Hostname: page-component-78c5997874-94fs2 Total loading time: 0 Render date: 2024-11-13T02:57:07.337Z Has data issue: false hasContentIssue false

Towards the characterisation of sustainable diet’s gut microbiota composition and functions: A narrative review

Published online by Cambridge University Press:  11 September 2023

Mariana Lares-Michel*
Affiliation:
Institute of Nutrition and Food Technology “José Mataix Verdú”, Biomedical Research Center, University of Granada, Avenida del Conocimiento S/N, Parque Tecnológico de la Salud, Armilla, 18071 Granada, Spain Instituto de Investigaciones en Comportamiento Alimentario y Nutrición (IICAN), Centro Universitario del Sur, Universidad de Guadalajara, Av. Enrique Arreola Silva 883, Col. Centro. 49000, Cd. Guzmán, Jalisco, México
Zyanya Reyes-Castillo
Affiliation:
Instituto de Investigaciones en Comportamiento Alimentario y Nutrición (IICAN), Centro Universitario del Sur, Universidad de Guadalajara, Av. Enrique Arreola Silva 883, Col. Centro. 49000, Cd. Guzmán, Jalisco, México
Fatima Ezzahra Housni
Affiliation:
Instituto de Investigaciones en Comportamiento Alimentario y Nutrición (IICAN), Centro Universitario del Sur, Universidad de Guadalajara, Av. Enrique Arreola Silva 883, Col. Centro. 49000, Cd. Guzmán, Jalisco, México
*
Corresponding author: Mariana Lares-Michel; Email: marianalares@correo.ugr.es

Abstract

The gut microbiome is a key element for health preservation and disease prevention. Nevertheless, defining a healthy gut microbiome is complex since it is modulated by several factors, such as host genetics, sex, age, geographical zone, drug use, and, especially, diet. Although a healthy diet has proven to increase microbial alpha and beta diversity and to promote the proliferation of health-related bacteria, considering the current environmental and nutritional crisis, such as climate change, water shortage, loss of diversity, and the obesity pandemic, it should be highlighted that a healthy diet is not always sustainable. Sustainable diets are dietary patterns that promote all dimensions of people’s health and well-being while exerting low pressure on the environment, and being accessible, affordable, safe, equitable, and culturally acceptable. Examples of diets that tend to be sustainable are the Planetary Health Diet of the EAT-Lancet Commission or territorial diets such as the Mediterranean and the Traditional Mexican diet (milpa diet), adapted to specific contexts. These diets are principally plant-based but include small or moderate amounts of animal-based foods. Characterising the effects of sustainable diets on gut microbiota is urgent to ensure that the benefits for human health are aligned with environmental preservation and respect the sociocultural aspects of individuals.

Type
Review
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press in association with The Nutrition Society

Introduction

Currently, we know the gut microbiome is one of the most critical determinants of health and its alterations are associated with the development of chronic degenerative diseases (Vijay and Valdes, Reference Vijay and Valdes2022). It also regulates several immunological, metabolic, physiological, and structural functions and even has a role in behaviour (Johnson and Foster, Reference Johnson and Foster2018; Vijay and Valdes, Reference Vijay and Valdes2022). The gut microbiome is modulated by several factors, such as genetics, sex, age, geographical zone, drug use, and, especially, diet. The understanding of the role of diet in the composition and functions of gut microbiota has increased significantly in the past decade (Rinninella et al., Reference Rinninella, Tohumcu, Raoul, Fiorani, Cintoni, Mele, Cammarota, Gasbarrini and Ianiro2023). Growing research indicates that a healthy diet could be the key element of a “healthy” gut microbiome, which is composed of bacteria generally associated with metabolic health and with little or no pathogenic bacteria. However, it is essential to mention that a healthy gut microbiome can vary significantly across hosts since each human can respond differently to the same nutrients, and the same bacteria can have different effects on each individual (Rinninella et al., Reference Rinninella, Tohumcu, Raoul, Fiorani, Cintoni, Mele, Cammarota, Gasbarrini and Ianiro2023; Shanahan et al., Reference Shanahan, Ghosh and O’Toole2021). Besides, the gut microbiome can be a fingerprinting of each individual or even of specific disease-related bacteria (Tierney et al., Reference Tierney, Yang, Luber, Beaudin, Wibowo, Baek, Mehlenbacher, Patel and Kostic2019).

Although some aspects of gut microbiota are consistent through literature, such as the fact that plant-based and high-fibre diets are related to bacteria such as Faecalibacterium prausnitzii, which is associated with anti-inflammatory effects (Sidhu et al., Reference Sidhu, Kok, Kunasegaran and Ramadas2023; Trefflich et al., Reference Trefflich, Jabakhanji, Menzel, Blaut, Michalsen, Lampen, Abraham and Weikert2020), whereas Western diets based on ultra-processed foods are related to dysbiosis (Rinninella et al., Reference Rinninella, Cintoni, Raoul, Lopetuso, Scaldaferri, Pulcini, Miggiano, Gasbarrini and Mele2019), these trends in research have spread and reinforced the idea that a healthy diet could be the key to having a gut microbiome as healthy as possible. However, when addressing diets in the context of the current environmental crisis it is essential to remember that their impact is not limited to human health, but also their production has critical environmental impacts. In this sense, recent research has evidenced that a healthy diet is not necessarily sustainable (Birney et al., Reference Birney, Franklin, Davidson and Webber2017; Macdiarmid, Reference Macdiarmid2013).

The sustainable diets concept is complex and integrates four essential dimensions: (1) health and nutrition, (2) environment, (3) economy, and (4) culture and society (Auestad and Fulgoni, Reference Auestad and Fulgoni2015). The most up-to-date definition of sustainable diets was provided by the Food and Agriculture Organization of the United Nations and World Health Organization (2019), which defines it as “dietary patterns that promote all the dimensions of people’s health and well-being; they have low pressure and environmental impact; they are accessible, affordable, safe and equitable; and are culturally acceptable” (p. 9).

Some of the main characteristics of sustainable diets are that they are locally produced, with little or no processing, and mainly of vegetable origin. However, as the concept itself indicates, multiple factors are directly and indirectly related, for example, the characteristics of where the diet is produced. In the sustainability context, biodiversity is essential to produce dense nutrient foods, and some regions are more productive than others. Several aspects are implicated in soil fertility, among which soil microbial diversity is essential. In this regard, McCarthy and Li (Reference McCarthy and Li2019) were the first authors to point out the importance that some promoters of sustainable diets, such as the EAT-Lancet Commission, start considering not only preserving species diversity in the earth’s biosphere but also promoting diversity of microbial species in the human gut. In this sense, although the characterisation of the gut microbiota in relation to plant-based diets, such as vegan, vegetarian, and Mediterranean, is currently a field of intense research, the specific effects that specific sustainable diets, locally produced, have on specific human populations have not been reported. Therefore, this review explores the literature regarding potential sustainable diets’ effects on gut microbiota composition and functions.

Healthy diet’s composition and its effects on the gut microbiota … are they sustainable?

A sustainable diet is a relatively new concept that aims to integrate health and nutrition with the environment and socio-economical aspects of the population to preserve the planet (Food and Agriculture Organization of the United Nations and World Health Organization, 2019). Although sustainable diets must be contextualised to be considered sustainable, in the current literature it is common to assume healthy diets as sustainable (Sidhu et al., Reference Sidhu, Kok, Kunasegaran and Ramadas2023). A healthy diet is defined as a health-promoting and disease-preventing diet. It provides adequacy, without excess, of nutrients and health-promoting substances from nutritious foods and avoids the consumption of health-harming substances (Neufeld et al., Reference Neufeld, Hendriks and Hugas2021).

Healthy diets are generally assumed as sustainable, and although in some cases it is true, this cannot be generalised (Lares-Michel et al., Reference Lares-Michel, Housni, Aguilera Cervantes, Carrillo, Michel Nava and Cañedo2021). Indeed, some studies have found that shifting current dietary patterns to dietary guideline recommendations would increase dietary environmental impact in several ways; for example, an increase of 15% in blue water footprint, 34% in energy use, 7% in dietary greenhouse gas emissions, and 34% in fertiliser use (Birney et al., Reference Birney, Franklin, Davidson and Webber2017).

Dietary guidelines are consistent worldwide, recommending a high consumption of vegetables, fruits, and whole grains, which must constitute half of a person’s daily diet. Besides, all dietary guidelines agree on moderating and/or avoiding refined grains, sugar, saturated fats, and ultra-processed foods (Armet et al., Reference Armet, Deehan, O’Sullivan, Mota, Field, Prado, Lucey and Walter2022). Regarding animal-based foods, recommendations vary a little more. Generally, all dietary guidelines promote moderation in meat, dairy, and egg consumption (Armet et al., Reference Armet, Deehan, O’Sullivan, Mota, Field, Prado, Lucey and Walter2022). Recently, some guidelines recommend substituting meats for legumes, nuts, and seeds (Cena and Calder, Reference Cena and Calder2020; Food and Agriculture Organization of the United Nations, 2023). However, country-specific dietary guidelines have not distinguished recommendations regarding critical elements in healthy sustainable diets, for example, the environmental impact of specific foods, especially meats (i.e., beef, pork, chicken, goat, and fish) (Cena and Calder, Reference Cena and Calder2020; Food and Agriculture Organization of the United Nations, 2023). Most dietary guidelines group red meat, poultry, fish, processed meats, and even legumes (Macedo-Ojeda et al., Reference Macedo-Ojeda, Márquez-Sandoval, Fernández-Ballart and Vizmanos2016). Besides having completely different environmental impacts, their effects on the gut microbiota and their related metabolites vary greatly (Lonnie et al., Reference Lonnie, Hooker, Brunstrom, Corfe, Green, Watson, Williams, Stevenson, Penson and Johnstone2018; Świątecka et al., Reference Świątecka, Narbad, Ridgway and Kostyra2011).

From an environmental sustainability perspective, beef’s international average water footprint is 15,415 litres per kilogram (L/kg) (Mekonnen and Hoekstra, Reference Mekonnen and Hoekstra2010); meanwhile, this figure can rise to more than 21,000 L/kg in water-scarce regions such as Mexico (Hoekstra et al., Reference Hoekstra, Chapagain, Aldaya and Mekonnen2012). Other meats, such as chicken, can have considerably lower impacts. For example, its water footprint is 4,325 L/kg, and pork has a water footprint of 5,988 L/kg. Similarly, greenhouse gas emissions vary greatly among meat types. Beef, for example, reaches more than 34 CO2eq/kg, while the carbon footprint of chicken is 8.58 CO2eq/kg and of fish is 11.62 CO2eq/kg (López-Olmedo et al., Reference López-Olmedo, Stern, Bakhtsiyarava, Pérez-Ferrer and Langellier2022). Besides, most dietary guidelines widely recommend the intake of nuts as a protein and/or healthy fats source (Armet et al., Reference Armet, Deehan, O’Sullivan, Mota, Field, Prado, Lucey and Walter2022). However, from an environmental perspective, its impact is even higher than most meats, with a water footprint of 9,063 L/kg (Mekonnen and Hoekstra, Reference Mekonnen and Hoekstra2012). The same occurs with olive oil, which has a water footprint of 14,431 L/kg (Mekonnen and Hoekstra, Reference Mekonnen and Hoekstra2010). Nevertheless, its carbon footprint is lower (3.10 CO2eq/kg) (Grasso et al., Reference Grasso, Olthof, van Dooren, Roca, Gili, Visser, Cabout, Bot, Penninx, van Grootheest, Kohls, Hegerl, Owens, Watkins, Brouwer and Investigators2020), and it should be considered that healthy fats can be included in a healthy sustainable diet in adequate portions, since a tablespoon of olive oil has only a water footprint of 216 litres. Meanwhile, servings of beef tend to be higher, for example, over 100 g, which would have a water footprint of 1,541 litres (Mekonnen and Hoekstra, Reference Mekonnen and Hoekstra2010). This highlights the importance of intake of recommended consumption amounts in current dietary guidelines.

