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Review

Trial watch: dietary interventions for cancer therapy

Sarah LévesqueEquipe 11 labellisée par la Ligue Nationale contre le Cancer, Centre de Recherche des Cordeliers, Paris, France;INSERM, U1138, Paris, France;Metabolomics and Cell Biology Platforms, Gustave Roussy Cancer Campus, Villejuif, France;Université Paris-Saclay, Orsay, France;Fondation pour la Recherche Médicale, Paris, FranceView further author information
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Jonathan G. PolEquipe 11 labellisée par la Ligue Nationale contre le Cancer, Centre de Recherche des Cordeliers, Paris, France;INSERM, U1138, Paris, France;Metabolomics and Cell Biology Platforms, Gustave Roussy Cancer Campus, Villejuif, France;Université Paris Descartes/Paris V, Sorbonne Paris Cité, Paris, France;Université Pierre et Marie Curie/Paris VI, Paris, FranceView further author information
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Gladys FerrereINSERM U1015, Villejuif, France;CICBT507, Villejuif, FranceView further author information
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Lorenzo GalluzziUniversité Paris Descartes/Paris V, Sorbonne Paris Cité, Paris, France;Department of Radiation Oncology, Weill Cornell Medical College, New York, NY, USA;Sandra and Edward Meyer Cancer Center, New York, NY, USA;Department of Dermatology, Yale School of Medicine, New Haven, CT, USAView further author information
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Laurence ZitvogelUniversité Paris-Saclay, Orsay, France;INSERM U1015, Villejuif, France;CICBT507, Villejuif, FranceORCID Iconhttps://orcid.org/0000-0003-1596-0998View further author information
ORCID Icon &
Guido KroemerEquipe 11 labellisée par la Ligue Nationale contre le Cancer, Centre de Recherche des Cordeliers, Paris, France;INSERM, U1138, Paris, France;Metabolomics and Cell Biology Platforms, Gustave Roussy Cancer Campus, Villejuif, France;Université Paris-Saclay, Orsay, France;Université Paris Descartes/Paris V, Sorbonne Paris Cité, Paris, France;Université Pierre et Marie Curie/Paris VI, Paris, France;Pôle de Biologie, Hôpital Européen Georges Pompidou, AP-HP, Paris, France;Department of Women’s and Children’s Health, Karolinska University Hospital, Stockholm, SwedenCorrespondence[email protected] [email protected]
ORCID Iconhttps://orcid.org/0000-0002-9334-4405View further author information
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Article: e1591878 | Received 28 Feb 2019, Accepted 05 Mar 2019, Published online: 03 Apr 2019

ABSTRACT

Dietary interventions have a profound impact on whole body metabolism, including oncometabolism (the metabolic features allowing cancer cells to proliferate) and immunometabolism (the catabolic and anabolic reactions that regulate immune responses). Recent preclinical studies demonstrated that multiple dietary changes can improve anticancer immunosurveillance of chemo-, radio- and immunotherapy. These findings have fostered the design of clinical trials evaluating the capacity of dietary interventions to synergize with treatment and hence limit tumor progression. Here, we discuss the scientific rationale for harnessing dietary interventions to improve the efficacy of anticancer therapy and present up-to-date information on clinical trials currently investigating this possibility.

Introduction

In the Western world, overnutrition has overcome undernutrition as a medical and societal problem.Citation1Citation3 Beyond quantitative considerations, it appears that the consumption of ultra-processed food (rich in carbohydrates, sugars, salt, and fat) and soft drinks coupled to a relative scarcity of fruit and vegetables affects the majority of individuals even in high-income countries.Citation4Citation9 Against this background, it is clear that the “normal diet” cannot be appreciated as a statistical norm (i.e., the diet of the average individual), but must be defined by public guidelines. Such guidelines, however, are overshadowed by political decisions and arguable observational epidemiology, meaning that they tend to differ among distinct countries.Citation10 Moreover, much of the preclinical research done with laboratory animals (mostly mice) is based on the comparison of different types of chemically non-defined regimens, meaning that the conclusions of such studies are often based on methodologically suboptimal approaches.Citation11,Citation12 Indeed, in pharmacology, it is common practice to compare different experimental conditions that only differ with respect to the absence and the presence of a drug administered at different concentrations. This kind of rigor is absent from most nutritional studies, which ideally should be designed to test the effects of just one single macro- or micronutrient admixed as a chemically defined entity (e.g., sucrose, sodium chloride, cholesterol or specific vitamins).Citation13 Notwithstanding these limitations, it has become clear that the quantity and quality of nutrition plays a major role in determining the risk of cancer.Citation14Citation16 Obesity is nowadays on the verge of beating tobacco as the principal avoidable risk factor for cancer.Citation17Citation19 Along similar lines, a high variety of food that supplies all necessary micronutrients appears to be one of the principal factors that link high socioeconomic status with low disease risk.Citation20 Finally, multiple animal studies favor the idea that nutritional interventions may curb the progression of established cancers and improve the efficacy of anticancer treatments.Citation21Citation27 These effects rely on the alteration of both oncometabolism (the anabolic and catabolic reactions that support oncogenesis, disease progression and resistance to treatment)Citation28,Citation29 and immunometabolism (the metabolic features that regulate immune responses).Citation30Citation34

