HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Permissions Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Sayegh, C. E. Articles by Ratcliffe, M. J. H. Search for Related Content PubMed PubMed Citation Articles by Sayegh, C. E. Articles by Ratcliffe, M. J. H.

Perinatal Deletion of B Cells Expressing Surface Ig Molecules That Lack V(D)J-Encoded Determinants in the Bursa of Fabricius Is Not Due to Intrafollicular Competition¹

Department of Microbiology and Immunology, McGill University, Montreal, Quebec, Canada

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

 
During embryonic development, the avian bursa of Fabricius selects B cell precursors that have undergone productive V(D)J recombination for expansion in oligoclonal follicles. During this expansion, Ig diversity is generated by gene conversion. We have used retroviral gene transfer in vivo to introduce surface Ig molecules that lack V(D)J-encoded determinants into B cell precursors. This truncated µ heavy chain supports both B cell expansion within embryo bursal lymphoid follicles and gene conversion. We show that individual follicles can be colonized exclusively by cells expressing the truncated µ chain and lacking endogenous surface IgM, ruling out a requirement for V(D)J-encoded determinants in the establishment of bursal lymphoid follicles. In striking contrast to their normal development in the embryo, bursal cells expressing the truncated µ-chain exhibit reduced rates of cell division and increased levels of apoptosis after hatching. The level of apoptosis in individual follicles reflects the proportion of cells within the follicle that express the truncated µ-chain. In particular, high levels of apoptosis are associated with follicles containing exclusively cells expressing the truncated µ receptor. Thus, apoptotic elimination of such cells is not due to competition within the follicle by cells expressing endogenous surface IgM receptors. This provides the first direct demonstration that the regulation of B cell development in the avian bursa after hatching differs fundamentally from that seen in the embryo. The requirement for intact IgM expression when the bursa is exposed to exogenous Ag implicates a role for Ag in avian B cell development after hatching.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
The bursa of Fabricius is the primary lymphoid organ responsible for B cell lymphopoiesis in birds (1, 2, 3, 4, 5, 6). Although the bursal microenvironment is not required for Ig gene rearrangement (7, 8) or expression (9, 10), B-lineage-committed precursor cells migrate in a single wave to the bursal primordium during embryonic life (11, 12). Those precursors that undergo productive Ig gene rearrangement migrate across the basement membrane and form follicles of rapidly dividing cells (13, 14), termed epithelial buds, and it is from these cells that the entire B cell compartment of the bird is derived. Chicken Ig gene rearrangement is restricted to the developing embryo and generates sIg receptors of very limited diversity (15, 16). The specificity of these receptors, however, is not important for the early stages of bursal colonization, since we have recently demonstrated (17) that the colonization of bursal follicles can be supported by the cell surface expression of a truncated Ig µ heavy chain (Tµ).³ The Tµ molecule lacks the VDJ_H and Cµ1 domains and, as a consequence, neither binds Ig light chain nor requires the presence of light chains for its surface expression on B cell precursors.

Those B cell precursors that productively colonize bursal follicles as a consequence of either endogenous sIgM expression or expression of the Tµ protein undergo rapid cell division during embryonic life (18), and the number of B-lineage cells within the bursa doubles every day for the last 10 days of embryonic life (19). Several experimental approaches have demonstrated that the B cells in each follicle are derived from a limited number (two to five) of sIg⁺ precursors and, further, that there is no traffic of B-lineage cells from one follicle to another (10, 20, 21). As a consequence, the increase in bursal cellularity observed after about embryonic day 15, when most immigration of B cell precursors to the bursa has ended, represents the consequences of B cell division within the bursa. Ig diversity is generated among this population of rapidly dividing sIg⁺ bursal cells (14, 15, 22). In chickens (1, 3, 14, 15), as in some other mammalian species (23, 24), Ab diversity is generated by a process of gene conversion. Sequences derived from upstream pseudo-V genes replace homologous sequences in the unique V_H1 and V_L1 genes following their rearrangement to DJ_H and J_L, respectively. We have demonstrated that although B cell precursors expressing Tµ do not express endogenous sIgM, some contain endogenous gene rearrangements (17). Analysis of VJ_L sequences from neonatal bursal cells expressing Tµ has demonstrated that they have undergone as much diversification by gene conversion as VJ_L sequences in cells expressing endogenous sIg receptors (25). Consequently, Tµ expression by B cell precursors is sufficient to support the stages of B cell development that occur in the avian embryo, namely follicular colonization with the onset of B cell proliferation and the induction of Ig diversification by gene conversion.

The physiology of the bursa undergoes a series of changes around the time of hatching. The rate of bursal cell growth, as judged by the number of B-lineage cells within the bursa, slows (19). Rather than doubling in cell number every day during embryonic life, cell numbers double about every 7 days. Some cells migrate from the epithelial bud back across the basement membrane to form an outer cortex of cells surrounding a central medulla, and the basement membrane develops into a complex cortico-medullary junction of interdigitating cells (26). As the cortico-medullary distribution of lymphocytes develops in the posthatching period, cortical cells continue to undergo rapid cell division. In contrast medullary lymphocytes have markedly reduced levels of cell division (18, 27, 28).

Based on calculations of the rates of bursal cell division and emigration of bursal cells to the periphery (29, 30), it has been estimated that only about 5% of the cells produced in the juvenile bursa emigrate to the periphery. The great majority of bursal cells die in situ by apoptosis (31, 32). Although bursal cells that lose the expression of sIg die in situ (32), it is unclear whether the loss of sIg expression is the trigger responsible for all bursal cell death. In this regard, gene conversion in the chick embryo efficiently maintains the productive reading frame of the IgV_L gene even under circumstances where bursal cell viability is maintained by expression of the Tµ protein and not by endogenous sIg expression (25).

The bursa is a gut-associated lymphoid tissue. Exogenous and gut-derived Ags are actively transported across the bursal epithelium into the lymphoid follicles of the bursa (33, 34, 35, 36). Therefore, the antigenic environment of B cells in the bursa after hatching differs from that of bursal cells developing in the embryo. At present, however, the consequences of bursal cell exposure to Ag remain unclear. Ligation of the bursal duct before hatching blocks the transport of gut-derived Ags and/or mitogens into the bursa and results in reduced proliferation of bursal cells after hatching (27). In addition, introduction of Ag into bursal follicles has been shown to result in increased Ab response in the periphery following subsequent systemic challenge (37). Two distinct populations of peripheral B cells have been identified as emigrating from the bursa (30, 38), leading to speculation that the maturation and/or emigration of at least some bursal cells might require a cognate interaction with Ag.

