Mechanisms of genetic control of immune responses

We examined multiple genetically regulated Immoral and cell-mediated immune (CMI) responses to poly(glu⁶⁰ala³⁰tyr¹⁰) (GAT) using a panel of mouse strains. We show that assignment of responder/nonresponder status depends upon the assay method. In addition, two distinct categories of nonresponder mice were found: (1) those which are unresponsive by all parameters tested (H-2 ^q and H-2 ^s haplotypes) and (2) those which are partially nonresponsive [H-2 ^bm12 mutant strain—a low/nonresponder by splenic plaque-forming cell (PFC) and delayed-type hypersensitivity (DTH) responses, but exhibits B6 parental levels of high GAT-specific T-cell proliferation (Tprlf) and interleukin-2 production]. The distinction between these two nonresponder types was confirmed by complementation tests in which significant GAT-specific PFC and DTH responses were seen in (H-2 ^q × H-2 ^bm12)F₁ hybrids, but not in (H-2 ^q × H-2 ^s )F₁ hybrids. Suppressor T cells (Ts) also play a selective role in nonresponsiveness to GAT. Cyclophosphamide treatment of nonresponders (to eliminate Ts activity) as well as immunization with GAT coupled to the immunogenic carrier MBSA result in the development of GAT-specific humoral, but not CMI responses. Our results indicate that the T cell is the cellular site of Ir gene expression and that Tprlf responses do not correlate with functional helper T-cell activity and suggest distinct, multi-step Th/Ts regulatory pathways in the development of humoral and CMI effector functions.     

Genetic control of immune responses in chickens

The immune response of inbred lines of chickens to the terpolymer poly(glu⁶⁰ala³⁰tyr¹⁰) and copolymer poly(glu⁶⁰ala⁴⁰) was determined. Of six lines immunized, one (line 7) contained birds that either did not respond or were low responders to two injections of 1 mg each of the polymers in Freund's complete adjuvant. As indicated by radioimmunoelectrophoresis, low responders produced a 7S response, although the switch from 17S (high molecular weight immunoglobulin) to 7S antibody production was slower than in high-responder lines. Analysis of the distribution of responders and nonresponders in F₂ generations produced byinter se mating of F₁ hybrids of line 7 with high-responder lines, showed that immune responses were clearly determined by certain alloalleles of theB blood group locus, the major histocompatibility system in the chicken.     

CD39 and control of cellular immune responses

CD39 is the cell surface-located prototypic member of the ecto-nucleoside triphosphate diphosphohydrolase (E-NTPDase) family. Biological actions of CD39 are a consequence (at least in part) of the regulated phosphohydrolytic activity on extracellular nucleotides. This ecto-enzymatic cascade in tandem with CD73 (ecto-5–nucleotidase) also generates adenosine and has major effects on both P2 and adenosine receptor signalling. Despite the early recognition of CD39 as a B lymphocyte activation marker, little is known of the role of CD39 in humoral or cellular immune responses. There is preliminary evidence to suggest that CD39 may impact upon antibody affinity maturation. Pericellular nucleotide/nucleoside fluxes caused by dendritic cell expressed CD39 are also involved in the recruitment, activation and polarization of naïve T cells. We have recently explored the patterns of CD39 expression and the functional role of this ecto-nucleotidase within quiescent and activated T cell subsets. Our data indicate that CD39, together with CD73, efficiently distinguishes T regulatory cells (Treg) from other resting or activated T cells in mice (and humans). Furthermore, CD39 serves as an integral component of the suppressive machinery of Treg, acting, at least in part, through the modulation of pericellular levels of adenosine. We have also shown that the coordinated regulation of CD39/CD73 expression and of the adenosine receptor A2A activates an immunoinhibitory loop that differentially regulates Th1 and Th2 responses. The in vivo relevance of this network is manifest in the phenotype of Cd39-null mice that spontaneously develop features of autoimmune diseases associated with Th1 immune deviation. These data indicate the potential of CD39 and modulated purinergic signalling in the co-ordination of immunoregulatory functions of dendritic and Treg cells. Our findings also suggest novel therapeutic strategies for immune-mediated diseases.     

Mouse genetic background influences severity of immune responses following trauma-hemorrhage

Studies have shown that following bacterial infection or endotoxin administration, immune functions are regulated differently in mice of different genetic background. Since the susceptibility to sepsis following trauma-hemorrhage is dependant on the severity of injury, it is important to determine whether genetic background of the animal influence immune functions after trauma-hemorrhage. The aim of our studies, therefore, was to assess differences in the immune functions in genetically different strains of age-matched C3H/HeN and C57BL/6 male mice following trauma-hemorrhage. The analysis for immune functions included: proliferation of splenocyte and bone-marrow cells, IL-2 and IFN-gamma release by splenocytes, and TNF-alpha and IL-10 release by splenic, peritoneal, liver (Kupffer cell), and bone-marrow macrophages. The results show significant differences in splenocyte and bone-marrow functions, and in the release of the mediators of immune function by immune competent cells: (a) between the two genetic strains, and (b) in each mouse strain following trauma-hemorrhage. Thus, genetic background appears to significantly influence the severity of immune responses in males following trauma-hemorrhage.     

