Defect in the generation of light-chain diversity in bursectomized chickens

Clonal anergy of CD117+chB6+ B cell progenitors induced by avian leukosis virus subgroup J is associated with immunological tolerance

BACKGROUND

The pathogenesis of immunological tolerance caused by avian leukosis virus subgroup J (ALV-J), an oncogenic retrovirus, is largely unknown.

RESULTS

In this study, the development, differentiation, and immunological capability of B cells and their progenitors infected with ALV-J were studied both morphologically and functionally by using a model of ALV-J congenital infection. Compared with posthatch infection, congenital infection of ALV-J resulted in severe immunological tolerance, which was identified as the absence of detectable specific antivirus antibodies. In congenitally infected chickens, immune organs, particularly the bursa of Fabricius, were poorly developed. Moreover, IgM-and IgG-positive cells and total immunoglobulin levels were significantly decreased in these chickens. Large numbers of bursa follicles with no differentiation into cortex and medulla indicated that B cell development was arrested at the early stage. Flow cytometry analysis further confirmed that ALV-J blocked the differentiation of CD117+chB6+ B cell progenitors in the bursa of Fabricius. Furthermore, both the humoral immunity and the immunological capability of B cells and their progenitors were significantly suppressed, as assessed by (a) the antibody titres against sheep red blood cells and the Marek's disease virus attenuated serotype 1 vaccine; (b) the proliferative response of B cells against thymus-independent antigen lipopolysaccharide (LPS) in the spleen germinal centres; and (c) the capacities for proliferation, differentiation and immunoglobulin gene class-switch recombination of B cell progenitors in response to LPS and interleukin-4(IL-4) in vitro.

CONCLUSIONS

These findings suggested that the anergy of B cells in congenitally infected chickens is caused by the developmental arrest and dysfunction of B cell progenitors, which is an important factor for the immunological tolerance induced by ALV-J.

The avian B-cell receptor complex: distinct roles of Igalpha and Igbeta in B-cell development

The bursa of Fabricius has evolved in birds as a gut-associated site of B-cell lymphopoiesis that is segregated from the development of other hematopoietic lineages. Despite differences in the developmental progression of chicken as compared to murine B-cell lymphopoiesis, cell-surface immunoglobulin (sIg) expression has been conserved in birds as an essential checkpoint in B-cell development. B-cell precursors that express an sIg complex that includes the evolutionarily conserved Igalpha/beta heterodimer colonize lymphoid follicles in the bursa, whereas B-cell precursors that fail to express sIg due to non-productive V(D)J recombination are eliminated. Productive retroviral gene transfer has allowed us to introduce chimeric receptor constructs into developing B-cell precursors in vivo. Chimeric proteins comprising the extracellular and transmembrane regions of murine CD8alpha fused to the cytoplasmic domain of chicken Igalpha efficiently supported B-cell development in precursors that lacked endogenous sIg expression. By contrast, expression of an equivalent chimeric receptor containing the cytoplasmic domain of Igbeta actively inhibited B-cell development. Consequently, the cytoplasmic domains of Igalpha and Igbeta play functionally distinct roles in chicken B-cell development.

Antigen-Induced Somatic Diversification of Rabbit IgH Genes: Gene Conversion and Point Mutation

During T cell-dependent immune responses in mouse and human, Ig genes diversify by somatic hypermutation within germinal centers. Rabbits, in addition to using somatic hypermutation to diversify their IgH genes, use a somatic gene conversion-like mechanism, which involves homologous recombination between upstream VH gene segments and the rearranged VDJ genes. Somatic gene conversion and somatic hypermutation occur in young rabbit gut-associated lymphoid tissue and are thought to diversify a primary Ab repertoire that is otherwise limited by preferential VH gene segment utilization. Because somatic gene conversion is rarely found within Ig genes during immune responses in mouse and human, we investigated whether gene conversion in rabbit also occurs during specific immune responses, in a location other than gut-associated lymphoid tissue. We analyzed clonally related VDJ genes from popliteal lymph node B cells responding to primary, secondary, and tertiary immunization with the hapten FITC coupled to a protein carrier. Clonally related VDJ gene sequences were derived from FITC-specific hybridomas, as well as from Ag-induced germinal centers of the popliteal lymph node. By analyzing the nature of mutations within these clonally related VDJ gene sequences, we found evidence not only of ongoing somatic hypermutation, but also of ongoing somatic gene conversion. Thus in rabbit, both somatic gene conversion and somatic hypermutation occur during the course of an immune response.

