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.     

The role of dendritic cells as stimulators of minor lymphocyte-stimulating locus-specific T cell responses in the mouse. I. Differential capacity of dendritic cells to stimulate minor lymphocyte-stimulating locus-reactive T cell hybridomas and the primary anti-minor lymphocyte-stimulating locus mixed lymphocyte reaction

The response of T cells to minor lymphocyte-stimulating locus (Mls) determinants remains poorly understood with respect to the antigenic determinants responsible for T cell stimulation and the types of APC capable of stimulating the response. In this report, we demonstrate that highly purified dendritic cells (DC) as well as B cells have the capacity to stimulate Mls-specific responses. Unseparated spleen cells, purified DC, resting B cells, and activated B cells were compared for their capacity to stimulate several Mls-reactive T cell hybridomas. Whereas the entire panel of Mls-reactive T cell hybridomas was stimulated strongly by unseparated spleen cells and activated B cells, the hybridomas responded only weakly to purified DC or resting B cells. Activation of resting B cells with either B cell stimulatory factor-1 (1 day pre-treatment) or LPS/dextran (2 or 3 day pre-treatment) greatly augmented their Mls-stimulatory capacity. In contrast, the Mls-stimulatory capacity of DC was not augmented by a 1-day pre-treatment with either B cell stimulatory factor-1 or supernatant from the DC-induced primary anti-Mls-MLR. In the primary anti-Mls-MLR, both purified DC and LPS/dextran-stimulated B blasts were found to elicit vigorous T cell proliferative responses. Much weaker responses were elicited by unseparated spleen cells. The stimulation of the primary anti-Mls-MLR by purified DC was further confirmed by producing Mls-specific T cell clones which were preferentially stimulated by DC. Autologous (Mlsb) DC were found to markedly enhance the primary anti-Mls-MLR response to small numbers of Mlsa B blasts. Thus, DC possess other "accessory cell" properties that augment the primary anti-Mls-MLR despite the predicted low level of Mls determinant expression on DC based on the results obtained with Mls-reactive hybridomas. Possible accessory cell properties of DC relevant to this phenomenon are discussed.     

Genetic determinants of sable and umbrous coat color phenotypes in mice

The dorsal fur in yellow F1 mice (F1-Ay) between C3H/HeJ and C57BL/6J-Ay is darker than that in C57BL/6J-Ay. Moreover, yellow F2 mice (F2-Ay) exhibit a wide spectrum of coat color phenotypes in terms of lightness and darkness. Quantitative trait locus (QTL) analysis on F2-Ay identified three significant modifier loci that accounted for darkening of the coat color on chromosomes 1 (Dmyaq1 and Dmyaq2) and 15 (Dmyaq3), and the C3H/HeJ allele at these loci increased the darkness. Because agouti F2 mice (F2-A) also exhibited a spectrum of coat color phenotypes, the question of whether these QTLs had any effects on F2-A was examined. Dmyaq1 and Dmyaq2 were shown to increase the darkness in F2-A, whereas Dmyaq3 did not. The results showed that Dmyaq1-Dmyaq3 were parts of determinants responsible for the sable (darker modification of yellow) coat color phenotype, and that Dmyaq1 and Dmyaq2 were parts of determinants responsible for the umbrous (darker modification of agouti) coat color phenotype. It is, thus, demonstrated that both the sable and the umbrous phenotypes resulted from multigenic contributions, and that they shared genetic bases, as had been implied for several decades.     

Genetic control of the development of experimental allergic encephalomyelitis in rats. Separation of MHC and non-MHC gene effects

Experimental allergic encephalomyelitis (EAE)-susceptible Lew and EAE-resistant Brown Norway (BN) rats and the corresponding MHC congenic strains were examined for their ability to develop clinical and histologic EAE. The ability of T cells from these animals to proliferate in vitro in response to whole guinea pig (GP) myelin basic protein (MBP), rat MBP, and to the major encephalitogenic peptide of GP MBP 66-88 (GP 68-88) was also assessed. We found that Lewis (Lew) was highly susceptible and showed good T cell responses to GP, MBP, rat MBP, and GP 68-88. Lew.1N (BN MHC on Lew background) and BN were not susceptible and T cells from these strains showed significant responses to GP MBP, but not to rat MBP or GP 68-88. Although BN.B1 (Lew MHC on BN background) was not susceptible to actively induced EAE, MBP-specific Lew T cells could transfer severe disease to BN.B1. BN.B1 T cells showed responses to GP-MBP, rat MBP, and GP 68-88 and, when transferred to naive BN.B1 or Lew, induced only mild clinical EAE in both strains. Increasing the number of T cells from BN.B1 had no effect on the severity of clinical symptoms in either recipient, suggesting some deficiency in the T cell repertoire that is necessary for induction of severe EAE. These results suggest that 1) the T cell response to rat MBP and GP68-88 (but not to sites other than 68-88 in GP MBP) is necessary for susceptibility to EAE; 2) the ability to respond to both rat MBP and GP 68-88 is determined by the MHC gene products on APC; and 3) given a permissive MHC, the T cell response that results in EAE is influenced by non-MHC genes.     