In this paper we have addressed the question of whether discrete physiological mechanisms regulate the growth and development of B cell precursors in the bursa before and after hatching. We show that while expression of the Tµ protein is sufficient to support normal bursal cell development in the embryo, cells expressing Tµ are selectively eliminated from the bursa after hatch. Elimination of Tµ⁺ bursal cells occurs both in follicles that also contain cells expressing endogenous sIgM receptors and in follicles containing exclusively Tµ⁺ cells. We can conclude, therefore, that the elimination of Tµ⁺ cells occurs independently of competition for intrafollicular space within the bursa. These results provide the first direct evidence that the Ag-binding Fab domains of the sIgM molecule play a critical role in avian B cell development.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

 
Generation of RCAS-Tµ-infected chicks

RCAS-Tµ- or control RCAS virus-infected chicks were generated as described previously (17). On day 3 of incubation, 1 million RCAS- or RCAS-Tµ-transfected line 0 embryo fibroblasts were injected in ovo into SC line (Hyline International, Dallas Center, IA) embryos.

Cell suspensions and flow cytometry

Bursal cells and thymocytes were prepared and stained with 11C6 (anti-chicken Ig light chain), Hy18 (anti-chicken µ), EP96 (anti-CD4), or EP72 (anti-CD8) as described previously (9, 17, 22, 39). Binding of primary Abs was detected using FITC-, R-PE-, or biotin-conjugated goat anti-mouse Ig isotype-specific secondary reagents (Southern Biotechnology Associates, Birmingham, AL). Biotin-conjugated Abs were detected with streptavidin-spectral red (Southern Biotechnology Associates). Viable cells were analyzed or sorted on a FACS Vantage (Becton Dickinson Canada, Mississauga, Canada) by gating on forward scatter and side scatter. Viable cells were sorted with additional gating for the exclusion of cells staining with propidium iodide (0.5 µg/ml).

For determination of cellular DNA content, stained bursal cells were FACS sorted to >98% purity, pelleted, and resuspended for 10 min at 37°C in Vindelov’s solution (3.4 mM Tris, 7.5 x 10^-5 M propidium iodide, 0.1% (v/v) Nonidet P-40, and 700 U/L RNase A in 10 mM NaCl, pH 7.6) as described previously (40). The DNA content of the resulting nuclei was then determined on a Becton Dickinson FACScan.

Immunohistochemistry

Bursae from hatched chicks were extracted and frozen in crushed dry ice for 2 min. The frozen tissues were then embedded in OCT and stored at -70°C. Eight-micron sections were cut in a refrigerated microtome at -17°C and mounted on SuperFrost Plus slides (Fisher Scientific, Nepean, Canada). The sections were dried overnight at room temperature before use. Slides were rehydrated in 50 mM Tris in 0.15 M NaCl, pH 7.4 (TBS), for 10 min, then washed three times, each for 10 min, with 0.09% (v/v) Tween 20 in TBS followed by two washes in TBS. Tissues were fixed in freshly prepared 4% paraformaldehyde in 70 mM NaHPO₄, pH 7.0, for 10 min and washed again twice for 5 min each time in TBS. Endogenous peroxidase activity was quenched using a 3% peroxide/methanol solution (1/4) for 30 min. This was followed by two more washes in TBS for 5 min each. The slides were then blocked in TBS with 2.5% FCS for at least 30 min in a humidified box at room temperature.

Sections were stained with the following mouse mAbs: anti-chicken µ 4-22, generated as described previously (22) at 30 µg/ml, anti-chicken light chain 11C6 (22) at 2.5 µg/ml, or a combination of 21-1A4 and Fu5.11G2 (anti-ChB6.1 and anti-ChB6.2, respectively) (41), each at 20 µg/ml.

Primary Abs were diluted in blocking buffer, and slides were incubated for 2 h at room temperature in a humidified box, after which they were washed three times in TBS. Binding of primary Abs was detected with biotinylated goat anti-mouse Ig Ab diluted in TBS containing normal goat serum (Vector, Burlingame, CA) and incubated for 1 h at room temperature followed by three washes in TBS. Biotinylated Abs were detected using the ABC kit from Vector and revealed with diaminobenzidine substrate to which NiCl₂ was added (17).

In situ detection of fragmented DNA

Fragmented DNA was detected in situ by TUNEL assays performed either on frozen sections, prepared as described above, or on paraffin-embedded sections. Frozen sections were air-dried for 30 min at room temperature and then heat-fixed for 3 min at 50°C. Slides were equilibrated to room temperature for 15 min, fixed in 4% paraformaldehyde, pH 7.0, for 1 h at room temperature, and washed three times in TBS, followed by incubation in 100% ethanol/glacial acetic acid (2/1) at -30°C for 5 min. After washing in TBS, endogenous peroxidase activity was blocked as described above. Paraffin-embedded sections were deparaffinized by incubation in xylene, xylene was removed by washing with 100% ethanol, and tissue was rehydrated by sequential washing in an ethanol gradient ranging from 95 to 35% ethanol in dH₂O followed by a wash in dH₂O. Slides were equilibrated in PBS, pH 6.6, and proteins were digested with proteinase K at 20 µg/ml for 15 min at 37°C. Slides were rinsed in dH₂O for a minimum of 15 min. Endogenous peroxidase activity was quenched as described above, except that washes were performed in dH₂O instead of TBS.

Sections were equilibrated with 50 µl of 0.25 mg/ml BSA in OPA Plus buffer (Amersham Pharmacia, Baie d’Urfé, Canada) for 10 min at room temperature in a humid chamber. Free DNA ends were subsequently biotin labeled by incubation with 15 U TdT, 10 µM dUTP-biotin, and 0.25 mg/ml BSA in 50 µl of Opa Plus buffer (all from Pharmacia) for 75 min at 37°C in a humid chamber. The reaction was stopped by washing the slides in 2x SSC for 5 min at room temperature followed by three washes in TBS. Biotinylated Abs were detected using the ABC kit from Vector and were developed using purple VIP (Vector) for about 4 min. Development was stopped by washing in TBS. Slides were counterstained in methyl green for about 5 min (0.5% methyl green in 0.1 M sodium citrate, pH 4.0).