Antigenic phenotype of early intra-embryonic lymphoid progenitors in the chicken

The stem cells for the definitive haematopoiesis are derived from intra-embryonic sources originally described in an avian model and later also in mammals. However, the molecular make-up of the early embryonic haematopoietic progenitors is not yet clearly defined. We have recently characterized the phenotype of prethymic intra-embryonic progenitors capable of thymic colonization. Here we studied the ontogeny of cell-surface antigens HEMCAM, alpha2beta1 integrin, thrombomucin, chL12 and c-kit and their co-expression on prethymic T-cell progenitors. The early intra-embryonic expression of avian B-cell antigen chB6 was also demonstrated on cells derived from the intra-embryonic areas. We suggest that in the chicken, embryonic B-cell progenitors segregate earlier than T-cell progenitors in the differentiation of multipotent haematopoietic stem cells to committed progenitors.

Avian B cell development

Development of B cells in chickens proceeds via a series of discrete developmental stages that includes the maturation of committed B cell progenitors in the specialized microenvironment of the bursa of Fabricius. The bursa has been shown to be required for the amplification of the B cell pool and selects for cells with productive immunoglobulin rearrangement events. Other events regulating chicken B cell development such as lymphocyte trafficking and apoptosis are just beginning to be elucidated. Within the bursa, the variable regions of immunoglobulin genes of B cell progenitors are diversified by a process of intrachromosomal gene conversion, where blocks of sequence information are transferred from pseudo-V regions to the recombined variable regions of the immunoglobulin genes. Recently gene conversion has been determined to play a role in the diversification of the immune repertoire in other species. In this review we focus on the current understanding and recent advances of B cell development in the chicken.

Distribution of bursal secretory dendritic cells in the chicken

BACKGROUND

The bursa of Fabricius provided the microenvironment for B-cell differentiation. Continuous contact between lymphoid cells and antigen in the bursa further suggested that antigenic material has an important influence on the maintenance and development of B cells in the bursa. In addition, a dendritic cell, the bursal secretory dendritic cell (BSDC), has been identified in the medulla. The hypothesis that, in the bursal follicles, the contact between the lymphoid cells and the antigen may be mediated by dendritic cells prompted us to identify a bursal dendritic cell that becomes activated after contact with the antigen.

METHODS

A polyclonal antiserum to S-100 protein was used to identify bursal dendritic cells because S-100 protein, a calcium-binding protein, has been shown to be a marker for the identification of chicken dendritic cells following recent contact with antigen.

RESULTS

At every age investigated, S-100-positive cells showed a location and shape identical to those described for BSDCs. Positive cells were found within and under the follicle-associated epithelial cells (FAE), indicating that these cells were strategically placed where they would encounter the antigen. In addition, positive cells were found arranged along the corticomedullary junction, which is a regenerative zone for the BSDC. After 10 weeks of age, the number of positive cells dramatically decreased, suggesting that the endocytic activity of the FAE may become impaired as the bursa regresses.

CONCLUSIONS

The polyclonal antiserum to S-100 protein identified the BSDCs in the bursal follicles. Positive cells may be BSDCs that have undergone a functional activation after contact with the antigen. These cells may have a role as antigen-presenting cells in the bursal follicles. Hence, these cells may be involved in the events that lead to B-cell differentiation.

