The ratio of full length IgY to truncated IgY in immune complexes affects macrophage phagocytosis and the acute phase response of mallard ducks (Anas platyrhynchos)

Ducks produce a full length IgY and a truncated isoform (IgYDeltaFc). IgY and IgY(DeltaFc) were isolated from ducks vaccinated against Escherichia coli and used to make E.coli-Ig immune complexes (IC). Phagocytosis of IC by duck monocytes decreased directly with the proportion of IgYDeltaFc (p<0.001). IC containing IgY:IgY(DeltaFc) at ratios of 100:0, 50:50, 0:100, and 0:0 (E. coli alone) were injected intravenously into na?ve mallard ducks. At 24 h after injection, plasma hemopexin levels were higher in ducks given either the 0:100 ratio or the 100:0 ratio than those given 50:50 or E. coli alone (p<0.005) Liver IL-1beta mRNA levels followed a similar pattern. Splenic IL-1beta mRNA decreased markedly as the proportion of IgY(DeltaFc) increased (p<0.01) Thus, IgY(DeltaFc) may shift the response to IC from the spleen to the liver as infections progress from acute to chronic.     

Antibodies, immunoglobulin genes and the bursa of Fabricius in chicken B cell development

The bursa of Fabricius is critical for the normal development of B lymphocytes in birds. It is productively colonized during embryonic life by a limited number of B cell precursors that have undergone the immunoglobulin gene rearrangements required for expression of cell surface immunoglobulin. Immunoglobulin gene rearrangement occurs in the absence of terminal deoxynucleotidyl transferase and generates minimal antibody diversity. In addition, observations that immunoglobulin heavy and light chain variable gene rearrangement occur at the same time and that allelic exclusion of immunoglobulin expression is regulated at the level of variable region gene rearrangement provide a striking contrast to rodent and primate models of immunoglobulin gene assembly. Following productive colonization of the bursa, developing B cells undergo rapid proliferation and the immunoglobulin V region genes that generate the specificity of the B cell surface immunoglobulin receptor undergo diversification. Immunoglobulin diversity in birds is generated by somatic gene conversion events in which sequences derived from upstream families of pseudogenes replace homologous sequences in unique and functionally rearranged immunoglobulin heavy and light chain variable region genes. This mechanism is distinct from and much more efficient than mechanisms of antibody diversification seen in rodents and primates. While the bursal microenvironment is not required for immunoglobulin gene rearrangement and expression, it is essential for the generation of antibody diversity by gene conversion. Following hatch, gut derived antigens are taken up by the bursa. While bursal development prior to hatch occurs in the absence of exogenous antigen, chicken B cell development after hatch may therefore be influenced by the presence of environmental antigen. This review focuses on the differences between B cell development in the chicken as compared to rodent and primate models.     

Expression of heavy chain‐only antibodies can support B‐cell development in light chain knockout chickens

Since the discovery of antibody‐producing B cells in chickens six decades ago, chickens have been a model for B‐cell development in gut‐associated lymphoid tissue species. Here we describe targeting of the immunoglobulin light chain locus by homologous recombination in chicken primordial germ cells (PGCs) and generation of VJC_L knockout chickens. In contrast to immunoglobulin heavy chain knockout chickens, which completely lack mature B cells, homozygous light chain knockout (IgL^?/?) chickens have a small population of B lineage cells that develop in the bursa and migrate to the periphery. This population of B cells expresses the immunoglobulin heavy chain molecule on the cell surface. Soluble heavy‐chain‐only IgM and IgY proteins of reduced molecular weight were detectable in plasma in 4‐week‐old IgL^?/? chickens, and antigen‐specific IgM and IgY heavy chain proteins were produced in response to immunization. Circulating heavy‐chain‐only IgM showed a deletion of the CH1 domain of the constant region enabling the immunoglobulin heavy chain to be secreted in the absence of the light chain. Our data suggest that the heavy chain by itself is enough to support all the important steps in B‐cell development in a gut‐associated lymphoid tissue species.     

Nonoverlapping functions of DNA polymerases mu, lambda, and terminal deoxynucleotidyltransferase during immunoglobulin V(D)J recombination in vivo

DNA polymerases mu (pol mu), lambda (pol lambda), and terminal deoxynucleotidyltransferase (TdT) are enzymes of the pol X family that share homology in sequence and functional domain organization. We showed previously that pol mu participates in light chain but surprisingly not heavy chain gene rearrangement. We show here that immunoglobulin heavy chain junctions from pol lambda-deficient animals have shorter length with normal N-additions, thus indicating that pol lambda is recruited during heavy chain rearrangement at a step that precedes the action of TdT. In contrast to previous in vitro studies, analysis of animals with combined inactivation of these enzymes revealed no overlapping or compensatory activities for V(D)J recombination between pol mu, pol lambda, and TdT. This complex usage of polymerases with distinct catalytic specificities may correspond to the specific function that the third hypervariable region assumes for each immunoglobulin chain, with pol lambda maintaining a large heavy chain junctional heterogeneity and pol mu ensuring a restricted light chain junctional variability.     

