Construction and properties of new Lyt-congenic strains and anti-Lyt-2.2 and anti-Lyt-3.1 monoclonal antibodies

Hybridomas producing mouse monoclonal IgM antibodies specific for Lyt-2.2 and Lyt-3.1 T-cell surface alloantigens have been constructed. Cytotoxic titers of ascites fluids were found to be 10^–6 or greater and no lysis of thymocytes of congenic strains bearing the alternative allele was observed at the lowest dilutions tested (12). The anti-Lyt-2.2 monoclonal antibody (HO-2.2) specifically precipiated from extracts of Lyt-2.2-positive thymocytes molecular species indistinguishable from those precipitated by conventional anti-Lyt-2.2 sera. However, by immunoprecipitation criteria (though not by cytotoxicity), the anti-Lyt-3.1 antibody (HO-3.1) demonstrated some cross-reactivity with similar molecular species from Lyt-3.1-negative thymocytes.In addition, three new strains of mice differing from existing strains in the region of theLyt-2 and4Lyt-3 loci have been constructed. They are: C.C58-Lyt-2^a, Lyt-3^a and C.AKR-Lyt-2^a, Lyt-3^a, congenic with Balb/cAn and bearingLyt-2 ^a andLyt-3 ^a alleles of C58/J and AKR/J, respectively; and AKR.C-Lyt-2^b, Lyt-3^b, congenic with AKR/J and bearing theLyt-2 ^b andLyt-3 ^b alleles of Balb/cJ.Abbreviations used in this paper DMSO dimethylsulfoxide - NP40 Nonidet P-40 detergent - SaCI Staphylococcus aureus, Cowan I strain - SDS sodium dodecyl sulfate - PAGE polyacrylamide gel electrophoreses - NP-NET buffer 0.15 M NaCl, 0.005 M EDTA, 0.05 M Tris, 0.02% sodium azide, pH 7.4, containing 0.5% or 0.05% NP40 as stated in text     

Sequential precipitation of mouse thymocyte extracts with anti-Lyt-2 and anti-Lyt-3 sera. I. Lyt-2.1 and Lyt-3.1 antigenic determinants reside on separable molecular species.

Anti-Lyt-2.1 and anti-Lyt-3.1 sera were employed for sequential precipitation of NP-40 extracts of 125I-labeled C57BL/6-Lyt-2a, Lyt-3a thymocytes (Lyt-2.1, Lyt-3.1) to determine whether these alloantigenic determinants are present on the same or different molecular species. Treatment of extracts with anti-Lyt-3.1 serum and SaCI completely precipitated both Lyt-3.1 and Lyt-2.1-specific components, whereas treatment with anti-Lyt-2.1 serum reduced by approximately 37% the quantity of labeled species subsequently precipitable by anti-Lyt-3.1 serum. When 125I-labeled thymocytes were subjected to mild trypsinization before NP-40 extraction, the quantity of radioactive components precipitated by anti-Lyt-2.1 serum was essentially unchanged, but that of anti-Lyt-3.1-precipitable components was greatly reduced. Moreover, sequential precipitation of extracts of trypsinized thymocytes with anti-Lyt-2.1 and anti-Lyt-3.1 sera demonstrated that these molecular species were precipitated independently. Thus 1) Lyt-2.1 and Lyt-3.1 antigenic determinants appear to reside on different molecular species; 2) some Lyt-2.1- and Lyt-3.1-positive molecules appear to be complexed with each other in the NP-40 extract; and 3) this association of Lyt-2.1- and Lyt-3.1-positive species was dependent upon components that were labile to trypsinization of intact thymocytes.     

