H-2-linked genes determine the level of the primary in vitro anti-Mls response

The level of cell proliferation and interleukin-2 (IL-2) production observed in an anti-Mls mixed lymphocyte reaction between spleen cells from H-2 compatible, Mls incompatible mouse strains is determined by the H-2 haplotype of the mouse combination. Thus, while AKR (H-2 ^k) spleen cells stimulated strong M1s^a responses in H-2^k responder cells, AKR H-2b spleen cells stimulated no or negligible M1s^a responses in responder cells from H-2 ^bmouse strains. This effect was observed at the levels of IL-2 production and cell proliferation. The magnitude of the response observed using F₁ (H-2 ^k/H-2 ^b) responder cells was found to be a function of stimulator rather than responder cells. The poor stimulatory capacity of AKRH-2 ^bspleen cells was also shown not to be due to the loss of the stimulatory Mls ^aallele during the construction of the congenic strain from AKR and C57BL/6 parental strains. Using stimulator cells from a second series of congenic mice, we found H-2 ^b(strain DLLP) again to represent a poorly Mls^a stimulatory H-2 haplotype. In addition, H-2^q (DBA/1) cells displayed very poor Mls^a stimulatory potential while H-2^d (D1.C) cells were efficient Mls^a stimulators. Again the effect was shown to be at the level of the stimulator cells. In toto, our findings indicate that the H-2 ^kand H-2 ^dhaplotypes encode strong Mls^a stimulatory potential while the H-2 ^band H-2 ^qhaplotypes determine poor Mls^a stimulatory potential in primary in vitro responses, measured as cell proliferation and IL-2 production.Abbreviations used in this paper: CTL cytotoxic T lymphocyte - IL-1 interleukin-1 - IL-2 interleukin-2 - MLR mixed lymphocyte reaction - NMS normal mouse serum     

Studies on non-H-2-linked lymphocyte-activating determinants. IV. Ontogeny of the Mls product on murine B cells.

The minor lymphocyte stimulating (Mls) locus codes for lymphocyte activating determinants (LADs) on murine B lymphocytes, but not T lymphocytes. This observation was strengthened by a series of techniques which allow deletion and addition of T and B cells. These included the use of cytotoxic antisera such as anti-Thy 1.2, anti-MTLA, anti-MBLA, and complement, and the use of a goat anti-μ antisera, and finally the use of a fluorescence activated cell sorter (FACS).The studies in this report document the organ distribution and the ontogenetic appearance of the surface LADs on the surface of B lymphocytes from DBA/2N (H-2^d, Mls^a) and CBA/J (H-2^k, Mls^d) mice. Adult-like ability to stimulate H-2 identical BALB/c (H-2^d, Mls^b) and C3H/He (H-2^k, Mls^c) responder cells appeared at about 4–5 weeks of age. Inability of neonatal cells to induce an Mls-defined MLC was found not to be due to a low frequency of B lymphocytes or to the presence of suppressor cells, but due to the absence of the Mls-coded LADs on their surface. These data support the concept that the Mls-coded LADs are present on adult B lymphocytes and are specific markers of B-cell differentiation, which is preceded by membrane IgM and the δ homologue of human IgD, Ia, and the receptor for the third component of complement.     

The mixed lymphocyte response of senescent mice: sensitivity to alloantigen and cell replication time.

The age-dependent alteration in the proliferative response of C57B1/6J lymph node cells to stimulation by H-2- and M-locus alloantigens was examined in one-way mixed lymphocyte cultures (MLC). Balb/c (H-2^d, Mls^b) and DBA (H-2^d, Mls^a) spleen cells served as stimulating cells differing from C57B1/6J (H-2^b, Mls^b) at the H-2 and H-2 plus Mls loci, respectively. The day of peak response and the ratio of responder to stimulator cells required for optimal stimulation were the same for all the age groups (3 to 29 months) tested, irrespective of the stimulator strain used. Results obtained in MLC under optimal conditions showed a maximal response to both Balb/c and DBA/2 stimulation at the age of 6 months, followed by a gradual decline in the response with age. In order to determine whether the decline with age in mixed lymphocyte reactivity can be attributed to a reduction in the proliferative capacity of the responding lymphocytes of aged mice, cell cycle analyses were performed. Auto-radiographic studies of MLC containing lymphocytes from CS7B1/6J mice aged 6 and 24 months showed no difference in generation time, S, G₂, G₁, and M phases of the cell cycle. In addition, lymphocytes of both age groups underwent two identical mitotic waves within the period of examination. Our results determine that the functional decline with age in proliferative activity in mixed lymphocyte cultures is attributable to a neither decrease in sensitivity to alloantigen nor to a decrease in generation time or the ability to undergo several mitotic divisions, and suggest that such a decline is caused by fewer cells capable of response in old mice.     