Regarding gut microbiome, it is interesting that the variations found in environmental sustainability tend to align with the type of bacteria associated with each food group and specific metabolites. For example, the foods with lower environmental impact, which are vegetables, fruits, whole grains, and legumes (Willett et al., Reference Willett, Rockström, Loken, Springmann, Lang, Vermeulen, Garnett, Tilman, DeClerck, Wood, Jonell, Clark, Gordon, Fanzo, Hawkes, Zurayk, Rivera, Vries, Sibanda and Murray2019), are the leading food groups associated with anti-inflammatory bacteria such as F. prausnitzii, Prevotella copri, and Akkermansia muciniphila (Avila-Nava et al., Reference Avila-Nava, Noriega, Tovar, Granados, Perez-Cruz, Pedraza-Chaverri and Torres2017; Sidhu et al., Reference Sidhu, Kok, Kunasegaran and Ramadas2023; Trefflich et al., Reference Trefflich, Jabakhanji, Menzel, Blaut, Michalsen, Lampen, Abraham and Weikert2020). However, this is not a rule since although nuts and olive oil have proved to increase the proliferation of metabolic health-associated bacteria, such as Bifidobacterium spp., and reduce pro-inflammatory bacteria, such as Pseudomonadota (previously called Proteobacteria) (Marcelino et al., Reference Marcelino, Hiane, de Cássia Freitas, Santana, Pott, Donadon and de Cássia Avellaneda Guimarães2019), their impact on water use generates controversy about the amounts recommended in current healthy dietary guidelines (Blas et al., Reference Blas, Garrido and Willaarts2016).

The same occurs with avocado, which has been widely recognised as essential to maintaining a diverse gut microbiome (increasing alpha diversity) and enriching bacteria such as Faecalibacterium, Lachnospira, and Alistipes. Besides, avocado consumption, in quantities from 175 g in men to 140 g in women, also modifies the human microbial metabolites (Thompson et al., Reference Thompson, Bailey, Taylor, Kaczmarek, Mysonhimer, Edwards, Reeser, Burd, Khan and Holscher2021). A randomised controlled trial (RCT) found increases in faecal acetate, stearic acid, and palmitic acid concentrations. In contrast, the concentrations of the bile acids, cholic and chenodeoxycholic acid, were 91% and 57% lower in persons consuming avocado compared to a control group. Also, its consumption favours greater fecal short-chain fatty acids (SCFAs) concentrations (Thompson et al., Reference Thompson, Bailey, Taylor, Kaczmarek, Mysonhimer, Edwards, Reeser, Burd, Khan and Holscher2021).

Nevertheless, avocados’ production leads to critical environmental impacts (De la Vega-Rivera and Merino-Pérez, Reference De la Vega-Rivera and Merino-Pérez2021). Although the avocado crop itself has a relatively low environmental impact, with around 900 L/kg of water footprint (Mekonnen and Hoekstra, Reference Mekonnen and Hoekstra2010) and 1.34 CO2eq/kg (López-Olmedo et al., Reference López-Olmedo, Stern, Bakhtsiyarava, Pérez-Ferrer and Langellier2022), the agribusiness dedicated to massive exports in countries like Mexico has brought severe environmental consequences (De la Vega-Rivera and Merino-Pérez, Reference De la Vega-Rivera and Merino-Pérez2021; Macias, Reference Macias2015).

Another food group that worries sustainability experts is dairy. Dairy is included in most dietary guidelines (Armet et al., Reference Armet, Deehan, O’Sullivan, Mota, Field, Prado, Lucey and Walter2022) since these are dense nutrient foods that also benefits the gut microbiota by increasing beneficial genera Lactobacillus and Bifidobacterium, and reducing pathogenic bacteria such as Bacteroides fragilis (Aslam et al., Reference Aslam, Marx, Rocks, Loughman, Chandrasekaran, Ruusunen, Dawson, West, Mullarkey, Pasco and Jacka2020). However, its role in sustainability remains controversial since it is considered one of the food groups with the highest environmental impact (Mekonnen and Hoekstra, Reference Mekonnen and Hoekstra2012; van Hooijdonk and Hettinga, Reference van Hooijdonk and Hettinga2015). Nevertheless, the caloric and fat intake rise significantly when substituting dairy for plant-based foods to obtain nutrients such as calcium (i.e., by consuming almonds) (Rodríguez Huertas et al., Reference Rodríguez Huertas, Rodríguez Lara, González Acevedo, Mesa, Rodríguez Huertas, Rodríguez Lara, González Acevedo and Mesa2019). Besides, these changes would also lead to even higher environmental impacts since, although plant-based, some dairy substitutes such as almond drinks have a higher environmental impact, especially from a water use perspective (Carlsson Kanyama et al., Reference Carlsson Kanyama, Hedin and Katzeff2021).

Nowadays, other dietary patterns that can be considered healthy are high protein diets, which have gained attention in the last years, especially for losing weight (Moon and Koh, Reference Moon and Koh2020) or regulating metabolic diseases such as type 2 diabetes (Malaeb et al., Reference Malaeb, Bakker, Chow and Bantle2019). However, their effects are still inconclusive (Malaeb et al., Reference Malaeb, Bakker, Chow and Bantle2019). With regard to the gut microbiota, the effect of high protein diets has been widely studied, showing that high animal protein intake leads to higher Pseudomonadota such as Deferribacteres (Senghor et al., Reference Senghor, Sokhna, Ruimy and Lagier2018) and decreases Bifidobacteria (Rinninella et al., Reference Rinninella, Cintoni, Raoul, Lopetuso, Scaldaferri, Pulcini, Miggiano, Gasbarrini and Mele2019). Also, high animal protein consumption promotes higher proliferation of the pathobionts Bilophila and Lachnoclostridium (Wu et al., Reference Wu, Shen, Liao and Huang2022), as well as Bilophila wadsworthia, which is also related to pro-inflammatory effects and the development of chronic and gastrointestinal diseases (David et al., Reference David, Maurice, Carmody, Gootenberg, Button, Wolfe, Ling, Devlin, Varma, Fischbach, Biddinger, Dutton and Turnbaugh2014).

Besides the environmental impact, most dietary guidelines do not consider food costs (Food and Agriculture Organization of the United Nations, 2023). This has been repeatedly referred to as one of the main barriers to adopting a healthy diet, and, currently, a healthy and sustainable diet (Barosh et al., Reference Barosh, Friel, Engelhardt and Chan2014). This could also be directly linked to dysbiosis by preferring cheap food that tends to be fast foods or ultra-processed foods, which have been proven to alter the gut microbiota, generating dysbiosis (Aguayo-Patrón and de la Barca, Reference Aguayo-Patrón and de la Barca2017). Besides, a cross-sectional study found interesting alterations in the gut microbiota of women and men consuming ultra-processed foods. It was found that women consuming more than five servings per day of these foods had more bacteria such as Acidaminococcus, Butyrivibrio, Gemmiger, Shigella, Anaerofilum, Parabacteroides, Bifidobacterium, Enterobacteriales, Bifidobacteriales, and Actinomycetota (previously called Actinobacteria), and a decrease in Melainabacter and Lachnospira. Meanwhile, men who consumed the same amount of ultra-processed foods presented an increase of Granulicatella, Blautia, Carnobacteriaceae, Bacteroidaceae, Peptostreptococcaceae, Bacteroidia, and Bacteroidota, and a decrease of Anaerostipes and Clostridiaceae (Cuevas-Sierra et al., Reference Cuevas-Sierra, Milagro, Aranaz, Martínez and Riezu-Boj2021).

Finally, although each dietary guideline is country-specific, cultural and social elements are not always included, especially at the individual level (Food and Agriculture Organization of the United Nations, 2023). Among cultural aspects, cooking and region-specific recipes can play an essential role in the gut microbiome (Carmody et al., Reference Carmody, Bisanz, Bowen, Maurice, Lyalina, Louie, Treen, Chadaideh, Rekdal, Bess, Spanogiannopoulos, Ang, Bauer, Balon, Pollard, Northen and Turnbaugh2019). Heat alters the physicochemical properties of foods in ways that could impact the gut microbiome. Cooking increases the ileal digestibility of carbohydrates by gelatinising starch, reducing the quantity reaching the colon, where the most numerous microbial community resides, and potentially affecting the fermentation capability of amylolytic gut bacteria. Cooking can also denature antimicrobial compounds present naturally in food or introduced through agriculture, thus limiting their bioactivity (Carmody et al., Reference Carmody, Bisanz, Bowen, Maurice, Lyalina, Louie, Treen, Chadaideh, Rekdal, Bess, Spanogiannopoulos, Ang, Bauer, Balon, Pollard, Northen and Turnbaugh2019).

Specifically, a study showed that cooking methods and ingredients for cooking can alter gut microbiota composition. For example, it was shown that butter positively impacts the abundance of potentially advantageous taxa, including Faecalibacterium, Roseburia, and Blautia. However, butter and other high-fat animal foods, such as dairy products and fish, also resulted in higher abundances of Lachnoclostridium, which has been associated with several diseases. Frying was identified as the cooking method producing the most distinct effects on the microbiota when contrasted to other methods of cooking a particular food. This could be related to its high generation of Maillard reaction products. However, in general, the impact of cooking methods on the effects of foods was highly varied across individuals (Lerma-Aguilera et al., Reference Lerma-Aguilera, Pérez-Burillo, Navajas-Porras, León, Ruíz, Pastoriza, Jiménez-Hernández, Cämmerer, Rufián-Henares, Gosalbes and Francino2022). This confirms the importance of personalised and precision nutrition. Besides, behavioural elements of individuals must be considered in healthy diet promotion to be considered sustainable dietary patterns (Lares-Michel et al., Reference Lares-Michel, Housni, Reyes-Castillo, Huertas, Aguilera-Cervantes and Michel-Nava2023).

Plant-based diets

Animal-based foods have been widely recognised as having the highest environmental impact (Willett et al., Reference Willett, Rockström, Loken, Springmann, Lang, Vermeulen, Garnett, Tilman, DeClerck, Wood, Jonell, Clark, Gordon, Fanzo, Hawkes, Zurayk, Rivera, Vries, Sibanda and Murray2019). Among those, meats, especially beef, are considered the food with the highest impact from all environmental sustainability perspectives, being the main contributors to climate change because they have the highest greenhouse gas emissions and land and water use (Scarborough et al., Reference Scarborough, Appleby, Mizdrak, Briggs, Travis, Bradbury and Key2014; Willett et al., Reference Willett, Rockström, Loken, Springmann, Lang, Vermeulen, Garnett, Tilman, DeClerck, Wood, Jonell, Clark, Gordon, Fanzo, Hawkes, Zurayk, Rivera, Vries, Sibanda and Murray2019). For this reason, dietary patterns restringing animal foods, such as plant-based diets, are constantly considered sustainable (Carey et al., Reference Carey, Paquette, Sahye-Pudaruth, Dadvar, Dinh, Khodabandehlou, Liang, Mishra, Sidhu, Brown, Tandon, Wanyan, Bazinet, Hanley, Malik, Sievenpiper and Jenkins2023). According to a recent systematic review, plant-based diets generate lower greenhouse gas emissions (GHGEs), use less land, and limit biodiversity loss than standard diets. Nevertheless, the impact on water and energy use may depend on the types of plant-based foods consumed. However, the paper concludes that, in general, plant-based dietary patterns reduce diet-related mortality and also promote environmental sustainability (Carey et al., Reference Carey, Paquette, Sahye-Pudaruth, Dadvar, Dinh, Khodabandehlou, Liang, Mishra, Sidhu, Brown, Tandon, Wanyan, Bazinet, Hanley, Malik, Sievenpiper and Jenkins2023).