Genetic control of susceptibility to experimental autoimmune uveoretinitis in the mouse model. Concomitant regulation by MHC and non-MHC genes.

Experimental autoimmune uveoretinitis (EAU) in animals is a T cell-mediated autoimmune response directed against cells of the neural retina, in particular the photoreceptors. EAU can be induced in susceptible strains of mice by immunization with purified retinal Ag, and serves as a model for human uveitis. Because strong HLA associations have been noted in a number of human uveitic diseases, we investigated the role of MHC vs non-MHC genes in the control of susceptibility to ocular autoimmunity using the mouse EAU model. Selected strains representing most of the known independent H-2 haplotypes, as well as several H-2-recombinant and congenic strains, were immunized with interphotoreceptor retinoid-binding protein. Ocular pathology was induced in strains of the H-2k haplotype and their I-A-matched congenics, as well as in strains of the H-2r, H-2b, and H-2d haplotypes. In a series of experiments utilizing intra-H-2 recombinant strains, MHC control of susceptibility was tentatively mapped to the I-A subregion of the H-2k. Expression of the I-Ek gene product was not required for susceptibility to EAU, and in fact appeared to have an ameliorating effect on disease. Incidence and severity of disease obtained in strains sharing the same H-2 on a different background, or sharing the same background in the context of a different H-2, indicated that non-MHC genes contribute significantly to the regulation of EAU. Disease expression of susceptible H-2 haplotypes was highest in strains with B10 background (permissive) and ranged from intermediate to absent in strains with other (nonpermissive) backgrounds. The data suggest that although the ability to develop ocular pathology is dependent on the I-A subregion of the H-2, the final expression of disease in susceptible haplotypes is largely determined by background, non-MHC genes.     

Genetic control of the immune response to nuclease. II. Detection of idiotypic determinants by the inhibition of antibody-mediated nuclease inactivation.

The humoral response of mice to staphylococcal nuclease has previously been shown to be controlled genetically by H-2-linked Ir gene(s). In order to examine the possible contributions of variable region immunoglobulin genes to this genetic control, we have developed a system for the detection of idiotypic determinants on anti-nuclease immunoglobulin molecules. Antisera to nuclease were raised in two high responder strains, A/J and SJL. The corresponding antibodies were purified by affinity chromotography on Sepharose-nuclease columns, and were used to immunize groups of Lewis rats. An assay system was developed to assess the inhibition of antibody-mediated inactivation of nuclease activity by the rat antisera thus produced. Despite the presence of many species-specific anti-mouse immunoglobulin antibodies in these sera, inhibition of antibody-mediated enzyme inactivation was found to be specific for anti-nuclease antibodies of the immunizing strain. The inhibition could not be removed by extensive absorption with normal serum proteins from the antibody-producing strain, and was shown to require antibodies directed toward binding sites of the anti-nuclease antibodies. This inhibition thus defines idiotypic determinants of anti-nuclease antibodies.     

In vitro analysis of allogeneic lymphocyte interaction. IV. Dual recognition of B cell-associated Mls locus and I-region determinants by a helper allogeneic effect factor (AEF) generated across a minor H locus disparity.

A helper allogeneic effect factor (AEF) was produced across an incompatibility at the minor histocompatibility loci. This AEF is genetically restricted in its activity since it helps B cells only of the stimulator haplotype and of haplotypes that share both an Mls and I-region identity with the stimulator haplotype. The I-region genes involved here map to the I-A and/or I-C subregions. An anti-LyM immunoadsorbent column but neither an anti-H-2 nor an anti-Ia column absorbed AEF helper activity. It is suggested that the activation of T helper cells by a positive allogeneic effect across a minor H locus difference and their genetically restricted interaction with allogeneic B cells may in part be due to the acquisition by alloactivated T cells of stimulator cell-derived LyM and/or Mls determinants. The data presented indicate that helper T cells recognize Mls locus alloantigens in the milieu of self Ia antigens.     

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.     

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)     

Genetic analysis of plasmid determinants for microcin J25 production and immunity.

