Your search keyword '"Milanez-Almeida, Pedro"' showing total 3 results

1. Advantages of Foxp3+ regulatory T cell depletion using DEREG mice

Author

Mayer, Christian T, Lahl, Katharina, Milanez-Almeida, Pedro, Watts, Deepika, Dittmer, Ulf, Fyhrquist, Nanna, Huehn, Jochen, Kopf, Manfred, Kretschmer, Karsten, Rouse, Barry, and Sparwasser, Tim

Subjects

Treg, Diphtheria toxin (DT), Medizin, DEREG, Autoimmunity, Regulatory T cells, Tolerance, hemic and immune systems, chemical and pharmacologic phenomena, Original Research

Abstract

Several mechanisms enable immunological self-tolerance. Regulatory T cells (Tregs) are a specialized T cell subset that prevents autoimmunity and excessive immune responses, but can also mediate detrimental tolerance to tumors and pathogens in a Foxp3-dependent manner. Genetic tools exploiting the foxp3 locus including bacterial artificial chromosome (BAC)-transgenic DEREG mice have provided essential information on Treg biology and the potential therapeutic modulation of tolerance. In DEREG mice, Foxp3+ Tregs selectively express eGFP and diphtheria toxin (DT) receptor, allowing for the specific depletion of Tregs through DT administration. We here provide a detailed overview about important considerations such as DT toxicity, which affects any mouse strain treated with DT, and Treg rebound after depletion. Additionally, we point out the specific advantages of BAC-transgenic DEREG mice including their suitability to study organ-specific autoimmunity such as type I diabetes. Moreover, we discuss recent insights into the role of Tregs in viral infections. In summary, DEREG mice are an important tool to study Treg-mediated tolerance and its therapeutic circumvention., Immunity, Inflammation and Disease, 2 (3), ISSN:2050-4527

Published

2014

2. Advantages of Foxp3+ regulatory T cell depletion using DEREG mice.

Author

Mayer, Christian T., Lahl, Katharina, Milanez‐Almeida, Pedro, Watts, Deepika, Dittmer, Ulf, Fyhrquist, Nanna, Huehn, Jochen, Kopf, Manfred, Kretschmer, Karsten, Rouse, Barry, and Sparwasser, Tim

Subjects

T cells, AUTOIMMUNITY, TYPE 1 diabetes, LABORATORY mice, IMMUNE response

Abstract

Several mechanisms enable immunological self-tolerance. Regulatory T cells (Tregs) are a specialized T cell subset that prevents autoimmunity and excessive immune responses, but can also mediate detrimental tolerance to tumors and pathogens in a Foxp3-dependent manner. Genetic tools exploiting the foxp3 locus including bacterial artificial chromosome (BAC)-transgenic DEREG mice have provided essential information on Treg biology and the potential therapeutic modulation of tolerance. In DEREG mice, Foxp3+ Tregs selectively express eGFP and diphtheria toxin (DT) receptor, allowing for the specific depletion of Tregs through DT administration. We here provide a detailed overview about important considerations such as DT toxicity, which affects any mouse strain treated with DT, and Treg rebound after depletion. Additionally, we point out the specific advantages of BAC-transgenic DEREG mice including their suitability to study organ-specific autoimmunity such as type I diabetes. Moreover, we discuss recent insights into the role of Tregs in viral infections. In summary, DEREG mice are an important tool to study Treg-mediated tolerance and its therapeutic circumvention. [ABSTRACT FROM AUTHOR]

Published

2014

3. A mathematical model of immune activation with a unified self-nonself concept.

Author

Khailaie, Sahamoddin, Bahrami, Fariba, Janahmadi, Mahyar, Milanez-Almeida, Pedro, Huehn, Jochen, and Meyer-Hermann, Michael

Subjects

ANTIGENS, IMMUNE response, AUTOIMMUNITY, T cells, IMMUNOLOGY

Abstract

The adaptive immune system reacts against pathogenic nonself, whereas it normally remains tolerant to self. The initiation of an immune response requires a critical antigen(Ag)-stimulation and a critical number of Ag-specific T cells. Autoreactive T cells are not completely deleted by thymic selection and partially present in the periphery of healthy individuals that respond in certain physiological conditions. A number of experimental and theoretical models are based on the concept that structural differences discriminate self from nonself. In this article, we establish a mathematical model for immune activation in which self and nonself are not distinguished. The model considers the dynamic interplay of conventional T cells, regulatory T cells (Tregs), and IL-2 molecules and shows that the renewal rate ratio of resting Tregs to naïve T cells as well as the proliferation rate of activated T cells determine the probability of immune stimulation. The actual initiation of an immune response, however, relies on the absolute renewal rate of naïve T cells. This result suggests that thymic selection reduces the probability of autoimmunity by increasing the Ag-stimulation threshold of self reaction which is established by selection of a low number of low-avidity autoreactive T cells balanced with a proper number of Tregs. The stability analysis of the ordinary differential equation model reveals three different possible immune reactions depending on critical levels of Ag-stimulation: a subcritical stimulation, a threshold stimulation inducing a proper immune response, and an overcritical stimulation leading to chronic co-existence of Ag and immune activity. The model exhibits oscillatory solutions in the case of persistent but moderate Ag-stimulation, while the system returns to the homeostatic state upon Ag clearance. In this unifying concept, self and nonself appear as a result of shifted Ag-stimulation thresholds which delineate these three regimes of immune activation. [ABSTRACT FROM AUTHOR]

Published

2013