Characterization of the fibronectin-attachment protein of Mycobacterium avium reveals a fibronectin-binding motif conserved among mycobacteria

Mycobacterium avium is an intracellular pathogen and a major opportunistic infectious agent observed in patients with acquired immune deficiency syndrome (AIDS). Evidence suggests that the initial portal of infection by M. avium is often the gastrointestinal tract. However, the mechanism by which the M. avium crosses the epithelial barrier is unclear. A possible mechanism is suggested by the ability of M. avium to bind fibronectin, an extracellular matrix protein that is a virulence factor for several extracellular pathogenic bacteria which bind to mucosal surfaces. To further characterize fibronectin binding by M. avium, we have cloned the M. avium fibronectin-attachment protein (FAP). The M. avium FAP (FAP-A) has an unusually large number of Pro and Ala residues (40% overall) and is 50% identical to FAP of both Mycobacterium leprae and Mycobacterium tuberculosis. Using recombinant FAP-A and FAP-A peptides, we show that two non-continuous regions in FAP-A bind fibronectin. Peptides from these regions and homologous sequences from M. leprae FAP inhibit fibronectin binding by both M. avium and Mycobacterium bovis Bacillus Calmette-Guerin (BCG). These regions have no homology to eukaryotic fibronectin-binding proteins and are only distantly related to fibronectin-binding peptides of Gram-positive bacteria. Nevertheless, these fibronectin-binding regions are highly conserved among the mycobacterial FAPs, suggesting an essential function for this interaction in mycobacteria infection of their metazoan hosts.

Essential flexibility in the T-cell recognition of antigen

alpha beta T cells specifically recognize a ligand composed of a peptide bound to a self-major-histocompatibility-complex molecule, but the recognition of slightly altered ligands by T cells can lead to a partial activation. This flexibility is crucial for T-cell development and can have both beneficial and harmful effects on peripheral T cells.

Endogenous altered peptide ligands can affect peripheral T cell responses

T cells potentially encounter a large number of endogenous self-peptide/MHC ligands in the thymus and the periphery. These endogenous ligands are critical to both positive and negative selection in the thymus; however, their effect on peripheral T cells has not been directly ascertained. Using the murine allelic Hbd (64-76)/I-Ek self-antigen model, we have previously identified altered peptide ligands (APLs) which are able to stimulate some but not all TCR-mediated effector functions. To determine directly the effect of endogenously synthesized APL/MHC complexes on peripheral T cells, we used a TCR transgenic mouse which had reversed our normal antigen system, with Ser69 peptide now being the agonist and Hbd(64-76) being the APL. In this report, we show that the constitutive level of endogenous Hbd(64-76)/I-Ek complexes presented by APCs in vivo is too low to affect the response of Ser69 reactive T cells. However, by increasing the number of Hbd(64-76)/I-Ek complexes expressed by the APCs, TCR antagonism is observed for both primary T cells and T cell hybridomas. In addition, the level of the CD4 coreceptor expressed on T cells and T cell hybridomas. In addition, the level of the CD4 coreceptor expressed on T cells changes the response pattern to endogenously presented Hbd(64-76)/I-Ek ligand. These findings demonstrate that T cells are selected to ignore the constitutive levels of endogenous complexes they encounter in the periphery. T cell responses can be affected by endogenous APLs in the periphery under limited but attainable circumstances which change the efficacy of the TCR/ligand interaction. Thus, endogenous APLs play a role in both the selection of T cells in the thymus and the responses of peripheral T cells.

Altered peptide ligand-induced partial T cell activation: molecular mechanisms and role in T cell biology

The elucidation of the phenomena of T cell antagonism and partial activation by altered peptide ligands has necessitated a revision in the traditional concepts of TCR recognition of antigen and subsequent signal transduction. Whereas previous models supported a single ligand specificity for any particular T cell, many studies using analogs of immunogenic peptides have now demonstrated a flexibility in this recognition. Moreover, interaction with such altered peptide ligands can result in dramatically different phenotypes of the T cells, ranging from inducing selective stimulatory functions to completely turning off their functional capacity. Investigations of the biochemical basis leading to these phenotypes have shown that altered peptide ligands can induce a qualitatively different pattern of signal transduction events than does any concentration of the native ligand. Such observations imply that several signaling modules are directly linked to the TCR/CD3 complex and that they can be dissociated from each other as a direct result of the nature of the ligand bound. Interestingly, many in vivo models of T cell activation are compatible with a selective signaling model, and several studies have shown that peptide analogs can play a role in various T cell biologic phenomena. These data strongly suggest that naturally occurring altered peptide ligands for any TCR exist in the repertoire of self-peptides or, in nature, derived from pathogens, and recent reports provide compelling evidence that this is indeed the case. The concept of altered peptide ligands, their effects on T cell signaling, the hypothesized mechanisms by which they exert their effects, and their possible roles in shaping the T cell immune response are the scope of this review.

The effect of endogenous altered peptide ligands on peripheral T-cell responses

Numerous studies have shown that a T cell can productively interact through its TCR with less-than-optimal ligands resulting in partial T-cell activation. These ligands, that we called 'altered peptide ligands' (APLs), can act as partial agonists, antagonists or weak agonists for the T cells. Here we discuss the self-antigen system that we used to provide evidence that endogenous APLs exist in vivo and affect T-cell development. We also report the ability of endogenous APLs to induce partial T-cell activation of peripheral T cells, and describe in which circumstances this could occur in vivo.

Interaction of 14-3-3 with signaling proteins is mediated by the recognition of phosphoserine

The highly conserved and ubiquitously expressed 14-3-3 family of proteins bind to a variety of proteins involved in signal transduction and cell cycle regulation. The nature and specificity of 14-3-3 binding is, however, not known. Here we show that 14-3-3 is a specific phosphoserine-binding protein. Using a panel of phosphorylated peptides based on Raf-1, we have defined the 14-3-3 binding motif and show that most of the known 14-3-3 binding proteins contain the motif. Peptides containing the motif could disrupt 14-3-3 complexes and inhibit maturation of Xenopus laevis oocytes. These results suggest that the interactions of 14-3-3 with signaling proteins are critical for the activation of signaling proteins. Our findings also suggest novel roles for serine/threonine phosphorylation in the assembly of protein-protein complexes.