Genetic analysis of the presentation of minor lymphocyte-stimulating determinants. II. Differing non-MHC control of super-stimulatory and more poorly stimulatory Mls phenotypes

Analysis of the capacity of splenocytes from non-prototypic Mlsa or Mlsc mouse strains to stimulate allogeneic H-2k-compatible T cells in a primary Mls-defined MLR provided interesting examples of exceptions to the usually stated characterization of Mlsa and Mlsc determinants as highly stimulatory of weakly stimulatory, respectively. Across the Mlsa barrier, MA/My stimulator cells had a significantly reduced capacity to elicit responder proliferation in comparison with prototypic AKR/J or less well studied C58/J, CE/J, or RF/J splenocytes. Across the Mlsc barrier, a gradient of stimulatory ability was observed with RF/J splenocytes being virtually nonstimulatory, prototypic C3H/HeJ splenocytes having an intermediate capacity, and CE/J and C58/J being highly stimulatory presenters of this non-MHC specificity. The differing capacity of each of these H-2k stimulator cells to elicit unprimed responder cell proliferation across an Mlsa or Mlsc difference correlated with the T cell growth factor activity that was secreted into the MLR supernatants. The super stimulatory form of Mlsc was expressed in an autosomal dominant fashion by (Mlsc poorly stimulatory x Mlsc super-stimulatory)F1 animals, (BALB.K x C58/J)F1 or (RF/J x CE/J)F1. The segregation of Mlsc stimulatory ability among first backcross and F2 animals derived from the former F1 was compatible with a single non-MHC gene controlling the expression and presentation of the super-stimulatory form of Mlsc. The regulatory nature of this gene was indicated by the observation that F1 animals generated from the Mlsc nonprototypic and poorly stimulatory BALB/c parental strain were self-tolerant to the super-stimulatory form of Mlsc. The existence of an Mls specificity other than a and c was suggested by positive non-MHC MLR responses in certain responder/stimulator cell combinations of Mls prototypic and nonprototypic mouse strains.     

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     

Genetic analysis of the Mls system. Formal Mls typing of the commonly used inbred strains

In order to elucidate the biological role of minor lymphocyte stimulating (Mls) gene products, we have been investigating the fundamental immunogenetic characteristics of the Mls system. In this report, describe the distribution of stimulatory Mls products, Mls^a and Mls^c, in a panel of laboratory inbred strains based on the response pattern of H-2-compatible naive T-cell populations as well as monospecific Mls^a- or Mls^c-reactive T-cell clones. In addition, the expression of four different T-cell receptor (Tcr) b-V segment Tcrb-V3, –V6, –V8.1, and –V9, which were recently reported to be associated with T-cell recognition of Mls gene products in these strains, was examined. The results indicate that the majority of commonly used laboratory strains including those originally typed as Mls ^aare also expressing Mls^c determinants and that very few independent inbred strains are non-Mls ^c. Moreover, the pattern of Tcrb-V expression in spleen as well as in thymus suggests that the association between Mls expression and clonal deletion of self Mls-reactive T cells appears to be the general rule in inbred strains. Based on these results, implications for the nondetectable Mls-like gene products in other species besides the mouse are discussed.     

