Investigação da capacidade imunomoduladora de células-tronco imaturas de polpa dentária humana. / Investigation of immunomodulatory capacity of human immature dental pulp stem cells.

Fernando de Sá Silva

15 January 2013

Este trabalho objetivou avaliar os efeitos imunomoduladores das células-tronco imaturas da polpa dentária (CTIPD) sobre a diferenciação, maturação das células dendríticas derivadas de monócitos (mo-DC), sua capacidade para ativar linfócitos T (Lin T), bem como verificar fatores solúveis liberados nos cocultivos celulares. As analises foram feitas por citometria de fluxo. Foi observado que mo-DC tiveram a diminuição de moléculas relacionadas à diferenciação para mo-DC e o aumento de moléculas relacionados ao estado precursor, o que parece ter refletido na maturação para mDC, verificado pela diminuição das moléculas de maturação. As mo-DC tiverem sua função em induzir a proliferação de Lin T reduzida, além, de favorecer o aumento da proporção de Lin T CD4+FoxP3+IL-10+ e Lin T CD4+FoxP3+IFN-<font face=\"Symbol\">g+. A mensuração dos fatores solúveis dos cocultivos mostrou que houve aumento de fatores anti-inflamatórios e redução de fatores pró-inflamatórios. Futura investigações podem suportar o uso das CTIPD em uma abordagem imunomoduladora utilizando DC em aplicações clínicas. / This study aimed to evaluate the immunomodulatory effects of immature stem cells from dental pulp on differentiation, maturation of monocyte-derived dendritic cells (mo-DC), their ability to activate T cells, as well as identify soluble factors released in cellular cocultures. The analyzes were performed by flow cytometry. It was observed a decrease of molecules related to mo-DC differentiation and an increase of molecules related to precursor state, which seems to have reflected to mDC maturation verified by reduction of maturation molecules. The mo-DC have their role in inducing T cells proliferation reduced, in addition, favored increase CD4+FoxP3+IL-10+ and CD4+FoxP3+IFN-<font face=\"Symbol\">g+ T cells population proportion. The measurement of soluble factors from coculture showed an increase of anti-inflammatory factors and a reduction of pro-inflammatory factors. Future research may support the use immature stem cells from dental pulp in an immunomodulatory approach using DC in clinical applications.

Células dendríticas

Células-tronco

Citometria de fluxo

Linfócitos T

Polpa dentária

Dendritic cells

Dental pulp

Flow cytometry

Stem cells

T lymphocytes

Beyond Toll-Like Receptor 9: Interactions Between Plasmacytoid Dendritic Cells and Aspergillus Fumigatus: A Dissertation

Ramirez-Ortiz, Zaida G.

