Machine Learning-based Analysis of the Relationship Between the Human Gut Microbiome and Bone Health

January 2020

abstract: The Human Gut Microbiome (GM) modulates a variety of structural, metabolic, and protective functions to benefit the host. A few recent studies also support the role of the gut microbiome in the regulation of bone health. The relationship between GM and bone health was analyzed based on the data collected from a group of twenty-three adolescent boys and girls who participated in a controlled feeding study, during which two different doses (0 g/d fiber and 12 g/d fiber) of Soluble Corn Fiber (SCF) were added to their diet. This analysis was performed by predicting measures of Bone Mineral Density (BMD) and Bone Mineral Content (BMC) which are indicators of bone strength, using the GM sequence of proportions of 178 microbes collected from 23 subjects, by building a machine learning regression model. The model developed was evaluated by calculating performance metrics such as Root Mean Squared Error, Pearson’s correlation coefficient, and Spearman’s rank correlation coefficient, using cross-validation. A noticeable correlation was observed between the GM and bone health, and it was observed that the overall prediction correlation was higher with SCF intervention (r ~ 0.51). The genera of microbes that played an important role in this relationship were identified. Eubacterium (g), Bacteroides (g), Megamonas (g), Acetivibrio (g), Faecalibacterium (g), and Paraprevotella (g) were some of the microbes that showed an increase in proportion with SCF intervention. / Dissertation/Thesis / Masters Thesis Electrical Engineering 2020

Electrical engineering

Bone Health

Cross-Validation

Human Gut Microbiome

Machine Learning

Soluble Corn Fiber

Genetic Characterization of the Gut Microbiome of Hajj Pilgrims

Beaudoin, Christopher

05 1900

Hajj, the annual Islamic pilgrimage to Makkah, Saudi Arabia, is a unique mass gathering event that brings more than 2 million individuals from around the world. Several public health considerations, such as the spread of infectious diseases, must be taken into account with this large temporary influx of people. Gastrointestinal diseases, such as diarrhea, are common at Hajj, yet little is known about the etiology. The human gut microbiome, collection of organisms residing within the intestinal tract, has been under intense study recently, since next generation DNA sequencing technologies allow for extensive surveying of genetic material found in complex biological samples, such as those containing many different organisms. Thus, using 16S rRNA and metagenomic shotgun sequencing, we have characterized the gut microbiome of over 612 pilgrims with and without diarrhea. Several metadata factors, such as hospitalization and different comorbidities, were found to have significant effects on the overall gut microbiome composition. Metagenomic shotgun sequencing efforts revealed the presence of antimicrobial resistance genes originating from disparate regions from around the world. This study provides a snapshot of information concerning the health status of the gut microbiome of Hajj pilgrims and provides more context to the investigation of how to best prepare for mass gathering events.

Hajj Pilgrimage

gut microbiome

metagenomic shotgun sequencing

16S rRNA sequencing

antimicrobial resistance

mass gathering event

Immune Challenge During Puberty: Role of the Gut Microbiota and Neurobehavioural Outcomes

Murray, Emma

06 May 2020

Puberty is a critical period of development characterized by rapid physiological changes and significant brain reorganizing and remodeling. These rapid changes render the developing brain particularly vulnerable to stress and immune challenge. In mice, exposure to an immune challenge (lipopolysaccharide; LPS) during puberty causes enduring effects on stress reactivity, cognitive functioning, and depression- and anxiety-like behaviors later in life. However, the mechanisms underlying these effects are unknown. The gut microbiome can profoundly influence the immune system. There is also close bidirectional communication between the gut microbiome and the central nervous system (CNS) through neural, endocrine and immune signaling pathways, which can alter brain chemistry and emotional behaviour. Thus, we hypothesized that altering microbial composition during puberty could mitigate acute immune responses and prevent enduring outcomes later in life. The current thesis examined the effect of gut manipulation with probiotics during puberty on LPS-induced immune responses and enduring anxiety- and depression-like behaviours, and stress-reactivity in adulthood, in male and female CD1 mice (Article 1). Next, we examined age and sex differences in gut microbial composition before and after exposure to an immune challenge. We also examined the effects of consuming a single strain probiotic bacterium (Lactobacillus Reuteri) during puberty on the immune response and the long-term changes in memory, anxiety-like behavior, and stress reactivity in adulthood (Article 2). Lastly, we examined how microbial colonization between pubertal and adult mice can alter acute peripheral and central inflammatory responses to LPS (Article 3). The current dissertation has addressed sex-specific vulnerabilities to an immune challenge during pubertal development and the moderating influence of the gut microbiome. These studies have demonstrated that manipulating the gut microbiome during puberty can mitigate acute immune responses and prevent enduring neurobehavioural outcomes later in life.

