Intestinal epithelium, mucosal immune system, and bacterial and non-bacterial flora represent a morph-functional system on dynamic balance responsible for the host local intestinal integrity and systemic barrier function.27 Gut harbour about 500 different species of microorganisms, weighing about 1.5kg in the normal subjects.28,29 The number of microbial luminal cells is 10-folds more than eukaryotic cells.28,30 At the same time, microbiota genome encode 100–1000 times more genetic information than the host genome.31 The gut, sterile during the intrauterine, is colonised immediately after birth. The numbers and species of bacteria fluctuate markedly during the early life.32 However, the gut microbiota of adults is comparatively steady over time.33 Over the course of millions of years of evolution, commensal bacteria have taken on many physiological functions essential to our health, including physical development, the intestinal barrier, immune regulation, metabolism, nutrition absorption, expelling toxin and so on.34 At the same time, gut microbiota are important factors to stimulate the mucosal immune system and systemic immune system to mature.35,36 There is convincing evidence from both human and animal studies suggesting that intestinal microbiota plays an important role in maintaining health and curing diseases; especially, new technologies have allowed the attempt to a systematic intestinal bacterial flora study giving more realistic information about its composition and its pathological variance.

Asthma is estimated to affect approximately 300million individuals worldwide, incurs significant health care expenditure,6,7 and is one of the most common chronic diseases. Given increases in disease prevalence over the last several decades, it is predicted that the number of individuals affected worldwide will increase by 100million people by 2025.8 In the United States, the risk of developing asthma is highest for children during the period between birth and four years of age37; disease prevalence is also higher among women, families below the poverty line, and people of multiple races compared to other groups.38 Although risk alleles have been associated with asthma development,39 the rapid increase in prevalence over recent decades, particularly among children, points to environmental factors playing a key role in disease development.40 Atopic sensitisation (allergy), characterised by elevated levels of total and allergen-specific IgE in the serum and typically by positive skin-prick tests to at least one of a panel of common allergens, is considered the strongest risk factor for childhood asthma development in westernised nations,41 and its rise is associated with a parallel increase in asthma prevalence.8 During the past 15 years, numerous human epidemiological studies have been conducted on the association between the gut microbiota composition and allergy/asthma. The vast majority of these studies suggest that those subjects with allergy and asthma exhibit alterations in the relative levels of “beneficial” and potentially harmful bacteria compared to healthy the subjects (Table 1).20–26 At the same time, there is convincing evidence from both human and animal studies suggesting that all kinds of factors are related to allergy and asthma disease by affecting gut microbiota. These contain early-life antimicrobial exposure, Caesarean birth, formula feeding, lack of maternal exposure to pets or livestock during pregnancy, and maternal consumption of antimicrobial during pregnancy.42–47

In 1999, Björkstén et al. reported that the research was completed in 29 Estonian and 33 Swedish 2-year-old children with either non-allergic (n=36) or had a confirmed diagnosis of allergy (n=27) to egg or cow's milk.20 In these group, the abundant levels of coliforms and Staphylococcus aureus are lower, while the levels of the lactobacilli and bifidobacteria are higher in the faecal samples compared to children with allergies to egg or cow's milk.20 Johansson et al. found that lactobacilli and bifidobacteria colonisation of infants at one week of age is a significant negative correlation with a risk for allergy at five years.21 There are some important findings about the beneficial effect of probiotics in allergy. A recent study reported that oral exposure of adult mice to house dust mediates Lactobacillus enrichment of intestinal microbiome and airway immune defence against allergens and virus infection,22 Increase of Lactobacillus johnsonii results in reductions in the total number and proportion of activated CD11c+/CD11b+ and CD11c+/CD8+ cells and airway Th2 cytokine expression.22 Meanwhile, the effects of probiotic intervention in early infancy to reduce the risk of atopic disease corroborate the above studies. Firstly, the research was completed in 230 infants with symptoms of the atopic eczema/dermatitis syndrome,23 In the whole group, the mean Severity Scoring of Atopic Dermatitis (SCORAD) decreased by 65%, especially in IgE-sensitised infants, the group with Lactobacillus GG treatment (a mixture of four probiotic strains) showed a greater reduction in SCORAD than did the placebo group,23 Treatment with LGG may alleviate the atopic eczema/dermatitis syndrome symptoms in IgE-sensitised infants but not in non-IgE-sensitised infants.23 Meanwhile, treatment resulted in increases in total counts of lactobacilli in the probiotic groups and decreases in the placebo group,23 and differences in changes between probiotic groups and the placebo group were significant. Total counts of bifidobacteria showed no major changes.23 Secondly, two probiotic Lactobacillus strains (lyophilised Lactobacillus rhamnosus19070-2 and Lactobacillus reuteri DSM 122460) were given in combination for six weeks to 1- to 13-year-old children with atopic dermatitis (AD).24 The treatment response was more pronounced in allergic patients with at least one positive skin prick test response and increased IgE levels.24 While the atopic dermatitis score and serum eosinophil cationic protein levels decreased, the production of the cytokines IL-2, IL-4, IL-10, or IFN-γ was unchanged.24 Similarly, the intestinal microbiota also play important role in development of asthma; a prospective birth cohort study show that colonisation of Clostridium difficile in gut at age one month was significantly associated with an increased risk for asthma,25 However, another study of oral administration of Clostridium leptum in adult mice showed the levels of C. leptum is negative correlation with asthma.26 Oral feeding with C. leptum for two weeks increased the percentage and total number of Tregs in the spleens and mediastinal lymph nodes and attenuated allergen-induced airway hyperresponsiveness and inflammation by inhibiting inflammatory cytokine production but enhancing interleukin 10 and transforming growth factor β1 production in the lungs.26 All in all, the data in the above shows that specific microbial species in gut may play a protective or pathogenic role in allergy or asthma development.

The authors declare that no patient data appears in this article.

The authors declare that no patient data appears in this article.

The authors declare that no experiments were performed on humans or animals for this investigation.