Epigenetic Mechanisms Regulating the Functional Effects of Chronic Alcohol Exposure of Human Monocyte-derived Dendritic Cells

Parira, Tiyash

06 November 2018

The effects of alcohol abuse are multi-dimensional since alcohol is widely known to affect both the innate and adaptive immune systems. Recently, epigenetics has come into focus and has been implicated in many diseases as well as substance abuse disorders. Therefore, research efforts of understanding the epigenetic mechanisms underlying substance abuse effects including alcohol abuse have become more predominant. In our laboratory, we have studied different epigenetic changes induced by alcohol exposure including regulation of histone deacetylases (HDACs), histone quantity, and histone modifications such as acetylation and deacetylation. We have observed differential effects of acute and chronic alcohol exposure in human monocyte-derived dendritic cells (MDDCs) wherein our laboratory previously found that HDACs were modulated in MDDCs treated acutely with alcohol in vitro, and in MDDCs from alcohol users. Our previous work has also demonstrated that alcohol consumption affects the dendritic cell function by modulating inflammatory markers and cannabinoid receptors such as CB2 and GPR55 through epigenetic modifications. For instance, chronic alcohol exposure upregulates histone (H) 4 acetylation at lysine 12 (H4k12ac) and acute alcohol effects on histone acetylation are associated with an increase in GPR55 expression. The hypothesis of the study is that chronic alcohol modulates human MDDC function through epigenetic mechanisms. Therefore, the primary objective of this research project is to elucidate novel pathways involving histone post-translational modifications due to chronic alcohol exposure in human dendritic cells. For this study, monocytes isolated from commercially available human buffy coats were differentiated into MDDCs, which were treated with chronic alcohol levels of 0.1 % (100mg/dL) and 0.2 % (200mg/dL) for 5 days in the presence or absence of the histone acetyltransferase inhibitor NU9056 (50nM) or the GPR55 antagonist CID16020046 (5µM). Results showed that chronic alcohol levels upregulated H4K12ac in MDDCs and this was associated with a concomitant increase in GPR55 gene and protein expression. Further, NU9056 and CID16020046 were able to reduce alcohol-induced inflammatory chemokine MCP-2 and reactive oxygen species production indicating that H4K12ac may be an inflammation and oxidative stress regulator. Additionally, NU9056 and CID16020046 could potentially reduce alcohol-induced inflammation and serve as potential therapeutic targets for alcohol use disorders.

Alcohol Use Disorders

Epigenetics

Immunology

Immune System Diseases

Life Sciences

Medicine and Health Sciences

Understanding regulatory factors in the skin during vitiligo

Essien, Kingsley I.

08 December 2018

Vitiligo is an autoimmune disease of the skin characterized by epidermal depigmentation that results from CD8+ T cell-mediated destruction of pigment producing melanocytes. Vitiligo affects up to 1% of the population and current treatments are moderately effective at facilitating repigmentation by suppressing cutaneous autoimmune inflammation to promote melanocyte regeneration. In order to cause disease, CD8+ T cells must overwhelm the mechanisms of peripheral tolerance in the skin and if we understand the suppressive mechanisms that are compromised during vitiligo, we can potentially use this information to improve existing treatments or engineer novel interventions. Therefore, my goal is to characterize the regulatory factors in the skin that suppress depigmentation during vitiligo. Our lab has developed a mouse model of vitiligo that accurately reflects human disease and I used this model to demonstrate that regulatory T cells suppress CD8+ T cell-mediated depigmentation and interact with CD8+ T cells in the skin during vitiligo. In this model of disease, I investigated the molecules involved in regulatory T cell function and observed that the chemokine receptors CCR5 and CCR6 play different roles in regulatory T cell suppression. While CCR6 facilitates regulatory T cell migration to the skin, CCR5 is dispensable for migration but required for optimal regulatory T cell function. Additionally, I used our mouse model to demonstrate that Langerhans cells suppress the incidence of disease during vitiligo. Taken together the results from these studies provide novel insights into the mechanisms of suppression during vitiligo.

Vitiligo

Regulatory T Cells

Tregs

Langerhans cells

Immune System Diseases

Immunopathology

Skin and Connective Tissue Diseases

Danger and Disgust: The Role of Valence Weighting Bias

Boggs, Shelby T.

