Your search keyword '"Heinsen, Femke-Anouska"' showing total 6 results

1. Comparative Studies of the Gut Microbiota in the Offspring of Mothers With and Without Gestational Diabetes.

Author

Crusell, Mie Korslund Wiinblad, Hansen, Tue Haldor, Nielsen, Trine, Allin, Kristine Højgaard, Rühlemann, Malte C., Damm, Peter, Vestergaard, Henrik, Rørbye, Christina, Jørgensen, Niklas Rye, Christiansen, Ole Bjarne, Heinsen, Femke-Anouska, Franke, Andre, Hansen, Torben, Lauenborg, Jeannet, and Pedersen, Oluf

Subjects

GESTATIONAL diabetes, GUT microbiome, SURROGATE mothers, MATERNAL age, ENVIRONMENTAL exposure, MOTHER-child relationship, COMPARATIVE studies

Abstract

Background: Offspring of mothers with gestational diabetes mellitus (GDM) have increased risk of developing metabolic disorders as they grow up. Microbial colonization of the newborn gut and environmental exposures affecting the configuration of the gut microbiota during infancy have been linked to increased risk of developing disease during childhood and adulthood. In a convenience sample, we examined whether the intestinal tract of children born to mothers with GDM is differentially colonized in early life compared to offspring of mothers with normal gestational glucose regulation. Secondly, we examined whether any such difference persists during infancy, thus potentially conferring increased risk of developing metabolic disease later in life. Methods: Fecal samples were collected from children of mothers with (n = 43) and without GDM (n = 82) during the first week of life and again at an average age of 9 months. The gut microbiota was characterized by 16S rRNA gene amplicon sequencing (V1–V2). Differences in diversity and composition according to maternal GDM status were assessed, addressing potential confounding by mode of delivery, perinatal antibiotics treatment, feeding and infant sex. Results: Children of mothers with GDM were featured by a differential composition of the gut microbiota, both during the first week of life and at 9 months, at higher taxonomic and OTU levels. Sixteen and 15 OTUs were differentially abundant after correction for multiple testing during the first week of life and at 9 months, respectively. Two OTUs remained differentially abundant after adjustment for potential confounders both during the first week of life and at 9 months. Richness (OTU) was decreased in neonates born to mothers with GDM; however, at 9 months no difference in richness was observed. There was no difference in Shannon's diversity or Pielou's evenness at any timepoint. Longitudinally, we detected differential changes in the gut microbiota composition from birth to infancy according to GDM status. Conclusion: Differences in glycaemic regulation in late pregnancy is linked with relatively modest variation in the gut microbiota composition of the offspring during the first week of life and 9 months after birth. [ABSTRACT FROM AUTHOR]

Published

2020

2. Hypothalamic Inflammation in Human Obesity Is Mediated by Environmental and Genetic Factors.

Author

Kreutzer, Carina, Peters, Sönke, Schulte, Dominik M., Fangmann, Daniela, Türk, Kathrin, Wolff, Stephan, van Eimeren, Thilo, Ahrens, Markus, Beckmann, Jan, Schafmayer, Clemens, Becker, Thomas, Kerby, Tina, Rohr, Axel, Riedel, Christian, Heinsen, Femke-Anouska, Degenhardt, Frauke, Franke, Andre, Rosenstiel, Philip, Zubek, Nana, and Henning, Christian

Subjects

OBESITY genetics, INFLAMMATION, OBESITY, BARIATRIC surgery, GENETIC polymorphisms, BACTERIA classification, HYPOTHALAMUS physiology, RNA metabolism, GUT microbiome, GENES, HYPERLIPIDEMIA, HYPOTHALAMUS, INSULIN resistance, MAGNETIC resonance imaging, RNA, CASE-control method