Some examples of plant-based diets are vegan, vegetarian, pescatarian, and flexitarian diets (Sidhu et al., Reference Sidhu, Kok, Kunasegaran and Ramadas2023). Vegan diets are plant-based and omit all animal products, even eggs, dairy products, and honey (Losno et al., Reference Losno, Sieferle, Perez-Cueto and Ritz2021; Melina et al., Reference Melina, Craig and Levin2016). A vegetarian diet is a plant-based diet that may or may not include egg or dairy products (Melina et al., Reference Melina, Craig and Levin2016). Pescatarians are defined as vegetarians who consume fish and seafood (Wozniak et al., Reference Wozniak, Larpin, de Mestral, Guessous, Reny and Stringhini2020). Finally, flexitarian or semi-vegetarian diets are a recent concept that refers to a plant-based dietary pattern with occasional beef, pork, poultry, or fish, perhaps once or twice weekly (Melina et al., Reference Melina, Craig and Levin2016).

Although, as said before, plant-based diets are generally aligned with environmental sustainability, health, nutrition, socioeconomic and cultural aspects are not always respected in this kind of diets. Besides, specific elements of these diets’ environmental impact are not always considered. Additionally, cultural and socioeconomic elements of plant-based diets are very controversial since they tend to be very distant from the traditional and regional diets of current populations, in addition to the fact that they do not usually align with the food preferences of the general population, besides being considered expensive diets for some specific socioeconomic strata (Drewnowski, Reference Drewnowski2020; Goulding et al., Reference Goulding, Lindberg and Russell2020). Despite this, plant-based diets’ effects on the gut microbiome have been called attention to in the last decade because those diets have a high content of microbiota-accessible carbohydrates (MACs) that are not digested and absorbed by the host, such as resistant starch, inulin, xylan, and pectin. These compounds favour the growth of specialised taxa like Ruminococcus bromii, Roseburia intestinalis, and, especially, F. prausnitzii, which is associated with anti-inflammatory effects (Shetty et al., Reference Shetty, Stege, Hordijk, Gijsbers, Dierikx, van Duijkeren, Franz, Willems, Paganelli and Fuentes2022; Sidhu et al., Reference Sidhu, Kok, Kunasegaran and Ramadas2023; Trefflich et al., Reference Trefflich, Jabakhanji, Menzel, Blaut, Michalsen, Lampen, Abraham and Weikert2020). Also, high-fibre diets rich in MACs are reported to benefit host physiology via enhanced butyrate production and promote higher bacterial diversity (Shetty et al., Reference Shetty, Stege, Hordijk, Gijsbers, Dierikx, van Duijkeren, Franz, Willems, Paganelli and Fuentes2022). According to Losno et al. (Reference Losno, Sieferle, Perez-Cueto and Ritz2021), the genus that is consistently reported as higher in vegans in contrast with omnivores is Prevotella. Specifically, P. copri has been reported to increase in vegans compared to omnivores (Trefflich et al., Reference Trefflich, Jabakhanji, Menzel, Blaut, Michalsen, Lampen, Abraham and Weikert2020).

Among plant-based diets, those that include some animal-based foods, such as pescatarians, have been shown to promote different gut microbiomes in the host, contrasting dietary patterns without animal foods. However, compared to the omnivore and vegetarian groups, a significantly higher Bacillota/Bacteroidota ratio (initially named as Firmicutes/Bacteroidetes ratio) has been reported in the pescatarian and vegan groups (Shetty et al., Reference Shetty, Stege, Hordijk, Gijsbers, Dierikx, van Duijkeren, Franz, Willems, Paganelli and Fuentes2022). This could indicate that some shared components in those diets, such as dairy and eggs in omnivores and vegetarians, could be the main determinants of gut microbiota distinctions. Meanwhile, shared high fruit and vegetable intake in vegans and pescatarians could modulate similar ratios between Bacillota (previously called Firmicutes) and Bacteroidota (previously called Bacteroidetes) (Shetty et al., Reference Shetty, Stege, Hordijk, Gijsbers, Dierikx, van Duijkeren, Franz, Willems, Paganelli and Fuentes2022). However, fish intake plays an inconclusive role on the gut microbiome because although its regular consumption lowers rates of ischemic heart disease than meat eaters, fish intake generates significant increases in plasma circulating levels of Trimethylamine-N-oxide (TMAO), which rise 15 min after a meal, reaching approximately 50 times higher circulating concentrations of TMAO than beef or egg consumption (Cho et al., Reference Cho, Taesuwan, Malysheva, Bender, Tulchinsky, Yan, Sutter and Caudill2017; Landberg and Hanhineva, Reference Landberg and Hanhineva2019).

From an environmental, economic, and social perspective, fish consumption is controversial since it can become an expensive source of protein and omega-3 fatty acids (Batis et al., Reference Batis, Gatica-Domínguez, Marrón-Ponce, Colchero, Rivera, Barquera and Stern2022) and is not linked with all traditional dietary patterns worldwide. For example, Mediterranean countries consume considerably more fish than other regions, such as India (Food and Agriculture Organization of the United Nations, 2020).

Territorial diets: Mediterranean and Nordic diets

Territorial diets (i.e., regionals) have stood out as sustainable dietary patterns among healthy diets. Among those, the Mediterranean diet is one of the most recognised worldwide as a healthy dietary pattern, and its beneficial effects on the gut microbiome are well-established (Bach-Faig et al., Reference Bach-Faig, Berry, Lairon, Reguant, Trichopoulou, Dernini, Medina, Battino, Belahsen, Miranda and Serra-Majem2011; Meslier et al., Reference Meslier, Laiola, Roager, De Filippis, Roume, Quinquis, Giacco, Mennella, Ferracane, Pons, Pasolli, Rivellese, Dragsted, Vitaglione, Ehrlich and Ercolini2020). The Mediterranean diet comprises vegetables, fruits, legumes, nuts, olive oil, and fish; additionally, it includes low amounts of red meat, dairy products, and saturated fats (Ghosh et al., Reference Ghosh, Rampelli, Jeffery, Santoro, Neto, Capri, Giampieri, Jennings, Candela, Turroni, Zoetendal, Hermes, Elodie, Meunier, Brugere, Pujos-Guillot, Berendsen, De Groot, Feskins, Kaluza, Pietruszka, Bielak, Comte, Maijo-Ferre, Nicoletti, De Vos, Fairweather-Tait, Cassidy, Brigidi, Franceschi and O’Toole2020; Serra-Majem et al., Reference Serra-Majem, Tomaino, Dernini, Berry, Lairon, Ngo de la Cruz, Bach-Faig, Donini, Medina, Belahsen, Piscopo, Capone, Aranceta-Bartrina, La Vecchia and Trichopoulou2020). Multiple RCTs have evidence that regular consumption promotes the proliferation of health-related bacteria. In an RCT conducted on individuals with excess body weight, increased adherence to a Mediterranean diet decreased plasma cholesterol concentrations and enriched F. prausnitzii and Roseburia abundances compared with a control diet (Meslier et al., Reference Meslier, Laiola, Roager, De Filippis, Roume, Quinquis, Giacco, Mennella, Ferracane, Pons, Pasolli, Rivellese, Dragsted, Vitaglione, Ehrlich and Ercolini2020). These bacteria were also identified as good predictors of dietary adherence scores in an RCT in older adults who consumed a Mediterranean diet for 12 months (Ghosh et al., Reference Ghosh, Rampelli, Jeffery, Santoro, Neto, Capri, Giampieri, Jennings, Candela, Turroni, Zoetendal, Hermes, Elodie, Meunier, Brugere, Pujos-Guillot, Berendsen, De Groot, Feskins, Kaluza, Pietruszka, Bielak, Comte, Maijo-Ferre, Nicoletti, De Vos, Fairweather-Tait, Cassidy, Brigidi, Franceschi and O’Toole2020).

Another study based on an intervention promoting adherence to the Mediterranean diet identified a decrease in Butyricicoccus, Haemophilus, Ruminiclostridium, and Eubacterium hallii in the participants consuming that diet compared with a control group. Also, changes in Lachnospiraceae NK4A136 were positively associated with changes in adherence to the Mediterranean diet (Muralidharan et al., Reference Muralidharan, Moreno-Indias, Bulló, Lopez, Corella, Castañer, Vidal, Atzeni, Fernandez-García, Torres-Collado, Fernández-Carrión, Fito, Olbeyra, Gomez-Perez, Galiè, Bernal-López, Martinez-Gonzalez, Salas-Salvadó and Tinahones2021). Similarly, specific taxa such as Anaerostipes hadrus showed high abundances in a Mediterranean diet enriched with fibre. Besides, Agathobaculum and Anaerostipes genus and Agathobaculum butyriciproducens and Anaerostipes hadrus species showed significantly higher (p < 0.05) abundances after an intervention with the Mediterranean diet. However, since only changes in specific taxa were observed, no significant effects on the core microbiota could be reported (Barber et al., Reference Barber, Mego, Sabater, Vallejo, Bendezu, Masihy, Guarner, Espín, Margolles and Azpiroz2021).

Although the Mediterranean diet is commonly assumed as a sustainable dietary pattern (Fresán et al., Reference Fresán, Martínez-Gonzalez, Sabaté and Bes-Rastrollo2018; Hachem et al., Reference Hachem, Vanham and Moreno2020; Serra-Majem et al., Reference Serra-Majem, Tomaino, Dernini, Berry, Lairon, Ngo de la Cruz, Bach-Faig, Donini, Medina, Belahsen, Piscopo, Capone, Aranceta-Bartrina, La Vecchia and Trichopoulou2020), some studies analysing their environmental impact and affordability have found diverse results that indicate that although being sustainable in some aspects, such as GHGE and affordability in some socioeconomic strata (Germani et al., Reference Germani, Vitiello, Giusti, Pinto, Donini and del Balzo2014), other indicators, such as the water footprint, tend to present high environmental impacts (Blas et al., Reference Blas, Garrido and Willaarts2016). Also, it is not affordable for some population sectors (Rubini et al., Reference Rubini, Vilaplana-Prieto, Flor-Alemany, Yeguas-Rosa, Hernández-González, Félix-García, Félix-Redondo and Fernández-Bergés2022). This emphasises the importance of contextualising and individualising diets to be considered sustainable and, thus, to characterise their specific effects on the gut microbiome.

Another diet recognised as healthy and, recently, as sustainable is the New Nordic diet (Hachem et al., Reference Hachem, Vanham and Moreno2020; Landberg and Hanhineva, Reference Landberg and Hanhineva2019). It is characterised by high content of local vegetables such as cabbages, mushrooms, root vegetables, and fruits such as berries, apples, and pears. It includes legumes, fresh herbs, potatoes, whole grains (Barley, rye, oats, spelt, and buckwheat), native nuts (hazelnuts, walnuts, and chestnuts), fish and shellfish, seaweed, and free-range livestock like pigs and poultry (Meltzer et al., Reference Meltzer, Brantsæter, Trolle, Eneroth, Fogelholm, Ydersbond and Birgisdottir2019; Mithril et al., Reference Mithril, Dragsted, Meyer, Tetens, Biltoft-Jensen and Astrup2013). It also comprises traditional foods sourced in the Nordic countries and focuses on those from the wild countryside and the sea and lakes (Hachem et al., Reference Hachem, Vanham and Moreno2020). Various studies have shown their beneficial effects on the gut microbiome. For example, interventions with whole grains have increased SCFA-producing Lachnospira spp. compared with a control group consuming refined grains (Vanegas et al., Reference Vanegas, Meydani, Barnett, Goldin, Kane, Rasmussen, Brown, Vangay, Knights, Jonnalagadda, Koecher, Karl, Thomas, Dolnikowski, Li, Saltzman, Wu and Meydani2017).

