Dendritic Cell Cross-Priming Is Essential for Immune Responses to Listeria monocytogenes

Cross-presentation is now recognized as a major mechanism for initiating CD8 T cell responses to virus and tumor antigens in vivo. It provides an elegant mechanism that allows relatively few Dendritic cells (DCs) to initiate primary immune responses while avoiding the consumptive nature of pathogenic infection. CD8 T cells play a major role in anti-bacterial immune responses; however, the contribution of cross-presentation for priming CD8 T cell responses to bacteria, in vivo, is not well established. Listeria monocytogenes (Listeria) is the causative agent of Listeriosis, an opportunistic food-borne bacterial infection that poses a significant public health risk. Here, we employ a transgenic mouse model in which cross-presentation is uniquely inactivated, to investigate cross-priming during primary Listeria infection. We show that cross-priming deficient mice are severely compromised in their ability to generate antigen-specific T cells to stimulate MHC I-restricted CTL responses following Listeria infection. The defect in generation of Listeria-elicited CD8 T cell responses is also apparent in vitro. However, in this setting, the endogenous route of processing Listeria-derived antigens is predominant. This reveals a new experimental dichotomy whereby functional sampling of Listeria-derived antigens in vivo but not in vitro is dependent on cross-presentation of exogenously derived antigen. Thus, under normal physiological circumstances, cross-presentation is demonstrated to play an essential role in priming CD8 T cell responses to bacteria.     

Trypanosoma cruzi: Effect on B-cell-responsive and -responding clones

During the course of Trypanosoma cruzi infection in C57BL/6 mice, which are relatively resistant to the parasite, the hosts developed antibody activity against previously unencountered antigens. The anti-sheep erythrocyte and antitrinitrophenyl antibody levels increased rapidly from Day 7 of infection, reached a peak by the 21st day, and were maintained at this level through 120 days postinfection in these mice. In contrast, highly susceptible C3H(He) mice did not have demonstrable antibody responses to SRBC or TNP during the 24-day infection period. Autoantibody activity against the selfantigens presented on isologous erythrocytes or thymocytes, however, were reduced in infected C57BL/6 mice. No significant reduction in autoreactivity to the self-antigens on erythrocytes or thymocytes was observed in C3H(He) mice infected with T. cruzi although a trend of reduced autoresponsiveness toward erythrocytes appeared to be developing by the time of death. C57BL/6 mice immunized with sheep erythrocytes as neonates and infected with T. cruzi as adults, or adult mice primed with low doses of sheep erythrocytes prior to infection, had elevated antibody responses to sheep erythrocytes unless the mice were immunized with sheep erythrocytes during the course of infection, in which case suppression of the response against sheep erythrocytes resulted. The nonspecific synthesis of immunoglobulins in infected C57BL/6 mice was, in part, a result of the lymphocyteactivating properties of T. cruzi-associated antigens. The T. cruzi-associated antigens induced proliferative and differentiative responses in spleen cells in vitro. It is proposed that the T. cruzi-associated antigens differentially affect lymphocytes capable of responding to antigen and those lymphocytes previously stimulated by antigen.     

Reduced Cellular Susceptibility to In Vitro HIV Infection Is Associated with CD4+ T Cell Quiescence

Background

HIV preferentially establishes productive infection in activated CD4+ T cells. Since proportions of activated CD4+ T cells vary between individuals, this study aimed to determine if individuals with a greater proportion of activated CD4+ T cells would be more susceptible to in vitro HIV infection.

Methodology/Principal Findings

Unstimulated peripheral blood mononuclear cells (PBMC) from various donors were inoculated with HIV_ML1956 in vitro. HIV replication was evaluated by HIV p24 ELISA of culture supernatants and intracellular staining for HIV p24, which was detected by flow cytometry. Baseline T cell phenotypes and infected cell phenotypes were also evaluated by flow cytometry. Ex vivo phenotyping at the time of blood draw showed that elevated T cell activation and reduced Tregs were associated with increased cellular susceptibility to in vitro infection. Furthermore, the infected CD4+ T cell population was enriched for activated cells.

Conclusion/Significance

These data suggest that CD4+ T cell quiescence provides an environment less conducive to the establishment of HIV infection by limiting the pool of activated target cells.     

