Immune Basis of Arterial Hypertension

Vazquez, Randy

January 2010

A better understanding of these structural changes that occur before Hypertension (HTN) could ultimately result in a treatment that can prevent or reverse this disease state before its onset. T cells have been shown essential for the development of HTN. The aim of these murine studies was to investigate the role of the T-helper CD4⁺ lymphocytes in initiating vascular remodeling and HTN in the absence of an increased mechanical load and to investigate the role of T-helper 17 (Th17) CD4⁺ lymphocyte initiating vascular remodeling and HTN by stimulating Lysyl Oxidase (LOX). LOX is known to cross-link collagen and elastin and. Excess synthesis of collagen and elastin results in a stiffer artery and hypertension. We established L-NAME-induce HTN in wild type (WT) mice. CD4⁺ splenic lymphocytes were isolated from these mice and adoptively transferred into naïve syngeneic severe combined immunodeficient (SCID) mice. The SCID mice receiving these cells became hypertensive. Cytokine analysis demonstrated an increase in both Th1 and Th17 cytokine in HTN donor mice and of lymphocytes in the aortic infiltrates of the HTN recipient mice. The increased collagen and LOX expression in recipient mice suggest that the adoptively transfer CD4⁺ lymphocytes are associated with vascular extracellular matrix remodeling. Furthermore we examined the role of Th17 lymphocyte in aortic LOX regulation in Angiotensin II-induced hypertension. The Increase in blood pressure and Velocity Time Integral (VTI) was measured in WT Angiotensin II treated mice whereas no change was detected in the Th17 deficient (RORT KO) Angiotensin II treated group. When compared to the control group the WT group infused with Angiotensin II had higher LOX protein expression, LOX fluorescent Immunohistochemical stain and LOX activity. This group also had increased hydroxyproline levels, collagen stain, hyperplasia and aortic thickening. In contrast, the Th17 deficient mice Angiotensin II treated group had no changes in these parameters. The results provide evidence that IL-17 mediates Angiotensin II-induced hypertension and vascular dysfunction by the overstimulation of LOX. Potentially targeting T17 cells will allow for a drug-specific therapeutic approach and delay the progression of hypertension pathology.

Angiotensin II

Extracellular Matrix

Hypertension

L-NAME

Lysyl Oxidase (LOX)

T-helper (Th)-17 lymphocytes

The role of insulin, peptide YY and the immune system in the pathogenesis of type 2 diabetes

Viardot, Alexander, Garvan Institute of Medical Research, Faculty of Medicine, UNSW

January 2008

Obesity and type 2 diabetes (T2D) are associated with insulin resistance and increased levels of inflammation markers, suggesting activation of the immune system. However, the link between this so called ??low-grade inflammation?? and insulin resistance is poorly understood. In this thesis we aimed to investigate the direct effects of insulin on immune cells, and if these effects are changed in the setting of insulin resistance. We showed that insulin has anti-inflammatory effects by shifting T cell differentiation into a T helper type 2 phenotype. This effect was lost in insulin resistant subjects, which resulted in a more pro-inflammatory T helper type 1 cell hyperpolarisation. We also demonstrated that the Th1/2 balance is related to the degree of insulin resistance, and varies accordingly in clinical models of increasing or decreasing insulin resistance. Furthermore, we demonstrated that in a very early stage of pre-diabetes, where normal glucose tolerance and insulin sensitivity are still preserved, we cannot detect any immune activation, but we see a blunted food response of the appetite suppressant hormone PYY. Whilst this could put subjects at risk for further weight gain and development of obesity and T2D, we also demonstrated for the first time that PYY itself has strong anti-inflammatory properties, and that a deficiency in PYY could result in promoting a pro-inflammatory environment. In summary, we could demonstrate strong evidence that both, insulin and PYY are potent anti-inflammatory hormones which modulate immune function, and the observed deficiency in these hormones could contribute to further increase in inflammation and disease progression. Further work is indicated in this area to better understand the sequence and mechanism of immune activation, which may open up new therapeutic avenues for prevention and treatment of T2D.

