Hybrid Ia antigens: Genetic,serologic, and biochemical analyses

Ia specificities 22 and 23 were found to be determinants on hybrid Ia molecules, formed by the noncovalent binding of a 26,000–28,000 dalton beta polypeptide chain (A_e) coded by the I-A subregion and a 32,000–35,000 dalton alpha chain (E_α) coded by the I-E subregion. For expression of Ia. 23 the A_e chain, coded by the I-A subregion, must be derived from the H-2^d haplotype, while A^b, A^s, or A^k can provide the complementing beta chain for the expression of Ia. 22. For expression of Ia. 22 and Ia. 23, most Ia. 7 positive strains can provide the complementing alpha chain (E_α), with the one exception of B 10. PL (E^u), which is Ia. 7 positive but will not complement with A^d to express Ia. 23. Antisera were also produced against hybrid Ia antigens by immunizing with F₁ cells expressing Ia. 22 or Ia. 23 generated by transcomplementation. These antisera detect the same specificities as conventional anti-Ia. 22 and anti-Ia. 23 sera produced against cis-complementing Ia antigens. It is postulated that hybrid Ia determinants are involved in recognition and generation of immune response to antigens under dual Ir gene control. It is also suggested that there are 2 types of Ia specificities: (1) allotypic Ia specificities expressed on the alpha or beta chains (for example, Ia. 7 on the E_α chain) and (2) hybrid Ia specificities, which are unique interaction determinants formed by the association of alpha and beta chains (for example, Ia. 22 and Ia. 23). These interaction gene products may be involved in antigen recognition and presentation.     

Serological cross-reactivity between products of different Ia loci

Antibody prepared in I-E-subregion-incompatible strains (anti-A _e ^s :E ^/k ) cross-reacts with I-A-subregion controlled A ^b : A ^/b and A ^q A ^q complexes. This cross-reaction defines a new I-region specificity designated Ia.50. The implications of this finding for the genetic origin of the I region and immuneresponse-gene function are discussed.     

Variable synthesis and expression of E β and A e (E β ) Ia polypeptide chains in mice of differentH-2 haplotypes

The genetic and molecular requirements for cell-surface expression of Ia antigens precipitated by anti-I-E subregion sera have been examined. Inbred mice of thed, k, p, andr haplotypes synthesize and express on their lymphocytes the two I-region products normally found in anti-I-E-subregion immunoprecipitates, E and A_e (E ). Cells from mice of theb ands haplotypes fail to synthesize E chains but do synthesize A_e chains, which remain in the cytoplasm as partially glycosylated precursors. Cells of thef andq haplotypes fail to synthesize either the A_e or E polypeptide chains, as shown by both genetic complementation tests and analyses of total cell proteins by two-dimensional polyacrylamide gel electrophoresis. The patterns of expression of the intact E :A_e complex are consistent with the theory that both the A_e and E polypeptide chains must be present in the cells for either chain to be expressed in normal amounts on the cell surface. The implications of these observations for the genetics ofI-region-controlled functions are discussed.     

A monoclonal antibody detecting an Ia specificity mapping in the I-A or I-E subregion

An H-2^s anti-H-2^d monoclonal la antibody (CE197) is described which appears to detect a new Ia specificity that maps either in the I-A or the I-E subregion, depending on the haplotype examined. Binding inhibition studies with radiolabeled, monoclonal I-A-and I-E-specific antibodies imply that CE197 reacts with a public determinant shared by a variety of A -A and E -E dimers.     