Multigene control of Mls c

Festenstein originally described the Mls locus as a single dominant autosomal gene with four alleles which mapped in the 13th linkage group of chromosome 1. We subsequently presented evidence which indicated that the mixed leukocyte reaction stimulatory products of DBA/2 and CBA/J were controlled by two independently segregating Mls loci. Recently, Mls ^d of CBA/J was shown to be composed of Mls ^a of AKR and Mls ^c of C3H. In the present report, classic segregation data is presented which indicates that Mls ^c of C3H is controlled by three independently segregating loci. As defined by stimulatory patterns of numerous cell lines, we postulate the following: either one of the loci is shared with BALB.K, CE, C58, and partially with MA/MyJ, one is shared with CBA/H and CBA/J, and one is shared with BALB.K, CBA/J, and partially with CE; or the groups of shared determinants are controlled by different alleles of unique loci (or locus). In any event, Mls ^c appears to be composed of at least three independently segregating loci; the number of alleles/locus is being investigated. In addition, C3H was stimulated by BALB.K (both were recently postulated to be Mls ^c ); this epitope was shared with CBA/J, CBA/H, AKR/Cum, Ma/MyJ, and C58/J.     

The expression of Mls c determinants on Mls a,Mls b,and Mls x prototypic strains

In the mouse sytem, specific determinants other than major histocompatibility complex (MHC) gene products are capable of inducing strong primary proliferative responses in naive T cells. These determinants are encoded by at least two gene loci designated as minor lymphocyte stimulatory (Mls) loci. In order to elucidate the biological role of the Mls system, an effort has been initiated to clarify the fundamental immunogenetic characteristics of the Mls system. In this report, we describe the unexpected finding that Mls ^c determinants are expressed on splenocytes of strains including those which have been used as prototypic examples of three other Mls types: Mls ^a (DBA/2, DBA/1), Mls ^b , (BALB/c), and Mls ^x (PL/J). The expression of Mls ^c by these strains was demonstrated both by the response patterns of unprimed T cells from MHC-identical inbred or F₁ hybrid strains and by the responses of a panel of Mls-specific T-cell clones. The experimental results reported here also suggest that the expression of Mls determinants may be influenced by multiple other genes, including MHC-linked genes.Abbreviations used in this paper MHC major histocompatibility complex - MLR mixed lymphocyte reaction - Mls minor lymphocyte stimulating locus antigen - MMC mitomycin C - NNT nylon wool nonadherent T cells     

Immune responses in vitro

The Mls locus was originally defined to have four alleles; three controlled products that were detectable in primary mixed leukocyte reactions (MLR), whereas one, b, was described as being null. Recently, other investigators postulated that the Mls locus is nonpolymorphic, being composed of the b null allele and of a singly expressed allele previously thought to be the a and d alleles. We previously reported that products controlled by Mls ^aand Mls ^dwere antigenically distinct and therefore are not controlled by the same allele, and the product of Mls ^bon cells of three different strains was easily detectable by Mls ^aand Mls ^dresponding cells. Thus the b allele is not null. In the present report evidence is presented which indicates that both Mls ^band Mls ^cencoded products were undetectable by MLR when in the presence of Mls ^aor Mls ^d. This was demonstrated by (a) the inability of Mls ^a/Mls ^cand Mls ^a/Mls ^bF₁ cells to stimulate Mls ^aresponding cells and Mls ^d/Mls ^cand Mls ^d/Mls ^bcells to stimulate Mls ^dcells; (b) the positive response of Mls ^a/Mls ^band Mls ^d/Mls ^bF₁-hybrid cells to Mls ^b-encoded products; and (c) the reactivity of Mls ^a/Mls ^cand Mls ^d/Mls ^cF₁ hybrid cells to Mls ^c-encoded determinants.     

Regulation of the in vitro presentation of minor lymphocyte stimulating determinants by major histocompatibility complex-encoded immune response genes

