SUMMARY Regulatory T (Treg) cells suppress inflammatory immune responses and autoimmunity caused by self-reactive T cells. The key Treg cell transcription factor Foxp3 is downregulated during inflammation to allow for the acquisition of effector T cell-like functions. Here, we demonstrate that stress signals elicited by proinflammatory cytokines and lipopolysaccharide lead to the degradation of Foxp3 through the action of the E3 ubiquitin ligase Stub1. Stub1 interacted with Foxp3 to promote its K48-linked polyubiquitination in an Hsp70-dependent manner. Knockdown of endogenous Stub1 or Hsp70 prevented Foxp3 degradation. Furthermore, the overexpression of Stub1 in Treg cells abrogated their ability to suppress inflammatory immune responses in vitro and in vivo, and conferred a T helper 1 (Th1) cell-like phenotype. Our results demonstrate the critical role of the stress-activated Stub1-Hsp70 complex in promoting Treg cell inactivation, thus providing a potential therapeutic target for the intervention against autoimmune disease, infection and cancer.
Significance Natural regulatory T cells (nTregs) play important roles in preventing autoimmune diseases, but they may be unstable in the presence of inflammation. Here we report that all - trans RA (atRA) but not rapamycin prevents human nTregs from converting to Th1/Th17 cells and sustains their suppressive function in inflammatory environments. Adoptive transfer of nTregs pretreated with atRA enhances their suppressive effects on xenograft-vs. - host diseases. Moreover, we show that atRA suppresses IL-1 receptor upregulation, accelerates IL-6 receptor downregulation, and affects the epigenetic modifications in Foxp3 locus in nTregs following inflammatory stimulation. We suggest that nTregs primed with atRA may represent a novel treatment strategy to control established chronic immune-mediated diseases.
Parkin is an E3 ubiquitin ligase that mediates the ubiquitination of protein substrates. The mutations in the parkin gene can lead to a loss of function of parkin and cause autosomal recessive juvenile onset parkinsonism. Recently, parkin was reported to be involved in the regulation of mitophagy. Here, we identify the Bcl-2, an anti-apoptotic and autophagy inhibitory protein, as a substrate for parkin. Parkin directly binds to Bcl-2 via its C terminus and mediates the mono-ubiquitination of Bcl-2, which increases the steady-state levels of Bcl-2. Overexpression of parkin, but not its ligase-deficient forms, decreases autophagy marker LC3 conversion, whereas knockdown of parkin increases LC3 II levels. In HeLa cells, a parkin-deficient cell line, knockdown of parkin does not change LC3 conversion. Moreover, overexpression of parkin enhances the interactions between Bcl-2 and Beclin 1. Our results provide evidence that parkin mono-ubiquitinates Bcl-2 and regulates autophagy via Bcl-2. Parkinson disease (PD)2 is the second most common neurodegenerative disorder after Alzheimer disease (1) and is characterized by a distinct set of motor symptoms including tremor, muscle rigidity, postural instability, and bradykinesia (2). Although the cause of PD is poorly understood, there is evidence that both environmental factors and genetic factors contribute to its development. Recently, several genes have been reported to be associated with the pathogenesis of familial forms of PD. Mutations in the parkin gene (PARK2; OMIM600116) cause autosomal recessive juvenile onset parkinsonism (3). It has been shown that mutations in parkin account for nearly 50% of patients with the early onset familial PD cases (3-6) and more than 15% of sporadic PD cases with early onset (7).Parkin is a 465-amino acid protein that contains an ubiquitin-like domain at its N terminus and two RING finger domains separated by an in-between-ring domain at its C terminus. Similar to other RING finger-containing proteins, parkin is an E3 ubiquitin ligase. Parkin ubiquitinates several target proteins and enhances their degradation via the ubiquitin-proteasome system (8, 9). Ubiquitination of a substrate is usually processed by a multi-step involving the sequential activity of an E1 ubiquitin-activating enzyme, an E2 ubiquitin-conjugating enzyme, and an E3 ubiquitin-protein ligase (10). It was reported that parkin can selectively interact with the E2 enzymes, UbcH7 and UbcH8 (9,11,12). A number of protein substrates for parkin have been identified, including synphilin-1 (13, 14), CDCrel-1 and 2a (12, 15), Pael-R (16), synaptotagmin XI (17), ␣-and -tubulin (18), RanBP2 (19), cyclin E (20), the aminoacyl-tRNA synthetase cofactor p38/AIMP2 (21, 22), Eps15 (23), and far upstream sequence element-binding protein 1 (24). Within these substrates, p38/AIMP2 and far upstream sequence element-binding protein 1 were reported to be accumulated in brains of parkin null mice, MPTP (1-Methyl-4-phenyl-1,2,3,6-tetrahydropyridine) treated mice, and sporadic PD cases (22,24)...