Myocarditis-inducing epitope of myosin binds constitutively and stably to I-Ak on antigen-presenting cells in the heart

Immune interactions in the heart were studied using a murine model of myosin-induced autoimmune myocarditis. A T cell hybridoma specific for mouse cardiac myosin was generated from A/J mice and used to demonstrate that endogenous myosin/I-Ak complexes are constitutively expressed on antigen-presenting cells in the heart. This T cell hybridoma, Seu.5, was used as a functional probe to identify a myocarditis-inducing epitope of cardiac myosin. Overlapping peptides based on the cardiac myosin heavy chain alpha (myhc alpha) sequences were synthesized and tested for their ability to stimulate Seu.5 T cells. One peptide, myhc alpha (325-357) strongly stimulated the Seu.5 T cells, localizing the epitope to this region of the myhc alpha molecule. Using truncated peptides, the epitope was further localized to residues 334-352. The myhc alpha (334-352) peptide strongly induced myocarditis when administered to A/J mice, which was histologically indistinguishable from that induced by myosin. The myhc alpha (334-352) epitope was present in cardiac myosin and not skeletal muscle myosins, providing a biochemical basis for the cardiac specificity of this autoimmune disease. Induction of myocarditis by this epitope was restricted to the myhc alpha isoform and not the myhc beta isoform, suggesting there may be a difference in the efficiency of generating tolerance to these isoforms of cardiac myosin, which are differentially developmentally regulated. The myhc alpha (334-352) epitope bound to purified I-Ak molecules in a similar manner to other I-Ak-restricted immunogenic epitopes, HEL(48-61) and RNase(43-56). Importantly, the myhc alpha (334-352) epitope was able to bind to I-Ak molecules on the surface of antigen-presenting cells in a stable manner. These findings demonstrate that autoantigenic epitopes can behave in a dominant manner and constitutively bind to class II molecules in the target organ in a similar manner to foreign immunogenic epitopes.

Intramolecular mimicry. Identification and analysis of two cross-reactive T cell epitopes within a single protein

The recognition of peptide Ags by T cells through the TCR has exquisite specificity. Cross-reactive T cell responses have been described; however, the structural basis for these responses is not known. We show that two peptides derived from the same protein can exhibit sufficient structural homology, despite minimal structural identity, to elicit cross-reactive T cell responses. In addition, we explore the structural basis for cross-reactivity. T cell hybridomas recognizing PiM and PiZ allelic forms of human alpha 1-antitrypsin (hAAT) each recognized both PiM 205-220 and PiM 335-350. These two peptides possessed primary sequence identity at only two of 16 amino acid residues. Cross-reactive peptides also exhibited homology at the bulk T cell level because lymph node T cells primed with one peptide proliferated to the other peptide in vitro. Critical amino acids for the responding T cells were determined, and the core was transferred into the less reactive peptide in an attempt to increase homology by increasing sequence identity. Interestingly, as identity increased, homology decreased: peptides with the least primary sequence identity appeared most homologous to the T cells. These results have important implications for understanding the development of autoimmune diseases, and imply that minimal obvious primary sequence identity may be sufficient to initiate cross-reactive T cell responses. The ability of structurally dissimilar peptides to mimic each other when bound to a class II MHC molecule may also be important to the understanding of T development and autoimmunity.

Intramolecular mimicry. Identification and analysis of two cross-reactive T cell epitopes within a single protein

The recognition of peptide Ags by T cells through the TCR has exquisite specificity. Cross-reactive T cell responses have been described; however, the structural basis for these responses is not known. We show that two peptides derived from the same protein can exhibit sufficient structural homology, despite minimal structural identity, to elicit cross-reactive T cell responses. In addition, we explore the structural basis for cross-reactivity. T cell hybridomas recognizing PiM and PiZ allelic forms of human alpha 1-antitrypsin (hAAT) each recognized both PiM 205-220 and PiM 335-350. These two peptides possessed primary sequence identity at only two of 16 amino acid residues. Cross-reactive peptides also exhibited homology at the bulk T cell level because lymph node T cells primed with one peptide proliferated to the other peptide in vitro. Critical amino acids for the responding T cells were determined, and the core was transferred into the less reactive peptide in an attempt to increase homology by increasing sequence identity. Interestingly, as identity increased, homology decreased: peptides with the least primary sequence identity appeared most homologous to the T cells. These results have important implications for understanding the development of autoimmune diseases, and imply that minimal obvious primary sequence identity may be sufficient to initiate cross-reactive T cell responses. The ability of structurally dissimilar peptides to mimic each other when bound to a class II MHC molecule may also be important to the understanding of T development and autoimmunity.

Specific T cell recognition of minimally homologous peptides: evidence for multiple endogenous ligands

The T cell receptor (TCR) can interact with a spectrum of peptides as part of its ligand, including the immunogenic peptide, variants of this peptide,and apparently unrelated peptides. The basis of this broad specificity for ligand was investigated by substitution analysis of a peptide antigen and functional testing using a B cell apoptosis assay. A peptide containing as few as 1 aa in common with this peptide could stimulate a specific T cell response. Two endogenous ligands, an agonist and a partial agonist, were readily identified from a search of the SwissProt database, indicating that multiple endogenous ligands likely exist for a given T cell. These findings strongly support the concept that one TCR has the ability to interact productively with multiple different ligands, and provide evidence that such ligands exist in the endogenous peptide repertoire.

Modulation of T cell development by an endogenous altered peptide ligand

T cells potentially encounter numerous endogenous peptides during selection in the thymus and in the periphery. We examined the impact of an endogenous peptide on in vivo T cell development, using a TCR transgenic mouse model based on a hemoglobin-specific T cell clone. In these mice, the transgenic beta chains paired with endogenous alpha chains. This led to a serendipitous primary reactivity to Ser69 peptide, an altered peptide ligand of the Hbd (64-76) epitope of the parent clone. Two Ser69-reactive T cell populations were identified. A smaller population of the Ser69-reactive T cells responded both to Ser69 and Hbd (64-76). A majority reacted only to Ser69, and not to Hbd(64-76); in fact, Hbd(64-76) was a specific TCR antagonist for these Ser69-only-reactive T cells. Thus, in this unique experimental system, Ser69 became an agonist, and Hbd (64-76) was an antagonist. Endogenous presentation of the antagonist ligand in the thymus selectively eliminated the high-avidity cells, while sparing low-avidity cells in the Ser69-reactive T cell repertoire. These results highlight how specificity guides developing T cells through a network of ligands and indicate that the endogenous peptide pool has a profound effect on T cell development and repertoire.

