Production of immunoadsorbents based on cellulose carbonates and their application to the isolation of specific immunoglobulin light chains

The purification of rabbit immunoglobulin molecules expressing kappa (κ) light chains, utilizing the allotypic specificity b4, has been achieved in stages involving isolation of specific antibody, preparation of a solid phase immunoadsorbent of coupled antibody, and subsequent isolation of b4 (κ) IgG. Cellulose trans-2.3-carbonate is shown to be an effective matrix enabling chemical coupling of antibodies and antigens to the support at neutral pH thus preservng immunological activity. The trans-2,3-carbonate derived from microcrystalline cellulose is more effective as a matrix than the trans-2,3-carbonate derived from macroporous cellulose for the chemical coupling of rabbit a1a3/b4 IgG antigen and binding of specific anti-b4 antibody. The microcrystalline celulose carbonate is also more efficient for the coupling of rabbit anti-b4 antibody and the subsequent binding and elution of rabbit b4 (κ) IgG, thus separating immunoglobulin, expressing kappa light chain, from that expressing lambda light chain. The purification technique has potential application in other allotypic systems and antibody- antigen populations.     

Surface immunoglobulin on rabbit lymphoid cells. III. Double expression and separate endocytosis of surface immunoglobulin allotypes on heterozygous lymphocytes demonstrated by immunoelectron microscopic labeling.

The expression of immunoglobulin b locus (k chain) allotypes on the surface of rabbit peripheral blood lymphocytes (PBL's) is examined using an indirect double immunoelectron microscopic labeling technique. Ferritin and whelk hemocyanin individually conjugated to allotypically specific IgG are used as ultrastructurally identifiable molecular markers. These indicators are coupled to lymphocyte surface immunoglobulin (Ig) allotypic determinants by an antiallotype antibody linkage. Human red blood cells, conjugated with IgG of a specific allotype and used as test cells, demonstrate the absolute specificity and high efficiency of the ultrastructural labeling technique. Specific labeling on rabbit PBL's shows that 65–75% of the cells are positive for surface Ig. Lymphocytes from homozygous donors (b4b4 or b6b6) are labeled specifically with only the appropriate allotypic labeling system. Thirty-three percent of the PBL's from heterozygous donors (b4b6) express both allotypes (allelic inclusion) on the cell surface; the remaining proportion of Ig-bearing cells have only one detectable allotype present (allelic exclusion). We conclude that approximately 50% of the Ig-bearing PBL's demonstrate allelic inclusion for the b locus allotypes. On allelically included heterozygous lymphocytes, both allotypic determinants can undergo specific endocytosis. Endocytosis of one allotype on heterozygous cells can be induced by stimulation with antiallotypic serum without affecting the surface appearance of the other allelic marker (separate endocytosis).     

Allotype-related sequence variation of the heavy chain of rabbit immunoglobulin G

The heavy chain of rabbit immunoglobulin G exists in three major allotypic patterns, Aa1–Aa3. A comparison of the amino acid compositions of the heavy chains isolated from immunoglobulin IgG homozygous for each allotypic determinant revealed the presence of an additional methionine residue per chain in the Aa3 allotype relative to the Aa1 and Aa2 allotypes. The position of the additional methionine residue was determined by cyanogen bromide cleavage and by tryptic digestion of the γ-chains; it coincided with the inter-Fd–Fc area of the chain. Isolation and characterization of the corresponding tryptic peptides of 31 amino acid residues from each of the allotypes showed the presence of a methionine-for-threonine replacement in the Aa3 allotype, but only in about 70–80% of the molecules. No other allotypic variations were seen in this tryptic peptide. Allotypically related variations in composition were also detected in the N-terminal cyanogen bromide-cleavage peptide.     

Heavy chain variable region allotypic subspecificities of rabbit immunoglobulins. II. Selective escape of the a1-AB Ig subpopulation after the induction of auto anti-a1 antibody.