26 October 2010

The opportunistic fungus, Aspergillus fumigatus, is a leading cause of morbidity and mortality among the immunocompromised population. Experimental and clinical findings have established that phagocytic defenses are critical in the recognition and clearance of A. fumigatus. Previous studies found that Toll-like receptors (TLRs), specifically TLR2 and TLR4, were essential in the detection of the mold. Furthermore, one study found that mice deficient in TLR9 lived longer than their wild-type counterparts following challenge with A. fumigatus. We sought to determine the role of TLR9 during A. fumigatus infection. Our results show that A. fumigatus contains unmethylated CpG DNA, the natural ligand of TLR9. Furthermore, A. fumigatus DNA stimulates a potent pro-inflammatory response in mouse bone marrow derived dendritic cells (BMDCs) and human plasmacytoid dendritic cells (pDCs). A genome wide analysis showed that A. fumigatus DNA contains 87 human and 23 mouse putative immunostimulatory motifs. The response to A. fumigatus DNA is TLR9-dependent, as BMDCs from TLR9-/- mice were unresponsive to the fungal DNA. In addition, HEK293 cells cotransfected with human TLR9 and NFκB driven Luciferase conferred responsiveness to A. fumigatus CpG-rich sequences found in the fungal DNA. Our results show that TLR9 detects A. fumigatus DNA, resulting in the secretion of proinflammatory cytokines. While pDCs secrete IFNα in response to A. fumigatus DNA, these cells have been mainly described to play critical roles in the antiviral responses. The role of pDCs during fungal infections remains to be elucidated. Our data show that CD304+ peripheral blood pDCs challenged with A. fumigatus hyphae secrete large concentrations of IFNα and TNFα in response to infection. Furthermore, the response appears to be TLR9- independent. However, pDCs spread over the hyphae and inhibit fungal growth. Furthermore, pDCs undergo cell lysis upon incubation with A. fumigatus. The antifungal activity of the pDCs was retained in the cell lysates, suggesting that this response was mediated by an intracellular factor. Addition of exogenous Zn2+, but not Fe3+, partially restores hyphal growth. In addition, western blot of pDC lysates show that these cells have the Zn2+-binding protein calprotectin. Over 60% cell death is observed in the pDC population following a 2 hour incubation with A. fumigatus. The observed pDC cell death can be partially attributed to gliotoxin, as pDCs challenged with A. fumigatus stains deficient in production of the mycotoxin result in decreased pDC cytotoxicity. Furthermore, pDC cell death occurs independent of contact with the mold, confirming that pDC cell death is mediated by a secreted fungal factor. In addition, our results show that pDCs are required for the host response against A. fumigatus. Mice depleted of their pDCs are more susceptible to A. fumigatus infection than the control counterparts, suggesting that pDCs play a role in the antifungal response. Also, we observe a 5-fold increase in the pDC population in the lungs of infected mice. Therefore, the possibility of these cells playing a role in recruiting and communicating with other immune cells cannot be eliminated. Upon maturation, pDCs acquire characteristics of conventional DCs (cDCs) such as upregulation of major histocompatability complex (MHC) and becoming more phagocytic. Whether mature pDCs are involved in the detection of and responses against fungal pathogens remains to be determined. Here we show that mature pDC secrete IFNα and TNFα in response to A. fumigatus conidia as early as 6 hours post-challenge. While cytokine secretion of mature pDCs against A. fumigatus does not require opsonization, it requires for A. fumigatus being alive and growing. Furthermore, supernatants from conidial growth induced cytokine secretion by the mature pDCs. The work presented in this thesis establishes that the nucleic acids in A. fumigatus serve as a pathogen associated molecular pattern (PAMP) that can induce a TLR9- dependent response. Furthermore, I show that pDCs secrete cytokines and induce an antifungal response against A. fumigatus conidia and hyphae. While the pDC population in the blood appears to be small, our work shows that these cells could be intimately involved in the antifungal responses against A. fumigatus.

Toll-Like Receptor 9

Aspergillus fumigatus

Aspergillosis

Dendritic Cells

Bacterial Infections and Mycoses

Cells

Fungi

Microbiology

Innate Detection of HIV-1 in Myeloid Dendritic Cells

McCauley, Sean Matthew

24 July 2018

Protective antiviral immune responses require priming of naïve T cells by dendritic cells (DCs) that have matured sufficiently to produce co-stimulatory cell surface molecules and cytokines. Although only low levels of productive HIV-1 infection are detected in ex vivo DCs following HIV-1 challenge, those few cells exhibit innate activation. Experimentally bypassing blocks to entry and replication leads to more efficient transduction of DCs and maturation as indicated by production of interferons and interferon stimulated genes. Furthermore, similar innate activation occurs upon transduction of macrophages or CD4+ T cells. However, the mechanism by which HIV-1 is detected to activate innate immune signaling is not clear. The purpose of this thesis is to incorporate my data and observations into the understanding of HIV-1 innate detection and attempt to resolve seemingly conflicting observations. Reverse transcription and genomic integration are necessary for innate activation implying the need de novo transcription. Coding sequences are unnecessary save for those cis-acting sequences necessary for the HIV-1 life cycle. CRM1 dependent, HIV-1 unspliced RNA export is essential for innate activation. As intact viral sequence is unnecessary for transcription and export, defective proviruses may contribute to systemic inflammation seen in chronically infected individuals. These insights, are hoped to aid in the production of qualitatively better anti-retroviral drugs as well as in the design a protective HIV vaccine.

