Meconium microbiota types dominated by lactic acid or enteric bacteria are differentially associated with maternal eczema and respiratory problems in infants.

BACKGROUND: Culture-dependent methods have shown that meconium, the newborn's first intestinal discharge, is not sterile, but the diversity of bacteria present in this material needs to be further characterized by means of more sensitive molecular techniques. OBJECTIVE: Our aims were to characterize molecularly the meconium microbiota in term infants, to assess whether it contributes to the future microbiota of the infants' gastrointestinal tract, and to evaluate how it relates to lifestyle variables and atopy-related conditions. METHODS: We applied high-throughput pyrosequencing of the 16S rRNA gene to study the meconium microbiota in twenty term newborns from a Spanish birth cohort. For comparison, we characterized the microbiota in fecal samples from seven pregnant women days before delivery and in two series of infant samples spanning the first seven months of life. We also compared our data with vaginal and skin microbiota characterized in independent studies. Different types of meconium microbiota were defined based on taxonomic composition and abundance and their associations with different factors were statistically evaluated. RESULTS: The meconium microbiota differs from those in adult feces, vagina and skin, but resembles that of fecal samples from young infants. Meconium samples clustered into two types with different bacterial diversity, richness and composition. One of the types was less diverse, dominated by enteric bacteria and associated with a history of atopic eczema in the mother (P = 0.038), whereas the second type was dominated by lactic acid bacteria and associated with respiratory problems in the infant (P = 0.040). CONCLUSIONS & CLINICAL RELEVANCE: Our findings suggest that the meconium microbiota has an intrauterine origin and participates in gut colonization. Although based on a small population sample, our association analyses also suggest that the type of bacteria detected in meconium is influenced by maternal factors and may have consequences for childhood health.

Asymmetries generated by transcription-coupled repair in enterobacterial genes.

Although certain replication errors occur at different frequencies on each of the complementary strands of DNA, it remains unclear whether this bias is prevalent enough during chromosome replication to affect sequence evolution. Here, nucleotide substitutions in enteric bacteria were examined, and no difference in mutation rates was detected between the leading and lagging strands, but in comparing the coding and noncoding strands, and excess of C-->T changes was observed on the coding strand. This asymmetry is best explained by transcription-coupled repair on the noncoding strand. Although the vast majority of mutations are thought to arise from spontaneous errors during replication, this result implicates DNA damage as a substantial source of mutations in the wild.

Strand asymmetries in DNA evolution.

The complementary strands of DNA differ with respect to replication and transcription. Both of these processes are asymmetric and can bias the occurrence of mutations between the strands: during replication, the discontinuous lagging strand undergoes certain errors at higher rates, and transcription overexposes the nontranscribed strand to DNA damage while targeting repair enzymes to the transcribed strand. While biases introduced during replication apparently have little impact on sequence evolution, the effects of transcription are observed in the asymmetric patterns of substitution in bacterial genes and might be influencing genome-wide patterns of base composition.

High frequencies of antibiotic resistance genes in infants' meconium and early fecal samples.

The gastrointestinal tract (GIT) microbiota has been identified as an important reservoir of antibiotic resistance genes (ARGs) that can be horizontally transferred to pathogenic species. Maternal GIT microbes can be transmitted to the offspring, and recent work indicates that such transfer starts before birth. We have used culture-independent genetic screenings to explore whether ARGs are already present in the meconium accumulated in the GIT during fetal life and in feces of 1-week-old infants. We have analyzed resistance to ß-lactam antibiotics (BLr) and tetracycline (Tcr), screening for a variety of genes conferring each. To evaluate whether ARGs could have been inherited by maternal transmission, we have screened perinatal fecal samples of the 1-week-old babies' mothers, as well as a mother-infant series including meconium, fecal samples collected through the infant's 1st year, maternal fecal samples and colostrum. Our results reveal a high prevalence of BLr and Tcr in both meconium and early fecal samples, implying that the GIT resistance reservoir starts to accumulate even before birth. We show that ARGs present in the mother may reach the meconium and colostrum and establish in the infant GIT, but also that some ARGs were likely acquired from other sources. Alarmingly, we identified in both meconium and 1-week-olds' samples a particularly elevated prevalence of mecA (>45%), six-fold higher than that detected in the mothers. The mecA gene confers BLr to methicillin-resistant Staphylococcus aureus, and although its detection does not imply the presence of this pathogen, it does implicate the young infant's GIT as a noteworthy reservoir of this gene.

R1 and R2 retrotransposable elements of Drosophila evolve at rates similar to those of nuclear genes.