Construction and properties of new Lyt-congenic strains and anti-Lyt-2.2 and anti-Lyt-3.1 monoclonal antibodies

Hybridomas producing mouse monoclonal IgM antibodies specific for Lyt-2.2 and Lyt-3.1 T-cell surface alloantigens have been constructed. Cytotoxic titers of ascites fluids were found to be 10(-6) or greater and no lysis of thymocytes of congenic strains bearing the alternative allele was observed at the lowest dilutions tested (1:2). The anti-Lyt-2.2 monoclonal antibody (HO-2.2) specifically precipiated from extracts of Lyt-2.2-positive thymocytes molecular species indistinguishable from those precipitated by conventional anti-Lyt-2.2 sera. However, by immunoprecipitation criteria (though not by cytotoxicity), the anti-Lyt-3.1 antibody (HO-3.1) demonstrated some cross-reactivity with similar molecular species from Lyt-3.1-negative thymocytes. In addition, three new strains of mice differing from existing strains in the region of the Lyt-2 and Lyt-3 loci have been constructed. They are: C.C58-Lyt-2a, Lyt-3a and C.AKR-Lyt-2a, Lyt-3a, congenic with Balb/cAn and bearing Lyt-2a and Lyt-3a alleles of C58/J and AKR/J, respectively; and AKR.C-Lyt-2b, Lyt-3b congenic with AKR/J and bearing the Lyt-2b and Lyt-3b alleles of Balb/cJ.     

Murine responses to (Tyr-Glu-Ala-Gly)n: II. H-2 and non-H-2 gene effects

Mice of the H-2^b haplotype responded to the sequential polymer poly(Tyr-Glu-Ala-Gly) in the in vitro T-cell proliferative assay, irrespective of whether they were homozygous or heterozygous at the H-2^b locus. The antibody responses of the H-2^b congenic mice to this polymer were variable, with A.BY and BALB.B showing responses better than those of C57BL/6 and C57BL/10 strains. The antibody responses of the F₁ progeny of (responder × nonresponder) strains of mice to this polymer are generally lower than the responder parents. F₁ mice with C57BL/10 background were the poorest responders. Studies with F₂ mice and backcross progenies of selective breeding of high and low antibody responder (C57BL/6 × BALB/c) F₁ to high responder C57BL/6 mice indicated that both non-H-2 genes and H-2 gene dosage effects influenced the magnitude of the humoral antibody responses. Animals having low responder non-H-2 background and only half the dosage of the responder immune response genes has greatly diminished antibody responses.     

TheH-2 class II genes and the susceptibility to the development of pulmonary adenoma in mice

To determine the locus in theH-2 complex that affects susceptibility to the development of pulmonary adenomas in mice,H-2 congenic and recombinant strains of mice with A/Wy, BALB/c, C3H, and B10 backgrounds were subjected to treatment with urethane. The average number and the incidence of adenoma foci were recorded five months after the treatment. InH-2 congenic strains on the A/Wy background, the average number of adenoma foci per mouse was significantly higher in mice of the A/Wy, A/J, and A-Tla ^b (H-2 ^a ) strains than in A.BY (H-2 ^b ) mice. In BALB/c and C3H congenic strains, the strains carrying theH-2 ^k haplotype were more susceptible than those carrying theH-2 ^b haplotype. InH-2 congenic strains on the B 10 background, the average number and incidence of foci was also higher in haplotypesa, h2, k, andj than in haplotypesb, s, f, d, r, h4, i3, i5, and4. The average numbers of adenoma foci in (A/J × A.BY)F₁ (H-2 ^a /H-2 ^b ) and (B10 × B10.A)F₁ (H-2 ^b /H-2 ^a ) were intermediate between the numbers in the parental strains. In [B10.A (4R) × B10.A (3R)]F₁ (H-2 ^h4 /H-2 ⁱ³ ) and [B10.A (4R) × B10.A (5R)]F₁ (H-2 ^h4 /H-2 ⁱ⁵ ), the numbers of adenoma foci were higher than in resistant parental recombinants. These patterns of response to urethane matched the patterns of the immune response to lactate dehydrogenase-B (LDH-B) and immunoglobulin gamma 2a (IgG2a) proteins. These differences between mice in their susceptibility to the development of pulmonary adenomas is probably due to the polymorphism of the class II genes in theH-2 complex.     