Partial amino acid sequences of marine Ia antigens of the I-ECd subregion

Partial N-terminal amino acid sequences of the Ia molecule encoded by theI-E orI-C (I-EC) subregion of theH- 2^d haplotype are presented. Several homology relationships are apparent when these sequences are compared to the gene products of the mouseI- EC^k andI-A subregions and to their human and guinea pig counterparts. The polypeptide differs from the EC ^k polypeptide in two of the seven positions at which they can be compared and shows moderate homology with its human p29 counterpart. The polypeptide is identical to the EC ^k polypeptide in the eight positions which can be compared and is highly homologous to the human p34 polypeptide. The genetic implications of these observations are discussed.Abbreviations used in this paper are SDS-PAGE sodium dodecyl sulphate polyacrylamide gel electrophoresis - PTH-amino acid phenylthiohydantoin amino acid - I-EC I-E or I-C (subregion of the I region)     

Biochemical evidence for multiple I-E Ia molecules

Sequential immunoprecipitation and isoelectric focusing analyses with monoclonal I-E-specific antibodies presented in this paper indicate the existence of multiple I-E molecules. In sequential immunoprecipitations with 13-4 (anti-Ia.7) and 17-3-3 (anti-Ia.22) monoclonal antibodies, 17-3-3 only partially cleared I-E molecules immunoprecipitated by 13-4. Similarly, 13-4 monoclonal antibody only partially cleared I-E molecules precipitated by 17-3-3 monoclonal antibody. These results suggested a minimum of three I-E molecules. One I-E molecule expresses both I3-4 and I7-3-3 determinants, a second I-E molecule expresses only 17-3-3 determinants, and a third I-E molecule expresses only 13-4 determinants. Isoelectric focusing analyses of I-E molcules immuno-precipitated by 13-4 and 17-3-3 showed differences in both A_e beta polypeptide chains and E alpha polypeptide chains. The sequential immunoprecipitation and isoelectric focusing analyses presented in this paper can be explained by a model in which there are at least two separate A_e genes being encoded within the I-A subregion and two separate E genes being encoded within the I-E subregion. The 17-3-3 monoclonal antibody would recognize a determinant on only one of two A_e beta polypeptide chains and the 13-4 monoclonal antibody would recognize a determinant on only one of two E polypeptide chains.Abbreviations used in this paper TAR torpedo acetylcholine receptor - MLR mixed lymphocyte reaction - GL-Phe poly(Glu⁵⁵Lys³⁶Phe⁹) - LPS lipopolysaccharide - SDS sodium dodecylsulfate - IEF isoelectric focusing     

Identity of molecules bearing murine ia alloantigenic specificities Ia.7 and Ia.22: Evidence for a single type of I-E molecule in homozygotes

In homozygous mice bearingI regions derived from haplotypek, only a single type of Ia molecule bearing the alloantigenic specificities Ia.7 and Ia.22 was found using techniques of sequential immune precipitation and tryptic peptide analysis. As suggested at the fourth Ir Gene Workshop (Sachs 1978), Ia.7 is considered here to be an antigenic determinant associated with I-E-subregionencoded molecules, i. e., it is excluded from theI–C subregion. TheI–C subregion is currently defined mainly by functional traits. It is now known that the I-E molecules are composed of an chain encoded in theI–E subregion, and a chain encoded in theI–A subregion. Since theI–C subregion is not involved with the determination of these Ia molecules, and since in homozygotes there is apparently only a single type of molecule bearing both specificities Ia.7 and Ia.22, the term I-E/C molecule should probably be dropped in favor of the simpler designation I-E.     