Innate immunity

dendritic cell

HIV-1

RNA export

pathogen recognition

nucleic acid detection

Immunology and Infectious Disease

Virology

Propriétés immuno-modulatrices des IgE dans le lupus érythémateux systémique : impact sur la sécrétion d’interféron de type I par les cellules dendritiques plasmacytoïdes / Immunomodulatory properties of IgE in systemic lupus erythematosus : impact on type I interferon secretion by plasmacytoid dendritic cells

Khoryati, Liliane

07 October 2014

Les cellules dendritiques plasmacytoïdes (pDCs) sont caractérisées par leur capacité unique de sécrétion massive d’interféron de type I (IFN-I) suite à la stimulation des Tolllike récepteurs (TLR) 7 et 9. Un rôle fondamental des pDCs a été démontré dans le lupus érythémateux systémique via la production d’IFN-I. Les pDC expriment le récepteur de forte affinité aux immunoglobulines de type E (IgE), FcεRI, impliqué dans la régulation négative de la sécrétion d’IFN-I. L’objectif de notre étude est d’explorer, dans le contexte lupique, les effets du traitement par les IgE sur les fonctions des pDC, particulièrement sur la production d’IFN-I. In vitro, le traitement des pDC par des IgE monoclonales permet la surexpression du FcεRI à leur surface et diminue le taux de transcrits des TLR7/9 et de l’IRF7. De plus, les pDC traitées par des IgE diminuent leur production d’IFN-I et l’expression de marqueurs de maturation, induites par leur stimulation par des ligands des TLR7/9 et des complexes immuns lupiques. En outre, ces pDC pré-traitées par des IgE induisent la différenciation de LT4 naïfs allogéniques en LT4 produisant de l’IL-10. In vivo, les patients lupiques en phase quiescente de la maladie présentent des taux plus élevés d’IgE totales comparés aux patients en phase active (indépendamment d’allergies et d’infestations parasitaires). Chez les patientslupiques, le taux d’IgE totales est inversement corrélé au taux d’anti-ADN et à l’activité de la maladie (SLEDAI). L’ensemble de nos résultats suggère un rôle protecteur des IgE dans le lupus à travers la modulation de la réponse inflammatoire des pDC. / Plasmacytoid dendritic cells (pDCs) are characterized by their unique ability to produce large amounts of type I interferon (IFN-I) upon Toll-like receptors (TLR) 7 and 9 triggering. A fundamental role for pDCs has been shown in systemic lupus erythematosus (SLE) through IFN-I production. pDCs express the high affinity Fc receptor for immunoglobulin E (IgE), FcεRI, involved in the negative regulation of IFN-I secretion. The objective of our study is to investigate, in the context of SLE, the effects of IgE treatment on pDCs functions, especially on IFN-I production. In vitro, monoclonal IgE treatment of pDCs upregulate their surface expression of FcεRI and decrease transcripts levels of TLR7/9 and IRF7. IgE-treated pDCs decrease IFN-α secretion and downregulate maturation markers expression induced by TLR7/9 and immune complexes triggering. Moreover, the coculture of IgE pretreated pDCs with allogeneic naive LT4 promotes their differentiation into IL-10-secreting cells. In vivo, patients with quiescent SLE have higher IgE levels than patients with active disease (independently of allergy or parasitic infection). In SLE patients, IgE levels are inversely correlated to anti-DNA antibodies and disease activity (SLEDAI). All together, our data suggest a protective role for IgE in SLE through the modulation of the inflammatory response by pDC.

Lupus érythémateux systémique

Cellule dendritique plasmacytoïde

Interféron de type I

Immunoglobuline E

Systemic lupus erythematosus

Plasmacytoid dendritic cell

Interferon type I

Immunoglobulin E

Le rôle des cellules myéloïdes et microARNs dans l'arthrite juvénile / Myeloid cell subsets and microRNAs in juvenile arthritis