Genetic control of “natural” killer lymphocytes in the mouse

Spleens from normal young mice contain lymphocytes that can kill certain in vitro grown Moloney lymphoma lines in a⁵¹Cr-release cytotoxicity test. A lymphoid cell without detectable T- or B-cell markers was previously shown to be responsible. Killing activity shows a marked dependence on the genotype of the donor mouse. When tested against a YAC line of strain A origin maintained in vitro spleens of A, A.CA, and A.SW mice had low activity, whereas CBA, C3H, C57L, and C57Bl spleens were highly active. In semisyngeneic F₁ crosses with strain A as one parent, reactivity resembled the opposite parental strain. Thus, (A×CBA)F₁, (A×C3H)F₁, (A×C57L)F₁, and (A×C57Bl)F₁ were reactive, whereas A×A.CA showed no significant activity. Analysis of the reactivity in (A×C57Bl)F₁×A backcross mice suggests that multiple genes are involved. Preliminary linkage analysis suggests at least oneH-2 linked factor. Another gene appears to be linked to theB (black) locus.     

Natural resistance of irradiated 129-strain mice to bone marrow allografts: Genetic control by theH-2K region

A major genetic determinant of natural resistance to bone marrow allografts, designated asHh-3, was mapped to theH-2K region. This gene may code for or regulate the expression of cell surface structures selectively expressed on donor hemopoietic cells and recognized by naturally occurring cytotoxic effectors. Resistance was observed as failure of donor cell growth in the spleen of irradiated 129-strain (H-2 ^bc ) recipients of H-2^k bone marrow cells. The mapping was accomplished by substituting donor cells bearingk alleles throughout theH-2 complex with cells of recombinant mouse lines bearingk alleles at definedH-2 regions. The host antigraft reaction underlying resistance was abrogated by pretreating 129-strain mice with either rabbit antimouse lymphocyte serum or the antimacrophage agent silica. Grafting of H-2K^k cells into mice ancestrally unrelated to 129 but sharing theH-2 ^bc or the similarH-2 ^b haplotype, and intoH-2 ^b/k ,H-2 ^k/bc , andH-2 ^k/d F₁ hybrids revealed that resistance was unique to 129 mice, since mice of the other strains, including F₁ hybrids, were susceptible to the grafts. Thus,Hh-3 incompatibility was a necessary but insufficient condition for the manifestation of allogeneic resistance; other genetic factors not associated withH-2 conferred responder status to 129-strain mice and nonresponder status to D1.LP, B10.129(6M), B10, B6, and possibly to F₁ hybrid mice. The possible relationships between allogeneic resistance to H-2^k marrow grafts, hybrid resistance to H-2^k lymphomas, and F₁ hybrid antiparental H-2^k cytotoxicity induced in vitro are discussed.     

A gene locus affecting tolerance to BGG in mice.

A genetic analysis was made of the ease of tolerance induction to bovine γ-globulin (BGG) in DBA/2, BALB/c, F₁ and backcross generation mice. Like parental DBA/2 mice, the F₁ generation of BALB/c × DBA/2 becomes tolerant when treated with 2 mg BGG. A backcross of this F₁ to DBA/2 parents produced mice that all became tolerant to this dose of BGG. A backcross of F₁ mice to BALB/c parents produced 50% offspring tolerized by the same dose of BGG and 50% resistant to tolerance induction.The data suggest a single autosomal locus affecting tolerance induction. Data presented elsewhere suggest that the locus affects macrophage function. We propose that this locus be called tolerance (symbol Tol-l) and the two alleles be (Tol-l^a (DBA/2 type) and Tol-l^b (BALB/c type) with Tol-l^a being dominant.     

