Introduction
Early nutrition studies on twins and multi-fetal pregnancies focused on the side effects of the pregnancy, achieving adequate maternal nutrition during gestation, and on the implications for the health of the growing fetuses( Reference Brown and Carlson 1 ). The womb, however, is a solitary internal environment, where nutritional parameters can be measured with more ease. Once twins enter the world, where a myriad of external environmental influences on different phenotypes can be assessed, twins provide us with the unique ability to accurately determine heritability of certain complex traits, such as dietary phenotypes. In this context, dietary phenotypes broadly refer to the observable and measurable foods, and their constituents, consumed by individuals or groups. Indeed, twin studies have proven that genetic makeup plays a significant role in dietary intakes( Reference Rankinen and Bouchard 2 ). Moreover, twins have the advantage of limiting inter-individual variability as they are raised in a similar environment and have matched age, genes and sex (for monozygotic (MZ) pairs). They therefore represent a natural matched case–control experiment.
Omics technologies allow for a systems approach to nutrition research that encompasses the primary level of DNA sequence (genomics), gene expression (transcriptomics) and epigenome, to the intermediate phenotypes (proteome, metabolome and microbiome), finally to clinical endpoints( Reference Kussmann, Raymond and Affolter 3 ). Food constituents may influence each of these areas, but their effect is difficult to ascertain due to imprecise dietary assessment methods. Omics techniques will help ameliorate this issue, through food intake biomarker discovery largely within the intermediate phenotypes, primarily the metabolome( Reference Zivkovic and German 4 ). Once biomarkers of intake have been validated, in conjunction with currently utilised intake and known biomarker measures, reliable associations between genomic and transcriptomic data can be made. This will allow for identification of groups susceptible to detrimental dietary patterns, gene–diet interactions and diet–disease associations, which combined will conjure an accurate depiction of a ‘healthy’ phenotype( Reference Kussmann, Raymond and Affolter 3 ).
In the present review, we first discuss the usage of twins for generating heritability estimates of food intake phenotypes, including energy and macronutrient intakes, dietary patterns and specific food group intakes. We then highlight the value of discordant MZ pairs, for furthering nutrition research through discovery and validation of biomarkers of intake and health status in conjunction with cutting-edge omics technologies.
Heritability of food intake phenotypes: the usage of twins for heritability estimates of intakes
The classic twin design allows for a natural experiment that exploits the difference in genetic relatedness between MZ and dizygotic (DZ) twins to estimate the degree to which phenotypic variability, such as food or nutrient intake, is explained by genetic and environmental factors. Heritability is defined as the degree of total phenotypic variance due to genetic variation and is relevant only to groups or populations and not at the individual level( Reference Visscher, Hill and Wray 5 ).
Heritability of energy and macronutrient intakes
Accurate assessments of the genetic influence on energy intakes are crucial as these provide a baseline assessment for which genes influence total food intakes( Reference de Castro 6 ), therefore justifying genotype-specific dietary intervention strategies. Furthermore, the degree to which macronutrient intakes are genetically determined may have significant implications for the suspected role of elevated intakes of energy-dense foods (i.e. those containing high concentrations of fat and refined carbohydrates) to the obesity epidemic( Reference Guyenet and Schwartz 7 ). Therefore, multiple twin studies have evaluated these components through various dietary assessment methods (Fig. 1(a); online Supplementary Table S1).
