁷ splenocytes in a volume of 0.05 ml were injected into the peritoneal cavity of newborn mice with a 30-gauge needle as described previously (21). Treatment with LTßR-Ig or human LFA3-Ig was by intraperitoneal injection as described previously (14), using 100 µg per injection.

Generation of LT-Transgenic Mice.
A DNA fragment encoding the transmembrane and membrane-proximal (stalk) regions of the LTß gene (22, 23), corresponding to nucleotides 1–450 (GenBank/EMBL/DDBJ accession no. U16985) was isolated by PCR from spleen cDNA using primers 5'-TAGTAGGGATCCGATATCCTGGATGGGGACACGGGGACT-3' (containing a 5' BamHI and EcoRV sites) and 5'-TAGTAGGTCGACATCATCATCATCTTTGTAATCGTTGAGG-3' (containing a 3' SalI site). A fragment containing nucleotides 124–609 (GenBank/EMBL/DDBJ accession no. M16819) of LT, encoding for the receptor-binding domain (24), was isolated with the primers 5'-TAGTAGGTCGACCATGGCATCCTGAAACCTGCT-3' (with SalI site) and 5'-TAGTAGATCGATGCGGCCGCCTACAGTGCAAAGGCTCC-3' (with NotI and ClaI sites). The PCR fragments were cloned into pEF-BOS-XC (25) and an EcoRV-NotI fragment containing the LTß-LT chimeric gene was isolated and cloned into end-blunted ClaI and NotI sites of the pBXD1 vector. PBXD1 was generated by combining the 2.1-kb Ig -promoter fragment from myeloma S107 in series with: (a) a 0.24 kb 5' chimeric intron from the pCI vector (Promega), (b) a multiple cloning site, (c) the 0.2 kb late SV40 poly A sequence, and (d) both 2.1 kb MAR/intron enhancer and 1.3 kb 3' enhancer regions from the Balb/c gene. The BamHI and EcoRI linearized chimeric LTß/LT minigene was microinjected into fertilized (C57BL/6J x DBA/2J)F2 oocytes according to standard techniques. To screen for transgenic mice, ear DNA was prepared and the transgene was detected by PCR using the above indicated primer pairs. Founder #4 was crossed with B6 LT-deficient mice (26) to generate LT-transgenic/LT^2/- mice. To distinguish the LT-targeted and wild-type alleles by PCR, a mixture of the following primers were used 5'-TAGTAGGTCGACATGACACTGCTCGGCCGTCT-3' (LT-specific), 5'-GCTTGCCGAATATCATGGTGG-3' (Neo-specific), and 5'-GGACAGAAGAGAGTGGAGAGG-3' (LT-specific), yielding a 180-bp fragment from the wild-type allele and a 380-bp fragment from the targeted allele. Amplification conditions were 94°C for 30 s, 55°C for 30 s, 72°C for 60 s, for 40 cycles. All the transgenic mice characterized were heterozygous for the transgene. The transgenic animals appeared healthy and grew equivalently to their littermate controls.

Northern Blot Analysis.
10–15 µg of total RNA from mouse spleens or lymph nodes was subjected to gel electrophoresis, transferred to Hybond N⁺ membranes (Amersham Pharmacia Biotech), and probed using randomly primed ³²P-labeled mouse cDNA probes of the following types: CCL21, bases 1–848 (27) and CCL19, bases 1–755 (28). To control for RNA loading, a mouse elongation factor 1 (EF1) probe was used. For quantitation, Northern blots were exposed to a phosphor screens for 6 h to 3 d and images were developed using a Storm860 PhosphorImager (Molecular Dynamics). Data were analyzed using ImageQuant^® software (Molecular Dynamics), and chemokine mRNA levels were corrected for RNA loaded by dividing the chemokine hybridization signal by the EF-1 signal for the same sample. Relative expression levels were calculated by dividing the corrected signal for each mutant or treated sample with the mean corrected signal for the wild-type or control treated samples, as appropriate, that were included on each of the Northern blots.