Retrovirus-induced B cell neoplasia in the bursa of Fabricius

The chicken bursa provides a revealing experimental model system which has helped unravel some of the mysteries surrounding induction of neoplasia by retroviruses lacking dominant viral oncogenes. Analysis of this system continues to provide opportunities for further insight into mechanisms underlying some of the essential characteristics of neoplastic change including maturation arrest, prolonged cell survival, and genetic instability. The deregulation of c-myc expression induced by nearby proviral integration appears to initiate preneoplastic change in a specific window of development, i.e., the bursal stem cell. The generation of large numbers of these preneoplastic stem cells, and the ability for further amplification by transplantation technology, may provide an opportunity to address questions such as how and why myc oncogenes produce preneoplastic maturation arrest or why stem cells are selective targets for these effects. Among the unexplained consequences of this preneoplastic state appears to be genetic instability which leads, inevitably, to formation of invasive bursal neoplasms. It is at least conceivable that the observed myc-induced enhancement of the remarkable capacity for apoptotic cell death present in bursal cells plays a role in this instability. DNA strand breakage is a very early feature of bursal cell apoptosis. If such breakage could occur in sublethal form it might provide a mechanism for increased frequency of genetic change (deletions, rearrangement, and recombination). Among the changes that seem required for successful tumor cell growth outside of follicles is the suppression of cell death induced by loss of cell-cell contact which is characteristic of normal and preneoplastic bursal cells. Several genes in the bcl-2 family are potentially important in the modulation of cell death events central to the evolution of these neoplasms. Their role, if any, remains to be established.

Isolation and characterization of the chicken bcl-2 gene: expression in a variety of tissues including lymphoid and neuronal organs in adult and embryo

The expression of human bcl-2 gene is de-regulated by t(14;18) translocation in most of follicular lymphoma. Recent studies indicated that the bcl-2 gene product has an ability to block apoptosis of hematopoietic cells. To facilitate the analysis of the role of this gene in normal development using an animal model, we have isolated and partially characterized the chicken homologue of human bcl-2 gene. The analysis of nucleotide sequence showed that the organization of the chicken bcl-2 gene is very similar to that of human bcl-2 gene. The primary transcript is spliced to encode a 25,687 dalton (233 a.a.) protein. The chicken Bcl-2 protein has two regions highly homologous to human Bcl-2 protein surrounding a totally non-homologous region. The expression of the chicken bcl-2 gene was analyzed in various chicken tissues. In the adult chicken, bcl-2 transcripts were detected in thymus, spleen, kidney, heart, ovary and brain, with the highest levels being detected in the thymus. However, the bursa of Fabricius, which is the site of early B cell development, expressed much less amounts of bcl-2 RNA. On the other hand, in embryo, the gene is extensively expressed in the bursa, as well as in muscle and the above tissues. Our findings indicate that a homologue of the human bcl-2 gene does exist in the chicken and that its expression is developmentally regulated in some tissues.

Involvement of the avian mu heavy chain in recolonization of the bursa of Fabricius

In the chicken, the B cells develop in a specialized organ, the bursa of Fabricius. Earlier it was shown that neonatal bursal cells treated with polyclonal anti-chicken immunoglobulin antibodies are not able to recolonize the bursa when transferred into cyclophosphamide-treated chicks. In this study, 4-day-old bursal cells were treated with different polyclonal and monoclonal anti-immunoglobulin antibodies and transferred into 4-day-old cyclophosphamide-treated chickens. Two monoclonal anti-chicken IgM antibodies, CVI-59.7 and 21-2B2, recognizing distinct epitopes of the mu heavy chain, were inhibitory. Incubation of cells with 21-2B2 antibody caused about 90% inhibition of bursal recolonization. After incubation with CVI-59.7 antibody the inhibition was 50%. The high inhibition by 21-2B2 antibody was also seen when F(ab')2 fragments of the antibody were used. These results suggest that the entry of the cells needed for bursal recolonization is inhibited almost totally by 21-2B2 antibody, or that this antibody blocks further proliferation of the cells in bursal follicles. In conclusion, we have shown that a mu heavy chain epitope is intimately involved in the recolonization of bursal follicles, and distinct epitopes of the mu heavy chain are not equally important in this process.