Puberty

Sex differences

Gut microbiome

Probiotic

Lactobacillus

Lipopolysaccharide

Anxiety

Depression

Gut-Brain Axis

Immune challenge

Development

Bacterial translocation to adipose tissue in metabolic disease

Massier, Lucas

23 October 2020

Alterations in composition and function of human gut microbiota can affect physiological processes and are known to be associated with many diseases including inflammatory bowel disease, hypertension, asthma and colon cancer. Complex interactions between gut microbiota, environmental toxins, nutrients and host genetics may result in an increased permeability of the gut, which is closely linked to the presence of adverse metabolic conditions. As a consequence, translocation of bacterial DNA into the blood circulation increases in patients with obesity. Obesity is a growing health problem worldwide and often paired with severe secondary complications, such as type 2 diabetes or cardiovascular problems. A main feature of disease progression is a chronic low-grade inflammation of adipose tissue which contributes to the development and aggravation of insulin resistance and many of the underlying mechanisms are still unknown. Although data from mice studies suggest that the presence of bacterial components in adipose tissue can support these processes, human studies on this subject are lacking. In my thesis entitled ``Bacterial translocation to adipose tissue in metabolic diseas'' I provide evidence supporting the initial hypothesis, namely that bacterial DNA is present in adipose tissue, even after stringent controlling for contaminants. To this end, I established a wet lab routine protocol to eliminate contamination as well as a bioinformatics pipeline accounting for contamination by subtracting negative controls. Briefly, this included the use of lab ware and reagents UV-treated for at least 90 minutes, the use of breath protection, extra-long gloves and single-use lab coats as well as working under a sterile laminar flood hood in a clean lab free of any PCR products. The bioinformatics pipeline employed commonly used 16S rRNA gene analysis tools including qiime2, phyloseq and DESeq2 as well as decontam, a novel tool to extract negative controls. Observed quantity of bacterial DNA was in the range of 1 to 10 pg/µg total isolated genomic DNA, which is equivalent to about 0.01 to 0.7% of bacterial cells per human cell. The highest quantity was present in subcutaneous adipose tissue, followed by mesenteric adipose tissue. Bacterial amount correlated with adipose tissue macrophages and PPARG expression in omental and with IL1B and TNF expression in subcutaneous adipose tissue. Mesenteric adipose tissue showed the highest diversity of the observed genera. The most commonly observed phyla in all tissues were Proteobacteria and Firmicutes, which is in line with previously published data on blood bacterial DNA. Still, many genera were predominantly found in specific tissues, e.g. Enterobacter in subcutaneous and Acinetobacter in omental adipose tissue. I further showed that the distribution of observed features could partially be explained by markers of insulin resistance (HOMA-IR, HbA1c) and inflammation (IL-6, TNFa, macrophages) and that certain genera, such as Rhodoferax or Lactobacillus are associated with type 2 diabetes status. In first functional approaches I demonstrated that concentrations of bacterial DNA in the observed range are sufficient to stimulate an inflammatory response in immortalized subcutaneous adipocytes derived from a healthy donor. The effect was most prominent after four hours of treatment and increased in a dose-dependent matter. One of the aims in the present study was to determine levels of gut leakage by measuring zonulin, the most commonly used biomarker for intestinal permeability in humans, and analyze possible associations with adipose tissue bacterial signature. As there are few well-conducted studies on circulating zonulin levels in patients with metabolic diseases, I first performed a correlation study in the available and metabolically well-characterized Sorbs cohort. Circulating zonulin correlated significantly positive with BMI, fasting glucose, triglycerides and cholesterol and negatively with HOMA-IS, high density lipoprotein and circulating adiponectin levels. Albeit these strong correlations with markers of glucose and lipid metabolism supported previously reported findings, the results pointed to some inconsistencies. As zonulin is reported to be pre-haptoglobin 2 (preHP2), and about 15% percent of a typical western European population are homozygous for haptoglobin 1, they should not express zonulin at all. I confirmed in the Sorbs cohort previously reported distributions of haptoglobin genotypes and showed that the target of the only commercially