Although different autoimmune diseases show discrete clinical features, there are common molecular pathways intimately involved. Here we show that miR-125a is downregulated in peripheral CD4 þ T cells of human autoimmune diseases including systemic lupus erythematosus and Crohn's disease, and relevant autoimmune mouse models. miR-125a stabilizes both the commitment and immunoregulatory capacity of Treg cells. In miR-125a-deficient mice, the balance appears to shift from immune suppression to inflammation, and results in more severe pathogenesis of colitis and experimental autoimmune encephalomyelitis (EAE). The genome-wide target analysis reveals that miR-125a suppresses several effector T-cell factors including Stat3, Ifng and Il13. Using a chemically synthesized miR-125a analogue, we show potential to re-programme the immune homeostasis in EAE models. These findings point to miR-125a as a critical factor that controls autoimmune diseases by stabilizing Treg-mediated immune homeostasis.
Forkhead box P3 (FOXP3)-positive Treg cells are crucial for maintaining immune homeostasis. FOXP3 cooperates with its binding partners to elicit Treg cells' signature and function, but the molecular mechanisms underlying the modulation of the FOXP3 complex remain unclear. Here we report that Deleted in breast cancer 1 (DBC1) is a key subunit of the FOXP3 complex. We found that DBC1 interacts physically with FOXP3, and depletion of DBC1 attenuates FOXP3 degradation in inflammatory conditions. Treg cells from Dbc1-deficient mice were more resistant to inflammationmediated abrogation of Foxp3 expression and function and delayed the onset and severity of experimental autoimmune encephalomyelitis and colitis in mice. These findings establish a previously unidentified mechanism regulating FOXP3 stability during inflammation and reveal a pathway for potential therapeutic modulation and intervention in inflammatory diseases.+ Treg cells are actively engaged in the prevention of autoimmunity and the mitigation of aberrant or excessive immune responses (1-3). The transcription factor Forkhead box P3 (denoted "FOXP3" in humans, and "Foxp3" in mice) is a well-characterized marker of Treg cells, and its expression typically is considered a requisite for Tregcell differentiation and function (4, 5). FOXP3 deficiency leads to the scurfy phenotype in mice and to the immune dysregulation, polyendocrinopathy, and enteropathy, X-linked syndrome in humans (6). Moreover, Treg-cell function is impaired in several autoimmune and inflammatory diseases, including colitis, rheumatoid arthritis, multiple sclerosis, and systemic lupus erythematosus (7). Thus, the manipulation of Treg-cell function might provide a practical approach to the treatment of autoimmune and inflammatory diseases.Despite the central role of FOXP3 in Treg cells, many questions remain regarding the molecular mechanisms by which FOXP3 regulates Treg-cell function. Foxp3 protein is expressed transiently in CD4 + CD25− effector T cells upon T-cell receptor (TCR) stimulation but does not generate T cells with suppressive activity (8, 9). It has become evident that Foxp3 alone is insufficient to reproduce completely the differentiation and functional characteristics of Treg cells (10-12). FOXP3 binds with its partners to form multiple positive and negative feedback loops to regulate Treg-cell function subtly (13). FOXP3 interacts with FOXP1 to form heterodimers that promote FOXP3-mediated repression of IL-2 production (14). FOXP3 also binds with several nuclear factors, such as GATA3 (11, 15), RORγt (16), Eos (17), and RUNX1 (18), to drive the Treg cells' genetic program. FOXP3 function also is regulated at the posttranslational level. FOXP3 has been shown to interact with the acetyltransferase Tat-interaction protein 60 kDa (TIP60) to promote FOXP3 acetylation, which is required for Treg cells' suppressive function (19). P300 also regulates (11); therefore, many questions remain regarding the differential modulation of this complex and its effect on Treg-cell differenti...
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