Significance of T-cell stimulation by altered peptide ligands in T cell biology

Investigations of T-cell responses to altered peptide ligands have provided functional evidence that a T-cell receptor can interpret subtle structural changes in its ligand, highlighting the complexity of this antigen receptor signaling system. Over the past year, observations from many studies have suggested several roles for such analog peptides in various aspects of immune responses. Collectively, these data strongly suggest the existence of naturally occurring altered peptide ligands in the endogenous peptide repertoire, that can actively participate in the development and shaping of T-cell immunity.

Partial T cell signaling: altered phospho-zeta and lack of zap70 recruitment in APL-induced T cell anergy

Studies of T cell responses to altered peptide ligands (APLs) have provided functional evidence that a T cell receptor (TCR) can interpret subtle changes in its ligand, resulting in different phenotypic outcomes. One dramatic effect of APL stimulation with live antigen-presenting cells (APCs) is the induction of energy as opposed to proliferation. We investigated the intracellular signaling events involved in generating this unresponsiveness by comparing protein-tyrosine phosphorylation patterns after stimulation with anergy-inducing APL or the immunogenic peptide. In resting T cell clones, presentation with APL/live APC stimulated a unique pattern of TCR phospho-zeta species and a subsequent lack of association with zap70. This demonstrates that the TCR-CD3 complex can engage selective intracellular biochemical signaling pathways as a direct consequence of the nature of the ligand recognized and the initial phosphotyrosine pattern of the TCR-CD3 proteins, leading to different phenotypes.

Th2 cell clonal anergy as a consequence of partial activation

We have demonstrated Th2 clonal anergy as a consequence of partial T cell activation by immunogenic peptide and chemically fixed APC, as well as by altered peptide ligand and live antigen-presenting cells (APC). Either stimulation resulted in a profound inability of the T cells to proliferate upon restimulation with antigen and functional APC, a similar phenomenon to that found with Th1 cells. The anergic state was long lasting and was restricted to proliferation, since the T cells retained the ability to produce cytokines upon restimulation, albeit at slightly reduced levels. Th2 anergy induction was inhibited by cyclosporine A, but not by provision of exogenous costimulation or growth factors. The data presented unify Th1 and Th2 cells with regard to anergy and suggest that the fundamental control during anergy for both subsets is prevention of clonal expansion, thus blocking amplification of the immune response.

Antagonism of superantigen-stimulated helper T-cell clones and hybridomas by altered peptide ligand

T-cell activation by an immunogenic peptide can be antagonized by nonstimulatory analogs of that peptide. We investigated this T-cell receptor antagonism by using staphylococcal enterotoxin superantigen to stimulate hemoglobin-specific helper T (Th) cells because its activation pathway may differ from that of conventional antigen. Interestingly, superantigen activation of these Th cells was antagonized by hemoglobin peptide analogs even though agonist (superantigen) and antagonist (analog peptide) bind at different sites on the major histocompatibility complex-encoded molecule and the T-cell receptor. The antagonism appeared to be a fundamental block in T-cell activation, as phosphoinositol generation, cytokine production, and proliferation were reduced in Th1 clones, and, similarly, proliferative and cytokine responses were inhibited in Th2 cells. Even T-cell hybridoma activation (cytokine production and apoptosis) was inhibited by peptide antagonists. Furthermore, analog peptides that functioned as partial agonists for these Th cells also antagonized superantigen-induced proliferation and thus were a subset of the peptide antagonists. In summary, our results demonstrate that analogs of immunogenic peptide are potent antagonists for Th cell responses induced by superantigen as well as immunogenic peptide.

Regulation of the costimulator B7, not class II major histocompatibility complex, restricts the ability of murine kidney tubule cells to stimulate CD4+ T cells

The proximal segment of murine kidney tubule cells (KTC) constitutively expresses low levels of class II major histocompatibility complex (MHC) that are upregulated during local and systemic inflammation. It is not known if KTC also express the costimulator molecules necessary for them to productively participate in immune responses and stimulate T cells. To answer this question, we studied the ability of KTC to present antigens to four Th1 clones. KTC did not induce T cell proliferation to specific antigen, superantigen, or concanavalin A. However, T cell receptors did engage the peptide/MHC ligand presented by KTC, as indicated by T cell enlargement and upregulation of interleukin-2 receptor expression. Importantly, KTC failed to express the Th1 costimulator, B7, as detected by fluorescence cytometry and reverse transcription polymerase chain reaction. We directly demonstrated that lack of B7 expression accounted for at least part of the KTC presentation defect, in that a KTC line transfected with the cDNA for B7 stimulated T cell proliferation to antigen. Our results suggest that epithelial cells expressing class II MHC have developed mechanisms to prevent costimulator expression and limit parenchymal tissue destruction. Failure of class II-expressing epithelial cells to limit costimulator expression may be an important component of organ-specific autoimmunity.

Tickling the TCR: selective T-cell functions stimulated by altered peptide ligands

Recent observations of T-cell responses following T-cell receptor (TCR) interaction with altered peptide ligands have highlighted the complexity of this signalling system. The indications are that the TCR responds to minor changes in ligand with gradations of T-cell activation and effector functions. Brian Evavold, Joanne Sloan-Lancaster and Paul Allen review these studies and present a model in which partial T-cell activation and TCR antagonism are related events in a continuum of signalling through the TCR.

