Kidney Transplantation Clinical Trial
Official title:
Effect of Different Therapeutic Strategies on Regulatory T Cells in Kidney Transplantation: a Randomized Study
The objective of the study will be to evaluate the effect of different therapeutic immunosuppressive strategies currently employed in common clinical practice on regulatory T lymphocytes and to verify the hypothesis that the association of thymoglobulins - mTOR inhibitors - small doses of Tacrolimus not only represents a safe anti-rejection therapy but it can also lead to mid-term formation of a high amount of regulatory T cells and, consequently, a high grade of tolerance.
Immune response is mediated by the interaction between antigen-presenting cells (APC), CD4+
helper T cells (Th) and regulatory T cells (Treg), a subpopulation of CD4+ T cells which
intensively expresses IL-2 receptor (CD25) and FoxP3 transcription factor. Treg cells
contribute maintaining tolerance by suppressing immune response to normal or tumour
self-antigens. Treg cells originate in the thymus during ontogenesis and represent
approximately 10% of peripheral CD4+ cells. All effector T lymphocytes generate in the
thymus at the early stages of life and evolve through the production of new T lymphocytes as
well as through antigen-induced expansion of virgin (naive) peripheral T lymphocytes which
convert to "memory" T lymphocytes and lie in peripheral lymphoid organs (17). Mature T
lymphocytes constitute 70-80% of normal peripheral blood lymphocytes, 30-40% of lymph nodes
cells and 20-30% of splenic lymphoid cells.
T lymphocytes are primary effectors of cell-mediated immunity and differentiate into a
subpopulation of CD8+ cytotoxic T lymphocytes which are able to lyse foreign cells or virus
infected host-cells and a subpopulation of CD4+ T lymphocytes with a regulating activity on
T and B lymphocytes and monocytes, through the production of cytokines and cell-to-cell
contact.
Treg lymphocytes play a central role among CD4+ cells in balancing tolerance and immunity,
as they are responsible for maintaining peripheral tolerance through the control of
self-reactive T cells which escaped thymic deletion (19). Studies have in fact demonstrated
that whether on one side a defect in their development or activity can lead to serious
autoimmune diseases, an excessive immunosuppression mediated by these cells stimulates, on
the other side, an immunodeficient condition also towards antigens produced by neoplastic
cells favouring, as a consequence, tumour growth.
Treg lymphocytes represent approximately 10% of all CD4+ T cells present in the thymus,
peripheral blood and lymphoid tissues; they consist of various populations which differ in
terms of particular cell-surface molecules expression and the production of diverse
cytokines, but share a common scarce response to antigenic stimulation and an
immunosuppressive activity.
The best characterized Treg lymphocytes are the so called "natural occurring Tregs"
(nTregs), a sub-group of CD4+ T cells which originates and develops in the thymus during
T-cellular maturation process and is afterwards normally present in peripheral blood with
the function of controlling self-antigens and preventing autoimmune diseases. These
lymphocytes are characterized by the constitutive expression of CD-25 (interleukin-2
receptor α chain), Foxp3 transcription factor (specific to these cells and implied in the
development control within the thymus), CTLA-4, GITR and LAG-3 surface molecules as well as
TGF-β cytokine, which is present in great quantity on cellular surface and is fundamental to
their functioning.
So called "induced Tregs" (iTregs) build the other Treg lymphocytes category: these are CD4+
T lymphocytes which lack in intrinsic regulatory potential but acquire their suppressive
activity thanks to a specific and cytokine-mediated activation (26). They are produced in
periphery and allow the development of peripheral tolerance to self-antigens, not or
scarcely expressed in the thymus. iTregs consist themselves of two different lymphocytic
subpopulations: Tr1, present in intestinal mucosa and characterized by a high production of
IL-10 and TGF-β but Foxp3 negative; and T helper 3 (Th3), deriving from the induction of
native CD4+ T cells due to the ingestion of alimentary antigens, responsible for oral
tolerance. Th3 are Foxp3 positive and release high levels of TGF-β (27).
While iTregs seem to function only by the production of immunosuppressive cytokines such as
IL-10 and TGF-β, nTregs can exert their activity also through various mechanisms, such as
cytokine-dependent, cell contact-dependent or both, according to the nature and intensity of
the inflammatory response and of the target tissue to which the latter is directed. This
context-dependent regulatory mechanism leads to the elaboration of the model of adaptability
and diversification within the function of these cells: in other words, Tregs would
constitute a functionally homogeneous cellular subgroup in which every single cell can exert
a different mechanism according to the characteristics of inflammatory response. Some
authors believe instead that Tregs consist of several subpopulations, each of these
presenting its own inhibitory mechanisms (27-28).
Phenotypic characterization of Tregs among circulating human lymphocytes has been
complicated by the fact that CD25 is not exclusively expressed by Tregs but also by
non-regulatory lymphocytes after activation, so at present only CD4+ cells expressing the
highest CD25 levels (CD4+CD25+bright) can be considered authentic Tregs.
