Respiratory vaccination of mice against influenza virus: dissection of T- and B-cell priming functions.

We find that a single respiratory administration of replicationally inactivated influenza A viral particles most often elicits a waning serum antibody response, as the long-sustained bone marrow antiviral plasma cell populations characteristically induced by viral infection are lacking, though antiviral plasma cells at other sites may occasionally persist for a long time. To determine whether this alteration in the pattern of the B-cell response is a reflection of the nature of T-helper (Th) priming, we simultaneously primed B cells with inactivated influenza A/PR8(H1N1) and Th cells with infectious A/x31(H3N2). We show that Th cells cross-react extensively between these two viruses, although the antibody response to viral envelope glycoproteins is completely non-cross-reactive. Th cells primed by infectious A/x31 have little impact on the antibody response specifically elicted from naïve B cells by inactivated A/PR8 viruses, suggesting that the characteristic vigour of the antibody response to influenza viral infection depends on the direct interaction of antiviral B cells with virally infected dendritic cells. Memory B cells primed by inactivated influenza viral particles however, respond rapidly to secondary challenge with live or inactivated viruses, promptly populating bone marrow with antiviral plasma cells. Moreover, Th cells primed by previous live A/x31 viral challenge alter the pattern of the response of naïve B cells to live A/PR8 challenge by accelerating the appearance of anti-H1/N1 plasma cells in bone marrow, eliminating the early spike of anti-H1/N1 plasma cells in the mediastinal node, and generally diminishing the magnitude of the lymph node response. Inactivated A/PR8 and infectious A/x31 are both effective vaccines against A/PR8 infection, as mice preimmunized with either vaccine exhibit much more rapid viral clearance from the lung after infectious A/PR8 challenge. In fact, even when given during a course of anti-CD8 treatment to preempt cross-reactive cytotoxic T cells, live A/x31 is a more effective vaccine against A/PR8 infection than is inactivated A/PR8 itself.

Long lived multi-isotype anti-HIV antibody responses following a prime-double boost immunization strategy.

Despite decades of work, an effective HIV vaccine remains elusive. In an effort to elicit protective immunity, investigators have sought to define vaccines able to elicit durable HIV-specific B-cell and T-cell activities. Additionally, vaccines are sought which can induce antibodies of a variety of isotypes, as each isotype possesses unique attributes in terms of opsonization, Fc receptor binding capacity, complement fixation and location. One prominent new vaccine strategy, applied to numerous distinct antigenic systems is the prime boost-regimen, with DNA, vaccinia virus (VV), and/or purified recombinant protein. To examine the durability, location and isotype distribution of responses induced by prime-boost regimens, we tested successive immunizations with DNA, VV and protein (D-V-P), comparing three forms of protein inoculations: (i) purified protein administered intramuscularly with complete Freunds adjuvant, (ii) purified protein administered intranasally, and (iii) purified protein conjugated to oxidized mannan, administered intranasally. We found that all three protocols elicited serum antibodies of multiple isotypes, with serum IgA being most prominent among mice immunized with mannan-conjugated protein. All D-V-P protocols, regardless of protein form or route, also elicited antibody responses at mucosal surfaces. In bronchoalveolar lavage, a tendency toward IgA production was again most prominent in mice boosted with the protein-mannan conjugate. Both B-cell and T-cell responses were sustained for more than 1 year post-immunization following each form of vaccination. Contemporaneous with long-lasting serum and mucosal antibodies were antibody forming cells in the bone marrow of primed animals. Results highlight the D-V-P vaccination strategy as a promising approach for attaining durable, multi-isotype B-cell and T-cell activities toward HIV.

Limited breadth of a T-helper cell response to a human immunodeficiency virus envelope protein.

Single-envelope human immunodeficiency virus (HIV) vaccines have been studied for more than a decade, with some successes in homologous challenge experiments in nonhuman primates but with no clear successes in clinical trials. To gain insight into the breadth of the immunity elicited by such vaccines, we have dissected the T-helper cell response of C57BL/6 mice to an individual, molecularly cloned envelope protein. Here, we report that T-helper cells responsive to HIV type 1 1035 envelope are very highly restricted in C57BL/6 animals: seven different hybridomas recovered from five separate mice recognized the same peptide, PKVSFEPIPIHYCAP, located in the C2 region of gp120. Three of these hybridomas were tested on a natural variant of the peptide but failed to respond. A more extensive analysis of whole splenic populations from other C57BL/6 mice immunized with the 1035 envelope reproducibly confirmed that the gp120-specific T-helper response was almost exclusively focused on a single epitope. We conclude that single-envelope vaccines may frequently fail to provoke an immune response sufficiently diverse to recognize variant sequences among circulating HIV. The results encourage the inclusion of more than one envelope in future vaccines to enhance the potential diversity and respective surveillance capacities of responding T-helper cell populations.