H-2-linked murine factor B phenotypes

A hemolytic assay has been developed which is specific for Factor B (B) activity in murine EDTA-plasma. Three discrete levels of B activity were observed among B 10-congenic strains. Mice with standard H-2 haplotypes, b, d, k, r, f, q, s, and u, all exhibited the same mean level of activity. However, plasma from H-2 ^v (B10.SM) mice contained only 0.25 of that level, and those with standard haplotype H-2 ^ja (B10.WB) or wild haplotype H-2^wr7 (B10.WR) exhibited 2.5 times the H-2 ^b (1310) basal level of activity. These differences among B10 congenic lines suggested that the activity is H-2 controlled; further tentative mapping with intra-H-2 recombinants indicated that the gene is located in the S region. A fourth phenotype was found among progeny of backcross generations between B10.BR (H-2 ^k ) and mice of subspecies Mus musculus molossinus and M. m. bactrianus. This ultra-high activity was found also to be governed by a gene very closely linked to Ss, the primary S region marker. F₁ generations between disparate phenotypes yielded progeny with activity levels intermediate between the parents; progeny of parents of different strains with the same phenotype expressed B hemolytic titres equal to those of the parental strains. No differences in antigenic levels of the protein among the strains of different phenotypes could be detected by radial immunodiffusion. In mixing experiments, resultant activity levels were intermediate between the higher and the lower phenotype, ruling out independent inhibitors or activators of the reaction. These studies indicate that an H-2-linked S region-located single gene governs structural differences in allelic B molecules that lead to differences in specific activities.     

Production of anti-self-H-2 antibodies by C3D2F1 mice hyperimmune to L cell/L1210 hybrids and L1210 leukemia cells

During the course of immunization of (C3H × DBA/2)F₁ mice (genotype H-2^k/b) with L cell (H-2^k/k)/L1210 leukemia cell (H-2^d/d) hybrids and L1210 leukemia cells, some of them produced a good titer of anti-self-H-2 (H-2^d) antibodies. Antigens recognized by this anti-self-H-2 antiserum were shown to be controlled by the H-2K-IA-IB-IJ-IE subregions of the H-2^d but not H-2^k nor H-2^b haplotypes of parental as well as F₁ origins and to have a tissue distribution identical to that of class 1 H-2 (H-2K/D) antigens.     

Xid-defective male (CBA/N x C57BL/6)F1 accessory cells present bovine insulin to long-term cultured F1-restricted T-cells

The reactivity of H-2^b-restricted murine T cells towards bovine insulin was reported to depend on the expression of Ia.W39, a private specificity of I-A^b, on antigen-presenting cells. Cells of male (CBA/N x B6)F₁ mice carrying the mutation xid on the X chromosome lack Ia.W39 on the cell surface. These cells are unable to present bovine insulin to primed T cells derived from female (CBA/N x B6)F₁ mice. We show here that spleen cells of male (CBA/N x B6)F₁ hybrids served perfectly as accessory cells for the insulin-dependent induction of a proliferative response of long-term cultured T cells with (B10 x B10.BR)F₁ genotype, restricted to recognizing insulin in the context of F₁-unique I-A determinants. The epitope on the insulin molecule essential for stimulation was determined to depend on the glutamic acid residue in position 4 of the A chain of insulin. This contrasts with the H-2^b-restricted response of B6 mice to bovine insulin, which appears to be directed at the A chain loop determinant (amino acids A8 and A10). These data suggest that distinct I-A^b-encoded structures, the expression of which is regulated independently, may serve as components of restriction elements for H-2^b and (H-2^b x H-2^k)F₁ restricted T cells, which are specific for different epitopes of bovine insulin.     

Studies on the mechanism of transplantation tolerance: I. Do suppressor cells play a role in the induction and maintenance of neonatal transplantation tolerance?

Neonatal transplantation tolerance was induced in CBA (H-2^k) mice to A (H-2^a) mice by injection of (CBA × A)F₁ spleen cells. Animals carrying an A-skin test allograft for more than 4 months without any visible sign of rejection were considered to be permanently tolerant. Permanently tolerant CBA mice were given normal syngeneic spleen cells to abrogate the state of tolerance. Abrogation of tolerance was greatly facilitated by antithymocyte serum (ATS) treatment of tolerant mice prior to the normal syngeneic cell transfer. Survival of A allografts on normal, adult, ATS-treated CBA mice was significantly prolonged (and in many cases “adult” tolerance was achieved) by transfer of spleen cells of syngeneic mice made permanently tolerant at neonatal age. The possible role of the F₁-cell “contamination” in the tolerance-inducing effect of the transferred “tolerant” spleen cells was excluded. The results indicate that ATS-sensitive suppressor cells play a definite role in the induction, maintenance, and transfer of neonatally induced transplantation tolerance.     