Insulin resistance

Type 2 diabetes

Immune system

Inflammation

PYY

T helper cells

Early growth response genes 2 and 3 are potent inhibitors of T-bet function for interferon gamma production in T-cells

Singh, Randeep

January 2016

Early growth response (Egr) gene 2 and 3 are genes encoding transcription factors important for maintaining immune homeostasis. Here we define a fundamental role of Egr2 and 3 to control T cell proliferation and differentiation of effector T cells. Egr2 and Egr3 deficiency in T cells resulted in impaired T cell proliferation, but hyper-activation and excessive differentiation of T cells in response to viral infection, while, conversely, sustained Egr2 expression enhanced proliferation, but severely impaired effector differentiation in to T helper (Th) subsets, such as, Th1 and Th17 subtypes. T-bet is important for differentiation of effector T cells in response to pathogen and in particular it is a master regulator for modulating the T helper 1 lineage specific differentiation programme. Although T-bet has been extensively studied in T cells, the regulation of T-bet function is less well known. We have now discovered that Egr2 and 3 are potent inhibitors for Tbet function in CD4 and CD8 effector T cells. Together with Egr2 and 3, T-bet is induced in naïve T cells by antigen stimulation, but the expression was reciprocally regulated by IFNγ, which inhibited Egr2 and 3, but promoted Tbet expression. The expression of Egr2 and 3 in CD4 T cells under TH2 and TH17 condition was essential to suppress TH1 differentiation in vitro. In response to viral infection, sustained Egr2 expression in T cells profoundly inhibited differentiation of effector cells, while Egr2 and 3 deficient T cells produced excessive levels of IFNγ. We found that both Egr2 and 3 can directly interact with the Tbox domain of T-bet, block its DNA binding and inhibit T-bet mediated production of IFNγ. Thus, Egr2 and 3 are antagonists for T-bet function in effector T cells and essential for the control of T cell differentiation and immune pathology.

616.07

INFLUENCE OF GAMMA-SECRETASE INHIBITOR ON CYTOKINE-INDUCED APOPTOSIS IN BREAST CANCER CELL LINES

Bagale, Abhishek

18 May 2021

No description available.