An a1a2 rabbit (P286-3), neonatally suppressed for the expression of the a1 allotype, was immunized with autologous a1 IgG at 2 months of age. Both auto anti-a1 Ab and a1 IgG molecules were found in the serum of this rabbit after the auto-immunization. The auto anti-a1 Ab and the IgG from the auto anti-a1 Ab-depleted serum were isolated. Of the previously defined a1-AB, a1-AC, and a1-AD Ig subpopulations, the a1 IgG in the IgG preparation from the rabbit P286-3 were all of the a1-AB Ig subpopulation. The auto anti-a1 Ab from rabbit P286-3 did not react with the a1-A, a1-B, and a1-C allotypic subspecificities; thus, it was presumably specific for the a1-AC and a1-D allotypic subspecificity. Thus, the a1-AB Ig subpopulation escaped from allotype suppression in rabbit P286-3, whereas the a1-AD Ig subpopulation remained suppressed. The a1-AD Ig subpopulation will probably remain suppressed for a long time and perhaps permanently since rabbit P286-3 has produced circulating auto-Ab specific for the a1-D allotypic subspecificity. These results indicate that the a1 Ig subpopulations are synthesized by distinct clones of lymphocytes under separate control.     

Structural and genetic studies on chicken 7S immunoglobulin allotypes. III. Proposed nomenclature for the CS-1 gene alleles.

A survey of 47 inbred or partially inbred chicken lines derived from five sources in the United States and Europe revealed considerable genetic polymorphism in the structural gene (CS-1) responsible for the production of the predominant chicken 7S Ig heavy chain. A minimum of 10 alleles of the CS-1 gene were detected as unique combinations or phenogroups of CS-1 specificities. A system of nomenclature for CS-1 alleles was developed and six homozygous lines were designated as prototype lines. The remaining four CS-1 alleles occurred only in lines that were polymorphic for 7S Ig allotypic specificities.     

An allotypic specificity presumably of the a series in rabbit immunoglobulins, different from a1, a2, and a3

From the serum of a wild rabbit lacking all the known allotypic specificities of the a series, IgG showing an allotypic specificity named. A100 has been isolated and antisera against it prepared in domestic rabbits. The determinants responsible for the A100 allotypic specificity are present both on IgG and IgM. They are located on the heavy chain and the Fab fragment of IgG.Evidence for the genetic determinism of A100 suggests that it is the product of a new allele at the $\text{a}$ locus.     

Rabbit latent group a allotypes: characterization and relationship to nominal group a allotypic specificities.

Latent group a allotypes were detected with a sensitive radioimmune inhibition assay. Sera, IgG preparations, and antibody fractions containing these allotypes inhibited the binding of insolubilized allotypic antisera to various radiolabeled antigens including IgG pools, homogeneous antibodies, and, in the case of a3, a VH fragment from a3/b4 IgG. Several different group a antiallotypic sera were used in the assays and all gave similar results. Comparison of inhibition curves for nominal and latent allotypes indicated that the full spectrum of allotypic subspecificities may be expressed in latent allotypes. Hemagglutination studies carried out with five sera containing high levels of latent allotypes confirmed the results obtained with the radioimmunoassay and indicated that inhibition values did not, at least in four of the five samples studied, reflect the presence of antiallotype antibodies.     

Immunoelectron microscopic localization of idiotypes and allotypes on immunoglobulin molecules

We have developed a novel approach to the analysis of antigenic (allotypic and idiotypic) determinants on intact immunoglobulin molecules. Immune complexes composed of IgG in combination with anti-idiotype or anti-allotype antibody were "visualized" by transmission electron microscopy. Individual Fab fragments of anti-idiotype or anti-allotype antibody, when bound to the IgG, altered the "Y" configuration in a reproducible and interpretable manner. Anti-idiotype antibody (either as Fab or IgG) bound to the terminus of the presumed V region of the IgG molecule, thus extending the apparent length of the Fab arms. Analysis of a rabbit VH framework allotype (a1) revealed that the determinant(s) is (are) located on the lateral portion of the V region of IgG. Binding of the anti-a1 Fab fragments was always at approximately right angles to the axis of the Fab arms of IgG. Fab antibody to the rabbit kappa light chain (b4) allotype bound to the lateral portion of the terminal half of the IgG Fab arms. This technique should be of value in localizing less well defined immunoglobulin determinants.     

