The influence of factors present in early life was identified in reports that analyzed the mortality rate from all causes in the UK and Sweden, from 1845 to 1925, at the age range of 10–100 years, which originated the hypothesis that a change in the environment could help reduce mortality.10,11 Failure to prove the hypothesis motivated the inclusion of the age group 5–10 years in the mortality study. This time, an association was observed between improvement in living conditions of children and adolescents and decrease in overall mortality rate in both countries, suggesting that the improvement of environmental conditions during pregnancy could have a direct effect on the health of children in the younger age groups.11

Studies carried out in equines12 demonstrated the influence of the maternal body on the fetus, regardless of the genetic factor. Fetuses of large animals implanted in the uterus of small species resulted in foals that were smaller than expected, as well as fetuses generated in small equines showed greater development when implanted in large mares.

In the context of these ideas, Neel13 published observations on the effects of maternal nutritional deprivation on the fetus. The author theorized that fetuses developed a type of metabolism aimed at conserving energy, with insulin resistance being important, which would be related to a random genetic mutation.13 The preponderance of this “thrifty genotype” would last and would be passed on to future generations, and thus, the abundant consumption of food would lead to obesity by excessive accumulation of reserves.

The effect of food shortages during the German siege of the Netherlands in World War II14 made women suffer the impact of malnutrition during pregnancy. The analysis of this natural experiment raised questions about Neel's hypothesis,13 as nutrient deprivation led to different effects than those expected. Fetuses that suffered malnutrition in the first trimester developed obesity in adulthood, while nutritional restriction after the initial phase of pregnancy was not associated with the same effect. Even if one would admit the importance of environmental stimuli in the occurrence of obesity, the genetic factor could not be ignored.

A Norwegian study15 reinforced the importance of nutritional status in childhood in the genesis of adult diseases. Considering the generation of individuals born between 1896 and 1925, it was verified that increased mortality in adults occurred in counties with higher infant mortality, with risk factors being increased blood cholesterol and a high-fat diet consumption, as well as individuals’ social status, smoking and type of nutrition. Regarding the contribution of the high-fat diet to high cholesterol levels, the study identified different behaviors according to the socioeconomic status of individuals. The ones who had previously experienced poverty had increased cholesterol related to a high-fat diet, which did not occur with those with a financially stable life.15 These findings provided the basis for the hypothesis that the deprivation period contributed for individuals to develop “fat intolerance”, being exposed to a higher risk of death when they received an abundant diet.

In addition to the hypotheses of fat intolerance and the “thrifty genotype”, a cohort in Hertfordshire16,17 demonstrated an association between low birth weight and death from coronary heart disease in adulthood. Risk factors for cardiovascular and metabolic diseases were more frequent among those born with low birth weight.17 Additionally, Barker16 proposed that the fetus responds with growth retardation when there is a nutrient deficit in its environment, which is associated with decreased insulin sensitivity, providing better survival circumstances. This adaptation also predicts, in adult life, maintenance of an environment with low supply of nutrients. If this situation does not occur, the abundant supply of food creates an imbalance that can lead to cardiometabolic diseases. This context led to the thrifty phenotype hypothesis,16 and subsequently, to the predictive adaptive response,3 which are depicted in Fig. 2.

Figure 2.

The thrifty phenotype hypothesis and predictive adaptive response.

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Situations related to birth weight alterations reinforce its importance as an indicative marker of intrauterine environment and predictor of cardiometabolic diseases in adolescence and adulthood.18–20 Thus, birth weight may have a constitutional origin or be secondary to intrauterine nutritional deprivation, which leads to fetal growth restriction. It is acknowledged that low birth weight newborns undergo the influence of different mechanisms of adaptation to extra-uterine environment, among which are the increase in carbohydrate metabolism and the consequent increase in adiposity, increasing the future risk of chronic diseases such as insulin resistance, obesity and type 2 diabetes.19 These mechanisms lead to high levels of leptin, secondary to increased resistance level of its receptors, related to lack of satiety in early life, which is associated with obesity and metabolic disorders in adolescence and adulthood, when these newborns are exposed to a nutritional environment with excessive nutritional offer in the early years of life.20