Biomedical Research

Biology

Immunology

Breast Cancer

Nirogacestat

Apoptosis

Immunotherapy

T-helper 1

IFN-gamma

TNF-alpha

ASSOCIATION OF IMMUNE DYSFUNCTION WITH MICROBIAL DYNAMICS AND ABERRANT ESTROGEN METABOLISM IN REPRODUCTIVE DISORDERS

Le, Nhung Xuan Hong

01 June 2021

Chronic inflammation is associated with the pathophysiology of obstetrical disorders (e.g. preterm birth [PTB]) and gynecological diseases (e.g. endometriosis); however, the exact mechanism(s) for these conditions are unknown. Numerous immunological conditions and disease states (e.g. inflammatory bowel disease, Crohn’s disease, systemic lupus erythematomus) also disrupt the microbiome homeostasis by inducing a number of changes in the microbial flora when compared to that of healthy individuals. Furthermore, the gastrointestinal (GI) microbiome is one of the principal regulators of circulating estrogens which are known to directly impact the female reproductive disorders endometriosis and PTB. Thus, an alteration of microbial species could indicate a shift in immune balance from homeostatic to pro-inflammatory, and an aberrant estrogen metabolism that precipitates the development of disease stages in endometriosis and/or PTB. The Braundmeier-Fleming lab has developed a systems biology model that investigates the interactions between the immune system, microbial dynamics (in the GI and reproductive system) and estrogen metabolism, in women, as a potential diagnostic tool for endometriosis and PTB. This dissertation, therefore, examined how inflammation triggered by female reproductive disorders (endometriosis or PTB) alter the systemic and localization immune responses, the microbial communities in the urogenital (UG), peritoneal and GI mucosal epithelium, as well as levels of excreted conjugated estrogen. The first specific hypothesis is that inflammation associated with endometriosis alters microbial dynamics and functions that are distinct from those of non-diseased patients. Preliminary data indicated that reproductive tract microbial communities from patients with endometriosis are unique when compared to non-disease patients. Therefore, the central aims of this study are to identify the immune and microbial profiles of patients diagnosed with endometriosis and determine if an alteration of these profiles impact estrogen signaling, thus driving disease pathogenesis. Additionally, I hypothesized that surgery or hormonal therapy will temporarily restore the microbiome and estrogen levels of patients with endometriosis. Differences in systemic (blood) regulatory T cell (Treg) and T-helper 17 (Th17) cell populations (tolerant and inflammatory, respectively) were measured by flow cytometry, and the immune mediators was measured by serum cytokine levels via 10-plex-ELISA kits. Immunohistochemistry was used to identify resident Th17/Treg immune cell distribution within the endometrium and ectopic endometriotic lesions, and RORγt+/FOXP3+ transcripts within these same tissues were analyzed by real-time-qPCR. We implemented high-throughput non genomic sequencing targeting bacterial-V4 16S rRNA and robust bioinformatics analyses to characterize microbial composition/diversity within the GI (fecal swab), vaginal (vaginal swab), and UG (urine) cavities. Alterations in estrogen metabolism, parent estrogens and metabolites, in urine were analyzed via LC-MS/MS. Patients with endometriosis exhibit 1) systemic and localized inflammation within ectopic and endometrial tissues, 2) altered GI/UG microbial dynamics, 3) aberrant levels of endogenous estrogen and estrogen metabolites, 4) dampened inflammation (caused by disease) due to hormonal therapy, 5) altered bacteria populations in the gut and vaginal canal of patients with endometriosis due to hormonal therapy treatment, and 6) increased post-surgical variability in microbial community dynamics. The second specific aims examined the hypothesis that induction of endometriosis in baboons (P. Anubis) results in chronic systemic and tissue specific inflammation through regulation of Th17 and Treg populations. Further, the induction of endometriosis altered GI/UG/peritoneal cavity microbial communities that are distinct from non-diseased animals. Utilizing a non-human primate animal model of induced endometriosis allowed us to characterize factors involved at the early onset of endometriosis and throughout the disease progression. We collected samples from 8 baboons at pre-inoculation (no evidence of disease) and at 3, 6, 9, and 15 months post-induction of the disease. We found that the induction of endometriosis decreased peripheral Tregs cells while Th17 cells increased at all post-induction collections with reduced ratio of total Tregs to Th17 cells indicating systemic inflammation. Microbial community diversities as well as abundances at each sample site (GI, UG [vagina, urine] tracts and peritoneal cavity) were also altered at post-induction. These results therefore suggest that induction of endometriosis in non-human primates caused an inflammatory shift. Disease induction also resulted in altered vaginal, urinary and fecal microbial profiles, which may drive inflammation through the production of inflammatory mediators. The last specific aims studied the hypothesis that patients who deliver preterm have a systemic and placental inflammatory phenotype and abnormal estrogen levels during pregnancy that are distinct from those of patients with term delivery. Biological samples were collected at 8-12 weeks, 20-24 weeks, 32-36 weeks, at delivery and 6 weeks postpartum. Subjects with PTB showed signs of systemic inflammation with an elevation in Th17:Treg ratio, greater Th17 and lower levels of natural Tregs during the 2nd trimester, and lower inducible Tregs during the 3rd trimester and at delivery. Placental tissues from subjects with PTB also had an inflammatory immune phenotype (higher Th17) within the decidua basalis and maternal-fetal interface. Immunological shifts from tolerant to inflammatory were observed in both patient groups, but these shifts occurred early in gestation for subjects with PTB and at a later gestational age for subjects delivering at term. Levels of conjugated parent estrogens and estrogen metabolites were reduced in subjects with PTB, indicative of an abnormal production of estrogen. These analyses gave us a better understanding of the inflammatory cascade with estrogen metabolism associated with pregnancy, and how these effects are correlated with premature labor. The data from this study suggest that the levels of endogenous estrogen and estrogen metabolites of estrogen metabolism were abnormal in PTB and endometriosis disease models of inflammation compared to their respective controls. In the human and non-human primate model of endometriosis studies, we observed that both patients and baboons with endometriosis had systemic and resident inflammatory phenotypes and an alteration in mucosal microbial community dynamics compared to their respective controls. All together, our long-term goal is to identify factors from the microbiome and/or the immune system that would allow us to have early non-invasive diagnostics for endometriosis or to predict which mothers are most at risk to encounter PTB. Furthermore, it would allow us to determine whether the mucosal microbiome may be a good indicator of immune stress, and if alternative therapies can alter microbial community dynamics—thereby eliminating immune stress associated with female reproductive diseases. These findings may have a substantial impact on the obstetrical care and management of patients with endometriosis and women at risk for PTB, as well as provide evidence to support the development of novel therapeutics to treat these diseases.