Nziza, Nadege

27 June 2019

L’arthrite juvénile idiopathique (AJI) est un groupe hétérogène de rhumatismes inflammatoires chroniques affectant les enfants de moins de 16 ans. Cette atteinte inflammatoire d’origine inconnue est caractérisée par une arthrite persistant plus de 6 semaines en l’absence de traitements.Afin de mettre en évidence des mécanismes impliqués dans la physiopathologie de l’AJI, une inclusion de patients atteints d’une autre forme d’arthrite juvénile, à savoir l’arthrite septique, a été effectuée. En parallèle, des études comparatives entre le sang périphérique (SP) et le liquide synovial (LS) des patients atteints d’AJI ont été réalisées afin de rechercher des mécanismes spécifiques aux perturbations articulaires. Un intérêt particulier a été porté sur les sous-populations de monocytes et de cellules dendritiques (DCs) ainsi que les profils d’expression des microARNs (miARNs) dans le sang périphérique et le LS des patients. Ces différents marqueurs biologiques ont été choisis car ils jouent un rôle majeur à la fois dans la régulation de l’inflammation et la pathogénèse des maladies inflammatoires.L’analyse de l’expression des miARNs par une approche de séquençage à haut débit suivie d’une validation par RT-qPCR a mis en évidence des miARNs dérégulés de façon spécifique dans l’AJI par rapport à l’AS. De plus, la caractérisation phénotypique des sous-populations de cellyles myéloïdes a montré une accumulation et une activation cellulaire propre à l’AJI. Dans l’ensemble, ce projet m’a permis d’identifier différents acteurs cellulaires et moléculaires pouvant être impliqués dans la physiopathologie de l’AJI. / Juvenile idiopathic arthritis (JIA) is a heterogeneous group of chronic inflammatory rheumatism affecting children under 16 years of age. This inflammatory disorder of unknown origin is characterized by arthritis lasting more than 6 weeks in the absence of treatments.In order to highlight mechanisms involved in the pathophysiology of JIA, an inclusion of patients suffering from septic arthritis, another form of juvenile arthritis, was performed. In parallel, comparative studies between the peripheral blood (PB) and the synovial fluid (SF) of patients with JIA were carried out in order to search for mechanisms specific of joint disturbances.We focused on monocytes and dendritic cells (DCs) subsets as well as the expression patterns of microRNAs (miRNAs) in the PB and SF of patients. These different biological markers are known to play a major role both in the regulation of inflammation and the pathogenesis of inflammatory diseases.Analysis of miRNA expression by a high-throughput sequencing approach followed by RT-qPCR validation revealed specifically deregulated miRNAs in JIA compared to AS. In addition, the phenotypic characterization of myeloid cell subpopulations showed an accumulation and activation profile specific of JIA cells. Overall, this project allowed me to identify different cellular and molecular actors that might be involved in the pathophysiology of JIA.

Arthrite juvénile

Monocytes

Cellules dendritiques

MicroARNs

Liquide synovial

Sang périphérique

Juvenile arthritis

Monocytes

Dendritic cells

MicroRNAs

Synovial fluid

Peripheral blood

Caracterização imunoistoquímica comparativa de subgrupos de células dendríticas e oncogênese viral no carcinoma espinocelular oral e orofaríngeo /

Silveira, Heitor Albergoni.

January 2020

Orientador: Jorge Esquiche León / Resumo: O carcinoma espinocelular (CEC) de cabeça e pescoço (CECCP) é o quinto tipo de câncer mais comum e a sexta causa de morte por câncer. Recentes estudos enfatizam o CEC oral (CECO) como uma entidade distinta do CEC de orofaringe (CECorof), com este último apresentando melhor prognóstico e estreitamente associado com infecção pelo papilomavírus humano (HPV). A etiologia do CECCP é multifatorial; porém, o CECO está relacionado com abuso do tabaco e álcool, enquanto o CECorof está frequentemente associado com infecção pelo HPV. As células dendríticas (CDs) são importantes células as quais regulam repostas imunes, incluindo aquelas vinculadas à tumorigênese, estabelecendo conexão entre o sistema imune inato e adaptativo. Estão divididas em dois grupos: CDs mieloides (CDmi) e CDs plasmocitóides (CDp), incluindo CDs imaturas (CDim) e CDs maduras (CDm). O objetivo do nosso estudo foi analisar comparativamente, através da técnica de imunoistoquímica (IQ) e hibridização in situ (HIS), a infiltração de CDmi e CDp, incluindo subgrupos de CDim e CDm, no CECO (n=109) e CECorof (n=126), bem como analisar a oncogênese viral (HPV amplo espectro, alto risco (ARHPV) e baixo risco (BRHPV) oncogênico e vírus Epstein-Barr [VEB]) por HIS. O CECOrof (25%) comparado com o CECO (11%) mostrou associação significativa com o HPV. No CECorof e no CECO, 19 e 7 mostram positividade para ARHPV (somente), 6 e 3 BRHPV (somente) e 3 e 2 ARHPV/BRHPV (co-infecção), respectivamente. Os tumores HPV-positivos compara... (Resumo completo, clicar acesso eletrônico abaixo) / Mestre