Despite its effects, a study showed that a dietary intervention with the New Nordic diet in adults 18-65 years did not affect the ratio when the abundances of 35 selected bacterial taxa were quantified before and after the intervention. Also, the study showed that the participant’s enterotype appeared to significantly impact the total plasma cholesterol more than diet. Besides, higher levels of the Prevotella/Bacteroides ratio were associated with higher total cholesterol levels (Roager et al., Reference Roager, Licht, Poulsen, Larsen and Bahl2014). Other studies assessing the effects of diets with the New Nordic Diet characteristics, such as whole grain diets, have only shown minor alterations in the gut microbiota. However, this diet has been associated with increased SCFA-producing Lachnospira spp. when compared with a control group consuming refined grains (Landberg and Hanhineva, Reference Landberg and Hanhineva2019).

Despite the well-demonstrated benefits of this diet on the gut microbiome, it is essential to mention that, from a sustainability perspective, there are elements that have not been addressed, such as the environmental impact of the persons following the dietary interventions previously mentioned. Besides, it is not mentioned if all participants had access to the same type and quality foods in the diet. Actually, a study mentioned that typical current diets in the Nordic countries are neither healthy nor environmentally sustainable, although there are indications of progress towards more fruit and vegetables in the diet. This could lead to essential differences in health outcomes, especially in the gut microbiome (Meltzer et al., Reference Meltzer, Brantsæter, Trolle, Eneroth, Fogelholm, Ydersbond and Birgisdottir2019).

Traditional diets: The Milpa diet

The European colonisation of American countries modified the traditional and Indigenous diets of populations such as the Mesoamericans (Palka, Reference Palka2009). Among those is the Mexican traditional pre-Hispanic diet, also known as the milpa diet (the cornfield diet), which is a plant-based diet composed of corn, beans, zucchini, and chili, and also includes a large number of native fresh fruits and vegetables, like citrus, papaya, quelites, red tomato, and cactus (nopales). It also comprises protein-rich seeds such as pumpkin seeds, chia, amaranth, and peanuts, and healthy fats like avocado. Fermented drinks, homemade cheese, and insects are also present in that diet (Lares-Michel et al., Reference Lares-Michel, Housni, Aguilera Cervantes, Reyes-Castillo, Michel Nava, Llanes Cañedo and de Jesús López Larios2022; Valerino-Perea et al., Reference Valerino-Perea, Lara-Castor, Armstrong and Papadaki2019).

The sustainability of the Mexican traditional diet has been recently claimed and proposed as an alternative for promoting human and planetary health in specific regions like Mexico, meanwhile promoting cultural and affordable diets (Almaguer González et al., Reference Almaguer González, García Ramírez, Padilla Mirazo and González Ferral2019; Lares-Michel et al., Reference Lares-Michel, Housni, Aguilera Cervantes, Reyes-Castillo, Michel Nava, Llanes Cañedo and de Jesús López Larios2022; Reference Lares-Michel, Housni, Reyes-Castillo, Huertas, Aguilera-Cervantes and Michel-Nava2023). Nevertheless, the principal problem regarding recovering traditional diets is to ensure that the population adheres to these kinds of dietary patterns. Currently, it has been reported that the Mexican population is consuming a Western diet with high environmental implications and detrimental to their health (Aburto et al., Reference Aburto, Batis, Pedroza-Tobías, Pedraza, Ramírez-Silva and Rivera2022; Batis et al., Reference Batis, Marrón-Ponce, Stern, Vandevijvere, Barquera and Rivera2021; López-Olmedo et al., Reference López-Olmedo, Stern, Bakhtsiyarava, Pérez-Ferrer and Langellier2022).

Regarding gut microbiota, a study in mice showed that a traditional Mexican diet based on corn, beans, tomato, nopal, chia, and pumpkin seeds in a dehydrated form significantly increases the relative abundances of Akkermansia and Bifidobacterium. Also, its consumption decreased glucose intolerance and the biochemical abnormalities caused by obesity by increasing the abundance of fatty acid oxidation proteins and decreasing oxidative stress (Avila-Nava et al., Reference Avila-Nava, Noriega, Tovar, Granados, Perez-Cruz, Pedraza-Chaverri and Torres2017).

Despite their beneficial effects on gut microbiota and the environment have been suggested, it is essential to mention that the personalisation of these dietary patterns is needed (Grasso et al., Reference Grasso, Olthof, Reinders, Wijnhoven, Visser and Brouwer2022). Also, the specific impact of this diet on environmental indicators, such as the water and carbon footprints and health outcomes, including the gut microbiota, needs to be known to promote the diet accurately. Besides, due to nutrition transition, behavioural interventions are needed to increase adherence to traditional diets, respecting sustainable diet dimensions (Biasini et al., Reference Biasini, Rosi, Giopp, Turgut, Scazzina and Menozzi2021; Vos et al., Reference Vos, Deforche, Van Kerckhove, Michels, Geuens and Van Lippevelde2022).

Fortunately, currently an RCT is being performed in Mexico, where a diet is being mathematically optimised to design a healthy, sustainable diet for Mexico’s context based on its traditional diet (Lares-Michel et al., Reference Lares-Michel, Housni, Reyes-Castillo, Huertas, Aguilera-Cervantes and Michel-Nava2023). The study will report the effects of this diet on specific bacteria such as Bacillota, Bacteroidota, Lactobacillus, Bifidobacterium, F. prausnitzii, A. muciniphila, P. copri, B. wadsworthia, Clostridium coccoides, and Streptococcus thermophilus. Besides, it includes environmental indicators and will cover all sustainable diet dimensions (Lares-Michel et al., Reference Lares-Michel, Housni, Reyes-Castillo, Huertas, Aguilera-Cervantes and Michel-Nava2023). When this research’s results are available, the gut microbiota effects of a personalised region-specific sustainable diet could be characterised for the first time.

Sustainable diet’s composition and its potential effects on the gut microbiome

Although healthy and sustainable diets used to be addressed separately, in 2021, the United Nations Food Systems Summit proposed a new definition for a healthy diet, referring to a healthy diet such as one that is human health-promoting and disease-preventing, and safeguarding of planetary health by providing adequacy, without excess, of nutrients from foods that are nutritious and healthy, avoiding the introduction of health-harming substances, through all stages of the value chain. Healthy diets must be affordable and culturally acceptable. They must progressively change towards originating from sustainable production and processing systems that do not adversely affect local and regional ecologies (Neufeld et al., Reference Neufeld, Hendriks, Hugas, Von Braun, Afsana, Fresco and Hassan2023). In this regard, the most up-to-date literature about healthy and sustainable diets starts addressing them as concepts that cannot be separated.

Currently, the most accepted definition of sustainable diets is the one proposed by the Food and Agriculture Organization of the United Nations and World Health Organization (2019), which defines this kind of diet as dietary patterns that promote all the dimensions of people’s health and well-being, meanwhile having low pressure on the environment, and being accessible, affordable, safe, and equitable for all populations, respecting the culture of the people. Nevertheless, the principal problem with these diets is that to achieve a person’s adherence to a diet of this type, many behaviours must be addressed simultaneously to modify current dietary habits. However, simultaneously ensuring the well-being of the population’s environment, health, nutrition, culture, and socioeconomic aspects is a big challenge (Biasini et al., Reference Biasini, Rosi, Giopp, Turgut, Scazzina and Menozzi2021; Drewnowski, Reference Drewnowski2020).

One of the most recognised diets for sustainability is the Planetary Health Diet, created in 2019 by researchers from the EAT-Lancet Commission. This diet model provided specific recommendations to promote healthy diets derived from sustainable food systems (Rehner et al., Reference Rehner, Schmartz, Kramer, Keller, Keller and Becker2023). However, this dietary pattern has been criticised in several ways (Verkerk, Reference Verkerk2019). First, it was criticised for not considering specific regions’ cultural elements, and its affordability has been questioned (Drewnowski, Reference Drewnowski2020). Besides, its macro and micronutrient profiles were pointed out as lacking adequacy, especially considering those generally found in higher quantities and more bioavailable forms in animal-source foods (Beal et al., Reference Beal, Ortenzi and Fanzo2023). Also, its practical implementation feasibility has been repeatedly referred to as one of the principal limitations of this diet (Breidenassel et al., Reference Breidenassel, Schäfer, Melanie, Richter, Linseisen and Watzl2022).

Despite the limitations of the Planetary Health Diet, a recent study reported its effects on the Human Gut Microbiome (Rehner et al., Reference Rehner, Schmartz, Kramer, Keller, Keller and Becker2023). The study was conducted on 41 German adults (22–57 years). The sample was divided into three groups, one consuming a Western omnivorous diet, the second consuming a vegan or vegetarian diet, and the third consuming the EAT-Lancet diet for Planetary Health for 12 weeks. In this study, a trend towards an increase in Bifidobacterium adolescentis and Coprococcus eutactus was identified in the group consuming the Planetary Health Diet (Rehner et al., Reference Rehner, Schmartz, Kramer, Keller, Keller and Becker2023). B. adolescentis is capable of degrading inulin (a type of fibre) into lactate and acetate, which can be used by Anaerostipes hadrus and Enterococcus rectale to produce the SCFA butyrate, thus generating anti-inflammatory effects on the host (Baxter et al., Reference Baxter, Schmidt, Venkataraman, Kim, Waldron and Schmidt2019). Another bacteria found after consuming the Planetary Health Diet was P. copri, which, although has been related to some beneficial metabolic effects, such as glucose regulation (Asnicar et al., Reference Asnicar, Berry, Valdes, Nguyen, Piccinno, Drew, Leeming, Gibson, Le Roy, Khatib, Francis, Mazidi, Mompeo, Valles-Colomer, Tett, Beghini, Dubois, Bazzani, Thomas, Mirzayi, Khleborodova, Oh, Hine, Bonnett, Capdevila, Danzanvilliers, Giordano, Geistlinger, Waldron, Davies, Hadjigeorgiou, Wolf, Ordovás, Gardner, Franks, Chan, Huttenhower, Spector and Segata2021; Losno et al., Reference Losno, Sieferle, Perez-Cueto and Ritz2021), has also been related to the development of rheumatoid arthritis (Scher et al., Reference Scher, Sczesnak, Longman, Segata, Ubeda, Bielski, Rostron, Cerundolo, Pamer, Abramson, Huttenhower and Littman2013). However, more studies are needed since this bacteria has been highly associated with healthy diets, especially plant-based (Losno et al., Reference Losno, Sieferle, Perez-Cueto and Ritz2021; Trefflich et al., Reference Trefflich, Jabakhanji, Menzel, Blaut, Michalsen, Lampen, Abraham and Weikert2020).

Despite the exciting insights that these emerging studies are providing to the study of the gut microbiota composition of sustainable diets, the sustainability limitations addressed before provide direction for future studies that characterise the composition of the gut microbiota generated by the consumption of sustainable, contextualised, and personalised diets, covering all sustainability dimensions. To the best of our knowledge, no study has analysed the effects that a sustainable diet covering all those elements could have on the gut microbiome.