Defense genes missing from the flight division

Birds have a smaller repertoire of immune genes than mammals. In our efforts to study antiviral responses to influenza in avian hosts, we have noted key genes that appear to be missing. As a result, we speculate that birds have impaired detection of viruses and intracellular pathogens. Birds are missing TLR8, a detector for single-stranded RNA. Chickens also lack RIG-I, the intracellular detector for single-stranded viral RNA. Riplet, an activator for RIG-I, is also missing in chickens. IRF3, the nuclear activator of interferon-beta in the RIG-I pathway is missing in birds. Downstream of interferon (IFN) signaling, some of the antiviral effectors are missing, including ISG15, and ISG54 and ISG56 (IFITs). Birds have only three antibody isotypes and IgD is missing. Ducks, but not chickens, make an unusual truncated IgY antibody that is missing the Fc fragment. Chickens have an expanded family of LILR leukocyte receptor genes, called CHIR genes, with hundreds of members, including several that encode IgY Fc receptors. Intriguingly, LILR homologues appear to be missing in ducks, including these IgY Fc receptors. The truncated IgY in ducks, and the duplicated IgY receptor genes in chickens may both have resulted from selective pressure by a pathogen on IgY FcR interactions. Birds have a minimal MHC, and the TAP transport and presentation of peptides on MHC class I is constrained, limiting function. Perhaps removing some constraint, ducks appear to lack tapasin, a chaperone involved in loading peptides on MHC class I. Finally, the absence of lymphotoxin-alpha and beta may account for the observed lack of lymph nodes in birds. As illustrated by these examples, the picture that emerges is some impairment of immune response to viruses in birds, either a cause or consequence of the host-pathogen arms race and long evolutionary relationship of birds and RNA viruses.     

Analysis of antigen receptor genes in Hodgkin's disease.

AIM--To analyse the configuration of the antigen receptor genes in Hodgkin's disease. METHODS--DNA extracted from 45 samples of Hodgkin's disease was analysed using Southern blotting and DNA hybridisation, using probes to the joining region of the immunoglobulin heavy chain gene, the constant region of kappa immunoglobulin light chain gene, and the constant region of the beta chain of the T cell receptor gene. RESULTS--A single case of nodular sclerosing disease showed clonal rearrangement of the immunoglobulin heavy and light chain genes, all other samples having germline immunoglobulin genes. The nature of the clonal population in the diseased tissue is uncertain, because the intensity of the rearranged bands did not correlate with the percentage of Reed-Sternberg cells present. The T cell receptor genes were in germline configuration in all the samples. CONCLUSIONS--Antigen receptor gene rearrangement is a rare finding in unselected cases of Hodgkin's disease.     

Clonal Epstein-Barr virus genome in T-cell-rich lymphomas of B or probable B lineage.

Seventeen nodal lymphomas (originally diagnosed as T-cell lymphomas based on histological features and immunohistochemical staining results) were studied for the presence of Epstein-Barr virus (EBV) genome, and the results correlated with immunoglobulin and T-cell receptor gene rearrangement analyses performed on the same tissue samples. All four EBV positive cases had clonal rearrangement of the joining region of the immunoglobulin heavy chain (IgJH) gene without clonal T-cell receptor beta-chain (TCR beta) gene rearrangement. Of these, two cases also showed clonally rearranged light chain gene, and they were reclassified as T-cell rich B-cell lymphomas (TRBL). The other two cases lacked clonal kappa or lambda light chain rearrangement and they were reclassified as T-cell rich lymphomas of probable B lineage, based on their isolated IgJH clonal rearrangement. These B-cell lymphomas may be easily misdiagnosed as T-cell lymphomas owing to the presence of an abundant reactive T-cell infiltrate masking the tumor population. The florid T-cell reaction may represent an unusual host response towards a clonal proliferation of EBV bearing B cells.     

Immunoglobulins and immunoglobulin genes of the horse

Antibodies of the horse were studied intensively by many notable immunologists throughout the past century until the early 1970's. After a large gap of interest in horse immunology, additional basic studies on horse immunoglobulin genes performed during the past 10 years have resulted in new insights into the equine humoral immune system. These include the characterization of the immunoglobulin lambda and kappa light chain genes, the immunoglobulin heavy chain constant (IGHC) gene regions, and initial studies regarding the heavy chain variable genes. Horses express predominately lambda light chains and seem to have a relatively restricted germline repertoire of both lambda and kappa chain variable genes. The IGHC region contains eleven constant heavy chain genes, seven of which are gamma heavy chain genes. It is suggested that all seven genes encoding IgG isotypes are expressed and have distinct functions in equine immune responses.     

