Toll-like receptor 4 (TLR4) na modulação da imunidade do tipo 2. / Toll-like receptor 4 (TLR4) and modulation of Th2 immunity.

Bortolatto, Juliana

16 October 2008

Lipopolissacarídeos (LPS), pode tanto proteger quanto exacerbar o desenvolvimento da asma. LPS inicia a ativação da resposta imune via ligação da molécula Toll-like receptor 4 (TLR4) que sinaliza por duas vias distintas, as moléculas adaptadoras MyD88 e TRIF. LPS é um adjuvante que induz resposta do tipo Th1, enquanto que o hidróxido de alumínio (Alum) desperta respostas Th2, porém, a mistura de ambos adjuvantes na indução da resposta alérgica pulmonar ainda não foi investigada. No presente estudo, nós determinamos o efeito de dois agonistas de TLR4, um natural (LPS) e outro sintético (ER-803022) adsorvidos ao Alum sobre o desenvolvimento de doença alérgica pulmonar. Os animais foram sensibilizados pela via subcutânea com os antígenos, Ovoalbumina (OVA) ou Toxóide Tetânico (TT) na presença ou ausência de agonistas de TLR4 co-adsorvidos ao Alum e desafiados com os respectivos antígenos pela via intranasal. Nossos resultados mostraram que a sensibilização com OVA ou TT e LPS coadsorvidos ao Alum, impede o estabelecimento da resposta alérgica mediada por linfócitos Th2, tais como, influxo de eosinófilos, produção de citocinas do tipo 2, hiperreatividade brônquica, secreção de muco, e produção de IgE ou IgG1 anafilática. Apesar dos níveis de IgG2a, isotipo associado com as respostas Th1 estarem aumentados, análise da histopatologia pulmonar não revelou um desvio para o padrão Th1 de inflamação. Verificamos que a presença das moléculas TLR4, MyD88, IL-12/IFN-g mas não TRIF foram necessários para LPS exercer seu efeito inibitório. O agonista sintético de TLR4, menos tóxico que LPS, também protegeu contra o desenvolvimento de inflamação alérgica pulmonar. Em conclusão, nosso trabalho esclarece o efeito da sinalização do TLR4 na sensibilização alérgica e indica que agonista sintético de TLR4 com baixa toxicidade, pode ser utilizado para modular a capacidade adjuvante do Alum e conseqüentemente diminuir a indução de alergias. / Epidemiological and experimental data suggest that bacterial lipopolysaccharides (LPS) can either protect from or exacerbate allergic asthma. LPS triggers immune responses through Toll-like receptor (TLR) 4 that in turn activates two major signaling pathways via either MyD88 or TRIF adaptor proteins. LPS is a pro-Th1 adjuvant while aluminum hydroxide (Alum) is a strong Th2 adjuvant, but the effect of mixing both adjuvants on development of lung allergy has not been investigated. We determined whether natural (LPS) or synthetic (ER-803022) TLR4 agonists adsorbed onto alum adjuvant affect allergen sensitization and development of airway allergic disease. To dissect LPS-induced molecular pathways we used TLR4, MyD88, TRIF, or IL-12/IFN-g deficient mice. Mice were sensitized subcutaneously to allergens such as ovalbumin (OVA) or tetanus toxoid (TT) with or without TLR4 agonists coadsorbed onto Alum and challenged twice via intranasal route with the same allergens. The development of type 2 immunity was evaluated 24 h after last allergen challenge. We found that sensitization with OVA or TT plus LPS co-adsorbed onto Alum impaired allergeninduced Th2-mediated responses such as airway eosinophilia, type 2 cytokines secretion, airway hyperreactivity, mucus hyper production and serum levels of IgE or IgG1 anaphylactic antibodies. Although the levels of IgG2a, a Th1 affiliated isotype increased, investigation into the lung-specific effects revealed that LPS did not induce a Th1 pattern of inflammation. LPS impaired the development of Th2 immunity, signaling via TLR4 and MyD88 molecules via the IL-12/IFN-g axis, but not through TRIF pathway. Moreover, the synthetic TLR4 agonists that proved to have a less systemic inflammatory response than LPS also protected against allergic asthma development. TLR4 agonists co-adsorbed with allergen onto Alum down modulate Th2 immunity and prevent the development of polarized T cell-mediated airway inflammation. Thus, our work clarifies the effect of TLR4 signaling in allergic sensitization and indicates that TLR4 agonists with low toxicity might be useful for down regulating the pro-Th2 adjuvant activity of alum and consequently decrease the induction of allergy.