Sex-dependent genetic effects on immune responses to a parasitic nematode

Background

Many disease aetiologies have sex specific effects, which have important implications for disease management. It is now becoming increasingly evident that such effects are the result of the differential expression of autosomal genes rather than sex-specific genes. Such sex-specific variation in the response to Trichuris muris, a murine parasitic nematode infection and model for the human parasitic nematode T. trichiura, has been well documented, however, the underlying genetic causes of these differences have been largely neglected. We used the BXD mouse set of recombinant inbred strains to identify sex-specific loci that contribute to immune phenotypes in T. muris infection.

Results

Response phenotypes to T. muris infection were found to be highly variable between different lines of BXD mice. A significant QTL on chromosome 5 (TM5) associated with IFN-γ production was found in male mice but not in female mice. This QTL was in the same location as a suggestive QTL for TNF-α and IL-6 production in male mice suggesting a common control of these pro-inflammatory cytokines. A second QTL was identified on chromosome 4 (TM4) affecting worm burden in both male and female cohorts. We have identified several genes as potential candidates for modifying responses to T. muris infection.

Conclusions

We have used the largest mammalian genetic model system, the BXD mouse population, to identify candidate genes with sex-specific effects in immune responses to T. muris infection. Some of these genes may be differentially expressed in male and female mice leading to the difference in immune response between the sexes reported in previous studies. Our study further highlights the importance of considering sex as an important factor in investigations of immune response at the genome-wide level, in particular the bias that can be introduced when generalizing results obtained from only one sex or a mixed sex population. Rather, analyses of interaction effects between sex and genotype should be part of future studies.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-193) contains supplementary material, which is available to authorized users.     

Function of macrophages in genetic control of immune responsiveness.

Macrophages serve an essential but poorly understood role in the cellular and molecular events that underlie immune competence. Antigenic proteins are now known to bind initially to macrophages prior to their recognition by T lymphocytes. Antigen uptake by macrophages is a metabolism-dependent event that results in an association of the antigen or a fragment thereof with a product of genes linked to the major histocompatibility complex of the species. For recognition of this associative form of antigen and self to result in cell proliferation, a direct physical interaction of antigen-bearing macrophage and lumphocyte must occur. Soluble forms of the altered antigen complexed to self may, however, function in nonproliferative T cell activation phenomenon. Using antigens of defined structure, it is possible to derive data which indicate that genetic control of immune responsiveness resides at the level of the antigen-presenting cell, thus indicating that these latter cells have profound discriminatory influences on host immune competence.     

Genetic control of murine immune responses to larval Dirofilaria immitis

Previous studies have demonstrated that BALB/c mice, immunized against infection with Dirofilaria immitis, were capable of killing a significant percentage of challenge larvae found within diffusion chambers. The percentage of larvae killed by immunized mice was, however, less than in immunized dogs and unlike immunized dogs, mice were unable to retard the development of the surviving larvae. The objective of the present study was to test 3 inbred strains of mice to determine whether a higher level of protective immunity would develop in these hosts and if larval growth retardation would occur. DBA/2J and C57BL/6J mice and their F1 hybrids B6D2F1/J were used in these studies; it was determined that there were differences in susceptibility among the 3 strains but no difference in ability to eliminate larvae from challenge infections. Growth retardation was seen in larvae recovered from immunized DBA/2J and C57BL/6J mice but not in B6D2F1/J. No difference was noted between immune and control mice in the cell types found in the diffusion chambers. The predominant cell types seen were mononuclear macrophages, multinucleate syncytial cells, and neutrophils. Antibody responses to soluble third- and fourth-stage larval antigens and larval excretory/secretory antigens were measured. Although antibodies to all 3 antigen groups were found in higher concentrations in immunized mice than in their respective controls, only antibody responses to soluble L-3 antigens provided a clear correlation with protective immunity.     