Endometriosis

Estrogen metabolism

Microbiome

Preterm Birth

Regulatory T cell

T helper 17

β-Glucan Exacerbates Allergic Airway Responses to House Dust Mite Allergen

Hadebe, Sabelo, Kirstein, Frank, Fierens, Kaat, Redelinghuys, Pierre, Murray, Graeme I., Williams, David L., Lambrecht, Bart N., Brombacher, Frank, Brown, Gordon D.

02 April 2016

β-(1,3)-Glucan is present in mould cell walls and frequently detected in house dust mite (HDM) faeces. β-Glucan exposure is thought to be associated with pulmonary allergic inflammation in mouse and man, although the published data are inconsistent. Here, we show that highly purified β-glucan exacerbates HDM-induced eosinophilic, T helper 2 type airway responses by acting as an adjuvant, promoting activation, proliferation and polarisation of HDM-specific T cells (1-Derβ T cells). We therefore provide definitive evidence that β-glucan can influence allergic pulmonary inflammation.

allergy

eosinophil

house dust mite

T helper 2

β-glucans

Surgery

Mucin Biosynthesis: Upregulation of Core 2 β1,6 N- Acetylglucosaminyltransferase by Retinoic Acid and Th2 Cytokines in a Human Airway Epithelial Cell Line

Beum, Paul V., Basma, Hesham, Bastola, Dhundy R., Cheng, Pi Wan

01 January 2005

Vitamin A and the T helper 2 cytokines IL-4 and IL-13 play important roles in the induction of mucin gene expression and mucus hypersecretion. However, the effects of these agents on enzymes responsible for mucin glycosylation have received little attention. Here, we report the upregulation of core 2 β1,6 N-acetylglucosaminyltransferase (C2GnT) activity both by all-trans retinoic acid (RA) and by IL-4 and IL-13 in the H292 airway epithelial cell line. Northern blotting analysis showed that the M isoform of C2GnT, which is expressed in mucus-secreting tissues and can form all mucin glycan β1,6-branched structures, including core 2, core 4, and blood group I antigen, was upregulated by both RA and IL-4/13. The L isoform, which forms only the core 2 structure, was moderately upregulated by IL-4/13 but not by RA. Enhancement of the M isoform of C2GnT by RA was abolished by an inhibitor, of RA receptor α, implicating RA receptor α in the effect of RA. Likewise, an inhibitor of the Janus kinase 3 pathway blocked the enhancing effects of IL-4/13 on the L and M isoforms of C2GnT, suggesting a role of this pathway in the upregulation of these two C2GnTs by these cytokines. Taken together, the results suggest that IL-4/13 T helper 2 cytokines and RA can alter the activity of enzymes that synthesize branching mucin carbohydrate structure in airway epithelial cells, potentially leading to altered mucin carbohydrate structure and properties.

