Project description:<p>B7H3 (CD276), a key immune checkpoint molecule that is overexpressed in tumors, plays a central role in cancer progression, making it a highly promising and specific therapeutic target. Here, we discovered that the cellular metabolite palmitic acid contributes to the development of an immunosuppressive microenvironment in colorectal cancer by triggering the palmitoylation of B7H3. Mechanistically, the palmitoyltransferase ZDHHC24 catalyzes the palmitoylation of B7H3 at Cys496, preventing its binding to the autophagy adaptor protein SQSTM1/p62 and inhibiting autophagic degradation. Using spectral flow techniques, we demonstrated that the mutation of this palmitoylation site restored CD8+ T cell antitumor activity. Additionally, CD8+ T cells also showed enhanced antitumor activity in a Zdhhc24-deficient colitis-associated colorectal (CAC) carcinogenesis mouse model. Furthermore, we developed a small-molecule peptide that enhances CD8+ T cell function by blocking the interaction between ZDHHC24 and B7H3, which works synergistically with anti-PD-1 therapy. In conclusion, our study revealed that B7H3 C496 palmitoylation is a critical immunosuppressive factor in colorectal cancer and represents a potential target for malignant immunotherapy.</p>

Project description:Mitochondria regulate T cell functions and response to cancer immunotherapy. We show that pharmacologically induced PKM2 activation enhances mitochondria-dependent effector functions in mouse and human CD8 T cells and CAR-T cells. Multi-omics analysis and 13C-glucose tracer experiments showed that PKM2 activation alters one-carbon metabolism with decreased levels of methionine leading to hypomethylation of mitochondrial and nuclear DNA and enhanced expression of genes supporting mitochondrial biogenesis and respiratory complex formation in CD8 T cells. Functionally, PKM2 activation increased the recall responses and anti-tumor functions of CD8 T cells after adoptive cell therapy. Using preclinical melanoma and colon cancer models, we found that PKM2-agonist induced CD8 T cell-dependent anti-tumor responses that synergized with PD1 blockade therapy. Immunologically, PKM2 agonists resulted in enhanced activation and decreased exhaustion of effector T cells while reducing the numbers of suppressive FoxP3+ Treg cells in the tumor microenvironment. Anti-PD1 combination further enhanced the frequency and activation of tumor specific CD8 T cells in the tumors. Together, we show that PKM2 agonism modulates mitochondrial structure and function, leading to enhanced effector functions of cytotoxic lymphocytes. Hence, targeting PKM2 via pharmacologically available small molecules can be a clinically viable strategy for the enhancement of therapeutic potential of in-situ immune responses, adoptive cell therapy, and immune checkpoint blockade therapy

Project description:Mitochondria regulate T cell functions and response to cancer immunotherapy. We show that pharmacologically induced PKM2 activation enhances mitochondria-dependent effector functions in mouse and human CD8 T cells and CAR-T cells. Multi-omics analysis and 13C-glucose tracer experiments showed that PKM2 activation alters one-carbon metabolism with decreased levels of methionine leading to hypomethylation of mitochondrial and nuclear DNA and enhanced expression of genes supporting mitochondrial biogenesis and respiratory complex formation in CD8 T cells. Functionally, PKM2 activation increased the recall responses and anti-tumor functions of CD8 T cells after adoptive cell therapy. Using preclinical melanoma and colon cancer models, we found that PKM2-agonist induced CD8 T cell-dependent anti-tumor responses that synergized with PD1 blockade therapy. Immunologically, PKM2 agonists resulted in enhanced activation and decreased exhaustion of effector T cells while reducing the numbers of suppressive FoxP3+ Treg cells in the tumor microenvironment. Anti-PD1 combination further enhanced the frequency and activation of tumor specific CD8 T cells in the tumors. Together, we show that PKM2 agonism modulates mitochondrial structure and function, leading to enhanced effector functions of cytotoxic lymphocytes. Hence, targeting PKM2 via pharmacologically available small molecules can be a clinically viable strategy for the enhancement of therapeutic potential of in-situ immune responses, adoptive cell therapy, and immune checkpoint blockade therapy