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
RCAS-Tµ is a productive avian retrovirus that contains the sequence encoding a truncated sIgµ heavy chain protein from which the VDJ_H and Cµ1 domains have been deleted, allowing Tµ expression in the absence of light chain expression (17). Transcripts encoding Tµ are initiated in the 5' long terminal repeat of the RCAS virus, and Tµ mRNA is produced by splicing between a splice donor at the 5' end of the gag gene and a splice acceptor 5' to the Tµ sequence. Transcription termination and polyadenylation signals are provided by the 3' long terminal repeat of the RCAS virus (42, 43).

We have previously shown that B cells expressing a truncated form of sIgµ (Tµ) develop in the lymphoid follicles of the avian embryo bursa of Fabricius despite lacking intact sIgM receptors encoded by endogenous Ig genes (17). As a consequence, neonatal bursae of chicks infected as embryos with RCAS-Tµ contain a significant proportion of µ⁺L^- cells. Bursal follicles are each colonized normally by two to five B cell precursors (20, 21), so it remained unclear from previous results whether individual follicles within the bursa could contain exclusively µ⁺L^- cells, or whether the formation of individual bursal follicles required the presence of cells expressing endogenous intact sIgM.

To address this question, serial sections of neonatal bursae from chicks infected as embryos with RCAS-Tµ or control RCAS viruses were stained with an mAb specific for Igµ heavy chain (which recognizes a determinant expressed on both endogenous sIgM as well as the Tµ protein), IgL (which recognizes cells expressing endogenous sIgM but not cells expressing the Tµ protein), or the ChB6 (Bu-1) pan-B cell Ag. The majority of follicles from RCAS-Tµ-infected chicks contained cells that stained with both anti-µ and anti-L Abs (Fig. 1, A–C), as did all follicles from RCAS-infected chicks (data not shown). In addition, however, we identified follicles from RCAS-Tµ-infected chicks that contained exclusively µ⁺L^- cells (arrow in Fig. 1A). These follicles were of normal morphology and cellularity, demonstrating that expression of intact sIgM is not required for the formation of individual bursal follicles in the bursa of Fabricius.

View larger version (86K): [in this window] [in a new window]   FIGURE 1. Bursal follicles in RCAS-Tµ-infected chicks can contain exclusively µ+L- cells. Frozen sections of embryonic day 21 bursae from RCAS-Tµ-infected chicks stained for the expression of IgL (A and D), the ChB6 pan-B cell marker (B and E), and µ (C and F). This bursa contained 18.5% µ+L- cells as judged by flow cytometry. A follicle containing exclusively µ+L- cells is indicated by the arrow in A. Follicles appearing to contain exclusively µ+L+ cells are indicated (*) in A and D. Follicle containing a mixture of µ+L- and µ+L+ cells is indicated by arrowheads in A and D. Bar = 100 µm.

Because bursal follicles in the embryonic bursa are oligoclonal, we would expect the majority of bursal follicles in RCAS-Tµ-infected chicks to contain both µ⁺L⁺ cells expressing endogenous sIgM and µ⁺L^- cells expressing Tµ under conditions where the bursa overall contains a mixture of both cell types. Indeed, bursal follicles of RCAS-Tµ-infected chicks frequently stain heterogeneously with anti-IgL Abs (Fig. 1, D–F), indicative of mixed follicles containing both µ⁺L⁺ and µ⁺L^- bursal cells.

The frequency of follicles containing exclusively µ⁺L^- cells is low (<3% of follicles) relative to the total proportion of µ⁺L^- cells in bursal cell suspensions of neonatal bursae (typically 10–25%), indicating that the majority of µ⁺L^- bursal cells proliferate in mixed follicles that also contain µ⁺L⁺ cells. This is consistent with the oligoclonality of bursal follicles and suggests that the efficiency with which µ⁺L^- precursors colonize bursal follicles is equivalent to that seen with µ⁺L⁺ precursors expressing endogenous receptors.

We have previously demonstrated that the proportion of µ⁺L^- cells in the bursa of neonatal chicks infected as day 3 embryos with RCAS-Tµ is about 20% (17). Surprisingly, flow cytometric analysis of bursal cell suspensions revealed that the proportion of µ⁺L^- bursal cells in RCAS-Tµ-infected chicks decreased rapidly in the first 2 wk after hatching (Fig. 2). By 2 wk of age, most chicks contained <1% µ⁺L^- cells and four of nine contained <0.3% µ⁺L^- bursal cells.

View larger version (13K): [in this window] [in a new window]   FIGURE 2. Loss of bursal cells expressing Tµ occurs after hatching. The proportion of µ+L- cells from the bursae of 89 chicks infected as day 3 embryos with RCAS-Tµ was determined by flow cytometry. Each point on the large graph represents an individual sample; the arrow shows the day of hatching. The inset shows the means with SEs for the proportion of µ+L- cells in the bursae shown on the large graph (•) or the proportion of CD4- and/or CD8-expressing thymocytes that express the Tµ protein ().

At the time of hatching, the rate of cell division among FACS-sorted µ⁺L^- bursal cells is indistinguishable from that seen with µ⁺L⁺ cells and exhibits the high rate of proliferation characteristic of the rapid expansion of B cells in the bursa of neonatal chicks (Fig. 3, D and E), confirming previous results (17, 18, 19). The growth rate of normal bursal cells declines after hatching, and this is reflected in the proportion of µ⁺L⁺ cells in S, G₂, and M phases of the cell cycle on day 5 (Fig. 3F). However, µ⁺L^- bursal cells of day 5 chicks show a dramatic reduction in proliferation compared with µ⁺L⁺ bursal cells from the same chicks (Fig. 3G). Therefore, the rapid disappearance of µ⁺L^- cells can be accounted for at least in part by a reduction in their rate of proliferation.

View larger version (42K): [in this window] [in a new window]   FIGURE 3. Loss of µ+L- bursal cells after hatching is due to reduced cell division and apoptosis. A–C, Contour plots of 20,000–50,000 bursal cells stained with anti-µ (Hy18) and anti-L (11C6). Shown are bursal cells from RCAS-infected (A) or RCAS-Tµ-infected (B and C) chicks on the day of hatching (B) or 5 days after hatching (A and C). The proportions of µ+L- cells in these samples were 26.5% (B) and 0.65% (C). D–J, µ+L+ (D, F, and H) and µ+L- (E, G, and J) cells were purified to >98% purity by cell sorting and stained for DNA content. Histograms of 10,000 cells are shown. H and J, The first 100 channels of F and G, respectively, with the y-axis amplified 10-fold.