Studies of different size and quality have estimated heritability of different energy and macronutrient intakes to lie between 8 and 70 %( Reference de Castro 6 , Reference Liu, Tuvblad and Raine 8 – Reference Hur, Bouchard and Eckert 14 ). Beginning from a young age, infant twins have demonstrated that the genetic component provides a small, albeit significant, effect on energy and macronutrient intakes (8 to 12 %)( Reference Pimpin, Ambrosini and Llewellyn 9 ). As children age and they become less dependent on their parents, the genetic effect on energy and macronutrient intakes appears to intensify, as suggested by findings in 11- to 13-year-old US twins (31 to 48 %)( Reference Liu, Tuvblad and Raine 8 ). This pattern is similar to other health-related phenotypes, including BMI( Reference Dubois, Ohm Kyvik and Girard 15 ), which has been recently confirmed through a more complex longitudinal genome-wide complex trait analysis for determining DNA-based heritability( Reference Llewellyn, Trzaskowski and Plomin 16 ). Heritability of dietary energy and macronutrients in adults has been found to vary widely: for energy (32 to 65 %); for fats (35 to 53 %); carbohydrates (25 to 67 %); and proteins (28 to 70 %)( Reference de Castro 6 , Reference Wade, Milner and Krondl 11 , Reference Hasselbalch, Heitmann and Kyvik 12 , Reference Hur, Bouchard and Eckert 14 ). Most recently, an extensive study of adult Danish twins demonstrated inheritance of energy and energy-adjusted macronutrient intakes to range from 28 to 55 %( Reference Hasselbalch, Heitmann and Kyvik 12 ). Although genetic effects on macronutrient intakes were more substantial in men (49 to 55 %) than women (28 to 36 %), they were not different between macronutrients. In support of this, two other twin studies suggested the same genetic mechanisms governing energy intakes( Reference Guyenet and Schwartz 7 ) influence macronutrient intakes( Reference de Castro 17 , Reference Faith, Rha and Neale 18 ).
The lack of evidence to date for independent sets of genes influencing macronutrient intakes from those genes governing energy intakes has focused attention on whether dietary energy density is genetically determined, with one study suggesting substantial genetic influence( Reference de Castro 19 ), and another not( Reference Hasselbalch, Heitmann and Kyvik 12 ). Despite this, in the latter Danish study, factors related to dietary energy density, including fibre, glycaemic index and the glycaemic load, were found to be significantly heritable both in women (49, 36 and 33 %, respectively) and men (41, 30 and 25 %, respectively). The dependence of these phenotypes on the constituents of the whole diet suggests that genetic effects on these phenotypes may be reflective of variable dietary patterns.
Heritability of dietary patterns
Dietary patterns are identified by two primary methods: empirically derived or a priori ( Reference Hu 20 ). Empirically derived dietary patterns employ statistical methods to identify natural groupings of intakes of food items (for example, principal component analysis or cluster analysis( Reference Hu 20 )). A priori dietary patterns are generated based on adherence to diet parameters previously associated with health outcomes or physiological states, such as the Mediterranean diet score. A key advantage to using dietary patterns is the translatable results that encompass the degree to which genetics influence the global diet.
Two twin studies on children using empirically derived dietary patterns generated highly inconsistent heritability estimates despite reasonable sample size (online Supplementary Table S2)( Reference Breen, Plomin and Wardle 21 , Reference Faith, Rhea and Corley 22 ). In a study of US 7-year-olds (n 792) heritability estimates of food pattern intakes obtained by 24 h recalls were stronger in boys than girls, ranging from 12 to 79 % and 20 to 56 %, respectively( Reference Faith, Rhea and Corley 22 ). In another study of 4- to 5-year-old UK twin pairs (n 214) heritability of food preference was measured through the use of a modified ninety-five-item ‘liking’ FFQ administered to parents( Reference Breen, Plomin and Wardle 21 ). Heritability ranged from 20 % (desserts) to 78 % (meat and fish) on food liking–disliking groups. It is difficult to make valid comparisons between these two studies as the dietary assessment methods used measure different outcomes (i.e. intakes v. liking), although it has been found that exposure to foods generally encourages liking and intakes in children( Reference Wardle, Sanderson and Gibson 23 ). This suggests that environmental influences may override genetic predispositions to food pattern intakes in children, which has implications for combating food neophobia, a highly heritable and perhaps evolutionarily important trait( Reference Cooke, Haworth and Wardle 24 ).