Carcinoma de células escamosas.

Boca.

Orofaringe

Papillomaviridae.

Imuno-histoquímica.

Células dendríticas.

Carcinoma de células escamosas.

Papillomaviridae.

Immunohistochemistry

Dendritic cells.

Funkce CX3CR1+ migratorních dendritických buněk v mechanismech centrální tolerance / CX3CR1+ migratory dendritic cells in the mechanisms of central tolerance

Březina, Jiří

January 2019

Display of thousands of self-antigens in the thymus is fundamental for the establishment of central tolerance as its failure can lead to the development of autoimmunity. Medullary thymic epithelial cells (mTECs) and thymic dendritic cells (DCs) constitute essential populations of antigen presenting cells (APCs) which present these self-antigens to developing T cells. While mTECs produce and present antigens in self-autonomous manner, DCs can hijack mTEC-derived antigens by the process of cooperative antigen transfer (CAT). It is well found that CAT is essential for working central tolerance, however, the overall heterogeneity of thymic APCs participating in CAT remains unclear. Using transgenic mouse models and multicolor flow cytometry analysis, we determined that APCs involved in CAT are exclusively of CD11c+ phenotype. Within these cells, we identified previously unrecognized CX3CR1+ subset of migratory DCs (mDCs) exhibiting monocyte/macrophage markers. These CX3CR1+ mDCs are more efficient in CAT than their CX3CR1- counterparts and reveal robust antigen presenting properties with the capability to present CAT-acquired antigen. Genetic ablation of CX3CR1+ mDCs resulted in increased cellularity of CD8+ and CD4+ thymocytes, indicating importance of this mDC subset for negative selection of...

A Novel Methodology to Probe the Structural and Functional Correlates of Synaptic Plasticity

Laura Andrea Roa Gonzalez (12873056)

15 June 2022

<p>Dendritic spines are mushroom-shaped appendages on the dendritic branches of neurons. They are invaluable to the function of the brain as they form the major site for excitatory signal transmission in the mammalian brain. These ubiquitous structures have several invaluable and unique characteristics – namely that their morphological and functional characteristics are activity-dependent and undergo remodeling as the spine experiences stimulation. This activity-dependent regulation then in turn modulates the excitatory postsynaptic potential that propagates into the adjacent parent dendrite, and which ultimately reaches the somatic compartment. The mediation of this modulatory effect on the postsynaptic signal by dendritic spines renders them invaluable to the brain’s ability to change neuronal circuits as it learns. The relationship between the structural and functional change in dendritic spines as plasticity is induced remains poorly understood; while efforts have been made to examine the morphology of dendritic spines during plasticity as well as the change to receptor insertion on the postsynaptic density, a comprehensive methodology to interrogate the concomitant changes to several aspects of dendritic spine structure and function as plasticity occurs has not been established. In this study, such a methodology was developed in order to facilitate future study of how a dendritic spine’s diffusional neck resistance, head volume, calcium-sensitive channels (on the postsynaptic density), and excitatory postsynaptic potential amplitude change concurrently as the spine undergoes activity-dependent regulation. This activity-dependent regulation also occurs in groups of spines called “clusters” <em>in vivo</em>, and the structural and functional dynamics of spines as these groups are formed also remains unknown. In order to to facilitate future <em>in vivo</em> studies on how clustered dendritic spines may change dynamically in both structure and function, a methodology for surgically accessing and recording calcium-based activity from the primary auditory cortex was developed, as the frequency-specific tuning of dendritic spines in this cortical area forms a compelling environment in which to study the relationship between spine form and function. </p>

