Molecular biomarkers are valuable tools to predict the disease and determine its course. Several markers have been associated with inflammatory bowel disease (IBD) and irritable bowel syndrome (IBS); Show more
Molecular biomarkers are valuable tools to predict the disease and determine its course. Several markers have been associated with inflammatory bowel disease (IBD) and irritable bowel syndrome (IBS); however, none is sufficiently reliable to enable accurate diagnosis. We characterized a broad panel of serum proteins to assess disease-specific biomarker profiles and associate these findings with faecal microbiota composition in newly diagnosed IBD and IBS patients and healthy individuals. The study cohort consisted of 49 newly diagnosed treatment-naïve adult patients (13 Crohn's disease (CD), 13 ulcerative colitis (UC), and 23 IBS) and 12 healthy individuals. Inflammatory and metabolism-related serum proteins were assessed using PEA multiplex panels, while gut microbiota composition was determined by 16 s rRNA gene amplicon sequencing. Serum proteins AXIN1, TNFSF14, RNASE3, EN-RAGE, OSM, ST1A1, CA13 and NADK were identified as markers with the most promising specificity/sensitivity and predictivity between healthy and disease groups, while IL-17A and TNFRSF9 enabled differentiation between IBD and IBS patients. Increased abundance of Enterobacteriaceae was associated with protein markers significantly elevated in IBD/IBS. In contrast, depletion of beneficial taxa like Ruminococcaceae and Verucomicrobiaceae (i.e. Akkermansia muciniphila) was associated with decrease of a set of markers in diseased groups. Differences in the abundance of Turicibacteriaceae were more predictive to discern CD from UC than any of the serum proteins investigated. By using a broad panel of inflammation and metabolism-related proteins, we determined serum markers with significantly different levels in treatment-naïve IBD and IBS patients compared to healthy individuals, as well as between IBD and IBS. KEY MESSAGES : Significant changes in the levels of several serum proteins and abundances of faecal bacterial taxa between study groups were found. Increased levels of AXIN1, TNFSF14, RNASE3, EN-RAGE, OSM, ST1A1, CA13 and NADK characterize both IBD and IBS, while IL-17A and TNFRSF9 differentiate IBD from IBS. Increase of Enterobacteriaceae and depletion of beneficial taxa Ruminococcaceae and Verucomicrobiaceae (i.e. Akkermansia muciniphila) was found in IBD and IBS. Differences in Turicibacteriaceae were more predictive to discern CD from UC than any of the serum proteins investigated. Show less
We have previously found that in utero exposure to excess maternal cortisol (1 mg/kg/day) in late gestation increases the incidence of stillbirth during labor and produces fetal bradycardia at birth. Show more
We have previously found that in utero exposure to excess maternal cortisol (1 mg/kg/day) in late gestation increases the incidence of stillbirth during labor and produces fetal bradycardia at birth. In the interventricular septum, mitochondrial DNA (mt-DNA) was decreased, and transcriptomics and metabolomics were consistent with altered mitochondrial metabolism. The present study uses transcriptomics to model effects of increased maternal cortisol on fetal biceps femoris. Transcriptomic modeling revealed that pathways related to mitochondrial metabolism were downregulated, whereas pathways for regulation of reactive oxygen species and activation of the apoptotic cascade were upregulated. Mt-DNA and the protein levels of cytochrome C were significantly decreased in the biceps femoris. RT-PCR validation of the pathways confirmed a significant decrease in SLC2A4 mRNA levels and a significant increase in PDK4, TXNIP, ANGPTL4 mRNA levels, suggesting that insulin sensitivity of the biceps femoris muscle may be reduced in cortisol offspring. We also tested for changes in gene expression in diaphragm by rt-PCR. PDK4, TXNIP, and ANGPTL4 mRNA were also increased in the diaphragm, but SLC2A4, cytochrome C protein, and mt-DNA were unchanged. Comparison of the change in gene expression in biceps femoris to that in cardiac interventricular septum and left ventricle showed few common genes and little overlap in specific metabolic or signaling pathways, despite reduction in mt-DNA in both heart and biceps femoris. Our results suggest that glucocorticoid exposure alters expression of nuclear genes important to mitochondrial activity and oxidative stress in both cardiac and skeletal muscle tissues, but that these effects are tissue-specific. Show less