core 2 glycosyltransferases

interleukin-13

interleukin-4

mucin carbohydrate

T helper 2

STAT PROTEIN REGULATION OF FOXP3 EXPRESSION AND INFLAMMATORY CYTOKINE PRODUCTION IN T HELPER CELL SUBSETS

O'Malley, John Thomas

19 March 2009

Indiana University-Purdue University Indianapolis (IUPUI) / The differentiation of naïve CD4+ T cells into subsets of T helper cells (Th) is an essential process that impacts host defense and the pathogenesis of immunemediated diseases. Signal transducers and activators of transcription (STAT) proteins, activated downstream of instructive cytokines, dictate and perpetuate the lineage decision of Th cells through both positive and negative effects. This is accomplished by regulating transcription factors, surface receptors and promoting epigenetic changes in gene expression through chromatin remodeling. Transforming growth factor-β1 (TGF-β1) can induce Foxp3 in developing Th cells and these Foxp3-expressing adaptive T regulatory cells (aTregs) are able to suppress inflammation in vitro and in vivo. To define the mechanism by which STAT proteins regulate Th cell pro- and anti-inflammatory phenotypes, we examined T cells deficient in Stat3, Stat4, and Stat6 as well as T cells expressing two STAT4 isoforms after being cultured in the presence or absence of TGF-β1 and cytokines known to be instructive in Th cell development. The negative effects of STAT proteins are demonstrated by our results indicating STAT3, STAT4 and STAT6 proteins activated downstream of the instructive cytokines IL- 6, IL-12 and IL-4, respectively, negatively regulate the development of TGF-β induced Foxp3 and aTreg development. STAT3, STAT4, and STAT6 utilize a vi Mark H. Kaplan, Ph.D., Chair common mechanism to inhibit aTreg generation by inhibiting STAT5, a positive regulator of Foxp3 expression, from binding to the Foxp3 gene. STAT proteins positively effecting inflammatory immunity are demonstrated by our analysis of STAT4 isoforms and their ability to regulate the production of proinflammatory cytokines downstream of IL-12. STAT4β, a STAT4 splice isoform that lacks a Cterminal domain, and STAT4α, a full-length isoform are both capable of mediating inflammatory cell development. However, STAT4β promotes greater inflammation in vivo than STAT4α independent of its ability to repress Foxp3. Instead, the inflammation correlates with STAT4 isoform-dependent expression of inflammatory cytokines. Thus, cytokine-stimulated STAT proteins orchestrate T helper cell pro- and anti-inflammatory cell phenotypes.

T helper cells

Stat proteins

Stat4

cytokines

inflammation

Foxp3

Phenotype

Transcription factors

Cytokines

T cells -- Differentiation

Novel Immunogens Of Cellular Immunity Revealed Using In Vitro Human Cell-based Approach