Abstract

Obesity is associated with hypothalamic inflammation (HI) in animal models. In the current study, we examined the mediobasal hypothalamus (MBH) of 57 obese human subjects and 54 age- and sex- matched nonobese control subjects by MRI and analyzed the T2 hyperintensity as a measure of HI. Obese subjects exhibited T2 hyperintensity in the left but not the right MBH, which was strongly associated with systemic low-grade inflammation. MRS revealed the number of neurons in the left hypothalamic region to be similar in obese versus control subjects, suggesting functional but not structural impairment due to the inflammatory process. To gain mechanistic insights, we performed nutritional analysis and 16S rDNA microbiome sequencing, which showed that high-fat diet induces reduction of Parasutterella sp. in the gut, which is significantly correlated with MBH T2 hyperintensity. In addition to these environmental factors, we found subjects carrying common polymorphisms in the JNK or the MC4R gene to be more susceptible to HI. Finally, in a subgroup analysis, bariatric surgery had no effect on MBH T2 hyperintensity despite inducing significant weight loss and improvement of peripheral insulin sensitivity. In conclusion, obesity in humans is associated with HI and disturbances in the gut-brain axis, which are influenced by both environmental and genetic factors. [ABSTRACT FROM AUTHOR]

Published

2017

3. Beneficial Effects of a Dietary Weight Loss Intervention on Human Gut Microbiome Diversity and Metabolism Are Not Sustained during Weight Maintenance.

Author

Heinsen, Femke-anouska, Fangmann, Daniela, Müller, Nike, Schulte, Dominik M., Rühlemann, Malte C., Türk, Kathrin, Settgast, Ute, Lieb, Wolfgang, Baines, John F., Schreiber, Stefan, Franke, andre, and Laudes, Matthias

Subjects

LOW-calorie diet, WEIGHT loss, GUT microbiome, PREVENTION of obesity, METABOLISM

Abstract

Objective: In the present study, we examined the effect of a very low-calorie diet(VLCD)- based obesity program on human gut microbiome diversity and metabolism during weight loss and weight maintenance. Methods: Obese subjects underwent 3 months of VLCD followed by 3 months of weight maintenance. A lean and an obese control group were included. The microbiome was characterized by performing high-throughput dual-indexed 16S rDNA amplicon sequencing. Results: At baseline, a significant difference in the Firmicutes/Bacteroidetes ratio between the lean and obese individuals was observed (p = 0.047). The VLCD resulted in significant alterations in gut microbiome diversity from baseline to 3 months (p = 0.0053). Acinetobacter represented an indicator species for the observed effect (indicator value = 0.998, p = 0.006). Metabolic analyses revealed alterations of the bacterial riboflavin pathway from baseline to 3 months (pnom = 0.0078). These changes in diversity and bacterial metabolism induced by VLCD diminished during the weight maintenance phase, despite sustained reductions in body weight and sustained improvements of insulin sensitivity. Conclusion: The present data show that a VLCD is able to beneficially alter both gut microbiome diversity and metabolism in obese humans, but that these changes are not sustained during weight maintenance. This finding might suggest that the microbiome should be targeted during obesity programs. [ABSTRACT FROM AUTHOR]

Published

2017

4. Effects of β-Lactam Antibiotics and Fluoroquinolones on Human Gut Microbiota in Relation to Clostridium difficile Associated Diarrhea.

Author

Knecht, Henrik, Neulinger, Sven C., Heinsen, Femke Anouska, Knecht, Carolin, Schilhabel, Anke, Schmitz, Ruth A., Zimmermann, Alexandra, dos Santos, Vitor Martins, Ferrer, Manuel, Rosenstiel, Philip C., Schreiber, Stefan, Friedrichs, Anette K., and Ott, Stephan J.

Subjects

DIARRHEA, THERAPEUTICS, BETA lactam antibiotics, FLUOROQUINOLONES, GUT microbiome, CLOSTRIDIOIDES difficile, NOSOCOMIAL infections