Hen egg-white lysozyme-specific T cells elicited in hen egg-white lysozyme-transgenic mice retain an imprint of self-tolerance

The characteristics of T cell self-tolerance were examined in hen egg-white lysozyme (HEL)-transgenic (Tg) mice that were tolerant to a dose of HEL that was immunogenic in non-Tg littermates. HEL-specific T cells were identified in the periphery of the Tg mice after immunization with 100-times more HEL than was required to achieve a response in normal littermates. The Tg T cells were functional in vivo as they were capable of providing help to generate a HEL-specific antibody response. Selective deletion of T cells specific for the dominant T cell determinant of the native protein was not the primary mechanism of T cell tolerance in the HEL-Tg mice because, similar to non-Tg littermates, the majority of lymph node (LN) and T cell clones from HEL-Tg mice were specific for the dominant T cell determinant of HEL. Rather, our findings support the idea that the HEL-reactive T cells were anergic in vivo, but could be partially activated with a strong stimulus to the immune system (i.e., 20 nmol HEL and CFA). This conclusion is based on three observations: 1) proliferation in vitro to HEL by Tg LN T cells was subnormal (25% of control) and required 2 log more Ag to proliferate when compared with proliferation of LN from non-Tg littermates; 2) T cell clones isolated from HEL-Tg mice also proliferated poorly upon stimulation with HEL and Con A, although lymphokine production from the same stimuli was similar to that obtained from non-Tg clones; 3) invariably, upon repeated antigenic stimulation in vitro, the Tg T cell clones acquired full proliferative capacity to Ag and mitogens.

Hen egg-white lysozyme-specific T cells elicited in hen egg-white lysozyme-transgenic mice retain an imprint of self-tolerance

The characteristics of T cell self-tolerance were examined in hen egg-white lysozyme (HEL)-transgenic (Tg) mice that were tolerant to a dose of HEL that was immunogenic in non-Tg littermates. HEL-specific T cells were identified in the periphery of the Tg mice after immunization with 100-times more HEL than was required to achieve a response in normal littermates. The Tg T cells were functional in vivo as they were capable of providing help to generate a HEL-specific antibody response. Selective deletion of T cells specific for the dominant T cell determinant of the native protein was not the primary mechanism of T cell tolerance in the HEL-Tg mice because, similar to non-Tg littermates, the majority of lymph node (LN) and T cell clones from HEL-Tg mice were specific for the dominant T cell determinant of HEL. Rather, our findings support the idea that the HEL-reactive T cells were anergic in vivo, but could be partially activated with a strong stimulus to the immune system (i.e., 20 nmol HEL and CFA). This conclusion is based on three observations: 1) proliferation in vitro to HEL by Tg LN T cells was subnormal (25% of control) and required 2 log more Ag to proliferate when compared with proliferation of LN from non-Tg littermates; 2) T cell clones isolated from HEL-Tg mice also proliferated poorly upon stimulation with HEL and Con A, although lymphokine production from the same stimuli was similar to that obtained from non-Tg clones; 3) invariably, upon repeated antigenic stimulation in vitro, the Tg T cell clones acquired full proliferative capacity to Ag and mitogens.

Critical components of obstetric management of chemically dependent women

Providing prenatal care to chemically dependent women presents multiple dilemmas and challenges to clinicians. It is a complex task and one that is incongruent with the usual perceptions of the obstetric experience. However, it must be viewed as an opportunity to bring these alienated women into the health care system. Pregnancy represents a period in most women's lives when they recognize the need for and are receptive to caring and responsive intervention. By optimizing the prenatal experience of chemically dependent women, maternal-fetal outcomes will be improved and the groundwork laid for the ongoing therapeutic services that are needed to maintain the health and well-being of the mother and child.

Induction of T-cell anergy by altered T-cell-receptor ligand on live antigen-presenting cells

Activation of CD4+ T helper cells results from the occupancy of the T-cell receptor (TCR) by immunogenic peptide bound to a class II major histocompatibility complex (MHC) molecule, together with a co-stimulatory signal from the antigen-presenting cell (APC). This activation leads to proliferation, cytokine production (Th1 or Th2 profile) and cytolysis. Engagement of the TCR in the absence of co-stimulation causes Th1 cells to become unresponsive to subsequent antigenic stimulation. We have previously demonstrated that analogues of an immunogenic peptide could stimulate Th1 and Th2 cells to carry out some effector functions without inducing proliferation, a phenomenon we term partial activation. Here we study the consequences of such partial activation through the TCR of two Th1 clones using peptide analogues presented by a live APC. A peptide analogue that is unable to stimulate clonal proliferation or production of cytokine or inositol phosphate can induce the T cells to become profoundly unresponsive to subsequent stimulation with the immunogenic peptide. Thus, altering the ligand of the TCR by using a peptide analogue on a functional APC sends a signal to Th1 clones that results in anergy.

Separation of T helper 1 clone cytolysis from proliferation and lymphokine production using analog peptides

In this report, we investigate the activation of Th1 clones using altered TCR ligand. By changing the immunogenic peptide, cytolytic function can be separated from proliferative and lymphokine responses. These three responses were examined and dissected in two Th1 clones using analogs of the murine hemoglobin [Hb(64-76)] peptide. This analysis was focused on amino acids in the immunogenic peptide that were possible T cell contact residues. Typically, several amino acids were identified as critical contact residues for a Th1 proliferative response. An examination of lymphokine production (IFN-gamma or IL-3) revealed the same pattern of response to the analog peptides indicating that the proliferative and lymphokine responses were directly related. However, for cytolysis, fewer amino acid residues were identified as critical contact residues for effector function. Thus, some altered peptide ligands allowed the disassociation of the cytolytic function from the proliferative and lymphokine responses in Th1 clones. To extend these findings, the activation of T cell hybridomas created from the Th1 clones were similarly examined using the altered TCR ligands. The lymphokine response (IL-2) of the T cell hybridomas identified the same critical amino acids as did the cytolytic response of the Th1 clones. Thus, analog peptides partially activated the Th1 clones such that cytolysis occurred independent from proliferative and lymphokine responses.

Separation of T helper 1 clone cytolysis from proliferation and lymphokine production using analog peptides

In this report, we investigate the activation of Th1 clones using altered TCR ligand. By changing the immunogenic peptide, cytolytic function can be separated from proliferative and lymphokine responses. These three responses were examined and dissected in two Th1 clones using analogs of the murine hemoglobin [Hb(64-76)] peptide. This analysis was focused on amino acids in the immunogenic peptide that were possible T cell contact residues. Typically, several amino acids were identified as critical contact residues for a Th1 proliferative response. An examination of lymphokine production (IFN-gamma or IL-3) revealed the same pattern of response to the analog peptides indicating that the proliferative and lymphokine responses were directly related. However, for cytolysis, fewer amino acid residues were identified as critical contact residues for effector function. Thus, some altered peptide ligands allowed the disassociation of the cytolytic function from the proliferative and lymphokine responses in Th1 clones. To extend these findings, the activation of T cell hybridomas created from the Th1 clones were similarly examined using the altered TCR ligands. The lymphokine response (IL-2) of the T cell hybridomas identified the same critical amino acids as did the cytolytic response of the Th1 clones. Thus, analog peptides partially activated the Th1 clones such that cytolysis occurred independent from proliferative and lymphokine responses.