available zonulin ELISA kit was not related to haptoglobin genotype, therefore presumably not measuring zonulin/ preHP2. Subsequently, I identified properdin as a possible target by employing mass spectrometry approaches. Properdin is structurally related to haptoglobin, as both proteins belong to the mannose-associated serine protease family, however further experiments are needed to validate a possible functional resemblance. In regard to bacterial translocation two adipose tissue depots were of notable interest due to their close proximity to the gastrointestinal tract. Mesenteric adipose tissue is located around the small intestine and the adipose tissue of the appendices epiploicae, small chunks of fat also called epiploic adipose tissue, are directly attached to the colon. After a thorough literature research I could also assert that both adipose tissues were rarely analyzed in the context of obesity. Therefore they were extensively investigated by measuring gene expression of adipo(cyto)kines, circulating inflammatory markers and analyzing adipocyte size and adipose tissue macrophages. Furthermore, a ``multiomics'' characterization was conducted and by analyzing transcriptome and methylome data I could identify epiploic adipose tissue as a tissue of interest in regard to type 2 diabetes and insulin resistance, which was further confirmed by untargeted proteomics data. Contrary to initial assumptions, I observed only a slight increase in translocation of bacterial DNA and no increased inflammation, as measured by tissue specific TNF and IL6 expression as well as adipose tissue macrophage infiltration. However, both transcriptome and proteome profiles allowed a clear discrimination of patients with and without insulin resistance which was most distinct in epiploic adipose tissue. Compared to other fat depots, epiploic adipose tissue exhibited a discriminable metabolic profile whereas mesenteric adipose tissue was more similar to omental-visceral adipose tissue. Most strikingly, epiploic adipose tissue showed a strong increase in leptin expression and, in general, the upregulation of various metabolic pathways involved in sugar, amino acid or sphingolipid metabolism. In accord with the leaky gut hypothesis high expression of lipopolysaccharide binding protein and various pathways involved in chemokine signaling were observed. In summary, I did not observe an increase in bacterial DNA or adipose tissue macrophages, but demonstrated elevated inflammatory signals such as increased chemokine or IL-8 signaling which are linked with an overall increase of metabolic processes and an increased expression of various adipokines. Epiploic adipose tissue might have a watch dog function by being the first adipose tissue sensing and forwarding certain (microbial) stimuli from the large intestine to the host. In the last part of my thesis I addressed a possible role of the HLA genomic region on the development of type 2 diabetes. The influence of HLA genetics on type 2 diabetes has been under debate for several decades, since HLA was recognized to largely contribute to type 1 diabetes heritability. However, studies remained inconclusive due to lacking cohorts with sample sizes providing sufficient statistical power for association analyses. More recently, animal studies suggested MHC class II proteins as crucial factors mediating adipose tissue inflammation and insulin resistance. The sample size of the leaky gut cohort was insufficient to determine any correlation between HLA class II genotypes and the presence or type of bacteria in adipose tissue due to the high variability in the observed genomic region. Yet, I had access to three large population-based cohorts which allowed me to analyze associations between HLA class II alleles and type 2 diabetes. Therefore HLA genotypes of the LIFE-Adult (N=4649), LIFE-Heart (N=4815) and Sorbs (N=949) cohort were imputed from SNP genotyping data and analyzed for association with type 2 diabetes. In a meta-analysis including all three cohorts, I identified a protective effect for the well-established type 1 diabetes protective haplotype DRB1*15:01~DQA1*01:02~DQB1*06:02 and confirmed DRB1*07:01~DQA1*02:01~DQB1*03:03 as a risk haplotype in non-insulin treated diabetes. These results suggest that the genetic foundation of both type 1 and 2 diabetes shares common elements involving the HLA class II locus. In conclusion, to the best of my knowledge, I provide in my work the first contaminant-aware identification of bacterial DNA in human adipose tissue and highlight the importance of analyzing novel adipose tissue depots by showing that fat of the appendices epiploicae, previously only considered to have a cushioning function, is metabolically active and possibly involved in the development of insulin resistance.