Induction of apoptosis during normal and neoplastic B-cell development in the bursa of Fabricius

The lymphoid cells of embryonic bursal follicles are engaged in rapid growth and preimmune diversification of immunoglobulin genes. Disruption of follicular architecture by mechanical dispersion of these cells in short-term tissue culture was accompanied by continued cell division and extensive cell death by apoptosis. Apoptosis was suppressed in parallel cultures of intact follicles. gamma Radiation also triggered extensive apoptosis in embryonic bursal follicles within a few hours. Preneoplastic bursal stem cell populations induced by a v-myc oncogene were hypersensitive to induction of apoptosis by follicular dispersion and radiation. In contrast, tumor progression in v-myc- and v-rel-initiated bursal neoplasms was accompanied by development of resistance to induction of apoptosis. A programmed cell death pathway can be activated during normal B-cell development in the bursa, and alterations in the expression of this pathway accompany neoplastic change in this system.

Chicken IgL variable region gene conversions display pseudogene donor preference and 5' to 3' polarity

Chicken immunoglobulin variable region diversity is generated during B-cell development in the bursa of Fabricius by intrachromosomal gene conversion, resulting in the replacement of sequence blocks within the unique rearranged VL1 and VH1 genes with homologous sequences derived from V region pseudogene segments (psi V). In this report, the nucleotide sequences of 217 gene conversion events in 52 random IgL clones were analyzed to characterize the molecular mechanism of gene conversion. The frequency of psi VL usage as gene conversion donors is shown to depend on the proximity of the psi VL segment to VL1, extent of homology with VL1, and relative orientation of the psi VL segments. Gene conversion events are not observed in the 5' region of homology between psi VL segments and VL1, but are distributed throughout the remainder of the VL1 exon. The 5' ends of individual gene conversion events always begin in regions of homology between the donor psi VL and recipient VL1 gene, whereas the 3' ends can occur in regions of nonhomology and often have nucleotide insertions or deletions. These results suggest a 5' to 3' polarity in the gene conversion mechanism. The implications of our data are discussed in relation to current molecular models of gene conversion.

Somatic diversification of the chicken immunoglobulin light-chain gene

The bursa of Fabricius provides a unique organ for the study of lineage-specific development in a multicellular organism. Unlike mammalian B cells, B cells in the chicken develop in a single wave of differentiation, beginning with the commitment of progenitor cells to the B cell lineage between days 10 and 15 of embryogenesis. By day 18 of embryogenesis, all lymphoid progenitor cells capable of differentiation along the B cell lineage have migrated to the bursa of Fabricius. Following migration to the bursa, these lymphoid progenitors enter exponential growth and begin to populate each of the 10(4) bursal follicles. Between day 18 of embryogenesis and 2-4 weeks of age, B cells undergo a stage of bursal-dependent differentiation. By the end of this period, chickens are able to mount primary immune responses against virtually all antigens. In addition, by this time sufficient numbers of B cells have migrated from the bursa to peripheral lymphoid organs so that the B cell immune system can be maintained even if the bird is bursectomized. Bursectomy of chicks after 4 weeks of age has no long-term effects on the development and maintenance of the B cell immune system in adult birds. Because of the central nature of the surface Ig molecule to B cell development in mammals, the chicken IgL gene locus has been intensively studied during avian B cell development. The chicken IgL locus is a particular interest because it has only one V region capable of rearrangement. Rearrangement of the IgL gene is not dependent on the bursal environment. B cell progenitors rearrange their IgL gene between days 10-15 of embryogenesis, prior to migration to the bursa. IgL gene rearrangement occurs by a deletional mechanism in which a precise joining of the IgL recombination signal sequences leads to a circular episomal element. During this deletion it appears that single nonrandom bases are added to both the V and J coding segments. Subsequent V-J joining occurs at random. Most progenitor B cells appear to rearrange only a single IgL allele. The high frequency of in-frame alleles observed in avian B cell lines appears to result from the selective amplification of cells with productive IgL rearrangements during bursal development between days 12 and 18 of embryogenesis. To create an immunological repertoire, chickens must diversify the coding sequence of this single functional V gene segment during development.(ABSTRACT TRUNCATED AT 400 WORDS)