Microcin J25 (MccJ25) is a small peptide antibiotic produced by an Escherichia coli strain isolated from human feces. The genetic determinants for MccJ25 synthesis and immunity have been cloned from the low-copy-number wild-type plasmid pTUC1OO into the compatible vectors pBR322 and pACYC184. Physical and phenotypical analysis of insertion mutations and complementation tests defined three contiguous genes involved in MccJ25 production which span a region of about 2.2 kb. Immunity to the antibiotic is provided by an additional gene adjacent to the production region.     

Genetic control of the immune response to the H-2Dk private specificity, H-2.32. II. Genetic linkage analysis of a backcross generation.

B10.AKM mice (H-2M) when immunized with H-2k cells showed very low cytotoxic antibody responses to the H-2Dk private specificity H-2.32, whereas AKR.M and (AKR.M X B10.AKM)F1 mice that possess the same H-2m haplotype mounted reasonable anti-H-2.32 antibody responses. The genetic nature of the non-H-2 linked gene(s) controlling the anti-H-2.32 response was analyzed on the backcross progeny raised between (AKR.M X B10.AKM)F1 and B10.AKM mice. The anti-H-2.32 antibody response was found to be predominantly controlled by a single locus. This locus segregated independently of the Ig heavy chain locus, the Ly2 locus, and the Mls locus. Despite the observed difference in antibody production, no significant differences between AKR.M and B10.AKM mice were detected in induction of H-2Dk-specific killer T cells. Thus, the defect in the response of B10.AKM mice to H-2.32 can be detected at the level of B cell function and is controlled by a single non-H-2-linked genetic locus, but is not attributable to genes linked to the major immunoglobulin structural genes nor to the Mls locus.     

Genetic analysis of ColN plasmid determinants for colicin production, release, and immunity.

Colicin N was identified as the 39,000-molecular-weight protein encoded by the 4,900-base-pair, multiple copy number, amplifiable plasmid ColN -284. Its production was controlled by the SOS regulatory circuit and by catabolite repression. Colicin accumulated intracellularly to ca. 10(6) molecules per cell after growth for 2 to 3 h in medium containing 0.5 microgram of mitomycin C per ml and was then released as the cells underwent partial lysis. Strains carrying pColN -284 and its derivatives exhibited low-level immunity to colicin N and were fully sensitive to all other colicins tested. Regions of the plasmid responsible for colicin N activity (cna), for mitomycin-induced lysis ( cnl ), and for colicin N immunity ( cni ) were localized and characterized by cloning, transposon Tn5 and hydroxylamine mutagenesis, and restriction endonuclease deletion and mapping analysis. The results are discussed in terms of both the organization of the cna, cnl , and cni genes and the respective role of cnl expression and colicin N production in mitomycin sensitivity, colicin export, and induced partial lysis of ColN + cells.     

Genetic analysis of 987P adhesion and fimbriation of Escherichia coli: the fas genes link both phenotypes.

The 987P fimbrial gene cluster has recently been shown to contain eight genes (fasA to fasH) clustered on large plasmids of enterotoxigenic Escherichia coli and adjacent to a Tn1681-like transposon encoding the heat-stable enterotoxin STIa. Different genetic approaches were used to study the relationship between 987P fimbriation and adhesion. TnphoA mutagenesis, complementation assays, and T7 RNA polymerase-promoted gene expression indicated that all of the fas genes were involved in fimbrial expression and adhesion. In contrast to other fimbrial systems, the lack of expression of any single fas gene never resulted in the dissociation of fimbriation and adhesion, indicating that the adhesin is required for fimbrial expression and suggesting that FasA, the fimbrial structural subunit itself, is the adhesin. In addition, fimbrial length was shown to be modulated by the levels of expression of different fas genes.     

Genetic control of lymphocyte antigens in sheep: TheOLA complex and two minor loci

Lymphocytotoxic reagents allowed us to define 11 lymphocyte factors in sheep. After a genetic control of monospecificity had been made, a genetic study based on 400 crossings indicated that nine factors are transmitted in two haplotypes containing 0.1 or 2 factors. The linked factors of the bifactorial haplotypes are the products of two genes at two closely linked loci,OLA- A andOLA- B, having a recombination rate of about 0.6%. The nine factors are the products of fiveOLA- A and fourOLA- B alleles. Allelic frequencies at the two loci, ranging from 0.05 to 0.23 were obtained by two methods. A linkage disequilibrium between the loci is described. Among the possible causes of this, inbreeding is excluded, whereas selective pressure or more probably old fusions between sheep populations must be retained. A tenth factor (frequency 0.33 to 0.35) has a 26% recombination with OLA factors; its locus (OL-X) would be on the same chromosome but very far from theOLA complex. An 11th factor (frequency 0.30) is probably independent ofOLA; its locus (OL-Z) may be on another chromosome. The two linkedOLA loci give evidence of a major histocompatibility complex in sheep; the observed linkage disequilibrium allows one to foretell certain applications in phylogeny and perhaps in selection.     