Myelin antigen-specific CD8+ T cells are encephalitogenic and produce severe disease in C57BL/6 mice.

Encephalitogenic T cells that mediate experimental autoimmune encephalomyelitis (EAE) are commonly assumed to be exclusively CD4+, but formal proof is still lacking. In this study, we report that synthetic peptides 35-55 from myelin oligodendrocyte glycoprotein (pMOG(35-55)) consistently activate a high proportion of CD8+ alphabetaTCR+ T cells that are encephalitogenic in C57BL/6 (B6) mice. The encephalitogenic potential of CD8+ MOG-specific T cells was established by adoptive transfer of CD8-enriched MOG-specific T cells. These cells induced a much more severe and permanent disease than disease actively induced by immunization with pMOG(35-55). CNS lesions in pMOG(35-55) CD8+ T cell-induced EAE were progressive and more destructive. The CD8+ T cells were strongly pathogenic in syngeneic B6 and RAG-1(-/-) mice, but not in isogeneic beta2-microglobulin-deficient mice. MOG-specific CD8+ T cells could be repeatedly reisolated for up to 287 days from recipient B6 or RAG-1(-/-) mice in which disease was induced adoptively with <1 x 10(6) T cells sensitized to pMOG(35-55). It is postulated that MOG induces a relapsing and/or progressive pattern of EAE by eliciting a T cell response dominated by CD8+ autoreactive T cells. Such cells appear to have an enhanced tissue-damaging effect and persist in the animal for long periods.

Global analysis of gene expression in cells of the immune system II. Cell-free translation products and high-density filter hybridization data.

We have developed an experimental system for linking information on cell-free transcription and translation products from cDNA clones with data obtained from hybridization signals from complex probes. The work described in this paper consists of two distinct processes, one being the construction of a system of clonal addresses and the other the identification of expressed genes involved in the studied processes. We describe the use of this system to identify genes involved in thymus development. Complex probes from fetal thymuses (GD15, 17 and newborn) of Balb/c mice were used to identify genes, which are up- or downregulated during the process of differentiation. The full set of information is available in the Clone-base of the Basel Institute for Immunology and will be retrievable from the website of the collaborating laboratories.

CD4+ T cell priming accelerates the clearance of Sendai virus in mice, but has a negative effect on CD8+ T cell memory.

Current vaccines designed to promote humoral immunity to respiratory virus infections also induce potent CD4+ T cell memory. However, little is known about the impact of primed CD4+ T cells on the immune response to heterologous viruses that are serologically distinct, but that share CD4+ T cell epitopes. In addition, the protective capacity of primed CD4+ T cells has not been fully evaluated. In the present study, we addressed these two issues using a murine Sendai virus model. Mice were primed with an HN421-436 peptide that represents the dominant CD4+ T cell epitope on the hemagglutinin-neuraminidase (HN) of Sendai virus. This vaccination strategy induced strong CD4+ T cell memory to the peptide, but did not induce Abs specific for the Sendai virus virion. Subsequent Sendai virus infection of primed mice resulted in 1) a substantially accelerated virus-specific CD4+ T cell response in the pneumonic lung; 2) enhanced primary antiviral Ab-forming cell response in the mediastinal lymph nodes; and 3) accelerated viral clearance. Interestingly, the virus-specific CD8+ T cell response in the lung and the development of long-term memory CD8+ T cells in the spleen were significantly reduced. Taken together, our data demonstrate that primed CD4+ T cells, in the absence of pre-existing Ab, can have a significant effect on the subsequent immune responses to a respiratory virus infection.

TH cells primed during influenza virus infection provide help for qualitatively distinct antibody responses to subsequent immunization.