Contrary to studies in children, studies in adults have generated relatively stable heritability estimates for food pattern intakes across patterns and sexes. ‘Healthy’ dietary patterns, characterised by high intakes of vegetables, fruits and whole grains and low intakes of fatty foods of animal origin and simple carbohydrates, have heritability estimates ranging from 33 to 54 %, while ‘unhealthy’ patterns ranged from 33 to 50 % (online Supplementary Table S2)( Reference van den Berg, Henneman and Willems van Dijk 25 – Reference van den Bree, Eaves and Dwyer 29 ). Furthermore, a study which utilised a twins-of-mistaken-zygosity approach (a useful method to control for potential equal environmental assumption bias( Reference Scarr 30 )) in US female twins (n 700) found additive genetic effects to account for 50 % of the variability in healthy pattern intakes, while an unhealthy diet pattern was not significantly heritable( Reference Gunderson, Tsai and Selby 28 ). A healthy diet is more phenotypically similar to diets that man has consumed through millennia and evolved with; it is only very recently that high-energy-dense foods have been readily available, and as such it makes sense that the variation in this diet may be more genetically influenced in some groups( Reference Breslin 31 ). One study conducted on an older age group ( ≥ 50 years) determined additive genetic effects to account for 33 % of the variability of consumption frequency for both healthy and unhealthy patterns( Reference van den Bree, Eaves and Dwyer 29 ).
Individual foods and food group heritabilities
A number of recent studies have estimated the genetic effect of food and beverage intakes in human subjects (Figs. 1(b) and 1(c); online Supplementary Tables S3 and S4), generating wide-ranging heritability estimates across food groups, particularly for children( Reference Pimpin, Ambrosini and Llewellyn 9 , Reference Fildes, van Jaarsveld and Llewellyn 32 ). Findings from the UK Gemini cohort of infants and children aged 21 months to 3 years have demonstrated that age effects on heritability of food group intakes are evident even in the early years( Reference Pimpin, Ambrosini and Llewellyn 9 , Reference Fildes, van Jaarsveld and Llewellyn 32 ). Intakes for 21-month-old children were minimally heritable for food groups ranging from 9 % (potatoes) to 17 % (dairy products). However, preference for food groups was highly heritable in 3-year-old children, ranging from 27 % (dairy products) to 54 % (vegetables). It should be noted that heritability estimates in the older children were calculated from age- and sex-adjusted residuals, an approach which may have prevented inflation of shared environmental effects( Reference McGue and Bouchard 33 ). The study on infants did not use this approach, perhaps resulting in an underestimation of the genetic effects on food group intakes.
Recent studies in adults have also confirmed that there is a genetic component to many food type intakes. Danish twins demonstrated a large degree of variation in calculated heritabilities overall ranging from 17 % (fish) to 68 % (potatoes) in men, and 20 % (whole-grain cereal) to 61 % (fish) in women( Reference Hasselbalch, Heitmann and Kyvik 12 ). Similar results were seen in UK female twins where heritabilities ranged from 8 % (refined grains) to 46 % (garlic)( Reference Teucher, Skinner and Skidmore 27 ). Furthermore, the grouping of fruit and vegetable sources generated the highest heritability estimate in this cohort (49 %). These authors proposed that taste perception may be a key driver of the predicted genetic influence, as foods characterised by strong tastes are the cornerstone of these groups. This observation extends to consistently substantial heritabilities for coffee as well as alcohol intakes, ranging from 29 to 73% and 28 to 82%, respectively( Reference Hasselbalch, Heitmann and Kyvik 12 , Reference Hur, Bouchard and Eckert 14 , Reference Teucher, Skinner and Skidmore 27 , Reference de Castro 34 ). However, the pharmacological properties of both must be considered as alcohol dependence, as well as caffeine consumption-related traits, are both highly heritable (30 to 70 %, and 36 to 58 %, respectively)( Reference Agrawal and Lynskey 35 , Reference Yang, Palmer and de Wit 36 ) and may drive intakes up in a way independent of taste preference or a biological requirement for these items.