Temperature in mice after ethanol: effect of probing and regain of righting reflex

The handling involved in rectally probing a mouse in order to measure body temperature is a stress which results in an increase in body temperature. However, after an injection of ethanol the fall in body temperature caused by ethanol is exacerbated by probing. In mice, decreases in temperature following probing are ethanol-dose dependent and can be generated on both the falling and rising phases of the ethanol induced change in temperature. The effect of probing can be observed when the mice are under the hypnotic influence of ethanol, and regain of righting reflex itself is followed by a fall in temperature. The resumption of motor activity in undisturbed mice following an hypnotic dose of ethanol also is accompanied by a fall in temperature. Therefore, the drop in temperature observed in any of these procedures which involve moving the mice may be attributable to the disruption of heat conservation rather than a stress interaction.

Tolerance to self and the processing and presentation of self antigens

Antigen processing and presentation is critical to the generation and maintenance of self tolerance. The hemoglobin system has provided important data on self antigen processing and presentation in vivo. Hemoglobin/Ia complexes were detectable in the thymus before the time of positive and negative selection. In addition, thymic epithelial cells were shown to lack the costimulatory factors necessary to trigger T cell clone proliferation. We have extended these findings to the renal proximal tubule. This class II MHC-expressing epithelial cell was demonstrated to process and present foreign as well as self antigens to T cell hybridomas. Current studies are examining whether this epithelial cell possesses the costimulatory factors required to fully stimulate T cell clones, or whether the proximal tubule may play an important role in the maintenance of self tolerance. In addition we describe the exciting model of murine autoimmune myocarditis. We have demonstrated that this is a T cell mediated disease and believe that cardiac antigen presenting cells constitutively process and present the inciting self antigen, myosin. These studies may provide important insights into autoimmunity and self tolerance.

Expression of myosin-class II major histocompatibility complexes in the normal myocardium occurs before induction of autoimmune myocarditis

Determining how an autoimmune response is initiated is essential to understanding the mechanisms of autoimmunity. Self-reactive T cells, self-protein, and a failure of tolerance to that self-protein are all involved in the pathogenesis of autoimmune disease; yet it is not clear how self-reactive T cells find the target self-protein to initiate an autoimmune response. Although a variety of self-proteins have been shown to be presented on both class I and class II major histocompatibility complex (MHC) molecules, the relationship of these self-proteins to autoimmune disease has not been established. To explore this further, we generated a T-cell hybridoma that recognizes mouse cardiac myosin, the self-protein that induces murine autoimmune myocarditis. Using this hybridoma as a probe to detect myosin-class II MHC complexes, we isolated a class II MHC+/CD45+ residential antigen-presenting cell (APC) population directly from the hearts of normal mice and looked for evidence of endogenous processing of cardiac myosin by these APC. In this report we show that myosin-class II MHC complexes are found on residential APC in the normal mouse heart. Induction of autoimmune myocarditis increased the expression of myosin-class II MHC in the heart and enhanced their APC functions. This result is a direct demonstration that epitopes of a self-antigen involved in initiating an autoimmune disease are endogenously processed and presented within the target organ.

Interaction of pregnanolone and pregnenolone sulfate with ethanol and pentobarbital

3-alpha-Hydroxy-5-beta-pregnan-20-one [pregnanolone (PA)] and 3-beta-hydroxy-5-pregnen-20-one 3-sulfate [pregnenolone sulfate (PS)] are steroids that have been shown in biochemical studies to be active at the GABA-benzodiazepine-chloride receptor complex, Pa as a "barbiturate-like" agonist and PS as a "picrotoxin-like" antagonist. Since other compounds that are active at this site interact with the effects of pentobarbital and ethanol, the behavioral effects of these steroids alone and in combination with pentobarbital and ethanol were tested. Pa blocks the convulsions caused by pentylenetetrazole (PTZ) and increases motor activity when given alone in low doses. In combination with either pentobarbital or ethanol, it enhances the depression in motor activity, hypothermia, and hypnosis. In contrast, PS has no effect on PTZ convulsions and depresses motor activity by itself. With pentobarbital, PS enhances the depression in motor activity but has no effect on hypothermia or hypnosis. With ethanol, PS enhances the hypothermia but does not affect motor activity or hypnosis. Therefore, Pa and PS show different but not opposite effects in interacting with compounds active at the GABA-benzodiazepine-chloride receptor complex.

Enhancing the immunogenicity of a permissive binding T cell epitope derived from the simian immunodeficiency virus-encoded negative regulatory factor

Using the murine system we have analyzed an immunogenic T cell peptide epitope corresponding to amino acids 96-112 of the simian immunodeficiency virus-negative regulatory protein sequence. This epitope was unusual in that it was strongly immunogenic in mice of five of the six H-2 haplotypes tested. We generated a T cell hybridoma (SVNF) specific for this peptide in order to determine how manipulating the peptide might alter its immunogenicity. Substitution analysis showed that His 103, Pro 104, Val 106, and Pro 107 were important amino acids for stimulating SVNF because substitutions at these positions diminished the reactivity of SVNF. However, we also found that substituting an Ala for a Val at position 100 or a Val for an Ala at position 110 enhanced reactivity of SVNF. We were able to further enhance the immunogenicity of this epitope by extending the carboxyl terminus two amino acids and making the resulting carboxyl-terminal Lys an amide and by adding a Glu to the amino terminus. These modifications shifted the in vitro activity of SVNF at least two orders of magnitude. We also compared the ability of this modified peptide and the wild-type SIV nef 96-112 to prime a T cell response in vivo. We primed mice with various doses of either the wild-type or the modified peptide and looked at the ability of the draining lymph node cells to proliferate to wild-type peptide. We found that the modified peptide was 10- to 100-fold better at priming a T cell response than the wild-type peptide. Therefore, we were able to create a peptide that was more immunogenic than the wild-type peptide in vivo as well as in vitro. Manipulations such as these that enhance the immunogenicity of T cell epitopes must be considered in developing peptide vaccines against HIV or other infectious agents.