PubMed database reports zero research when using the terms (“gut microbiota” OR “gut microbiome” OR “gut bacteria” OR “microbiota diversity” OR “intestinal bacteria” OR “gut bacteria” OR “intestinal flora”) AND (“sustainable diet”). Only three registered protocols on ClinicalTrials.com are in course for assessing the effects of sustainable diets on gut microbiota. The first protocol is being carried out in the United Kingdom (ClinicalTrials.gov Identifier: NCT05231317). To the moment, the authors have included 20 participants (18–70 years) that were divided into an experimental plant-based diet group, which was referred to as a diet rich in fruit and vegetables (42% carbohydrates, 17.2% fibres; 15% proteins; and 43% fats), during 16 days with all foods provided. Furthermore, an active comparator group following a Western diet based on processed foods (48% carbohydrates, 10.4% fibres; 14% proteins; and 39% fats) was included. The study’s primary outcomes are significant changes in the number of Bifidobacteria over 14 days and changes in Trimethylamine N-oxide over 16 days assessed by changes in response to L-Carnitine challenge (ClinicalTrials.gov, 2022a). Although this study is one of the pioneers in the study of the gut microbiome of sustainable diets, it has been noted that the inclusion of the sustainability diet elements is not mentioned, and besides, no specific behavioural techniques are detailed for guaranteeing the population actually adheres to the prescribed diet (ClinicalTrials.gov, 2022a).

The second study is being developed in Mexico and is based on a Sustainable-psycho-nutritional Intervention Program that aims to promote adherence to a region-specific sustainable diet and to evaluate their effects on several environmental and health outcomes, including the gut microbiota (ClinicalTrials.gov Identifier: NCT05457439). The study is an RCT, targeting a control (n = 50) and intervention (n = 50) group (18–35 years), with metabolic-health risk factors. The intervention group followed a sustainable diet mathematically designed for Mexico’s context for 7 weeks. This was then followed up for 7 more weeks. The control group did not receive any intervention or nutritional advice. Regarding gut microbiome, the study evaluates the changes in relative abundances of specific bacteria related to metabolic health or dietary patterns, such as Bacillota, Bacteroidota, Lactobacillus, Bifidobacterium, F. prausnitzii, A. muciniphila, P. copri, B. wadsworthia, C. coccoides, and S. thermophilus (ClinicalTrials.gov, 2022b). No results have been reported, but the current Clinical Trials report indicates the project is about to get completed.

Finally, the most recent registered study on Clinical Trials is another study in Mexico that aims to Reduce Metabolic Endotoxemia in 100 adults through a low-inflammatory and environmentally friendly dietary strategy (ClinicalTrials.gov Identifier: NCT05776329). Among their primary outcomes is a change in Lipopolysaccharide-binding protein, and secondarily the study will evaluate Prevotella changes. All variables are measured over 6 weeks (ClinicalTrials.gov, 2023). Also, no results are yet available.

Although evidence is still scarce for defining the composition of gut microbiota related to sustainable diet consumption, based on available data, it can be assumed that sustainable diets could promote the proliferation of the same or at least similar bacteria observed in plant-based diets (Rehner et al., Reference Rehner, Schmartz, Kramer, Keller, Keller and Becker2023). However, it must be remembered that sustainable diets are not necessarily vegan or vegetarian and can include minor or even moderate amounts of animal-based foods, especially considering that for a diet to be sustainable, personal food preferences, culture, and societal aspects of each individual must be addressed (Biasini et al., Reference Biasini, Rosi, Giopp, Turgut, Scazzina and Menozzi2021; Carey et al., Reference Carey, Paquette, Sahye-Pudaruth, Dadvar, Dinh, Khodabandehlou, Liang, Mishra, Sidhu, Brown, Tandon, Wanyan, Bazinet, Hanley, Malik, Sievenpiper and Jenkins2023). Also, exploring how locally produced food can affect individuals in specific regions is exciting. Some previous studies have shown that geographical location is a crucial determinant of gut microbiota, so this must also be considered when exploring the sustainability context (Senghor et al., Reference Senghor, Sokhna, Ruimy and Lagier2018).

Those variations among diets, geographical zones, and gut microbiota composition and functions could also confirm the role of bacteria on human evolution and how bacteria can play a role in human adaptation to specific contexts, climates, soil types, and of course, food intake. However, not only could bacteria have a role in this process, but diet could modulate the differences in the gut microbiota of ancestors in contrast with modern societies (Elechi et al., Reference Elechi, Sirianni, Conforti, Cione and Pellegrino2023). Also, the evolution of the food system, and especially the use of herbicides and fertilisers, could have influenced the gut microbiota of individuals. Seasonal food consumption is also a characteristic of sustainable diets, for which specific environmental characteristics such as climate could also impact gut microbiota (Elechi et al., Reference Elechi, Sirianni, Conforti, Cione and Pellegrino2023; Robinson et al., Reference Robinson, Mills and Breed2018). Therefore, returning to consuming a diet based on un-processed and vegetable foods, locally produced in natural seasons and produced respecting the environment, is promising for a gut microbiota aligned with health (González Olmo et al., Reference González Olmo, Butler and Barrientos2021).

Exploring the gut microbiota and its metabolites in relation to sustainable diets should be further studied to allow the configuration of even more personalised nutrition for gut microbiota modulation. Nowadays, we know that more diverse gut microbiota and a higher proliferation of butyrate-producing bacteria, considered anti-inflammatory, are essential for health preservation. So far, the scientific consensus points towards rich fibre diets, low in ultra-processed foods, and animal origin to improve human intestinal microbiota’s diversity and population and preserve its proper functioning (McCarthy and Li, Reference McCarthy and Li2019; Rinninella et al., Reference Rinninella, Cintoni, Raoul, Lopetuso, Scaldaferri, Pulcini, Miggiano, Gasbarrini and Mele2019). Even the consumption of beef (the food with the most significant environmental impact) has been related to a decrease in beneficial bacteria such as Bifidobacterium, and the substitution of animal protein for vegetable sources has been referred to as a suitable option to increase the number of health-related bacteria in the body (Bifidobacterium and Lactobacillus) and reduce those that are considered pathogenic (B. fragilis and Clostridium perfringens) (Świątecka et al., Reference Świątecka, Narbad, Ridgway and Kostyra2011).

Some insight has emerged for specific regional dietary patterns, such as the Mediterranean and the Mexican traditional or milpa, suggesting that their current composition, which is principally plant-based, could be sustainable and could improve gut microbiota composition (Avila-Nava et al., Reference Avila-Nava, Noriega, Tovar, Granados, Perez-Cruz, Pedraza-Chaverri and Torres2017; Muralidharan et al., Reference Muralidharan, Moreno-Indias, Bulló, Lopez, Corella, Castañer, Vidal, Atzeni, Fernandez-García, Torres-Collado, Fernández-Carrión, Fito, Olbeyra, Gomez-Perez, Galiè, Bernal-López, Martinez-Gonzalez, Salas-Salvadó and Tinahones2021). However, no study has addressed all sustainability dimensions of those dietary patterns in relation to the gut microbiota composition and functions of the population consuming those diets. Also, the composition of the diet for planetary health of the EAT-Lancet Commission, which is also a plant-based diet, is promising for the gut microbiota, considering fibre content, antioxidants, and vegetable protein. Nevertheless, as far as no contextualisation to specific regions is done, that diet cannot be considered sustainable (Rehner et al., Reference Rehner, Schmartz, Kramer, Keller, Keller and Becker2023).

Therefore, so far, the characteristics of a diet that benefits the intestinal microbiota coincide with the elements of a diet that optimises the use of natural resources and generates low environmental impacts. However, in-depth studies identifying production regions, and their related characteristics (soil characteristics, climate, food production techniques, use of herbicides), could bring new perspectives and further characterise what a sustainable diet gut microbiota composition and functions are (Biasini et al., Reference Biasini, Rosi, Giopp, Turgut, Scazzina and Menozzi2021; Rehner et al., Reference Rehner, Schmartz, Kramer, Keller, Keller and Becker2023). Also, it is essential to recognise that evolution has not stopped, and technologies will keep emerging. Therefore, they should be used to improve current food production and direct it towards more sustainable techniques. Even technologies can help produce sustainable, functional food ingredients to modulate the human gut microbiota (de Carvalho et al., Reference de Carvalho, Oliveira, Costa, Pintado and Madureira2023).

Conclusions

Characterising the gut microbiome of individuals consuming healthy sustainable diets is essential to generate evidence of their effects on the planet and the population’s health status. Modulating the gut microbiome could regulate health status, and its role in sustainable food production and biodiversity preservation must arise. It is urgent to stop generalising and assuming healthy or plant-based diets to be sustainable because contextualisation and personalisation are necessary for a dietary pattern to be considered sustainable. Thus, consistently, for a diet to be sustainable, it must consider health and nutrition, environment, cultural and socioeconomic aspects. Finally, multidisciplinary behavioural interventions and public health policies are needed to encourage healthy behaviour and change current food environments to achieve the potential benefits of sustainable diets on gut microbiota. It is also important to consider strategies to reduce food waste, which will significantly benefit the environment, and to reduce caloric intake, which will benefit both the environment and human health. Precision nutrition will likely play a role in optimising personal health in the future. However, much more research is needed before it can be widely applied to disease prevention and planet conservation while improving health outcomes such as the gut microbiome (Hemler and Hu, Reference Hemler and Hu2019).

Acknowledgements

We thank the National Council for Science and Technology (CONACYT) for the scholarship provided to the CVU number 934420. Also, we thank the University Center of the South, University of Guadalajara, and The Behavioral Feeding and Nutrition Research Institute (IICAN), University of Guadalajara for the financial support provided. Besides, we thank BioRender, since the figures were created with BioRender.com.

Author contribution

Conceptualization: M.L.; Data curation: M.L.; Formal Analysis: M.L; Investigation: M.L., Z.R. and F.E.H.; Project administration: M.L., Z.R. and F.E.H.; Supervision: M.L., Z.R. and F.E.H.; Visualization: M.L., Z.R. and F.E.H.; Writing-Review and Editing, M.L., Z.R. and F.E.H.; Writing-Original Draft, M.L.; Funding Acquisition, M.L., Z.R. and F.E.H.

Funding

This project has received financial support from the University Center of the South, University of Guadalajara, and The Behavioral Feeding and Nutrition Research Institute (IICAN), University of Guadalajara. However, funding sources did not have any role in the design and development of this project.

Competing interest

The authors declare no conflict of interest.