Taste is the strongest determinant of food choices( Reference Feeney, O'Brien and Scannell 37 ), and a recent twin study demonstrated multiple chemosensory facets of numerous food compounds to be highly heritable and associated with particular gene variants( Reference Knaapila, Hwang and Lysenko 38 ). Although an investigation of this area is beyond the scope of the present review, future heritability studies of food intakes may shift the focus to food groupings characterised by specific tastes.
Nutritional phenotype heritability conclusion
In summary, twin studies have demonstrated food and macronutrient intakes to be genetically determined. However, heritability estimates are often inconsistent between studies for multiple reasons. First, heritability is only specific to the population studied, which can vary greatly, due to the vast country-specific food environments. Indeed, if a food is not readily available in a population there is no capacity for intakes to be genetically determined. Second, although beyond the scope of the present review, important evidence is available for familial and community influence on food intake (such as parenting styles, food exposures, socio-economic status), which have an important place for battling current issues, such as childhood obesity( Reference Berge 39 ) and food neophobia( Reference Anzman-Frasca, Savage and Marini 40 ), and diabetes( Reference Pollard, Zachary and Wingert 41 ). Finally, methods for determining heritability are not standardised, for instance the inclusion/exclusion of variables from the model (for example, age, country), the segregation/aggregation of sexes, and the different methods for obtaining and analysing dietary data tend to be unique for each study. The same genetic mechanisms governing energy intakes are suspected to influence macronutrient intakes. However, recent studies have assessed the impact of gene variants encoding proteins related to the complex energy intake regulatory systems under central nervous system control( Reference Guyenet and Schwartz 7 ) on preference for macronutrient types. These studies are few on twins( Reference Hasselbalch, Angquist and Christiansen 42 , Reference Bouchard-Mercier, Paradis and Perusse 43 ). Heritability estimates are more limited for macronutrient subtype intakes (for example, the fatty acid profile( Reference Heller, O'Connell and Roberts 10 , Reference Hur, Bouchard and Eckert 14 )), different age groups or changing physiological states (for example, pregnancy), and socially driven diets (for example, veganism). Macronutrient profiles do not account entirely for food pattern preferences that may be more determined by genetic makeup. Variation in diet patterns of adults is to a relatively high degree attributable to genetics( Reference van den Berg, Henneman and Willems van Dijk 25 – Reference van den Bree, Eaves and Dwyer 29 ). Furthermore, specific food-type intakes that characterise a healthy diet pattern tend to be highly heritable in adults and in turn consist of foods that elicit distinctive taste responses (for example, garlic, fruit and vegetables)( Reference Teucher, Skinner and Skidmore 27 ).
The substantial heritability of multiple dietary phenotypes supports the concept of personalised dietary recommendations, the generation of which has so far primarily relied on the exploration of an individual's genetic makeup. However, on a molecular level, the search for genotypes predisposing individuals to particular dietary intakes is very much in its infancy. Nonetheless, the evidence generated by twin heritability studies can lead scientists to dietary phenotypes that are consistently highly heritable and demand further exploration through genome-wide association and candidate gene studies, following which twins can aid the determination of the heritable contribution of specific SNP to the dietary phenotype (as used previously for human height( Reference Yang, Benyamin and McEvoy 44 )).
A key issue that has long plagued nutrigenetic research arises from the inaccuracies of self-reported diet intake and food preference data and, as a result, the hunt for dietary biomarkers, objective measures of dietary intakes and nutritional status, has been hastened. These may allow for more accurate heritability calculations for food and nutrient intakes as has recently been demonstrated for salt intakes using urinary Na excretion, an established, valid biomarker of salt intake( Reference Kho, Lee and Song 45 ), and could potentially be used in genetic association studies. However, the usage of biomarkers is not confined to genetic studies. It is becoming increasingly clear that for the establishment and refinement of personalised nutrition, in combination with genetic information, a whole organism, multi-systems approach must be undertaken, where the usage of biomarkers of food intakes and nutritional status will be essential. Nutrition research is now embarking on a nutriomics era, where emerging high-throughput omics technologies will substantially aid biomarker discovery and ‘healthy phenotype’ definition. As will be explored next, twin studies are progressively taking steps to make a major contribution in this way.