Under normal circumstances, apoptotic cells are rapidly phagocytosed by tissue macrophages (44, 45). Assessment of apoptotic cells by flow cytometry probably underestimates the proportion of apoptotic cells within the bursa, because the analysis was restricted to cells of lymphoid size, and macrophages containing phagocytosed apoptotic remnants would be excluded from the analysis. The frequency and distribution of apoptotic cells in situ within the bursa were therefore determined by TUNEL staining of paraffin-embedded bursal sections (Fig. 4), followed by counting the number of apoptotic cells per bursal follicle section (Fig. 5).

View larger version (82K): [in this window] [in a new window]   FIGURE 4. Increased apoptosis in the bursa of RCAS-Tµ-infected chicks after hatch. Apoptosis detected by TUNEL assay on paraffin sections of bursae from chicks infected with RCAS control (A, C, and E) or RCAS-Tµ (B, D, and F) on embryonic day 21 (A and B) or day 2 after hatching (C–F). By flow cytometry the embryonic day 21 RCAS-Tµ-infected bursa shown in B contained 78% µ+L- cells; the day 2 RCAS-Tµ-infected bursa shown in D and F contained 8.4% µ+L- cells. Filled bars = 100 µm (A–D) or 50 µm (E and F).

View larger version (32K): [in this window] [in a new window]   FIGURE 5. Quantitation of apoptosis in the bursa of RCAS-Tµ-infected chicks. Apoptotic cells were counted under x40 magnification from bursae from chicks infected with RCAS control () or RCAS-Tµ () on embryonic day 21 (A and C) or day 2 after hatching (B and D). A, Each set of three bars corresponds to data from (left to right) 255 follicle sections of RCAS-infected bursa, 253 follicle sections from RCAS-Tµ-infected bursa containing 17.3% µ+L- cells, and 258 follicle sections from RCAS-Tµ-infected bursa containing 78.7% µ+L- cells. B, Each set of three bars corresponds to data from (left to right) 296 follicle sections of RCAS-infected bursa, 225 follicle sections from RCAS-Tµ-infected bursa containing 12.2% µ+L- cells, and 174 follicle sections from RCAS-Tµ-infected bursa containing 8.4% µ+L- cells. C and D, From the data sets in A and B, respectively, the number of apoptotic cells present in phagocytosed clusters (as shown, for example, in Fig. 4F) was counted for each follicle and expressed as a proportion of the total number of follicles.

Within 2 days after hatching, however, there was a marked difference in the frequency and distribution of apoptotic cells when comparing bursal sections from RCAS-Tµ and RCAS-infected chicks (Figs. 4, C and D, and 5B). The frequency of apoptotic cells in RCAS-infected bursae was increased after hatching compared with that in embryonic day 21 bursae. However, in sections from RCAS-Tµ-infected chicks the average number of apoptotic cells per follicle section was increased compared with that in age-matched RCAS control sections, and there was a striking increase in the frequency of follicles containing a high number of apoptotic nuclei per follicle. In particular, the frequency of follicles that contained 20 or more apoptotic nuclei increased to >35% of all follicles in the section compared with about 10% of follicles in control sections from RCAS-infected chicks. Conversely, there was a marked reduction in the frequency of bursal follicles with zero to three detectable apoptotic events per follicle in RCAS-Tµ-derived sections compared with that in RCAS control sections.

There were also differences in the distribution of apoptotic cells within bursal follicles of RCAS-Tµ-infected chicks after hatching compared with that in control bursae. Apoptotic cells in control bursal sections were typically distributed evenly as single cells within follicles, with <5% of follicles containing >10 phagocytosed nuclei/follicle on day 2 after hatching (Figs. 4E and 5C). In contrast, the follicles from RCAS-Tµ-infected chicks contained a significant proportion of apoptotic cells within clusters, many of which had the appearance of tissue macrophages that had ingested several apoptotic cells (Fig. 4F). The frequency of follicles from RCAS-Tµ-infected chicks containing >10 phagocytosed nuclei on day 2 after hatching was about 20% of follicles.

The distribution of apoptosis in bursal follicles from RCAS-Tµ-infected chicks was not even. Individual sections contained follicles with little apoptosis as well as follicles with considerable apoptosis (Figs. 4D and 5B). For example, 35% of follicle sections from Tg57 contained 20 or more apoptotic cells, while 10% of follicles contained three or fewer apoptotic cells. We therefore determined whether follicles from RCAS-Tµ-infected chicks that contained exclusively µ⁺L^- cells contained elevated levels of apoptotic cells or, alternatively, whether these follicles exhibited reduced levels of apoptosis. Serial frozen sections of bursal tissue from RCAS-Tµ-infected chicks were assayed for apoptotic cells by TUNEL and for IgL and either Igµ or ChB6 to identify follicles containing exclusively Tµ⁺ cells. On days 2–3 of age most follicles containing exclusively µ⁺L^- cells contained high levels of apoptotic cells (Fig. 6). Not surprisingly, given that the majority of µ⁺L^- cells develop in mixed follicles that also contain µ⁺L⁺ cells, some highly apoptotic follicles also stained heterogeneously for the expression of IgL, demonstrating that they do indeed contain µ⁺L⁺ cells expressing endogenous receptors (Fig. 6, G and H). Nonetheless, the high levels of apoptosis in follicles containing exclusively µ⁺L^- cells demonstrates that elimination of µ⁺L^- cells by apoptosis is not a consequence of competition with cells expressing endogenous sIgM for physiological space within a follicle.

View larger version (165K): [in this window] [in a new window]   FIGURE 6. Apoptosis in bursal follicles containing exclusively µ+L- cells. Frozen sections from day 2 (A–C and G–J) or day 3 (D–F) RCAS-Tµ-infected bursae stained for IgL (A, D, and G), TUNEL (B, E, and H), Igµ (F), or ChB6 (C and J). By flow cytometry the RCAS-Tµ-infected bursa shown in A–C and G–H contained 20% µ+L- cells, and the RCAS-Tµ-infected bursa shown in D–F contained 12.6% µ+L- cells. Follicles containing exclusively µ+L- cells are indicated by arrows, follicles appearing to contain exclusively µ+L+ cells are indicated by asterisks, and follicles containing a mixture of µ+L- and µ+L+ cells are indicated by arrowheads. Bars = 100 µm.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

On the average, µ⁺L^- bursal cells in neonatal RCAS-Tµ-infected chicks accounted for 15–20% of total bursal B cells. However, the frequency of bursal follicles that uniquely contained µ⁺L^- precursors was typically about 2%, indicating that the majority of µ⁺L^- bursal cells develop in follicles containing both µ⁺L⁺ and µ⁺L^- cells. This is consistent with several reports demonstrating that a limited number of B cell precursors (between two and five) productively colonize each bursal follicle during embryogenesis and that there is no interfollicular trafficking of lymphoid cells within the bursa (10, 21, 22). Indeed in the case of a bursa containing 25% µ⁺L^- cells, in which each bursal follicle is colonized by three precursors, one would expect about 1.5% of follicles to have been colonized by three µ⁺L^- precursors. Our results therefore are consistent with the oligoclonal colonization of bursal follicles by two or three precursors and furthermore demonstrate that the efficiency of bursal follicle colonization by µ⁺L^- precursors is equivalent to that seen with µ⁺L⁺ precursors.