A model of bursal colonization

In the chicken, and perhaps in all birds, the development of the cells which form antibodies, the B-cells, differs substantially from that in mammals. In birds, committed B-cells colonize a specialized organ, the bursa of Fabricius, which consists of some 10(4) follicles. Diversification, i.e., the development of the antibody repertoire, takes place in bursal follicles by a process termed "gene conversion." The avian bursa is easily accessible experimentally, and in the chicken, it has been the subject of extensive research. As an aid to experimentation in this field, we present here a formal mathematical model of bursal development. Formulae are derived which allow one to estimate the number and sizes of B-cell clones in bursal follicles, and hence the size of the overall antibody repertoire. Particular attention is paid to the problem of estimating experimental errors.

Selection for B cells with productive IgL gene rearrangements occurs in the bursa of Fabricius during chicken embryonic development

The vast majority of immunoglobulin-expressing mature chicken B lymphocytes contain one functionally rearranged and one unrearranged allele of the immunoglobulin light chain (IgL) gene. Therefore, nearly all IgL V-J rearrangements present in mature chickens are in-frame. In contrast, the Ig genes of mature mammalian B cells contain a high proportion of out-of-frame V-J joints. To investigate the basis for this difference, gene rearrangement at the chicken IgL locus was characterized during embryonic development and in mature B-cell lines. Joining of the single functional variable (VL) segment with the single joining (JL) segment occurs in cells in multiple tissues during a transient period of chicken embryogenesis. Only one-third of the V-J joints cloned from days 10-12 of development are in-frame. An increasing proportion of in-frame V-J joints is observed within the bursa of Fabricius at successively later stages of development. Our data suggest that the bursa of Fabricius serves during embryonic development as a site of selective amplification of cells that have undergone productive V-J joining, such that nearly all V-J joints present in postembryonic B cells are in-frame. The high frequency of rearranged alleles joined in-frame that is found in posthatching bursal cells and mature B-cell lines appears to result from a low frequency with which cells undergo IgL rearrangement at both alleles, rather than from an increase in the precision of V-J joining in avian species.

B cell precursors in chick embryos surgically bursectomized at 72 h of incubation

To determine the presence of precursor B cells in chick embryos surgically bursectomized at 72 h of incubation (E-Bx) we studied chick chimeras that were produced by establishing parabiotic connections between blood vessels of chorioallantoic membranes of normal and surgically bursectomized chick embryos. Using sex chromosomes and a B cell alloantigen (Bu-1a) as markers we showed that chick embryos bursectomized at 72 h of incubation contain B cell precursors capable of colonizing the bursa of Fabricius and developing into B lymphocytes. The repopulation capacity of 14-day-old embryonic spleen cells from E-Bx recipients was tested by transferring them into age-matched X-irradiated Bu-1-disparate embryos. The results show that B cell precursors are present in 14-day spleen of chick embryos bursectomized at 72 h of incubation. These precursors carry the Bu-1 B cell alloantigen, suggesting that commitment to the B cell lineage can take place in the absence of bursa.

