T Cell Interactions in Mycobacterial Granulomas: Non-Specific T Cells Regulate Mycobacteria-Specific T Cells in Granulomatous Lesions.

Infections with pathogenic mycobacteria are controlled by the formation of a unique structure known as a granuloma. The granuloma represents a host-pathogen interface where bacteria are killed and confined by the host response, but also where bacteria persist. Previous work has demonstrated that the T cell repertoire is heterogenous even at the single granuloma level. However, further work using pigeon cytochrome C (PCC) epitope-tagged BCG (PCC-BCG) and PCC-specific 5CC7 RAG-/- TCR transgenic (Tg) mice has demonstrated that a monoclonal T cell population is able to control infection. At the chronic stage of infection, granuloma-infiltrating T cells remain highly activated in wild-type mice, while T cells in the monoclonal T cell mice are anergic. We hypothesized that addition of an acutely activated non-specific T cell to the monoclonal T cell system could recapitulate the wild-type phenotype. Here we report that activated non-specific T cells have access to the granuloma and deliver a set of cytokines and chemokines to the lesions. Strikingly, non-specific T cells rescue BCG-specific T cells from anergy and enhance the function of BCG-specific T cells in the granuloma in the chronic phase of infection when bacterial antigen load is low. In addition, we find that these same non-specific T cells have an inhibitory effect on systemic BCG-specific T cells. Taken together, these data suggest that T cells non-specific for granuloma-inducing agents can alter the function of granuloma-specific T cells and have important roles in mycobacterial immunity and other granulomatous disorders.

Mycobacterium bovis Bacillus Calmette-Guérin-Infected Dendritic Cells Induce TNF-α-Dependent Cell Cluster Formation That Promotes Bacterial Dissemination through an In Vitro Model of the Blood-Brain Barrier.

CNS tuberculosis (CNSTB) is the most severe manifestation of extrapulmonary tuberculosis infection, but the mechanism of how mycobacteria cross the blood-brain barrier (BBB) is not well understood. In this study, we report a novel murine in vitro BBB model combining primary brain endothelial cells, Mycobacterium bovis bacillus Calmette-Guérin-infected dendritic cells (DCs), PBMCs, and bacterial Ag-specific CD4+ T cells. We show that mycobacterial infection limits DC mobility and also induces cellular cluster formation that has a similar composition to pulmonary mycobacterial granulomas. Within the clusters, infection from DCs disseminates to the recruited monocytes, promoting bacterial expansion. Mycobacterium-induced in vitro granulomas have been described previously, but this report shows that they can form on brain endothelial cell monolayers. Cellular cluster formation leads to cluster-associated damage of the endothelial cell monolayer defined by mitochondrial stress, disorganization of the tight junction proteins ZO-1 and claudin-5, upregulation of the adhesion molecules VCAM-1 and ICAM-1, and increased transmigration of bacteria-infected cells across the BBB. TNF-α inhibition reduces cluster formation on brain endothelial cells and mitigates cluster-associated damage. These data describe a model of bacterial dissemination across the BBB shedding light on a mechanism that might contribute to CNS tuberculosis infection and facilitate treatments.

Current concepts in granulomatous immune responses.

Persistent irritants that are resistant to innate and cognate immunity induce granulomas. These macrophage-dominated lesions that partially isolate the healthy tissue from the irritant and the irritant induced inflammation. Particles, toxins, autoantigens and infectious agents can induce granulomas. The corresponding lesions can be protective for the host but they can also cause damage and such damage has been associated with the pathology of more than a hundred human diseases. Recently, multiple molecular mechanisms underlying how normal macrophages transform into granuloma-inducing macrophages have been discovered and new information has been gathered, indicating how these lesions are initiated, spread and regulated. In this review, differences between the innate and cognate granuloma pathways are discussed by summarizing how the dendritic cell - T cell axis changes granulomatous immunity. Granuloma lesions are highly dynamic and depend on continuous cell replacement. This feature provides new therapeutic approaches to treat granulomatous diseases.

A Novel In Vitro Mouse Model to Study Mycobacterium tuberculosis Dissemination Across Brain Vessels: A Combination Granuloma and Blood-Brain Barrier Mouse Model.