µ⁺L⁺ and µ⁺L^- cells from neonatal chicks proliferate at the same rate (Fig. 3, D and E) typical of the rapid expansion of bursal cells during embryonic development (18, 19). Taken together with the observation that most µ⁺L^- bursal cells develop in oligoclonal follicles that also contain µ⁺L⁺ cells, these results indicate that µ⁺L^- precursors are at no intrafollicular competitive disadvantage with respect to their proliferation during embryogenesis in the presence of µ⁺L⁺ precursors. In contrast, anergic murine B cells persist in the periphery only in the absence of competition from nonanergic B cells. In the presence of competing B cells, anergic B cells are excluded from follicular niches and are quickly eliminated (48, 49). The observation that µ⁺L^- cells in the bursa develop initially at normal rates despite the presence of competitor B cells expressing endogenous receptors supports our conclusion that these cells are undergoing a normal program of development during embryogenesis. This conclusion is further strengthened by the demonstration that at the time of hatching the small proportion of µ⁺L^- cells in the bursa of RCAS-Tµ-infected chicks that have rearranged the endogenous VJ_L locus (17) has undergone as much Ig VJ_L diversification by gene conversion as their µ⁺L⁺ counterparts (25).

Surface expression of either endogenous sIgM or Tµ is required for B cell expansion in the embryo bursa. Because the chicken sIgM complex includes homologues to CD79a (Ig) and CD79b (Igß), and both endogenous sIg and Tµ (50, 51) can transduce signals across the plasma membrane, constitutive basal signaling through the sIg complex may be sufficient to support B cell development in the embryo. This is analogous to the requirement for continuous sIg expression in the murine spleen, where B cell survival depends on constitutive basal signaling through sIg (52). The disappearance of cells expressing Tµ in the posthatching period, however, demonstrates that such basal signaling is not sufficient to support bursal cell development after hatching.

µ⁺L^- cells after hatching drop out of cell division, as demonstrated by reduced levels of cells in S, G₂, and M phases of the cell cycle, and undergo apoptotic cell death. We have previously demonstrated that cell death in bursal cells from juvenile chickens is preceded by the loss of sIg (31). It was argued that the loss of sIg could be induced in part by nonproductive gene conversion events leading to out-of-frame VJ_L gene segments. However, µ⁺L^- bursal cells from RCAS-Tµ-infected chicks express the Tµ receptor independent of the status of the endogenous Ig genes. Therefore, failed gene conversion events cannot account for the loss of µ⁺L^- bursal cells after hatching.

Several lines of evidence suggest that the cellularity of the bursa is closely regulated by homeostatic mechanisms that are currently undefined but probably reflect competition for physiological space among developing bursal cells. Thus, in IgM-1^a/IgM-1^b allotype heterozygous chicks, deletion of bursal cells expressing the sIgM-1a allotype results in a compensatory expansion of cells expressing the alternative sIgM-1b allotype (53). Similarly, bursal follicles experimentally colonized by single precursor cells rapidly attain the same cellularity as follicles naturally colonized by several precursor cells (20). It is currently unclear whether the elimination of µ⁺L^- cells requires the presence of competing µ⁺L⁺ B cells within the bursa, because the RCAS-Tµ chicks described here contain bursal cells expressing endogenous sIgM receptors. Nonetheless, the elimination of µ⁺L^- cells from follicles that do not contain µ⁺L⁺ cells demonstrates that there is clearly no requirement for intrafollicular competition from µ⁺L⁺ bursal cells. If interfollicular competition is required for the elimination of µ⁺L^- cells, it must operate by soluble intermediates, because there is no traffic of B cells from one follicle to another.

The bursa as well as the lymphoid cells within it undergo a series of physiological changes that are initiated in the perinatal period. During embryonic development, lymphoid cells proliferate in epithelial buds, resulting in an exponential increase in the number of sIg⁺ cells within the bursa, such that B cell numbers double every day. After hatching, however, the rate at which the number of B cells in the bursa increases slows dramatically, such that bursal B cell numbers double every 7 days (19). This is consistent with the reduced number of cells in S, G₂, and M phases of the cell cycle in µ⁺L⁺ bursal cells on day 5 (22%; Fig. 3F) compared with that on the day of hatching (46%; Fig. 3D). In addition, starting around the time of hatching, B cells in the epithelial buds segregate to form an outer cortex of cells surrounding the inner medulla. After this occurs, most bursal cell proliferation occurs in the cortex of bursal follicles, the medulla contains largely nondividing cells (18, 27, 28). The factors determining which B cells within the epithelial bud migrate to form the cortex of rapidly dividing cells within the bursal follicle are currently unknown. The results presented here suggest, however, that expression of Tµ is not sufficient to support this development.

The frequency of apoptotic cells in the normal bursa increases after hatching. Thus, in control sections the average number of apoptotic cells per follicle increased between embryonic day 21 (Figs. 4A and 5A) and day 2 after hatching (Figs. 4C and 5B). The mechanism by which the frequency of apoptosis in the bursa increases after hatching is unclear, although glucocorticoid concentrations in the embryo increase around the time of hatching (54), and injection of glucocorticoids into the hatched chick induces bursal cell death (55).

There are several lines of evidence that would be consistent with a role for Ags and/or mitogens in promoting the development of bursal cells after hatching. Gut-derived Ags are transported by means of the bursal duct into the bursal lumen. From there, they are actively transported by pinocytosis from the bursal lumen to the epithelial bud or medulla of bursal follicles under conditions where they can physically interact with developing bursal lymphoid cells (33, 34, 35, 36). Ligation of the bursal duct blocks the traffic of gut-derived Ags into the lymphoid compartment of the bursa. Although this treatment does not impede either the rate of B cell expansion in embryo epithelial buds (27) or the rate of Ab diversification by gene conversion during embryonic development (56), the rate of B cell growth in the posthatching bursa is reduced. A similar situation occurs when bursal epithelia are grafted into the abdominal wall (12). Such epithelia become colonized by bursal precursors and develop normally during embryonic life under conditions where they are isolated from gut-derived Ags. After hatching, however, these ectopic bursae involute.