The importance of twins for emerging nutriomic research
This next section will explore how diet makes an impact on genes themselves (epigenetics), gene expression (transcriptomics), protein expression (proteomics) and metabolism (metabolomics). Integrating these technologies to determine a ‘healthy’ phenotype is the long-term goal of personalised nutrition( Reference van Ommen and Stierum 46 ). A reoccurring issue with this type of analysis is the high degree of inter-individual variation, making associations often inconsistent( Reference Kussmann, Raymond and Affolter 3 ). As such, the usage of identical twins discordant for dietary factors or objective measures of nutrition status, matched entirely for age, sex, genetics and partially for early environmental influences, will provide an enhanced method of assessing diet and biological relationships.
Obesity, the greatest and fastest-growing health concern in the world at this time, is a highly genetic disorder, influenced by myriad complex factors( Reference Després, Moorjani and Lupien 47 ). However, rare obese discordant identical twin pairs provide a unique opportunity to disentangle lifestyle and environmental factors on the human system derangements induced by energy imbalance independently of genetics.
Nutrimetabolomics
Nutritional metabolomics involves the extensive chemical profiling of various tissues completed in a global manner through targeted and untargeted methods used as a complement to diet- and health-related complex systems approaches. The metabolome gives unique information into the metabolic status of an individual by providing a snapshot of the metabolic processes undertaken in a bodily system, specific organ, tissue or cell, which cannot be identified through measuring gene expression or the proteome. Nutrition and the metabolome are intimately linked in that nutrients and non-nutrient food constituents supply metabolites; however, these contributions make the dietary influence on the metabolome all the more difficult to ascertain( Reference Gibney, Walsh and Brennan 48 ). Despite this, dietary pattern and food intakes generated through self-reported intake data have identified novel biomarkers within the metabolome( Reference O'Sullivan, Gibney and Brennan 49 – Reference Guertin, Moore and Sampson 51 ), validating this approach for use in epidemiological studies. However, the genetic influence on metabolite levels is wide-ranging( Reference Suhre, Shin and Petersen 52 ), therefore novel usage of the twin model provides an ideal method for determining the nutritional impact on metabolites, through segregating the non-genetic component. Recently, a nutri-metabolomic study conducted on twins further confirmed self-reported intake associations with metabolites( Reference Menni, Zhai and Macgregor 53 ). Female UK twins completed a 131-item FFQ that generated dietary constituents and intake patterns that were found to associate with forty-two metabolite levels in the larger twin population. MZ twins discordant for dietary intakes were then identified and utilised to replicate results, confirming the utility of this method( Reference Zivkovic and German 4 ).
Lipidomics, a branch of metabolomics, was used to characterise environmental and lifestyle-induced changes to the global serum lipid profile in fourteen healthy, young MZ obesity-discordant twin pairs( Reference Pietilainen, Sysi-Aho and Rissanen 54 ). Levels of lysophosphatidylcholines, lipids associated with inflammation( Reference Yang, Radu and Wang 55 ) and atherogenesis( Reference Glass and Witztum 56 ), were found to be elevated in obese co-twins, with concommitant decreases in antioxidant( Reference Wallner and Schmitz 57 ) ether phospholipids. Moreover, despite the young ages of the obese co-twins (24 to 27 years), these lipid profile changes were associated with insulin resistance.
The metabolome is highly complex and inter-individual variation is high for a multitude of reasons( Reference Zulyniak and Mutch 58 ), thus factoring solely nutritional intake into nutrimetabolomic studies is problematic and the relative importance of blood and urine levels is unclear. For instance, the gut microbiota has been determined to account for 10 % of the variability in the plasma metabolome in rodents( Reference Wikoff, Anfora and Liu 59 ). Although estimates for humans are unknown at this time, regional variation in human metabolomic profiles has been attributed in part to gut microbes( Reference Nicholson, Holmes and Kinross 60 ). In turn, the gut microbiota carry out processes in the digestion and handling of nutrients, some of which are essential for optimal nutrition, before entering the host metabolome( Reference Nicholson, Holmes and Kinross 60 ). Emerging methods for direct measurement of the intestinal metabolome will help to unravel effects of the microbiome on the host metabolome( Reference Ursell, Haiser and Van Treuren 61 ).