The quality of the primary Ab-forming cell (AFC) response in cervical lymph nodes and mediastinal lymph nodes of mice to intranasal influenza virus was strongly influenced by viral replicative capacity. IgA secretors were prominent in the early AFC response to infectious virus in mediastinal lymph nodes, while IgG expression was more frequent among isotypically switched AFC in cervical lymph nodes of the same mice; this pattern was reversed in the response to inactivated virus. Influenza viruses A/Puerto Rico/8/34 (A/PR8) and A/X-31 share six of eight genome segments, differing only in hemagglutinin (H1 in A/PR8, H3 in A/X-31) and neuraminidase (N1 in A/PR8, N2 in A/X-31) genes. These viruses therefore elicit extensively cross-reactive TH populations, though their glycoproteins are serologically unrelated. Mice recovered from an A/X-31 infection thus mount a primary B cell response against A/PR8 glycoproteins, when challenged with the latter virus, though this response can call upon memory TH cells. To assess the impact of memory TH populations on a primary Ab response, we compared the AFC response to inactivated A/PR8 in naive mice and mice that had cleared an A/X-31 infection. A/X-31 immune mice mounted a more vigorous AFC response against A/PR8 H1 and N1 glycoproteins than naive animals, when immunized intranasally with inactivated A/PR8. However the distribution of isotypes among H1/N1-specific AFC in lymph nodes of A/X-31-primed mice resembled that of naive mice. Evidently, in this functional context, memory TH cells retained the ability to help Ab responses different in quality from that generated during their primary reaction.

Alanine-substituted peptide ligands differ greatly in their ability to activate autoreactive T-cell subsets specific for the wild-type peptide.

Alanine-substituted peptide ligands (APLs) have the potential to reduce or block autoreactive T-cell activation. Most previous investigations aimed at either identification of the amino acid residue within a peptide ligand that is critical for T-cell activation or characterization of inhibitory APLs have analyzed the effects of APLs on one, or a limited number, of T-cell lines. In this study, we compared the effects of a panel of peptides on the proliferative and activation responses of one T-cell line as well as the effects of one peptide on the responses of a panel of T-cell lines. This study reveals that the T cells that comprise the T-cell population that responds to a specific peptide are heterogeneous in that an APL may fail to induce a response in some of these T cells although it is capable of inducing a response in the others. Moreover, APLs can induce T-cell activation, in terms of production of IL-2 and/or TNF-alpha, in the absence of appreciable cell proliferation. Indeed, despite being poor stimulators in proliferation assays, most APLs readily induce production of TNF-alpha. Our results demonstrate that the net outcome of APL treatment in vivo represents the sum of diverse effects, which may not be revealed completely by limited and randomly chosen in vitro assays.

Murine gammaherpesvirus M2 gene is latency-associated and its protein a target for CD8(+) T lymphocytes.

Murine gammaherpesvirus 68 (MHV-68) infection of mice is a potential model with which to address fundamental aspects of the pathobiology and host control of gammaherpesvirus latency. Control of MHV-68 infection, like that of Epstein-Barr virus, is strongly dependent on the cellular immune system. However, the molecular biology of MHV-68 latency is largely undefined. A screen of the MHV-68 genome for potential latency-associated mRNAs revealed that the region encompassing and flanking the genomic terminal repeats is transcriptionally active in the latently infected murine B-cell tumor line S11. Transcription of one MHV-68 gene, that encoding the hypothetical M2 protein, was detected in virtually all latently infected S11 cells and in splenocytes of latently infected mice, but not in lytically infected fibroblasts. Furthermore, an epitope was identified in the predicted M2 protein that is recognized by CD8(+) T cells from infected mice and a cytotoxic T lymphocyte line that recognizes this epitope killed S11 cells, indicating that the M2 protein is expressed during latent infection and is a target for the host cytotoxic T lymphocyte response. This work therefore provides essential information for modeling MHV-68 latency and strategies of immunotherapy against gammaherpesvirus-related diseases in a highly tractable animal model.

Reciprocal stimulation between TNF-alpha and nitric oxide may exacerbate CNS inflammation in experimental autoimmune encephalomyelitis.

