Article Commentary: The Influence of Early Infant-Feeding Practices on the Intestinal Microbiome and Body Composition in Infants

Infant gut microbiome and health

Infants are exposed to their first inoculum of human microbes in utero.^55,56 The microbial colonization pattern of the infant is complicated and relies heavily on the mode of delivery and diet. Infants born vaginally are colonized by resident bacteria of the vagina and perineal area with a dominance of Lactobacillus and Prevotella spp., and infants born by C-section acquire species endemic to maternal skin from Staphylococcus, Corynebacterium, and Propionibacterium. ⁵⁷ Additionally, the fecal microbiota of infants born vaginally resembles maternal fecal microbiota by day 3 and day 7 of age, which is not observed in infants delivered by cesarean section. ⁵⁸ Thus, the vertical transmission of beneficial microbiota from mother to infant relies on the vaginal mode of delivery. In addition to the mode of delivery, infant diet plays a substantial role in shaping the infant gut microbiome.^16,17,59 It is well documented that exclusively breastfed infants have higher taxa from the protective bacterial class Actinobacteria and formula-fed infants have higher levels of the proinflammatory bacterial class γ-Proteobacteria.^16,18–20 Using metagenomic sequencing, Bäckhed et al recently discovered that the complexity of the infant gut microbiome increased over time and resembled more adult-like patterns, but the adult-like patterns were more prominent in formula-fed than exclusively breastfed infants. Furthermore, the intestinal microbiota of breastfed infants was less diverse than that of formula-fed infants, but this lower alpha diversity in breastfed infants was consistent with the enrichment of genes required for the degradation of human milk oligosaccharides (HMOs) from breast milk. ¹⁶ The differences in the microbiome between breastfed and formula-fed infants result in differences in gene transcription in the human host.^17,59 Using metagenomics and host gene transcriptomic analysis, Praveen et al ¹⁷ found that the intestinal microbiota diversity was significantly lower in breastfed infants, but their microbial genes interacted twofold more with host genes associated with immunological, metabolic, and biosynthetic activities compared with formula-fed infants. Schwartz et al ⁵⁹ discovered that the expression of microbial virulence factors was higher in breastfed infants, but this finding was concomitant with the downregulation of inflammatory genes in host epithelial cells. Thus, compared with formula-fed infants, the gut microbiome of exclusively breastfed infants is dominant of protective gut bacteria that utilize the complex sugars in human milk and interact more with host cells.

Breast milk provides a wide spectrum of biologically active factors that aid in the development and maturation of the gut, systemic metabolism, and the innate and acquired immune systems. It also develops a supportive and protective microbiota. Glycosylated proteins such as lactoferrin, lysozyme, and immunoglobulins are important nonnutritive factors that protect infants from infection and, as a result, affect the development of the intestinal microbiome. These bioactive proteins are the first line of defense against potential pathogens within the infant gut and exert their protective effects via multiple and often overlapping mechanisms. These may have either direct or indirect effects on the intestinal microbiome by interacting with bacteria, engaging in pathogen destruction/deflection including immune exclusion, interacting with the infant mucosal immune system, and stimulating epithelial barrier function.^60–63

Recent advances in mass spectrometry-based tools have revealed the detailed chemical structures of the complex and diverse-free and conjugated glycans in human milk.^64–66 HMOs, the third most abundant component in human milk (~10-20 g/L), is a constellation of complex sugars that are non-digestible by the infant but support the competitive growth of protective Bifidobacterium strains within the intestine of the breastfed infant. Specifically, two main bifidobacterial species populate the breastfed infant colon, Bifidobacterium longum^67–72 and B. breve. ⁷³ The B. longum clade contains two subspecies found in humans, B. longum subsp. longum (herein termed B. longum) and B. longum subsp. infantis (B. infantis). Breakthroughs in microbiology have led to a detailed description of the natural colonization of protective Bifidobacterium in breastfed infants and identified HMO in breast milk as natural prebiotics that selectively enrich the growth and function of these beneficial bacteria.^{67–70,72,74–80} Specifically, HMO consumption is most efficient among B. infantis strains but is absent in B. longum strains. ⁷⁹ When grown in the presence of HMOs, B. infantis upregulates its expression of two groups of bacterial genes-specific binding proteins that import HMOs ⁷² and 16 glycosyl hydrolases with specificity for every linkage in HMOs.^{67,69,70,77,81} This suggests that B. infantis is able to efficiently transport intact HMOs into its cytoplasm and digest HMOs within the bacterial cytoplasm. These HMO-associated genes are not upregulated when B. infantis is grown on more simple prebiotics added to formula, such as fructo-oligosaccharides, galacto-oligosaccharides and inulin,^72,82 even though other strains of Bifidobacterium efficiently utilize them. ⁸³ Levels of intestinal B. infantis are positively associated with immune protection through several proposed mechanisms (reviewed in Ref. 84). These mechanisms include: (1) through enhanced adherence to intestinal cells and inhibition of gut invasion by undesirable bacterial strains; ⁸⁵ (2) through direct interaction with intestinal cells and dendritic cells resulting in the production of anti-inflammatory cytokines and reduction of proinflammatory cytokines and enhanced gut barrier function;^86,87 (3) through the secretion of bioactive factors that directly reduce expression of toll-like receptors 2 and 4, reduce the production of proinflammatory cytokines, enhance the release of anti-inflammatory cytokines, and enhance gut barrier function;^88,89 (4) through increased activation of T-regulatory cells with concomitant inhibition of chemokine secretion within the mucosa during pathogen infection; ⁹⁰ and (5) through inhibiting the translocation of gram-negative bacterial toxins via the increased production of short-chain fatty acids as by-products of carbohydrate fermentation. ⁹¹ Microbial production of short-chain fatty acids was also found to directly reduce gut inflammation by increasing the number of colonic T-regulatory cells and their production of interleukin-10. ⁹² Clinically, Bangladeshi infants colonized by high levels of gut B. infantis were shown to have larger thymus glands and better peripheral T-cell responses following vaccinations against the oral polio virus and tetanus toxoid. ⁹³ In premature infants, B. infantis but not Bifidobacterium animalis subspecies lactis, given in combination with human milk increased Bifidobacterium and decreased γ-Proteobacteria in feces. ⁹⁴ Additionally, probiotics containing B. infantis was found to decrease the risk of necrotizing enterocolitis in premature infants. ⁹⁵ Thus, mammalian lactation has evolved to selectively nourish targeted strains of Bifidobacterium that in turn protect and guide the intestinal health and immune system of the developing infant.