Clonal analysis of B- and T-cell responses to Ia antigens

Thirty-five Ia^k-specific monoclonal alloantibodies, derived from hybridomas constructed by fusion between mouse myeloma and spleen cells from A.TH alloimmune mice (I ^S anti-I ^k ), have been used to estimate the allotypic polyporphism of the I^k-gene products. Cross-blocking studies using 17 mAb specific for the I-A molecule indicated that six determinants, which were associated with the conventional specificities Ia.2 and Ia.19, were organized in at least three distinct polymorphic areas of the I-A^k molecules. Similarly, another group of six determinants, which did not correspond to previously described conventional Ia specificities, were found to be topologically heterogeneous. By contrast, the five epitopes associated with the Ia. 1 specificity were clustered into a single region of this molecule. In addition the potentiation of binding observed between mAb specific for topologically distinct epitope regions of the I-A^k molecule, suggested that the latter may undergo conformational changes after binding of a given mAb. A similar analysis of 17 mAb specific for the I-E^k molecule indicated that specificity Ia. 7 of the E chain (as defined in this series by eight mAb) was composed of three topologically distinct polymorphic areas, one of which is also spatially related to a complex cluster of eight new determinants of the I-E^k molecule. Finally, one mAb identified a so far undescribed shared determinant of the I-A^k and I-E^k molecules. The present results, which provide a new estimate of the allotypic polymorphism of the Ia^k antigens, are discussed with regard to their functional, biochemical, and evolutionary implications.Abbreviations used in this paper mAb monoclonal antibodies - FCS Fetal calf serum - Con A concanavalin A - H-2 mouse major histocompatibility complex - NMS normal mouse serum - SaCI Staphylococcus aureus Cowan I strain - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis     

Free Ia Eα chain expression in the E α + :E β − : recombinant strain A.TFR5

Molecular and biochemical techniques have been used to explore the reasons behind low E chain expression in the E ⁺ E ^– I-region recombinant strain, A.TFR5. A.TFR5 (A ^f E ^k, ap5), a recombinant between A.CA (A ^f E ^f) and A.TL (A ^k E ^k), carries the E ^k subregion. Previous results have shown that it expresses the E chain, but at reduced levels relative to E ⁺ E ⁺ strains. No E chains were detected, which is consistent with the A.TFR5E gene being derived from the A.CA parent, which carries the null E ^f allele. In this paper, the defect in E-chain expression is explored. Restriction fragment length polymorphism analysis has localized the recombination event in A.TFR5 approximately 30 kb upstream of E, in the region of the large intervening sequence of E. Northern blot analysis of total RNA from A.TFR5 shows normal amounts of the E message, but no E message. Two-dimensional gel analysis of 15 min pulse-labeled A.TFR5, A.CA, and A.TL E immunoprecipitates shows decreased levels of the intracellular E chain in A.TFR5 relative to A.TL. However, analysis of total cell extracts shows normal levels of this protein. A glycoprotein fraction isolated from total cell extracts of 5 h labeled cells contains normal amounts of intracellular E, but decreased amounts of the mature cell-surface protein. These data suggest that in the absence of E, the E chain (1) takes on an altered conformation that is not as efficiently recognized by alloantibodies, and (2) is found in normal levels as the partially glycosylated intracellular precursor, but is not processed and/or transported efficiently to the cell surface.     

Cloned T cells recognize Trichinella spiralis antigen in association with an Ek βEk α restriction element

A method is described for the production of T-cell lines and clones specific for solubilized Trichinella spiralis antigens. hese T cells are antigen-specific and do not respond to challenge with a third party antigen (lysozyme). The proliferation responses of the cloned T cells are specifically inhibited by anti-I-E but not by anti I-A subregion monoclonal reagents. The inhibition patterns obtained are consistent with cis-gene complementation in B10.K cells involving the E^k -chain and the E^k -chain of the I-E molecule. Inhibition is obtained with an E^k -specific monoclonal antibody (H9-14.8) but not with an A^k -specific monoclonal antibody (10-2.16). Inhibition was also observed with Ia.7-specific (H40-242) or Ia.22-specific (17-3-3) monoclonal antibodies. The inhibition patterns were confirmed by antigen presentation experiments using recombinant inbred mice. Only B 10.K (E^k E^k spleen cells and not B 10.A(5R) (E^b E^k ) or B10.S(9R) (E^s E^k ) spleen cells could effectively present T. spiralis antigens. The role of hybrid Ia molecules in the immune response to T. spiralis is discussed.     

