Jana Sinkorova

Antibody Repertoire Development in Fetal and Neonatal Piglets. VI. B Cell Lymphogenesis Occurs at Multiple Sites with Differences in the Frequency of In-frame Rearrangements

B cell lymphogenesis in mammals occurs in various tissues during development but it is generally accepted that it operates by the same mechanism in all tissues. We show that in swine, the frequency of in-frame (IF) VDJ rearrangements differs among yolk sac, fetal liver, spleen, early thymus, bone marrow, and late thymus. All VDJ rearrangements recovered and analyzed on the 20th day of gestation (DG20) from the yolk sac were 100% IF. Those recovered at DG30 in the fetal liver were >90% IF, and this predominance of cells with apparently a single IF rearrangement continued in all organs until approximately DG45, which corresponds to the time when lymphopoiesis begins in the bone marrow. Thereafter, the proportion of IF rearrangements drops to ∼71%, i.e., the value predicted whether VDJ rearrangement is random and both chromosomes were involved. Unlike other tissues, VDJs recovered from thymus after DG50 display a pattern suggesting no selection for IF rearrangements. Regardless of differences in the proportion of IF rearrangements, we observed no significant age- or tissue-dependent changes in CDR3 diversity, N region additions, or other characteristics of fetal VDJs during ontogeny. These findings indicate there are multiple sites of B cell lymphogenesis in fetal piglets and differences in the frequency of productive VDJ rearrangements at various sites. We propose the latter to result from differential selection or a developmentally dependent change in the intrinsic mechanism of VDJ rearrangement.

Development of γδ thymocyte subsets during prenatal and postnatal ontogeny

In this report, we describe 12 subpopulations of porcine γδ thymocytes based on their expression of CD1, CD2, CD4, CD8‐isoforms and CD45RC. Our data suggest that γδ thymocytes can be divided into two major families: (a) one large family of CD4–γδ thymocytes that could be further subdivided according to the CD2/CD8αα phenotype and (b) a small family of CD4+γδ thymocytes bearing CD8αβ and possessing certain unusual features in comparison with other γδ thymocytes. Maturation of γδ thymocytes within the CD4– family begins with proliferation of the CD2+ CD8– CD1+ CD45RC–γδ common precursor. This developmental stage is followed by diversification into the CD2+ CD8αα+, CD2+ CD8– and CD2– CD8– subsets. Their further maturation is accompanied by a loss of expression of CD1 and by increased expression of CD45RC. Therefore, individual subsets develop from CD1+ CD45RC– through CD1– CD45RC– into CD1– CD45RC+ cells. On the other hand, γδ thymocytes within the CD4+ family bear exclusively CD8αβ, always express CD1, but may coexpress CD45RC. These cells have no counterpart in the periphery. Our observations suggest that all peripheral CD8+γδ T cells express CD8αα and that two subsets of these cells differing in major histocompatibility complex II expression, occur. We propose that one subset acquires CD8αα in the thymus while the second acquires CD8αα as a result of stimulation in the periphery.

Ileal Peyer’s Patches Are Not Necessary for Systemic B Cell Development and Maintenance and Do Not Contribute Significantly to the Overall B Cell Pool in Swine

Based on studies of sheep, ileal Peyer’s patches (IPP) have been regarded as a type of primary lymphoid tissue similar to the bursa of Fabricius in chicken. Because bursectomy results in B cell deficiency, we wondered whether resection of the IPP of piglets would have a similar effect. Comparison of IPP-resected, surgical shams and untreated germ-free piglets, all of which were later colonized with a defined commensal flora, demonstrated that resection of the IPP did not alter the level and phenotype of B and T cells in lymphoid tissues and the blood 10 wk after surgery. Additionally, colonization of IPP caused a shift from the fetal type of lymphocyte distribution to the adult type that is characterized by prevalence of B cells, with many of them representing IgA+ switched B cells or displaying a more mature CD2−CD21+ and CD2−CD21− phenotype. Moreover, colonization leads to appearance of effector CD4+CD8+ αβ T helper and CD2+CD8− γδ T cells. Comparison of germ-free with colonized pigs and experiments utilizing surgical transposition of jejunal Peyer’s patch into terminal ileum or construction of isolated ileal loops indicated that lymphocyte development in IPP is dependent on colonization. Although our studies confirmed higher mitotic and apoptotic rates in IPP, they failed to identify any cell populations that resemble developing B lineage cells in the bone marrow. These results indicate that porcine IPP are not required for systemic B cell generation or maintenance, but they are secondary lymphoid tissue that appears important in immune responses to colonizing bacteria.

