Although it is frequently assumed that the hypothesis that nutrition could be a cause of cancer started to be considered around the 1940s, evidence indicates that professional interest in the diet, nutrition and cancer association can be traced back to the 1800s.⁵ A landmark publication in the field was the article by Doll and Peto from 1981, where they estimated that 35% of cancer was attributed to diet.⁶ Although some⁷ have reviewed this original estimate and proposed lower figures (i.e., 20%), Doll and Peto’s findings were key to increase awareness of the influence of nutritional factors on cancer development. Since then, intense research has been conducted at the epidemiological, clinical and experimental levels.^8,9 Accumulated data indicate that diet and nutrition and cancer association is very complex and several aspects are yet not clear. For example, it has been pointed out that the estimation of dietary influence on cancer risk should further take into account early life nutrition, as developmental stages such as in utero life, early childhood and puberty may represent particularly vulnerable periods for cancer development in adulthood.¹⁰ According to the World Health Organization,³ 30–50% of all cancers are preventable through reduction of exposure to risk factors (tobacco, environmental pollution, occupational carcinogens, infections and alcohol) and adoption of healthy lifestyles (physical exercise, healthy diet and weight).

In addition to the timing of food consumption, other factors that further complicate the elucidation of nutritional modulation of carcinogenesis include the great diversity of dietary components (i.e., more than 5 000 flavonoids have been identified in fruits and vegetables), the concentrations of which in foodstuffs can vary according to farming, harvesting, transporting and cooking conditions.^11,12 Furthermore, for those nutritional factors associated with decreased (fruits and vegetables, vitamin D, folic acid, selenium, zinc, polyphenols and carotenoids, among others) or increased (red and processed meat, alcohol, saturated fatty acids and obesity, among others) cancer risk, the exact underlying cellular and molecular mechanisms are still not clear.^13–22 More recently, nutrient–gene interactions (nutritional genomics), including epigenetics,^23–25 stem cells as cellular targets^26,27 and the intestinal microbiota,^28,29 have emerged as key factors that should be considered in order to better understand diet, nutrition and cancer and thus establish nutritional recommendations for cancer prevention.

Ingestion of fruits and vegetables is associated with cancer prevention.^30–32 These protective effects have been ascribed to the presence of several bioactive compounds.^33,34 In Chapter 2, the role of bioactive food compounds in cancer prevention is covered. These natural substances are widely distributed in plant-based foods such as fruits, vegetables, whole grains and beans. They originate from the secondary metabolism of plants, belong to different classes, such as polyphenols, terpenoids, allyl compounds and isothiocyanates, among others, and exert different cancer preventive effects. The molecular mechanisms underlying their protective effects are discussed and include modulation of phase I and II carcinogen metabolizing enzymes, regulation of gene expression through activation of nuclear receptors, interference with cell signaling pathways and modulation of epigenetic processes such as DNA methylation and histone post-translational modifications. Such complex mechanisms of action by bioactive food components could be associated with the cancer prevention effects of whole grains, fruits, vegetables and beans. Major limitations concerning establishing recommended levels of intake of these compounds are discussed and include limited information on their levels in foods and their bioavailability, which is influenced by individual genetic backgrounds and intestinal microbiota.

Among different micronutrients with cancer prevention potential, vitamin D can be highlighted.^35,36 Chapter 3 covers the role of vitamin D in obesity, an established risk factor for cancer, and in cancer prevention itself. An overview of the nutritional/physiological roles of vitamin D is provided with emphasis on its metabolism. Evidence of the cancer preventive potential of vitamin D based on epidemiological and intervention studies is then discussed. Inhibition of cell proliferation, induction of apoptosis and cell differentiation, and inhibition of angiogenesis, migration and invasion of tumor cells have been indicated as potential vitamin D anticancer actions. The impact of different polymorphisms in the vitamin D receptor (VDR) gene on cancer risk is then discussed. This gene codes for the nuclear receptor that mediates the genomic actions of vitamin D. Alterations in VDR expression or conformation could impair the cancer preventive actions of vitamin D. In addition, the actions of vitamin D at the epigenetic level are presented.

Selenium represents one of the most studied nutrients with cancer prevention potential.^37,38 This aspect of selenium’s beneficial effects is covered in Chapter 4. Selenium is found in both organic and inorganic forms, which present different bioavailability and metabolic pathways. These aspects are first discussed. Nutritional recommendations, food sources and biomarkers of selenium status are then covered. Epidemiological evidence linking selenium and cancer prevention is also provided and conflicting results between outcomes from the two main randomized clinical trials – the Nutritional Prevention of Cancer and the Selenium and Vitamin E Cancer Prevention trials – are discussed. The different outcomes from these clinical trials could be related to differences in genetic background. Thus, polymorphisms in key genes involved in selenium’s cancer prevention actions, such as those coding different antioxidant glutathione peroxidases, are suggested to increase the risk of different cancers, including breast, prostate and colorectal cancers. Furthermore, the proposed mechanisms underlying selenium’s cancer preventive actions are discussed, including those at the epigenetic level.

Zinc represents another micronutrient with cancer prevention activity³⁹ and this is discussed in Chapter 5. The nutritional importance of zinc is first discussed. It is an essential micronutrient that exerts key biological functions at the structural, catalytic and regulatory levels, modulating oxidative stress response, genomic stability, immunological function, DNA repair, cell proliferation and apoptosis, all of which are deregulated during carcinogenesis. Thus, disturbances in zinc homeostasis could increase the risk of cancer development. The impact of zin...