Structural polymorphism of murine factor B controlled by a locus closely linked to the H-2 complex and demonstration of multiple alleles

New alleles of murine factor B (Bf) protein were demonstrated. When ethylenediaminetetraacetic acid (EDTA)-plasmas from inbred and wild mice were analyzed by isoelectro-focusing (IEF) and immunofixation, murine Bf proteins were visualized as distinct protein bands in all mice tested. Four variants of murine Bf could be demonstrated in a large number of tested mice: Bf 1 (isoelectro-focusing point (P.I.) range of 5.8–6.1) exemplified by B10 and B10.BR, Bf 2 (P.I. range of 5.8–6.0) exemplified by B10.MOL (OHM), Bf 3 (P.I. range of 5.6–5.9) exemplified by B10.MOL (TEN2) and Mus musculus (Mus m.) subspecies Chc, Bf4 (P.I. range of 6.0–6.3) exemplified by Mus m. subspecies Shh. The genetic linkage between S locus and Bf locus was studied with two backcross progenies — [B 10.BR × (B10.BR × Mus m. subspecies Chc)F₁] and [B 10.BR × (B10.BR × Mus m. subspecies Shh)F₁]. Totally, 256 backcross progenies were typed for Bf type and for Ss type (plasma level of the fourth complement protein regulated by S locus). The results indicated that murine Bf was controlled by a single codominant locus located close to the H-2 complex because no mouse showing recombination between Bf locus and S locus was found.     

MHC recognition by clones of Mls specific T-lymphocytes

To test whether M1s determinants, like other non-MHC or nominal antigens, are recognized by T-cells in association with H-2 determinants, the in vitro proliferative responses of T-cell lines and clones were studied. Lines and clones were prepared by soft agar cloning (B10.BR x BALB/c)F₁ (H-2^k/H-2^d, M1s^b/M1s^b) T-cells responding in a primary MLR to AKD2F1 (H-2^k/H-2^d, M1s^a/M1s^a) stimulator cells. All the T-cell clones obtained could respond equally well in a proliferative assay to the Mls^a determinant in association with the H-2 haplotype of either parent, i. e., DBA/2 (H-2^d, M1s^a), and AKR (H-2^k, M1s^a) both stimulated equally well. When the T-cell lines and clones were screened against stimulators from recombinant inbred (RI) strains, it became apparent that strains exhibiting the H-2^b, M1s^a genotype stimulated poorly or not at all. This shows that the T-cell response to M1s^a involves MHC recognition, and raises the possibility that the response to M1s^a can involve recognition of H-2 specificities shared between the H-2 ^k and H-2 ^d haplotypes.Abbreviations used in this paper MHC major histocompatibility complex - MLC mixed lymphocyte culture - IL-2 interleukin 2 - Con A concanavalin A - RI recombinant inbred Howard Hughes Medical Institute     

Immunological properties of Fc receptor on lymphocytes. 6. Characterization of suppressive B-cell factor (SBF) released from Fc receptor-bearing B cells.

EA, i.e., antigen-antibody complexes are able to induce an antigen-nonspecific suppressive factor(s) from FcR⁺ B cells by binding on FcR. This factor, termed “suppressive B-cell factor (SBF)” was only effective on H-2 compatible, but not on H-2 incompatible spleen cells in an adoptive cell transfer system. Furthermore, SBF, prepared from B10.A (H-2^a) splenic FcR⁺ B cells, suppressed the adoptive primary response of B10.D2 mice (H-2^d), in addition to A/J mice (H-2^a) against DNP-DE, by the pretreatment of cells with SBF in vitro. Absorption with affinity columns demonstrated that active components) of SBF from C3H/He mice (H-2^k) was eliminated by both B6 anti-CBA (H-2^b anti-H-2^k) and B10.D2 anti-B10.BR (H-2^d anti-H-2^k), but not B10 anti-B10.A (H-2^b anti-H-2^a). In contrast, the suppressive activity of SBF was eliminated neither by anti-mouse Ig nor by a heat-aggregated human γ-globulin column. These results indicate that SBF contains a product coded by the right-hand side of H-2 gene complex, but does not contain Ig determinants nor FcR. Thus, it is conceivable that a compatibility of the right-hand side of H-2 gene complex is required for inducing effective suppression of spleen cells by SBF. SBF was considered to be a trypsin-resistant and heat-labile substance with a molecular weight of 30,000–63,000. The target cells for SBF were FcR^? B precursors, but not helper T cells.     

