Obesity and elevated circulating cholesterol are risk factors for breast cancer recurrence, while the use of statins, cholesterol biosynthesis inhibitors widely used for treating hypercholesterolemia, is associated with improved disease-free survival. Here, we show that cholesterol mediates the metastatic effects of a high-fat diet via its oxysterol metabolite, 27-hydroxycholesterol. Ablation or inhibition of CYP27A1, the enzyme responsible for the rate-limiting step in 27-hydroxycholesterol biosynthesis, significantly reduces metastasis in relevant animal models of cancer. The robust effects of 27-hydroxycholesterol on metastasis requires myeloid immune cell function, and it was found that this oxysterol increases the number of polymorphonuclear-neutrophils and γδ-T cells at distal metastatic sites. The pro-metastatic actions of 27-hydroxycholesterol requires both polymorphonuclear-neutrophils and γδ-T cells, and 27-hydroxycholesterol treatment results in a decreased number of cytotoxic CD8+T lymphocytes. Therefore, through its actions on γδ-T cells and polymorphonuclear-neutrophils, 27-hydroxycholesterol functions as a biochemical mediator of the metastatic effects of hypercholesterolemia.
The quest to decipher HLA immunogenicity: Telling friend from foe
| INTRODUC TI ONAdvances in HLA typing and HLA antibody testing over the past two decades transformed our ability to assess donor/recipient compatibility in the context of organ transplantation. Beginning from serologic donor/recipient HLA matching through emphasis on avoidance of preformed donor-specific HLA antibodies (DSAs), current approaches delve into amino acid sequences of HLA alleles, assessing the so-called molecular mismatch between donor and recipient, using one or more of the currently available tools: HLAMatchmaker, [1][2][3][4] Amino-Acid comparison, Electrostatic Mismatch Score (EMS 5-7 ), or PIRCHE-Predicted Indirectly ReCognizable HLA Epitopes presented by recipient HLA-Class II antigens. 8-10 A short description of each method is provided in the supplemental material.It is notable that only minor variations were found when comparing the ability of these different approaches to predict poor graft outcome (correlation ranging between R 2 of .85-.96). 8,11 In addition, when different patient populations were studied (eg, pediatric vs adult; kidney vs lung), different cutoff values were reported, 12-19 indicating the need Funding information Paul I Terasaki Research FoundationMolecular mismatch load analysis was recently introduced as a means for performing risk stratification following organ transplantation. However, although good correlation was demonstrated between molecular mismatch load and generation of de novo donor-specific HLA antibody (DSA), quite a few exceptions exist, and the underlying factors that define HLA immunogenicity remain unclear. Herein, we present a new paradigm to interrogate differences between molecular mismatches that lead to the generation of de novo DSA and those that do not (the 2MM1DSA cohort).Specifically, patients transplanted across 2 HLA-DQ mismatches, who formed de novo DSA only to one mismatch (foe) but not the other (friend), provide a unique environment in which patient-specific factors that affect the immune response other than immunogenicity, such as infection and immunosuppression, can be controlled for. It further permits focusing on mismatches uniquely exhibited by the de novo DSA allele, rather than mismatches shared by both DSA and non-DSA alleles. This concept paper illustrates several examples, highlights the need for center-specific or population-specific cutoff values for posttransplant risk stratification, and mostly argues that if there is no direct correlation between molecular mismatch load and immunogenicity, then molecular mismatch load must not be adopted as an approach for equitable organ allocation. K E Y W O R D Salloantibody, antigen presentation/recognition, clinical research/practice, histocompatibility, organ allocation
Cholesterol has been implicated in the clinical progression of breast cancer, a disease that continues to be the most commonly diagnosed cancer in women. Previous work has identified the cholesterol metabolite, 27-hydroxycholesterol (27HC), as a major mediator of the effects of cholesterol on breast tumor growth and progression. 