Activation of murine B lymphocytes in a splenocyte stimulator population with affinity-purified goat anti-mouse IgD (G alpha M delta) antibody was previously shown by this laboratory to enhance the presentation of strongly stimulatory major histocompatibility complex (MHC) and minor lymphocyte-stimulating (Mlsa,d) determinants in a primary mixed lymphocyte reaction. In the present study, the G alpha M delta treatment of murine splenocytes was employed to enhance the detection of the weakly stimulatory non-MHC Mlsc determinant in order to study the role the MHC might play as a restricting element for the recognition of these minor antigens in a primary mixed lymphocyte reaction. Indeed, enhanced T cell proliferation to Mlsc determinants presented on G alpha M delta-treated splenocytes was observed when the responder and activated H-2-compatible stimulator cell shared certain MHC haplotypes. High responsiveness was associated with the H-2a,k,j,p haplotypes, intermediate responsiveness was associated with the H-2f,g haplotypes and low responsiveness was associated with the H-2b,s haplotypes. (Low X high responder)F1 T cells preferentially responded to the Mlsc determinants presented on G alpha M delta-treated stimulator cells of the F1 or parental high responder H-2 haplotype. When mitomycin C instead of irradiation was used to inactivate normal (non-IgD-treated) splenocytes, a similar preferential response of T cells to Mlsc determinants presented on stimulator cells of a high responder H-2 haplotype was also observed. The inability of G alpha M delta-treated splenocytes of the low responder haplotype to elicit substantial levels of T cell proliferation across an Mlsc difference could not be attributed to the failure of these stimulator cells to become activated by the anti-Ig antibody. In addition, co-culture experiments could not identify the poor T cell response to Mlsc determinants presented on certain MHC haplotypes as being caused by the induction of nonspecific suppressor cells. Presentation of Mlsc determinants caused by transgene product complementation was detectable in F1 mice derived by crossing one parent that had the Mlsc non-MHC genes and a poorly permissive H-2 haplotype with a parent that expressed a permissive H-2 haplotype but lacked the Mlsc non-MHC genes.(ABSTRACT TRUNCATED AT 400 WORDS)     

Multi-gene/allele control of Mls b of CBA/H

Festenstein originally described the Mls locus as a single dominant autosomal gene with four alleles which mapped in the 13th linkage group of chromosome 1. We subsequently presented evidence indicating that the mixed leukocyte reaction (MLR) stimulatory products of DBA/2 and CBA/J were controlled by two independently segregating Mls loci and that Mls of C3H was in fact a composite of three independently segregating loci. Recently, Mls ^d of CBA/J was shown to be composed of Mls ^a of AKR and a product on C3H, which was presumed to be Mls ^c . Based on strain distributions, this product cannot be encoded by the Mls ^c originally defined by Festenstein. In the present report, three Mls specificities of CBA/H (Mls ^b ) are defined. Based on the strain distribution, we postulate that these specificities are controlled by three loci, three alleles/locus, or by some combination of the preceding two possibilities.     

NK gene complex and chromosome 19 loci enhance MHC resistance to murine cytomegalovirus infection

An H-2^k MHC locus is critical for murine cytomegalovirus (MCMV) resistance in MA/My mice and virus control is abolished if H-2^k is replaced with H-2^b MHC genes from MCMV-susceptible C57L mice. Yet, H-2^k resistance varies with genetic background; thus, modifiers of virus resistance must exist. To identify non-MHC resistance loci, spleen and liver MCMV levels and genome-wide genotypes were assessed in (C57L × MA/My) and (MA/My × C57L) F₂ offspring (representing 550 meioses). Significantly, a non-Mendelian frequency of MHC genotypes was observed for offspring of the latter cross. Quantitative trait loci (QTL) and their interaction potential in MCMV resistance were assessed in R/qtl; QTL on chromosomes 17, 6, and 19 affected MCMV levels in infected animals. A chromosome 6 QTL was linked with the NK gene complex and acted in an additive fashion with an H-2^k MHC QTL to mitigate spleen MCMV levels. We provide biological confirmation that this chromosome 6 QTL provided MCMV control independent of H-2^k via NK cells. Importantly, both chromosome 6 and 19 QTLs contribute to virus control independent of H-2^k. Altogether, MHC and non-MHC MCMV-resistance QTL contribute in early resistance to MCMV infection in this genetic system.     

Differential responsiveness to MIs locus antigens in graft-versus-host and host-versus-graft reactions