January 2019

No description available.

Psychology

Investigating the impact of cigarette smoke on the immunopathogenesis of chronic respiratory disease / CIGARETTE SMOKE IMPACT ON RESPIRATORY DISEASE IMMUNOPATHOLOGY

Cass, Steven P

January 2021

Overall, the work presented in this thesis explored the impact of cigarette smoke on the immunopathogenesis of respiratory disease. This thesis highlighted the determinantal impact of cigarette smoke on (auto)antibody levels and pulmonary macrophage composition. Work completed by Steven P Cass 2016-2021. / Cigarette smoke is an insidious insult that is associated with a spectrum of respiratory diseases that range from cancer to obstructive diseases such as chronic obstructive pulmonary disease (COPD), to restrictive diseases such as idiopathic pulmonary fibrosis (IPF). In this thesis, we explore how cigarette smoke impacts immune components that contribute to respiratory disease. To begin, we assessed the impact of cigarette smoke on airway antibody and autoantibody levels. We assessed sputum, a non-invasive method to sample the lower airways, to directly assess the presence of antibodies and autoantibodies in COPD. Total immunoglobulin M (IgM), IgG and IgA were detectable in the sputum of subjects. Notably, in patients with mild to moderate COPD, current smoking status was associated with decreased IgM and IgG. Next, using a comprehensive autoantigen array, we measured matched sputum and serum autoantibodies in 224 individuals. Serum autoantibodies were more abundant than sputum autoantibodies and correlated strongly between two independent COPD cohorts. Overall, the autoantibody profile of a patient with COPD was the same as a control subject. A proportion of autoantibody specificities were differentially expressed in patients with COPD with anti-tissue autoantibodies weakly associated with measures of emphysema. Taken together, these data suggested chronic cigarette smoke exposure was associated with limited differential expression of autoantibodies, but these changes were not a reliable method to identify COPD status. In our third study, we assessed the impact of cigarette smoke exposure on the composition and function of pulmonary macrophage subpopulations. Macrophages perform a central role in respiratory host defence and are implicated in the pathobiology of several respiratory diseases. Using a mouse model of cigarette smoke exposure, we reported cigarette smoke-induced expansion of CD11b+ macrophage subpopulations including monocyte-derived alveolar macrophages and interstitial macrophages. The altered pulmonary macrophage composition following cigarette smoke exposure contributed to attenuated fibrogenesis in a model of bleomycin-induced lung injury. This study offered insight to pulmonary macrophage composition and function following cigarette smoke exposure. This thesis summarises the original contributions and work completed during the course of this Ph.D., aimed at understanding the impact of cigarette smoke exposure on immune components central to respiratory disease. In conclusion, these findings shed light on the presence of (auto)antibodies in patients with COPD and the composition of macrophage subpopulations following cigarette smoke exposure. / Thesis / Doctor of Philosophy (PhD) / Currently there are 1.3 billion people who use tobacco across the world. The most common method to consume tobacco is by smoking cigarettes. Cigarette smoking is well-known to cause disease; however, smoking rates are still increasing with more daily cigarette smokers in 2012 than there were in 1980. In this thesis, we explore the impact of cigarette smoke upon the immune system. We first assessed whether cigarette smoking impacts the levels of antibodies, proteins that are produced by the immune system to protect against foreign bodies, in healthy individuals, cigarette smokers without disease and patients with chronic obstructive pulmonary disease (COPD). We found that current smokers had decreased antibodies in the airways, thus predisposing cigarette smokers to increased damage. In our second study, we measured the presence of airway and blood autoantibodies. These are antibodies that target self and have the potential to inflict damage. We discovered that patients with COPD had minor changes in autoantibodies and these changes were weakly associated with emphysema. In our third study, we evaluated the impact of cigarette smoke on lung macrophages, cells that eat and destroy foreign bodies, in a mouse model of cigarette smoke exposure. Cigarette smoke increased the number of bone marrow-derived macrophages and this change in macrophage populations was associated with a reduced wound healing ability. Overall, these studies offer insight into how cigarette smoke impairs the function of the immune system and contributes to lung disease.