Abstract

Clostridium difficile infections are an emerging health problem in the modern hospital environment. Severe alterations of the gut microbiome with loss of resistance to colonization against C. difficile are thought to be the major trigger, but there is no clear concept of how C. difficile infection evolves and which microbiological factors are involved. We sequenced 16S rRNA amplicons generated from DNA and RNA/cDNA of fecal samples from three groups of individuals by FLX technology: (i) healthy controls (no antibiotic therapy); (ii) individuals receiving antibiotic therapy (Ampicillin/Sulbactam, cephalosporins, and fluoroquinolones with subsequent development of C. difficile infection or (iii) individuals receiving antibiotic therapy without C. difficile infection. We compared the effects of the three different antibiotic classes on the intestinal microbiome and the effects of alterations of the gut microbiome on C. difficile infection at the DNA (total microbiota) and rRNA (potentially active) levels. A comparison of antibiotic classes showed significant differences at DNA level, but not at RNA level. Among individuals that developed or did not develop a C. difficile infection under antibiotics we found no significant differences. We identified single species that were up- or down regulated in individuals receiving antibiotics who developed the infection compared to non-infected individuals. We found no significant differences in the global composition of the transcriptionally active gut microbiome associated with C. difficile infections. We suggest that up- and down regulation of specific bacterial species may be involved in colonization resistance against C. difficile providing a potential therapeutic approach through specific manipulation of the intestinal microbiome. [ABSTRACT FROM AUTHOR]

Published

2014

5. Gut microbiota disturbance during antibiotic therapy: a multi-omic approach.

Author

Pérez-Cobas, Ana Elena, Gosalbes, María José, Friedrichs, Anette, Knecht, Henrik, Artacho, Alejandro, Eismann, Kathleen, Otto, Wolfgang, Rojo, David, Bargiela, Rafael, Bergen, Martin von, Neulinger, Sven C., Däumer, Carolin, Heinsen, Femke-Anouska, Latorre, Amparo, Barbas, Coral, Seifert, Jana, dos Santos, Vitor Martins, Ott, Stephan J., Ferrer, Manuel, and Moya, Andrés

Subjects

GUT microbiome, ANTIBIOTICS, RECOMBINANT DNA, CHOLESTEROL, HORMONES

Abstract

Objective: Antibiotic (AB) usage strongly affects microbial intestinal metabolism and thereby impacts human health. Understanding this process and the underlying mechanisms remains a major research goal. Accordingly, we conducted the first comparative omic investigation of gut microbial communities in faecal samples taken at multiple time points from an individual subjected to β-lactam therapy. Methods: The total (16S rDNA) and active (16S rRNA) microbiota, metagenome, metatranscriptome (mRNAs), metametabolome (high-performance liquid chromatography coupled to electrospray ionisation and quadrupole time-of-flight mass spectrometry) and metaproteome (ultra high performing liquid chromatography coupled to an Orbitrap MS instrument [UPLC-LTQ Orbitrap-MS/MS]) of a patient undergoingAB therapy for 14 days were evaluated. Results: Apparently oscillatory population dynamics were observed, with an early reduction in Gram-negative organisms (day 6) and an overall collapse in diversity and possible further colonisation by 'presumptive' naturally resistant bacteria (day 11), followed by the re-growth of Gram-positive species (day 14). During this process, the maximum imbalance in the active microbial fraction occurred later (day 14) than the greatest change in the total microbial fraction, which reached a minimum biodiversity and richness on day 11; additionally, major metabolic changes occurred at day 6. Gut bacteria respond to ABs early by activating systems to avoid the antimicrobial effects of the drugs, while 'presumptively' ttenuating their overall energetic metabolic status and the capacity to transport and metabolise bile acid, cholesterol, hormones and vitamins; host-microbial interactions significantly improved after treatment cessation. Conclusions: This proof-of-concept study provides an extensive description of gut microbiota responses to followup β-lactam therapy. The results demonstrate that ABs targeting specific pathogenic infections and diseases may alter gut microbial ecology and interactions with host metabolism at a much higher level than previously assumed. [ABSTRACT FROM AUTHOR]

Published

2013

6. Stool frequency is associated with gut microbiota composition.

Author

Hadizadeh, Fatemeh, Walter, Susanna, Belheouane, Meriem, Bonfiglio, Ferdinando, Heinsen, Femke-Anouska, Andreasson, Anna, Agreus, Lars, Engstrand, Lars, Baines, John F., Rafter, Joseph, Franke, Andre, and D'Amato, Mauro

Subjects

FECES, MICROBIOLOGY, GUT microbiome, ENTEROTYPES

Published

2017