One possible interpretation of these results is that bursal cell development after hatching is driven by gut-derived mitogen(s). This is difficult to reconcile with the failure of Tµ⁺ bursal cells to develop normally after hatching, because we have been unable to demonstrate any difference in phenotype between Tµ⁺ cells and cells expressing endogenously encoded sIgM, using a large range of mAbs that recognize bursal cell surface Ags (17, 57). In addition, there is no a priori reason why expression of Tµ should inhibit the expression of a mitogen receptor or block the function of that receptor.

The Tµ protein lacks the VDJ_H and Cµ1 domains. As a consequence it cannot bind light chain and does not require association with light chain for surface expression; indeed, the great majority of Tµ⁺ cells do not contain a functionally rearranged light chain gene (17). Consequently, the major difference between Tµ⁺ cells and cells expressing endogenously encoded sIgM is that the latter can bind Ag by means of the V(D)J-encoded µ and light chain V domains. The results presented here demonstrate that sIg molecules that lack Ag-binding capacity fail to promote the development of bursal cells after hatching. The repertoire of developing bursal cells has been extensively diversified by gene conversion by the time of hatching (13, 14, 15, 16), so posthatching bursal development cannot be driven by a small set of B cell specificities. Posthatching bursal cell development may therefore be driven by specific interactions between the sIg receptor and multiple gut-derived Ags presented within the bursal follicle. The presence of cells in the bursa expressing immune complexes on their surface would be consistent with this view (58). Alternatively, V(D)J-encoded determinants in the bursa may be ligated by a B cell superantigen, as has been proposed in other species (59, 60). The requirement for sIg ligation at a time when endogenous glucocorticoids are elevated would suggest the possibility that bursal cells become susceptible to glucocorticoid-induced cell death in the perinatal period unless Ag or superantigen induces sIg ligation. A balance between glucocorticoid-induced death and Ag receptor ligation has been proposed to regulate the selection of T cells in the developing thymus (61, 62).

In conclusion, we have demonstrated that during embryonic development, bursal follicles in RCAS-Tµ-infected chicks can be colonized exclusively by µ⁺L^- cells lacking endogenous sIgM receptors. We show that µ⁺L^- cells are rapidly lost from the bursa after hatching as a consequence of decreased cell division rates and by the selective increase in apoptosis of µ⁺L^- cells compared with that of µ⁺L⁺ bursal cells expressing endogenous receptors. The high level of apoptosis in bursal follicles containing exclusively µ⁺L^- cells after hatching demonstrates that apoptotic elimination of such cells occurs independently of intrafollicular competition from bursal cells expressing endogenous receptors.

	Acknowledgments

 
We thank Sandra Iacampo for expert technical assistance, Ken McDonald for flow cytometric cell sorting, and Emilia Antecka for assistance with immunohistochemistry.

	Footnotes

 
¹ This work was supported by the Medical Research Council of Canada (MT10040). C.E.S. was supported by a Medical Research Council of Canada studentship.

² Address correspondence and reprint requests to Dr. Michael J. H. Ratcliffe, Department of Microbiology and Immunology, McGill University, 3775 University Street, Montreal, Quebec, Canada H3A 2B4.

³ Abbreviations used in this paper: Tµ, truncated Igµ chain; sIg, cell surface Ig.

Received for publication December 29, 1999. Accepted for publication February 28, 2000.

	References

Top Abstract Introduction Materials and Methods Results Discussion References

 