Enhancing the immunogenicity of a permissive binding T cell epitope derived from the simian immunodeficiency virus-encoded negative regulatory factor

Using the murine system we have analyzed an immunogenic T cell peptide epitope corresponding to amino acids 96-112 of the simian immunodeficiency virus-negative regulatory protein sequence. This epitope was unusual in that it was strongly immunogenic in mice of five of the six H-2 haplotypes tested. We generated a T cell hybridoma (SVNF) specific for this peptide in order to determine how manipulating the peptide might alter its immunogenicity. Substitution analysis showed that His 103, Pro 104, Val 106, and Pro 107 were important amino acids for stimulating SVNF because substitutions at these positions diminished the reactivity of SVNF. However, we also found that substituting an Ala for a Val at position 100 or a Val for an Ala at position 110 enhanced reactivity of SVNF. We were able to further enhance the immunogenicity of this epitope by extending the carboxyl terminus two amino acids and making the resulting carboxyl-terminal Lys an amide and by adding a Glu to the amino terminus. These modifications shifted the in vitro activity of SVNF at least two orders of magnitude. We also compared the ability of this modified peptide and the wild-type SIV nef 96-112 to prime a T cell response in vivo. We primed mice with various doses of either the wild-type or the modified peptide and looked at the ability of the draining lymph node cells to proliferate to wild-type peptide. We found that the modified peptide was 10- to 100-fold better at priming a T cell response than the wild-type peptide. Therefore, we were able to create a peptide that was more immunogenic than the wild-type peptide in vivo as well as in vitro. Manipulations such as these that enhance the immunogenicity of T cell epitopes must be considered in developing peptide vaccines against HIV or other infectious agents.

Processing and presentation of self and foreign antigens by the renal proximal tubule

The renal proximal tubule (PT) in many ways resembles an APC. The PT is one of the few epithelial cells in the body reported to constitutively express the class II MHC molecules required to present Ag to CD4+ T cells. We questioned whether the PT could function as an APC in vitro and in vivo. Fluorescence cytometry demonstrated that the normal CBA/J PT constitutively expressed low levels of class II MHC and that this expression was markedly augmented by either IFN-gamma or systemic Listeria monocytogenes infection. Functionally, the PT from normal CBA/J mice also stimulated T cell hybridomas when cultured in vitro with Ag, and this ability was markedly up-regulated by both IFN-gamma as well as L. monocytogenes infection. To prove that the PT constitutively processed and presented self Ag in vivo, freshly isolated PT from mice transgenic for human alpha 1-antitrypsin were cultured with the appropriate T cell hybridoma in the absence of exogenous Ag. Strong stimulation of the T cell hybridoma occurred. Our data show that the renal proximal tubule processes and presents foreign Ag both in vitro and in vivo, and that it constitutively processes and presents the self Ag hAAT in vivo. These results have important implications for the understanding of renal interstitial autoimmune diseases as well as the interstitial nephritis that occurs in response to foreign Ag.

Processing and presentation of self and foreign antigens by the renal proximal tubule

The renal proximal tubule (PT) in many ways resembles an APC. The PT is one of the few epithelial cells in the body reported to constitutively express the class II MHC molecules required to present Ag to CD4+ T cells. We questioned whether the PT could function as an APC in vitro and in vivo. Fluorescence cytometry demonstrated that the normal CBA/J PT constitutively expressed low levels of class II MHC and that this expression was markedly augmented by either IFN-gamma or systemic Listeria monocytogenes infection. Functionally, the PT from normal CBA/J mice also stimulated T cell hybridomas when cultured in vitro with Ag, and this ability was markedly up-regulated by both IFN-gamma as well as L. monocytogenes infection. To prove that the PT constitutively processed and presented self Ag in vivo, freshly isolated PT from mice transgenic for human alpha 1-antitrypsin were cultured with the appropriate T cell hybridoma in the absence of exogenous Ag. Strong stimulation of the T cell hybridoma occurred. Our data show that the renal proximal tubule processes and presents foreign Ag both in vitro and in vivo, and that it constitutively processes and presents the self Ag hAAT in vivo. These results have important implications for the understanding of renal interstitial autoimmune diseases as well as the interstitial nephritis that occurs in response to foreign Ag.

Neutralization of endogenous tumor necrosis factor ameliorates the severity of myosin-induced myocarditis

Tumor necrosis factor (TNF) and interferon gamma (IFN-gamma) are pluripotent cytokines and have multiple functions during the inflammatory response. Using a murine model of autoimmune myocarditis, we studied the role of TNF and IFN-gamma in myocardial inflammation. Neutralizing monoclonal antibodies against TNF-alpha/beta and IFN-gamma were administered to myosin-immunized A/J mice to assess the effect on the severity of myocardial inflammation. Anti-TNF treatment significantly reduced the severity of myocarditis compared with rat immunoglobulin G or saline controls (p less than 0.0007) when given before myosin immunization. Myosin-specific lymph node T-cell proliferation studies showed no difference in the proliferative response between the anti-TNF-treated mice and controls. Administration of anti-TNF to mice after myosin immunization had no effect on the severity of inflammation. This suggests that TNF is an important mediator early in the pathogenesis of myocardial inflammation in this model of myocarditis. Neutralization of IFN-gamma significantly increased the severity of myocarditis compared with rat immunoglobulin G and saline controls (p less than 0.0065), suggesting that IFN-gamma may function as an important regulatory cytokine early in the pathogenesis of myocardial inflammation. Understanding the functions of cytokines during the inflammatory response to myocardial injury may provide important information on possible methods to limit myocardial damage.