Immunohistochemistry.
Cryostat sections (6–7 µm) were fixed and stained as described previously (29) using the following mAbs: rat anti-B220 (CalTag); rat anti-MAdCAM-1 (BD PharMingen); goat anti-mouse 6Ckine (CCL21; R&D Systems); sheep anti-IgD (BD PharMingen); and syrian hamster anti-gp38 (provided by Andrew Farr, University of Washington, Seattle, WA). Rat IgG antibodies were detected with goat anti–rat-IgG conjugated alkaline phosphatase (AP; Southern Biotechnology Associates, Inc.) or donkey anti–rat-IgG conjugated horseradish peroxidase (HRP). Goat IgG antibodies were detected with biotinylated donkey anti–goat (Southern Biotechnology Associates, Inc.), followed by Vectastain ABC-AP (Vector Laboratories). Sheep IgG antibodies were detected with donkey anti–sheep-IgG HRP (Jackson ImmunoResearch Laboratories). Syrian hamster IgG antibodies were detected with anti-syrian hamster-AP (Jackson ImmunoResearch Laboratories). Enzyme reactions were developed with conventional substrates for peroxidases (diaminobenzidine/H₂O₂; Sigma-Aldrich) and AP (FAST BLUE/Naphthol AS-MX; Sigma-Aldrich). For measuring T zone and red pulp areas, cross-sections were made through central segments of the spleen, stained for gp38, CD3, or B220, analyzed at 5x objective magnification, and digital images of a fixed resolution were acquired using a cooled MDEI850 CCD camera (Optronics Engineering). Using Adobe Photoshop^® software, an outline was drawn around positively stained areas using the lasso tool and the total pixels within each lassoed area were obtained using the histogram function. Data were collected from a minimum of two cross-sections per spleen. The total number of pixels was then divided by the number of spleen cross-sections analyzed to provide a measurement of pixel counts per cross-section. Pixel counts for red pulp areas were obtained by subtracting the CD3⁺ areas (for BCR^-/-), or B220⁺ areas (for wild-type) from the total splenic cross-sectional area obtained by lassoing the entire spleen cross-section.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
B Cells Regulate Splenic T Zone Chemokine Expression.
To examine the cellular requirements for expression of the T zone chemokines, CCL21 (SLC) and CCL19 (ELC), we performed Northern blot analysis of spleen and lymph node tissue from B- and T cell–deficient mice. Surprisingly, expression of CCL21 in spleen was strongly dependent on B cells but not on T cells (Fig. 1, A and B). Splenic CCL19 mRNA expression was less affected by lymphocyte deficiency and showed a slightly greater dependence on B cells than T cells (Fig. 1, A and C). Lymphocytes are not a significant source of CCL19 or CCL21 (27, 28). Therefore, the absence of B and/or T lymphocyte RNA in the mutant spleens cannot explain the reduction in chemokine mRNA and instead may cause the magnitude of the reduction to be underestimated. The decrease in CCL21 in B cell deficient spleen was also evident by in situ hybridization and immunohistochemical analysis (data not shown). In contrast to spleen, CCL21 mRNA expression in LNs was not affected by B cell deficiency (Fig. 1 E). T cells were also not required for CCL21 expression in lymph nodes (Fig. 1 E). Similarly, lymph node CCL19 expression was not dependent on the presence of B cells or T cells (Fig. 1 F). Previous studies established that splenic expression of the B zone chemokine, CXCL13, is dependent on B cells but not on T cells (14) and we find here, in contrast to CCL21, that CXCL13 mRNA expression in lymph nodes is also B cell dependent (Fig. 1 D). In summary, B cells promote CCL21, and to a lesser extent CCL19, expression in spleen but not in lymph nodes, whereas they promote CXCL13 expression in both types of lymphoid tissues.

View larger version (65K): [in this window] [in a new window]   Figure 1. Reduced expression of splenic T zone chemokines in B cell–deficient mice. (A) Northern blot analysis of total RNA isolated from spleen tissue of the indicated mice, probed to detect expression of CCL21 (SLC) and CCL19 (ELC). Hybridization to EF1 was used to control for RNA loaded. WT, wild-type. (B–F) Relative chemokine mRNA levels in spleen or mesenteric lymph node (MLN) RNA, determined by PhosphorImager analysis of multiple Northern blots, including blots probed for CXCL13 (BLC). Data from individual mice are shown as circles and means as bars.