Schanen, Brian

01 January 2012

In the last 150 years, tremendous headway has been made in our understanding of the human immune system. Pioneers in the field such as Paul Ehrlich, Elie Metchnikoff, Louis Pasteur, Robert Koch and Walter Reed carried out seminal studies that established the groundwork for our understanding of humoral and cellular immunity in humans. However, this direct line of evidence into human immunology was diverted in the mid-20th century with the adoption of a model which allowed for investigators to use a reductionist-approach with the promise to resolve immunity at a molecular level. This revolutionary model was the scientific commercialization of various inbred strains of mice. It seems inconceivable how a four-legged nocturnal rodent managed to become the focus of billions of dollars of research to improve our understanding of human immunity. Nevertheless, this strange surrogate for human immunity did provide us with major conceptual advances in areas, such as identification of dendritic cell population heterogeneity, T cell help for B cell antibody production, MHC-restricted recognition of virusinfected cells, and even the discovery of cell types like NKT cells. However, these prior advances have now been prefaced with decades-worth of disappointing, non-translational findings. The best examples of such disappointments are in murine models of autoimmunity, cancer immunotherapy, and vaccinology where numerous studies have revealed promising outcomes in mice but were met with failure or limited success upon translation into humans. We do not look at this as a failure of the murine model; rather we consider it a call to arms to innovate in vitro surrogates to examine human immunity when otherwise bound by ethical limitation from working directly in humans. To overcome these challenges, we developed a system to interrogate novel immunogens that begins by generating human dendritic cells (DCs), a cell type necessary to mounting a protective immune response. DCs for research and clinical applications are typically derived from purified blood monocytes that are cultured in a cocktail of cytokines for a week or more. Because it has been iv suggested that these cytokine-derived DCs may be deficient in some important immunological functions and might not accurately represent antigen presenting cell (APC) populations found under normal conditions in vivo, there is an interest in developing methods that permit the derivation of DCs in a more physiologically relevant manner in vitro. Here, we describe a simple and reliable technique for generating large numbers of highly purified DCs that is based on a one-way migration of blood monocytes through a layer of human umbilical vein endothelial cells (HUVECs) that are cultured to confluency in the upper chamber of a Transwell device. The resultant APCs, harvested from the lower Transwell chamber, resemble other cultured DC populations in their expression of major histocompatibility (MHC) and costimulatory molecules, ability to phagocytose protein antigens and capacity to trigger primary antigen-specific T cell responses. This technique offers several advantages over the standard method of in vitro cytokine-driven DC development, including: (1) the rapidity of this approach, as DC differentiation occurs in only 2 days, (2) the differentiation process itself, which is more akin to the development of DCs under physiologic conditions and (3) the cost effectiveness of the system, since no monocyte pre-selection is required and DC development occurs in the absence of expensive recombinant cytokines. Taken together, this approach allows for the exploration of novel immunogens utilizing a physiologically representative population of APCs enriched from circulating blood. The outbreak of the swine-origin H1N1 influenza in the spring of 2009 took epidemiologists, immunologists, and vaccinologists by surprise and galvanized a massive worldwide effort to produce millions of vaccine doses to protect against this single virus strain. Of particular concern was the apparent lack of pre-existing antibody capable of eliciting cross-protective immunity against this novel virus, which fueled fears this strain would trigger a particularly far-reaching and lethal pandemic. Given that disease caused by the swine-origin virus was far less severe than expected, we hypothesized v cellular immunity to cross-conserved T cell epitopes might have played a significant role in protecting against the pandemic H1N1 in the absence of cross-reactive humoral immunity. We collaborated with bioinformaticians to develop an immunoinformatics approach to predict CD4+ T cell epitopes conserved between the 2008-2009 seasonal H1N1 vaccine strain and pandemic H1N1 (A/California/04/2009) hemagglutinin proteins that could act as novel immunogens and function as potential vaccine candidates or compliments to current vaccine formulations. We examined these peptides using T cells from human donors not exposed to the pandemic virus demonstrating that pre-existing CD4+ T cells can elicit cross-reactive effector responses against the pandemic H1N1 virus. As well, we showed the computational tools created by our collaborators were 80-90% accurate in predicting CD4+ T cell epitopes and their HLA-DRB1-dependent response profiles in donors that were chosen at random for HLA haplotype. Combined, these results confirm the power of coupling immunoinformatics to define broadly reactive CD4+ T cell epitopes with a highly sensitive in vitro model to verify these in silico predictions as a means to understand human cellular immunity, including cross-protective responses, and to define CD4+ T cell epitopes for potential vaccination efforts against future influenza viruses and other pathogens. It is thought that utilizing highly conserved peptides as novel immunogens of cellular immunity for future vaccination strategies may require an adjuvant for efficacy. However, the FDA has approved the use of only two adjuvant compounds (Alum or MPL®) which may not be compatible or offer effective immune enhancement in novel vaccine preparations, thereby soliciting the need for novel adjuvants. Nanoparticles have since been a topic of adjuvant potential. Nanoparticles harbor great potential because they possess unique physicochemical properties compared to their larger counter parts as a result of quantum-size effects and their inherent large surface area to volume ratio. These physicochemical properties govern how a nanoparticle will behave in its environment. However, vi researchers have only just begun to catalogue the biological effect these properties illicit. Moreover, little is known about the interaction between the immune system and NPs. However, in light of the recent development in new adjuvants that involves composites and coatings of polymers, lipids, ligands, TLR agonist, the ability of a simple metal oxide nanopowder to effectively induce or couple immunomodulation would provide researchers a basic alternative to costly and complex adjuvant development. Considering the evidence suggesting NPs can act as immunopotentiators, we questioned whether these materials can act not only as innate adjuvants, but as novel immunogens to cellular immunity. To accomplish this, we under took a set of studies to investigate any nanoparticle size-induced effects using TiO2, one of the most widely manufactured nanoparticles, as a model. We explored titanium dioxide synthesized into its three most commonly nanoarchitectures: anatase (7-10 nm), rutile (15-20 nm), and nanotube (10-15 nm diameters, 70-150 nm length) in comparison to a micron-sized formulation. We used the fully human autologous MIMIC® immunological construct has been utilized as a predictive, nonanimal alternative to diagnose nanoparticle immunogenicity. Cumulatively, treatment with titanium dioxide nanoparticles in the MIMIC® system led to elevated levels of proinflammatory cytokines and increased maturation and expression of costimulatory molecules on dendritic cells. Additionally, these treatments effectively primed activation and proliferation of naïve CD4+ T cells in comparison to dendritic cells treated with titanium dioxide microspheres, characteristic of an in vivo inflammatory response, providing evidence of a size induced difference between the nano-sized and micron-sized material, revealing novel immune cell recognition and activation by a crystalline nanomaterial in a size-dependent manner. Having identified nanomaterial size as a contributing feature of nanoparticle induced immunopotentiation, we became interested if additional physicochemical properties such as surface vii reactivity or catalytic behavior could also be immunostimulatory. Moreover, because we witnessed a stimulatory effect to dendritic cells following nanoparticle treatment, we were curious how these nanoparticle-touched dendritic cells would impact adaptive immunity. Since TiO2 acts as an oxidant we chose an antioxidant nanoparticle, CeO2, as a counterpart to explore how divergent nanoparticle surface reactivity impacts innate and adaptive immunity. We focused on the effect these nanoparticles had on human dendritic cells and TH cells as a strategy towards defining their impact to cellular immunity. Combined, we report that TiO2 nanoparticles potentiate DC maturation inducing the secretion of IL- 12p70 and IL-1B, while treatment with CeO2 nanoparticles induced IL-10, a hallmark of suppression. When delivered to T cells alone TiO2 nanoparticles induced stronger proliferation in comparison to CeO2 which also stimulated TReg differentiation. When co-cultured in allogeneic T cell assays, the materials directed alternate TH polarization whereby TiO2 drives largely a TH1 dominate response, whereas CeO2 drove a TH2 bias. Combined, we report a novel immunomodulatory capacity of nanomaterials with catalytic activity. While unintentional exposure to these nanomaterials could pose a serious health risk, development and targeted use of such immunomodulatory nanoparticles could provide researchers with new tools for novel adjuvant strategies or therapeutics.

