Erica M. Carlisle

Microbiome Assembly across Multiple Body Sites in Low-Birthweight Infants

ABSTRACT The purpose of this study was to evaluate the composition and richness of bacterial communities associated with low-birthweight (LBW) infants in relation to host body site, individual, and age. Bacterial 16S rRNA genes from saliva samples, skin swabs, and stool samples collected on postnatal days 8, 10, 12, 15, 18, and 21 from six LBW (five premature) infants were amplified, pyrosequenced, and analyzed within a comparative framework that included analogous data from normal-birthweight (NBW) infants and healthy adults. We found that body site was the primary determinant of bacterial community composition in the LBW infants. However, site specificity depended on postnatal age: saliva and stool compositions diverged over time but were not significantly different until the babies were 15 days old. This divergence was primarily driven by progressive temporal turnover in the distal gut, which proceeded at a rate similar to that of age-matched NBW infants. Neonatal skin was the most adult-like in microbiota composition, while saliva and stool remained the least so. Compositional variation among infants was marked and depended on body site and age. Only the smallest, most premature infant received antibiotics during the study period; this heralded a coexpansion of Pseudomonas aeruginosa and a novel Mycoplasma sp. in the oral cavity of this vaginally delivered, intubated patient. We conclude that concurrent molecular surveillance of multiple body sites in LBW neonates reveals a delayed compositional differentiation of the oral cavity and distal gut microbiota and, in the case of one infant, an abundant, uncultivated oral Mycoplasma sp., recently detected in human vaginal samples. IMPORTANCE Complications of premature birth are the most common cause of neonatal mortality. Colonization by the indigenous microbiota, which begins at delivery, may predispose some high-risk newborns to invasive infection or necrotizing enterocolitis (NEC), and protect others, yet neonatal microbiome dynamics are poorly understood. Here, we present the first cultivation-independent time series tracking microbiota assembly across multiple body sites in a synchronous cohort of hospitalized low-birthweight (LBW) neonates. We take advantage of archived samples and publically available sequence data and compare our LBW infant findings to those from normal-birthweight (NBW) infants and healthy adults. Our results suggest potential windows of opportunity for the dispersal of microbes within and between hosts and support recent findings of substantial baseline spatiotemporal variation in microbiota composition among high-risk newborns. Complications of premature birth are the most common cause of neonatal mortality. Colonization by the indigenous microbiota, which begins at delivery, may predispose some high-risk newborns to invasive infection or necrotizing enterocolitis (NEC), and protect others, yet neonatal microbiome dynamics are poorly understood. Here, we present the first cultivation-independent time series tracking microbiota assembly across multiple body sites in a synchronous cohort of hospitalized low-birthweight (LBW) neonates. We take advantage of archived samples and publically available sequence data and compare our LBW infant findings to those from normal-birthweight (NBW) infants and healthy adults. Our results suggest potential windows of opportunity for the dispersal of microbes within and between hosts and support recent findings of substantial baseline spatiotemporal variation in microbiota composition among high-risk newborns.

The intestinal microbiome and necrotizing enterocolitis.

Purpose of review Necrotizing enterocolitis (NEC) continues to be a major cause of morbidity and mortality in low birth weight infants. Although decades of research point to a role for gut bacteria in the pathogenesis of the disease, the exact relationship between microbes and NEC has not been elucidated. In this review, we describe recent advances in the use of molecular methods to compare gut bacteria in infants with and without NEC. Recent findings Our understanding of how bacteria contribute to NEC pathogenesis has been limited by the use of traditional, culture-based investigations. Recent advances in microbial ecology and DNA sequencing have made it possible to comprehensively study gut bacterial populations and to understand their physiologic importance. Several studies have identified differences in the microbiota among infants with and without NEC, but the findings have often varied across studies. Summary To date, no single change in the gut microbiota has definitively been identified as a risk factor or cause of NEC. The findings at present suggest that NEC does not result from growth of a single causative pathogen, but rather that the disease results from a generalized disturbance of normal colonization patterns in the developing gut.

Contributions of Intestinal Bacteria to Nutrition and Metabolism in the Critically Ill

Important advances in the study of bacteria associated with the human gastrointestinal tract have significant implications for clinicians striving to meet the metabolic and nutritional needs of critically ill patients. This article offers a broad overview of the importance of the host-microbe relationship, discusses what is currently known about the role of gut microbes in nutrition and metabolism in the healthy human host, reviews how gut microbes are affected by critical illness, and discusses interventions that have already been used to manipulate the gut microbiome in patients in the intensive care unit.