View larger version (96K): [in this window] [in a new window]   Figure 2. GP38-expressing stromal cell networks are small in B cell–deficient spleens and undetectable in LT-deficient spleens. Spleen and lymph node tissue from wild-type (WT), B cell-deficient (BCR-/-), and LT-/- mice, as indicated, was sectioned and stained to detect gp38 (blue) and IgD (brown). No lymph nodes were found in the LT-/- animal. The bottom left panel demonstrates the method used for measuring gp38+ cross-sectional areas, showing the BCR-/- spleen cross-section with gp38+ stained areas ‘lassoed’ and the number of pixels present in the single fully identified gp38+ area indicated. Original objective magnification for all panels: x5. Data are representative of tissues from more than 10 animals of each type.

View larger version (38K): [in this window] [in a new window]   Figure 3. B cells promote splenic T zone stromal cell development and accumulation of splenic T cells and DCs. (A) Cross-sectional areas of gp38- and CD3 staining in B cell–deficient and wild-type (WT) spleens. Positively stained areas were determined as indicated in Fig. 2 and the numbers of pixels per splenic cross-section was calculated using Adobe Photoshop® software as described in Materials and Methods. Data were collected from seven wild-type and seven BCR-/- spleens. (B) Cross-sectional area of red pulp in B cell–deficient and wild-type spleens. Pixel counts were determined as in A, and red pulp areas were obtained by subtracting the white pulp areas (identified as the outer boundaries of CD3 and B220 staining) from the total splenic cross-sectional area. Data were collected from 12 spleens of each type. (C–E) Cell numbers in spleen, peripheral lymph nodes (pool of brachial, axillary, and inguinal) and blood. Cells were identified by flow cytometry as CD3+CD4+, CD3+CD8+, or MHC classII+CD11c+. Data are from 8–11 mice per group. In all panels, open bars correspond to wild-type and shaded bars to B cell deficient. Bars represent means and error bars, standard deviations. Statistical comparison is by Student's t test.

B cells have previously been established to function as a source of LT1ß2 necessary for FDC development (9, 10, 37). To test whether B cell–derived LT1ß2 is required for splenic T zone development, we first asked whether constitutive LT1ß2 signaling was important for maintaining CCL21 expression. Previous studies indicated that blocking LT1ß2 signaling in adult mice using LTßR-Ig treatment reduced CCL21 levels by 30% (14); however, it was unclear in these studies whether all LT1ß2 function had been blocked. Therefore, we took a further approach to test for the requirement for LT1ß2, reconstituting lethally irradiated adult mice with LT-deficient bone marrow. Despite efficient reconstitution by donor-derived cells (data not shown), CCL21 expression was not strongly affected compared with animals reconstituted with wild-type bone marrow (Fig. 4 A). Similar findings were made when lethally irradiated mice were reconstituted with BCR^-/- or RAG1^-/- bone marrow (data not shown). By contrast, CXCL13 levels were reduced to 40% of wild-type (Fig. 4 A). Reciprocally, when lymphocyte-deficient mice were reconstituted with wild-type bone marrow, they failed to upregulate CCL21 expression (Fig. 4 B), whereas substantial upregulation of CXCL13 was observed (Fig. 4 B). Taken together, these results suggest that the strong deficit in CCL21 in mice congenitally deficient in LT1ß2 or B cells reflects a role for B cells and LT1ß2 in inducing CCL21 during a fixed window in spleen development.

View larger version (28K): [in this window] [in a new window]   Figure 4. B cell and LT dependence of splenic T zone stroma is developmental. (A) Relative CXCL13 or CCL21 mRNA levels in spleen, as determined by Northern blot, of wild-type (WT) or LT-deficient mice, or irradiated wild-type mice 6 wk after reconstitution with WT or LT-/- bone marrow. (B) Relative CXCL13 or CCL21 mRNA levels in spleen of WT or RAG1-deficient mice, or irradiated RAG1-deficient mice 6 wk after reconstitution with WT or RAG1-deficient bone marrow. (C) Relative CCL21 mRNA levels in spleen of 6-wk-old RAG1-deficient mice or RAG1-/- mice that were injected intraperitoneally (i.p.) with 2 x 107 splenocytes from adult T cell-deficient (TCR-/-) or LT-deficient mice at day 0.5 after birth. B cell numbers in spleens at isolation were between 0.7–3.106 (TCR-/- recipients) or 1.0–2.5 x 106 (LT-/- recipients). Each circle represents an individual recipient and bars represent means. White bars, wild-type, black bars, LT-/- or RAG1-/-, shading, mice reconstituted with wild-type bone marrow or TcR-/- spleen cells, hatched bars, mice reconstituted with mutant bone marrow or LT2/- spleen cells. Statistical comparison is by Student's t test.