After (semi)allogeneic transplantation of lymphoid cells into lethally irradiated mice, the development of anti-host directed T effector cells can be demonstrated by means of a simple delayed-type hypersensitivity (DTH) assay. Using this assay we have shown that in H-2 compatible combinations Mls locus antigens can induce the generation of such T effector cells during a graft-versus-host (GvH) reaction. Other non-H-2 alloantigens are probably of minor importance. The capacity of Mls locus antigens to induce distinct anti-host DTH reactivity correlated with the capacity to induce a one-way mixed lymphocyte culture (MLC) response. Mls^a and Mls^c locus antigens initiated a positive MLC response as well as distinct GvH-related DTH reactivity. On the other hand, in the combination DBA/2 versus (BALB/c × DBA/2) F₁, the Mls^b locus antigen was not able to initiate in vitro proliferation, a lack of response which coincided with a marginal and short-lasting GvH-related DTH reactivity. In contrast, the host-versus-graft (HvG) DTH reaction of BALB/c and DBA/2 mice to subcutaneously injected (BALB/c × DBA/2) F₁ spleen cells was equally strong. Here antigens other than those coded for by the Mls locus were mainly responsible for the antigraft DTH response. These results suggest that T effector cells generated in GvH and HvG reactions are specific for largely different sets of minor histocompatibility antigens, with a selective stimulation by Mls locus antigens under GvH conditions.     

Cellular interactions in lymphocyte proliferation: effect of syngeneic and xenogeneic macrophages.

Secondary cell-mediated responses to ectromelia virus infection were studied using an in vitro system. Lymphoid “responder” cells from mice which had recovered from intravenous primary infection at various times prior to sacrifice, were cultured with syngeneic, virus-infected macrophages or spleen cells as “stimulator” cells at 39 °C, a temperature which prevented the virus from exerting cytopathic effects against responder cells. This restrictive temperature and medium with 2-mercaptoethanol at 10^?4M often gave viable cell yields of more than 100% of the original responder cells over 4 days of culture. Preliminary experiments showed that spleen cells from primed mice, cultured with syngeneic, infected spleen cells from normal mice gave the most powerful secondary cytotoxic cell responses as measured by ⁵¹Cr release from virusinfected H-2-compatible target cells. The cytotoxic cells were sensitive to anti-θ and complement treatment and lysed H-2-compatible, virus-infected target cells much more efficiently than infected, allogeneic target cells, thus indicating that they were T cells. Some activity against uninfected H-2-compatible target cells was also generated, but this was largely independent of the presence of virus-induced antigen, (i.e. infected stimulator cells were unnecessary) and therefore seemed to be a consequence of the cultural conditions. Cold target competition showed that this activity was the responsibility of a T cell subset separate from the virus-specific cytotoxic T cells. The peak of cytotoxic activity against virus-infected targets occurred at 4 days of culture and DNA synthesis was maximal on day 3. The concentration of cytotoxic T cells at the peak was eight-fold higher than at the peak of the splenic primary response in vivo, Memory T cells (precursors of secondary cytotoxic T cells) appeared in spleen within 12–14 days of primary infection in vivo, reached a plateau at 5–6 weeks and persisted for at least 16 months. Spleen cells appeared partly refractory to secondary stimulation in vitro at 8–10 days post-priming. This did not seem to be due to cellular migration from spleen to lymph nodes or peritoneal cavity, but its cause was not determined. Primary responses in vitro were not detectable under conditions optimal for secondary responses, thus suggesting a major quantitative, or qualitative difference between virgin and memory T cells.     

Requirement for the location of both appropriate and irrelevant H-2 antigens on the same stimulator cell for unspecific DNA-synthesis inhibition by the H-2-antigen-primed,specific suppressor T cells

Specific suppressor T cells (SSTC), primed in vivo with H-2 antigens, have been shown previously to inhibit DNA synthesis in the one-way, three-cell mixed lymphocyte reaction (MLR) provided that (a) the stimulator cells bear the priming H-2 antigens, and (b) the responder cells possessIC+S regions homologous to those of the SSTC. Anti-B10.A BlO.A(2R) SSTC (anti-D^d) and anti-A.AL A.TL SSTC (anti-K^k) are shown here to be able to inhibit the DNA synthesis triggered in MLR, not only by the corresponding antigens, D^d and K^k, respectively, but also by irrelevant, third-party H-2 and Mls products provided that the corresponding and third-party antigens are presented on the same stimulator cell. If stimulatorH-2 regions, whose products interact with SSTC and responders, are located on different stimulator cells within the particular MLR, SSTC activity is not elicited. Participation of cytotoxic T lymphocytes in DNA-synthesis suppression is ruled out. Direct contact or location of the inhibited responder cell very close to SSTC is considered to be required for the development of SSTC activity.     

