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Literature DB >> 18658168

What roles do regulatory T cells play in the control of the adaptive immune response?

Abstract

The immune system, like many systems responsive to specific stimuli, requires feedback regulation. The key regulatory element determining antigen-specific responsiveness is the effector T helper. As the response tends to overshoot, a feedback control of the magnitude of the response is critical to avoid immunopathology. This is the proposed role of the effector T suppressor (T(s)). The reasons for this interpretation of the data are discussed as are the reasons that the competing postulate is ruled out, namely that T(s) function in determining the self-non-self-discrimination. The regulatory T cell family consists of two lineages, T helpers and T(s). Differentiated derivatives of the T helper lineage drive the expression and amplification of specific classes of defensive effector cells. T(s) feedback to limit the magnitude of the process so that debilitating immunopathology is acceptably infrequent.

Mesh：

Year: 2008 PMID： 18658168 PMCID： PMC2733841 DOI： 10.1093/intimm/dxn088

Source DB: PubMed Journal: Int Immunol ISSN： 0953-8178 Impact factor: 4.823

63 in total

Review 1. On the role of feedback in promoting conflicting goals of the adaptive immune system.

Authors: L A Segel; R L Bar-Or
Journal: J Immunol Date: 1999-08-01 Impact factor: 5.422

2. More antigen-dependent CD4(+) T cell / CD4(+) T cell interactions are required for the primary generation of Th2 than of Th1 cells.

Authors: N Ismail; P A Bretscher
Journal: Eur J Immunol Date: 2001-06 Impact factor: 5.532

3. Immune system protects integrity of tissues.

Authors: Z Dembic
Journal: Mol Immunol Date: 2000-08 Impact factor: 4.407

4. To be or Not to be ridded?--That is the question addressed by the associative antigen recognition model.

Authors: M Cohn; R E Langman
Journal: Scand J Immunol Date: 2002-04 Impact factor: 3.487

Review 5. Tritope model of restrictive recognition by the TCR.

Authors: Melvin Cohn
Journal: Trends Immunol Date: 2003-03 Impact factor: 16.687

6. The immune system: a weapon of mass destruction invented by evolution to even the odds during the war of the DNAs.

Authors: Melvin Cohn
Journal: Immunol Rev Date: 2002-07 Impact factor: 12.988

7. A computerized model for the self-non-self discrimination at the level of the T(h) (Th genesis). I. The origin of 'primer' effector T(h) cells.

Authors: Melvin Cohn; Rodney E Langman; James J Mata
Journal: Int Immunol Date: 2002-10 Impact factor: 4.823

8. A computerized model for the self-non-self discrimination at the level of the T(h) (Th genesis). II. The behavior of the system upon encounter with non-self antigens.

Authors: Rodney E Langman; James J Mata; Melvin Cohn
Journal: Int Immunol Date: 2003-05 Impact factor: 4.823

Review 6. A stepwise model of polyreactivity of the T cell antigen-receptor (TCR): its impact on the self-nonself discrimination and on related observations (receptor editing, anergy, dual receptor cells).

Authors: Melvin Cohn
Journal: Cell Mol Life Sci Date: 2013-12-14 Impact factor: 9.261

Review 10. How do regulatory T cells work?

Authors: A Corthay
Journal: Scand J Immunol Date: 2009-10 Impact factor: 3.487

What roles do regulatory T cells play in the control of the adaptive immune response?

Review 1. On the role of feedback in promoting conflicting goals of the adaptive immune system.

2. More antigen-dependent CD4(+) T cell / CD4(+) T cell interactions are required for the primary generation of Th2 than of Th1 cells.

3. Immune system protects integrity of tissues.

4. To be or Not to be ridded?--That is the question addressed by the associative antigen recognition model.

Review 5. Tritope model of restrictive recognition by the TCR.

6. The immune system: a weapon of mass destruction invented by evolution to even the odds during the war of the DNAs.

7. A computerized model for the self-non-self discrimination at the level of the T(h) (Th genesis). I. The origin of 'primer' effector T(h) cells.

8. A computerized model for the self-non-self discrimination at the level of the T(h) (Th genesis). II. The behavior of the system upon encounter with non-self antigens.

9. The specificity of immunological reactions.

10. Foxp3 and dominant tolerance.

1. Ten experiments that would make a difference in understanding immune mechanisms.

2. Co-inhibitory molecules: Controlling the effectors or controlling the controllers?

3. Analysis of Paris meeting redefining the "self" of the immune system.

Review 4. Learning from a contemporary history of immunology.

Review 5. Rationalizing the path to a universal graft recipient.

Review 6. A stepwise model of polyreactivity of the T cell antigen-receptor (TCR): its impact on the self-nonself discrimination and on related observations (receptor editing, anergy, dual receptor cells).

7. The evolutionary context for a self-nonself discrimination.

8. On the opposing views of the self-nonself discrimination by the immune system.

Review 9. Protease-activated receptors and prostaglandins in inflammatory lung disease.

Review 10. How do regulatory T cells work?