The structural basis of rabbit VH allotypes: serologic studies on a1 H chains with defined amino acid sequence.

The amino acid sequences for the VH regions of three homogeneous antibodies elicited by type III pneumococcal vaccine were determined. All three antibodies had the group a allotype a1. Two of the antibody H chains (3372, 3381) had identical amino acid sequences in all framework positions that are considered correlates of the VH allotype, whereas the third H chain (3T72) differed from these at positions 15 and 16. The a1 allotypic specificities of the three homogeneous antibodies were compared by quantitative radiobinding and inhibition assays by using both insolubilized anti-a1 antisera and allotypic antiserum fractions rendered specific for the homogeneous antibody 3374. It was found that antibodies 3374 and 3381 are allotypically indistinguishable and have in common an a1 allotypic specificity that predominates in pooled a1 IgG. The allotypic specificity of the 3T72 antibody, on the other hand, was markedly deficient to those of 3374, 3381, and the a1 IgG pool. This correlation of allotypic difference with amino acid sequence variation at position 15 and 16 of the H chain indicates the involvement of these two residues in a major a1 allotypic determinant.     

Apparent effect of rabbit endogenous lentivirus type K acquisition on retrovirus restriction by lagomorph Trim5αs

To test the hypothesis that rabbit endogenous lentivirus type K (RELIK) could play a role in shaping the evolution of TRIM5α, the susceptibility of viruses containing the RELIK capsid (CA) to TRIM5 restriction was evaluated. RELIK CA-containing viruses were susceptible to the TRIM5αs from Old World monkeys but were unaffected by most ape or New World monkey factors. TRIM5αs from various lagomorph species were also isolated and tested for anti-retroviral activity. The TRIM5αs from both cottontail rabbit and pika restrict a range of retroviruses, including HIV-1, HIV-2, FIV, EIAV and N-MLV. TRIM5αs from the European and cottontail rabbit, which have previously been found to contain RELIK, also restricted RELIK CA-containing viruses, whereas a weaker restriction was observed with chimeric TRIM5α containing the B30.2 domain from the pika, which lacks RELIK. Taken together, these results could suggest that the pika had not been exposed to exogenous RELIK and that endogenized RELIK might exert a selective pressure on lagomorph TRIM5α.     

The distribution of immunoglobulin allotypes in rabbit populations in Australia and on Macquarie Island

Wild rabbit populations from several parts of south-eastern Australia and from Tasmania and Macquarie Island were tested for the As1, As2, As3 ( a locus) and the As4, As5, As6, As9 ( b locus) allotypic IgG markers. All markers except As6 were present in the Australian mainland and Tasmanian populations, and there appeared to be a significant increase in As ¹ frequency with decreasing rainfall. On the other hand the Macquarie Island samples were virtually all homozygous As1 at the a locus and lacked As6 and As9 at the b locus.
These results are discussed against the background of the known history of the introduction of the rabbit into the areas studied. It was felt that 'founder effect' could account for the observed distribution on Macquarie Island. However, the As ¹ cline in Australia warrants further study, particularly in relation to possible selective effects.     

Evolution of genes for allelic and isotypic forms of immunoglobulin kappa chains and of the genes for T-cell receptor beta chains in rabbits