Enhanced Virus-Specific CD8+ T Cell Responses by Listeria monocytogenes-Infected Dendritic Cells in the Context of Tim-3 Blockade

In this study, we engineered Listeria monocytogens (Lm) by deleting the LmΔactA/ΔinlB virulence determinants and inserting HCV-NS5B consensus antigens to develop a therapeutic vaccine against hepatitis C virus (HCV) infection. We tested this recombinant Lm-HCV vaccine in triggering of innate and adaptive immune responses in vitro using immune cells from HCV-infected and uninfected individuals. This live-attenuated Lm-HCV vaccine could naturally infect human dendritic cells (DC), thereby driving DC maturation and antigen presentation, producing Th1 cytokines, and triggering CTL responses in uninfected individuals. However, vaccine responses were diminished when using DC and T cells derived from chronically HCV-infected individuals, who express higher levels of inhibitory molecule Tim-3 on immune cells. Notably, blocking Tim-3 signaling significantly improved the innate and adaptive immune responses in chronically HCV-infected patients, indicating that novel strategies to enhance the potential of antigen presentation and cellular responses are essential for developing an effective therapeutic vaccine against HCV infection.     

Antigen-encapsulating host extracellular vesicles derived from Salmonella-infected cells stimulate pathogen-specific Th1-type responses in vivo

Salmonella Typhimurium is a causative agent of nontyphoidal salmonellosis, for which there is a lack of a clinically approved vaccine in humans. As an intracellular pathogen, Salmonella impacts many cellular pathways. However, the intercellular communication mechanism facilitated by host-derived small extracellular vesicles (EVs), such as exosomes, is an overlooked aspect of the host responses to this infection. We used a comprehensive proteome-based network analysis of exosomes derived from Salmonella-infected macrophages to identify host molecules that are trafficked via these EVs. This analysis predicted that the host-derived small EVs generated during macrophage infection stimulate macrophages and promote activation of T helper 1 (Th1) cells. We identified that exosomes generated during infection contain Salmonella proteins, including unique antigens previously shown to stimulate protective immune responses against Salmonella in murine studies. Furthermore, we showed that host EVs formed upon infection stimulate a mucosal immune response against Salmonella infection when delivered intranasally to BALB/c mice, a route of antigen administration known to initiate mucosal immunity. Specifically, the administration of these vesicles to animals stimulated the production of anti-Salmonella IgG antibodies, such as anti-OmpA antibodies. Exosomes also stimulated antigen-specific cell-mediated immunity. In particular, splenic mononuclear cells isolated from mice administered with exosomes derived from Salmonella-infected antigen-presenting cells increased CD4+ T cells secreting Th1-type cytokines in response to Salmonella antigens. These results demonstrate that small EVs, formed during infection, contribute to Th1 cell bias in the anti-Salmonella responses. Collectively, this study helps to unravel the role of host-derived small EVs as vehicles transmitting antigens to induce Th1-type immunity against Gram-negative bacteria. Understanding the EV-mediated defense mechanisms will allow the development of future approaches to combat bacterial infections.     

Bromodeoxyuridine and light treatment enhances responsiveness of pokeweed mitogen-stimulated human lymphocytes to autologous and allogeneic determinants

We have investigated a novel system whereby lymphocytes from normal human subjects can be induced to develop exaggerated reactivity to histocompatibility antigens in vitro. Peripheral blood mononuclear cells (PBMC) stimulated with pokeweed mitogen (PWM) showed increased and accelerated subsequent proliferation to both autologous and allogeneic stimulators. Addition of bromodeoxyuridine (BUdR) during the period of maximal PWM-induced DNA synthesis followed by light exposure caused unexpected, but marked enhancement of this secondary proliferation. While untreated cultures contained a preponderance of T8⁺ cells after PWM activation, BUdR plus light-treated cultures were largely T4⁺ cells. Because removal of suppressor cells in nonsuicided cultures with anti-T8 and complement just before restimulation failed to unmask enhanced autoreactivity, events critical in the induction of the enhanced response must have occurred during priming. Cultures of PBMC with medium alone or concanavalin A, as well as purified T cells cultured with PWM, gave no enhanced autoproliferation after BUdR and light; thus T and non-T cells must be acted on by a T- and B-cell mitogenic stimulus to prime T cells for enhanced responsiveness. The interactions between T cells and activated B cells in this in vitro system may be relevant to regulatory mechanisms important in the induction of pathological autoimmune responses.     