When leaving this situation of restricted growth, due to hormonal or nutritional issues, to another with adequate supply of nutrients, accelerated growth recovery may occur to achieve the genetically determined potential,21 which is the so-called catch-up growth.22

Catch-up growth can be defined as the rate of weight gain and/or growth that is higher than the statistical limits of normality for age and maturity that occurs during a defined period of time, following a transient period of growth inhibition.21 Catch-up growth is a physiological process related to size recovery of a body subjected to restriction, so that it can reach the adequate size for age, gender and degree of maturity, depending on the action of the somatotropic axis, with an increase in hormone receptors.21

This recovery, resulting from unfavorable conditions for growth during the prenatal and early postnatal periods, can influence the risk of developing cardiometabolic diseases throughout life.23,24 However, short-term growth recovery offers advantages for neurodevelopment, particularly for children born with very low birth weight, and also contributes to increased resistance to infections. Hence the question of identifying whether the benefits of increased growth velocity can occur without adverse metabolic consequences.18

It is accepted that a catch-up growth >0.67 standard deviations would be associated with central obesity25 and trigger insulin resistance, which leads to a compensatory increase in insulin secretion, even in low birth weight newborns that showed increased growth rate, but remain small during childhood. Even if these children show an increase in growth rate, they have compensatory hyperinsulinemia to a greater degree than well-nourished children or the ones who are excessively fed. Thus, hyperinsulinemia secondary to insulin resistance could be the key explanation for the genesis of metabolic syndrome.26

Insulin resistance in preterm infants is associated with hypersecretion of growth hormone and reduced levels of IGF-1, which persist for 3 months after birth in the absence of adequate nutritional supply. This altered endocrine status favors reduction of subcutaneous adipose tissue, with relative visceral adiposity, a marker of insulin resistance, dyslipidemia, and the presence of other metabolic syndrome components.27

Despite these observations, it is not clear whether central obesity, rather than subcutaneous fat, is a function of prematurity, of being born small for gestational age or of catch-up growth. Studies have shown that infants with growth restriction at birth have reduced subcutaneous fat, but maintain levels of abdominal fat similar to those of newborns that are adequate for gestational age.28 A cohort study carried out to investigate the association between fetal and early postnatal growth and metabolic and anthropometric alterations showed that catch-up growth was associated with the fetal growth pattern, regardless of birth weight, and was related to higher insulin sensitivity and lower concentrations of leptin at birth. Therefore, the catch-up growth would promote the recovery of body size and fat stores without deleterious consequences to the metabolic profile and body composition, after one year of age.29

A recent review30 was performed to search evidence on the association between low weight, insulin resistance and type 2 diabetes in adults, considering body composition and metabolic pathways. The empirical basis shows a multifactorial association and points out that, in some children and adults who were born preterm, insulin resistance and increased abdominal adiposity originate from the variation of the glucocorticoid receptor gene. Higher concentrations of glucocorticoids activate the hypothalamic-pituitary-adrenal axis, promoting the intake of palatable foods, which activate the pleasure centers of the brain and trigger greater accumulation of adipocytes. Thus, adults who were born preterm may have increased sensitivity to stressors, leading to an overproduction of glucocorticoids, stimulating the omental population of pre-adipocytes, with increased abdominal fat deposition.

Experimental studies have brought new ideas to explain the origin of adult diseases in early life, but raised new questions. The hypotheses did not contribute to the understanding about the occurrence of these diseases in individuals born large for gestational age, as well as in fetuses with adequate weight that developed them in adulthood. Moreover, they did not explain how fetuses with intrauterine growth restriction (IUGR), with decreased insulin sensitivity in early postnatal life, developed increased resistance only in adult life, which seems to indicate loss of the metabolic process continuum, as if the latter had started only in adulthood.

