To better understand the response to mitochondrial dysfunction, we examined the mechanism by which Activating Transcription Factor associated with Stress-1 (ATFS-1) senses mitochondrial stress and communicates with the nucleus during the mitochondrial unfolded protein response (UPRmt). We found that the key point of regulation was the mitochondrial import efficiency of ATFS-1. In addition to a nuclear localization sequence, ATFS-1 has an amino-terminal mitochondrial targeting sequence, which was essential for UPRmt repression. Normally, ATFS-1 is imported into mitochondria and degraded. However, during mitochondrial stress, import efficiency was reduced allowing a percentage of ATFS-1 to accumulate in the cytosol and traffic to the nucleus. Our results show that cells monitor mitochondrial import efficiency via ATFS-1 to coordinate the level of mitochondrial dysfunction with the protective transcriptional response.
SUMMARY Mitochondrial dysfunction is pervasive in human pathologies such as neurodegeneration, diabetes, cancer and pathogen infections as well as during normal aging. Cells sense and respond to mitochondrial dysfunction by activating a protective transcriptional program known as the mitochondrial unfolded protein response (UPRmt), which includes genes that promote mitochondrial protein homeostasis and the recovery of defective organelles [1, 2]. Work in C. elegans has shown that the UPRmt is regulated by the transcription factor ATFS-1, which is regulated by organelle partitioning. Normally, ATFS-1 accumulates within mitochondria, but during respiratory chain dysfunction, high levels of ROS or mitochondrial protein folding stress, a percentage of ATFS-1 accumulates in the cytosol and traffics to the nucleus where it activates the UPRmt [2]. While similar transcriptional responses have been described in mammals [3, 4], how the UPRmt is regulated remains unclear. Here, we describe a mammalian transcription factor, ATF5, which is regulated similarly to ATFS-1 and induces a similar transcriptional response. ATF5 expression can rescue UPRmt signaling in atfs-1-deficient worms requiring the same UPRmt promoter element identified in C. elegans. Furthermore, mammalian cells require ATF5 to maintain mitochondrial activity during mitochondrial stress and to promote organelle recovery. Combined, these data suggest that regulation of the UPRmt is conserved from worms to mammals.
Foxp3+CD25+CD4+ regulatory T cells (Treg) mediate immunological self-tolerance and suppress immune responses. A subset of dendritic cells (DCs) in the intestine is specialized to induce Treg in a TGF-β- and retinoic acid-dependent manner to allow for oral tolerance. In this study we compare two major DC subsets from mouse spleen. We find that CD8+ DEC-205/CD205+ DCs, but not the major fraction of CD8− DC inhibitory receptor-2 (DCIR2)+ DCs, induce functional Foxp3+ Treg from Foxp3− precursors in the presence of low doses of Ag but without added TGF-β. CD8+CD205+ DCs preferentially express TGF-β, and the induction of Treg by these DCs in vitro is blocked by neutralizing Ab to TGF-β. In contrast, CD8−DCIR2+ DCs better induce Foxp3+ Treg when exogenous TGF-β is supplied. In vivo, CD8+CD205+ DCs likewise preferentially induce Treg from adoptively transferred, Ag-specific DO11.10 RAG−/− Foxp3−CD4+ T cells, whereas the CD8−DCIR2+ DCs better stimulate natural Foxp3+ Treg. These results indicate that a subset of DCs in spleen, a systemic lymphoid organ, is specialized to differentiate peripheral Foxp3+ Treg, in part through the endogenous formation of TGF-β. Targeting of Ag to these DCs might be useful for inducing Ag-specific Foxp3+ Treg for treatment of autoimmune diseases, transplant rejection, and allergy.
Summary Mitochondrial diseases and aging are associated with defects in the oxidative phosphorylation machinery (OXPHOS), which are the only complexes composed of proteins encoded by separate genomes. To better understand genome coordination and OXPHOS recovery during mitochondrial dysfunction, we examined ATFS-1, a transcription factor that regulates mitochondria-to-nuclear communication during the mitochondrial UPR, via ChIP-sequencing. Surprisingly, in addition to regulating mitochondrial chaperone, OXPHOS complex assembly factor, and glycolysis genes, ATFS-1 bound directly to OXPHOS gene promoters in both the nuclear and mitochondrial genomes. Interestingly, atfs-1 was required to limit the accumulation of OXPHOS transcripts during mitochondrial stress, which required accumulation of ATFS-1 in the nucleus and mitochondria. Because balanced ATFS-1 accumulation promoted OXPHOS complex assembly and function, our data suggest that ATFS-1 stimulates respiratory recovery by fine-tuning OXPHOS expression to match the capacity of the suboptimal protein-folding environment in stressed mitochondria, while simultaneously increasing proteostasis capacity.