Glucose 6-phosphatase deficiency: Mechanisms of genetic control and biochemistry

Mechanisms are discussed by which several radiation-induced lethal mutations in the mouse control enzyme activity and morphogenesis. These mutations behave as alleles at the albino locus in chromosome I; furthermore, all of them suppress glucose 6-phosphatase activity, resulting in perinatal death of albino homozygotes. Additional pleiotropic effects, and the absence of a dosage effect in heterozygotes, are not easily explained by a mutational change in the structural gene for glucose 6-phosphatase. The mutations might affect membrane proteins and thus render membrane structure abnormal; such membranes may lack the ability to bind tyrosinase as well as glucose 6-phosphatase and may also be responsible for morphogenetic abnormalities.This paper was presented at a symposium entitled Genetic Control of Mammalian Metabolism held at The Jackson Laboratory, Bar Harbor, Maine, June 30–July 2, 1969. The symposium was supported in part by an allocation from NIH General Research Support Grant FR 05545 from the Division of Research Resources to The Jackson Laboratory.Studies discussed in this paper were supported by grants from the National Institute of Health (GM 00110, HD 00193, and AM 11448) and the American Cancer Society (E-79).     

The genetic control of the immune response to murine histocompatibility antigens

The genetic control of the immune response to H-4 histocompatibility alloantigens is described. The rejection of H-4.2-incompatible skin grafts is regulated by anH-2-linkedIr gene. Fast responsiveness is determined by a dominant allele at theIrH-4.2 locus. TheH-2 ^b ,H-2 ^d , andH-2 ^s haplotypes share the fast response allele;H-2 ^a has the slow response allele. Through the use of intra-H-2 recombinants, we have mapped theIrH-4.2 locus to theI-B subregion of theH-2 complex; theH-2 ^h4 ,H-2 ¹⁵, andH-2 ^t4 haplotypes are fast responder haplotypes. These observations suggest that the strength of non-H-2 histocompatibility antigens is ultimately determined by the antigen-specific recipient responsiveness.     

Interethnic differences in the genetic control of the human immune status

Most parameters of the immune status were found to depend on the HLA-antigens determined in the phenotypes of the human subjects under study. The findings suggest a HLA-transmitted genetic regulation of immune response. Various HLA-markers related to certain parameters of the immune status, were determined. These markers seem to be unique and different for each examined population.     

Mechanisms of testicular immune privilege

The testis exhibits a distinctive form of immune privilege to protect the germ cells from the host immune attack. The property of testicular immune privilege was originally attributed to the blood-testis barrier in the seminiferous epithelium, which sequesters antigens. Recent studies have uncovered several levels of immune control besides the blood-testis barrier involved in the privilege of the testis, including the mechanisms of immune tolerance, reduced immune activation, localized active immunosuppression and antigen-specific immunoregulation. The somatic cells of the testis, especially Sertoli cells, play a key role in regulating the testicular immune privileged status. The constitutive expression of anti-inflammatory factors in the testis by somatic cells is essential for local immunosuppression. Growing evidence shows that androgens orchestrate the inhibition of proinflammatory factors and shift cytokine balance toward a tolerogenic environment. Disruption of these protective mechanisms, which may be caused by trauma, infection and genetic factors, can lead to orchitis and infertility. This review article highlights the unique immune environment of the testis, particularly focuses on the regulation of testicular immune privilege.     

Mechanisms of virus-induced immune suppression

The recent demonstration that the acquired immune deficiency syndrome (AIDS) is caused by a retrovirus that affects humans has given rise to widespread concern about the immunosuppressive properties of viruses in general. A wide variety of viruses have been shown to be able to compromise immune function. Sometimes immunosuppression results from the pathologic processes that viruses are able to induce. In other instances virus-induced immune derangements may themselves be responsible for the onset of pathologic change. In some cases a single infectious viral agent may be able to modulate several immunologic mechanisms simultaneously. This review discusses some of the various complex mechanisms through which viral infections can alter the function of the immune system.     

Immune responses to complex protein antigens I. MHC control of immune responses to bovine albumin

Murine T cell proliferative and antibody responses to the multi-determinant protein bovine serum albumin (BSA) are controlled by Ir genes mapping within the H-2 gene complex. Strains possessing the H-2k, H-2a, and H-2d haplotypes are classified as high responders to BSA. In contrast, H-2b strains are low responders to BSA. Genetic mapping experiments employing strains with recombinant H-2 haplotypes indicate that both T cell proliferative and antibody responses are at least in part regulated by genes within the I-A subregion. Studies on the inhibition of T cell proliferation by monoclonal anti-Ia antibodies are consistent with the assignment of an Ir gene for BSA to the I-A subregion and strongly suggest a role for genes within the I-E/C subregions as well. The MHC-mediated control of antibody responses did not affect the affinity or the isotype of the antibody produced. The relative quantities of antibody specific for each of the three domains of BSA appears to be regulated by H-2-linked BSA Ir genes, and domain III antigenic determinants were found to be dominant in the responses of low-responder mice and in the early response of high-responder mice. This domain III epitope dominance essentially disappears by the tertiary response of high-responder mice.     