Sex-dependent effects of non-H-2 loci on lethal GVH reaction induced across an H-2 barrier

We have studied the influence of DBA/2 non-H-2 antigens on the lethal graft-versus-host reaction (GVHR) developed across an H-2 barrier. (DBA/2 x B10.D2)F₁ x B10.D2 (H-2 ^d) backcross (BC) mice were typed for their allelic constitution at nine genetically independent chromosome markers and used as individual cell donors simultaneously for two to three (DBA/2 X B10.D2)F₁ recipients incompatible for DBA/2 non-H-2 antigens alone and two to three (DBA/2 x B10.BR)F₁ recipients incompatible for DBA/2 non-H-2 antigens and H-2^k. The results showed that, when compared with that developed in a control group incompatible for H-2 ^kalone [B10.D2(B10.D2xB10.BR)F₁], the GVHR mortality seen in the presence of an additional incompatibility for DBA/2 non-H-2 antigens [(DBA/2 X B10.BR)F₁recipients] is significantly delayed but only in female mice. An analysis of individual BC donors indicated that this protective effect of DBA/2 non-H-2 antigens correlates with incompatibility for gene(s) linked to the Pgm-1 chromosome marker. In contrast, incompatibility for gene(s) linked to Mod-1 and Es-3 markers accelerates GVHR mortality, but only in male mice. Finally, the results obtained with (DBA/2 x B10.D2)F₁ and (DBA/2 x B10.BR)F₁ recipients were compared; they showed that the intensity of the GVHR developed by cells from individual BC donors against a given set of DBA/2 non-H-2 antigens correlates well with that developed by the same BC donor against the same set of non-H-2 antigens plus H-2^k. We conclude that certain non-H-2 genes (and antigens) can modulate the intensity of the GVHR developed across an H-2 barrier. The number of such genes is probably great; their effects are strong and complex, and can be sex-dependent.     

Glucocorticoid-Induced Cleft Palate in the Mouse: Two Major Histocompatibility Complex, H-2, Loci with Different Mechanisms

Isolated cleft palate is induced in the progeny of pregnant mice that are given glucocorticoids. The incidence varies among inbred strains and with dose and stage of gestation when the drug is given. One chromosomal region responsible for strain-associated differences in sensitivity is the major histocompatibility complex, H-2. H-2^a is associated with susceptibility, H-2^b with resistance. There appear to be both maternal and embryonic genetic factors affecting the sensitivity to glucocorticoids. In experiments reported here congenic strains of mice with H-2^a, H-2^d and H-2^k haplotypes on a C57BL/10 genomic background were used. This allowed the determination of the effect on sensitivity by two H-2 subregions; the subregions are H-2K to I-E and I-C to H-2D. Methods included dose-response analysis and reciprocal cross analysis using dexamethasone given on day 12 of pregnancy. Results show that each subregion affects the strain's sensitivity to dexamethasone-induced cleft palate. The regression coefficients for B10.A-H-2^a (45.4 ± 4.13) were different from those for B10.BR-H-2^k (67.2 ± 10.8) and B10.D2-H-2^d (70.5 ± 9.74). The estimated mean arcsine% cleft palate at 160 mg/kg was different for each strain: B10.A- H-2^a, 53.1 ± 2.19; B10.BR-H-2^k, 33.1 ± 2.27; B10.D2-H-2^d, 25.0 ± 2.75. Different patterns of change in sensitivity were observed among the reciprocal crosses. In summary, the H-2K to I-E subregion seemed to influence both maternal and embryonic factors, whereas only embryonic factors were influenced by the I-C to H-2D subregion. These data suggest that the mechanisms affecting glucocorticoid sensitivity which are genetically encoded within each H-2 subregion are different, and there is an interaction between the alleles. The mode of interaction can be either complementation or epistasis.     