Project description:Mitochondrial loss and dysfunction drive T cell exhaustion and represent major barriers to successful T cell immunotherapies. We found that mesenchymal stromal cells (MSC) establish nanotubular connections with T cells in a TLN2-dependent manner and leveraged these intercellular highways to supply new mitochondria to CD8+ T cells. Acquisition of MSC mitochondria increased T cell basal mitochondrial respiration and spare respiratory capacity. When transferred into tumor-bearing hosts, tumor-specific CD8+ T cells with donated mitochondria expanded more robustly, infiltrated the tumor more efficiently, and exhibited fewer signs of exhaustion compared to CD8+ T cells that did not take up mitochondria. As a result, mitochondria-boosted CD8+ T cells mediated superior antitumor responses, prolonging animal survival. To unravel the mechanisms behind mitochondrial transfer we performed RNA sequencing on CD8+ T cells that acquired donor mitochondria (MitoPositive), or did not acquire donor mitochondira (MitoNegative) directly after after co-culture (0hr timepoint).

Project description:Enhancing CD8+ T cell function is crucial for improving cancer immunotherapy. Through CRISPR screening and validation, we identified that mitochondrial translation is upregulated in activated and exhausted CD8+ T cells, leading to the accumulation of misfolded proteins that induce mitochondrial stress and contribute to T cell dysfunction. Inhibition of this over-translation using low doses of chloramphenicol (CAP) significantly enhanced the antitumor activity of activated CD8+ T cells by promoting their expansion and reducing apoptosis and exhaustion. Low-dose CAP treatment preserved oxidative phosphorylation (OXPHOS) and cytokine production while restoring mitochondrial membrane potential. Furthermore, CAP facilitated the import of mitochondrial protein precursors, shifted HSP70 pools binding toward NFATc1, and limited its nuclear translocation, thereby reducing exhaustion markers of TIM-3 and PD1. Notably, a short course of low-dose Linezolid, a commonly used antibiotic and mitochondrial translation inhibitor, improved the CD8+ T cell ratio in the peripheral blood of patients with diffuse large B cell lymphoma. These findings highlight mitochondrial translation inhibition as a promising strategy to enhance CD8+ T cell function and potentially improve the effectiveness of cancer immunotherapy.

Project description:Iron is an irreplaceable co-factor for metabolism. Iron deficiency affects >1 billion people and decreased iron availability impairs immunity. Nevertheless, how iron deprivation impacts immune cell function remains poorly characterised. We interrogated how physiologically low iron availability affected CD8+ T cell metabolism and function, using multi-omic and metabolic labelling approaches. Iron limitation did not substantially alter initial post-activation increases in cell size and CD25 upregulation. However, low iron profoundly stalled proliferation (without influencing cell viability), altered histone methylation status, gene expression, and disrupted mitochondrial membrane potential. Glucose and glutamine metabolism in the TCA cycle was limited and partially reversed to a reductive trajectory. Previous studies identified mitochondria-derived aspartate as crucial for proliferation of transformed cells. Surprisingly and despite aberrant TCA cycling, aspartate was increased in stalled iron deficient CD8+ T-cells but was not utilised for nucleotide synthesis, likely due to trapping within depolarised mitochondria. Exogenous aspartate markedly rescued expansion and some functions of severely iron-deficient CD8+ T-cells. Overall, iron scarcity creates a mitochondrial-located metabolic bottleneck, which is bypassed by supplying inhibited biochemical processes with aspartate. These findings reveal molecular consequences of iron deficiency for CD8+ T cell function, providing mechanistic insight into the basis for immune impairment during iron deficiency.

