Alloimmunity

Alloimmunity is an immune response to foreign antigens (alloantigens) from members of the same species. The body attacks mainly transplanted tissue and even the fetus in some cases. Alloimmune response results in graft rejection, which is manifested as deterioration or complete loss of graft function. In contrast, autoimmunity is an immune response to the self's own proteins. (The allo- prefix means "other", whereas the auto- prefix means "self".)

Alloimmunity is caused by the difference between products of highly polymorphic genes, primarily genes of MHC complex, of the donor and graft recipient. These products are recognized by T-lymphocytes and other mononuclear leukocytes which infiltrate the graft and damage it.

Types of the rejection

Mechanisms of rejection

CD4+ and CD8+ T-lymphocytes along with other mononuclear leukocytes (their exact function regarding the topic is not known) participate in the rejection.[1] B-lymphocytes, NK cells and cytokines also play a role in it.

B-lymphocytes

Humoral (antibody-mediated) type of rejection is caused by recipient’s B-lymphocytes which produce alloantibodies against donor MHC class I and II molecules.[3] These alloantibodies can activate the complement – this leads to target cell lysis. Alternatively, donor cells are coated with alloantibodies that initiate phagocytosis through Fc receptors of mononuclear leukocytes. Mechanism of humoral rejection is relevant for hyperacute, accelerated and chronic rejection. Alloimmunity can be also regulated by neonatal B cells.[4]

Cytokines

Cytokine microenvironment where CD4+ T-lymphocytes recognize alloantigens significantly influences polarization of the immune response.

NK cells

NK cells can also directly target the transplanted tissue. It depends on the balance of activating and inhibitory NK cell receptors and on their ligands expressed by the graft. Receptors of KIR (Killer-cell immunoglobulin-like receptor) family bind concrete MHC class I molecules. If the graft has these ligands on its surface, NK cell cannot be activated (KIR receptors provide inhibitory signal). So if these ligands are missing, there is no inhibitory signal and NK cell becomes activated. It recognizes target cells by “missing-self strategy” [7] and induces their apoptosis by enzymes perforin and granzymes released from its cytotoxic granules. Alloreactive NK cells also secrete proinflammatory cytokines IFN-γ and TNF-α to increase expression of MHC molecules and costimulatory receptors on the surface of APCs (antigen-presenting cells). This promotes APC maturation [8] which leads to amplification of T-cell alloreactivity by means of direct and also indirect pathway of alloantigen recognition (as described below). NK cells are able to kill Foxp3+ regulatory T-lymphocytes as well [7] and shift the immune response from graft tolerance toward its rejection. Besides the ability of NK cells to influence APC maturation and T cell development, they can probably reduce or even prevent alloimmune response to transplanted tissue – either by killing the Donor APCs [9] or by anti-inflammatory cytokine IL-10 and TGF-β secretion.[10] However it is important to note that NK cell sub-populations differ in alloreactivity rate and in their immunomodulatory potential. Concerning immunosuppressive drugs, the effects on NK cells are milder in comparison to T cells.[7]

T-lymphocytes

Alloantigen recognition

Alloantigen on APC surface can be recognized by recipient’s T-lymphocytes through two different pathways:[11]

Activation of T-lymphocytes

T-lymphocytes are fully activated under two conditions:

Alloimmune response can be enhanced by proinflammatory cytokines and by CD4+ T-lymphocytes [18] that are responsible for APC maturation and IL-2 production. IL-2 is crucial for memory CD8+ T cell development.[19] These cells may represent a serious problem after the transplantation. As the effect of being exposed to various infections in the past, antigen-specific T-lymphocytes have developed in patient’s body. Part of them is kept in organism as memory cells and these cells could be a reason for “cross-reactivity” – immune response against unrelated but similar graft alloantigens.[20] This immune response is called secondary and is faster, more efficient and more robust.

Graft tolerance

Transplanted tissue is accepted by immunocompetent recipient if it is functional in the absence of immunosuppressive drugs and without histologic signs of rejection. Host can accept another graft from the same donor but reject graft from different donor.[21] Graft acceptance depends on the balance of proinflammatory Th1, Th17 lymphocytes and anti-inflammatory regulatory T cells.[1] This is influenced by cytokine microenvironment, as mentioned before, where CD4+ T-lymphocytes are activated and also by inflammation level (because pathogens invading organism activate the immune system to various degrees and causing proinflammatory cytokine secretion, therefore they support the rejection).[22] Immunosuppressive drugs are used to suppress the immune response, but the effect is not specific. Therefore organism can be affected by the infection or cancer much more easily. The goal of the future therapies is to suppress the alloimmune response specifically to prevent these risks. The tolerance could be achieved by elimination of most or all alloreactive T cells and by influencing alloreactive effector-regulatory T-lymphocytes ratio in favor of regulatory cells which could inhibit alloreactive effector cells.[1] Another method would be based on costimulatory signal blockade during alloreactive T-lymphocytes activation.[23]