Nitric oxide (NO) and TNF-alpha are both highly active pleotypic modulators of cell function that are abundantly generated during inflammation. Experiments in animal systems have linked the generation of NO and TNF-alpha to autoimmune pathogenesis, and blockade of either NO or TNF-alpha has been shown to impede disease development. In this study, we show that NO and TNF-alpha can act mutually to stimulate each other's production. While IFN-gamma alone induces NO release from microglia, astrocytes are provoked into significant NO production only by a combination of IFN-gamma and TNF-alpha. Since both TNF-alpha and NO are abundantly generated during T-glial cell interaction, we asked whether and how NO affects TNF-alpha production. Using an in vitro system in which TNF-alpha secretion is induced in MBP-reactive T cells by co-culture with syngeneic astrocytes, we observed that the efficiency of TNF-alpha secretion was markedly increased, in a dose-dependent fashion, by addition of micromolar concentrations of a chemical generator of NO donor, sodium nitroprusside (SNP). Similarly, low concentrations of SNP significantly enhanced the IL-2 dependent growth of MBP-reactive T cells. These results suggest that autoimmune pathogenesis initiated by inflammatory responses within the CNS may result in part from a vicious cycle in which TNF-alpha and NO mutually provoke each other's production.

Cell death mediated by Fas-FasL interaction between glial cells and MBP-reactive T cells.

Apoptosis in T cells that have penetrated into the central nervous system (CNS) may be important for the physiological control of T cells with potentially dangerous reactivities to CNS antigens; such control may be dysfunctional in animals suffering from experimental autoimmune encephalomyelitis (EAE). In this study we examined the expression of Fas and FasL genes both in myelin basic protein (MBP)-reactive T cells and in glial cells and the susceptibility of these cells to death induced by Fas/FasL interaction. Both Fas and FasL gene expression is detectable in glial cells and MBP-reactive T cells. Cell death is not unidirectional: when T cells interact with glial cells death can be induced in the former or in the latter population. The ability to induce death of Fas-expressing cells varies greatly among different lines of MBP-reactive T cells, as does resistance to death induction by cells expressing FasL. Moreover, the ability of T cells both to deliver and to resist death signals is a function of their activation status: T cells freshly activated transmit a stronger apoptotic signal to Fas-positive target cells and are also more resistant to FasL-induced suicide. Soluble form of FasL provides a convenient titratable means of delivering death signals via Fas. However, comparison of the susceptibility of different targets to soluble FasL and to FasL expressed on the surface of a transfected glial line revealed differences, suggesting that signals arising from Fas/FasL interaction may be modulated by additional cell-surface molecules.

Quantitative assessment of myelin basic protein-reactive T cell entry to the central nervous system by using oligonucleotide probes complementary to VDJ junctional sequences of rat TCR beta-chain.

The VDJ junctional region represents the most diverse part of the antigenic TCR. We have previously reported that of 200 sequenced TCR beta-chains of rat MBP-reactive T cells, rarely did two share sequence homology over the entire CDR3 region. In this study, we demonstrate that sequences of the TCR CDR3 region are excellent clonotypic markers for rat MBP-reactive T cell clones and oligonucleotide probes complementary to the CDR3 region of three T cell clones specifically recognized the TCR from which they were derived, but failed to recognize syngeneic T cells that express a similar TCR beta-chain or T cells that share both V beta and J beta usage. To explore this observation, we determined the ability of MBP-reactive T cell clones to enter the CNS. We were able to show that some MBP-reactive T cell clones have an augmented ability to enter the CNS and that fully-activated T cells have a higher penetrating activity than their less-activated T cell counterparts.

Nonactivated astrocytes downregulate T cell receptor expression and reduce antigen-specific proliferation and cytokine production of myelin basic protein (MBP)-reactive T cells.

Astrocytes express variable levels of MHC class II antigens depending on their activation status or exposure to certain cytokines, notably IFN-gamma. When they are induced to express higher surface densities of MHC class II molecules, astrocytes are capable of stimulating syngeneic myelin basic protein (MBP)-reactive T cells to proliferate at a modest rate and to secrete proinflammatory cytokines, such as TNF-alpha, in response to antigen. In the present investigation evidence is presented that uninduced astrocytes, whether fresh or established as clones, on which surface MHC class II molecules are expressed at a very low density, promote an antigen-dependent reduction of TCR on the surface of syngeneic T cells. Accompanying this effect on the TCR is an induction of T cell hyporeactivity and little or no production of proinflammatory cytokines. These observations suggest that the ability of the astrocyte, through varying their surface MHC class II molecules, can control the effect of antigen-induced T cell responses. In their normal state of low MHC II expression astrocytes are expected to induce no or partial, rather than full, activation of autoreactive T cells that enter the CNS, resulting in T cell hyporeactivity. Since astrocytes usually diminish the production of proinflammatory cytokines by T cells that enter the CNS, the status and control of MHC class II expression on astrocytes should be important determinants of the suppression or enhancement of in situ immune responses in the CNS.