Central nervous system

dendritic spines

FRAP

calcium imaging

electrical compartmentalization

biochemical compartmentalization

calcium channel variance

EPSP

primary auditory cortex

A-type Potassium Channels in Dendritic Integration : Role in Epileptogenesis

Tigerholm, Jenny

January 2009

During cognitive tasks, synchronicity of neural activity varies and is correlated with performance. However, there may be an upper limit to normal synchronised activity – specifically, epileptogenic activity is characterized byexcess spiking at high synchronicity. An epileptic seizure has a complicated course of events and I therefore focused on the synchronised activity preceding a seizure (fast ripples). These high frequency oscillations (200–1000 Hz) have been identified as possible signature markers of epileptogenic activity and may be involved in generating seizures. Moreover, a range of ionic currents have been suggested to be involved in distinct aspects of epileptogenesis. Based on pharmacological and genetic studies, potassium currents have been implicated, in particular the transient A–type potassium channel (KA). Our first objective was to investigate if KA could suppress synchronized input while minimally affecting desynchronised input. The second objective was to investigate if KA could suppress fast ripple activity. To study this I use a detailed compartmental model of a hippocampal CA1 pyramidal cell. The ion channels were described by Hodgkin–Huxley dynamics. The result showed that KA selectively could suppress highly synchronized input. I further used two models of fast ripple input and both models showed a strong reduction in the cellular spiking activity when KA was present. In an ongoing in vitro brain slice experiment our prediction from the simulations is being tested. Preliminary results show that the cellular response was reduced by 30 % for synchronised input, thus confirming our theoretical predictions. By suppressing fast ripples KA may prevent the highly synchronised spiking activity to spread and thereby preventing the seizure. Many antiepileptic drugs down regulate cell excitability by targeting sodium channels or GABA–receptors. These antiepileptic drugs affect the cell during normal brain activity thereby causing significant side effects. KA mainly suppresses the spiking activity when the cell is exposed to abnormally high synchronised input. An enhancement in the KA current might therefore be beneficial in reducing seizures while not affecting normal brain activity.

epileptogenesis

fast ripples

synchronicity

dendritic potentials

transient A–type potassium current

KV 4.2

Information Systems

The Protective Function of Human C-Reactive Protein in Mouse Models of Streptococcus Pneumoniae Infection

Agrawal, Alok, Suresh, Madathilparambil V., Singh, Sanjay K., Ferguson, Donald A.

01 December 2008

Human C-reactive protein (CRP), injected intravenously into mice or produced inside mice by a human transgene, protects mice from death following administration of lethal numbers of Streptococcus pneumoniae. The protective effect of CRP is due to reduction in the concentration of bacteria in the blood. The exact mechanism of CRP-dependent killing of pneumococci and the partners of CRP in this process are yet to be defined. The current efforts to determine the mechanism of action of CRP in mice are directed by four known in vitro functions of CRP: 1. the ability of pneumococcal C-polysaccharide-complexed CRP to activate complement pathways, 2. the ability of CRP to bind to Fcγ receptors on phagocytic cells, 3. the ability of CRP to bind to immobilized complement regulator protein factor H which can also be present on pneumococci, and, 4. the ability of CRP to interact with dendritic cells. CRP-treated dendritic cells may well be as host-defensive as CRP alone. An interesting condition for the protective function of CRP is that CRP must be given to mice within a few hours of the administration of pneumococci. CRP does not protect mice if given later, suggesting that CRP works prophylactically but not as a treatment for infection. However, full knowledge of CRP may lead to the development of CRP-based treatment strategies to control pneumococcal infection. Also, because CRP deficiency in humans has not yet been reported, it becomes important to investigate the deficiency of the mechanism of action of CRP in CRP-positive individuals.

C-reactive protein

complement system

dendritic cells

factor H

Fcγ receptors

lectin pathway

phagocytosis

phosphocholine

pneumococci

Biomedical Sciences