Functional similarities of AeEα Ia molecules as determined by analysis with T-cell clones

Recognition of A_eE Ia antigens at the functional level was investigated using T-cell clones. The reactivities of an alloreactive and an antigen-reactive clone, both of which recognized A_eE Ia molecules, were compared on a panel of stimulator/antigen-presenting cells of various genotypes. The two clones recognized all tested A _e ^b E ^x Ia molecules, where x is a haplotype capable of expressing an Ia.7-bearing E polypeptide. Ia antigen recognition by either clone could be inhibited by the monoclonal antibody Y-17, which recognizes a combinatorial serologic determinant on certain A_eE molecules. There were no differences in the recognition of Ia by the alloreactive versus the antigen-reactive clone, suggesting that Ia antigens are recognized by the two clones in a fundamentally similar way. The recognition of these various Ia molecules by the two cloned T-cell lines provides evidence that the E polypeptides from H-2 haplotypes k, d, r, and u are functionally indistinguishable.Abreviations MHC major histocompatibility complex - Mb myoglobin - MLR mixed leukocyte reaction - PBS phosphate buffered saline - APC antigen presenting cell - KLH keyhole limpet hemocyanin - GAT poly (glut⁶⁰ alai³⁰ tyr¹⁰)n - (TG)-A—L poly (L-tyr, L-glu)-poly (D, L-ala)—poly L-lys - GLPhe poly (glu⁵⁵ lys³⁶ phe⁹)n     

Structural comparisons of serologically identical IA- and IE-encoded antigens from inbred and wild mice

The IA and IE products of B10.S(9R), B10.A, B10.KPB128, and B10.GAA37 were analyzed for primary structural variations by comparative tryptic peptide mapping. The A,A , andE products of B10.S(9R) and B10.A differed in about 40% of their acid-soluble tryptic peptides, indicating that intra-I-region recombinant strain B10.S(9R) received the genes encoding A, A, and E from theH- 2 ^s parental chromosome rather than fromH- 2 ^a . The tryptic peptides of E chains from B10.S(9R) and B10.A were indistinguishable, suggesting that B10.S(9R) received the gene encoding the E chain from theH- 2 ^a parental chromosome. Consistent with the results of others, these data suggest that the genes encodingA ,A and E chains are centromeric to theIJ subregion, while the gene encoding E chains is telomeric toIJ. The I-region products of two congenic lines carrying wild-derivedH- 2 haplotypes on a C57BL/10 background, designated B10.KPB128 and B10.GAA37, are serologically indistinguishable from those of B10.S(9R). The IA and IE products of B10.S(9R) were compared with those of B10.GAA37 and B10.KPB128 to determine the structural similarity of serologically identical products from allopatric populations of wild mice. The A,A , and E products of B10.S(9R) were indistinguishable from those of B10.GAA37 and B10.KPB128 by comparative tryptic peptide mapping. The E chains of these three lines differed in one or two of their acid-soluble tryptic peptides. The results indicate that the IA-encoded products of these three lines are structurally very similar and may be identical suggesting that some alleles of the A, A, and E chains may be maintained in stable linkage associations in allopatric populations of wild mice. The minor structural variations detected in the E chains of these three congenic lines indicate that the E chain is encoded by chromosome 17 and suggest that allelic E chains exhibit considerably less structural variability than other I-region encoded antigens.     

Calcium-induced associations of the caseins: Thermodynamic linkage of calcium binding to colloidal stability of casein micelles

The caseins occur in milk as colloidal complexes of protein aggregates, calcium, and inorganic phosphate. As determined by electron microscopy, these particles are spherical and have approximately a 650 Å radius (casein micelles). In the absence of calcium, the protein aggregates themselves (submicelles) have been shown to result from mainly hydrophobic interactions. The fractional concentration of stable colloidal casein micelles can be obtained in a calcium caseinate solution by centrifugation at 1500g. Thus, the amount of stable colloid present with varying Ca²⁺ concentrations can be determined and then analyzed by application of equations derived from Wyman's Thermodynamic Linkage Theory. Ca²⁺-induced colloid stability profiles were obtained experimentally for model micelles consisting of only _s1- (a calcium insoluble casein) and the stabilizing protein -casein, eliminating the complications arising from - and minor casein forms. Two distinct genetic variants _s1-A andB were used. Analysis of _s1-A colloid stability profiles yielded a precipitation (salting-out) constantk ₁, as well as colloid stability (salting-in) parameterk ₂. No variations ofk ₁ ork ₂ were found with increasing amounts of -casein. From the variation of the amount of colloidal casein capable of being stabilized vs. amount of added -casein an association constant of 4 L/g could be calculated for the complexation of _s1-A and -casein. For the _s1-B and -casein micelles, an additional Ca²⁺-dependent colloidal destabilization parameter,k ₃, was added to the existingk ₁ andk ₂ parameters in order to fully describe this more complex system. Furthermore, the value ofk ₃ decreased with increasing concentration of -casein. These results were analyzed with respect to the specific deletion which occurs in _s1-caseinA in order to determine the sites responsible for these Ca²⁺-induced quaternary structural effects.     