Analysis of a randomly assorted cDNA library from BW 5147 lymphoid cells. Frequency estimates based on computer aided concatenation matching of 2D gel polypeptide products.

A cDNA library was divided into 291 sectors of low complexity, 800-1000 recombinant phage plaques per sector. Aliquots of DNA from sectors prepared from high titer phage were subjected to in vitro transcription using T7 polymerase and thereafter RNA was translated in a cell-free rabbit reticulocyte system in the presence of [35S] methionine. The resulting polypeptides were separated by 2D gel electrophoresis. Radiofluorographs of the gels prepared from 10 sectors were subjected to scanning and image analysis. A multilevel spot matching procedure was employed allowing us to recognise spot occurrence in the 10 sectors. The number of detected polypeptide spots per sector varied between 147 and 325. Overall, 1082 different spots were counted totalling 1983 spots considering multiple entries. The distribution of the spots and the frequency distribution of the RNA population among the 10 sectors are shown. The highest detected frequency is 10(-2), while one half of the RNA molecular species are present at a frequency of 10(-3) or lower.

Matching antibody class with pathogen type and portal of entry: cognate mechanisms regulate local isotype expression patterns in lymph nodes draining the respiratory tract of mice inoculated with respiratory viruses, according to virus replication competence and site of inoculation.

Intranasal deposition of Sendai virus (SV) in C57BL/6 mice provokes an Ab-forming cell (AFC) reaction in mediastinal (MLN) and cervical lymph nodes (CLN), which drain the lungs and upper respiratory tract, respectively. While the majority of AFC elicited by infectious SV at both sites produced IgG, the CLN response to SV rendered inactive in replication was restricted almost entirely to IgA, although isotype switching in mediastinal continued to be skewed heavily to IgG. However, in vitro restimulation of the accompanying virus-specific T cell populations from the two sites did not reveal any significant difference in lymphokine output, and isotype expression was not altered substantially in mice lacking IL-4 or IL-6 genes. To dissociate the response to specific Ags from the inflammatory reaction to viral infection, we examined the response to inactivated SV in the face of infection with influenza virus A/HKx31. The magnitude and IgA dominance of the anti-SV AFC population in the CLN were unaffected by a simultaneous, vigorous, IgG-dominated CLN anti-influenza reaction. Evidently, the characteristics of this antiviral response are determined primarily by cognate interactions. Moreover, the IgA bias of the CLN AFC response to inactivated SV was observed only when the virus was delivered intranasally: injection under the epidermis of the cheek, a site that has a lymphatic drainage into the CLN, resulted in an IgG-dominated CLN AFC reaction, lacking IgA. The site of deposition of a vaccine can thus have more influence on the pattern of isotypes induced than the site at which the immune response is initiated.

Intranasal Sendai virus vaccine protects African green monkeys from infection with human parainfluenza virus-type one.

Human parainfluenza virus-type I (hPIV-1) infections are a common cause of "group" and hospitalizations among young children. Here we address the possibility of using the xenotropic Sendai virus [a mouse parainfluenza virus (PIV)] as a vaccine for hPIV-1. Sendai virus was administered to six African green monkeys (Cercopithecus aethiops) by the intranasal (i.n.) route. A long lasting virus-specific antibody response was elicited, both in the serum and nasal cavity. Sendai virus caused no apparent clinical symptoms in the primates, but live virus was detected in the nasal cavity for several days after inoculation. No virus was detected after a second dose of Sendai virus was administered on day 126 after the initial priming. Animals were challenged with hPIV-1 i.n. on day 154. All six vaccinated animals were fully protected from infection while six of six control animals were infected with hPIV-1. The antibody responses induced by Sendai virus immunizations proved to be greater than those induced by hPIV-1. These results demonstrate that unmanipulated Sendai virus is an effective vaccine against hPIV-1 in a primate model and may constitute a practical vaccine for human use.