See also

Literature

References

  1. 1 2 3 4 5 6 7 Sánchez-Fueyo A, Strom TB (2011), Immunologic basis of graft rejection and tolerance following transplantation of liver or other solid organs. Gastroenterology 140(1):51-64
  2. Seetharam A, Tiriveedhi V, Mohanakumar T (2010), Alloimmunity and autoimmunity in chronic rejection. Curr Opin Organ Transplant 15(4):531-536
  3. Fang Li, Mary E. Atz, Elaine F. Reed (2009), Human leukocyte antigen antibodies in chronic transplant vasculopathy-mechanisms and pathways. Curr Opin Immunol. 21(5): 557–562
  4. Walker WE, Goldstein DR (August 2007). "Neonatal B cells suppress innate toll-like receptor immune responses and modulate alloimmunity". J. Immunol. 179 (3): 1700–10. doi:10.4049/jimmunol.179.3.1700. PMID 17641036.
  5. Walsh PT, Strom TB, Turka LA (2004), Routes to transplant tolerance versus rejection: the role of cytokines. Immunity (20):121-131
  6. Korn T, Bettelli E, Gao W, Awasthi A, Jäger A, Strom TB, Oukka M, Kuchroo VK (2007), IL-21 initiates an alternative pathway to induce proinflammatory T(H)17 cells. Nature 448(7152):484-7
  7. 1 2 3 Villard J. (2011), The role of natural killer cells in human solid organ and tissue transplantation. J Innate Immun. 3(4): 395-402
  8. McNerney ME, Lee KM, Zhou P, Molinero L, Mashayekhi M, Guzior D, Sattar H, Kuppireddi S, Wang CR, Kumar V, Alegre ML (2006), Role of natural killer cell subsets in cardiac allograft rejection. Am J Transplant. 6(3):505-13
  9. Yu G, Xu X, Vu MD, Kilpatrick ED, Li XC (2006), NK cells promote transplant tolerance by killing donor antigen-presenting cells. J Exp Med. 203(8):1851-8
  10. De Maria A, Fogli M, Mazza S, Basso M, Picciotto A, Costa P, Congia S, Mingari MC, Moretta L (2007), Increased natural cytotoxicity receptor expression and relevant IL-10 production in NK cells from chronically infected viremic HCV patiens. Eur J Immunol. 37(2):445-55
  11. Lafferty KJ, Prowse SJ, Simeonovic CJ, Warren HS (1983), Immunobiology of tissue transplantation: a return to the passenger leukocyte concept. Annu Rev Immunol.1:143-73 – according Archbold JK, Ely LK, Kjer-Nielsen L, Burrows SR, Rossjohn J, McCluskey J, Macdonald WA (2008), T-cell allorecognition and MHC-restriction – A case of Jekyll and Hyde? Mol Immunol. 45(3):583-98
  12. Fangmann J, Dalchau R, Fabre JW (1992), Rejection of skin allografts by indirect allorecognition of donor class I major histocompatibility complex peptides. J Exp Med. 175(6):1521-9
  13. Gould DS, Auchincloss H Jr (1999), Direct and indirect recognition: the role of MHC antigens in graft rejection. Immunol Today. 20(2):77-82
  14. Li XC, Rothstein DM, Sayegh MH (2009), Costimulatory pathways in transplantation: challenges and new developments. Immunol Rev. 229(1):271-93
  15. Jenkins MK, Taylor PS, Norton SD, Urdahl KB (1991), CD28 delivers a costimulatory signal involved in antigen-specific IL-2 production by human T cells. J Immunol. 147(8):2461-6 – according Priyadharshini B, Greiner DL, Brehm MA (2012), T-cell activation and transplantation tolerance. Transplant Rev (Orlando). 26(3):212-22
  16. Walunas TL, Lenschow DJ, Bakker CY, Linsley PS, Freeman GJ, Green JM, Thompson CB, Bluestone JA (1994), CTLA-4 can function as a negative regulator of T cell activation. Immunity. ;1(5):405-13 – according Priyadharshini B, Greiner DL, Brehm MA (2012), T-cell activation and transplantation tolerance. Transplant Rev (Orlando). 26(3):212-22
  17. Jenkins MK, Schwartz RH (1987), Antigen presentation by chemically modified splenocytes induces antigen-specific T cell unresponsiveness in vitro and in vivo. J Exp Med. 165(2):302-19
  18. Curtsinger JM, Mescher MF (2010), Inflammatory cytokines as a third signal for T cell activation. Curr Opin Immunol. 22(3):333-40
  19. Williams MA, Tyznik AJ, Bevan MJ (2006), Interleukin-2 signals during priming are required for secondary expansion of CD8+ memory T cells. Nature. 441(7095):890-3
  20. Welsh RM, Selin LK (2002), No one is naive: the significance of heterologous T-cell immunity. Nat Rev Immunol. 2(6):417-26
  21. Ashton-Chess J, Giral M, Brouard S, Soulillou JP (2007), Spontaneous operational tolerance after immunosuppressive drug withdrawal in clinical renal allotransplantation. Transplantation. 84(10):1215-9 – according Sánchez-Fueyo A, Strom TB (2011), Immunologic basis of graft rejection and tolerance following transplantation of liver or other solid organs. Gastroenterology 140(1):51-64
  22. Ahmed EB, Daniels M, Alegre ML, Chong AS (2011), Bacterial infections, alloimmunity, and transplantation tolerance. Transplant Rev (Orlando). 25(1):27-35
  23. Ford ML, Larsen CP (2009), Translating costimulation blockade to the clinic - lessons learned from three pathways. Immunol Rev. 229(1):294-306

External links

This article is issued from Wikipedia - version of the Tuesday, July 07, 2015. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.