Abnormal priming of CD4(+) T cells by dendritic cells expressing hepatitis C virus core and E1 proteins

Patients infected with hepatitis C virus (HCV) have an impaired response against HCV antigens while keeping immune competence for other antigens. We hypothesized that expression of HCV proteins in infected dendritic cells (DC) might impair their antigen-presenting function, leading to a defective anti-HCV T-cell immunity. To test this hypothesis, DC from normal donors were transduced with an adenovirus coding for HCV core and E1 proteins and these cells (DC-CE1) were used to stimulate T lymphocytes. DC-CE1 were poor stimulators of allogeneic reactions and of autologous primary and secondary proliferative responses. Autologous T cells stimulated with DC-CE1 exhibited a pattern of incomplete activation characterized by enhanced CD25 expression but reduced interleukin 2 production. The same pattern of incomplete lymphocyte activation was observed in CD4(+) T cells responding to HCV core in patients with chronic HCV infection. However, CD4(+) response to HCV core was normal in patients who cleared HCV after alpha interferon therapy. Moreover, a normal CD4(+) response to tetanus toxoid was found in both chronic HCV carriers and patients who had eliminated the infection. Our results suggest that expression of HCV structural antigens in infected DC disturbs their antigen-presenting function, leading to incomplete activation of anti-HCV-specific T cells and chronicity of infection. However, presentation of unrelated antigens by noninfected DC would allow normal T-cell immunity to other pathogens.     

Peripheral blood white cell responses during Angiostrongylus cantonensis infection in rats

Yono W. K. and Dobson C. 1984. Peripheral blood white cell responses during Angiostrongylus cantonensis infections in rats. Interntional Journal for Parasitology14: 207–211. Changes in white blood cell (WBC) populations and their proliferative responses to phytohaemagglutinin (PHA) and parasite antigens in vitro were studied in rats given one to three concurrent infections with Angiostrongylus cantonensis. WBC counts were elevated following infection; these changes were augmented following each successive reinfection. The WBC response could be partitioned into variations in the numbers of four major cell types. There was a loss of lymphocytes from the circulation after infection or reinfection followed by an increase in circulating lymphocytes when the parasite migrated to the lungs and matured. An eosinophilia was observed in all rats immediately after infection which was enhanced successively after each reinfection. The monocyte populations increased in a similar, but less obvious manner, to the eosinophil leucocytes. Neutrophil leucocytes increased after infection, but the numbers declined after reinfection. All rats given one to three infections showed a neutrophilia late in the experiment. A reversal in the neutrophil leucocyte-lymphocyte ratio was observed after each infection. A peak response in the proliferation of peripheral blood lymphocytes in vitro to PHA preceded and exceeded that stimulated by A. cantonensis antigen. These responses were interpreted as the dissemination of uncommitted thymus-dependent lymphocytes involved in the induction of antigen sensitized memory cells released following the protective immune reaction. The degree of lymphocyte responsiveness to mitogens correlated with the numbers of these cells circulating at each time interval. The relationships between in vitro lymphocyte responses and protective immunity in the rat against A. cantonensis are discussed.     

B Cell Responses to HIV Antigen Are a Potent Correlate of Viremia in HIV-1 Infection and Improve with PD-1 Blockade

Infection with Human Immunodeficiency Virus Type 1 (HIV-1) induces defects of both cellular and humoral immune responses. Impaired CD4+ T cell help and B cell dysfunction may partially explain the low frequency of broadly neutralizing antibodies in HIV-infected individuals. To understand the extent of B cell dysfunction during HIV infection, we assessed the level of B cell activation at baseline and after stimulation with a variety of antigens. Increased levels of viremia were associated with higher baseline expression of the activation marker CD86 on B cells and with decreased ability of B cells to increase expression of CD86 after in vitro stimulation with inactivated HIV-1. In a series of cell isolation experiments B cell responses to antigen were enhanced in the presence of autologous CD4+ T cells. HIV infected individuals had a higher frequency of PD-1 expression on B cells compared to HIV- subjects and PD-1 blockade improved B cell responsiveness to HIV antigen, suggesting that inhibitory molecule expression during HIV-1 infection may contribute to some of the observed B cell defects. Our findings demonstrate that during chronic HIV infection, B cells are activated and lose full capacity to respond to antigen, but suppression of inhibitory pressures as well as a robust CD4+ T cell response may help preserve B cell function.     