To analyze the association between low birth weight and hypertension development in adulthood, Huxley et al.,31 in a meta-analysis, compared 18 articles submitted by researchers that corroborated the thrifty phenotype hypothesis with 37 studies from other researchers. Although this meta-analysis31 did not show an association between low birth weight and hypertension in adults, it did not rule out the adaptive hypotheses, and other aspects of late expression of intrauterine life determinants started to be investigated. The hypotheses were based on the idea of conservation, which did not seem to represent the overall process. Observations from the beginning of life suggested a much wider and widespread phenomenon, in which the pattern of development could be modified in any direction, depending on the stimulus.32,33

Based on the possibility that the phenotype can generate different genotype under different environmental conditions, that is, phenotypic plasticity, Gluckman et al.34 enunciated the hypothesis of an “adaptive predictive response” to the environment. The development plasticity would be evoked by environmental alterations early in life, generating an adaptive phenotypic response, of which advantages would manifest only in later stages. Therefore, the phenotypic plasticity might have granted advantages to the human species to face environments with nutritional restriction or high-energy expenditure. However, when submitted to a different nutritional environment than the programmed one, individuals would have exacerbated responses and develop diseases in adulthood.34 The “predictive adaptive response” will be an adaptive advantage when the “prediction” about the environment is correct (match) and may determine a disadvantage when it is wrong (mismatch),34 characterizing plasticity.

Plasticity can trigger different responses with immediate expression, such as nutritional restrictions to the fetus, which reacts with a decrease in its nutritional reserves, decreased anabolism, plasma insulin, insulin-like growth factor 1 (IGF-1), and blood flow diversion to protect the heart and brain. These immediate adaptations to the restrictive environment allow adequate survival, but result in low birth weight, increased risk of morbidity and mortality, cognitive impairment, and persistent growth deficit.35

Responses aimed at ensuring survival can, however, lead to adaptive errors. Maternal hyperglycemia in early pregnancy can contribute to embryopathy, by leading to the reduction of myo-inositol, which is essential for embryonic development during gastrulation and the neurulation stages. Myo-inositol deficiency seems to disturb the phosphoinositide system, which leads to abnormalities in the arachidonic acid–prostaglandin pathways and increase in reactive oxygen substances.36 This chain of events is responsible for fetal cardiovascular abnormalities, such as transposition of the great vessels, ventricular septal defects, hypoplastic left heart syndrome, and dextrocardia.37 Increased maternal glycated hemoglobin is associated with embryonic alterations in 66% of fetuses, but when lower than 9.5%, it does not alter embryogenesis,36 characterizing disruption,3 in which a hormone can trigger an undesirable effect on the response process to environmental adaptation.

Although the fetal and postnatal organisms have adaptive responses to a restrictive intrauterine environment in a continuous manner, their development has “plasticity windows”, i.e., the possibility of interference with the adaptive programming, correcting inappropriate responses.38 This hypothesis is corroborated by an experimental study comparing offspring with growth retardation, born to malnourished rats during pregnancy, to the offspring of well-nourished rats, after feeding a hypercaloric diet to the offspring without IUGR and leptin to those with IUGR. The authors verified that growth in the two groups did not differ and concluded that the increase in leptin concentration signaled the presence of an adequate amount of adipose tissue in the offspring organism and, therefore, of nutritional reserves.38

The adaptive continuity to environmental changes and “windows of opportunity” are explained by the epigenetic theory, i.e., the possibility that environmental factors interfere with gene expression. Predictive adaptive responses are modulated by covalent modifications of deoxyribonucleic acid and histones, which are necessary for the phenomenon of gene transcription, namely the synthesis of ribonucleic acid for protein synthesis.39

Evidence suggests that the fetal period is more sensitive for the occurrence of epigenetic variations that will influence cell and tissue genetic expression, sexual dimorphism and the risk of triggering disorders that will manifest later in life.40 An example of the influence of epigenetics on the early neonatal period is the effect of high-fat diets during pregnancy,41 i.e., overeating in the offspring and increased expression of orexigenic peptides promoting increase and deregulation of neonatal leptin.

The deregulation is important, because leptin is one of the first hormones synthesized during embryonic development by the placenta, by adipocytes of white adipose tissue, liver cells, cartilaginous structures and heart muscle. This molecule acts on neurogenesis, axonal growth, dendritic proliferation, synapse formation,23 in the development of neurological pathways to satiety, hunger and thermal regulation, which begins in intrauterine life and is completed in the first months of life, when supplied by breast milk.42