Along the lines of our Trial Watch series,Citation35,Citation36 we discuss the rationale for harnessing nutritional interventions in support of cancer therapy and the progress of recent clinical trials testing this therapeutic paradigm in cancer patients.

Anticancer effects of dietary interventions – a cell-autonomous rationale

Cancer cells, especially those studied in the laboratory, are characterized by an increase in anabolic reactions that give rise to the so-called Warburg effect, the fact that such cells tend to take up large amounts of glucose even in conditions in which oxidative phosphorylation can proceed in an unlimited fashion.Citation37Citation40 This so-called ‘aerobic glycolysis’ allows glucose-derived carbon atoms to be used for biosynthetic reactions. Cancer cells also take up large amounts of amino acids through specific transporters in the plasma membrane, acquire increased amounts of proteins by pinocytosis, and even engulf their neighbors to cannibalize them.Citation41Citation43 In an analogous fashion, cancer cells are avid consumers of lipids.Citation44 Given their anabolic appetite, it is not surprising that nutritional interventions designed to reduce tumor growth involve a reduction in macronutrient uptake. Thus, it has been shown in mice that short-term starvation (STS, meaning no food supply for 1–2 days with access to drinking water ad libitum) and alternate-day fasting (ADF, meaning the alternation of 1-day intervals with and without access to food) can reduce tumor progression.Citation25,Citation27 Moreover, the specific depletion of proteins (as well as selected aminoacids) from nutrients can be harnessed to limit cancer growth.Citation45,Citation46 One particular dietary intervention consists in a close-to-zero carbohydrate, low-protein, high-fat regimen that causes ketosis (i.e., the accumulation of 3-hydroxybutyrate, acetoacetate, and acetone, commonly known as ketone bodies).Citation47 Ketone bodies can be used by multiple tissues in replacement of glucose for energy metabolism.Citation48 In mice, multiple variants of ketogenic diet slowdown the progression of some cancer types and boost the efficacy of targeted therapeutic agents,Citation49,Citation50 an effect that (at least in some setting) is linked to reduced insulin signaling.Citation50,Citation51

One particular facet of these dietary interventions is their capacity to reduce the unwarranted side effect of genotoxic chemotherapy. For example, periodic fasting as well as the administration of a hypocaloric ‘fasting-mimicking diet’ (FMD) can enhance the efficacy of chemotherapy and, at the same time, limit chemotherapy-related weight loss and cardiotoxicity.Citation27,Citation52 It has been theorized that transient calorie deprivation enhances the ‘differential stress resistance’ between chemotherapy-treated cancer cells (that would become more susceptible to the treatment) and normal, non-neoplastic cells (that would become more resistant to the toxic side effects to chemotherapy).Citation53Citation56

Anticancer effects of dietary interventions – an immunological rationale

Over the past years, an ever-expanding body of evidence pleads in favor of the notion that the long-term success of chemotherapy, targeted therapy and radiotherapy requires the reestablishment of immunosurveillance.Citation57 In other words, the efficacy of antineoplastic treatments, which has long been thought to exclusively rely on cancer cell-autonomous effects, now turns out to require the induction of a protracted anticancer immune response to be efficient.Citation58Citation61 Logically, the impact of dietary intervention on such immune-dependent antitumor effects has been studied in preclinical models.

