Immunology across two islands: understanding the research landscape of Aotearoa (New Zealand).

In the unique landscape of immunology research in New Zealand, this article explores the collaborative networks spanning the two main islands, through a conversation with Associate Professor Joanna Kirman and Dr Robert Weinkove. The discussions delve into their dynamic collaborations with countries such as Asia, Australia and the United States, from their laboratories at the University of Otago and the Malaghan Institute of Medical Research, respectively, provides insight into the translational research landscape of New Zealand, and the integration of Maori culture into all aspects of scientific research and clinical practise. Kirman's work in understanding immunological memory in tuberculosis and Weinkove's research in cancer immunotherapies, particularly CAR-T cells, are highlighted. The natural beauty and accessibility of New Zealand supports its research diversity.

Intranasal immunization with Ag85B peptide 25 displayed on Lactococcus lactis using the PilVax platform induces antigen-specific B- and T-cell responses.

Mycobacterium tuberculosis (Mtb) remains a global epidemic despite the widespread use of Bacillus Calmette-Guérin (BCG). Consequently, novel vaccines are required to facilitate a reduction in Mtb morbidity and mortality. PilVax is a peptide delivery strategy for the generation of highly specific mucosal immune responses and is based on the food-grade bacterium Lactococcus lactis that is used to express selected peptides engineered within the Streptococcus pyogenes M1T1 pilus, allowing for peptide amplification, stabilization and enhanced immunogenicity. In the present study, the dominant T-cell epitope from the Mtb protein Ag85B was genetically engineered into the pilus backbone subunit and expressed on the surface of L. lactis. Western blot and flow cytometry confirmed formation of pilus containing the peptide DNA sequence. B-cell responses in intranasally vaccinated mice were analyzed by ELISA while T-cell responses were analyzed by flow cytometry. Serum titers of peptide-specific immunoglobulin (Ig) G and IgA were detected, confirming that vaccination produced antibodies against the cognate peptide. Peptide-specific IgA was also detected across several mucosal sites sampled. Peptide-specific CD4+ T cells were detected at levels similar to those of mice immunized with BCG. PilVax immunization resulted in an unexpected increase in the numbers of CD3+ CD4- CD8- [double negative (DN)] T cells in the lungs of vaccinated mice. Analysis of cytokine production following stimulation with the cognate peptide showed the major cytokine producing cells to be CD4+ T cells and DN T cells. This study provides insight into the antibody and peptide-specific cellular immune responses generated by PilVax vaccination and demonstrates the suitability of this vaccine for conducting a protection study.

Innovative antigen carrier system for the development of tuberculosis vaccines.

A major obstacle to tuberculosis (TB)-subunit-vaccine development has been the induction of inadequate levels of protective immunity due to the limited breadth of antigen in vaccine preparations. In this study, immunogenic mycobacterial fusion peptides Ag85B-TB10.4 and Ag85B-TB10.4-Rv2660c were covalently displayed on the surface of self-assembled polyester particles. This study investigated whether polyester particles displaying mycobacterial antigens could provide augmented immunogenicity (i.e., offer an innovative vaccine formulation) when compared with free soluble antigens. Herein, polyester particle-based particulate vaccines were produced in an endotoxin-free Escherichia coli strain and emulsified with the adjuvant dimethyl dioctadecyl ammonium bromide. C57BL/6 mice were used to study the immunogenicity of formulated particulate vaccines. The result of humoral immunity showed the antibodies only interacted with target antigens and not with PhaC and the background proteins of the production host. The analysis of T helper 1 cellular immunity indicated that a relatively strong production of cellular immunity biomarkers, IFN-γ and IL-17A cytokines, was induced by particulate vaccines when compared with the respective soluble controls. This study demonstrated that polyester particles have the potential to perform as a mycobacterial antigen-delivery agent to induce augmented antigen-specific immune responses in contrast to free soluble vaccines.-Chen, S., Sandford, S., Kirman, J. R., Rehm, B. H. A. Innovative antigen carrier system for the development of tuberculosis vaccines.

Beyond memory T cells: mechanisms of protective immunity to tuberculosis infection.

Tuberculosis (TB) is a serious infectious disease caused by infection with Mycobacterium tuberculosis, and kills more people annually than any other single infectious agent. Although a vaccine is available, it is only moderately effective and an improved vaccine is urgently needed. The ability to develop a more effective vaccine has been thwarted by a lack of understanding of the mechanism of vaccine-induced immune protection. Over recent decades, many novel TB vaccines have been developed and almost all have aimed to generate memory CD4 T cells. In this review, we critically evaluate evidence in the literature that supports the contention that memory CD4 T cells are the prime mediators of vaccine-induced protection against TB. Because of the lack of robust evidence supporting memory CD4 T cells in this role, the potential for B-cell antibody and "trained" innate cells as alternative mediators of protective immunity is explored.