Aluminium hydroxide adjuvant (Alum)

Asma experimental

Experimental asthma

Lipopolissacarídeo bacteriano (LPS)

Lipopolysaccharides bacterial (LPS)

OVA

OVA

Tetanic toxoid (TT)

Toll-like receptor-4 (TLR-4)

Toll-like receptor-4 (TLR-4)

Toxóide Tetânico (TT)

Toll-like receptor 4 (TLR4) na modulação da imunidade do tipo 2. / Toll-like receptor 4 (TLR4) and modulation of Th2 immunity.

Juliana Bortolatto

16 October 2008

Lipopolissacarídeos (LPS), pode tanto proteger quanto exacerbar o desenvolvimento da asma. LPS inicia a ativação da resposta imune via ligação da molécula Toll-like receptor 4 (TLR4) que sinaliza por duas vias distintas, as moléculas adaptadoras MyD88 e TRIF. LPS é um adjuvante que induz resposta do tipo Th1, enquanto que o hidróxido de alumínio (Alum) desperta respostas Th2, porém, a mistura de ambos adjuvantes na indução da resposta alérgica pulmonar ainda não foi investigada. No presente estudo, nós determinamos o efeito de dois agonistas de TLR4, um natural (LPS) e outro sintético (ER-803022) adsorvidos ao Alum sobre o desenvolvimento de doença alérgica pulmonar. Os animais foram sensibilizados pela via subcutânea com os antígenos, Ovoalbumina (OVA) ou Toxóide Tetânico (TT) na presença ou ausência de agonistas de TLR4 co-adsorvidos ao Alum e desafiados com os respectivos antígenos pela via intranasal. Nossos resultados mostraram que a sensibilização com OVA ou TT e LPS coadsorvidos ao Alum, impede o estabelecimento da resposta alérgica mediada por linfócitos Th2, tais como, influxo de eosinófilos, produção de citocinas do tipo 2, hiperreatividade brônquica, secreção de muco, e produção de IgE ou IgG1 anafilática. Apesar dos níveis de IgG2a, isotipo associado com as respostas Th1 estarem aumentados, análise da histopatologia pulmonar não revelou um desvio para o padrão Th1 de inflamação. Verificamos que a presença das moléculas TLR4, MyD88, IL-12/IFN-g mas não TRIF foram necessários para LPS exercer seu efeito inibitório. O agonista sintético de TLR4, menos tóxico que LPS, também protegeu contra o desenvolvimento de inflamação alérgica pulmonar. Em conclusão, nosso trabalho esclarece o efeito da sinalização do TLR4 na sensibilização alérgica e indica que agonista sintético de TLR4 com baixa toxicidade, pode ser utilizado para modular a capacidade adjuvante do Alum e conseqüentemente diminuir a indução de alergias. / Epidemiological and experimental data suggest that bacterial lipopolysaccharides (LPS) can either protect from or exacerbate allergic asthma. LPS triggers immune responses through Toll-like receptor (TLR) 4 that in turn activates two major signaling pathways via either MyD88 or TRIF adaptor proteins. LPS is a pro-Th1 adjuvant while aluminum hydroxide (Alum) is a strong Th2 adjuvant, but the effect of mixing both adjuvants on development of lung allergy has not been investigated. We determined whether natural (LPS) or synthetic (ER-803022) TLR4 agonists adsorbed onto alum adjuvant affect allergen sensitization and development of airway allergic disease. To dissect LPS-induced molecular pathways we used TLR4, MyD88, TRIF, or IL-12/IFN-g deficient mice. Mice were sensitized subcutaneously to allergens such as ovalbumin (OVA) or tetanus toxoid (TT) with or without TLR4 agonists coadsorbed onto Alum and challenged twice via intranasal route with the same allergens. The development of type 2 immunity was evaluated 24 h after last allergen challenge. We found that sensitization with OVA or TT plus LPS co-adsorbed onto Alum impaired allergeninduced Th2-mediated responses such as airway eosinophilia, type 2 cytokines secretion, airway hyperreactivity, mucus hyper production and serum levels of IgE or IgG1 anaphylactic antibodies. Although the levels of IgG2a, a Th1 affiliated isotype increased, investigation into the lung-specific effects revealed that LPS did not induce a Th1 pattern of inflammation. LPS impaired the development of Th2 immunity, signaling via TLR4 and MyD88 molecules via the IL-12/IFN-g axis, but not through TRIF pathway. Moreover, the synthetic TLR4 agonists that proved to have a less systemic inflammatory response than LPS also protected against allergic asthma development. TLR4 agonists co-adsorbed with allergen onto Alum down modulate Th2 immunity and prevent the development of polarized T cell-mediated airway inflammation. Thus, our work clarifies the effect of TLR4 signaling in allergic sensitization and indicates that TLR4 agonists with low toxicity might be useful for down regulating the pro-Th2 adjuvant activity of alum and consequently decrease the induction of allergy.