In immunocompetent mice bearing transplantable tumors or carcinogen-induced breast cancer, chemotherapy with anthracyclines or oxaliplatin becomes more efficient if combined with shorts periods of starvation.Citation22,Citation24 These combinatorial effects of chemotherapy and dietary intervention fully rely on a T lymphocyte-mediated anticancer immune response, meaning that they are lost upon T cell depletion.Citation22,Citation24 Mechanistically, they have been linked to the induction of heme oxygenase-1 (HO-1) in cancer cells, the stimulation of autophagy in cancer cells (which would enhance their immunogenicity),Citation62Citation64 a decrease in circulating insulin-like growth factor-1 (IGF1), as well as an increase in the frequency of common lymphocyte precursors (which would be immunostimulatory).Citation22,Citation24,Citation65 Whether such effects might involve major shifts in the gut microbiota has not been investigated thus far.Citation66,Citation67 Moreover, the impact of dietary interventions on immunotherapies has been poorly explored, at least to our knowledge.Citation68,Citation69 Available clinical evidence suggests that anti-melanoma immunotherapy with PD-1/PD-L1 blocking antibodiesCitation70,Citation71 is more efficient in obese than lean males,Citation72 casting doubts on the possibility to improve such therapies by brutal interventions designed to reduce overweight.

Published and ongoing clinical trials

Very few trials testing the ability of nutritional interventions to boost the efficacy of cancer therapy have been reported in the peer-reviewed literature so far. A series of anecdotal cases of self-imposed starvation during chemotherapy suggested an improvement of subjective well-being suggestive of a reduction of side-effects.Citation73 In the same line, fasting for 48 h prior and 24 h after platinum-based chemotherapy proved its safety and feasibility in patients treated for diverse cancer types.Citation74 A Phase I trial confirmed that STS for 60 h (from 36 h prior to chemotherapy to 24 h post-chemotherapy) improves quality of life and fatigue in patients with gynecological cancer.Citation75 In breast cancer patients treated with neoadjuvant multimodal chemotherapy,Citation76 a 48-h starvation period (from 24 h before to 24 h after chemotherapy) reduced hematological toxicity and accelerated recovery from DNA damage in circulating leukocytes.Citation77 Women with ovarian and endometrial cancer following a ketogenic diet for 12 weeks reported higher physical and energy status compared to the control group, highlighting the feasibility of this regimen.Citation78 A special ketogenic diet, the so-called ‘modified Atkins diet’, reportedly reduces the progression of some advanced cancer patients, especially individuals experience robust weight reduction.Citation79 Similarly, a ketogenic regimen has been reported to induce objective responses in 6 out of 7 patients with recurrent glioblastoma that simultaneously were treated with the antiangiogenic drug bevacizumab.Citation80Citation82 This effect appeared particularly strong in patients with stable ketosis.Citation80

The website ClinicalTrials.gov informs on multiple clinical trials that are either ongoing or completed, yet generally lack published information on the outcome (). Many of these trials evaluate dietary interventions without further treatment (NCT01092247, NCT01865162, NCT02092753, NCT02286167, NCT03160599, NCT03194516, NCT03328858, NCT03785808, NCT00003367, NCT00020995, NCT00082732, NCT00444054, NCT01692587, NCT02129218, NCT02176902, NCT03221920, and NCT03679260). Such interventions include STS, intermediate fasting, FMD, multiple ketogenic and low-carbohydrate diets, low-fat/high-fiber regimens, protein-restrictive diets, low-calorie and low-glycemic regimens and a vegan diet in patients with a variety of advanced solid malignancies including glioblastoma (the most frequent indication), breast and gynecological cancer, melanoma, head and neck cancer, non-small cell lung carcinoma, ovarian cancer, pancreatic adenocarcinoma, and prostate cancer. Several trials also aim at investigating the combination of dietary interventions with (1) chemotherapy (NCT01175837, NCT02379585, NCT02126449, NCT02710721, NCT03162289, NCT03340935, NCT03595540, NCT03700437, NCT01419483, NCT01419587, NCT01975766, NCT02046187, NCT02302235, NCT02516501, NCT02939378, NCT02983942, NCT03075514, NCT03278249, NCT03451799, NCT03535701, NCT01802346, NCT02019979, and NCT02437474), (2) radiotherapy (NCT03340935, NCT01419483, NCT01419587, NCT01754350, NCT01975766, NCT02046187, NCT02302235, NCT02516501, NCT03075514, NCT03278249, NCT03451799, NCT01170299, and NCT02437474), (3) metformin, a medication for type II diabetes with pleiotropic effects on cancer cellsCitation83Citation85 (NCT03709147 and NCT02019979), (4) targeted-therapies (NCT02379585, NCT03595540 and NCT02768389), and (5) immunotherapies such as immune checkpoint blockers targeting PD-1Citation86,Citation87 (NCT03595540 and NCT03700437) or the dendritic cells based-vaccine Sipuleucel-TCitation88,Citation89 (NCT03329742). Interestingly, one study also sets to monitor anticancer immune responses induced by an FMD (NCT03454282).