B cell development and VDJ rearrangement in the fetal pig

Hematopoietic activity of the swine has been documented in three phases during fetal ontogeny. The hematopoietic system develops first in the yolk sac, then in fetal liver and finally in the bone marrow. Using flow cytometry (FCM) and molecular biological techniques we show that B-cell lymphogenesis and the appearance of B cells follows a pattern. First, VDJ rearrangement occurs at the 20th day of gestation (DG20) in the yolk sac at a time when light chain transcription is absent. Next, B-cell lymphogenesis is detected at DG30 in the fetal liver. Thereafter, bone marrow becomes the major B lymphopoietic organ (DG45). In yolk sac and fetal liver, more than 90% of the VDJ rearrangements were in-frame but expression of micro heavy chain could not be clearly detected by FCM. However, cells with a putative phenotype of B-cell precursors are present. These cells express high levels of MHC class II (SLA-DR) and low levels of CD2 and CD25. CDR3 length analysis (spectratyping) indicates that the heavy chain repertoire is oligoclonal at this time with large inter-animal variations. Consistent with our earlier reports, fetal VDJ rearrangements are not mutated and there is no evidence for an age-dependent increase in TdT activity or a change in V(H) and D(H) usage from those used by B-cells formed in the yolk sac or fetal liver. However, our findings indicate major differences in the regulatory environment and/or selective pressures in yolk sac and fetal liver versus bone marrow. In contrast with the yolk sac and fetal liver, the proportion of in-frame VDJ rearrangements in the bone marrow correspond to a value indicative of random recombination.

Two Groups of Porcine TCRγδ+ Thymocytes Behave and Diverge Differently

Developmental pathways of γδ T cells are still unknown, largely because of the absence of recognized lineage-specific surface markers other than the TCR. We have shown that porcine γδ thymocytes can be divided into 12 subsets of the following two major groups: 1) CD4− γδ thymocytes that can be further subdivided according to their CD2/CD8αα phenotype, and 2) CD4+ γδ thymocytes that are always CD1+CD2+CD8αβ+ and have no counterpart in the periphery. In this study, we have analyzed γδ thymocyte subsets with respect to behavior during cultivation, cell cycle status, and lymphocyte-specific transcripts. The group of CD4− γδ thymocytes gives rise to all γδ T cells found in the periphery. Proliferating CD2+CD8−CD1+CD45RC− γδ thymocytes are a common precursor of this group. These precursors differentiate into CD2+CD8αα+, CD2+CD8−, and CD2−CD8− γδ T cell subsets, which subsequently mature by loss of CD1 and by eventual gain of CD45RC expression. In contrast, the group of CD4+ γδ thymocytes represents transient and independent subsets that are never exported from thymus as TCRγδ+ T cells. In accordance with the following findings, we propose that CD4+CD8αβ+ γδ thymocytes extinguish their TCRγδ expression and differentiate along the αβ T cell lineage program: 1) CD4+ γδ thymocytes are actively dividing; 2) CD4+ γδ thymocytes do not die, although their numbers decreased with prolonged cultivation; 3) CD4+ γδ thymocytes express transcripts for RAG-1, TdT, and TCRβ; and 4) CD4+ γδ thymocytes are able to alter their phenotype to TCRαβ+ thymocytes under appropriate culture conditions.

Different anti-CD21 antibodies can be used to discriminate developmentally and functionally different subsets of B lymphocytes in circulation of pigs

Monoclonal antibodies IAH-CC51, BB6-11C9.6 and B-Ly4 are routinely used to detect CD21 orthologue on the surface of porcine B lymphocytes. Cross-reactive studies show that IAH-CC51 and B-Ly4 recognize only a portion of B cells that are positive for pan-specific BB6-11C9.6. This indicates that CD21 is always present on all mature B cells but can be expressed in at least two differential forms, and these were assigned as CD21(a) and CD21(b). We used IAH-CC51 together with anti-CD2 to define four subpopulations of B cells. Ontogenetic and in vitro culture studies, analysis of cell size, expression of CD11b and class-switched phenotype together with measurement of proliferation and cell death, revealed that these subsets represent distinct populations. Phenotypic and functional features collectively suggest that CD21(b+) B cells are less mature than CD21(b-). The present work is the first to show that distinct subsets of mature B cells can express differential forms of CD21.