References

Aburto, TC, Batis, C, Pedroza-Tobías, A, Pedraza, LS, Ramírez-Silva, I and Rivera, JA (2022) Dietary intake of the Mexican population: Comparing food group contribution to recommendations, 2012–2016. Salud Publica De Mexico 64(3), 267279. https://doi.org/10.21149/13091CrossRefGoogle ScholarPubMed
Aguayo-Patrón, SV and de la Barca, AM (2017) Old fashioned vs. ultra-processed-based current diets: Possible implication in the increased susceptibility to type 1 diabetes and celiac disease in childhood. Foods (Basel, Switzerland) 6(11), E100. https://doi.org/10.3390/foods6110100Google ScholarPubMed
Almaguer González, J, García Ramírez, H, Padilla Mirazo, M and González Ferral, M (2019) Fortalecimiento de la salud con comida, ejercicio y buen humor: La dieta de la milpa. Modelo de alimentación mesoamericana saludable y culturalmente pertinente. Secretaría de Salud. Google Docs. Available at https://drive.google.com/file/d/1n05pSVGY09FlzW91Rt8IZk_6J-KIPRJT/view?usp=sharing&usp=embed_facebook. Accessed on July 5, 2023Google Scholar
Armet, AM, Deehan, EC, O’Sullivan, AF, Mota, JF, Field, CJ, Prado, CM, Lucey, AJ and Walter, J (2022) Rethinking healthy eating in light of the gut microbiome. Cell Host & Microbe 30(6), 764785. https://doi.org/10.1016/j.chom.2022.04.016CrossRefGoogle ScholarPubMed
Aslam, H, Marx, W, Rocks, T, Loughman, A, Chandrasekaran, V, Ruusunen, A, Dawson, SL, West, M, Mullarkey, E, Pasco, JA and Jacka, FN (2020) The effects of dairy and dairy derivatives on the gut microbiota: A systematic literature review. Gut Microbes 12(1), 1799533. https://doi.org/10.1080/19490976.2020.1799533CrossRefGoogle ScholarPubMed
Asnicar, F, Berry, SE, Valdes, AM, Nguyen, LH, Piccinno, G, Drew, DA, Leeming, E, Gibson, R, Le Roy, C, Khatib, HA, Francis, L, Mazidi, M, Mompeo, O, Valles-Colomer, M, Tett, A, Beghini, F, Dubois, L, Bazzani, D, Thomas, AM, Mirzayi, C, Khleborodova, A, Oh, S, Hine, R, Bonnett, C, Capdevila, J, Danzanvilliers, S, Giordano, F, Geistlinger, L, Waldron, L, Davies, R, Hadjigeorgiou, G, Wolf, J, Ordovás, JM, Gardner, C, Franks, PW, Chan, AT, Huttenhower, C, Spector, TD and Segata, N (2021) Microbiome connections with host metabolism and habitual diet from 1,098 deeply phenotyped individuals. Nature Medicine 27(2), Article 2. https://doi.org/10.1038/s41591-020-01183-8CrossRefGoogle ScholarPubMed
Auestad, N and Fulgoni, VL (2015) What current literature tells us about sustainable diets: Emerging research linking dietary patterns, environmental sustainability, and economics. Advances in Nutrition (Bethesda, Md.) 6(1), 1936. https://doi.org/10.3945/an.114.005694CrossRefGoogle ScholarPubMed
Avila-Nava, A, Noriega, LG, Tovar, AR, Granados, O, Perez-Cruz, C, Pedraza-Chaverri, J and Torres, N (2017) Food combination based on a pre-hispanic Mexican diet decreases metabolic and cognitive abnormalities and gut microbiota dysbiosis caused by a sucrose-enriched high-fat diet in rats. Molecular Nutrition & Food Research 61(1). https://doi.org/10.1002/mnfr.201501023CrossRefGoogle ScholarPubMed
Bach-Faig, A, Berry, EM, Lairon, D, Reguant, J, Trichopoulou, A, Dernini, S, Medina, FX, Battino, M, Belahsen, R, Miranda, G, Serra-Majem, L and Mediterranean Diet Foundation Expert Group (2011) Mediterranean diet pyramid today. Science and cultural updates. Public Health Nutrition 14(12A), 22742284. https://doi.org/10.1017/S1368980011002515CrossRefGoogle ScholarPubMed
Barber, C, Mego, M, Sabater, C, Vallejo, F, Bendezu, RA, Masihy, M, Guarner, F, Espín, JC, Margolles, A and Azpiroz, F (2021) Differential effects of Western and Mediterranean-type diets on gut microbiota: A metagenomics and metabolomics approach. Nutrients 13(8), Article 8. https://doi.org/10.3390/nu13082638CrossRefGoogle ScholarPubMed
Barosh, L, Friel, S, Engelhardt, K and Chan, L (2014) The cost of a healthy and sustainable diet—Who can afford it? Australian and New Zealand Journal of Public Health 38(1), 712. https://doi.org/10.1111/1753-6405.12158CrossRefGoogle Scholar
Batis, C, Gatica-Domínguez, G, Marrón-Ponce, JA, Colchero, MA, Rivera, JA, Barquera, S and Stern, D (2022) Price trends of healthy and less healthy foods and beverages in Mexico from 2011–2018. Journal of the Academy of Nutrition and Dietetics 122(2), 309319, e16. https://doi.org/10.1016/j.jand.2021.08.105CrossRefGoogle ScholarPubMed
Batis, C, Marrón-Ponce, JA, Stern, D, Vandevijvere, S, Barquera, S and Rivera, JA (2021) Adoption of healthy and sustainable diets in Mexico does not imply higher expenditure on food. Nature Food 2(10), Article 10. https://doi.org/10.1038/s43016-021-00359-wCrossRefGoogle Scholar
Baxter, NT, Schmidt, AW, Venkataraman, A, Kim, KS, Waldron, C and Schmidt, TM (2019) Dynamics of human gut microbiota and short-chain fatty acids in response to dietary interventions with three fermentable fibers. MBio 10(1), e02566e02518. https://doi.org/10.1128/mBio.02566-18CrossRefGoogle ScholarPubMed
Beal, T, Ortenzi, F and Fanzo, J (2023) Estimated micronutrient shortfalls of the EAT–lancet planetary health diet. The Lancet Planetary Health 7(3), e233e237. https://doi.org/10.1016/S2542-5196(23)00006-2CrossRefGoogle ScholarPubMed
Biasini, B, Rosi, A, Giopp, F, Turgut, R, Scazzina, F and Menozzi, D (2021) Understanding, promoting and predicting sustainable diets: A systematic review. Trends in Food Science & Technology 111, 191207. https://doi.org/10.1016/j.tifs.2021.02.062CrossRefGoogle Scholar
Birney, CI, Franklin, KF, Davidson, FT and Webber, ME (2017) An assessment of individual foodprints attributed to diets and food waste in the United States. Environmental Research Letters 12(10), 105008. https://doi.org/10.1088/1748-9326/aa8494CrossRefGoogle Scholar
Blas, A, Garrido, A and Willaarts, BA (2016) Evaluating the water footprint of the Mediterranean and American diets. Water 8(10), Article 10. https://doi.org/10.3390/w8100448CrossRefGoogle Scholar
Breidenassel, C, Schäfer, AC, Melanie, M, Richter, M, Linseisen, J and Watzl, B (2022) The planetary health diet in contrast to the food-based dietary guidelines of the German nutrition society (DGE). Ernahrungs Umschau 69(5), 5672. https://doi.org/10.4455/eu.2022.012Google Scholar
Carey, CN, Paquette, M, Sahye-Pudaruth, S, Dadvar, A, Dinh, D, Khodabandehlou, K, Liang, F, Mishra, E, Sidhu, M, Brown, R, Tandon, S, Wanyan, J, Bazinet, RP, Hanley, AJ, Malik, V, Sievenpiper, JL and Jenkins, DJA (2023) The environmental sustainability of plant-based dietary patterns: A scoping review. Journal of Nutrition 153(3), 857869. https://doi.org/10.1016/j.tjnut.2023.02.001CrossRefGoogle ScholarPubMed
Carlsson Kanyama, A, Hedin, B and Katzeff, C (2021) Differences in environmental impact between plant-based alternatives to dairy and dairy products: A systematic literature review. Sustainability 13(22), 22. https://doi.org/10.3390/su132212599CrossRefGoogle Scholar
Carmody, RN, Bisanz, JE, Bowen, BP, Maurice, CF, Lyalina, S, Louie, KB, Treen, D, Chadaideh, KS, Rekdal, VM, Bess, EN, Spanogiannopoulos, P, Ang, QY, Bauer, KC, Balon, TW, Pollard, KS, Northen, TR and Turnbaugh, PJ (2019) Cooking shapes the structure and function of the gut microbiome. Nature Microbiology 4(12), 20522063. https://doi.org/10.1038/s41564-019-0569-4CrossRefGoogle ScholarPubMed
Cena, H and Calder, PC (2020) Defining a healthy diet: Evidence for the role of contemporary dietary patterns in health and disease. Nutrients 12(2), 334. https://doi.org/10.3390/nu12020334CrossRefGoogle ScholarPubMed
Cho, CE, Taesuwan, S, Malysheva, OV, Bender, E, Tulchinsky, NF, Yan, J, Sutter, JL and Caudill, MA (2017) Trimethylamine-N-oxide (TMAO) response to animal source foods varies among healthy young men and is influenced by their gut microbiota composition: A randomized controlled trial. Molecular Nutrition & Food Research 61(1), 1600324. https://doi.org/10.1002/mnfr.201600324CrossRefGoogle ScholarPubMed
ClinicalTrials.gov (2022a) Effect of the Sustainable Diet on Gut Microbiota and the Metabolome: A Randomised Crossover Study (SUSUGUT). ClinicalTrials.gov Identifier: NCT05231317. Available at https://beta.clinicaltrials.gov/study/NCT05231317?distance=50&cond=Gut%20Microbiota&term=sustainable%20diet&rank=1. Accessed on July 5, 2023Google Scholar
ClinicalTrials.gov (2022b) Sustainable-psycho-nutritional Intervention Program and Its Effects on Health Outcomes and the Environment—Full Text View—ClinicalTrials.gov. Available at https://clinicaltrials.gov/ct2/show/NCT05457439. Accessed on July 5, 2023Google Scholar
ClinicalTrials.gov (2023) Dietary Intervention to Reduce Metabolic Endotoxemia—Full Text View—ClinicalTrials.gov. Available at https://clinicaltrials.gov/ct2/show/NCT05776329. Accessed on July 5, 2023Google Scholar
Cuevas-Sierra, A, Milagro, FI, Aranaz, P, Martínez, JA and Riezu-Boj, JI (2021) Gut microbiota differences according to ultra-processed food consumption in a Spanish population. Nutrients 13(8), 2710. https://doi.org/10.3390/nu13082710CrossRefGoogle Scholar
David, LA, Maurice, CF, Carmody, RN, Gootenberg, DB, Button, JE, Wolfe, BE, Ling, AV, Devlin, AS, Varma, Y, Fischbach, MA, Biddinger, SB, Dutton, RJ and Turnbaugh, PJ (2014) Diet rapidly and reproducibly alters the human gut microbiome. Nature 505(7484), Article 7484. https://doi.org/10.1038/nature12820CrossRefGoogle ScholarPubMed
de Carvalho, NM, Oliveira, DL, Costa, CM, Pintado, ME and Madureira, AR (2023) Strategies to assess the impact of sustainable functional food ingredients on gut microbiota. Food 12(11), 11. https://doi.org/10.3390/foods12112209Google ScholarPubMed
De la Vega-Rivera, A and Merino-Pérez, L (2021) Socio-environmental impacts of the avocado boom in the Meseta Purépecha, Michoacán, Mexico. Sustainability 13(13), Article 13. https://doi.org/10.3390/su13137247CrossRefGoogle Scholar
Drewnowski, A (2020) Analysing the affordability of the EAT–lancet diet. Lancet Global Health 8(1), e6e7. https://doi.org/10.1016/S2214-109X(19)30502-9CrossRefGoogle ScholarPubMed