Mycobacterium tuberculosis Promotes HIV trans-Infection and Suppresses Major Histocompatibility Complex Class II Antigen Processing by Dendritic Cells

Mycobacterium tuberculosis is a leading killer of HIV-infected individuals worldwide, particularly in sub-Saharan Africa, where it is responsible for up to 50% of HIV-related deaths. Infection by HIV predisposes individuals to M. tuberculosis infection, and coinfection accelerates the progression of both diseases. In contrast to most other opportunistic infections associated with HIV, an increased risk of M. tuberculosis infection occurs during early-stage HIV disease, long before CD4 T cell counts fall below critical levels. We hypothesized that M. tuberculosis infection contributes to HIV pathogenesis by interfering with dendritic cell (DC)-mediated immune control. DCs carry pathogens like M. tuberculosis and HIV from sites of infection into lymphoid tissues, where they process and present antigenic peptides to CD4 T cells. Paradoxically, DCs can also deliver infectious HIV to T cells without first becoming infected, a process known as trans-infection. Lipopolysaccharide (LPS)-activated DCs sequester HIV in pocketlike membrane invaginations that remain open to the cell surface, and individual virions are delivered from the pocket into T cells at the site of contact during trans-infection. Here we report that M. tuberculosis exposure increases HIV trans-infection and induces viral sequestration within surface-accessible compartments identical to those seen in LPS-stimulated DCs. At the same time, M. tuberculosis dramatically decreases the degradative processing and major histocompatibility complex class II (MHC-II) presentation of HIV antigens to CD4 T cells. Our data suggest that M. tuberculosis infection promotes a shift in the dynamic balance between antigen processing and intact virion presentation, favoring DC-mediated amplification of HIV infections.Dendritic cells (DCs) comprise a diverse family of cell types whose primary function is to initiate and drive immune responses. Myeloid DCs (myDCs) are essential antigen-presenting cells that monitor peripheral tissues for invading pathogens. myDCs bind and internalize bacteria and viruses using a variety of surface receptors. When stimulated by pathogenic or inflammatory signals, peripheral-tissue DCs migrate to lymphoid tissues and undergo maturation, degrading stored antigens into peptides that are loaded onto major histocompatibility complex class II (MHC-II) molecules and expressed on the cell surface for presentation to CD4 T cells (reviewed in reference 4). In addition to presentation of processed peptide antigens, DCs carry intact, unprocessed proteins and pathogens from peripheral tissues to lymph nodes, where they can be passed to other antigen-presenting cells to increase the breadth of the immune response (reviewed in reference 10).HIV can exploit the natural trafficking of DCs to establish and amplify infection of CD4 T cells. DCs efficiently transfer intact, infectious HIV to T cells during immune interactions through a process known as trans-infection (14). DCs trans-infect HIV by binding and concentrating the intact virus at the cellular interface, forming an “infectious synapse” that concentrates HIV receptors on the T cell to the same site (24). Importantly, trans-infection does not require productive infection of the DCs, which are not infected efficiently by HIV in vitro or in vivo (14). Immature DCs significantly enhance infection of T cells through trans-infection, and prior activation by cytokine or bacterial stimuli markedly increases infectious synapse formation and concomitant trans-infection (2, 24, 33).Worldwide, nearly one-third of HIV-infected people are coinfected with Mycobacterium tuberculosis, and active tuberculosis disease (TB) is the number one cause of death in HIV-infected people. Coinfected individuals are 30 times more likely to progress to active TB, which can in turn increase HIV replication and accelerate the progression to AIDS (35). The mechanisms by which coinfection with M. tuberculosis and HIV accelerates the progression of both diseases are poorly understood.Lung macrophages are the primary target of M. tuberculosis infection, and active disease is characterized by unconstrained replication in these cells. Dendritic cells can also be infected by M. tuberculosis, but M. tuberculosis growth is restricted due to a lack of nutrient access in the DC phagolysosomal structure in which it resides (20). Importantly, M. tuberculosis-infected DCs traffic between the infected lung and draining lymph nodes, bringing bacterial antigens into lymphoid tissues to initiate CD4 T cell responses essential for disease control (39).Others have established that M. tuberculosis binds to and is internalized by DCs via an interaction between the mycobacterial cell wall component mannosylated lipoarabinomannan (ManLAM) and the cell surface receptor DC-SIGN on dendritic cells (15). After ManLAM stimulation, DCs begin to secrete interleukin-10 (IL-10) and show defects in immunostimulatory functions (15). However, a more recent study suggests that ManLAM may not be solely responsible for these outcomes (1).Previously, it has been shown that lipopolysaccharide (LPS) potently stimulates HIV trans-infection of CD4 T cells by DCs (24, 33). Therefore, we reasoned that M. tuberculosis and its products might similarly stimulate DC trans-infection during active M. tuberculosis infections. Further, we hypothesized that DC activation by M. tuberculosis would result in downmodulation of processing and MHC-II presentation of newly bound HIV particles, shifting the balance away from immune control in favor of viral dissemination and pathogenesis.Here, we demonstrate that M. tuberculosis infection of DCs enhances HIV trans-infection mediated through surface-accessible, pocketlike invaginations of the plasma membrane. Increased HIV trans-infection is accompanied by decreased MHC-II processing and presentation of HIV antigens to CD4 T cells. Our results suggest one mechanism whereby M. tuberculosis infection can fuel HIV dissemination in coinfected individuals and at the same time decrease immune control of both HIV and M. tuberculosis infections.     