Project description:This phase I pilot trial studies the side effects of cluster of differentiation 8 (CD8)+ T cells in treating patients with gastrointestinal tumors that have spread to other places in the body. Tumor cells and blood are used to help create an adoptive T cell therapy, such as CD8+ T cell therapy, that is individually designed for a patient and may help doctors learn more about genetic changes in the tumor. Immunotherapy with monoclonal antibodies, such as pembrolizumab, may help the body’s immune system attack the cancer, and may interfere with the ability of tumor cells to grow and spread. Giving CD8+ T cell therapy and pembrolizumab may work better in treating patients with gastrointestinal tumors.

Project description:Metabolic reprogramming dictates the fate and function of stimulated T cells, yet these pathways can be suppressed in T cells subjected to unique microenvironments, such as in a tumor. We previously showed that glycolytic and mitochondrial adaptations directly contribute to reduced effector functions of Renal Cell Carcinoma (RCC) CD8 tumor infiltrating lymphocytes (TIL). Here we define the role of these metabolic pathways in the activation and effector functions of RCC CD8 TIL. CD28 co-stimulation plays a key role to augment T cell activation and metabolism and is antagonized by inhibitory and checkpoint immunotherapy receptors CTLA4 and PD-1. While RCC CD8 TIL activated poorly when stimulated through the T cell receptor alone, addition of CD28 co-stimulation greatly enhanced activation, function, and proliferation. CD28 co-stimulation reprogrammed RCC CD8 TIL metabolism with increased glycolysis and mitochondrial oxidative metabolism, in part through upregulation of GLUT3. Mitochondria also became more fused, with higher membrane potential and overall mass. These phenotypes were dependent on glucose metabolism, as the glycolytic inhibitor 2-deoxyglucose both prevented changes to mitochondria and suppressed RCC CD8 TIL activation and function. These data show that CD28 co-stimulation can restore RCC CD8 TIL metabolism and function through rescue of T cell glycolysis that supports mitochondrial mass and activity.

Project description:Mitochondrialloss and dysfunctiondrive T cell exhaustion, representing major barriers to successful T cell-based immunotherapies. We found that bone marrow stromal cells (BMSCs) transfer stromal cell mitochondria into CD8+ T cells. CD8+ T cells with donated mitochondria displayed enhanced mitochondrial respiration and spare respiratory capacity. When transferred into tumor-bearing hosts, these supercharged T cells expanded more robustly, infiltrated the tumor more efficiently, and exhibited fewer signs of exhaustion compared to T cells that did not take up mitochondria. As a result, mitochondria-boosted CD8+ T cells mediated superior antitumor responses, prolonging animal survival.

Project description:Enhancing mitophagy, a naturally-occurring cellular process for elimination of damaged mitochondria, holds great promise for the intervention of many human diseases. Proteolysis-targeting chimeras (PROTACs) are heterobifunctional molecules that induce ubiquitination and subsequent proteasome-mediated degradation of a target protein through simultaneously binding to the target protein and an E3 ubiquitin ligase. However, the narrow cavity of the proteasome prevents the degradation of mitochondria. Here we show that the E3 ubiquitin ligase MAP3K1, when recruited to the outer mitochondria membrane (OMM) protein TSPO by our PROTAC-designed molecules (termed “mitophagy-enhancing chimeras”, or MECs), induced extensive K63 ubiquitination of TSPO and other OMM proteins, reminiscent of the PINK1-activated Parkin, without triggering proteasome-mediated degradation of TSPO. Aided by NBR1 and Nur77, this increased K63 ubiquitination of OMM proteins triggered mitophagy exclusively for damaged mitochondria, leading to improved mitochondria function and diminished cellular ROS. With the capability to enhance mitophagy at low nanomolar concentrations, MECs effectively inhibited NLRP3 inflammasome activation, abrogated acetaminophen-induced acute liver injury and mitigated high-fat diet-induced obesity in mice. Our work provided a proof-of-concept for developing unconventionally-acting PROTACs to achieve degradation of damaged mitochondria and possibly other organelles.