info:eu-repo/classification/ddc/610

ddc:610

Studying the Temporal Dynamics of the Gut Microbiota Using Metabolic Stable Isotope Labeling and Metaproteomics

Smyth, Patrick

29 June 2021

The gut microbiome and its metabolic processes are dynamic systems. Surprisingly, our understanding of gut microbiome dynamics is limited. Here we report a metaproteomic workflow that involves protein stable isotope probing (protein-SIP) and identification/quantification of partially labeled peptides. We also developed a package, which we call MetaProfiler, that corrects for false identifications and performs phylogenetic and time series analysis for the study of microbiome dynamics. From the stool sample of five mice that were fed with 15-N hydrolysate from Ralstonia eutropha, we identified 15,297 non-redundant unlabeled peptides of which 10,839 of their heavy counterparts were quantified. These peptides revealed incorporation profiles over time that were different between and within taxa, as well as between and within clusters of orthologous groups (COGs). Our study helps unravel the complex dynamics of protein synthesis and bacterial dynamics in the mouse gut microbiome.

Gut Microbiome

Temporal Dynamics

Metaproteomics

15N Labeling

Protein-Based Stable Isotope Probing

Partial Labeling

Bacteriophage technologies and their application to synthetic gene networks

Krom, Russell-John

03 November 2015

Synthetic biology, a field that sits between Biology and Engineering disciplines, has come into its own in the last decade. The decreasing cost of DNA synthesis has lead to the creation of larger and more complex synthetic gene networks, engineered with functional goals rather than simple demonstration. While many methods have been developed to reduce the time required to produce complex networks, none focus upon the considerable tuning needed to turn structurally correct networks into functional gene networks. To this end, we created a Plug-and-Play synthetic gene network assembly that emphasizes character-driven iteration for producing functional synthetic gene networks. This platform enables post-construction modification and easy tuning of networks through its ability to swap individual parts. To demonstrate this system, we constructed a functional bistable genetic toggle and transformed it into two functionally distinct synthetic networks. Once these networks have been created and tuned at the bench, they next must be delivered to bacteria in their target environment. While this is easy for industrial applications, delivering synthetic networks as medical therapeutics has a host of problems, such as competing microbes, the host immune system, and harsh microenvironments. Therefore, we employed bacteriophage technologies to deliver functional synthetic gene networks to specific bacterial strains in various microenvironments. We first sought to deliver functional genetic networks to bacteria present in the gut microbiome. This allows for functionalization of these bacteria to eventually sense disease states and secrete therapeutics. As a proof of concept a simple circuit was created using the Plug-and-Play platform and tested before being moved into the replicative form plasmid of the M13 bacteriophage. Bacteriophage particles carrying this network were used to infect gut bacteria of mice. Infection and functionality of the synthetic network was monitored from screening fecal samples. Next, we employed phagemid technologies to deliver high copy plasmids expressing antibacterial networks to target bacteria. This allows for sustained expression of antibacterial genes that cause non-lytic bacterial death without reliance upon traditional small molecule antibiotics. Phagemid particles carrying our antibacterial networks were then tested against wild type and antibiotic-resistant bacteria in an in vitro and in vivo environment.

Biomedical engineering

Bacterial infections

Bacteriophage technologies

Gut microbiome

Medical therapeutics

Synthetic biology

Synthetic gene networks

Impact of Basal Diet on Obesity Phenotype of Recipient Mice Following Fecal Microbiome Transfer from Obese or Lean Human Donors

Rodriguez Jimenez, Daphne Michelle

01 August 2018

The composition of the gut microbiome can be affected by environmental factors, such as diet. The Western dietary pattern is associated with microbiome dysbiosis and adverse health outcomes, including obesity and metabolic disorders. The objective of this study was to examine the effect of gut microbiota from lean or obese human donors on metabolism and weight gain in recipient mice fed one of three basal diets: 1) the standard AIN93G diet, which promotes rodent health; 2) the total Western diet (TWD), which mimics the American dietary pattern and promotes inflammation-associated colorectal carcinogenesis; and 3) a 45% high fat diet-induced obesity (DIO) diet, which promotes excessive weight gain and symptoms of metabolic syndrome. We hypothesized that fecal microbiome transfer (FMT)from obese human donors would lead to an obese phenotype with symptoms of metabolic syndrome in recipient mice, and that consumption of TWD or DIO diets would further exacerbate the metabolic syndrome phenotype. The experiment design consisted of two main factors: body type of the human donor (obese or lean) and experimental diet (AIN, DIO or TWD), which was fed to mice for 22 weeks. Prior to FMT, the resident gut microbiome in mice was depleted using an established broad spectrum antibiotic/antifugal oral dosing regimen. Interestingly, human donor body type did not significantly affect final body weight or body composition in recipient

fecal bacteria

obesity

basal diet

Western diet

gut microbiome

Animal Sciences

Dairy Science

Veterinary Medicine

Phenylethylamine Derivatives: Pharmacological and Toxicological Studies

Aburahma, Amal

January 2021

No description available.

Chemistry

Pharmacology

Toxicology

Drugs of abuse

Phenylethylamines

Hyperthermia

Microdialysis

FMT

Gut microbiome

methamphetamine

MDMA

MDPV

Elucidating Tomato Steroidal Glycoalkaloid Metabolism and Effects of Consumption onthe Gut Microbiome in a Pig Model

Goggans, Mallory

January 2020

No description available.

Food Science

steroidal glycoalkaloids

tomatoes

tomatoes and human health

gut microbiome

microbiome

phytochemicals

phytochemical metabolism

Assessing and Evaluating Biomarkers and Chemical Markers by Targeted and Untargeted Mass Spectrometry-based Metabolomics

Yang, Kundi

11 November 2020

No description available.

Chemistry

Analytical Chemistry

Biochemistry

targeted metabolomics

untargeted metabolomics

mass spectrometry

gut microbiome

bourbon fingerprint