Long terminal repeat (LTR) sequences, env, and a region near the 5' LTR influence the pathogenic potential of recombinants between Rous-associated virus types 0 and 1

A series of recombinants between Rous-associated virus type 0 (RAV-0), RAV-1, and a replication-competent avian leukosis virus vector (RCAN) have been tested for disease potential in day-old inoculated K28 chicks. RAV-0 is a benign virus, whereas RAV-1 and RCAN induce lymphoma and a low incidence of a variety of other neoplasms. The results of the oncogenicity tests indicate that (i) the long terminal repeat regions of RAV-1 and RCAN play a major role in disease potential, (ii) subgroup A envelope glycoproteins are associated with a two- to fourfold higher incidence of lymphoma than subgroup E glycoproteins, and (iii) certain combinations of 5' viral and env sequences cause osteopetrosis in a highly context-dependent manner. Long terminal repeat and env sequences appeared to influence lymphomogenic potential by determining the extent of bursal infection within the first 2 to 3 weeks of life. This would suggest that bursal but not postbursal stem cells are targets for avian leukosis virus-induced lymphomogenesis. The induction of neutralizing antibody had no obvious influence on the incidence of lymphoma.

Immunoglobulin diversification in embryonic chicken bursae and in individual bursal follicles

Previous studies have shown that the same immunoglobulin (Ig) V lambda gene (V lambda 1) is rearranged in all chicken B cells, and that extensive sequence diversification of this gene occurs during B cell development in the bursa of Fabricius. We used two-dimensional gel electrophoresis to compare the heterogeneity of Ig lambda light chains produced by B cells at different stages of bursal development. Somatically diversified light chains were observed in Ig molecules produced by bursal cells as early as 15 days of embryonic incubation. The two principal species of light chain observed probably represent glycosylated and nonglycosylated forms of lambda chain encoded by alleles of a single lambda gene. Extensive diversification was observed during late embryogenesis. We also studied lambda light chain diversity in cyclophosphamide-treated birds repopulated with normal bursal cells. In these birds, individual bursal follicles are repopulated by single B cell precursors. Follicular cells derived from single B cell precursors were able to produce a spectrum of light chains almost as diverse as that of the total bursal cell population. We used two monoclonal anti-idiotype antibodies to study idiotype expression in individual normal or reconstituted follicles. About 30% of follicles contained 0.1% to 5% of lymphocytes which reacted with one or both of the antibodies. The results indicate that within individual bursal follicles bursa stem cells undergo Ig hyperdiversification.

Review of studies on the immunological capacity in the bursectomized chick

This paper summarizes data on the immunological capacity in the bursectomized chick. A series of experiments described by Glick and Sadler represented the functional importance of the bursa of Fabricius for the humoral immunity in chicken. Later studies of immune responses in bursaless chickens reported by Lerner et al. contributed to our knowledge of bursa-independent humoral immunity and demonstrated an extra-bursal site for B-cell differentiation. Bursectomy at an early stage of chicken development changes the immune responses after hatching. Here I present my current understanding of embryonic B-cell populations (bursa-dependent and independent) following in ovo bursectomy which may influence B-cell differentiation with reference to our experiments on J chain production.

Somatic diversification of the chicken immunoglobulin light chain gene is limited to the rearranged variable gene segment

Previous studies have shown that the chicken lambda immunoglobulin light chain gene undergoes a single rearrangement that results in functional VJ joining of the unique variable (V lambda 1) and joining (J lambda) coding regions. The immunologic repertoire of lambda genes is created through extensive sequence diversification within the rearranged locus during B cell development in the bursa of Fabricius. This sequence diversification was detected only at the rearranged V lambda 1 segment and not within the 5' leader sequence, the J lambda segment, or the unrearranged V lambda 1 segment. The selective diversification of the rearranged V lambda 1 segment was associated with unique DNAase I-hypersensitive sites on the rearranged allele. While probes for V lambda 1 sequences detect multiple homologous V lambda segments, probes for both the 5' leader and J lambda segments fail to detect homologous sequences. Taken together, these results suggest that a highly selective process, possibly gene conversion, operates during B cell ontogeny to generate diversity within the lambda gene.