1. Weill, J. C., C. A. Reynaud. 1987. The chicken B cell compartment. Science 238:1904.
2. Ratcliffe, M. J. H.. 1989. Development of the avian B lymphocyte lineage. Crit. Rev. Poult. Biol. 2:207.
3. McCormack, W. T., L. J. Tjoelker, C. B. Thompson. 1991. Avian B cell development: generation of an immunoglobulin repertoire by gene conversion. Annu. Rev. Immunol. 9:219.[Medline]
4. Ratcliffe, M. J. H.. 1985. The ontogeny and cloning of B cells in the bursa of Fabricius. Immunol. Today 6:223.
5. Ratcliffe, M. J. H., E. Paramithiotis. 1990. The end can justify the means. Semin. Immunol. 2:217.[Medline]
6. Ratcliffe, M. J. H., K. A. Jacobsen. 1994. Rearrangement of immunoglobulin genes in chicken B cell development. Semin. Immunol. 6:175.[Medline]
7. Reynaud, C. A., B. A. Imhof, V. Anquez, J. C. Weill. 1992. Emergence of committed B lymphoid precursors in the developing chick embryo. EMBO J. 11:4349.[Medline]
8. Mansikka, A., M. Sandberg, O. Lassila, P. Toivanen. 1990. Rearrangement of immunoglobulin light chains in the chicken occurs prior to colonization of the embryonic bursa of Fabricius. Proc. Natl. Acad. Sci. USA 87:9416.[Abstract/Free Full Text]
9. Benatar, T., S. Iacampo, L. Tkalec, M. J. H. Ratcliffe. 1991. Expression of immunoglobulin genes in the avian embryo bone marrow revealed by retroviral transformation. Eur. J. Immunol. 21:2529.[Medline]
10. Ratcliffe, M. J. H., O. Lassila, J. R. L. Pink, O. Vainio. 1986. Avian B cell precursors: surface immunoglobulin expression is an early, possibly bursa-independent, event. Eur. J. Immunol. 16:129.[Medline]
11. Houssaint, E., M. Belo, N. M. Le Douarin. 1976. Investigations of cell lineage and tissue interactions in the developing bursa of Fabricius through interspecific chimeras. Dev. Biol. 53:250.[Medline]
12. Houssaint, E., A. Torano, J. Ivanyi. 1983. Ontogenic restriction of the colonization of the bursa of Fabricius. Eur. J. Immunol. 13:590.[Medline]
13. McCormack, W. T., L. W. Tjoelker, C. F. Barth, L. M. Carlson, B. Petryniak, E. H. Humphries, C. B. Thompson. 1989. Selection for B cells with productive IgL gene rearrangements occurs in the bursa of Fabricius during chicken embryonic development. Genes Dev. 3:838.[Abstract/Free Full Text]
14. Reynaud, C. A., V. Anquez, J. C. Weill. 1991. The chicken D locus and its contribution to the immunoglobulin heavy chain repertoire. Eur. J. Immunol. 21:2661.[Medline]
15. Reynaud, C. A., V. Anquez, H. Grimal, J. C. Weill. 1987. A hyperconversion mechanism generates the chicken light chain preimmune repertoire. Cell 48:379.[Medline]
16. Reynaud, C. A., A. Dahan, V. Anquez, J. C. Weill. 1989. Somatic hyperconversion diversifies the single V_H gene of the chicken with a high incidence in the D region. Cell 59:171.[Medline]
17. Sayegh, C. E., S. L. Demaries, S. Iacampo, M. J. H. Ratcliffe. 1999. Development of B cells expressing surface immunoglobulin receptors that lack V(D)J-encoded determinants. Proc. Natl. Acad. Sci. USA 96:10806.[Abstract/Free Full Text]
18. Reynolds, J. D.. 1987. Mitotic rate maturation in the Peyer’s patches of fetal sheep and in the bursa of Fabricius of the chick embryo. Eur. J. Immunol. 17:503.[Medline]
19. Lydyard, P. M., C. E. Grossi, M. D. Cooper. 1976. Ontogeny of B cells in the chicken. I. Sequential development of clonal diversity in the bursa. J. Exp. Med. 144:79.[Abstract/Free Full Text]
20. Pink, J. R. L., O. Vainio, A. M. Rijnbeek. 1985. Clones of B lymphocytes in individual follicles of the bursa of Fabricius. Eur. J. Immunol. 15:83.[Medline]
21. Pink, J. R. L., M. J. H. Ratcliffe, O. Vainio. 1985. Immunoglobulin bearing stem cells for clones of B (bursa derived) lymphocytes. Eur. J. Immunol. 15:617.[Medline]
22. Ratcliffe, M. J. H.. 1989. Generation of immunoglobulin heavy chain diversity subsequent to cell surface immunoglobulin expression in the avian bursa of Fabricius. J. Exp. Med. 170:1165.[Abstract/Free Full Text]
23. Knight, K. L., R. A. Barrington. 1998. Somatic diversification of IgH genes in rabbit. Immunol. Rev. 162:37.[Medline]
24. Parng, C. L., S. Hansal, R. A. Goldsby, B. A. Osborne. 1996. Gene conversion contributes to Ig light chain diversity in cattle. J. Immunol. 157:5478.[Abstract]
25. Sayegh, C. E., G. Drury, M. J. H. Ratcliffe. 1999. Efficient antibody diversification by gene conversion in vivo in the absence of selection for V(D)J-encoded determinants. EMBO J. 18:6319.[Medline]
26. Romanoff, A. L.. 1960. The Avian Embryo: Structural and Functional Development. Macmillan, New York, pp. :497.-508.
27. Ekino, S.. 1993. Role of environmental antigens in B cell proliferation in the bursa of Fabricius at the neonatal stage. Eur. J. Immunol. 23:772.[Medline]
28. Paramithiotis, E., M. J. H. Ratcliffe. 1994. B cell emigration directly from the cortex of lymphoid follicles in the bursa of Fabricius. Eur. J. Immunol. 24:458.[Medline]
29. Lassila, O.. 1989. Emigration of B cells from the chicken bursa of Fabricius. Eur. J. Immunol. 19:955.[Medline]
30. Paramithiotis, E., M. J. H. Ratcliffe. 1993. Bursa-dependent subpopulations of peripheral B lymphocytes in chicken blood. Eur. J. Immunol. 23:96.[Medline]
31. Motyka, B., J. D. Reynolds. 1991. Apoptosis is associated with the extensive B cell death in the sheep ileal Peyer’s patches and the chicken bursa of Fabricius: a possible role in B cell selection. Eur. J. Immunol. 21:1951.[Medline]
32. Paramithiotis, E., K. A. Jacobsen, M. J. H. Ratcliffe. 1995. Loss of surface immunoglobulin expression precedes B cell death by apoptosis in the bursa of Fabricius. J. Exp. Med. 181:105.[Abstract/Free Full Text]
33. Bockman, D. E., M. D. Cooper. 1973. Pinocytosis by epithelium associated with lymphoid follicles in the bursa of Fabricius, appendix, and Peyer’s patches: an electron microscopic study. Am. J. Anat. 136:445.
34. Schnaffner, T., J. Mueller, M. W. Hess, H. Cottier, B. Sordat, C. Ropke. 1974. The bursa of Fabricius: a central organ providing for contact between the lymphoid system and intestinal content. Cell. Immunol. 13:304.[Medline]
35. Sorvari, T., R. Sorvari, P. Ruotsalainen, A. Toivanin, P. Toivanen. 1975. Uptake of environmental antigens by the bursa of Fabricius. Nature 253:217.[Medline]
36. Sorvari, R., T. E. Sorvari. 1977. Bursa of Fabricii as a peripheral lymphoid organ: transport of various materials from the anal lips to the bursal lymphoid follicles with reference to its immunological importance. Immunology 32:499.[Medline]
37. Ekino, S., K. Matsuno, S. Harada, H. Fugii, Y. Nawa, M. Kotani. 1979. Amplification of plaque-forming cells in the spleen after intracloacal antigen stimulation in neonatal chicken. Immunology 37:811.[Medline]
38. Paramithiotis, E., M. J. H. Ratcliffe. 1996. Evidence for phenotypic heterogeneity among B cells emigrating from the bursa of Fabricius: a reflection of functional diversity?. Curr. Top. Microbiol. Immunol. 212:27.
39. Paramithiotis, E., L. Tkalec, M. J. H. Ratcliffe. 1991. High levels of CD45 are coordinately expressed with CD4 and CD8 on avian thymocytes. J. Immunol. 147:3710.[Abstract]
40. Vindelov, L. L.. 1977. Flow microfluorometric analysis of nuclear DNA in cells from solid tumors and cell suspensions: a new method for rapid isolation and staining of nuclei. Virchows Arch. B Cell Pathol. 24:227.
41. Veromaa, T., O. Vainio, E. Eerola, P. Toivanen. 1988. Monoclonal antibodies against chicken Bu-1a and Bu-1b alloantigens. Hybridoma 7:41.[Medline]
42. Hughes, S. H., J. J. Greenhouse, C. J. Petropoulos, P. Sutrave. 1987. Adaptor plasmids simplify the insertion of foreign DNA into helper-independent retroviral vectors. J. Virol. 61:3004.[Abstract/Free Full Text]
43. Petropoulos, C. J., W. Payne, D. W. Salter, S. H. Hughes. 1992. Using avian retroviral vectors for gene transfer. J. Virol. 66:3391.[Abstract/Free Full Text]
44. Savill, J. I., N. Hogg Dransfield, C. Haslett. 1990. Vitronectin receptor-mediated phagocytosis of cells undergoing apoptosis. Nature 343:170.[Medline]
45. Fadok, V. A., D. R. Voelker, P. A. Campbell, J. J. Cohen, D. L. Bratton, P. M. Henson. 1992. Exposure of phosphatidylserine on the surface of apoptotic lymphocytes triggers specific recognition and removal by macrophages. J. Immunol. 148:2207.[Abstract]
46. Gonzalez, M., F. Mackay, J. L. Browning, M. H. Kosco-Vilbois, R. J. Noelle. 1998. The sequential role of lymphotoxin and B cells in the development of splenic follicles. J. Exp. Med. 187:887.
47. Chaplin, D. D., Y. X. Fu. 1998. Cytokine regulation of secondary lymphoid organ development. Curr. Opin. Immunol. 10:289.[Medline]
48. Cyster, J. G., S. B. Hartley, C. C. Goodnow. 1994. Competition for follicular niches excludes self-reactive cells from the recirculating B-cell repertoire. Nature 371:380.
49. Cyster, J. G., C. C. Goodnow. 1995. Antigen-induced exclusion from follicles and anergy are separate and complementary processes that influence peripheral B cell fate. Immunity 3:691.[Medline]
50. Ratcliffe, M. J. H., L. Tkalec. 1990. Cross-linking of the surface immunoglobulin of lymphocytes from the bursa of Fabricius results in second messenger generation. Eur. J. Immunol. 20:1073.[Medline]
51. Sayegh, C. E., S. L. Demaries, K. A. Pike, J. E. Friedmann, and M. J. H. Ratcliffe. 2000. The chicken B-cell receptor complex and its role in avian B-cell development. Immunol. Rev. 175: In press.
52. Lam, K. P., R. Kuhn, K. Rajewsky. 1997. In vivo ablation of surface immunoglobulin on mature B cells by inducible gene targeting results in rapid cell death. Cell 90:1073.[Medline]
53. Ratcliffe, M. J. H., J. Ivanyi. 1981. Allotype suppression in the chicken. IV. Deletion of B cells and lack of suppressor cells during chronic suppression. Eur. J. Immunol. 11:306.[Medline]
54. Scott, T. R., W. A. Johnson, D. G. Satterlee, R. P. Gildersleeve. 1981. Circulating levels of corticosterone in the serum of developing chick embryos and newly hatched chicks. Poult. Sci. 60:1314.[Medline]
55. Compton, M. M., P. S. Gibbs, L. R. Johnson. 1990. Glucocorticoid activation of deoxyribonucleic acid degradation in bursal lymphocytes. Poult. Sci. 69:1292.[Medline]
56. Lassila, O., I. Lefkovits, A. Alanen. 1989. Immunoglobulin diversification in bursal duct-ligated chickens. Eur. J. Immunol. 19:1343.[Medline]
57. Sayegh, C. E., M. A. Rao, M. J. H. Ratcliffe. 1999. Avian B cell development: lessons from transgenic models. Vet. Immunol. Immunopathol. 72:31.[Medline]
58. Ekino, S. B., F. G. Riwar, E. H. Kroese, G. Koch Schwander, P. Nieuwenhuis. 1995. Role of environmental antigen in the development of IgG⁺ cells in the bursa of Fabricius. J. Immunol. 155:4551.[Abstract]
59. Pospisil, R., G. O. Young-Cooper, R. G. Mage. 1995. Preferential expansion and survival of B lymphocytes based on VH framework 1 and framework 3 expression: "positive" selection in appendix of normal and VH-mutant rabbits. Proc. Natl. Acad. Sci. USA 92:6961.[Abstract/Free Full Text]
60. Silverman, G. J.. 1992. Human antibody responses to bacterial antigens: studies of a model conventional antigen and a proposed model B cell superantigen. Int. Rev. Immunol. 9:57.[Medline]
61. Ashwell, J. D., L. B. King, M. S. Vacchio. 1996. Cross-talk between the T cell antigen receptor and the glucocorticoid receptor regulates thymocyte development. Stem Cells 14:490.[Medline]
62. Vacchio, M. S., J. D. Ashwell. 1997. Thymus-derived glucocorticoids regulate antigen-specific positive selection. J. Exp. Med. 185:2033.[Abstract/Free Full Text]