Microbiome
The human gut microbiome is estimated to contain hundreds of bacterial species, with upwards of 536000 bacterial genes among them( Reference Qin, Li and Raes 62 ). For years, dietary constituents, such as pre- and probiotics, have been consumed for their proposed health benefits postulated to be through modulation of the gut microbial population( Reference Collins and Gibson 63 ). More recently, vegetarian and omnivorian dietary patterns have been associated with differential gut microbial species in a Slovenian population study( Reference Matijašić, Obermajer and Lipoglavšek 64 ). In a recent study, twins discordant for obesity have demonstrated significantly different gut microbial species composition( Reference Tims, Derom and Jonkers 65 ). Lower BMI was associated with increased primary fibre degraders, while higher BMI subjects displayed an abundant network of butyrate producers; as such it was suggested that a shift in fermentation patterns near the end of the colon may be influencing energy homeostasis, although this study neglected to investigate the dietary impact on the microbial species population.
A recent analysis on Finnish MZ twin pairs concordant (n 9) and discordant (n 11) for BMI found dietary energy intakes and constituents to be more influential on microbial populations than BMI group( Reference Simoes, Maukonen and Kaprio 66 ). Specifically, stool bacterial counts were significantly influenced by intakes of energy, MUFA and n-3 and n-6 PUFA, and soluble fibre intakes. Furthermore, profiles of Bacteroides spp. were very similar in co-twins consuming the same amount of energy or saturated fats than twins discordant for intakes. These findings suggest that the obesity status per se is less influential on microbial species population and, rather, it is the content of the diet (i.e. high energy and fat) mediating important changes, highlighting the essential need to incorporate dietary variables into obesity research. The role of host genetics on the microbiome composition is still unclear and larger studies (which are ongoing) are needed to provide clarity( Reference Turnbaugh and Gordon 67 ).
Recent findings suggest that the microbial species signature has the potential to promote and aggravate an obesity phenotype and may interact synergistically through diet × microbiota interactions. In a unique study, transplantation of faecal samples from US female lean and obese co-twins (three dizygotic; one MZ) into germ-free mice revealed that the obese (Ob mice) compared with lean (Ln mice) co-twin's microbiota significantly increased adiposity and metabolic derangements in mice( Reference Ridaura, Faith and Rey 68 ). When co-housed with Ln mice, Ob mice adiposity and metabolic effects were reduced, suspected to be a result of Bacteroidetes translocation from Ln to Ob mice. When fed a diet based on the lower tertile of saturated fats and upper tertile of fruits and vegetables of the US National Health and Nutrition Examination Survey (NHANES), Ob mice adiposity was sustained, but relieved when co-housed with Ln mice. Moreover, when compared with co-housing with normal chow, the healthier diet aided the success of Ln to Ob mice bacterial invasion. When supplied with an unhealthy diet containing the upper tertile of saturated fats with the lower tertile of fruits and vegetables from the NHANES survey, both Ln and Ob mice presented with significantly increased adiposity, mitigating transmissible effects. These results show the potentially causal role of the microbiome composition and potential for its manipulation.
Epigenetics
Epigenetic variation is another source of phenotypic variation and discordance in twins( Reference Bell and Spector 69 ). Epigenetics involves the changes to marks on the genome that are copied from one cell generation to the next, which may alter gene expression, but does not involve modifications of the DNA sequence. Three specific, albeit inter-related, epigenetic mechanisms that control the magnitude and timing of gene expression during cellular differentiation and fetal development, as well as throughout life, are possibly modified by dietary factors (for a summary, see Canani et al. ( Reference Canani, Costanzo and Leone 70 )). These include DNA methylation, histone modifications and non-coding microRNA( Reference McKay and Mathers 71 , Reference Zeisel 72 ). However, the bulk of the evidence for these mechanisms originates from animal studies.