BCG vaccination drives accumulation and effector function of innate lymphoid cells in murine lungs.

The tuberculosis (TB) vaccine bacille Calmette-Guérin (BCG) prevents disseminated childhood TB; however, it fails to protect against the more prevalent pulmonary TB. Limited understanding of the immune response to Mycobacterium tuberculosis, the causative agent of TB, has hindered development of improved vaccines. Although memory CD4 T cells are considered the main mediators of protection against TB, recent studies suggest there are other key subsets that contribute to antimycobacterial immunity. To that end, innate cells may be involved in the protective response. In this study, we investigated the primary response of innate lymphoid cells (ILCs) to BCG exposure. Using a murine model, we showed that ILCs increased in number in the lungs and lymph nodes in response to BCG vaccination. Additionally, there was significant production of the antimycobacterial cytokine IFN-γ by ILCs. As ILCs are located at mucosal sites, it was investigated whether mucosal vaccination (intranasal) stimulated an enhanced response compared to the traditional vaccination approach (intradermal or subcutaneous). Indeed, in response to intranasal vaccination, the number of ILCs, and IFN-γ production in NK cells and ILC1s in the lungs and lymph nodes, were higher than that provoked through intradermal or subcutaneous vaccination. This work provides the first evidence that BCG vaccination activates ILCs, paving the way for future research to elucidate the protective potential of ILCs against mycobacterial infection. Additionally, the finding that lung ILCs respond rigorously to mucosal vaccination may have implications for the delivery of novel TB vaccines.

Increased numbers of monocyte-derived dendritic cells during successful tumor immunotherapy with immune-activating agents.

Local treatment with selected TLR ligands or bacteria such as bacillus Calmette-Guérin increases antitumor immune responses and delays tumor growth. It is thought that these treatments may act by activating tumor-associated dendritic cells (DCs), thereby supporting the induction of antitumor immune responses. However, common parameters of successful immune activation have not been identified. We used mouse models to compare treatments with different immune-activating agents for the ability to delay tumor growth, improve priming of tumor-specific T cells, and induce early cytokine production and DC activation. Treatment with polyinosinic-polycytidylic acid or a combination of monosodium urate crystals and Mycobacterium smegmatis was effective at delaying the growth of s.c. B16 melanomas, orthotopic 4T1 mammary carcinomas, and reducing 4T1 lung metastases. In contrast, LPS, monosodium urate crystals, or M. smegmatis alone had no activity. Effective treatments required both NK1.1(+) and CD8(+) cells, and resulted in increased T cell priming and the infiltration of NK cells and CD8(+) T cells in tumors. Unexpectedly, both effective and ineffective treatments increased DC numbers and the expression of costimulatory molecules in the tumor-draining lymph node. However, only effective treatments induced the rapid appearance of a population of monocyte-derived DCs in the draining lymph node, early release of IL-12p70 and IFN-γ, and low IL-10 in the serum. These results suggest that the activation of existing DC subsets is not sufficient for the induction of antitumor immune responses, whereas early induction of Th1 cytokines and monocyte-derived DCs are features of successful activation of antitumor immunity.

Induction of T cell responses and recruitment of an inflammatory dendritic cell subset following tumor immunotherapy with Mycobacterium smegmatis.

Mycobacteria and their cell wall components have been used with varying degrees of success to treat tumors, and Mycobacterium bovis BCG remains in use as a standard treatment for superficial bladder cancer. Mycobacterial immunotherapy is very effective in eliciting local immune responses against solid tumors when administered topically; however, its effectiveness in eliciting adaptive immune responses has been variable. Using a subcutaneous mouse thymoma model, we investigated whether immunotherapy with Mycobacterium smegmatis, a fast-growing mycobacterium of low pathogenicity, induces a systemic adaptive immune response. We found that M. smegmatis delivered adjacent to the tumor site elicited a systemic anti-tumor immune response that was primarily mediated by CD8(+) T cells. Of note, we identified a CD11c(+)CD40(int)CD11b(hi)Gr-1(+) inflammatory DC population in the tumor-draining lymph nodes that was found only in mice treated with M. smegmatis. Our data suggest that, rather than rescuing the function of the DC already present in the tumor and/or tumor-draining lymph node, M. smegmatis treatment may promote anti-tumor immune responses by inducing the involvement of a new population of inflammatory cells with intact function.