Cigarette smoke

Respiratory disease

COPD

Autoantibodies

Macrophage

Immunology

Immune system

Tissue remodelling

MECHANISMS OF TGF BETA-INDUCED INHIBITION OF CD1D-MEDIATED ANTIGEN PRESENTATION

Ryan, Jennifer Carrie

18 November 2011

Indiana University-Purdue University Indianapolis (IUPUI) / CD1d is a cell surface glycolipid that, like Major Histocompatibility Complex (MHC) class I and MHC class II molecules, presents antigen. However, instead of peptides, CD1d presents lipids to Natural Killer (NK) T cells, a subset of T cells that express both NK cell markers and the T cell receptor and produces both T helper (Th) 1 and Th2 cytokines. Our lab focuses on the regulation CD1d-mediated antigen presentation. TGF beta is a known regulator of the immune system, such as controlling MHC class II antigen presentation. Further, TGF beta can activate the mitogen activated protein kinase (MAPK) p38, a known negative regulator of CD1d-mediated antigen presentation. Therefore, we hypothesized that TGF beta would be a negative regulator of CD1d-mediated antigen presentation, and our results showed a decrease in antigen presentation by CD1d in response to TGF beta treatment. However, this inhibition was not through p38 activation, as indicated by the absence of a rescue of CD1d-mediated antigen presentation in, TGF beta-treated, p38 dominant negative-expressing cells. Alternatively, the Smad pathway, the canonical pathway activated by TGF beta, was investigated through a lentivirus shRNA-mediated knockdown of Smad2, Smad3 and Smad4 proteins. Smad2 shRNA-expressing cells showed in an increase in CD1d-mediated antigen presentation, suggesting an inhibitory role for Smad2. In contrast, Smad3 shRNA-expressing cells did not differ from control cells. However, as in the case of Smad2, CD1d+ cells in which Smad4 was knocked down, were substantially better at CD1d-mediated antigen presentation than control cells, suggesting that it also negatively regulates antigen presentation. Overall, these studies demonstrate that the canonical TGF beta/Smad pathway regulates an important part of the host’s innate immune response, vis-à-vis CD1d-mediated antigen presentation.

Antigen presenting cells -- Regulation

Glycolipids -- Regulation

Immune system -- Regulation

Transforming growth factors-beta

T cells

S100A9 Sustains Myeloid-Derived Suppressor Expansion and Immunosuppression During Chronic Murine Sepsis

Alkhateeb, Tuqa, PharmD, Kumbhare, Ajinkya, MD, Bah, Isatou, BS, Elgazzar, Mohamed, PhD

12 April 2019

Myeloid-derived suppressor cells (MDSC) expand during sepsis, suppress both innate and adaptive immunity, and promote chronic immunosuppression, which characterizes the late/chronic phase of sepsis. We previously reported that the transcription factors Stat3 and C/EBPb synergize to induces the expression of microRNA (miR)-21 and miR-181b to promote MDSC expansion in a mouse model of polymicrobial sepsis that progresses from an early/acute proinflammatory phase to a late/chronic immunosuppressive stage. We also showed that Gr1+CD11b+ cells, the precursors of MDSCs, from mice genetically deficient in the inflammatory protein S100A9 lack miR-21 or miR-181b in late sepsis, and are not immunosuppressive. In the present study, we show that S100A9 induces miR-21 and miR-181b during the late sepsis phase. We find that S100A9 associates with and stabilizes the Stat3-C/EBPb protein complex that activates the miRNA promoters. Reconstituting Gr1+CD11b+ cells from the S100A9 knockout mice with late sepsis with S100A9 protein restores the Stat3-C/EBPb protein complex and miRNA expressions, and switches the Gr1+CD11b+ cells into the immunosuppressive, MDSC phenotype. Importantly, we find that this process requires IL-10 mediated signaling, which induces S100A9 translocation from the cytosol to the nucleus. These results demonstrate that S100A9 promotes MDSC expansion and immunosuppression in late/chronic sepsis by inducing the expression of miR-21 and miR-181b.