Gram Negative Bacteria Are Associated with the Early Stages of Necrotizing Enterocolitis

Introduction Necrotizing enterocolitis (NEC) affects 5–10% of infants born weighing less than 1500 g. Most models of NEC recapitulate late-stage disease with gut necrosis and elevated inflammatory mediators. Evaluation of NEC at earlier, less lethal stages of disease will allow investigation of initial disease triggers and may advance our understanding of temporal relationships between factors implicated in NEC pathogenesis. In this manuscript, we describe our investigation of early NEC and test the hypothesis that bacteria and inflammatory mediators differ between animals with early NEC and disease free animals. Methods On DOL7 C3HeB/FeJ pups were fed liquid formula with 1×104 Streptococcus thoraltensis, Serratia marcescens, and Pseudomonas aeruginosa every 3 h. To initiate NEC, pups underwent asphyxia (100% N2 for 90 s) and hypothermia (4°C for 10 min) after feeding. Pups were euthanized at 72 h. Intestines were collected for histologic NEC scoring and DNA/RNA extraction. Bacterial populations were identified by 16S rRNA pyrosequencing and principal component analysis (PCA). RNA isolates underwent QRT-PCR for Toll-like Receptor 4 (TLR4) and inducible nitric oxide synthase (iNOS). Results Despite histologic, intestinal damage in mice with NEC, no gross necrosis was observed suggesting early disease. QRT-PCR yielded no difference between groups in TLR4 or iNOS mRNA levels. PCA demonstrated relative clustering of microbial communities based on presence or absence of NEC. 16S pyrosequencing demonstrated similar phyla between groups (Firmicutes and Proteobacteria predominated in all animals). However, the colonic microbiota of animals with NEC had more Citrobacter (p<0.01), Klebsiella (p<0.05), and Tatumella (p<0.05), while that of animals without NEC had more Streptococcus (p<0.01) and Enterococcus (p<0.01). Conclusion Citrobacter, Klebsiella, and Tatumella are associated with NEC. Differential colonic bacteria were identified despite the lack of inflammatory mediator elevation traditionally associated with NEC. This suggests a temporal relationship between bacteria and inflammatory mediators such that alterations in gut microbiota are associated with early NEC, while inflammatory mediator elevation is associated with advanced NEC.

The human microbiome and surgical disease.

Objective:The purpose of this review article is to summarize what is currently known about microbes associated with the human body and to provide examples of how this knowledge impacts the care of surgical patients. Background:Pioneering research over the past decade has demonstrated that human beings live in close, constant contact with dynamic communities of microbial organisms. This new reality has wide-ranging implications for the care of surgical patients. Methods and Results:Recent advances in the culture-independent study of the human microbiome are reviewed. To illustrate the translational relevance of these studies to surgical disease, we discuss in detail what is known about the role of microbes in the pathogenesis of obesity, gastrointestinal malignancies, Crohn disease, and perioperative complications including surgical site infections and sepsis. The topics of mechanical bowel preparation and perioperative antibiotics are also discussed. Conclusions:Heightened understanding of the microbiome in coming years will likely offer opportunities to refine the prevention and treatment of a wide variety of surgical conditions.

Murine gut microbiota and transcriptome are diet dependent.

Objective: Here, we determine how formula feeding impacts the gut microbiota and host transcriptome. Background: Formula-fed (FF) infants are at risk for diseases that involve complex interactions between microbes and host immune elements such as necrotizing enterocolitis. The aims of this study were to simultaneously examine the microbiota and host transcriptional profiles of FF and maternal-fed (MF) mice to evaluate how diet impacts gut colonization and host genes. Methods: After 72 hours of FF or MF, colonic tissue was collected. 16S ribosomal RNA was sequenced with Roche GS-FLX (Genome Sequencer-FLX) pyrosequencing. Operational taxonomical unit clustering, diversity analysis, and principal coordinate analysis (PCA) were performed. Complementary DNA libraries were sequenced by Solexa. Reads were annotated by BLAST (Basic Local Alignment Search Tool) search against mouse RNA database [National Center for Biotechnology Information (NCBI) build-37] and functionally classified using the KOG (Eukaryotic Orthologous Groups) database (NCBI). Results: Firmicutes (P < 0.001) was the dominant phylum in MF pups, whereas Proteobacteria (P < 0.001) and Bacteroidetes (P < 0.05) were dominant in FF mice. On the genus level, FF mice had increased Serratia (P < 0.001) and Lactococcus (P < 0.05) whereas MF mice had increased Lactobacillus (P < 0.001). PCA confirmed clustering by diet. Solexa sequencing demonstrated different (P < 0.05) messenger RNA transcript levels in 148 genes. Heme oxygenase 1 (P < 0.01), an oxidative stress marker, was increased 25-fold in FF mice. In addition, decreased vinculin (P < 0.05), a cytoskeletal protein associated with adherens junctions in FF pups suggested impaired gut structural integrity. Diet also impacted immune regulation, cell cycle control/gene expression, cell motility, and vascular function genes. Conclusions: FF shifted gut microbiota and structural integrity, oxidative stress, and immune function genes, presumably increasing vulnerability to disease in FF mice. Interrogation of microbial and host gene expression in FF neonates may offer new insight on how diet affects disease pathogenesis.