Most of what is known about how diet influences the infant gut microbiome is through the comparison of exclusively breastfed versus formula-fed infants. However, it is not well understood how mixed-feeding influences the gut microbiome. It is also unknown whether there is a difference in mixed-feeding early in life when the gut is naïve versus in later life after the infant's gut microbiome is established and the gut is more mature. On the first day of age, Enterobacteriaceae, Streptococcus, and Staphylococcus are present in infant feces. Bifidobacterium, the protective obligate anaerobic genus, does not appear until day 2 of age, and its level is not stable until day 4 of age. ⁹⁶ It has been proposed that the gradual consumption of oxygen in the intestine by aerobic microorganisms decreases the oxidation–reduction potential and thus provides the conditions for the settlement of a dominance of anaerobic bacteria. ⁹⁷ The intestinal level of the genus Bifidobacterium has been reported to be similar between breast and formula-fed infants at one month of age;^19,20 yet, few studies examined the fecal microbiology to the level of species and subspecies belonging to this genus. Among Bifidobacterium, B. infantis, B. breve, B. adolescentis, B. longum, and B. bifidum are typical of breastfed infants.^73,98–100 On the other hand, B. longum, the adult strain of Bifidobacterium, ¹⁰⁰ is higher in formula-fed infants. ¹⁷ It has been reported that relatively small amounts of formula supplemented to breastfed infants shifted the gastrointestinal environment and microbiota from a breastfed to a formula-fed pattern. Bullen et al reported that the infant fecal microbiology was similar in the first week of life regardless of the type of milk they were receiving: (1) exclusively breastfed, (2) exclusively formula-fed, or (3) mixed-fed (breastfed + fed formula one bottle every 24 hours). However, the class Clostridia was not present or present in very low levels in breastfed infants (10 ³ ) over the first six weeks of life but rose from 10 ⁵ to 10 ⁷ over the six–week study period in the formula-fed and mixed-fed infants. Proteus bacteria, belonging to the proinflammatory class γ-Proteobacteria, was not detected in breastfed infants, yet was found in 30% of formula-fed infants and 20% of mixed-fed infants. ²³ These data suggest that in breastfed infants, consumption of formula for only one week resulted in unfavorable consequences on the gut microbial ecology throughout the six–week study duration. Well–designed studies are needed to understand the long-term effects of brief formula-feeding in breastfed infants (a common practice) on the infant gut microbiome and gut health.

The nature of mucosal gut microbial ecology ecology acquired in early infancy has been proven to be critical in the determination of mucosal immune response and tolerance, so that alterations of the gut environment are directly responsible for mucosal inflammation and disease, autoimmunity, and allergic disorders in childhood and adulthood.^24,101 Breastfed infants have a much lower colonic pH, and more breastfed infants have higher concentrations of fecal acetate than formula-fed or mixed-fed infants.^22,23,102 Acetate production by protective bifidobacteria has been shown to act in vivo to promote defense functions of the host epithelial cells and protect the cell from enteropathogenic infection. ⁹¹ Additionally, levels of colonic acetate was found to be anti-inflammatory through the regulation of colonic T-regulatory cells. ⁹² These data suggest that even in a breastfed infant, consumption of one bottle of formula per day for the first week of life is enough to shift the gastrointestinal microbiology toward proinflammatory taxa with concomitant lower concentrations of colonic acetate several weeks postnatally. More research is needed with long-term studies on breastfed infants who are also formula-fed early in life, a common practice used by hospitals that do not adhere to the Baby Friendly guidelines established by the WHO and UNICEF.