As a further approach to test the requirement of LT1ß2 early in life for T zone chemokine expression, newborn or 1-wk-old wild-type mice were treated with LTßR-Ig and then the treatment was either stopped or continued as the animals grew to become adults. Analysis of spleen tissue from 5-wk-old animals given continuous injections of LTßR-Ig from birth showed a striking inhibition of CCL21 expression (Fig. 5 A), an effect markedly greater than the 30% decrease observed after treating adult animals with the antagonist for a similar period (14). In further agreement with a role for LT1ß2 early in spleen T zone development, CCL21 levels were strongly reduced in animals treated with a single injection of LTßR-Ig at day 0.5 of life (Fig. 5 A). Although the LTßR-Ig is likely to have persisted in the serum of these animals for several weeks (40), the importance of LT1ß2 signaling during the first week after birth is supported by the lesser effect on CCL21 levels when the treatment was delayed until week one (Fig. 5 A). Strikingly, immunohistochemical analysis of spleens from mice treated at day 0.5 revealed a severe disruption in organization and failure to express gp38 (Fig. 6 A), a phenotype similar to congenic LT-deficiency (see Figs. 2 and 6 B). When the antagonist treatment was delayed until day 7, the effect was much less severe as white pulp cords with gp38⁺ T cells areas could be identified (Fig. 6 A). In agreement with B cells serving as a source of LT1ß2 in the early postnatal period, flow cytometric analysis of B cells from day 5 spleens showed that, despite having the expected IgD^loCD21^lo immature phenotype (data not shown), they expressed measurable surface LT1ß2 as assessed by staining with LTßR-Ig (Fig. 5 B), although the fraction of positively stained B cells was two- to threefold lower than in adult spleen (7). In summary, these findings suggest that B cells promote CCL21 upregulation and splenic T zone development at least in part by acting as a source of LT1ß2 in the neonate.

View larger version (43K): [in this window] [in a new window]   Figure 5. LT1ß2 antagonism in newborn mice inhibits CCL21 upregulation. (A) Relative CCL21 mRNA levels in spleen of 5-wk-old mice that were treated at day 0.5 (wk 0), days 7, 14, 21, and 28 (wk 1–4) or days 0.5, 7, 14, 21, and 28 (wk 0–4) after birth with LFA3-Ig or LTßR-Ig, as indicated. Each circle represents an individual animal and bars represents means. (B) Representative flow cytometric profiles of spleen cells from 5-d-old mice stained to detect B cells (CD19) and LTßR ligands (LTßR-Ig). In the bottom panel, the cells were preincubated with unconjugated anti-LTß antibody that inhibits LTßR-binding to LT1ß2 as a staining control. The mean percentage of B cells falling within the gate indicated by the filled box is indicated (± SD) for cells from three 5-d-old mice.

View larger version (150K): [in this window] [in a new window]   Figure 6. LT1ß2 antagonism in newborn mice inhibits T zone stromal cell development, and transgenic expression of LT1ß2 on B cells rescues T zone development in LT-deficient mice. (A) Spleen tissue from mice treated with control (hLFA3-Ig) on days 0.5, 7, 14, 21, and 28 (left panel), or with LT1ß2 antagonist (LTßR-Ig) on day 0.5 (center panel) or days 7, 14, 21, and 28 (right panel), stained to detect B220 (brown) and gp38 (blue). (B) Spleen tissue from wild-type, LT-deficient or LT-deficient carrying the LT transgene (LT-tg/LT-/-) stained in brown to detect B220 (all panels) and in blue to detect CCL21 (top panels) and gp38 (bottom panels). Data are representative of more than four animals of each type. Note that the faint blue signal in the red pulp of the panels in A and the upper LT2/- panel in B was due to background staining and was also observed in sections stained with control antibodies.

Selective Expression of LT1ß2 in B Cells Is Sufficient to Promote Splenic CCL21 Expression, White Pulp T Zone Development, and Splenic DC Accumulation.