The umbilical mass: a rare neonatal anomaly

Umbilical anomalies are a rare presentation in the pediatric patient. The differential diagnosis includes anomalies resulting from urachal and vitelline duct derivatives such as urachal sinus, urachal cyst, urachal diverticulum, patent urachus, herniated Meckel’s diverticulum, umbilico-enteric fistula, or umbilical polyp. In this article, a case presentation of an umbilical anomaly along with the differential diagnosis and management options are discussed. Based upon this review of the literature, the authors propose a management algorithm for treating children with umbilical anomalies.

Pediatric surgery and the human microbiome

Bold advances in the past decade have made it possible to carefully study the contributions of microbes to normal human development and to disease pathogenesis. The intestinal microbiota has been implicated in adult diseases ranging from obesity to cancer, but there have been relatively few investigations of bacteria in surgical diseases of infancy and childhood. In this review, we discuss how novel culture-independent approaches have been harnessed to profile microbes present within clinical specimens. Unique features of the pediatric microbiota and innovative approaches to manipulate the gut flora are also reviewed. Finally, we detail the contributions of gut microbes to 3 diseases relevant to pediatric surgeons: necrotizing enterocolitis, obesity, and inflammatory bowel disease. Current and future research regarding the pediatric microbiota is likely to translate to improved outcomes for infants and children with surgical diseases.

Adult to adult living related liver transplantation： Where do we currently stand？

Adult to adult living donor liver transplantation (AALDLT) was first preformed in the United States in 1997. The procedure was rapidly integrated into clinical practice, but in 2002, possibly due to the first widely publicized donor death, the number of living liver donors plummeted. The number of donors has since reached a steady plateau far below its initial peak. In this review we evaluate the current climate of AALDLT. Specifically, we focus on several issues key to the success of AALDLT: determining the optimal indications for AALDLT, balancing graft size and donor safety, assuring adequate outflow, minimizing biliary complications, and maintaining ethical practices. We conclude by offering suggestions for the future of AALDLT in United States transplantation centers.

Candidatus Mycoplasma girerdii replicates, diversifies, and co-occurs with Trichomonas vaginalis in the oral cavity of a premature infant

Genital mycoplasmas, which can be vertically transmitted, have been implicated in preterm birth, neonatal infections, and chronic lung disease of prematurity. Our prior work uncovered 16S rRNA genes belonging to a novel, as-yet-uncultivated mycoplasma (lineage ‘Mnola’) in the oral cavity of a premature neonate. Here, we characterize the organism’s associated community, growth status, metabolic potential, and population diversity. Sequencing of genomic DNA from the infant’s saliva yielded 1.44 Gbp of high-quality, non-human read data, from which we recovered three essentially complete (including ‘Mnola’) and three partial draft genomes (including Trichomonas vaginalis). The completed 629,409-bp ‘Mnola’ genome (Candidatus Mycoplasma girerdii str. UC-B3) was distinct at the strain level from its closest relative, vaginally-derived Ca. M. girerdii str. VCU-M1, which is also associated with T. vaginalis. Replication rate measurements indicated growth of str. UC-B3 within the infant. Genes encoding surface-associated proteins and restriction-modification systems were especially diverse within and between strains. In UC-B3, the population genetic underpinnings of phase variable expression were evident in vivo. Unique among mycoplasmas, Ca. M. girerdii encodes pyruvate-ferredoxin oxidoreductase and may be sensitive to metronidazole. This study reveals a metabolically unique mycoplasma colonizing a premature neonate, and establishes the value of genome-resolved metagenomics in tracking phase variation.