Elechi, JOG, Sirianni, R, Conforti, FL, Cione, E and Pellegrino, M (2023) Food system transformation and gut microbiota transition: Evidence on advancing obesity, cardiovascular diseases, and cancers-A narrative review. Foods (Basel, Switzerland) 12(12), 2286. https://doi.org/10.3390/foods12122286CrossRefGoogle Scholar
Food and Agriculture Organization of the United Nations (2020) Consumption of fish and shellfish and the regional markets. Food and Agriculture Organization of the United Nations. Available at https://www.fao.org/3/s9727e/s9727e03.htm. Accessed on July 5, 2023Google Scholar
Food and Agriculture Organization of the United Nations (2023) Food-based dietary guidelines. Food and Agriculture Organization of the United Nations. Available at http://www.fao.org/nutrition/education/food-dietary-guidelines/home/en/. Accessed on July 5, 2023Google Scholar
Food and Agriculture Organization of the United Nations & World Health Organization (2019) Sustainable healthy diets: Guiding principles. Available at https://www.who.int/publications/i/item/9789241516648. Accessed on July 5, 2023.Google Scholar
Fresán, U, Martínez-Gonzalez, M-A, Sabaté, J and Bes-Rastrollo, M (2018) The Mediterranean diet, an environmentally friendly option: Evidence from the Seguimiento Universidad de Navarra (SUN) cohort. Public Health Nutrition 21(8), 15731582. https://doi.org/10.1017/S1368980017003986CrossRefGoogle Scholar
Germani, A, Vitiello, V, Giusti, AM, Pinto, A, Donini, LM and del Balzo, V (2014) Environmental and economic sustainability of the Mediterranean diet. International Journal of Food Sciences and Nutrition 65(8), 10081012. https://doi.org/10.3109/09637486.2014.945152CrossRefGoogle ScholarPubMed
Ghosh, TS, Rampelli, S, Jeffery, IB, Santoro, A, Neto, M, Capri, M, Giampieri, E, Jennings, A, Candela, M, Turroni, S, Zoetendal, EG, Hermes, GDA, Elodie, C, Meunier, N, Brugere, CM, Pujos-Guillot, E, Berendsen, AM, De Groot, LCPGM, Feskins, EJM, Kaluza, J, Pietruszka, B, Bielak, MJ, Comte, B, Maijo-Ferre, M, Nicoletti, C, De Vos, WM, Fairweather-Tait, S, Cassidy, A, Brigidi, P, Franceschi, C and O’Toole, PW (2020) Mediterranean diet intervention alters the gut microbiome in older people reducing frailty and improving health status: The NU-AGE 1-year dietary intervention across five European countries. Gut 69(7), 12181228. https://doi.org/10.1136/gutjnl-2019-319654CrossRefGoogle ScholarPubMed
González Olmo, BM, Butler, MJ and Barrientos, RM (2021) Evolution of the human diet and its impact on gut microbiota, immune responses, and brain health. Nutrients 13(1), 196. https://doi.org/10.3390/nu13010196CrossRefGoogle ScholarPubMed
Goulding, T, Lindberg, R and Russell, CG (2020) The affordability of a healthy and sustainable diet: An Australian case study. Nutrition Journal 19(1), 109. https://doi.org/10.1186/s12937-020-00606-zCrossRefGoogle ScholarPubMed
Grasso, AC, Olthof, MR, Reinders, I, Wijnhoven, HAH, Visser, M and Brouwer, IA (2022) Effect of personalized dietary advice to increase protein intake on food consumption and the environmental impact of the diet in community-dwelling older adults: Results from the PROMISS trial. European Journal of Nutrition 61, 40154026. https://doi.org/10.1007/s00394-022-02896-xCrossRefGoogle ScholarPubMed
Grasso, AC, Olthof, MR, van Dooren, C, Roca, M, Gili, M, Visser, M, Cabout, M, Bot, M, Penninx, BWJH, van Grootheest, G, Kohls, E, Hegerl, U, Owens, M, Watkins, E, Brouwer, IA and Investigators, MooDFOOD Prevention Trial (2020) Effect of food-related behavioral activation therapy on food intake and the environmental impact of the diet: Results from the MooDFOOD prevention trial. European Journal of Nutrition 59(6), 25792591. https://doi.org/10.1007/s00394-019-02106-1CrossRefGoogle Scholar
Hachem, F, Vanham, D and Moreno, LA (2020) Territorial and sustainable healthy diets. Food and Nutrition Bulletin 41(2_suppl), 87S103S. https://doi.org/10.1177/0379572120976253CrossRefGoogle ScholarPubMed
Hemler, EC and Hu, FB (2019) Plant-based diets for personal, population, and planetary health. Advances in Nutrition 10(Suppl_4), S275S283. https://doi.org/10.1093/advances/nmy117CrossRefGoogle ScholarPubMed
Hoekstra, AY, Chapagain, AK, Aldaya, MM and Mekonnen, MM (2012) The Water Footprint Assessment Manual: Setting the Global Standard (1st ed.). Routledge, London, UK. https://doi.org/10.4324/9781849775526Google Scholar
Johnson, KV-A and Foster, KR (2018) Why does the microbiome affect behaviour? Nature Reviews Microbiology 16(10), 647655. https://doi.org/10.1038/s41579-018-0014-3CrossRefGoogle ScholarPubMed
Landberg, R and Hanhineva, K (2019) Biomarkers of a healthy Nordic diet—From dietary exposure biomarkers to microbiota signatures in the metabolome. Nutrients 12(1), 27. https://doi.org/10.3390/nu12010027CrossRefGoogle ScholarPubMed
Lares-Michel, M, Housni, FE, Aguilera Cervantes, VG, Carrillo, P, Michel Nava, RM and Cañedo, CL (2021) Eat well to fight obesity… and save water: The water footprint of different diets and caloric intake and its relationship with adiposity. Frontiers in Nutrition 8, 694775. https://doi.org/10.3389/fnut.2021.694775CrossRefGoogle ScholarPubMed
Lares-Michel, M, Housni, FE, Aguilera Cervantes, VG, Reyes-Castillo, Z, Michel Nava, RM, Llanes Cañedo, C and de Jesús López Larios, M (2022) The water footprint and nutritional implications of diet change in Mexico: A principal component analysis. European Journal of Nutrition 61, 32013226. https://doi.org/10.1007/s00394-022-02878-zCrossRefGoogle ScholarPubMed
Lares-Michel, M, Housni, FE, Reyes-Castillo, Z, Huertas, JR, Aguilera-Cervantes, VG and Michel-Nava, RM (2023) Sustainable-psycho-nutritional intervention programme for a sustainable diet (the ‘NutriSOS’ study) and its effects on eating behaviour, diet quality, nutritional status, physical activity, metabolic biomarkers, gut microbiota and water and carbon footprints in Mexican population: Study protocol of an mHealth randomised controlled trial. British Journal of Nutrition, 116. https://doi.org/10.1017/S0007114523000843CrossRefGoogle ScholarPubMed
Lerma-Aguilera, AM, Pérez-Burillo, S, Navajas-Porras, B, León, ED, Ruíz, S, Pastoriza, S, Jiménez-Hernández, N, Cämmerer, B-M, Rufián-Henares, , Gosalbes, MJ and Francino, MP (2022) Effects of different foods and cooking methods on the gut microbiota: An in vitro approach. Preprint, in review. https://doi.org/10.21203/rs.3.rs-2405776/v1CrossRefGoogle Scholar
Lonnie, M, Hooker, E, Brunstrom, JM, Corfe, BM, Green, MA, Watson, AW, Williams, EA, Stevenson, EJ, Penson, S and Johnstone, AM (2018) Protein for life: Review of optimal protein intake, sustainable dietary sources and the effect on appetite in ageing adults. Nutrients 10(3), Article 3. https://doi.org/10.3390/nu10030360CrossRefGoogle ScholarPubMed
López-Olmedo, N, Stern, D, Bakhtsiyarava, M, Pérez-Ferrer, C and Langellier, B (2022) Greenhouse gas emissions associated with the Mexican diet: Identifying social groups with the largest carbon footprint. Frontiers in Nutrition 9, 791767. https://doi.org/10.3389/fnut.2022.791767CrossRefGoogle ScholarPubMed
Losno, EA, Sieferle, K, Perez-Cueto, FJA and Ritz, C (2021) Vegan diet and the gut microbiota composition in healthy adults. Nutrients 13(7), 2402. https://doi.org/10.3390/nu13072402CrossRefGoogle ScholarPubMed
Macdiarmid, JI (2013) Is a healthy diet an environmentally sustainable diet? Proceedings of the Nutrition Society 72(1), 1320. https://doi.org/10.1017/S0029665112002893CrossRefGoogle ScholarPubMed
Macedo-Ojeda, G, Márquez-Sandoval, F, Fernández-Ballart, J and Vizmanos, B (2016) The reproducibility and relative validity of a Mexican diet quality index (ICDMx) for the assessment of the habitual diet of adults. Nutrients 8(9), 516. https://doi.org/10.3390/nu8090516CrossRefGoogle ScholarPubMed
Macias, A (2015) La Agroindustria del Aguacate en el Sur de Jalisco. Universidad de Guadalajara, México.Google Scholar
Malaeb, S, Bakker, C, Chow, LS and Bantle, AE (2019) High-protein diets for treatment of type 2 diabetes mellitus: A systematic review. Advances in Nutrition 10(4), 621633. https://doi.org/10.1093/advances/nmz002CrossRefGoogle ScholarPubMed
Marcelino, G, Hiane, PA, de Cássia Freitas, K, Santana, LF, Pott, A, Donadon, JR and de Cássia Avellaneda Guimarães, R (2019) Effects of olive oil and its minor components on cardiovascular diseases, inflammation, and gut microbiota. Nutrients 11(8), 1826. https://doi.org/10.3390/nu11081826CrossRefGoogle ScholarPubMed
McCarthy, WJ and Li, Z (2019) Healthy diets and sustainable food systems. Lancet 394(10194), 214. https://doi.org/10.1016/S0140-6736(19)31109-2CrossRefGoogle ScholarPubMed
Mekonnen, MM and Hoekstra, AY (2010) The Green, Blue and Grey Water Footprint of Crops and Derived Crop Products (series no. 47) [Research Report], UNESCO-IHE, Institute for Water Education, p. 42.Google Scholar
Mekonnen, MM and Hoekstra, AY (2012) A global assessment of the water footprint of farm animal products. Ecosystems 15(3), 401415. https://doi.org/10.1007/s10021-011-9517-8CrossRefGoogle Scholar
Melina, V, Craig, W and Levin, S (2016) Position of the academy of nutrition and dietetics: Vegetarian diets. Journal of the Academy of Nutrition and Dietetics 116(12), 19701980. https://doi.org/10.1016/j.jand.2016.09.025CrossRefGoogle Scholar
Meltzer, HM, Brantsæter, AL, Trolle, E, Eneroth, H, Fogelholm, M, Ydersbond, TA and Birgisdottir, BE (2019) Environmental sustainability perspectives of the Nordic diet. Nutrients 11(9), E2248. https://doi.org/10.3390/nu11092248CrossRefGoogle ScholarPubMed
Meslier, V, Laiola, M, Roager, HM, De Filippis, F, Roume, H, Quinquis, B, Giacco, R, Mennella, I, Ferracane, R, Pons, N, Pasolli, E, Rivellese, A, Dragsted, LO, Vitaglione, P, Ehrlich, SD and Ercolini, D (2020) Mediterranean diet intervention in overweight and obese subjects lowers plasma cholesterol and causes changes in the gut microbiome and metabolome independently of energy intake. Gut 69(7), 12581268. https://doi.org/10.1136/gutjnl-2019-320438CrossRefGoogle ScholarPubMed
Mithril, C, Dragsted, LO, Meyer, C, Tetens, I, Biltoft-Jensen, A and Astrup, A (2013) Dietary composition and nutrient content of the new Nordic diet. Public Health Nutrition 16(5), 777785. https://doi.org/10.1017/S1368980012004521CrossRefGoogle ScholarPubMed