The Mlsd-defined primary mixed lymphocyte reaction: a composite response to Mlsa and Mlsc determinants

Considerable disagreement exists among immunologists regarding the polymorphic nature of the murine Mls system. An estimate of the capacity of a given putative Mls allelic gene product expressed on a stimulator population to elicit proliferation of H-2-compatible Mls-disparate unprimed T cells may vary widely among different groups of investigators. This laboratory has shown previously that preactivation of B lymphocytes in a splenocyte stimulator population by exposure to goat anti-mouse IgD (GaMD) before irradiation dramatically enhanced the in vitro presentation not only of the strongly stimulatory (and highly cross-reactive) Mlsa and Mlsd, but also the more poorly stimulatory Mlsc specificity. Therefore, by the use of GaMD-treated splenocytes that optimally present the various Mls non-H-2 stimulatory epitopes, we attempted in this study to obtain a clearer understanding of Mls polymorphism by re-examining the conflicting claims associated with the mixed lymphocyte reaction (MLR) stimulatory capacity of different Mls specificities. Among H-2k responder cells of the Mls null, Mlsa, Mlsb, or Mlsd genotypes, only T cells from Mlsd-bearing CBA/J mice did not respond to Mlsc determinants present on GaMD-treated C3H/HeJ stimulator cells. Crossing CBA/J with an Mlsc-responsive mouse strain yielded an F1 animal in which nonresponsiveness to Mlsc was dominant. Although Mlsa (AKR/J) and Mlsc (C3H/HeJ) parental T cells both proliferated vigorously to Mlsd (CBA/J) stimulator cells, the Mlsa/c (AKR X C3H)F1 T cells responded poorly to GaMD-treated Mlsd stimulator cells. In addition, Mlsd (CBA/J) T cells were nonresponsive to Mlsa (AKR/J), Mlsc (C3H/HeJ), and Mlsa/c (AKR X C3H)F1 GaMD-treated stimulator cells. Because Mlsa (AKR/J) and Mlsc (C3H/HeJ) specificities are mutually stimulatory, at least limited polymorphism must exist in the Mls system. However, because Mlsa/c (AKR X C3H) and Mlsd (CBA/J) specificities are mutually nonstimulatory, T cell proliferation in an Mlsd-defined primary MLR is most likely due to a composite response to Mlsa and Mlsc epitopes present on CBA/J stimulator cells.     

Soluble Mlsa antigens: Stimulatory effect in vitro versus suppressive effect in vivo

Using a pair of congenic strains of mice differing only at the Mls haplotype (Mls locus and closely linked genes), BALB/c (Mls ^b ) and BALB.D2-Mls ^a , we have compared the in vitro proliferative responses of M1s^b lymphocytes to M1s^a antigens presented on either lymph node cells (LNC) or peritoneal adherent cells (PAC). Results showed that M1s^a-PAC are stronger stimulators than M1s^a-LNC, and furthermore, that the supernatant from M1s^a-PAC may be effective in eliciting a lymphocyte proliferative response. The proliferation in response to PAC supernatant is partially due to activation by nonspecific factor(s); however, the response in the presence of M1s^a incompatible PAC supernatant is about three times greater than the response obtained in the presence of syngeneic M1s^b-PAC supernatant, suggesting an additional stimulation by soluble M1s^a antigens. Contrasting with the ability of PAC-supernatant to stimulate a primary proliferative response in vitro, the in vivo immunization of Mls^b mice with M1s^a-PAC supernatant abrogates the specific proliferative response in subsequent one-way mixed lymphocyte cultures. This abrogation of the specific response is comparable to that observed after immunization with intact M1s^a peritoneal or spleen cells, although in the latter case the anti-H-2 proliferative response is also decreased, regardless of whether the H-2 incompatible stimulating cells express an additional incompatibility for M1s^a. The proliferation of untreated, but not of M1s^a-immunized BALB/c LNC, is stronger in cultures with DBA/2 stimulating cells (incompatible for M1s^a and other non-H-2 antigens) than in cultures with BALBM-Mls ^a cells (incompatible for M1s^a alone), and is comparable in intensity to that activated by H-2 incompatibility. We conclude that M1s^a antigens are more efficiently recognized by unprimed helper T cells when presented on PAC than when presented on LNC. In the primary proliferative response, the effects of M1s^a and other non-H-2 antigens may be cumulative. In vivo immunization against M1s^a antigens results in suppression of the specific proliferative response and, to a certain extent, of the nonspecific proliferative response (directed against both H-2 and other non-H-2 antigens). Since M1s^a antigens are obtainable in soluble form, their physicochemical purification can now be envisaged.     