View larger version (146K): [in this window] [in a new window]   Figure 7. Transgenic restoration of LT1ß2 on B cells in LT-deficient mice promotes splenic CCL21 and CXCL13 expression and DC accumulation. (A) A schematic diagram of the membrane LT transgenic construct. See Materials and Methods for details. TMD, transmembrane domain; MAR, matrix-attachment region; E, enhancer. (B) Representative flow cytometric profiles of LTßR-Ig binding of B220+ B cells from blood and spleen of WT, LT-/-, and LT-transgenic/LT-/- mice as indicated. (C) Relative CCL21 and CXCL13 mRNA levels in spleen tissue from the indicated mice. Each circle represents an individual animal and bars represents means. (D) Flow cytometric profiles of CD11c staining in the indicated mice. Profiles are representative of four mice of each type and are for spleen cells prepared in the absence of collagenase. Analysis of two further spleen samples that had been prepared with collagenase revealed greater frequencies of CD11c+ cells, and continued to show restoration of CD11c+ cell frequency in the LT-tg/LT2/- animals.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

 
In the above studies, we demonstrate that B cells play a critical role in splenic, but not lymph node, T zone development. In mice lacking B cells, splenic gp38⁺ T zone stromal cells fail to develop into their normal extensive network, and T zone CCL21 expression is markedly reduced. Our findings indicate that B cells promote splenic T zone stromal cell development and chemokine expression at least in part by acting as a source of LT1ß2. This function of B cells is largely a fixed, developmental role. We also find that B cell–derived LT1ß2 promotes splenic DC accumulation or development. Furthermore, B cells are needed for accumulation of normal numbers of T cells in the spleen. Previous studies have indicated that LT1ß2 and T zone chemokines, CCL19 (ELC) and CCL21 (SLC), are not required for T cell accumulation in the spleen (16–18, 42). Therefore, we conclude that B cells provide at least two types of signals necessary for normal spleen organogenesis: (a) signals that promote CD4 and CD8 T cell accumulation in the spleen, and: (b) signals, including LT1ß2, that regulate properties of white pulp stromal cells and promote development of T zones and development or accumulation of DCs.

T zone stromal cells have been characterized as a population of mesenchymal cells that are distributed throughout lymphoid organ T zones (15, 43). The recent finding that these cells are a major source of CCL21 and CCL19 has suggested that they play a central role in bringing CCR7-positive T cells and DCs together (11). Previously, using the white-pulp stromal cell marker BP3, we provided evidence that T zone stromal cell maturation was dependent on LT1ß2 (14). Other studies have indicated that there are alterations in the expression pattern of the T zone and red-pulp stromal marker, ER-TR7, in LT-deficient or depleted mice (18, 44, 45). We show here that expression of gp38, a marker that is thought to stain the majority of T zone stromal cells (15), is also LT1ß2-dependent. Therefore, LT1ß2 appears to be critical for development of T zone stromal cells and, in turn, for the development of organized splenic T cell zones (Fig. 8).

View larger version (33K): [in this window] [in a new window]   Figure 8. Model of splenic T zone development in the mouse. Step 1, occurring in the days before and around the time of birth, LTßR+ mesenchymal cells proximal to splenic arterioles acquire some features of T zone stromal cells by unknown mechanisms. These cells produce low levels of CCL19 (not shown) and CCL21 in a LT1ß2-independent manner. Step 2, occurring in the first days to a few weeks after birth, newly produced B cells arrive in the spleen and express surface LT1ß2, possibly in response to CCL19 and CCL21 (reference 7), but likely also in response to other signals, and induce LTßR-signaling in the primitive stromal cells. These signals may act directly to promote growth (possibly involving cell division) of the stromal cell network and to increase expression of CCL21, gp38 and, to a lesser extent, CCL19. Alternatively, the signals may act indirectly, through intermediary LTßR+ cell types to cause these outcomes. It is also possible that the effects of LT1ß2 and B cells on chemokine and gp38 expression do not reflect direct induction but are secondary to growth of the T zone stromal network. Furthermore, cells in addition to B cells may contribute LT1ß2, especially for induction of gp38 as this marker is expressed at higher amounts in B cell–deficient animals than in LT-deficient animals. Step 3, T cells and DCs are recruited to the network of CCL21 and CCL19 producing stromal cells and the mature T zone forms.