Moon, J and Koh, G (2020) Clinical evidence and mechanisms of high-protein diet-induced weight loss. Journal of Obesity & Metabolic Syndrome 29(3), 166173. https://doi.org/10.7570/jomes20028CrossRefGoogle ScholarPubMed
Muralidharan, J, Moreno-Indias, I, Bulló, M, Lopez, JV, Corella, D, Castañer, O, Vidal, J, Atzeni, A, Fernandez-García, JC, Torres-Collado, L, Fernández-Carrión, R, Fito, M, Olbeyra, R, Gomez-Perez, AM, Galiè, S, Bernal-López, MR, Martinez-Gonzalez, MA, Salas-Salvadó, J and Tinahones, FJ (2021) Effect on gut microbiota of a 1-y lifestyle intervention with Mediterranean diet compared with energy-reduced Mediterranean diet and physical activity promotion: PREDIMED-plus study. American Journal of Clinical Nutrition 114(3), 11481158. https://doi.org/10.1093/ajcn/nqab150CrossRefGoogle ScholarPubMed
Neufeld, LM, Hendriks, S and Hugas, M (2021) Healthy diet. A definition for the United Nations food systems summit 2021. Available at https://www.un.org/sites/un2.un.org/files/2020/12/healthy_diet_draft-scientific_group_25-11-2020.pdf. Accessed on 3 July, 2023Google Scholar
Neufeld, LM, Hendriks, S and Hugas, M (2023) Healthy diet: A definition for the United Nations food systems summit 2021. In Von Braun, J, Afsana, K, Fresco, LO and Hassan, MHA (eds), Science and Innovations for Food Systems Transformation. Cham: Springer International Publishing, pp. 2130. https://doi.org/10.1007/978-3-031-15703-5_3.CrossRefGoogle Scholar
Palka, JW (2009) Historical archaeology of indigenous culture change in Mesoamerica. Journal of Archaeological Research 17(4), 297346. https://www.jstor.org/stable/41053266CrossRefGoogle Scholar
Rehner, J, Schmartz, GP, Kramer, T, Keller, V, Keller, A and Becker, SL (2023) The effect of a planetary health diet on the human gut microbiome: A descriptive analysis. Nutrients 15(8), 1924. https://doi.org/10.3390/nu15081924CrossRefGoogle ScholarPubMed
Rinninella, E, Cintoni, M, Raoul, P, Lopetuso, LR, Scaldaferri, F, Pulcini, G, Miggiano, GAD, Gasbarrini, A and Mele, MC (2019) Food components and dietary habits: Keys for a healthy gut microbiota composition. Nutrients 11(10), E2393. https://doi.org/10.3390/nu11102393CrossRefGoogle ScholarPubMed
Rinninella, E, Tohumcu, E, Raoul, P, Fiorani, M, Cintoni, M, Mele, MC, Cammarota, G, Gasbarrini, A and Ianiro, G (2023) The role of diet in shaping human gut microbiota. Best Practice & Research Clinical Gastroenterology 62–63, 101828. https://doi.org/10.1016/j.bpg.2023.101828CrossRefGoogle ScholarPubMed
Roager, HM, Licht, TR, Poulsen, SK, Larsen, TM and Bahl, MI (2014) Microbial enterotypes, inferred by the prevotella-to-bacteroides ratio, remained stable during a 6-month randomized controlled diet intervention with the new nordic diet. Applied and Environmental Microbiology 80(3), 11421149. https://doi.org/10.1128/AEM.03549-13CrossRefGoogle ScholarPubMed
Robinson, JM, Mills, JG and Breed, MF (2018) Walking ecosystems in microbiome-inspired Green infrastructure: An ecological perspective on enhancing personal and planetary health. Challenges 9(2), 2. https://doi.org/10.3390/challe9020040CrossRefGoogle Scholar
Rodríguez Huertas, J, Rodríguez Lara, A, González Acevedo, O, Mesa, MD, Rodríguez Huertas, J, Rodríguez Lara, A, González Acevedo, O and Mesa, MD (2019) Leche y productos lácteos Como vehículos de calcio y vitamina D: Papel de las leches enriquecidas. Nutrición Hospitalaria 36(4), 962973. https://doi.org/10.20960/nh.02570Google Scholar
Rubini, A, Vilaplana-Prieto, C, Flor-Alemany, M, Yeguas-Rosa, L, Hernández-González, M, Félix-García, FJ, Félix-Redondo, FJ and Fernández-Bergés, D (2022) Assessment of the cost of the Mediterranean diet in a low-income region: Adherence and relationship with available incomes. BMC Public Health 22(1), 58. https://doi.org/10.1186/s12889-021-12433-wCrossRefGoogle Scholar
Scarborough, P, Appleby, PN, Mizdrak, A, Briggs, ADM, Travis, RC, Bradbury, KE and Key, TJ (2014) Dietary greenhouse gas emissions of meat-eaters, fish-eaters, vegetarians and vegans in the UK. Climatic Change 125(2), 179192. https://doi.org/10.1007/s10584-014-1169-1CrossRefGoogle ScholarPubMed
Scher, JU, Sczesnak, A, Longman, RS, Segata, N, Ubeda, C, Bielski, C, Rostron, T, Cerundolo, V, Pamer, EG, Abramson, SB, Huttenhower, C and Littman, DR (2013) Expansion of intestinal Prevotella copri correlates with enhanced susceptibility to arthritis. eLife 2, e01202. https://doi.org/10.7554/eLife.01202CrossRefGoogle ScholarPubMed
Senghor, B, Sokhna, C, Ruimy, R and Lagier, J-C (2018) Gut microbiota diversity according to dietary habits and geographical provenance. Human Microbiome Journal 7–8, 19. https://doi.org/10.1016/j.humic.2018.01.001CrossRefGoogle Scholar
Serra-Majem, L, Tomaino, L, Dernini, S, Berry, EM, Lairon, D, Ngo de la Cruz, J, Bach-Faig, A, Donini, LM, Medina, F-X, Belahsen, R, Piscopo, S, Capone, R, Aranceta-Bartrina, J, La Vecchia, C and Trichopoulou, A (2020) Updating the Mediterranean diet pyramid towards sustainability: Focus on environmental concerns. International Journal of Environmental Research and Public Health 17(23), 8758. https://doi.org/10.3390/ijerph17238758CrossRefGoogle ScholarPubMed
Shanahan, F, Ghosh, TS and O’Toole, PW (2021) The healthy microbiome—What is the definition of a healthy gut microbiome? Gastroenterology 160(2), 483494. https://doi.org/10.1053/j.gastro.2020.09.057CrossRefGoogle ScholarPubMed
Shetty, SA, Stege, PB, Hordijk, J, Gijsbers, E, Dierikx, CM, van Duijkeren, E, Franz, E, Willems, RJL, Paganelli, FL and Fuentes, S (2022) Species-specific patterns of gut metabolic modules in Dutch individuals with different dietary habits. MSphere 7(6), e0051222. https://doi.org/10.1128/msphere.00512-22CrossRefGoogle ScholarPubMed
Sidhu, SRK, Kok, CW, Kunasegaran, T and Ramadas, A (2023) Effect of plant-based diets on gut microbiota: A systematic review of interventional studies. Nutrients 15(6), 1510. https://doi.org/10.3390/nu15061510CrossRefGoogle ScholarPubMed
Świątecka, D, Narbad, A, Ridgway, KP and Kostyra, H (2011) The study on the impact of glycated pea proteins on human intestinal bacteria. International Journal of Food Microbiology 145(1), 267272. https://doi.org/10.1016/j.ijfoodmicro.2011.01.002Google Scholar
Thompson, SV, Bailey, MA, Taylor, AM, Kaczmarek, JL, Mysonhimer, AR, Edwards, CG, Reeser, GE, Burd, NA, Khan, NA, & Holscher, HD. (2021). Avocado Consumption Alters Gastrointestinal Bacteria Abundance and Microbial Metabolite Concentrations among Adults with Overweight or Obesity: A Randomized Controlled Trial. The Journal of Nutrition, 151(4), 753762. https://doi.org/10.1093/jn/nxaa219CrossRefGoogle ScholarPubMed
Tierney, BT, Yang, Z, Luber, JM, Beaudin, M, Wibowo, MC, Baek, C, Mehlenbacher, E, Patel, CJ and Kostic, AD (2019) The landscape of genetic content in the gut and Oral human microbiome. Cell Host & Microbe 26(2), 283295, e8. https://doi.org/10.1016/j.chom.2019.07.008CrossRefGoogle ScholarPubMed
Trefflich, I, Jabakhanji, A, Menzel, J, Blaut, M, Michalsen, A, Lampen, A, Abraham, K and Weikert, C (2020a) Is a vegan or a vegetarian diet associated with the microbiota composition in the gut? Results of a new cross-sectional study and systematic review. Critical Reviews in Food Science and Nutrition 60(17), 29903004. https://doi.org/10.1080/10408398.2019.1676697CrossRefGoogle ScholarPubMed
Valerino-Perea, S, Lara-Castor, L, Armstrong, MEG and Papadaki, A (2019) Definition of the traditional Mexican diet and its role in health: A systematic review. Nutrients 11(11), 11. https://doi.org/10.3390/nu11112803CrossRefGoogle ScholarPubMed
van Hooijdonk, T and Hettinga, K (2015) Dairy in a sustainable diet: A question of balance. Nutrition Reviews 73(Suppl 1), 4854. https://doi.org/10.1093/nutrit/nuv040CrossRefGoogle Scholar
Vanegas, SM, Meydani, M, Barnett, JB, Goldin, B, Kane, A, Rasmussen, H, Brown, C, Vangay, P, Knights, D, Jonnalagadda, S, Koecher, K, Karl, JP, Thomas, M, Dolnikowski, G, Li, L, Saltzman, E, Wu, D and Meydani, SN (2017) Substituting whole grains for refined grains in a 6-wk randomized trial has a modest effect on gut microbiota and immune and inflammatory markers of healthy adults. American Journal of Clinical Nutrition 105(3), 635650. https://doi.org/10.3945/ajcn.116.146928CrossRefGoogle Scholar
Verkerk, R (2019) EAT-lancet – Is there such a thing as ‘one- size-fits-all’ sustainability? Journal of Holistic Healthcare 16(3), 1522Google Scholar
Vijay, A and Valdes, AM (2022) Role of the gut microbiome in chronic diseases: A narrative review. European Journal of Clinical Nutrition 76(4), 4. https://doi.org/10.1038/s41430-021-00991-6CrossRefGoogle ScholarPubMed
Vos, M, Deforche, B, Van Kerckhove, A, Michels, N, Geuens, M and Van Lippevelde, W (2022) Intervention strategies to promote healthy and sustainable food choices among parents with lower and higher socioeconomic status. BMC Public Health 22(1), 2378. https://doi.org/10.1186/s12889-022-14817-yCrossRefGoogle ScholarPubMed
Willett, W, Rockström, J, Loken, B, Springmann, M, Lang, T, Vermeulen, S, Garnett, T, Tilman, D, DeClerck, F, Wood, A, Jonell, M, Clark, M, Gordon, LJ, Fanzo, J, Hawkes, C, Zurayk, R, Rivera, JA, Vries, WD, Sibanda, LM and Murray, CJL (2019) Food in the Anthropocene: The EAT–lancet commission on healthy diets from sustainable food systems. Lancet 393(10170), 447492. https://doi.org/10.1016/S0140-6736(18)31788-4CrossRefGoogle ScholarPubMed
Wozniak, H, Larpin, C, de Mestral, C, Guessous, I, Reny, J-L and Stringhini, S (2020) Vegetarian, pescatarian and flexitarian diets: Sociodemographic determinants and association with cardiovascular risk factors in a Swiss urban population. British Journal of Nutrition 124(8), 844852. https://doi.org/10.1017/S0007114520001762CrossRefGoogle Scholar
Wu, Y-T, Shen, S-J, Liao, K-F and Huang, C-Y (2022) Dietary plant and animal protein sources oppositely modulate fecal Bilophila and Lachnoclostridium in vegetarians and omnivores. Microbiology Spectrum 10(2), e02047. https://doi.org/10.1128/spectrum.02047-21Google ScholarPubMed