Metazoans identify and eliminate bacterial pathogens in microbe-rich environments such as the intestinal lumen, however the mechanisms are unclear. Potentially, host cells employ intracellular surveillance or stress response programs to detect pathogens that target monitored cellular activities to initiate innate immune responses1–3. Mitochondrial function is evaluated by monitoring mitochondrial protein import efficiency of the transcription factor ATFS-1, which mediates the mitochondrial unfolded protein response (UPRmt). During mitochondrial stress, import is impaired4 allowing ATFS-1 to traffic to the nucleus where it mediates a transcriptional response to re-establish mitochondrial homeostasis5. Here, we examined the role of ATFS-1 during pathogen exposure because in addition to mitochondrial protective genes, ATFS-1 induced innate immune genes during mitochondrial stress that included a secreted lysozyme and anti-microbial peptides. Exposure to the pathogen Pseudomonas aeruginosa caused mitochondrial dysfunction and activation of the UPRmt. Animals lacking atfs-1 were susceptible to P. aeruginosa, while hyper-activation of ATFS-1 and the UPRmt improved clearance of P. aeruginosa from the intestine and prolonged C. elegans survival largely independent of known innate immune pathways6,7. We propose that ATFS-1 import efficiency and the UPRmt is a means to detect pathogens that target mitochondria and initiate a protective innate immune response.
Harnessing DCs for immunotherapies in vivo requires the elucidation of the physiological role of distinct DC populations. Migratory DCs traffic from peripheral tissues to draining lymph nodes charged with tissue self antigens. We hypothesized that these DC populations have a specialized role in the maintenance of peripheral tolerance, specifically, to generate suppressive Foxp3 + Tregs. To examine the differential capacity of migratory DCs versus blood-derived lymphoid-resident DCs for Treg generation in vivo, we targeted a self antigen, myelin oligodendrocyte glycoprotein, using antibodies against cell surface receptors differentially expressed in these DC populations. Using this approach together with mouse models that lack specific DC populations, we found that migratory DCs have a superior ability to generate Tregs in vivo, which in turn drastically improve the outcome of experimental autoimmune encephalomyelitis. These results provide a rationale for the development of novel therapies targeting migratory DCs for the treatment of autoimmune diseases.
Improved protein-based vaccines should facilitate the goal of effective vaccines against HIV and other pathogens. With respect to T cells, the efficiency of immunization, or "immunogenicity," is improved by targeting vaccine proteins to maturing dendritic cells (DCs) within mAbs to DC receptors. Here, we compared the capacity of Langerin/CD207, DEC205/CD205, and Clec9A receptors, each expressed on the CD8 + DC subset in mice, to bring about immunization of microbial-specific T cells from the polyclonal repertoire, using HIV gag-p24 protein as an antigen. α-Langerin mAb targeted splenic CD8 + DCs selectively in vivo, whereas α-DEC205 and α-Clec9A mAbs targeted additional cell types. When the mAb heavy chains were engineered to express gag-p24, the α-Langerin, α-DEC205, and α-Clec9A fusion mAbs given along with a maturation stimulus induced comparable levels of gag-specific T helper 1 (Th1) and CD8 + T cells in BALB/c × C57BL/6 F1 mice. These immune T cells were more numerous than targeting the CD8 − DC subset with α-DCIR2-gag-p24. In an in vivo assay in which gag-primed T cells were used to report the early stages of T-cell responses, α-Langerin, α-DEC205, and α-Clec9A also mediated cross-presentation to primed CD8 + T cells if, in parallel to antigen uptake, the DCs were stimulated with α-CD40. α-Langerin, α-DEC205, and α-Clec9A targeting greatly enhanced T-cell immunization relative to nonbinding control mAb or nontargeted HIV gag-p24 protein. Therefore, when the appropriate subset of DCs is targeted with a vaccine protein, several different receptors expressed by that subset are able to initiate combined Th1 and CD8 + immunity.antigen presentation | C-type lectins | cross-priming A major goal in the development of effective vaccines against pathogens such as HIV and malaria is the induction of durable and protective T-cell immunity. Attenuated viral vectors are being emphasized widely as a vaccine platform to elicit T-cell immunity in humans (1). Attenuated vectors have potential limitations with respect to immunogenicity and repeated use, however (2). Protein vaccines could provide a stand-alone or complementary platform (e.g., to viral vectors), with relative ease of production and ability to be repeatedly injected. Proteins are poorly immunogenic for T cells, however, even when administered repeatedly in high doses.Recent progress in immunobiology provides the potential to overcome this obstacle. The immunogenicity of proteins can be greatly enhanced by improving the delivery of protein to dendritic cells (DCs). To do this, one approach is to introduce the protein into mAbs that efficiently and specifically target to DC receptors in situ, within lymphoid tissues, and then to coadminister the fusion antibody with an appropriate agonist for DC maturation [reviewed in (3, 4)]. Delivery of vaccine proteins within mAbs increases the efficiency of antigen presentation on MHC class I and II molecules ∼100-fold and allows protein vaccines to induce T helper 1 (Th1) type CD4 + T cells and CD8 + T cells (5-8).The DC ...
During development and cellular differentiation, tissue and cell-specific programs mediate mitochondrial biogenesis in order to meet physiological needs. However, environmental and disease-associated factors can perturb mitochondrial activities requiring cells to adapt to protect mitochondria and maintain cellular homeostasis. Several mitochondria-to-nuclear signaling pathways, or retrograde responses, have been described, but the mechanisms by which mitochondrial stress or dysfunction is sensed to precisely coordinate the appropriate response has only recently begun to be understood. Recent studies of the mitochondrial unfolded protein response (UPRmt) indicate that the cell monitors mitochondrial protein import efficiency as an indicator of mitochondrial function. Here, we review how the cell evaluates mitochondrial function and regulates transcriptional induction of the UPRmt, adapts protein synthesis rates and activates mitochondrial autophagy to promote mitochondrial function and cell survival during stress.
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