The finding that T zone development is dependent on both LT1ß2 and B cells, together with the previous demonstration that B cells are a source of LT1ß2 (7, 9, 10, 37), led to the prediction that B cells act as the major source of this cytokine for splenic T zone development. Consistent with this, B cells enter the spleen in the first few days after birth and during this period the cells are located around central arterioles, in regions destined to become T cell areas (38, 39). Later, B cells continuously migrate through the outer T zone as they traffic to B cell areas (4). Immature B cells in the developing spleen were found to have low but measurable surface LT1ß2 (Fig. 5) and transfer of wild-type B cells, but not LT-deficient cells, to newborn lymphocyte-deficient mice was sufficient to upregulate splenic CCL21 (Fig. 4). Furthermore, transgenic expression of LT under control of Ig-kappa promoter and enhancer elements restored splenic CCL21 (and also CXCL13) expression and led to development of gp38⁺ T zone stromal cell networks in LT-deficient mice (Figs. 6 and 7). Therefore, several different findings support the conclusion that B cells act as a critical source of LT1ß2 in splenic T zone development. A model incorporating these findings is shown in Fig. 8.

A question that arises from these findings is whether B cells function as the only source of LT1ß2 required for splenic T zone development. Arguing against this is the Northern blot analysis of CCL21, which indicates that mRNA levels are reduced 5–10-fold in B cell–deficient spleen compared with 20-fold in LT-deficient spleen (14; Figs. 1 and 4). In addition, Gonzalez et al., found that pretreatment of SCID mice with LTßR-Ig influenced the subsequent ability of transferred B and T cells to organize within the white pulp (10). Recently, a hematopoietic cell type, characterized as CD4⁺CD3^-IL7R⁺LT1ß2⁺, has been implicated in the earliest steps in lymph node and Peyer's patch development (48–50). As we have not found a role for B cells or T cells in lymph node T zone stromal cell development (Figs. 1 and 2), we favor a model where CD4⁺CD3^- cells provide the necessary LT1ß2 signals. By contrast with lymph nodes, CD4⁺CD3^- cells are very infrequent in embryonic spleen and they have so far not been implicated in spleen development (48, 50, 51). In addition, we have shown that T cells are not needed as a source of LT1ß2 for induction of splenic CCL21. Future studies need to investigate what other cell types express LT1ß2 in the developing spleen. However, our studies are also consistent with the possibility that in normal animals, B cells act as a sufficient source of LT1ß2 for spleen development and the contributions of other cell types only become evident when B cells are absent. Interestingly, in the transgenic animals constitutively expressing LT1ß2 on B cells, the pattern of gp38⁺ T zone stromal cell networks is well developed but differs from wild-type by showing higher amounts of staining at B/T-zone boundaries (see Fig. 6). In addition, although B cell areas develop, they fail to form the highly polarized clusters typical of wild-type follicles (Fig. 6, and data not shown). A likely explanation for these differences is the altered regulation of LT1ß2 expression in B cells. In wild-type animals, we have provided evidence that LT1ß2 expression on B cells is cyclical, being induced by CXCL13 to maximal levels as B cells migrate into the FDC networks and then being downregulated as cells pass into the blood (7). By contrast, in the transgenic animals the expression is constitutive and divorced from normal regulatory controls, and B cells at the B/T boundary are likely to express the same high levels of LT1ß2 as cells within the CXCL13-producing FDC networks. While further study of the transgenic animals is needed, these observations provide support for the conclusion that cyclical expression of LT1ß2 on migratory B cells is important for the formation and maintenance of pattern in lymphoid tissue.

The ability of B cells to promote development of T zones in a LT1ß2-dependent manner was previously suggested by the finding that ectopic expression of CXCL13 in the pancreas caused recruitment of B cells and development of lymph node like structures, with T cell areas containing stromal cells, DCs and CCL21 (52). Such ectopic T cell areas did not develop in mice lacking B cells and antagonism of LT1ß2 function was sufficient to block T zone development (52). However, in contrast to the ectopic system, CXCL13 is not required for promoting splenic T zone development as these areas develop normally in CXCL13-deficient mice (7), and splenic CCL21 levels are unaffected by CXCL13 deficiency (unpublished observations). Perhaps another lymphoid tissue–expressed chemokine that is capable of upregulating LT1ß2 on B cells (7) plays this role during spleen development. The findings here and in the RIP-BLC system indicate that there are several pathways by which B cells can be induced to express LT1ß2 and to promote T zone development.