Biochemical characterization of murine Ia antigens with xenoantisera

Rabbit anti-Ia sera was produced by immunization with detergentsolubilized extracts from splenic, lymph-node and thymus cells. The antisera contained activity against H-2 as well as Ia molecules. By a sequential immunoprecipitation assay it was shown that the rabbit anti-mouseH-2 ^s serum precipitated a second Ia molecule in theH-2 ^s haplotype. Previous studies with alloantisera have shown only one Ia molecule associated with this haplotype. Sequential precipitations with alloantiserum against the wholeI region were used to show that this second Ia molecule is coded by genes within theI region. Since only I-A- and I-E-region coded molecules are immunoprecipitable in most haplotypes, we presume that the rabbit antiserum could be identifying the I-E-subregion coded molecule in theH-2 ^s haplotype. The rabbit antiserum reacts with an isotypic specificity on the molecule. The studies suggest that theI-E subregion does exist in theH-2 ^s haplotype even though alloantiserum cannot be produced to identify allotypic variants associated with this subregion.     

Serological cross-reactivity between products of separate I regions

A B10.S(7R) anti-B10.S(9R) serum (anti-IJE ^k C ^d ) contained, as expected, antibodies specific for the I-E-subregion-encoded determinant Ia.7. However, tests on recombinant haplotypes demonstrated a series of unexpected weak extrareactions which could be interpreted to be directed against antigenic determinants encoded in the I-A subregion of the H-2 complex. The same type of extrareaction was observed in eluates from I-A ^s , I-E ^k cells coated with A.TH anti-A.TL (I-A ^s , I-E ^s anti-I-A ^k , I-E ^k ) serum. This reactivity in serum and eluates could be interpreted as cross-reactivity between products of the I-E and I-A subregions.     

Alterations in the expression of Ia antigens in F1 hybrid mice

The Ia.8 and 9 specificities detected either by conventional or monoclonal antisera (Ia.m3, 4) are present in strains bearing the b H-2 haplotype, but absent from those with the k haplotype. It would be expected that the (b x k)F₁ hybrids would have approximately half the amount of these specificities found on the b parent, but the Ia.8 and 9 specificities are absent or reduced in this F₁ hybrid, though not on F₁ LPS blasts. Examination of appropriate H-2 congenic strains demonstrated that only the k haplotype confers the absence of these specificities on H-2 ^b — it was not observed with b, d, q, r or s haplotypes. In the k haplotype the gene(s) responsible for this effect is mapped to the I-A ^k subregion. The reason for this low expression effect is not clear but the observation has important implications for the relationship of Ia specificities and Ir genes and may serve to explain the low responder status of certain F₁ hybrids, e. g., to TNP-mouse serum albumin, as observed elsewhere.     

E infα supk transgene in B10 mice suppresses the development of myasthenia gravis

Mice bearing the H-2 ^bhaplotype are susceptible to the development of experimental autoimmune myasthenia gravis (EAMG), induced by acetylcholine receptor (AChR) autoimmunity. One of the genes influencing EAMG susceptibility has been mapped to the A ^blocus of the major histocompatibility complex, and the A chain has been implicated in the pathogenesis. Mice of the H-2 ^bhaplotype, including C57BL/10 (B10), have a genomic deletion of the E gene and therefore fail to express the E molecule on their cell surface. To test the hypothesis that failure to express the cell surface E molecule in B10 mice contributes to EAMG pathogenesis, E _inf ^supk transgenic B10 mice expressing the T molecule were examined. Expression of the E molecule in E _inf ^supk transgenic B10 mice partially prevented the development of EAMG.     