New insights into the evolution of the families of genes encoding immunoglobulins and T-cell receptors of rabbits (Oryctolagus cuniculus) have come from molecular genetic studies. In contrast to human and mouse, rabbits were shown to have two genes for the constant region of immunoglobulin light chains (C kappa 1 and C kappa 2 isotypes) and complex allelic variants of K1 (allotypes). Although K1 allotype protein sequences differed at up to 41% of the amino acid positions, 3' untranslated, 5', and 3' flanking regions were conserved, and in the coding regions 78-80% of the codons with differences had replacement changes. Proportions of silent changes and changes in noncoding regions were comparable. Thus, in spite of their markedly different protein sequences, the K1b4, b5, and b9 allotypes appeared to be products of allelic genes. Molecular genetic analyses suggested that they may have undergone rapid divergence after an ancestral K2-like gene duplicated. Some rabbits were found to have two similar T-cell receptor C beta genes as do humans and many strains of mice, but others appeared to have three different C beta. In addition, we found allotypic forms of C beta. Some of the C beta allotypic differences occurred at positions where analogous C kappa allotypic differences were found. We also found V beta in mouse and human that were more similar to rabbit V beta than closely linked rabbit genes were to each other. This contrasts with rabbit immunoglobulin VH gene sequences that reflect concerted evolution. The data suggested that T-cell receptor V beta genes duplicated prior to mammalian radiation.     

Localization of the xg allotypic determinants,in which carbohydrate structures take part,to the separable parts of the rabbit IgG molecule

Enzyme-immunologic and radio-immunologic techniques made it possible to localize the determinants responsible for the xg allotypic specificity (in which carbohydrate structures are involved) to the heavy polypeptide chains and the Fc fragment of rabbit IgG, but not to the light chains nor the Fab fragment, and in part to the F(ab′)2 fragment obtained by pepsin digestion. The relationship between the xg and the e14 allotypic patterns, to date always found together in the same individuals, is discussed in light of these results.     

A reverse hemolytic plaque assay for the detection and the enumeration of immunoglobulin allotype-secreting cells

We describe a reverse hemolytic plaque assay to enumerate rabbit immunoglobulin allotype-secreting cells. This technique makes use of sheep red blood cells (SRBC) sensitized with goat anti-rabbit IgG and rabbit anti-allotypic sera as revealing antisera. We have used the assay to compare at the IgG molecule level and at the immunoglobulin allotype-secreting cell level, the preferential expression (pecking order), in heterozygous rabbits, of one of the two alleles either at the a or the b locus, respectively, governing the a series allotypic specificities carried by the variable region of the heavy chains and the b series allotypic specificities essentially carried by the constant region of the K light chains.     

Quantitative measurement of mouse IgG subclasses with the use of heteroantisera: the importance of allotype considerations.

Double antibody radioimmunoassays have been used to determine the quantities of IgG1, IgG2a and IgG2b in samples of normal serum IgG from BALB/cJ, AKR/J and C57BL/6J inbred mice. The assays employed subclass-specific goat antisera which had been prepared with BALB/c myeloma proteins as immunogens and as immunoabsorbents. 125I-labeled BALB/c myeloma proteins were used as probes. Results indicate that partial resolution of mouse IgG subclasses was achieved by ion exchange chromatography on DEAE-Sephadex. Nearly all of the protein in BALB/cJ and AKR/J IgG fractions could be accounted for as IgG1, IgG2a and IgG2b, and IgG2a was the predominant species observed. However, considerably less protein in C57BL/6J IgG fractions of purity similar to the BALB/cJ fractions could be accounted for as these three subclasses, and virtually no IgG2a was detected. Furthermore, an IgG2a myeloma protein bearing the C57BL/6 allotype failed to inhibit the IgG2a-specific assay significantly. Thus the IgG2a-specific antibody in the goat heteroantiserum employed appeared to consist nearly exclusively of antibody to BALB/c Ig-1a allotypic determinants. These findings point to the importance of allotype considerations in the use of heteroantisera to quantitate IgG subclasses.     

Transmission of Sarcocystis leporum from a cottontail rabbit to domestic cats.

Muscle tissue containing grossly visible cysts of Sarcocystis leporum from a cottontail rabbit (Sylvilagus floridanus) was fed to laboratory cats. Sporocysts averaging 13.2 x 9.7 micron were detected in the feces 14 days post-infection and were found until 69 days post-infection.     