During the first pregnancy trimester, leptin synthesis occurs in the placenta, triggering a cascade of transcription factors in pre-adipocytes, contributing to the formation of white adipose tissue, which becomes the main source of leptin synthesis. This molecule, by crossing the blood–brain barrier, contributes to the development of several brain regions, among them the hypothalamus, where their receptors are located.23 The leptin-receptor binding is essential to indicate the need for nutrient intake and the increase in energy reserves in adipose tissue. When leptin concentrations in the hypothalamus are reduced due to binding to the receptors, the feeling of satiety is triggered by the activation of anorexigenic neurons. Thus, the phenotypic alteration of leptin receptors, characterizing leptin resistance, results in the persistence of the feeling of hunger and promotes ingestion of large quantities of nutrients and adipose tissue hypertrophy.24

The epigenesis of leptin resistance explains the increased risk of obesity in children of obese and diabetic mothers, as well as in newborns with IUGR submitted to excess nutrient intake or whose mothers were fed lipid-rich diets. In contrast, when during pregnancy and lactation, the mothers receive balanced diets, or when fetuses with IUGR are submitted to restrictive diets during the lactation period, they show normal growth of the adipose tissue, but develop post-weaning hyperphagia, attributed to phosphorylation deregulation of hypothalamic leptin receptors, reduction in anorexigenic receptors and reduction in permeability of the blood–brain barrier to this molecule.24

Epidemiological research18 has corroborated the hypothesis of adaptive predictive response,33 by demonstrating that an abundant food supply contributes to catch-up growth. However, it is also confirmed when there is absence of abdominal obesity, with normal neurodevelopment, in children receiving adequate nutrition, but not in excess. The significance of the nutrition of the newborn has been debated,43 especially for preterm ones, because there is more organic plasticity early in life. Thus, adequate interventions shortly after birth have plasticity as the possibility for correction of developmental delay, maintaining the benefits by cumulative effect. As age increases, with the decline in plasticity, nutrition that is adequate to the body's need will make the child's body composition reach the level of a child born to term, at the same age. Similarly, excess nutrition, also due to plasticity, will result in deleterious effects that will manifest throughout life.

One must consider4 the processes by which the quantity and quality of nutrients supplied to the fetus and the embryo are determined, due to their permanent effects on development, a process called nutritional programming, which depends on both maternal characteristics (before, during and after pregnancy), and fetal nutritional status.

Among the maternal and environmental characteristics that affect the fetal and newborn development are the socioeconomic and nutritional statuses, with direct effect, and maternal education, with an indirect effect. Nepalese infants born with low birth weight more frequently had mothers with low or very low socioeconomic level, low educational level and inadequate nutrition, factors that were associated with lower level of prenatal medical care.44 A population-based cohort followed between 1961 and 2000 disclosed that, in four decades, in the United Kingdom, socioeconomic inequalities still determined a higher frequency of low birth weight or premature births among mothers from the lower socioeconomic classes, even after adjusting for maternal age.44

Among the demographic and social factors are the maternal variables, such as age extremes (<20 and >30 years), low educational level, parity, short interbirth interval, drug use,45 and short stature.46 Breastfeeding is also considered, given its weak to moderate protective effect on adult obesity. Breastfeeding, by meeting the newborn's needs, reduces the risk of insulin resistance and increased intra-abdominal adiposity, and provides leptin concentrations capable of modulating the hunger–satiety mechanism.47

This evidence is consistent with the hypothesis accepted by Gluckman et al.,3 which affirms that nature directs its efforts to reproduction. Thus, if there are signs of a threatening postnatal environment, the fetus is born prematurely or smaller than expected, and in a nutrient-rich environment, unlike the planned trajectory, develops metabolic disease, in a multifactorial process in which many maternal and fetal factors interact (Fig. 3).

Figure 3.

Explanatory model – cardiometabolic diseases.

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Currently, a large number of experimental, epidemiological and clinical studies that provide a robust empirical basis contribute to a paradigm change in relation to the understanding of early origin of diseases. All this knowledge has a direct effect on the training of health care professionals, particularly, in medical training. It shows the need for apprehending several aspects of biological knowledge, especially of the evolution theory, because it is through this view that one can capture the importance of the interaction between genotype and the environment and the several mechanisms used by the body to adapt to the environment. Physicians, especially pediatricians, have a key role in this scenario, as they care for human beings at a time when there are more opportunities to act and generate changes, due to developmental plasticity.