A hyperconversion mechanism generates the chicken light chain preimmune repertoire

The chicken immunoglobulin light chain repertoire has been shown to be entirely derived from a single V lambda 1-J rearranged combination. The complete coding information of the lambda locus was determined: it comprises 25 V-hybridizing elements, all of which are pseudogenes, clustered in both orientations within 19 kb of DNA, starting 2.4 kb upstream of the V lambda 1 gene. Sequences of somatically rearranged V lambda 1 genes from embryonic and posthatching bursal cells show that diversification of light chain sequences occurs during ontogeny by a segmental gene conversion mechanism which takes place at a frequency of 0.05-0.1 per cell generation between the pseudogene pool and the unique rearranged functional V gene.

Selective integration of avian leukosis virus in different hematopoietic tissues

Hematopoietic tissues obtained from avian leukosis virus (ALV)-infected Hyline SC chickens were analyzed for the presence of integrated viral DNA sequences. Cells were prepared from bone marrow, bursa, spleen, thymus, and peripheral blood. Following the removal of erythrocytes, cellular DNAs from each of these tissues were examined by Southern analysis. During the first few weeks of infection, DNA from the bone marrow contained as many as 0.5 copies of viral DNA per haploid genome. Cells from the bursa and peripheral blood contained between 0.05 and 0.15 copies per haploid genome. In contrast, neither splenic nor thymic DNA contained significant levels of viral DNA sequences even though infected birds developed titers of circulating virus between 10(5) and 10(6) IU/ml of plasma. DNA prepared from erythrocytes isolated from the peripheral blood of these birds contained approximately 0.4 copies of integrated viral sequences per haploid genome at 2 weeks after infection. Despite greater levels of integrated sequences in other tissues, by 9 weeks after infection viral sequences were detected only in DNA from bursal lymphocytes. Cells prepared from the spleen and thymus of infected birds were also examined for their size distribution, their internal complexity and their surface expression of immunoglobulin. None of the populations examined differed from normal, uninfected control preparations. These results suggest that ALV infection occurs primarily in the bone marrow and that the different tissues of the hematopoietic system are selectively infected. Further, these results indicate that ALV infection persists longer in bursal lymphocytes than in other hematopoietic tissues. Previous studies have demonstrated that the lymphoid tumors that develop in white leghorn chickens following ALV infection are bursal-dependent B-cell lymphomas that express immunoglobulin M. The observations presented in this communication offer, in part, an explanation for the restricted phenotype of the lymphoid tumor that develops in the SC chicken. Further, the data suggest an explanation for the bursal-dependent nature of the ALV-induced lymphoma.

Counting components of the chicken's B cell system

At the risk of representing a chicken as a hybrid between a hummingbird and an ostrich, we can summarize the preceding sections and order-of-magnitude estimates as follows. Chicken B lymphocytes are derived from less than 10(5) lymphoid precursor cells, which either have already rearranged their Ig genes before they colonize the embryonic bursa, or (more probably) rapidly give rise to cells with rearranged genes within the bursa's 10(4) follicles. Since the bird's functional germline Ig V genes are few in number (less than or equal to 10?), most rearrangements have similar outcomes. The B cells proliferate rapidly in the bursa, in an antigen-independent manner, undergoing somatic modifications of their Ig V genes at a high rate (probably at least once in every 10(3) cell divisions). In the young chick, B cells are produced in the bursa at a rate of 10(7) to 10(8) per d; many of these die but the rest contribute to formation of the adult bird's B cell pool of about 10(10) lymphocytes, with a repertoire of at least 10(6) different antibody specificities. the bird's B cells are entirely self-renewing, in the sense that none are derived from Ig-negative precursors at any time after hatching.