Table 1. Clinical trials employing diet for cancer therapy.

It will be interesting to see whether any of these studies will document a clinical benefit linked to a specific nutritional intervention.

Concluding remarks

Knowing the importance of nutrition and metabolism for human physiology, including the crosstalk between malignant and immune cells, it is not surprising that dietary interventions are attracting attention as safe means to limit tumor progression or restore disease control by the host immune system.Citation90Citation92 While evidence from preclinical studies suggests that reducing total calorie intake (and perhaps specific macronutrients) may stimulate anticancer immunity, such evidence has not yet been obtained in clinical trials. Multiple trials testing these possibilities in patients with multiple types of cancer are on the way (). Unfortunately, it will be difficult to compare results from different studies for at least two reasons that add upon the usual heterogeneity of clinical trials. First, dietary interventions are quite heterogeneous in nature.Citation13 Thus, the term ‘ketogenic diet’ may refer to distinct regimens differing in quantity, composition and even in the gross protein:fat ratio.Citation93 Second, the control arms of the studies, when exist, usually receive consulting on ‘healthy dietary habits’, which (1) is a non-standardized notion (with major cross-continental and cross-cultural divergences), (2) is usually not enforced, and (3) is extremely complex to monitor.

Thus, the studies listed in might examine the differences between salutary (interventional) and poor (control) regimens, meaning that control regimens can be expected to have a negative impact on health status. For this reason, it will be important to standardize control diets, ensure compliance, and to define interventional regimens in an accurate fashion. This implies strict guidelines, their enforcement by connected objects and phone app-mediated control, as well as monitoring of multiple metabolic parameters (such as plasma metabolome, cytokine and hormone status, stool microbiota). Moreover, it will be important to monitor immune parameters in the tumor and the peripheral blood to gain insights into therapeutically relevant anticancer immune responses. Without this information, it will be difficult to obtain any useful knowledge on the impact of nutritional interventions on cancer therapy.

Disclosure of Potential Conflicts of Interest

LG provides remunerated consulting to OmniSEQ (Buffalo, NY, USA), Astra Zeneca (Gaithersburg, MD, USA), VL47 (New York, NY, USA) and the Luke Heller TECPR2 Foundation (Boston, MA, USA), and he is member of the Scientific Advisory Committee of OmniSEQ (Buffalo, NY, USA). GK and LZ receive a research grant by Elior.

Acknowledgments

SL is supported by an end of PhD grant from the Fondation pour la Recherche Médicale (FRM FDT201805005722). LG is supported by a Breakthrough Level 2 grant from the US Department of Defense (DoD), Breast Cancer Research Program (BRCP) [#BC180476P1], by a startup grant from the Dept. of Radiation Oncology at Weill Cornell Medicine (New York, US), by industrial collaborations with Lytix (Oslo, Norway) and Phosplatin (New York, US), and by donations from Phosplatin (New York, US), the Luke Heller TECPR2 Foundation (Boston, US) and Sotio a.s. (Prague, Czech Republic). GK is supported by the Ligue contre le Cancer (équipe labellisée); Agence National de la Recherche (ANR) – Projets blancs; ANR under the frame of E-Rare-2, the ERA-Net for Research on Rare Diseases; Association pour la recherche sur le cancer; Cancéropôle Ile-de-France; Chancelerie des universités de Paris (Legs Poix), Fondation pour la Recherche Médicale (FRM); a donation by Elior; European Research Area Network on Cardiovascular Diseases (ERA-CVD, MINOTAUR); the European Union Horizon 2020 Project Oncobiome; Fondation Carrefour; Institut National du Cancer (INCa); Inserm (HTE); Institut Universitaire de France; LeDucq Foundation; the LabEx Immuno-Oncology; the RHU Torino Lumière; the Seerave Foundation; the SIRIC Stratified Oncology Cell DNA Repair and Tumor Immune Elimination (SOCRATE); and the SIRIC Cancer Research and Personalized Medicine (CARPEM).

Additional information

Funding

This work was supported by the Agence Nationale de la Recherche [E-Rare-2]; Fondation pour la Recherche Médicale [FRM FDT201805005722]; H2020 European Union [Oncobiome].

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