Mitogens and T-independent antigens stimulate T lymphocytes to secrete La antigens.

Previous reports from this laboratory suggest that certain I region-associated (Ia) antigens can be detected in normal mouse serum. It was found that, when mitogens are injected into mice, they produce substantial increases (up to 125-fold) in the levels of these Ia antigens in mouse serum. Similar increases were obtained when either T- or B-cell mitogens were injected. Furthermore, in vitro and in vivo studies demonstrated that the mitogens stimulated T cells to secrete Ia antigens. It appears likely, however, that the Ia antigens detected in these studies may differ from the conventional Ia glycoproteins found on the surface of B lymphocytes.All T-independent antigens tested also augmented the concentrations of Ia antigen in serum, the increases depending on the T-independent antigen injected and ranging from 3- to 125-fold. In contrast, T-dependent antigens, unless injected in large amounts, were unable to produce detectable changes in the serum levels of Ia antigen. These data indicate that an inverse relationship exists between the T dependence of an antigen and its ability to stimulate T cells to secrete Ia antigens. On the basis of this conclusion it is proposed that all antigens are T dependent and merely vary in the efficiency with which they activate T cells to release helper factors.     

B Cells and Programmed Death-Ligand 2 Signaling Are Required for Maximal Interferon-γ Recall Response by Splenic CD4+ Memory T Cells of Mice Vaccinated with Mycobacterium tuberculosis Ag85B

CD4⁺ T cells producing interferon-γ are crucial for protection against Mycobacterium tuberculosis infection and are the cornerstone of tuberculosis vaccination and immunological diagnostic assays. Since emerging evidence indicates that B cells can modulate T cell responses to M. tuberculosis infection, we investigated the contribution of B cells in regulating interferon-γ recall response by memory Thelper1 cells specific for Ag85B, a leading candidate for tuberculosis sub-unit vaccines. We found that B cells were able to maximize the reactivation of CD4⁺ memory T cells and the interferon-γ response against ex vivo antigen recall in spleens of mice vaccinated with Ag85B. B cell-mediated increase of interferon-γ response was particular evident for high interferon-γ producer CD4⁺ memory T cells, likely because those T cells were required for triggering and amplification of B cell activation. A positive-feedback loop of mutual activation between B cells, not necessarily antigen-experienced but with integral phosphatidylinositol-3 kinase (PI3K) pathway and a peculiar interferon-γ-producing CD4^highT cell subset was established. Programed death-ligand 2 (PD-L2), expressed both on B and the highly activated CD4^high T cells, contributed to the increase of interferon-γ recall response through a PD1-independent pathway. In B cell-deficient mice, interferon-γ production and activation of Ag85B-specific CD4⁺ T cells were blunted against ex vivo antigen recall but these responses could be restored by adding B cells. On the other hand, B cells appeared to down-regulate interleukin-22 recall response. Our data point out that nature of antigen presenting cells determines quality and size of T cell cytokine recall responses. Thus, antigen presenting cells, including B cells, deserve to be considered for a better prediction of cytokine responses by peripheral memory T cells specific for M. tuberculosis antigens. We also invite to consider B cells, PD-L2 and PI3K as potential targets for therapeutic modulation of T cell cytokine responses for tuberculosis control.     