Asma experimental

Lipopolissacarídeo bacteriano (LPS)

OVA

Toll-like receptor-4 (TLR-4)

Toxóide Tetânico (TT)

Aluminium hydroxide adjuvant (Alum)

Experimental asthma

Lipopolysaccharides bacterial (LPS)

OVA

Tetanic toxoid (TT)

Toll-like receptor-4 (TLR-4)

Role of a Mitochondrial Micropeptide in Regulating Innate Immune Responses

Bhatta, Ankit

29 September 2020

Short ORF-encoded peptides (SEPs) are increasingly being identified as functional elements in various cellular processes. The current computational methods and experimental molecular biochemistry allow us to discover putative SEPs or micropeptides from proteogenomic datasets and experimentally validate them. Here, we identified a micropeptide produced from a putative long noncoding RNA (lncRNA) 1810058I24Rik which is downregulated in both human and murine myeloid cells exposed to lipopolysaccharide (LPS), as well as other TLR ligands and inflammatory cytokines. Analysis of lncRNA 1810058I24Rik subcellular localization revealed this transcript is localized in the cytosol, prompting us to evaluate its coding potential. In vitro translation with 35S-labeled methionine resulted in translation of a 47 amino acid micropeptide. Microscopy and subcellular fractionation studies in macrophages demonstrated endogenous expression of this peptide on the mitochondrion. We thus named this gene ‘Mitochondrial micropeptide-47 (Mm47)’. Functional studies using siRNA and Cripsr-cas9-mediated deletion in primary cells, showed that the transcriptional response downstream of TLR4 was not affected by Mm47 loss of function. In contrast, both the Crispr-cas9- and siRNA-targeted BMDM cells were compromised for Nlrp3 inflammasome responses. However, the primary macrophages derived from the Mm47 knockout mice do not require Mm47 for Nlrp3 activation, likely due to basal downregulation of a negative regulator microRNA of Nlrp3 called Mir-223. Notably, the Mm47-deficient mice are susceptible to influenza virus infection and succumb despite comparable antiviral and inflammatory response to wildtype mice. We hypothesize that the Mm47 deficiency may affect the antiviral resilience of mice due to secondary mitochondria dependent immunometabolic defect or failure of recovery from immune pathology, which warrants further investigation. This study therefore identifies a novel mitochondrial micropeptide Mm47 that is required for activation of the Nlrp3 inflammasome in cells and resistance to influenza virus infection. Broadly, this work highlights the presence of translatable ORFs is annotated noncoding RNA transcripts and underscores their importance in innate immunity and virus infection.

LncRNA

long noncoding RNA

noncoding RNA

Micropeptide

Short-ORF-encoded peptides

SEPs

inflammation

inflammasome

NLRP3

Nod-like receptor

bacterial LPS

mitochondria

innate immune signaling

influenza A virus

IAV

Immunology and Infectious Disease

Microbiology