Identical twins display large epigenetic differences at birth( Reference Loke, Novakovic and Ollikainen 73 ). On diet, numerous studies have emerged focusing on the developmental origins of adult disease (Barker) hypothesis( Reference de Boo and Harding 74 ). This involves the influence of detrimental maternal nutrition, and other lifestyle factors, contributing to intra-uterine growth retardation, and subsequent premature birth and/or low birth weight. This flawed in utero environment may activate fetal epigenetic events, inducing long-term changes in expression of genes encoding proteins responsible for metabolic processes, potentially leading to chronic diseases in adulthood. Data are still accumulating on the extent of this effect, and no good longitudinal studies yet exist. An early study found young MZ twins to be more epigenetically alike than adult twin pairs, and this distinction extended to gene expression profiles( Reference Fraga, Ballestar and Paz 75 ). In addition, twin birth weight has been found to be less influential on adult body adiposity than an obesogenic postnatal environment( Reference Skidmore, Cassidy and Swaminathan 76 ). This suggests that environmental and genetic events throughout life, not only during the early years, influence the epigenome and gene expression.
Recently, an MZ twin candidate gene study demonstrated that SLC6A4 promoter, a serotonin transporter gene, hypermethylation in blood leucocytes was significantly associated with increased adiposity measures including BMI, body weight and waist circumference( Reference Zhao, Goldberg and Vaccarino 77 ). Interestingly, although causality could not be determined, the serotonergic system is involved in the complex energy-regulatory processes governing energy intakes. A lone study on epigenetic differences in MZ twin pairs discordant for BMI (n 16) found no significant differences in gene methylation at differentially methylated regions most associated with abnormal growth syndromes, many characterised by severe obesity( Reference Souren, Tierling and Fryns 78 ). However, only DNA extracted from saliva samples was used for this study and recent findings suggest that DNA methylation is tissue specific( Reference Lokk, Modhukur and Rajashekar 79 ); therefore analysis of different tissues may provide contrasting findings. New high-throughput epigenome sequencing in connection with BMI has recently provided promising findings( Reference Dick, Nelson and Tsaprouni 80 ), in conjuction with transcriptomics; this may provide more definitive answers as coverage so far has been poor( Reference Dick, Nelson and Tsaprouni 80 ).
Transcriptomics
The purposes of transcriptomics for nutrition research include the provision of biologically relevant mechanisms for effects of particular nutrients or diet patterns, confirming alterations in genes, proteins or metabolites in pre-disease state which may serve as biomarkers, and, finally, identifying and elucidating nutrient-regulated pathways( Reference Müller and Kersten 81 ). With these purposes in mind, the use of twins with their shared genetic background can add significant strength to transcriptomic studies. Despite this, twin studies have to date largely focused on defining gene expression phenotypes related to metabolic derangements, particularly those related to obesity.
An analysis of global gene expression patterns in the adipose tissue of obesity-discordant MZ twin pairs has demonstrated marked changes induced by acquired obesity( Reference Pietilainen, Naukkarinen and Rissanen 82 ), such as a reduction in mitochondrial DNA copy number, which may impair oxidative phosphorylation. Additionally, a significant down-regulation of mitochondrial branched-chain amino acid catabolism, a process commonly activated during adipocyte differentiation in conjunction with PPARγ and metabolites of oxidative energy processes, has been observed( Reference Hackl, Burkard and Sturn 83 ). These derangements of energy metabolism in adipose tissue were associated with liver fat accumulation, insulin resistance and hyperinsulinaemia in obese co-twins, providing significant evidence for the influence of lifestyle to obesity-related metabolic derangements. A limited analysis of dietary intake demonstrated that lower amounts of MUFA and PUFA were consumed by obese co-twins. This could be of interest, as unsaturated fatty acids are potent activators of PPARα and PPARγ by acting as nuclear transcription factors( Reference Keller, Dreyer and Medin 84 ). Pathways involved in inflammatory and immune responses were highly overexpressed in adipose tissue in the former twin study, particularly the pro-inflammatory cytokine osteopontin( Reference Daniele, Guardado Mendoza and Winnier 85 ).