This article has been cited by other articles:

				S. Kothlow, I. Morgenroth, Y. Graef, K. Schneider, I. Riehl, P. Staeheli, P. Schneider, and B. Kaspers Unique and conserved functions of B cell-activating factor of the TNF family (BAFF) in the chicken Int. Immunol., February 1, 2007; 19(2): 203 - 215. [Abstract] [Full Text] [PDF]

				N. Fujiwara, S. Hidano, H. Mamada, K. Ogasawara, D. Kitamura, M. D Cooper, N. Hozumi, C.-l. H Chen, and R. Goitsuka A novel avian homologue of CD72, chB1r, down modulates BCR-mediated activation signals Int. Immunol., May 1, 2006; 18(5): 775 - 783. [Abstract] [Full Text] [PDF]

				K. A. Pike, S. Iacampo, J. E. Friedmann, and M. J. H. Ratcliffe The Cytoplasmic Domain of Ig{alpha} Is Necessary and Sufficient to Support Efficient Early B Cell Development J. Immunol., February 15, 2004; 172(4): 2210 - 2218. [Abstract] [Full Text] [PDF]

				P. J. Jasper, S.-K. Zhai, S. L. Kalis, M. Kingzette, and K. L. Knight B Lymphocyte Development in Rabbit: Progenitor B Cells and Waning of B Lymphopoiesis J. Immunol., December 15, 2003; 171(12): 6372 - 6380. [Abstract] [Full Text] [PDF]

				H. Arakawa, K.-i. Kuma, M. Yasuda, S. Ekino, A. Shimizu, and H. Yamagishi Effect of Environmental Antigens on the Ig Diversification and the Selection of Productive V-J Joints in the Bursa J. Immunol., July 15, 2002; 169(2): 818 - 828. [Abstract] [Full Text] [PDF]

This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Permissions Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Sayegh, C. E. Articles by Ratcliffe, M. J. H. Search for Related Content PubMed PubMed Citation Articles by Sayegh, C. E. Articles by Ratcliffe, M. J. H.