Production of tumor necrosis factor-alpha as a result of glia-T-cell interaction correlates with the pathogenic activity of myelin basic protein-reactive T cells in experimental autoimmune encephalomyelitis.

Tumor necrosis factor-alpha (TNF-alpha) has attracted the greatest attention as a major factor in experimental autoimmune encephalomyelitis (EAE) pathogenesis. We compared rats undergoing EAE with manipulated but healthy animals by examining TNF-alpha gene expression in cells recovered from the brain. We used reverse transcriptase-polymerase chain reaction (RT-PCR) as a sensitive assay for detection and Northern blot hybridization as a reliable quantitative assay of TNF-alpha mRNA. TNF-alpha gene expression was consistently detected in rats immunized with myelin basic protein (MBP) emulsified in complete Freund adjuvant (CFA), but not in rats immunized with MBP emulsified in incomplete Freund adjuvant (IFA), which does not induce EAE. Similarly, brain-derived cells from rats injected with cloned encephalitogenic T cells contained increased amounts of TNF-alpha mRNA compared with rats injected with nonencephalitogenic T cell clones similar in antigen specificity and in vitro lymphokine-producing capacity. Considering that the differing pathogenic capacity of MBP-reactive T cells might result from differing patterns of interaction with glia, we examined the impact of T-cell-glia interaction in vitro on cytokine gene expression in both cell types. Glial components were efficient in inducing TNF-alpha expression in T cells; T cells and T-cell-derived cytokines could elicit expression of several lymphokine genes in glial cells. Comparison of RT-PCR and blot hybridization assays, however, suggested that cytokine expression was much more efficient, on a per cell basis, in T cells than in glia. TNF-alpha was shown to have direct cytotoxic effect on glial cells, which was greatly enhanced by small amounts of interferon-gamma (IFN-gamma).

The pattern of cytokine gene expression induced in rat T cells specific for myelin basic protein depends on the type and quality of antigenic stimulus.

Rat T cells reactive against myelin basic protein (MBP) are exclusively, CD4+ CD8- CD45RC-, inevitably produce abundant IFN-gamma, and appear to correspond to members of the Th1 CD4+ T cell subset characterized in mice. To ascertain the basis of the pathogenic activity of these cells, we studied their pattern of cytokine expression in response to activation by distinct TCR ligands. Using RT-PCR and Northern blot assays to quantify cytokine gene production and cytokine production from intact cells, we show that (i) rat MBP-reactive T cells express IL-2, IFN-gamma, and TNF-alpha as well as IL-5 and IL-10; (ii) cytokine production is not an all or nothing phenomenon, but rather varies according to the type and dose of TCR ligand, leading to variation in the pattern of cytokine production, or dissociation between cytokine production and cell proliferation; and (iii) nonencephalitogenic T cells do not differ appreciably from their encephalitogenic counterparts in ability to produce major cytokines.

Human parainfluenza virus type 1 immunization of infant mice protects from subsequent Sendai virus infection.

Human parainfluenza virus type 1 (hPIV-1) infections are a common cause of "croup" and hospitalizations among young children, yet no vaccine is yet available. Sendai virus (mouse PIV-1) is the closest known homologue of hPIV-1. Here we address the possibility of using a xenotropic, nonpathogenic PIV as a vaccine in infants, by assessing the efficacy of hPIV-1 vaccination of infant mice against a subsequent challenge with Sendai virus. hPIV-1 was administered intranasally to mice age 3-6 days and shown by serum antibody ELISA and elispot analysis to elicit virus-specific IgM and isotype-switched antibody-forming cells (AFC). The response was completely cross-reactive between hPIV-1 and Sendai virus. Mice were challenged with Sendai virus 6-8 weeks later and generated AFC and serum antibody responses composed of IgM, as well as IgG and IgA, unlike challenged, age-matched controls. The high IgM response among AFC was not seen in mice primed as adults with hPIV-1 and challenged with Sendai virus. The hPIV-1 priming of infant mice afforded protection, as the majority of these mice survived the lethal Sendai virus challenge, as did all adult primed animals. These data support the notion that the unmodified xenotropic Sendai virus might function effectively in human infants as a vaccine against hPIV-1.