Proteomics
Proteomics remains the most complex challenge to omic studies, due to the expanse of the human protein expression profile and to the uncertainty of how many proteins exist. For perspective, the human genome includes greater than 25 000 genes( Reference Lander, Linton and Birren 86 ), while the human proteome includes at least 100 000 proteins, compounded by various forms and variants( Reference Kussmann, Affolter and Fay 87 ). To date, few proteomic studies have been conducted on twins. One study quantified serum protein levels by antibody arrays and determined variation attributable to familial factors to be minimal (12 %), while experimental variation was quite large (63 %), accentuating the importance of considering the latter when designing and evaluating studies for biomarker discoveries utilising high-throughput methods( Reference Kato, Nicholson and Neiman 88 ). To date, no twin or obese co-twin studies have incorporated dietary factors using these methods. Whereas global protein expression levels are available, protein structure and function studies are far from being understood, yet have huge future potential( Reference Kussmann, Raymond and Affolter 3 ).
Conclusion
The interconnectedness between each omic presented in this review is evident. A systems biological approach that incorporates multiple omics methods for phenotype definition for use in nutriomic studies is much needed( Reference Norheim, Gjelstad and Hjorth 89 ). The principle central to this approach is that the whole organism will provide a more accurate view than the sum of its parts, or, rather, the entire system has definitive characteristics which will not be replicated by simply adding the effects( Reference MacLellan, Wang and Lusis 90 ). However, a primary setback for amalgamating these methods is the inability to define what is ‘normal’ due to the significant inter-individual variability underlying metabolic processes( Reference Kussmann, Raymond and Affolter 3 ). Furthermore, it has been suggested that many omics vary relatively little over time within individuals but significantly between individuals compounded by factors such as age, BMI and sex( Reference Eady, Wortley and Wormstone 91 ). To aid in discerning these effects, longitudinal phenotypic information from twin registries will be a critical resource for molecular dietary studies of the future( Reference van Dongen, Slagboom and Draisma 92 ). The studies presented in this review fall short of this view of an integrated technology-driven approach and focus rather on omics in isolation, as this is where the current research stands. To move forward twin cohorts need to make a collaborative effort, collecting extensive dietary data in conjunction with multiple omics, undertaking complex statistical analyses, while contributing findings to international proposed databases such as the Nutritional Phenotype database( Reference van Ommen, Bouwman and Dragsted 93 ).
Identifying individuals susceptible to poor dietary habits and defining an (un)healthy phenotype are the overarching aims of nutrigenetic and nutrigenomic research. Twins have provided valuable evidence that many dietary intakes are influenced by genetics, validating further nutrigenetic research and future dietary counselling which targets this domain. Early studies of twins for nutriomic studies have primarily been for unhealthy phenotype definition and used a single omic, while being less inclusive of diet. However, future studies need to begin to incorporate dietary factors to fill a void in this research area. However, accurate dietary assessment methods are problematic( Reference Tucker, Smith and Lai 94 ). As twins have demonstrated, metabolites are significantly correlated with dietary constituents, and could in the future be used as surrogates, as well as other techniques (for example, the microbiome)( Reference Lloyd, Beckmann and Haldar 95 , Reference Vernocchi, Vannini and Gottardi 96 ). Twin studies will remain an important and integral part of nutritional research now and in the future.
Acknowledgements
Twins UK was funded by the Wellcome Trust; European Community's Seventh Framework Programme (FP7/2007-2013). The study also receives support from the National Institute for Health Research (NIHR) BioResource Clinical Research Facility and Biomedical Research Centre based at Guy's and St Thomas’ NHS Foundation Trust and King's College London. T. D. S. is holder of an ERC Advanced Principal Investigator award.
All authors contributed, read and approved the final version.
None of the authors had any conflicts of interest.
Supplementary material
To view supplementary material for this article, please visit http://dx.doi.org/10.1017/S095442241400016X