Complete dissection of the Hb(64-76) determinant using T helper 1, T helper 2 clones, and T cell hybridomas

We have generated cloned Th1 cells, Th2 cells, and T cell hybridomas specific for the single immunogenic peptide from the beta-chain of murine hemoglobin (Hb(64-76)). The availability of these various types of T cells provided us an unique opportunity to examine and dissect the T cell response to an immunogenic peptide. A panel of altered Hb peptides was made by replacing each amino acid in the Hb peptide (positions 64-76) with a conservative amino acid substitution or an alanine. Although none of the eleven T cell clones and hybridomas tested exhibited the same pattern of reactivity to the substituted Hb peptides, some general features were identified for all T cell responses. The primary T cell contact residue of Hb(64-76) was shown to be asparagine 72. For every Hb(64-76) specific T cell, no activation was observed using a peptide containing the conservative substitution of a glutamine for the asparagine at position 72. The flanking glutamic acid at position 73 was also required for a proliferative response for all of the Th1 and Th2 clones. The Th subtypes were not grossly unique in their responses to the substituted Hb peptides, but exhibited minor differences in fine specificity with the Th1 cells identifying more critical amino acids then did the Th2 cells. For the Th1 cells and also the T cell hybridomas, the phenylalanine at position 71 was critical for a T cell response. Analysis of peptide affinity for IEk molecules indicated that position 71 played a role in peptide binding to MHC. Secondary T cell contact residues, which were important for many but not all of the T cells, were identified at positions 69, 70, and 76. Overall T cell responses were minimally affected by changes in the amino acid residues at positions 64-68, 74, and 75. We have also demonstrated that cloned Th1 cells, Th2 cells and T hybridomas can be generated against the same Hb(64-76) determinant.

Complete dissection of the Hb(64-76) determinant using T helper 1, T helper 2 clones, and T cell hybridomas

We have generated cloned Th1 cells, Th2 cells, and T cell hybridomas specific for the single immunogenic peptide from the beta-chain of murine hemoglobin (Hb(64-76)). The availability of these various types of T cells provided us an unique opportunity to examine and dissect the T cell response to an immunogenic peptide. A panel of altered Hb peptides was made by replacing each amino acid in the Hb peptide (positions 64-76) with a conservative amino acid substitution or an alanine. Although none of the eleven T cell clones and hybridomas tested exhibited the same pattern of reactivity to the substituted Hb peptides, some general features were identified for all T cell responses. The primary T cell contact residue of Hb(64-76) was shown to be asparagine 72. For every Hb(64-76) specific T cell, no activation was observed using a peptide containing the conservative substitution of a glutamine for the asparagine at position 72. The flanking glutamic acid at position 73 was also required for a proliferative response for all of the Th1 and Th2 clones. The Th subtypes were not grossly unique in their responses to the substituted Hb peptides, but exhibited minor differences in fine specificity with the Th1 cells identifying more critical amino acids then did the Th2 cells. For the Th1 cells and also the T cell hybridomas, the phenylalanine at position 71 was critical for a T cell response. Analysis of peptide affinity for IEk molecules indicated that position 71 played a role in peptide binding to MHC. Secondary T cell contact residues, which were important for many but not all of the T cells, were identified at positions 69, 70, and 76. Overall T cell responses were minimally affected by changes in the amino acid residues at positions 64-68, 74, and 75. We have also demonstrated that cloned Th1 cells, Th2 cells and T hybridomas can be generated against the same Hb(64-76) determinant.

Identification and characterization of a T cell-inducing epitope of bovine ribonuclease that can be restricted by multiple class II molecules

An immunodominant epitope of bovine RNase restricted by I-Ek molecules was identified using a T cell hybridoma recognizing RNase. This epitope was localized to the peptide RNase(90-105). Single conservative amino acid substitutions were made at each of the positions 94 through 105. It was found that only at one position, Asn-103, were conservative substitutions not allowed. This residue was shown to be the critical residue in determining T cell specificity. The ability of RNase(90-105) and the well-defined T cell epitope, HEL(46-61) to stimulate mouse strains expressing different independent H-2 haplotypes was examined using a T cell proliferation assay. The response to HEL(46-61) was completely restricted to mice expressing an I-Ak molecule. In striking contrast, 6 of 10 different mouse strains, H-2b,f,k,q,s,u, mounted vigorous T cell responses to RNase(90-105). The response was restricted to both I-A and I-E molecules, including I-Ab, I-Af, I-Ek, I-Aq, and I-As. H-2d mice were nonresponders to RNase(90-105), which was shown to be due to the failure of RNase(90-105) to bind to I-Ad molecules. A variant RNase(90-105) peptide was generated, containing an I-Ad binding motif, that could bind to I-Ad molecules. Despite its ability to bind, this variant peptide was not able to stimulate a response in H-2d mice. This result demonstrates that the ability of a peptide to bind to an Ia molecule is necessary but not always sufficient for a response to occur. Thus, in contrast to the highly restricted HEL(46-61) determinant, the RNase(90-105) determinant is permissive in its binding to Ia molecules. These results show that in the universe of T cell inducing epitopes contains both highly restricted and broadly restricted epitopes are found.

Identification and characterization of a T cell-inducing epitope of bovine ribonuclease that can be restricted by multiple class II molecules

An immunodominant epitope of bovine RNase restricted by I-Ek molecules was identified using a T cell hybridoma recognizing RNase. This epitope was localized to the peptide RNase(90-105). Single conservative amino acid substitutions were made at each of the positions 94 through 105. It was found that only at one position, Asn-103, were conservative substitutions not allowed. This residue was shown to be the critical residue in determining T cell specificity. The ability of RNase(90-105) and the well-defined T cell epitope, HEL(46-61) to stimulate mouse strains expressing different independent H-2 haplotypes was examined using a T cell proliferation assay. The response to HEL(46-61) was completely restricted to mice expressing an I-Ak molecule. In striking contrast, 6 of 10 different mouse strains, H-2b,f,k,q,s,u, mounted vigorous T cell responses to RNase(90-105). The response was restricted to both I-A and I-E molecules, including I-Ab, I-Af, I-Ek, I-Aq, and I-As. H-2d mice were nonresponders to RNase(90-105), which was shown to be due to the failure of RNase(90-105) to bind to I-Ad molecules. A variant RNase(90-105) peptide was generated, containing an I-Ad binding motif, that could bind to I-Ad molecules. Despite its ability to bind, this variant peptide was not able to stimulate a response in H-2d mice. This result demonstrates that the ability of a peptide to bind to an Ia molecule is necessary but not always sufficient for a response to occur. Thus, in contrast to the highly restricted HEL(46-61) determinant, the RNase(90-105) determinant is permissive in its binding to Ia molecules. These results show that in the universe of T cell inducing epitopes contains both highly restricted and broadly restricted epitopes are found.