Inactivation of rabbit immunoglobulin lambda chain variable region genes by the insertion of short interspersed elements of the C family

Two rabbit germ-line genes encoding immunoglobulin lambda light chain V regions were cloned from a rabbit genomic liver DNA library and characterized. One, V lambda 1, is separated by at least 8 kb from any other V lambda gene. The second, V lamdba 4, forms part of a three-gene cluster with two functional V lambda genes recently reported. Both V lambda 1 and V lambda 4 have structural features rendering them pseudogenes. The coding regions have frame-shift mutations which would yield defective protein products; both genes are also interrupted by the insertions of short, interspersed repetitive elements of the C family. In the V lambda 1 gene, the 369-bp insert is located upstream of the gene between the putative TATA box and the leader exon, whereas in gene V lambda 4, the 360-bp insert interrupts the FR2 at codon 48c. In addition, the sequence of the complement-determining region 3 of gene V lambda 1 is very similar to the mouse DSP2.6 sequence.     

Endogenous immunoglobulin expression in mu transgenic mice

Transgenic mice (M54) containing a functional mu heavy chain were examined to determine the effects of the transgene on rearrangement and expression of endogenous immunoglobulin genes. Two major novel findings are presented. (i) In transgenic mice, the expressed endogenous VH repertoire in LPS-generated B cell blasts and hybridomas is skewed toward expression of JH-proximal VH families (VH7183 and Q52). (ii) There is an increase in the frequency of B cells expressing lambda light chain genes in transgenic mice. Furthermore, in Abelson-MuLV transformed pre-B cells, VH to DJH is inhibited more than the D to JH rearrangement. The results presented indicate that the transgene skews the expressed VH repertoire by inhibiting the VH to DJH rearrangement while permitting an expansion of B cells expressing limited VH and lambda light chain genes.     

Comparison of in situ hybridisation and polymerase chain reaction in the diagnosis of B cell lymphoma.

AIM: To compare the sensitivity of the detection of immunoglobulin light chain messenger RNA (mRNA) restriction by in situ hybridisation (ISH) and clonal immunoglobulin heavy chain gene rearrangements by polymerase chain reaction (PCR) in the diagnosis of B cell lymphoma. METHODS: Analyses were applied to formalin fixed, paraffin wax embedded, routine diagnostic specimens from cases with a provisional diagnosis of reactive lymph node (n = 23), B cell lymphoma (n = 21), and T cell lymphoma (n = 4). Nonisotopic ISH for kappa and lambda immunoglobulin light chain mRNA was performed using both fluorescein and digoxigenin labelled oligodeoxynucleotide probe cocktails. PCR was carried out on DNA extracted from sections using primers to framework 3 (Fr3) of the V segments and to conserved sequences from the J regions of the immunoglobulin heavy chain genes. RESULTS: All reactive lymph nodes showed a polyclonal pattern of light chain mRNA by ISH, although one showed an excess of kappa positive cells. Nineteen of 21 (90%) cases of B cell lymphoma showed light chain restriction, and a further case showed a vast excess of kappa positive cells. By PCR, 20 of 23 reactive nodes (87%) showed a polyclonal pattern. In 13 of 21 B cell lymphomas (62%) a clonal band was detected. CONCLUSION: In the diagnosis of B cell lymphoma in routinely processed diagnostic material ISH for light chain mRNA was more sensitive (90%) than PCR for heavy chain gene rearrangement using Fr3 and J region primers (62%).     

Unusual Sequence of Immunoglobulin L-Chain Rearrangements in a Gamma Heavy Chain Disease Patient

Patients with gamma heavy chain disease (gamma-HCD) generally produce incomplete immunoglobulin (Ig) gamma-heavy chains (gamma-HCD protein) which cannot associate with light chains (IgL). In most patients Bence Jones proteins (BJP) are not observed. However, in the 61-year-old patient WIN we found gamma l-HCD proteins and lambda BJP in serum and urine. WIN gamma l-HCD protein does not carry the Ig Fd region, has a molecular weight of 33.5 kDa, and the seven N-terminal amino acid residues are not translated from any of the known immunoglobulin heavy chain (IgH) gene sequences. These residues are followed by the C gamma l-hinge region. In DNA from peripheral blood lymphocytes of patient WIN we found bands representing dominant rearrangements in one of the two alleles of the IgH, Ig kappa and Ig lambda locus. Taken together, the data from protein and DNA analysis strongly suggest, albeit do not formally prove, that one dominant B-cell clone which carries a rearranged and a non-rearranged allele of each Ig locus produces gamma-HCD protein and lambda BJP. The productive lambda-gene rearrangement in this clone thus has not been preceded by abortive rearrangements in both kappa-locus alleles. Lymphocytes with an unusual sequence of IgL-chain gene activation seem to be involved in the case of gamma-HCD described here.     

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.