A key role for lung-resident memory lymphocytes in protective immune responses after BCG vaccination.

The immune mechanisms that orchestrate protection against tuberculosis as a result of BCG vaccination are not fully understood. We used the immunomodulatory properties of fingolimod (FTY720) treatment to test whether the lung-resident memory T lymphocytes generated by BCG vaccination were sufficient to maintain immunity against challenge infection with mycobacteria (BCG). Mice were given daily fingolimod treatment, starting either immediately before s.c. BCG vaccination or during subsequent BCG i.n. challenge, to prevent LN effector and memory lymphocytes from entering the periphery either during priming or challenge, respectively. Treatment with fingolimod during vaccination reduced vaccine-mediated protection against subsequent infection. By contrast, BCG-vaccinated mice were protected when fingolimod was given during the infectious challenge, suggesting that memory lymphocytes that migrate to the lung following vaccination are sufficient for protection. Notably, the antigen-reactive IFN-gamma or multicytokine-producing CD4(+) T cells present in the lung when fingolimod was given during BCG challenge did not correlate with protection; however, expression of MHC class II on macrophages isolated from the lungs post BCG challenge was increased in the protected mice. We conclude that protection conferred by BCG vaccination is dependent on memory lymphocytes retained in the lung, although IFN-gamma production by this population is not correlated with vaccine-mediated protection.

Particulate Mycobacterial Vaccines Induce Protective Immunity against Tuberculosis in Mice.

Currently available vaccines fail to provide consistent protection against tuberculosis (TB). New, improved vaccines are urgently needed for controlling the disease. The mycobacterial antigen fusions H4 (Ag85B-TB10.4) and H28 (Ag85B-TB10.4-Rv2660c) have been shown to be very immunogenic and have been considered as potential candidates for TB vaccine development. However, soluble protein vaccines are often poorly immunogenic, but augmented immune responses can be induced when selected antigens are delivered in particulate form. This study investigated whether the mycobacterial antigen fusions H4 and H28 can induce protective immunity when assembled into particulate vaccines (polyester nanoparticle-H4, polyester nanoparticle-H28, H4 nanoparticles and H28 nanoparticles). The particulate mycobacterial vaccines were assembled inside an engineered endotoxin-free production strain of Escherichia coli at high yield. Vaccine nanoparticles were purified and induced long-lasting antigen-specific T cell responses and protective immunity in mice challenged by aerosol with virulent Mycobacterium tuberculosis. A significant reduction of M. tuberculosis CFU, up to 0.7-log10 protection, occurred in the lungs of mice immunized with particulate vaccines in comparison to placebo-vaccinated mice (p < 0.0001). Polyester nanoparticles displaying the mycobacterial antigen fusion H4 induced a similar level of protective immunity in the lung when compared to M. bovis bacillus Calmette-Guérin (BCG), the currently approved TB vaccine. The safe and immunogenic polyester nanoparticle-H4 vaccine is a promising subunit vaccine candidate, as it can be cost-effectively manufactured and efficiently induces protection against TB.

Vaccination with heat-killed leishmania antigen or recombinant leishmanial protein and CpG oligodeoxynucleotides induces long-term memory CD4+ and CD8+ T cell responses and protection against leishmania major infection.

CpG oligodeoxynucleotides (ODN) have potent effects on innate and adaptive cellular immune responses. In this report, the ability of CpG ODN to confer long-term immunity and protection when used as a vaccine adjuvant with a clinical grade of leishmanial antigen, autoclaved Leishmania major (ALM), or a recombinant leishmanial protein was studied. In two different mouse models of L. major infection, vaccination with ALM plus CpG ODN was able to control infection and markedly reduce lesion development in susceptible BALB/c and resistant C57BL/6 (B6) mice, respectively, up to 12 wk after immunization. Moreover, B6 mice immunized with ALM plus CpG ODNs were still protected against infectious challenge even 6 mo after vaccination. In terms of immune correlates of protection, ALM plus CpG ODN-vaccinated mice displayed L. major-specific T helper cell 1 and CD8+ responses. In addition, complete protection was markedly abrogated in mice depleted of CD8+ T cells at the time of vaccination. Similarly, mice vaccinated with a recombinant leishmanial protein plus CpG ODN also had long-term protection that was dependent on CD8+ T cells in vivo. Together, these data demonstrate that CpG ODN, when used as a vaccine adjuvant with either a recombinant protein or heat-killed leishmanial antigen, can induce long-term protection against an intracellular infection in a CD8-dependent manner.