27HC can act as an estrogen receptor (ER) modulator to promote the growth of ERα+ tumors, and a liver x receptor (LXR) ligand in myeloid immune cells to establish an immune-suppressive program. In fact, the metastatic properties of 27HC require the presence of myeloid cells, with neutrophils (PMNs) being essential for the increase in lung metastasis in murine models. In an effort to further elucidate the mechanisms by which 27HC alters breast cancer progression, we made the striking finding that 27HC promoted the secretion of extracellular vesicles (EVs), a diverse assortment of membrane bound particles that include exosomes. The resulting EVs had a size distribution that was skewed slightly larger, compared to EVs generated by treating cells with vehicle. The increase in EV secretion and size was consistent across three different subtypes: primary murine PMNs, RAW264.7 monocytic cells and 4T1 murine mammary cancer cells. Label-free analysis of 27HC-EVs indicated that they had a different metabolite composition to those from vehicle-treated cells. Importantly, 27HC-EVs from primary PMNs promoted tumor growth and metastasis in two different syngeneic models, demonstrating the potential role of 27HC induced EVs in the progression of breast cancer. EVs from PMNs were taken up by cancer cells, macrophages and PMNs, but not T cells. Since EVs did not alter proliferation of cancer cells, it is likely that their pro-tumor effects are mediated through interactions with myeloid cells. Interestingly, RNA-seq analysis of tumors from 27HC-EV treated mice do not display significantly altered transcriptomes, suggesting that the effects of 27HC-EVs occur early on in tumor establishment and growth. Future work will be required to elucidate the mechanisms by which 27HC increases EV secretion, and how these EVs promote breast cancer progression. Collectively however, our data indicate that EV secretion and content can be regulated by a cholesterol metabolite, which may have detrimental effects in terms of disease progression, important findings given the prevalence of both breast cancer and hypercholesterolemia.
With upwards of 90% of mortalities associated with breast cancer being attributed to metastasis, there is an urgent need to better understand what drives this stage of disease. In this regard, it has been reported that an elevated concentration of circulating cholesterol is an independent risk factor for breast cancer recurrence. Supporting the relationship between cholesterol and breast cancer progression, the use of cholesterol lowering drugs (statins) has been demonstrated to improve recurrence-free survival. These clinical observations suggest that cholesterol influences the metastatic progression of breast cancer. Therefore, in this study we directly tested the impact of cholesterol on breast cancer metastasis, and interrogated the downstream mechanisms by which it may be doing so. In strong support of our hypothesis, increased metastasis was observed when mice were placed on a high cholesterol diet. These findings highlighted recent work by us and others demonstrating that the primary metabolite, 27-hydroxycholesterol (27HC), was able to modulate the activities of two hormone receptors: the estrogen and the liver X receptors. Thus, we pursued a series of experiments to determine whether 27HC was responsible for the metastatic actions of cholesterol. 27HC is synthesized from cholesterol by the enzyme CYP27A1. The genetic ablation of CYP27A1 completely attenuated the effects of a high cholesterol diet, implicating 27HC as a primary mediator of cholesterol. Treatment with exogenous 27HC robustly increased metastasis. Importantly, genetic or pharmacologic inhibition of CYP27A1 also reduced the basal metastatic burden, indicating that this enzyme may be a suitable target for the prevention and/or treatment of metastatic breast cancer. Intriguingly, we found that the pro-metastatic effects of 27HC also required the presence of myeloid cells, which was demonstrated by their ablation using clodronate-loaded liposomes. In the absence of myeloid cells, the ability of 27HC to promote metastasis was dramatically reduced. Whilst interrogating the distal metastatic site, we found that this oxysterol enriched Ly6G+/CD11b+ polymorphonuclear-neutrophils (PMNs) and γδ T cells. The induction of metastasis by 27HC was lost in models where either PMNs or γδ T cells were ablated. We further demonstrate that 27HC treatment results in a decrease in cytotoxic CD8+ T cells, suggesting that the net result of the 27HC enriched γδ T cells and PMNs is local immune suppression. Collectively, our results demonstrate that cholesterol increases metastasis via the actions of its metabolite 27HC, which exerts its effects through γδ T cells and PMNs to suppress acquired immunity. Since 27HC acts on the host environment to promote breast cancer progression, these results strongly support the immediate translational potential of targeting the 27HC pathway for the prevention and treatment of metastasis. Citation Format: Amy E. Baek, Sisi He, Hannah B. McDowell, Erik R. Nelson. The cholesterol metabolite 27-hydroxycholesterol promotes breast cancer progression by affecting immune responses [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 997.
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