In addition to their requirement for development of T zone stromal cells, B cells (34; Fig. 2) and LT1ß2 (19) are required for normal accumulation of DCs in the spleen. Our findings provide evidence that B cells can function as a sufficient source of LT1ß2 for promoting normal DC accumulation in the spleen. Consistent with an important role for B cells in regulating splenic DC development, a recent report found that DCs from B cell–deficient spleens were functionally distinct from DCs taken from wild-type spleens (53). The origin of splenic DCs is not well defined. While some may derive directly from precursors in the blood or from DCs that have entered the blood, for example, from the heart or liver, there is also evidence that splenic DCs can develop locally from precursors in the spleen (54–56). LTßR expression has been reported in myeloid-lineage cells (57, 58), making it possible that B cell LT1ß2 acts directly on DC precursors. Alternatively, B cell–mediated induction of white pulp stromal cell maturation may indirectly promote DC development or may allow the survival of more DCs to be supported. It is unlikely that the effect of B cells on DC numbers is through effects on CCL21 or CCL19 as mice that lack these chemokines in lymphoid tissues have normal numbers of spleen DCs (11, 12), but it remains possible that B cells promote DC homing to the spleen through effects on other chemokines or trafficking molecules.

The finding that B cells were needed in the spleen for normal T zone stromal cell development and chemokine expression, and for normal accumulation of CD4 and CD8 T cells initially led us to consider that these processes were linked. However, this does not appear to be the case as animals that lack LT or LTß contain approximately normal numbers of T cells in the spleen (16–18). The plt mouse strain, lacking lymphoid CCL19 and CCL21 expression, also has normal numbers of splenic T cells (12). In both types of animal, the T cells are distributed mostly in the red pulp. A complication with these studies is that these animals either lack or have a severe paucity of T cells in lymph nodes, possibly leading to an indirect effect on T cell numbers in the spleen. However, we have found that when B cell–deficient mice are reconstituted with wild-type bone marrow or are restored as adults with a transfer of B cells, spleen size grows and T cell numbers reach normal levels (data not shown) despite the failure to upregulate CCL21 expression in spleen (Fig. 4). Therefore, the findings suggest a dissociation between B cell effects on T zone stromal cell development, CCL21 expression and DC accumulation, which involves B cell–derived LT1ß2, and B cell promotion of T cell accumulation in the spleen, which does not. We suggest that B cells provide signals, other than LT1ß2, that allow the spleen to accommodate the adult number of T cells. In this regard it is important to note that B cells have been shown to provide signals necessary for full development of Peyer's patches (59, 60), and at least some of these signals are suggested to be independent of LT1ß2 (59).

Our findings establish an important role for B cells in controlling spleen T zone development and provide a possible additional mechanism for how B cell deficiency may cause defects in immunity unrelated to a lack of antibody production. Such defects include reduced T cell responses to Salmonella typhimurium (61), Bordatella pertussis (62), Chlamydia trachomatis (63), Francisella tulaensis (64), Plasmodium chabaudi (65), and Leishmania major (66). B cells are also required for development of auotreactive T cells in MRL-lpr mice (33) and they facilitate T cell–mediated destruction of pancreatic ß-cells in NOD mice (67). While B cell antigen-presenting function may be a critical parameter in these diseases, we propose that some of the defects of B cell deficiency may reflect the role of B cells in promoting CCL21 expression, T zone stromal cell development and DC maturation or accumulation in spleen, in other B cell rich organs, and in B cell-rich inflammatory lesions. Futures studies need to investigate the contributions of these parameters to disease susceptibility in B cell–deficient humans, and to human inflammatory diseases involving B cells (68, 69).

	Acknowledgments

 
We thank Andrew Farr for anti-gp38, Jeff Browning for LTßR-Ig, Andrea Schmidt for microinjection, Jon Sedgwick and David Chaplin for LT-deficient mice, and Jeff Browning, Sanjiv Luther, and Karin Reif for comments on the manuscript.

This work was supported by the Howard Hughes Medical Institute and by National Institutes of Health grant AI45073.

Submitted: July 17, 2001
Revised: October 9, 2001
Accepted: October 25, 2001

	Footnotes

 
^* Abbreviations used in this paper: AP, alkaline phosphatase; DC, dendritic cell; FDC, follicular DC; LT, lymphotoxin; RAG, recombination activating gene.

	References

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