Control of the antibody response of C57BL/6 Lyt-congenic strains to the Lyt-3.1 alloantigen by a gene linked to theLyt-2 locus

Congenic anti-Lyt-3.1 sera have recently been produced by immunizing B6-Lyt-2^a mice with thymocytes from either B6-Lyt-2^a, Lyt-3^a or B6-Lyt-2^a, Lyt-3^a, H-2^k mice (Boos et al. 1978). Surprisingly, mice of the congenic strain B6 failed to produce either anti-Lyt-2.1 or anti-Lyt-3.1 cytotoxic antibodies after identical immunizations. To determine the genetic basis for the difference in response to Lyt-3.1, (B6 × B6-Lyt-2^a)F_a mice and progeny of the backcross, (B6 × B6-Lyt-2^a)F₁ × B6-Lyt-2^a, were immunized with B6-Lyt-2^a, Lyt-3^a, H-2^k thymocytes. In addition, thymic biopsies of backcross progeny were performed and thymocytes tested for the Lyt-2.2 antigenic specificity. Results indicate that gene(s) governing the immune response to Lyt-3.1 is (are) linked to theLyt-2 locus, and that the responder allele (linked toLyt-2 ^a ) shows very poor penetrance in Lyt-2^a/Lyt-2^b mice.     

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.     

Analysis of T-T lymphocytes and T-accessory cell interactions using cloned T cells: MHC I restricted cloned T cells activate MHC II restricted T helper cells

We evaluated the role of molecules of the major histocompatibility complex (MHC) involved in the cellular interactions of two T-cell clones by testing the effect of monoclonal antibodies on the responses of the clones in vitro. The two T-cell clones used in the study are specific for minor histocompatibility antigens and restricted to the H-2K^k. In the absence of exogenous IL-2 the clones require the presence of Ia⁺, Thy-1⁻ accessory cells and of Thy-1⁺, Lyt-1⁺2⁻ cells in the irradiated spleen cell suspension used as stimulator. It is also necessary that both the accessory cells and the T cells in the stimulator cell populations are recognized specifically by the clones. Monoclonal antibodies specific for the H-2K product inhibited the lytic effector function of the cytolytic clone. These antibodies when added to cultures of stimulator cells and clones inhibited also the proliferation of this clone and of a nonlytic clone. When antigen recognition was measured by the increase in sensitivity of the clones to IL-2 while confronted with uv-irradiated stimulator cells, both clones were blocked efficiently by anti-H-2K antibodies. Thus, these results suggest that the interaction of monoclonal antibodies with the restricting H-2K molecule is sufficient to block the recognition signal, a prerequisite for proliferation. In contrast, monoclonal antibodies specific for A_αA_β and/or E_αE_β had no effect on cytolysis or on restricted recognition. However, they inhibited the proliferative responses as efficiently as the H-2K specific antibodies. Inhibition by class II-specific antibodies was not abolished when stimulator cell populations were depleted of Lyt-2⁺ cells. The blocking effect, however, was reversed by the addition of IL-2. No inhibition was obtained with antibody specific for E_αE_β when B10.A(4R) spleen cells, which do not express E_αE_β, or when B10.A(4R) accessory cells, which were reconstituted with (BALB/c X B10.A(4R)) F1 T cells, were used as stimulators. Stimulator cells heterozygous for H-2 could be inhibited by antibodies to the parental haplotype not encoded in the clones (H-2K^d). These and previous results suggest that H-2K-restricted minor histocompatibility antigen-specific recognition transmits an activating signal to the clones and to the stimulator cells. The clones probably are induced to express more IL-2 receptors. The stimulator T cells seem to interact through A_αA_β and E_αE_β molecules with syngeneic accessory cells. This interaction results in IL-2 production by the stimulator T cells and thus in the proliferation of the clones.