The processing and presentation of the self-antigen hemoglobin. Self-reactivity can be limited by antigen availability and costimulator expression

APC do not distinguish between self- and foreign proteins. Previous studies from our laboratory demonstrated that most endogenous host APC constitutively processed and presented the self-Ag, hemoglobin (Hb), as detected by the Hb-specific T cell hybridoma, YO1.6. We have now examined APC in organs known to be involved in RBC degradation (liver Kupffer cells and splenic small resting B cells) for the presence of Hb/Ia complexes and for the expression of the costimulation necessary to trigger proliferation of T cell clones. We detected Hb/Ia complexes not only on splenic small resting B cells, but also on liver Kupffer cells. Interestingly, complexes were not present on lymph node small resting B cells. Splenic small resting B cells expressed costimulatory activity and efficiently stimulated the Th2 clones only. The opposite pattern was observed with liver Kupffer cells, which expressed costimulatory activity for Th1 clones only. However, if costimulatory activity was provided for the Th2 clones (IL-1 beta) and Th1 clones (allogenic spleen cells), the clones did proliferate in response to Kupffer cells and small resting B cells, respectively. In this report we have demonstrated that 1) endogenously formed self Hb/Ia complexes are expressed on splenic small resting B cells and liver Kupffer cells but not on lymph node small resting B cells and 2) these APC are also able to limit the expression of costimulatory activity for Th2 and Th1 T cell clones. Thus, endogenous APC not only constitutively process and present the self-Ag Hb, but also limit expression of the costimulatory activity necessary to trigger T cell proliferation against a self-Ag. The constitutive processing and presentation of self-Ag, as well as the regulation of costimulatory activity on APC, is likely an important feature of the maintenance of self-tolerance.

The processing and presentation of the self-antigen hemoglobin. Self-reactivity can be limited by antigen availability and costimulator expression

APC do not distinguish between self- and foreign proteins. Previous studies from our laboratory demonstrated that most endogenous host APC constitutively processed and presented the self-Ag, hemoglobin (Hb), as detected by the Hb-specific T cell hybridoma, YO1.6. We have now examined APC in organs known to be involved in RBC degradation (liver Kupffer cells and splenic small resting B cells) for the presence of Hb/Ia complexes and for the expression of the costimulation necessary to trigger proliferation of T cell clones. We detected Hb/Ia complexes not only on splenic small resting B cells, but also on liver Kupffer cells. Interestingly, complexes were not present on lymph node small resting B cells. Splenic small resting B cells expressed costimulatory activity and efficiently stimulated the Th2 clones only. The opposite pattern was observed with liver Kupffer cells, which expressed costimulatory activity for Th1 clones only. However, if costimulatory activity was provided for the Th2 clones (IL-1 beta) and Th1 clones (allogenic spleen cells), the clones did proliferate in response to Kupffer cells and small resting B cells, respectively. In this report we have demonstrated that 1) endogenously formed self Hb/Ia complexes are expressed on splenic small resting B cells and liver Kupffer cells but not on lymph node small resting B cells and 2) these APC are also able to limit the expression of costimulatory activity for Th2 and Th1 T cell clones. Thus, endogenous APC not only constitutively process and present the self-Ag Hb, but also limit expression of the costimulatory activity necessary to trigger T cell proliferation against a self-Ag. The constitutive processing and presentation of self-Ag, as well as the regulation of costimulatory activity on APC, is likely an important feature of the maintenance of self-tolerance.

Myosin-induced acute myocarditis is a T cell-mediated disease

The heart is a target organ in several autoimmune diseases, and therefore it is important to understand more about the effector cells involved in immune-mediated mechanisms of myocardial cell death. Because immune T lymphocytes are central to many immune responses, we wanted to study the role of T cells in causing cardiac specific inflammation. We used purified mouse cardiac myosin to cause acute myocarditis in mice. The adoptive transfer of purified T cells from C.B-17 mice with active myocarditis to SCID recipients successfully transferred the disease into SCID hosts. In contrast, transfer of serum with high-titer antimyosin antibodies to SCID hosts did not cause myocarditis. Using mAb to deplete A/J mice of CD4+ T cells, we showed that these mice were protected against the induction of myocarditis. Depletion of CD8+ T cells reduced the severity of inflammation but did not prevent induction of myocarditis. We were also able to prevent the induction of myocarditis using major histocompatibility class II protein-binding, nonimmunogenic, competitor peptides. These blocking studies also indicated that in H-2k mice, myocarditis is an I-Ak-restricted disease, and provided further evidence that CD4+ T cells are critical to the induction of disease. Together, these studies provide direct evidence that myosin-induced myocarditis is a T cell-mediated disease.

Myosin-induced acute myocarditis is a T cell-mediated disease

The heart is a target organ in several autoimmune diseases, and therefore it is important to understand more about the effector cells involved in immune-mediated mechanisms of myocardial cell death. Because immune T lymphocytes are central to many immune responses, we wanted to study the role of T cells in causing cardiac specific inflammation. We used purified mouse cardiac myosin to cause acute myocarditis in mice. The adoptive transfer of purified T cells from C.B-17 mice with active myocarditis to SCID recipients successfully transferred the disease into SCID hosts. In contrast, transfer of serum with high-titer antimyosin antibodies to SCID hosts did not cause myocarditis. Using mAb to deplete A/J mice of CD4+ T cells, we showed that these mice were protected against the induction of myocarditis. Depletion of CD8+ T cells reduced the severity of inflammation but did not prevent induction of myocarditis. We were also able to prevent the induction of myocarditis using major histocompatibility class II protein-binding, nonimmunogenic, competitor peptides. These blocking studies also indicated that in H-2k mice, myocarditis is an I-Ak-restricted disease, and provided further evidence that CD4+ T cells are critical to the induction of disease. Together, these studies provide direct evidence that myosin-induced myocarditis is a T cell-mediated disease.