Infant growth and body composition

Infancy is a period of rapid growth; from birth to two years of life, body length increases by ~75% and weight increases 3.5-fold (http://www.who.int/childgrowth/standards/weight_for_age/en/). At birth, body fat accounts for ~15% of weight, and this increases to ~25% at six months, peaking at ~30% at 12 months. Deviations in growth in early life are associated with increased risk of disease in the short and long term; hence, growth is often used as a proxy measure of infant health. Some of the most referenced infant growth studies date back to the 1980s and 1990s when it was apparent that the growth patterns of exclusively breastfed infants deviated significantly from WHO standard growth charts, which at the time were based on predominantly formula-fed populations. ¹⁰³ Most of these earlier publications investigating infant growth reported weight and length gains, with the majority identifying a more rapid growth trajectory for formula-fed infants and a higher absolute body weight. ¹⁰³ Although some of the early studies reported measures of adiposity suggesting that breastfed infants were generally leaner than formula-fed infants, these investigations were limited by the measurement techniques used. ¹⁰³ In contrast, a recent systematic review and meta-analysis reported higher fat-free mass in formula-fed infants over the first year of life. Fat mass was higher in breastfed infants at three to four months and at six months; however, by 12 months, this effect was no longer significant and there was a trend toward a higher fat mass in formula-fed infants. ¹⁰⁴ Recognizing the differences among breast and formula-fed infants, other investigations have targeted potential consequences of different feeding practices/growth trajectories and reported a protective effect of breastfeeding against obesity risk ¹⁰⁵ and a positive association between rapid weight gain and obesity risk. ¹⁰⁶ Since exclusive breastfeeding is associated with the highest standard of health, the growth pattern of breastfed infants is regarded as the standard for all infants, and so international growth reference charts have been revised accordingly. The mechanisms that explain how breast milk consumption and breastfeeding can impact infant growth and protect against obesity can be broadly classified under two major categories: (1) components/composition of breast milk and (2) behaviors related to infant feeding. The sources, quantities, and qualities of macronutrients and micronutrients are different in breast milk and formula. Taking protein as an example, despite recent modifications, formula still contains more protein and different types of proteins than breast milk. The higher protein intake reported in formula-fed infants results in higher concentrations of plasma amino acids, particularly branched-chain, insulinogenic amino acids (valine, leucine, isoleucine). The formula-fed infants’ amino acid profile is associated with higher concentrations of insulin that is thought to impact growth and potentially obesity risk. ¹⁰⁷ In addition to nutritive components, breast milk also provides a range of nonnutritive bioactives such as immune cells, growth factors, and hormones that must also be considered in relation to growth and body composition (bioactives reviewed in Refs 108,109). For example, studies show that breast milk concentrations of leptin and adiponectin are associated with infant weight gain.^110,111 Leptin regulates appetite and therefore provides a link to improved self-regulation of milk intake in breastfed infants compared to formula-fed infants. Indeed, regulating milk intake is one aspect of feeding behavior that is different between breast and formula-fed infants. However, behaviors of the caregiver also play an important role in infant feeding. Formula-fed infants are often encouraged to empty the bottle, which may override infants’ internal satiety cues and result in poor self-regulation of intake. ¹¹² This highlights another key point that bottle-feeding, regardless of the type of milk, is distinct from breastfeeding in its effect on the infant's ability to self-regulate intake. ¹¹²

Studies examining the relationship between infant feeding and growth typically compare exclusive breastfeeding and full formula-feeding, despite the fact that mixed-feeding is a common practice. Consequently, there are a limited number of studies that include a group of infants that consume breast milk and formula. One recently published paper from a large Canadian cohort classified infant–feeding practices as (1) only breastfed, (2) mixed-fed, or (3) only formula-fed. ¹¹³ This study reported that a higher proportion of children who were introduced to formula in early infancy were overweight or obese compared to children who received formula in later infancy or who never received formula. When classified by feeding type, there was no difference in the proportion of obese children in the only breastfed or mixed-fed groups; however, the proportion of obese children in the only formula-fed group was higher. ¹¹³ In slight contrast, NHANES data showed similar rates of childhood obesity among mixed-fed and only formula-fed infants, which were higher than the only breastfed group. ¹¹⁴ Based on the Canadian data, one might expect that the consumption of any breast milk will be protective against obesity, while the NHANES data suggest that any breast milk will not ameliorate the effects of formula on body weight. The conflicting findings are potentially due to the age at which BMI/obesity was measured and/or due to variations in the definition of mixed-fed infants. Indeed, one final study that included mixed-feeding as an independent group reported that the duration of partial breastfeeding that was necessary to impart a protective effect against obesity was longer than when breastfeeding was exclusive. ¹¹⁵ In a population of low-income children, Bogen et al ¹¹⁵ found that breastfeeding for at least 16 weeks without formula or at least 26 weeks with formula was associated with a reduced risk of obesity at age four years. Similarly, studies investigating obesity risk and duration of exclusive breastfeeding consistently report a protective effect when formula is delayed.^116,117