sepsis

MDSCs

immunosuppression

S100A9

Immune System

Bacterial Infections

Infectious Diseases

Inflammation

Critical Care

Time to Think Deeper when HSV is Presenting in an Unusual Way

Gleadhill, Claire, Macariola, Demetrio, Jr

12 April 2019

This study demonstrates the first case report in which an NK Cell deficiency initially presented as an asymptomatic disseminated herpes simplex viremia (HSV). A pre-term 13- day- old patient presented with disseminated HSV after investigation because his twin brother was found to have HSV vesicular lesions. The patient remained asymptomatic throughout the entire hospital course. While 40% of neonates never exhibit vesicular lesions, most of the infants will be symptomatic with DIC and/or respiratory and/or hepatic failure. The HSV development in his twin brother prompted immediate multiple HSV PCR testing even though he was asymptomatic. The results were positive for HSV in both plasma & nasopharynx. He received intravenous acyclovir treatment for 21 days. Both CSF & brain MRI studies demonstrated no CNS involvement. He was discharged home with oral acyclovir for one year. Two months after being off acyclovir he developed herpetic vesicles which resolved with acyclovir treatment. Currently, he is on chronic acyclovir treatment. Lymphocyte enumeration tests demonstrated NK cell deficiency. Typically, HSV is a virulent symptomatic infection especially when it presents with viremia. Here we have a case of asymptomatic HSV viremia. Likewise, HSV infection does not usually recur after 1 year of acyclovir treatment. Here, we have a child presenting with what seems to be recurrent congenital HSV infection even with adequate treatment. These atypical HSV presentations may have been due to NK cell deficiency. We, therefore, propose that clinicians should consider NK cell deficiency as possible etiology when HSV presents in an atypical manner as described in our case.

HSV

NK cell deficiency

congenital

asymptomatic

Communicable Diseases

Immune System Disorders

Infectious Diseases

Modification of extracellular matrix by the product of DHA oxidation promotes retention of macrophages and progression of chronic inflammation

Casteel, Jared, Keever, Kasey R, Ardell, Christopher L, Williams, David L, Gao, Detao, Podrez, Eugene A, Byzova, Tatiana V, Yakubenko, Valentin P

25 April 2023

Oxidation of polyunsaturated fatty acids contributes to different aspects of the inflammatory response due to the variety of products generated. Specifically, the oxidation of DHA produces the end-product, carboxyethylpyrrole (CEP), which forms a covalent adduct with proteins via an ϵ-amino group of lysines. Previously, we found that CEP formation is dramatically increased in inflamed tissue and CEP-modified albumin and fibrinogen became ligands for αDß2 (CD11d/CD18) and αMß2 (CD11b/CD18) integrins. In this study, we evaluated the effect of extracellular matrix (ECM) modification with CEP on the adhesive properties of M1-polarized macrophages, particularly during chronic inflammation. Using digested atherosclerotic lesions and in vitro oxidation assays, we demonstrated the ability of ECM proteins to form adducts with CEP, particularly, DHA oxidation leads to the formation of CEP adducts with collagen IV and laminin, but not with collagen I. Using integrin αDß2-transfected HEK293 cells, WT, and αD-/- mouse M1- polarized macrophages, we revealed that CEP-modified proteins support stronger cell adhesion and spreading when compared with natural ECM ligands such as collagen IV, laminin, and fibrinogen. Integrin αDß2 is critical for M1 macrophage adhesion to CEP. Based on biolayer interferometry results, the isolated αD I-domain demonstrates markedly higher binding affinity to CEP compared to the “natural” αDß2 ligand fibrinogen. Finally, the presence of CEP-modified proteins in a 3D fibrin matrix significantly increased M1 macrophage retention. Therefore, CEP modification converts ECM proteins to αDß2- recognition ligands by changing a positively charged lysine to negatively charged CEP, which increases M1 macrophage adhesion to ECM and promotes macrophage retention during detrimental inflammation, autoimmunity, and chronic inflammation.

macrophage

adhesion

migration

integrin aDb2

CD11d/CD18

carboxyethylpyrrole (CEP)

ECM

inflammation

Cardiovascular System

Immune System

Examining Gender In Pharmaceutical Rhetoric Through A Cultural Studies Lens: A Case Study On The Gardasil Vaccine