Human

immune system

dendritic cells

nanoparticle

t helper

immunomodulation

Molecular Biology

Regulation of the germinal center reaction by T helper cells and T regulatory cells

Wu, Hao

11 April 2016

Indiana University-Purdue University Indianapolis (IUPUI) / Germinal Centers (GCs) are transient lymphoid structures that arise in lymphoid organs in response to T cell-dependent antigen. Within the GC, follicular T helper (TFH) cells promote GC B cell differentiation and in turn the proper antibody production to protect us from invading pathogens. We wished to study the regulation of this process by transcription factors STAT3 and Bcl6. STAT3 is important for both TFH cell differentiation and IL-4 production by Th2 cells. IL-4 is a major functional cytokine produced by TFH cells. To dissect the role of STAT3 in IL-4 production by TFH cells, we generated T cell-specific conditional STAT3 knockout mice (STAT3KO). Compared to WT mice, TFH cell differentiation in STAT3KO mice was partially impaired, both in spleen following sheep red blood cells (SRBC) immunization and in Peyer's patches (PPs). In STAT3KO mice, the numbers of splenic GC B cells were markedly decreased, whereas PP GC B cells developed at normal numbers and IgG1 class switching was greatly increased. Unexpectedly, we found that STAT3 intrinsically suppressed the expression of IL-4 and Bcl6 in TFH cells. Mechanistically, in vitro repression of IL-4 expression in CD4 T cells by Bcl6 required STAT3 function. Apart from TFH cells, the GC reaction is also controlled by regulatory follicular T helper (TFR) cells, a subset of Treg cells. To study the mechanism of how TFR cells regulate the GC reaction, we generated mice specifically lacking TFR cells by specifically deleting Bcl6 in Treg cells. Following immunization, these "Bcl6FC" mice developed normal TFH and GC B cell populations. However, Bcl6FC mice produced altered antigen-specific antibody responses, with reduced titers of IgG and increased IgA. Bcl6FC mice also developed IgG antibodies with significantly decreased avidity to antigen in an HIV-1 gp120 "prime-boost" vaccine model. Additionally, TFH cells from Bcl6FC mice produced higher levels of Interferon-γ, IL-10 and IL-21. Loss of TFR cells therefore leads to highly abnormal TFH and GC B cell responses. Overall, our studies have uncovered unexpected regulatory roles of STAT3 in TFH cell function as well as the novel regulatory roles of TFR cells on cytokine production by TFH cells and on antibody production.

Antibody production

Bcl6

Follicular T helper cell

Germinal center

Regulatory follicular T helper cell

Stat3

Germinal centers

Lymph nodes

Lymphoid tissue

Th2 cells

Lymphocytes

Cytokines

Cell differentiation

Immunoglobulins

Pathogenic microorganisms

Transcription factors