In 2003 the Forkhead Transcription Factor (Foxp3) was identified as major regulator in Tregs
development; its expression is predominantly restricted to CD4+CD25+ T lymphocytes and Foxp3
expression in naive T cells supports their conversion into a regulatory T phenotype
functionally similar to nTregs. Foxp3 is therefore considered an extremely specific marker
of Treg cells and is fundamental to the control of their development und functioning.
Particularly, some studies have demonstrated that the lack of Foxp3 at birth in humans and
rats leads to a massive T-cellular hyperproliferation, resulting in multi-organ autoimmunity
and premature death (24), whereas its deletion in adult rats causes hyperproliferation and
expansion of dendritic cells as well as death within two weeks. Based on these results Foxp3
seems to be the ideal marker for tolerance study.
Tregs production is strictly controlled by signals emanated by various types of cells, such
as epithelial cells, T lymphocytes and APCs. Although the presence of the latter is
fundamental to TCR-mediated activation of Tregs, the real suppressive phase in vitro induced
by nTregs is actually APC-independent. It implies in fact a mechanism of contact between
CD4+CD25- effector T lymphocytes and CD4+CD25+ nTregs.
At present we dispose of little knowledge regarding functional consequences of suppression
carried out by Tregs on CD4+ and CD8+ lymphocytes which are sensitive to them, beside that
they inhibit IL-2 transcription and, consequently, induce cell cycle interruption. Further
immune suppression mechanisms reported by other studies, but not yet confirmed, are
following: anergy induction in responsive T cells, refractory reaction to the mitogenic
effects of IL-2, release of new iTregs which are likely to suppress Th1s and Th2s by
producing TGFβ1 and/or IL-10.
NTregs require particular cytokines for their development and homeostasis. Moreover, Tregs
result to be hypoproliferative or anergic to TCR activation, probably due to their
incapability of transcribing and actively secreting IL-2. This cytokine is principally
released by activated T lymphocytes but not by nTregs and it exerts its biologic activities
by binding to its receptor, a membrane protein complex formed by three subunits: α (CD25), β
and γ chain.
When IL-2 binds to its receptor in T cells it activates Janus kinases (JAKs) which
consequently phosphorylate and release STAT5 proteins (signal transducers and transcription
activators). IL-2 exerts in fact its effects on T cells by regulating several target genes
primarily at transcriptional level; it does not only increase the expression of IL-2R α and
β chains but it also modulates the expression of genes involved in cell cycle regulation, by
inducing for instance the up-regulation of proto-oncogenes such as c-myc, c-fos and c-jun,
as well as anti-apoptotic genes such as bcl-2 or pro-apoptotic genes like Fas ligand. IL-2
is essential for nTreg development and maintenance, as some studies have demonstrated:
induced IL-2 depletion in rats causes autoimmune diseases which can be associated to a
reduced number of Foxp3+ nTreg lymphocytes in peripheral compartment.
Another important cytokine to the functioning of Tregs is TGF-β. Despite its inhibitory
effects on other T cells, this growth factor is likely to support extra-thymic production of
Treg cells and the increase of Foxp3 expression: this action is, however, necessary
exclusively to the initial induction. TGF-β plays therefore a different but complementary
role to IL-2.
Finally, a further critical cytokine to the functioning of Tr1 lymphocytes is IL-10. Chronic
activation in vitro of CD4+ lymphocytes in the presence of IL-10 leads to their
differentiation in Tr1, high levels of IL-10 and TGF-β, low levels of IL-2 and IL-4 and a
scarce proliferation after restimulation. IL-10 can moreover induce immunosuppression by
supporting the formation of anergic T cells capable of inhibiting the activity of other
activated T lymphocytes through a contact-dependent mechanism, by competing with the latter
for specific APC (Antigen Presenting Cells) receptors and for locally produced IL-2. These
anergic T cells are able to suppress immune response in vivo, as their transfer in rats
which underwent allogeneic skin graft showed a longer transplant survival.
Beside the above mentioned cytokines, others seem to be involved in different ways in Treg
generation and induction, such as IL-4 and IL-13, whereas other cytokines have an antagonist
effect on them, such as IL-6 for instance, which contrasts their immunosuppressive activity
without interfering with proliferation. Other studies on Treg function have also showed that
a transfusion of allogeneic Treg lymphocytes and the subsequent skin graft in IL2Rβ-/- rats
(rapidly prone to lethal autoimmune diseases if not treated) not only controlled and
suppressed those diseases although Tregs and self-reactive T cells were MHC-incompatible,
but also consequently allowed to establish a state of tolerance to those transplants
presenting common MHC molecules to donor Tregs. This experiment has then proved that Tregs
suppress also self-reactive T cells deriving from non MHC-correlated donors and so,
theoretically, that the donor pool for Treg-based immune therapy would be potentially very
wide.
Thanks to their essential role in immune tolerance and their immunosuppressive function,
Treg lymphocytes are therefore gaining more and more importance in transplantology, as
experimental models of organ transplants have underlined their capability of modulating CD4+
and CD8+ cell activity, both responsible for rejection, by inhibiting it, and of suppressing
GVHD (Graft-versus-host disease), mediating in this way allotransplant tolerance. There are,
however, controversial results regarding Treg phenotype and their action mechanism,
depending on the experimental model and on the protocol used to induce this tolerance.
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