Fickley-Baker, Jennifer

01 January 2012

On June 8, 2006, Merck announced the debut of Gardasil, the world's first vaccine found successful in preventing human papillomavirus (HPV) infections, a sexually transmitted infection that is one of the main causes of certain cancers in men and women, including cervical, vulvar, penile and anal cancers. To promote the vaccine's release, Merck launched Gardasil's "One Less" advertising campaign that included television commercials, print ads and a consumerfocused website (www.Gardasil.com), each promoting the message that "you" could now be "one less woman" affected by cervical cancer ("One Less" campaign). The vaccine, tested and approved only for females age 9-26, was advertised to this age group, as well as parents or guardians responsible for making medical decisions for female minors. As the campaign launched, commercials depicted females laughing and enjoying hobbies while mentioning the positive decision they made to receive the Gardasil vaccine. Many commercials also included portrayals of mothers talking happily about their decision to get their young daughters vaccinated. Interestingly, male figures were completely left out of Gardasil's "One Less" campaign ads, despite the fact that in reality, males administer the vaccine as medical professionals, transmit the infection as sexual partners, and suffer cancers as HPVinfected patients. Males were even left out of the ads as parents, who were always portrayed by women in the ad campaign. iv Informed consumers may have expected all this to change on Oct. 16, 2009 – three years after Gardasil's debut – when the Food & Drug Administration (FDA) approved the vaccine for use in males age 9-26 to protect against HPV-caused genital warts. Though Merck's vaccine was now accessible to more consumers than ever, the advertising that surrounded this medical breakthrough changed very little. Television commercials for the vaccine still promoted Gardasil primarily to women for the purpose of preventing HPV-related cervical cancer. Again, men were not featured in commercials as medical professionals, parents, guardians, romantic partners, or even as patients able to get the vaccine. Males did begin appearing on the vaccine's official website, however these depictions were limited to showing only young boys, who appeared standing with a mother's protective arm around them. Males that represent the older age range (up to age 26) were never shown. What effect does the lack of male representation have on the verbal and nonverbal message these ads are sending consumers about who fits in the target consumer group, as well as who is at risk for an HPV infection? On a broader level, how does gender representation as a whole affect pharmaceutical advertisements and the adoption of the potentially life-saving products they promote? How does a pharmaceutical technology become "gendered"? How do specific gender portrayals impact the educational aspects of pharmaceutical ads, which may shape a consumer's opinion of who is at risk for an illness, and who is responsible for its treatment or prevention? And how do these gender portrayals connect with, reflect or reinforce v dominant cultural beliefs about the roles males and females play in protecting themselves and others from disease? In this study, I investigate these questions using a blended cultural studies/social sciences research perspective, first looking at the controversial history of direct-toconsumer pharmaceutical advertising and the gender stereotypes that traditionally exist in this form of rhetoric. I then test the affect Merck's gender portrayals has on its ad message in a blind study done with a small sample population, which provides evidence that Merck's ads are confusing and exclusive of certain populations, particularly men. I then investigate how Merck's existing gender portrayals, and strong focus on women, reflect larger historical beliefs on the roles that males and females play in health care and in the family. I show how, through advertising, Gardasil has become "gendered" as a pharmaceutical technology for female children. From here, I will show how pharmaceutical companies, such as Merck, have both reflected and reinforced the belief that women are the primary caregivers to children, how this stereotype is both damaging and statistically incorrect, and how using it targets Gardasil ads to a very narrow population of consumers, miscommunicating the message of who is at risk for illness contraction and perhaps even damaging sales in addition to prevention. I later provide evidence that Merck's current Gardasil ad series and other actions in the marketplace are dangerously misleading certain populations regarding the nature of the HPV virus, the protective abilities of the vaccine, and the populations responsible for accessing Gardasil. I then provide the argument that gendering Gardasil as a "women's technology" is done intentionally by Merck, which has a history of making vi profits a priority over responsibly treating patient health. I conclude by providing detailed suggestions on how Merck can augment their current ad series to de-gender Gardasil to become more medically responsible, and break out of the cycle of portraying men and women using damaging and outdated stereotypes. Instead, my suggestions for changes to Gardasil's advertising approach would make the vaccine's messages appeal to all audiences at risk.

Gender

rhetoric

pharmaceuticals

health

communication

Advertising and Promotion Management

Immune System Diseases

Rhetoric

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