Tumour-induced altered gastrointestinal steady-states: absence of MHC restriction in the paraneoplastic gastrointestine

Abstract The growth of a number of experimental rodent tumours including the Lewis lung tumour (LLca) progressively compromises the integrity of the host's gastrointestine by inducing cytokinetic alterations in the small bowel resembling those generally defining the intestinal phase of a graft-versus-host reaction (GVHR). To determine whether the induction of this paraneoplastic gastrointestine (PGI) involves, similar to a GVHR, a disparity between the MHC of the donor (LLca tumour) and the recipient (host), PGI development was evaluated in various LLca tumour-bearing murine strains that were either ‘syngeneic’[C57BL/6 and BL/10 (H-2^b)], ‘semisyngeneic’[B6D2F₁ (H-2^bd) and B6C3F₁ (H-2^bk)] or ‘allogeneic’[C3H/HeJ (H-2^k) and DBA/2 (H-2^d)] to the H-2^b LLca tumour. The temporal appearance and magnitude of a PGI developing in either LLca-syngeneic or semi-syngeneic hosts, but not the allogeneic strains, suggested that the mechanism(s) involved in PGI development, like the GVHR, was restricted by the MHC. Subsequent studies using congenic strains [B10.A (H-2^k) and B10.D2/nSn (H-2^d)], however, demonstrated that the mechanism(s) responsible for the PGI was restricted by the non-MHC loci of the C57BL mouse. These observations were supported by the appearance of a LLca-induced PGI in various B10.A congenic strains carrying mutations at the I-A or I-E/I-J loci of the MHC. Not unlike the intestinal phase of a GVHR, development of the PGI required the participation of enhanced mucosal mast cells which were limited in the WCB6F₁ (S1/S1^d) but not the (+/+) murine strains. These observations are discussed in light of the postulated premature migration of immature thymocytes that accompany tumour growth and their ability to non-specifically enhance (or suppress) cell mediated immune reactions in the host.     

Analysis of intrathymic differentiation patterns during the course of AKR leukemogenesis

Thymocytes from AKR mice in different stages of leukemia development were analyzed with the fluorescence-activated cell sorter (FACS) using monoclonal antisera to Lyt-1, Lyt-2, Thy-1.1, H-2K^k, and Ia^k. In addition, the number of cells bearing receptors for peanut agglutinin (PNA) was assessed. The results were correlated with the expression of murine leukemia virus (MuLV) antigen. Thymocytes from late preleukemic and leukemic stages were found to have a phenotype characteristic of a more mature cell population in that there was an increase in the expression of determinants encoded within the K end of H-2^k and Ia^k. This was associated with a decrease in the number of thymocytes bearing receptors for PNA during the leukemic stage. Simultaneously, a shift from a Lyt-1⁺ 2⁺ thymocyte population to cells with varying expressions of Ly antigens was observed. Analysis of Lyt determinants on thymomas indicated that they could arise from cells bearing any of the different possible combinations of Ly phenotypes. The cell surface antigen changes occurred in temporal correlation with an increased expression of MuLV antigens.     

A model for genetic analysis of programmed gene expression as reflected in the development of membrane antigens.

The red blood cell antigen determined in mice by the H-2^b allele was detectable by hemagglutination at birth, H-2^b-early (bE), in strain $\text{C57BL}\text{10}$, whereas that determined by H-2^a not until 3 days later, H-2^a-late (aL), in strain A. Each F₁ individual was both aL and bE. Timing genes segregated in the F₂ and BC₁ generations to give H-2^a-early (aE) and H-2^b-late (bL) in combinations with aL and bE in apparent Mendelian ratios. In some strain combinations in which H-2 alleles and strain background had been interchanged, timing type was transferred along with H-2, whereas in others it was the background which seemed to be more important for the timing type. Moreover, no recombinant types were found in the F₂ and BC₁ generations of these lines. Lines originating from the (B10 × A)F₂ generation were selected for reversed parental-strain-type phenotypes under a full-sib mating regime. True breeding aE or bL lines were not realized until the ninth to eleventh inbreeding generation. We propose a remote-cis-effect model consisting of one temporal gene tightly linked with H-2 and at least two others with special cis and recognition properties linked with each other but not with H-2.