Geographical differences in the proportion of human group A rotavirus strains within New Zealand during one epidemic season.

The prospect of future rotavirus vaccine programs means it is important to understand rotavirus strain diversity within New Zealand, especially if this was to influence vaccine effectiveness. The G-genotype of 359 group A rotavirus strains isolated from 416 stool samples collected from June 2005 to May 2006 (inclusive) from children less than 5 years of age in multiple centers throughout New Zealand was determined. G1 was the dominant circulating strain (55.8%) followed by G4 (21.4%), G3 (3.4%), G9 (3.4%) G2 (1.0%), and mixed infection (1.0%). Two less common strains, G6 and G8, were identified for the first time in New Zealand. P genotypes were determined for a random 10% of samples containing the common G-type strains, and all samples with an unusual G-type. All samples able to be tested contained P[8] bearing strains, except for G1P[4], G2P[4], and G8P[14] strains. Importantly, significant differences in strain frequency were found between samples collected from the North and South Islands of New Zealand. G1 was the most commonly identified strain in the North Island (81.9%); whereas G4 predominated in the South Island (39.6%). Of note, no significant differences in the relative frequency of rotavirus strains were observed between samples collected from children treated in hospital compared to samples collected from children seen by their primary healthcare provider in the community. Regional strain variation highlights the importance of ensuring multi-center surveillance to help monitor program effectiveness when rotavirus vaccines are introduced into New Zealand's national childhood immunization schedule.

Gr1int/high Cells Dominate the Early Phagocyte Response to Mycobacterial Lung Infection in Mice.

Lung infection by Mycobacterium tuberculosis is characterized by chronic infection of lung-resident macrophages, long considered to be the primary hosts and determinants of the outcome of the early immune response. Although alveolar macrophages are well-known to host intracellular mycobacteria at later stages of disease, little is known about the earliest events of the innate immune response. The phagocytes that take up mycobacteria immediately following infection, and how the early lung phagocyte response is altered by vaccination with M. bovis bacille Calmette-Guérin (BCG) were unknown. Using BCG expressing the bright red fluorescent protein tdTomato and flow cytometry, we modeled early infection in C57BL/6 mice and tracked phagocyte population kinetics and uptake of mycobacteria, to better understand the involvement of specific phagocyte subsets. By 1 day post-infection, dose-dependent accumulation of neutrophils was observed and surprisingly, granulocytes comprised a greater proportion of infected phagocytes than alveolar macrophages. By 7 days post-infection alveolar macrophages had become the dominant BCG-associated phagocytes. Prior mucosal BCG exposure provided immunized mice with greater frequencies and numbers of lung macrophage subsets, and a significantly greater proportion of alveolar macrophages expressed CD11b prior to and following challenge infection. These data provide the first evidence of granulocytes as the dominant infected phagocyte subset early after mycobacterial infection, and highlight enhanced recruitment of lung macrophages as a factor associated with protection in BCG-immunized mice.

TCR- or Cytokine-Activated CD8+ Mucosal-Associated Invariant T Cells Are Rapid Polyfunctional Effectors That Can Coordinate Immune Responses.

Mucosal-associated invariant T (MAIT) cells can be activated via either their T cell receptor (TCR), which recognizes MR1-bound pyrimidines derived from microbial riboflavin biosynthesis, or via cytokines. These two modes of activation may act in concert or independently, depending upon the stimulus. It is unknown, however, how MAIT cell responses differ with the mode of activation. Here, we define transcriptional and effector responses of human CD8+ MAIT cells to TCR and cytokine stimulation. We report that MAIT cells rapidly respond to TCR stimulation, producing multiple cytokines and chemokines, altering their cytotoxic granule content and transcription factor expression, and upregulating co-stimulatory proteins. In contrast, cytokine-mediated activation is slower and results in a more limited response. Therefore, we propose that, in infections by riboflavin-synthesizing bacteria, MAIT cells play a key early role in effecting and coordinating immune responses, while in the absence of TCR stimulation, their role is likely to differ.

Langerin+ CD8α+ Dendritic Cells Drive Early CD8+ T Cell Activation and IL-12 Production During Systemic Bacterial Infection.