Activation requirements of cloned inducer T cells. III. Need for two stimulator cells in the response of a cloned line to Mls determinants

To gain insight into the nature of Mls determinants, we examined the stimulator cells responsible for the activation of inducer T cell clones by Mls determinants. Two types of clones responding to Mls determinants were identified. One type responded to purified B cells, but not to splenic adherent cells (SAC), from mice bearing Mls stimulatory determinants. The other type of Mls-reactive T cell clone, including the representative clone Ly1-N5, demonstrated a vigorous response to unfractionated spleen cells, but showed little or no response to B cells alone or to SAC alone from mice bearing the Mlsa or Mlsd stimulatory determinant. The response of these clones to Mls determinants required stimulation by two cell types. The failure of clone Ly1-N5 to respond to Mlsa-bearing B cells was reversed by the addition of SAC taken from mice bearing the Mlsa allele. In addition, SAC from mice bearing the nonstimulatory Mlsb allele could synergize with B cells from Mlsa-bearing animals. B cells were required to provide the Mlsa determinant, because the combination of Mlsa-bearing SAC and Mlsb-bearing B cells did not activate the clone. The response of clone Ly1-N5 to Mls is restricted by Ia determinants (shared by H-2b, H-2d, and H-2k haplotypes but not by the H-2q haplotype). The permissive H-2 alleles can be present either on the stimulator B cell or on the SAC. The optimal response of the clone was obtained by using B cells bearing Mlsa and the permissive Ia epitopes. However, a significant response of the clone to B cells bearing Mlsa but an inappropriate Ia (Iaq) was also seen in the presence of SAC bearing the nonstimulatory Mlsb allele but the permissive Ia epitopes.     

Genetic analysis of SecY: additional export-defective mutations and factors affecting their phenotypes

A number of secY mutants of Escherichia coli showing protein export defects were isolated by a combination of localized mutagenesis and secA-lacZ screening. Most of them were cold sensitive and contained single base substitutions in secY leading to amino acid replacements in various parts of the SecY protein, mainly in the cytoplasmic and the transmembrane domains. A temperature-sensitive mutant with an export defect had the same base substitution as secY24, which was characterized previously. Many cold-sensitive secY mutants exhibited rapid responses to temperature lowering but their apparent defects varied at the permissive temperature. Others exhibited delayed responses to the temperature shift. Some secY mutations, including secY39, interfered with protein export when expressed from a multicopy plasmid, even in the presence of wild-type secY on the chromosome. Such dominant negative mutations, including secY ^–d l, which was studied previously, were all located in either cytoplasmic domain 5 or 6, which is consistent with our previous proposal that the C-terminal region of SecY is important for its function as a protein translocator. We also studied the phenotypes of strains in which one of the secY mutations was combined with the components of the SecD operon. Overexpression of SecD partially suppressed the secY39 mutation, while overexpression of secF exacerbated the export defects of secY122 and secY125 mutations. Overexpression of yajC, located within the SecD operon, suppressed sec Y ^–d1. Although yajC itself proved to be dispensable, its disruption impaired the growth of the secY39 mutant at 42°C. These observations suggest that SecY interacts with SecD, SecF, and the product of yajC.     

Genetic analysis of a phosphatidylinositol 3-kinase SH2 domain reveals determinants of specificity.

Phosphatidylinositol 3-kinase is an important element in both normal and oncogenic signal transduction. Polyomavirus middle T antigen transforms cells in a manner depending on association of its tyrosine 315 phosphorylation site with Src homology 2 (SH2) domains on the p85 subunit of the phosphatidylinositol 3-kinase. Both nonselective and site-directed mutagenesis have been used to probe the interaction of middle T with the N-terminal SH2 domain of p85. Most of the 24 mutants obtained showed reduced middle T binding. However, mutations that showed increased binding were also found. Comparison of middle T binding to that of the platelet-derived growth factor receptor showed that some mutations altered the specificity of recognition by the SH2 domain. Mutations altering S-393, D-394, and P-395 were shown to affect the ability of the SH2 domain to select peptides from a degenerate phosphopeptide library. These results focus attention on the role of the EF loop in the SH2 domain in determining binding selectivity at the third position after the phosphotyrosine.