Antitumour immune responses

The role of the immune system in combating tumour progression has been studied extensively. The two branches of the immune response - humoral and cell-mediated - act both independently and in concert to combat tumour progression, the success of which depends on the immunogenicity of the tumour cells. The immune system discriminates between transformed cells and normal cells by virtue of the presence of unique antigens on tumour cells. Despite this, the immune system is not always able to detect and kill cancerous cells because neoplasms have also evolved various strategies to escape immune surveillance. Attempts are being made to trigger the immune system into an early and efficient response against malignant cells, and various therapeutic modalities are being developed to enhance the strength of the immune response against tumours. This review aims to elucidate the tumoricidal role of various components of the immune system, including macrophages, lymphocytes, dendritic cells and complement.     

Long-term control of Mycobacterium tuberculosis infection is mediated by dynamic immune responses

The primary goal of this study was to determine how chronic exposure to Ag influences the functionality of Mycobacterium tuberculosis-specific T cell responses. The frequency of IFN-gamma-producing effector CD4(+) and CD8(+) T cells dynamically changed during persistent M. tuberculosis infection. CD8(+) T cells used differential effector functions during acute and chronic phases of the immune response, where CD8(+) T cells produced negligible amounts of IFN-gamma early in infection, but switched to cytokine production during the chronic stage of infection. Using limiting dilution analysis, CD8(+) T cells isolated during the initial phase of infection demonstrated lytic potential, but this waned in the chronic stage. The apparent loss of cytotoxic activity was not associated with the lack of perforin. Ag dose could potentially govern the functional program of CD8(+) T cells. Collectively, these results depict a host immune response mounted against M. tuberculosis of a significantly more dynamic nature than previously recognized.     

Differential immune and genetic responses in rat models of Crohn's colitis and ulcerative colitis

Crohn's disease and ulcerative colitis are clinically, immunologically, and morphologically distinct forms of inflammatory bowel disease (IBD). However, smooth muscle function is impaired similarly in both diseases, resulting in diarrhea. We tested the hypothesis that differential cellular, genetic, and immunological mechanisms mediate smooth muscle dysfunction in two animal models believed to represent the two diseases. We used the rat models of trinitrobenzene sulfonic acid (TNBS)- and dextran sodium sulfate (DSS)-induced colonic inflammations, which closely mimic the clinical and morphological features of Crohn's disease and ulcerative colitis, respectively. DSS inflammation induced oxidative stress initially in mucosa/submucosa, which then propagated to the muscularis externa to impair smooth muscle function. The muscularis externa showed no increase of cytokines/chemokines. On the other hand, TNBS inflammation almost simultaneously induced oxidative stress, recruited or activated immune cells, and generated cytokines/chemokines in both mucosa/submucosa and muscularis externa. The generation of cytokines/chemokines did not correlate with the recruitment and activation of immune cells. Consequently, the impairment of smooth muscle function in DSS inflammation was primarily due to oxidative stress, whereas that in TNBS inflammation was due to both oxidative stress and proinflammatory cytokines. The impairment of smooth muscle function in DSS inflammation was due to suppression of Gα(q) protein of the excitation-contraction coupling. In TNBS inflammation, it was due to suppression of the α(1C)1b subunit of Ca(v)1.2b channels, CPI-17 and Gα(q). TNBS inflammation increased IGF-1 and TGF-β time dependently in the muscularis externa. IGF-1 induced smooth muscle hyperplasia; both IGF-1 and TGF-β induced hypertrophy. In conclusion, both TNBS and DSS induce transmural inflammation, albeit with different types of inflammatory mediators. The recruitment or activation of immune cells does not correlate directly with the intensity of generation of inflammatory mediators. The inflammatory mediators in TNBS and DSS inflammations target different genes to impair smooth muscle function.     

The role of the macrophage in genetic control of the immune response.

The ability of an animal to mount an immune response is controlled by a number of autosomal dominant immune response (Ir) genes that are linked to the major histocompatibility complex of the species. In the guinea pig, alloantiserums raised by cross-immunization of inbred strain 2 and strain 13 animals specifically inhibited the in vitro proliferative responses of (2 X 13) F1 lymphocytes to those antigens the response to which is controlled by Ir genes linked to the alloantigens against which the serums are directed. A genetic analysis indicated that the inhibitory activity of the alloantiserums was directed against the alloantigens rather than the products of specific Ir genes. The interaction of antigen-pulsed macrophages with immune T lymphocytes is also mediated by the 2/13 alloantigens and alloantiserums are capable of inhibiting macrophage-T lymphocyte interaction. Studies involving combinations of macrophages and lymphocytes that differed at alloantigens or Ir gene products or both raised the possibility of the expression of the Ir gene product in the macrophage.