In vitro culture models of the blood-brain barrier (BBB) provide a useful platform to test the mechanisms of cellular infiltration and pathogen dissemination into the central nervous system (CNS). We present an in vitro mouse model of the BBB to test Mycobacterium tuberculosis (Mtb) dissemination across brain endothelial cells. One-third of the global population is infected with Mtb, and in 1%-2% of cases bacteria invade the CNS through a largely unknown process. The "Trojan horse" theory supports the role of a cellular carrier that engulfs bacteria and carries them to the brain without being recognized. We present for the first time a protocol for an in vitro BBB-granuloma model that supports the Trojan horse mechanism of Mtb dissemination into the CNS. Handling of bacterial cultures, in vivo and in vitro infections, isolation of primary astroglial and endothelial cells, and assembly of the in vitro BBB model is presented. These techniques can be used to analyze the interaction of adaptive and innate immune system cells with brain endothelial cells, cellular transmigration, BBB morphological and functional changes, and methods of bacterial dissemination. © 2020 Wiley Periodicals LLC. Basic Protocol 1: Isolation of primary mouse brain astrocytes and endothelial cells Basic Protocol 2: Isolation of primary mouse bone marrow-derived dendritic cells Support Protocol 1: Validation of dendritic cell purity by flow cytometry Basic Protocol 3: Isolation of primary mouse peripheral blood mononuclear cells Support Protocol 2: Isolation of primary mouse spleen cells Support Protocol 3: Purification and validation of CD4+ T cells from PBMCs and spleen cells Basic Protocol 4: Isolation of liver granuloma supernatant and determination of organ load Support Protocol 4: In vivo and in vitro infection with mycobacteria Basic Protocol 5: Assembly of the BBB co-culture model Basic Protocol 6: Assembly of the combined in vitro granuloma and BBB model.

VEGF-A from Granuloma Macrophages Regulates Granulomatous Inflammation by a Non-angiogenic Pathway during Mycobacterial Infection.

Many autoimmune and infectious diseases are characterized by the formation of granulomas which are inflammatory lesions that consist of spatially organized immune cells. These sites protect the host and control pathogens like Mycobacterium tuberculosis (Mtb), but are highly inflammatory and cause pathology. Using bacille Calmette-Guerin (BCG) and Mtb infection in mice that induce sarcoid or caseating granulomas, we show that a subpopulation of granuloma macrophages produces vascular endothelial growth factor (VEGF-A), which recruits immune cells to the granuloma by a non-angiogenic pathway. Selective blockade of VEGF-A in myeloid cells, combined with granuloma transplantation, shows that granuloma VEGF-A regulates granulomatous inflammation. The severity of granuloma-related inflammation can be ameliorated by pharmaceutical or genetic inhibition of VEGF-A, which improves survival of mice infected with virulent Mtb without altering host protection. These data show that VEGF-A inhibitors could be used as a host-directed therapy against granulomatous diseases like tuberculosis and sarcoidosis, thereby expanding the value of already existing and approved anti-VEGF-A drugs.

Coadministration of antigen-conjugated and free CpG: effects of in vitro and in vivo interactions in a murine model.

CpG oligodeoxynucleotides (CpG) are widely studied as promising adjuvants in vaccines against a range of diseases including infection, cancer or allergy. Conjugating antigen to CpG has been shown to potentiate the adjuvant effect via enhancing antigen uptake and danger signaling by the very same cell. In the present study, using biotinylated CpG and streptavidin as a model system, we demonstrate that CpG motif containing free and antigen-conjugated oligonucleotides do not compete in terms of cell activation via TLR9, but do compete for cellular uptake. Antigen-conjugated CpG enhances cellular association and uptake of the antigen by antigen-presenting cells (APC) and T cells. Free CpG efficiently competes with antigen-CpG conjugates in BMDC and T cells, but shows weak or no competition in B cells that have higher TLR9 expression. Vaccination with antigen-conjugated CpG or with a mixture of antigen and CpG elevates the level of antigen-specific antibodies but co-administration of CpG-antigen conjugates and free CpG adversely effects immunogenicity. These observations may help optimize CpG-based vaccine formulation.

Modulation of the humoral immune response by targeting CD40 and FcγRII/III; delivery of soluble but not particulate antigen to CD40 enhances antibody responses with a Th1 bias.

Targeted delivery of antigen improves immunogenicity and can obviate the use of adjuvants. In addition to molecular targeting based on affinity interactions, particle-based antigen targeting to myeloid cells is also an efficient means to enhance immune responses. We compared the efficiency of targeting a model antigen, streptavidin, to CD40 and low affinity Fc gamma receptors II and III, either in a soluble or in a particulate form. Single chain fragments targeting these receptors were used to generate soluble tetramers with streptavidin or to decorate streptavidin coated nanobeads, and mice were immunized with the different formulations. Whereas particulate presentation of streptavidin enhanced total IgG1 and IgG2a levels, overall antigen specific antibody production increased in the case of targeted soluble antigen only, as assessed by reverse protein arrays and ELISPOT. In particular, soluble CD40 targeted antigen induced the strongest IgG2a responses, suggesting a Th1 bias compared to FcgammaRII/III targeting. Combined targeting to these receptors did not further increase immunogenicity. Thus, in our model, affinity targeting of soluble antigen to CD40 proved to be superior to particle-mediated delivery both in terms of antibody quantity and quality.