The Microvesicle Component of HIV-1 Inocula Modulates Dendritic Cell Infection and Maturation and Enhances Adhesion to and Activation of T Lymphocytes

HIV-1 is taken up by immature monocyte derived dendritic cells (iMDDCs) into tetraspanin rich caves from which the virus can either be transferred to T lymphocytes or enter into endosomes resulting in degradation. HIV-1 binding and fusion with the DC membrane results in low level de novo infection that can also be transferred to T lymphocytes at a later stage. We have previously reported that HIV-1 can induce partial maturation of iMDDCs at both stages of trafficking. Here we show that CD45⁺ microvesicles (MV) which contaminate purified HIV-1 inocula due to similar size and density, affect DC maturation, de novo HIV-1 infection and transfer to T lymphocytes. Comparing iMDDCs infected with CD45-depleted HIV-1_BaL or matched non-depleted preparations, the presence of CD45⁺ MVs was shown to enhance DC maturation and ICAM-1 (CD54) expression, which is involved in DC∶T lymphocyte interactions, while restricting HIV-1 infection of MDDCs. Furthermore, in the DC culture HIV-1 infected (p24⁺) MDDCs were more mature than bystander cells. Depletion of MVs from the HIV-1 inoculum markedly inhibited DC∶T lymphocyte clustering and the induction of alloproliferation as well as limiting HIV-1 transfer from DCs to T lymphocytes. The effects of MV depletion on these functions were reversed by the re-addition of purified MVs from activated but not non-activated SUPT1.CCR5-CL.30 or primary T cells. Analysis of the protein complement of these MVs and of these HIV-1 inocula before and after MV depletion showed that Heat Shock Proteins (HSPs) and nef were the likely DC maturation candidates. Recombinant HSP90α and β and nef all induced DC maturation and ICAM-1 expression, greater when combined. These results suggest that MVs contaminating HIV-1 released from infected T lymphocytes may be biologically important, especially in enhancing T cell activation, during uptake by DCs in vitro and in vivo, particularly as MVs have been detected in the circulation of HIV-1 infected subjects.     

Adoptive transfer of delayed-type hypersensitivity to Sendai virus: II. Different modes of antigen presentation determine K,D-region or I-region restriction of T cells mediating delayed-type hypersensitivity to Sendai virus

Requirements for antigen presentation for in vitro stimulation of two subpopulations of Td lymphocytes were investigated. One subset was K,D-region-restricted and required infection or fusion of virus particles with stimulator cells for induction. The other subpopulation was I-region-restricted and required presentation of antigen by adherent cells (presumably macrophages). Presentation of antigen on Ia antigen positive stimulator cells (LPS blasts) failed to lead to stimulation of I-region-restricted T lymphocytes, thus suggesting that phagoctyosis and processing of antigen rather than association of viral antigens via fusion or infection was required for stimulation of these T lymphocytes.     

The CagA protein of Helicobacter pylori suppresses the functions of dendritic cell in mice

CagA protein is the most assessed effecter molecule of Helicobacter pylori. In this report, we demonstrate how CagA protein regulates the functions of dendritic cells (DC) against H. pylori infection. In addition, we found that CagA protein was tyrosine-phosphorylated in DC. The responses to cagA-positive H. pylori in DC were reduced in comparison to those induced by cagA-negative H. pylori. CagA-overexpressing DC also exhibited a decline in the responses against LPS stimulation and the differentiation of CD4⁺ T cells toward Th1 type cells compared to wild type DC. In addition, the level of phosphorylated IRF3 decreased in CagA-overexpressing DC stimulated with LPS, indicating that activated SHP-2 suppressed the enzymatic activity of TBK1 and consequently IRF3 phosphorylation. These data suggest that CagA protein negatively regulates the functions of DC via CagA phosphorylation and that cagA-positive H. pylori strains suppress host immune responses resulting in their chronic colonization of the stomach.     

Selective responses of mouse T lymphocytes to different T mitogens and in mixed lymphocyte culture induced cytolysis reaction.