The non-long-terminal repeat retrotransposable elements, R1 and R2, insert at unique locations in the 28S ribosomal RNA genes of insects. Based on the nucleotide sequences of these elements in the eight members of the melanogaster species subgroup of the genus Drosophila, they have been maintained by vertical germline transmission for the 17-20 million year history of this subgroup. The stable inheritance of R1 and R2 within these species has enabled a determination of their nucleotide substitution rates. The sequence of the R1 and R2 elements from D. ambigua, a member of the obscura species group, has also been determined to enable an extrapolation of this rate over an estimated 45-60 million years. The mean rate of substitutions at synonymous sites (Ks) was 6.6 and 9.6 times the rate at replacement sites (Ka) in the R1 and R2 elements, respectively. Both elements appear to have been under selective pressure to maintain their open reading frames and thus their ability to retrotranspose for most of their evolution in these lineages. Using the rate of change at synonymous sites (Ks) as the best indicator of the nucleotide substitution rate, the mean Ks values for R1 and R2 were 2.3 and 2.2 times that of the alcohol dehydrogenase (Adh) genes. However, this faster rate is a result of the lower codon usage bias of R1 and R2 compared with that of Adh. When the Ks rates of R1 and R2 were compared with that of a larger number of nuclear genes available from at least two of the nine species under investigation, R1 and R2 were found to evolve in most lineages at rates similar to that of nuclear genes with low codon bias. The ability of R1 and R2 to maintain their presence in this species subgroup by retrotransposition while exhibiting rates of nucleotide evolution similar to nuclear genes suggests these transposition events are rare or not as error prone as that of retroviruses.

Antibiotics and the Human Gut Microbiome: Dysbioses and Accumulation of Resistances.

The human microbiome is overly exposed to antibiotics, due, not only to their medical use, but also to their utilization in farm animals and crops. Microbiome composition can be rapidly altered by exposure to antibiotics, with potential immediate effects on health, for instance through the selection of resistant opportunistic pathogens that can cause acute disease. Microbiome alterations induced by antibiotics can also indirectly affect health in the long-term. The mutualistic microbes in the human body interact with many physiological processes, and participate in the regulation of immune and metabolic homeostasis. Therefore, antibiotic exposure can alter many basic physiological equilibria, promoting long-term disease. In addition, excessive antibiotic use fosters bacterial resistance, and the overly exposed human microbiome has become a significant reservoir of resistance genes, contributing to the increasing difficulty in controlling bacterial infections. Here, the complex relationships between antibiotics and the human microbiome are reviewed, with focus on the intestinal microbiota, addressing (1) the effects of antibiotic use on the composition and function of the gut microbiota, (2) the impact of antibiotic-induced microbiota alterations on immunity, metabolism, and health, and (3) the role of the gut microbiota as a reservoir of antibiotic resistances.

Metagenomics and development of the gut microbiota in infants.

The establishment of a balanced intestinal microbiota is essential for numerous aspects of human health, yet the microbial colonization of the gastrointestinal tract of infants is both complex and highly variable among individuals. In addition, the gastrointestinal tract microbiota is often exposed to antibiotics, and may be an important reservoir of resistant strains and of transferable resistance genes from early infancy. We are investigating by means of diverse metagenomic approaches several areas of microbiota development in infants, including the deployment of functional capabilities at the community level, the presence of antibiotic resistances and the population dynamics of the most abundant genera.

The genome of the obligately intracellular bacterium Ehrlichia canis reveals themes of complex membrane structure and immune evasion strategies.

Ehrlichia canis, a small obligately intracellular, tick-transmitted, gram-negative, alpha-proteobacterium, is the primary etiologic agent of globally distributed canine monocytic ehrlichiosis. Complete genome sequencing revealed that the E. canis genome consists of a single circular chromosome of 1,315,030 bp predicted to encode 925 proteins, 40 stable RNA species, 17 putative pseudogenes, and a substantial proportion of noncoding sequence (27%). Interesting genome features include a large set of proteins with transmembrane helices and/or signal sequences and a unique serine-threonine bias associated with the potential for O glycosylation that was prominent in proteins associated with pathogen-host interactions. Furthermore, two paralogous protein families associated with immune evasion were identified, one of which contains poly(G-C) tracts, suggesting that they may play a role in phase variation and facilitation of persistent infections. Genes associated with pathogen-host interactions were identified, including a small group encoding proteins (n = 12) with tandem repeats and another group encoding proteins with eukaryote-like ankyrin domains (n = 7).

Strand symmetry around the beta-globin origin of replication in primates.

Certain mutations are known to occur with differing frequencies on the leading and lagging strands of DNA. The extent to which these mutational biases affect the sequences of higher eukaryotes has been difficult to ascertain because the positions of most replication origins are not known, making it impossible to distinguish between the leading and lagging strands. To resolve whether strand biases influence the evolution of primate sequences, we compared the substitution patterns in noncoding regions adjacent to an origin of replication identified within the beta-globin complex. Although there was limited asymmetry around the beta-globin origin of replication, patterns of substitutions do not support the existence of a mutational bias between the leading and lagging strands of chromosomal DNA replication in primates.