Fine specificity of a proliferating T-cell clone activated by a conformational determinant of the I-Ek molecule

We have examined the fine specificity of a stable Thy-1.2⁺, Lyt-1.2⁺, Lyt-2^–, and I-A^s– anti-I-E^k proliferating T-cell clone isolated from an A.TH anti-A.TL secondary mixed lymphocyte culture. Spleen cells from various I-A^k, E^k strains induced either a strong (A.TL, OH, and CBA) or a weak (AKR and B10.BR) proliferative response, although such cells expressed at their surface similar amounts of I-E^k antigens. Analysis of H-2 recombinant strains indicated that this clone recognized a conformational determinant carried by the E ^k E ^k dimer, but not on the Ea chain per se. Among the Fl hybrid strains in which the combinatorial E ^k E ^k product was detected by cellular binding with monoclonal E ^k -specific antibodies (mAb), some [(BIO.S(8R) × BlO.HTT) but not others (for example, B10.A(4R) × B10.A(5R)] were stimulatory. Seventeen anti-E^k mAb, regardless of the three spatially separated domains that they defined by antibody binding competition, completely inhibited the restimulation of this clone, whereas 15 other anti-A^k mAb failed to do so. This clone was not reactivated by stimulating cells from strains with the H-2 haplotypes p, j, v, b, r, and s but it proliferated strongly against cells from several H-2 ^d or H-2 ^q strains. Genetic evidence or blocking studies with selected mAb assigned these cross-reactive mixed lymphocyte reaction determinants to the A^d or A^q molecules, respectively. The data support the conclusion that alloreactive T cells may define a polymorphism of I-region coded products not detected by serological analyses and extend at the T-cell level the observations of serological cross-reactions between A and E molecules.     

Biochemical documentation of allelic variation of the I-E antigens of the d,k, p,r, and u haplotypes

The extent of allelic variation of the E and E polypeptide chains of the I-E antigens from the H-2> ^d ,H-2 ^k , H-2 ^p , H-2 ^r , and H-2 ^u haplotypes is described. E and E chains were individually labeled with arginine or lysine and compared by tryptic peptide analysis. The results indicate minimum variability among the E polypeptides encoded by the d, k, p, and r haplotypes. However, the E ^u chain differed significantly from the other allelic E gene products. On the other hand, the E alleles demonstrated substantial variability with the E ^d being notably less similar to the other alleles than they are to each other. These findings are consistent with a number of observations regarding the serology and functions of the I-E antigens.Abbreviations MHC major histocompatibility complex - NMS normal mouse serum - NP-40 Nonidet P-40 - NTS 0.25% NP-40, 10 mM Tris-Cl, 0.15 M NaCl (pH 7.4) - SDS sodium dodecylsulfate - SDS-PAGE polyacrylamide gel electrophoresis in the presence of SDS     

Genetic mapping of the component chains of Ia antigens

The genes encoding the two polypeptide chains ( and) that comprise the murine Ia antigens were localized within distinct regions of the major histocompatibility complex (MHC). This was accomplished by correlating allelic forms of the and chains with the MHC congenic strains of mice from which they were isolated. Allelic forms of and chains were distinguished by their unique structural markers, such as isoelectric points, amino acid sequences or peptide maps. The results indicate that the structural genes for both the and chains of I-A subregion antigens are located within the K to I-A genetic interval. In contrast, the gene encoding the chain of I-E subregion antigens is located outside of theI-E subregion and within the K to I-B genetic interval. These findings may have important implications for analysis of observations that complementation by twoI-region genes is sometimes required for development of immune responses.