CBA spleen T lymphocytes were stimulated by the T mitogens concanavalin-A (Con-A), phytohemagglutinin (PHA), and leukoagglutinin (LA). On the 2nd to 3rd culture day the activated cells (blasts) were separated from the nonactivated cells (lymphocytes) by 1g velocity sedimentation. The lymphocytes which were not activated during the primary culture (lymphocyte fraction from the velocity sedimentation) were then stimulated by the same mitogens or in one-way MLC to DBA/2 m, and tested for relevant target lysis after MLC stimulation. Primary stimulation with Con-A abolished the responses to Con-A, to PHA, and to LA, whereas primary stimulation with PHA or with LA abolished the responses to these mitogens but left behind a considerable Con-A response. Stimulation with any one of the listed T mitogens did not significantly affect the MLC responses. While primary stimulation with Con-A abolished the relevant target cell lysis after MLC stimulation, primary stimulation with PHA or with LA reduced it only slightly. Assuming that the various mitogens stimulate separate subpopulations of T cells, the results seem to indicate that the Con-A-responsive population includes the PHA- and LA-responsive populations but not the MLC-responsive population. It also appears that the T cells generated to killer cells during MLC are mainly confined to the concanavalin-responsive population.     

Dipetalonema viteae: in vitro blastogenesis of hamster spleen and lymph node cells to phytohemagglutinin and filarial antigens

Hamsters of the randomly bred LAKZ and inbred LSH strains were infected with Dipetalonema viteae, and the in vitro responses of lymph node and spleen lymphocytes to male and female worm antigens and phytohemagglutinin (PHA) were measured by a [³H]-thymidine-uptake assay at various times after infection. The PHA response remained unchanged at the level of controls in infected LAKZ hamsters while LSH hamsters showed a depressed response to the mitogen during late infection. Stimulation of lymph node cells by filarial antigens was maximal in both strains of hamsters at Week 4 postinfection, almost reaching values obtained in PHA stimulated cultures. A similar high lymphocyte transformation reaction was measured after the injection of dead third stage larvae. During transient microfilaremia, when antibody titers reached a maximal level, the lymphocyte reactivity to filarial antigens decreased drastically and only occasionally was demonstrated in hamsters 20 and 30 weeks after infection. No correlation between lymphocyte reactivity and parasitological findings (worm load or intensity and duration of microfilaremia) could be demonstrated. The cellular unresponsiveness to filarial antigens was further analyzed in chronically infected LAKZ hamsters. No suppressor cells could be found in lymphocyte suspensions of nonresponding hamsters. A challenge infection did not restore lymphocyte reactivity. Serum of chronically infected hamsters caused marked inhibition when added to filarial antigen-sensitive lymphocytes. Lymphocytes from hamsters with a mixed D. viteae and Schistosoma mansoni infection responded as well to soluble schistosomal egg antigens at Week 30 of a D. viteae infection as lymphocytes from hamsters infected with S. mansoni alone. The humoral immune response to schistosomal antigens, however, was significantly lower in animals with a mixed infection.     

Antigenic stimulation of lymphocytes. II. Immunogenicity of dinitrophenyl-polyethylene oxide antigens.

Synthetic antigens consisting of dinitrophenyl groups attached to linear or branched-chain polyethylene oxide stimulate anti-DNP antibody production in rabbits and a proliferative response in vitro in immune rabbit lymphocytes. A requirement for immunogenicity is divalence. Linear DNP₂PEO is most effective at a molecular weight of 10⁴, but a clear response is obtained even at 10³. The optimal valence of DNP_nPEO (n = 4–80, MW, 4 × 10⁵) is 20. Destruction of T cells with antithymocyte serum does not impair the in vitro response of the remaining B lymphocytes to DNP₂PEO, indicating that these antigens are T independent.     

Natural killer cell function in HIV-1 infected patients

A cross-talk between dendritic cells (DC) and resting natural killer (NK) cells leads to the activation of both cell populations, a process requiring cell-cell contact. When the number of activated NK cells overwhelms surrounding DC, they became able to kill specifically immature DC, a feedback mechanism to shut off DC-mediated immune responses. DC, at the mucosal site, can capture HIV and transfer it to CD4+ T lymphocytes present in the regional lymph node thus giving rise to a productive infection; on the other hand, NK cells represent the first line of defence against viral infection. Our preliminary results suggest that during the early phases of an HIV infection, NK cell activity is not functionally compromised, but that infected cells might escape natural immune surveillance through several mechanisms, including a reduced lysis of autologous DC.