Bloodstream infections induce considerable morbidity, high mortality, and represent a significant burden of cost in health care; however, our understanding of the immune response to bacteremia is incomplete. Langerin+ CD8α+ dendritic cells (DCs), residing in the marginal zone of the murine spleen, have the capacity to cross-prime CD8+ T cells and produce IL-12, both of which are important components of antimicrobial immunity. Accordingly, we hypothesized that this DC subset may be a key promoter of adaptive immune responses to blood-borne bacterial infections. Utilizing mice that express the diphtheria toxin receptor under control of the langerin promoter, we investigated the impact of depleting langerin+ CD8α+ DCs in a murine model of intravenous infection with Mycobacterium bovis bacille Calmette-Guerin (BCG). In the absence of langerin+ CD8α+ DCs, the immune response to blood-borne BCG infection was diminished: bacterial numbers in the spleen increased, serum IL-12p40 decreased, and delayed CD8+ T cell activation, proliferation, and IFN-γ production was evident. Our data revealed that langerin+ CD8α+ DCs play a pivotal role in initiating CD8+ T cell responses and IL-12 production in response to bacteremia and may influence the early control of systemic bacterial infections.

DNA vaccination: the answer to stable, protective T-cell memory?

Distinct populations of both CD4(+) and CD8(+) memory T cells have been identified on the basis of their location (lymphoid versus non-lymphoid tissues) and function. There have been several recent advances in our understanding of the factors that govern the generation and maintenance of T-cell memory in vivo. Utilising this knowledge could contribute to the refinement of DNA vaccine technology to induce more robust and longer-lasting protective T-cell based immunity.

Half-truths and selective memory: Interferon gamma, CD4(+) T cells and protective memory against tuberculosis.

Efforts to develop a new, more effective vaccine for tuberculosis have been hampered by a lack of understanding of what constitutes a protective memory immune response. While interferon gamma production by CD4(+) T cells after vaccination is commonly used as a surrogate of protective memory immunity, its use in this regard appears to have little predictive value. We argue that this is due to the different requirements for interferon gamma-mediated protection in the primary response versus the memory recall response. In this review, we present evidence that suggests memory CD4(+) T cells can protect against tuberculosis in the absence of interferon gamma, and discuss potential mechanisms that may be involved such as IL-17 and regulatory T cells. A comprehensive understanding of the requirements for protective memory immunity to tuberculosis is essential for the development of an effective vaccine.

The Memory Immune Response to Tuberculosis.

Immunological memory is a central feature of the adaptive immune system and a prerequisite for generating effective vaccines. Understanding long-term memory responses to Mycobacterium tuberculosis will thus provide us with valuable insights that can guide us in the search for a novel vaccine against tuberculosis (TB). For many years, triggering CD4 T cells and, in particular, those secreting interferon-γ has been the goal of most TB vaccine research, and numerous data from animals and humans support the key role of this subset in protective immunity. More recently, we have learned that the memory response required for effective control of M. tuberculosis is much more complex, probably involving several phenotypically different CD4 T cell subsets as well as other cell types that are yet to be defined. Herein, we describe recent insights into memory immunity to TB in the context of both animal models and the human infection. With the increasing amount of data generated from clinical testing of novel TB vaccines, we also summarize recent knowledge of vaccine-induced memory immunity.

IL-1ßR-dependent priming of antitumor CD4+ T cells and sustained antitumor immunity after peri-tumoral treatment with MSU and mycobacteria.

Local immune-activating therapies seek to improve the presentation of tumor antigen, thereby promoting the activation of antitumor CD8+ T cells and delaying tumor growth. Surprisingly, little is known about the ability of these therapies to stimulate antitumor CD4+ T cells. We examined tumor-specific CD4+ T cell responses after peri-tumoral administration of the TLR3 agonist polyinosinic-polycytidylic acid (poly I:C), or the danger signal monosodium urate crystals in combination with Mycobacterium smegmatis (MSU + Msmeg) in mice. Both treatments delayed tumor growth, however, only MSU + Msmeg induced proliferation of tumor-specific CD4+ T cells in the draining lymph node (dLN). In line with the proliferation data, administration of MSU + Msmeg, but not poly I:C, enhanced the infiltration of CD4+FoxP3- T cells into the tumor, increased their capacity to produce IFNγ and TNF-α, and decreased PD-1 expression on tumor-infiltrating CD8+ T cells. Induction of CD4+ T cell proliferation by treatment with MSU + Msmeg required IL-1ßR signaling, as it was blocked by administration of the IL-1ßR antagonist Anakinra. In addition, treatment with Anakinra or with anti-CD4 also reversed the increased survival after tumor challenge in MSU + Msmeg treated mice. Thus, peri-tumoral treatment with MSU + Msmeg results in IL-1ßR-dependent priming of antitumor CD4+ T cells in the LN, with consequent superior activation of CD4+ and CD8+ T cells within the tumor, and sustained antitumor activity.