The comparative profile of lymphoid cells and the T and B cell spectratype of germ-free piglets infected with viruses SIV, PRRSV or PCV2

Lymphocyte subsets isolated from germ-free piglets experimentally infected with swine influenza virus (SIV), porcine reproductive and respiratory syndrome virus (PRRSV) or porcine circovirus type 2 (PCV2) were studied and the profile of these subsets among these three infections was monitored. Germ-free piglets were used since their response could be directly correlated to the viral infection. Because SIV infections are resolved even by colostrum-deprived neonates whereas PRRSV and PCV2 infections are not, SIV was used as a benchmark for an effectively resolved viral infection. PRRSV caused a large increase in the proportion of lymphocytes at the site of infection and rapid differentiation of B cells leading to a high level of Ig-producing cells but a severe reduction in CD2—CD21+ primed B cells. Unlike SIV and PCV2, PRRSV also caused an increase in terminally differentiated subset of CD2+CD8α+ γδ cells and polyclonal expansion of major Vβ families suggesting that non-specific helper T cells drive swift B cell activation. Distinct from infections with SIV and PRRSV, PCV2 infection led to the: (a) prevalence of MHC-II+ T cytotoxic cells, (b) restriction of the T helper compartment in the respiratory tract, (c) generation of a high proportion of FoxP3+ T cells in the blood and (d) selective expansion of IgA and IgE suggesting this virus elicits a mucosal immune response. Our findings suggest that PRRSV and PCV2 may negatively modulate the host immune system by different mechanisms which may explain their persistence.

B Cell Lymphogenesis in Swine Is Located in the Bone Marrow

A course and a site of B cell development in swine are not firmly known. In this study, we show that B cell lymphogenesis is located in the bone marrow (BM). According to expression of MHC class II (MHC-II), CD2, CD21, CD25, CD45RC, CD172a, swine workshop cluster (identification number) (SWC) 7, and μHC, porcine BM cells were resolved into seven subsets representing sequential stages of development. Profile of rearrangement-specific products and transcripts from sorted BM cells confirmed the proposed developmental pathway. The same developmental pathway was further proven by analysis of selection for productive rearrangements in Ig H chains and also by cultivation studies. Cultivation also showed that earliest precursors with incomplete DJ rearrangements can still revert their B cell differentiation and develop along myeloid lineage, whereas this is impossible for later developmental stages. Proliferation and the apoptotic potential of individual developmental stages as well as critical checkpoints were also identified. Colocalization experiments showed early colocalization of MHC-II/CD2/CD172a is replaced by colocalization of MHC-II/CD2/CD21/SWC7/IgM in immature cells, whereas CD25 and CD45RC did not colocalize with any other studied molecules. In this study, we also finally prove that the BM in pigs is fully functional in adult animals and that B lymphogenesis occurs there throughout life. To our knowledge, this is the first study showing a course and a direct site of B cell lymphogenesis in swine.

The distribution of lymphoid cells in the small intestine of germ-free and conventional piglets.

Porcine ileum is populated with a high proportion of B cells but previous studies have shown that they are not developed there. While B cells prevail in the ileum even in germ-free animals, microbial colonization is a major factor that causes even a greater prevalence of B cells in the ileum and further differential representation of lymphoid cells throughout small intestine. Analysis of lymphoid subpopulations showed that the effector cells appear only after colonization. These include class-switched IgM(+)IgA(+) B cells, primed CD2(-)CD21(+) B cells, antibody-producing/memory CD2(+)CD21(-) B cells, and effector/memory CD4(+)CD8(+) αβ Th cells. While colonization resulted in a uniform distribution of effector cells throughout the gut, it caused a decrease in the frequency of cytotoxic αβ and CD2(+)CD8(+) γδ T cells. These results suggest that the ileum is a site where naive B cells expand presumably to increase antibody repertoire but the entire small intestine is immunofunctionally comparable.

Ig Light Chain Precedes Heavy Chain Gene Rearrangement during Development of B Cells in Swine

The current mammalian paradigm states that 1) rearrangements in the IgH locus precede those in IgL loci, 2) IgLλ genes rearrange only when IgLκ genes are consumed, and 3) the surrogate L chain is necessary for selection of productive IgH gene rearrangements. We show in swine that IgL rearrangements precede IgH gene rearrangements, resulting in the expression of naked IgL on a surface of precursor B cells. Findings also suggest that there is no dependency on the surrogate L chain, and thus the authentic IgL proteins may be used for selection of the IgH repertoire. Although rearrangement starts with IgLκ genes, it is rapidly replaced by IgLλ rearrangement. Fast replacement is characterized by occurrence of IgLλloIgLκlo dual-expressing precursors in which IgLκ expression is a remnant of a previous translation. Most IgLκ+ B cells are then generated later, indicating that there are two waves of IgLκ synthesis in different developmental stages with IgLλ gene rearrangements in between. In the absence of stromal cells, the stepwise order of rearrangements is blocked so that IgLλ gene rearrangements predominate in early B cell development. To our knowledge, this is the first evidence that some mammals can use an inverted order of Ig loci rearrangement. Moreover, a situation in which the generation of BCR-bearing IgLκ is delayed until after IgLλ becomes the dominant isotype may help explain the extreme deviations in the IgLκ/IgLλ ratios among mammals.