The N-terminal sequence of the heavy chain of rabbit immunoglobulin IgG

The absence of an N-terminal amino acid with a free alpha-amino group from the heavy chain of rabbit immunoglobulin IgG has been confirmed and no evidence could be found of a blocking formyl, acetyl or propionyl group. The N-terminal amino acid appears to be pyrrolid-2-one-5-carboxylic acid (PCA) in all molecules. A mixed amino acid sequence follows in the approximate proportions: PCA-Ser-Val-Glu-Glu-Ser-Gly-Gly-Arg, 50%; PCA-Ser-Leu-Glu, 20%; PCA-Glu(NH(2)), 20%. The heavy chains of a purified antibody, namely anti-(human serum albumin), and of immunoglobulin IgG from a rabbit homozygous at the allotypic loci both showed a similar mixed N-terminal sequence.     

In vitro host erythrocyte specificity and differential morphology of Babesia divergens and a zoonotic Babesia sp. from eastern cottontail rabbits (Sylvilagus floridanus)

A Babesia sp. isolated from eastern cottontail rabbits (Sylvilagus floridanus) is morphologically similar and genetically identical, based on SSU rRNA gene comparisons, to 2 agents responsible for human babesiosis in the United States. This zoonotic agent is closely related to the European parasite, Babesia divergens. The 2 organisms were characterized by in vitro comparisons. In vitro growth of the rabbit Babesia sp. was supported in human and cottontail rabbit erythrocytes, but not in bovine cells. Babesia divergens was supported in vitro in bovine and human erythrocytes, but not in cottontail rabbit cells. Morphometric analysis classifies B. divergens as a small babesia in bovine erythrocytes, but the parasite exceeds this size in human erythrocytes. The rabbit Babesia sp. is large, the same size in both human or rabbit erythrocytes, and is significantly larger than B. divergens. Eight or more rabbit Babesia sp. parasites may occur within a single erythrocyte, sometimes in a floret array, unlike B. divergens. The erythrocyte specificity and morphological differences reported in this study agree with previous in vivo results and validate the use of in vitro methods for characterization of Babesia species.     

Herpesvirus sylvilagus in cottontail rabbits: antibody prevalence and flea burden relationships

A serologic survey of a wild cottontail rabbit (Sylvilagus floridanus) population in southern Wisconsin was conducted from November-March, 1971-72 and November-April, 1972-73, to determine prevalence of antibody against Herpesvirus sylvilagus. Flea burdens on each live-trapped cottontail were quantified by species. All but six of the 5029 fleas collected were Cediopsylla simplex. No correlation was found between flea infestation and viral antibody. Of 101 cottontail rabbits trapped, only six had specific antibody as determined by plaque neutralization in rabbit kidney cell culture. Three of the six developed antibody between January and March of the trapping season. Blood samples from 46 captured rabbits were negative for virus.     

An HLA-A2.1-transgenic rabbit model to study immunity to papillomavirus infection

We have established several HLA-A2.1-transgenic rabbit lines to provide a host to study CD8(+) T cell responses during virus infections. HLA-A2.1 protein expression was detected on cell surfaces within various organ tissues. Continuous cultured cells from these transgenic rabbits were capable of presenting both endogenous and exogenous HLA-A2.1-restricted epitopes to an HLA-A2.1-restricted epitope-specific CTL clone. A DNA vaccine containing an HLA-A2.1-restricted human papillomavirus type 16 E7 epitope (amino acid residues 82-90) stimulated epitope-specific CTLs in both PBLs and spleen cells of transgenic rabbits. In addition, vaccinated transgenic rabbits were protected against infection with a mutant cottontail rabbit papillomavirus DNA containing an embedded human papillomavirus type 16 E7/82-90 epitope. Complete protection was achieved using a multivalent epitope DNA vaccine based on epitope selection from cottontail rabbit papillomavirus E1 using MHC class I epitope prediction software. HLA-A2.1-transgenic rabbits will be an important preclinical animal model system to study virus-host interactions and to assess specific targets for immunotherapy.