Browsing by Subject "Darmmikrobiom"

Now showing 1 - 3 of 3
  • Thumbnail Image
    Publication
    Effects of diets with different phosporus availability on the intestinal microbiota of chickens and pigs
    (2019) Tilocca, Bruno; Seifert, Jana
    In the research works of the present thesis, 16S rRNA gene sequencing and metaproteomics were employed to investigate the gut microbiota of chickens and pigs kept at experimental diets with varying amount of calcium-phosphorus (CaP) and supplemented MP. This represents a valuable approach to investigate the bacterial specimens involved in the P absorption, allowing for a comprehensive understanding of how the intestinal bacteria adapt to a new diet and which metabolic routes are affected by changing levels of supplemented P and/or MP. Two major experimental trials were performed during the investigation. The first one was conducted on chickens operating a modulation in the dietary levels of Ca, P and MP. This trial highlighted a shift in the composition of the crop and ceca-associated microbial community depending on the composition of the diet fed. Also, investigated protein inventory revealed that the stress condition due to the reduced P availability is mirrored in the gastrointestinal tract (GIT)-associated microbiota. Marked differences were observed in the functions of the bacterial community in the case of P-available diets versus P-deficient ones. Protein repertoire of the first case draws a thriving microbial community focused on complex and anabolic functions. Contrariwise, the bacterial community in the case of P-lacking diets appears to deal with catabolic functions and stress response. The second trial was conducted on pigs and attempts to define the dynamics featuring the microbiota adaptation to a new challenging diet composed of different protein sources and varying levels of Ca and P. Statistical evidences reveal a stepwise adaptation of the fecal microbiota to the experimental diets fed. Both DNA-based approach and metaproteomics independently reveal three main adaptation phases: -before the feeding of the experimental trial (i.e. Zero), -the response of the microbial community to the challenging factor (i.e. MA) and, finally, - the newly achieved homeostatic balance (i.e. EQ). As observed in the first trial, feeding of the experimental diets impairs the overall fecal microbiota composition, stimulating the presence of phase-specific bacterial specimens and a characteristic relative abundance of the shared ones. Bacterial families responsible for the phase-specific architecture of the fecal microbiota are also active in the biochemical pathways driving the functional peculiarities of each adaptation phase. A deeper investigation of the identified protein repertoire revealed that the observed statistical differences among the adaptation phases are uniquely due to the Ca and P composition of the diets fed. None of the observed effects can be attributed to the diverse protein sources supplemented with the diets. Functional categorization of the identified protein inventory depicts three diverse functional assets of the microbial community. Specifically, prior the feeding of the experimental diets, bacteria are hypothesized to live under homeostatic condition, since they appear to be involved in complex and highly-specialized functions. Following the administration of the experimental diets microbial community changes its functional priority and reduce the expression of highly specialized functions to focus on more essential ones. Proteins involved in complex functions such as widening the substrates array and facing complex sugars tend to increase in abundance while the new homeostatic balance is achieved. Altogether, data from both trials provide useful information for future studies aimed to design effective breeding strategies finalized to reduce the P supplementation in the routinely breeding of livestock and maintain a balanced microbial activity in the animal GIT. Investigation of the dynamics of the porcine microbiota provides instructions on the minimal exposure time required from the intestinal microbiota to adapt to a new dietary composition. This is of fundamental importance for the design of future studies aimed to confirm and/or continue our results. Moreover, the anatomical and physiological similarities occurring between humans and pigs, make our findings of interest for future human nutritional studies, where the mechanisms and lasts of the microbiota adaptation process is still object of discussion.
  • Thumbnail Image
    Publication
    High-throughput sequencing techniques to analyze microbial communities in the gastrointestinal tract of broiler chickens
    (2018) Borda Molina, Daniel Enrique; Camarinha-Silva, Amélia
    Broiler chicken represents an excellent case-study to elucidate the inter-communication between the host and its microbial communities. The general aim of this thesis was to describe the changes in bacterial community structure that occurred in chickens, in response to different experimental diets. An update of the state of the art of the chicken gastrointestinal microbiota was done in chapter 2. The composition and functionality are described through the most recent technologies that provide taxonomic information at DNA level using 16S rRNA genes. Gene catalogs and their abundance are deciphered through shotgun metagenome sequencing, which is still at its infancy and only eight publications have been published so far. At the protein level, only two studies were found that contribute metaproteomic information. Thanks to these technologies many studies were able to focus on answering how feed supplementations altered the microbes in GIT sections. The second part presented in chapter 3 comprises an extensive investigation of the broiler chicken microbiota composition in digesta and mucosa of individual samples under varying supplementation of calcium, phosphorus, and phytase. The dietary impact on the distribution of the microbial communities was studied in the crop, ileum, and caecum through illumina sequencing of the 16S rRNA gene. One important outcome was the high variability in the microbial composition between individual samples. Significant differences were observed between the digesta and mucosa samples, supporting the hypothesis that being close to the host, mucosa-associated communities show a different composition. A calcium effect on the performance was observed, where values for body weight gain and feed conversion were lower in comparison to the other treatments. Microbial communities in the crop mucosa revealed a dietary effect, while in the digesta samples no significant changes were seen. Regarding the ileum mucosa, there was an effect of P addition on the microbial distribution. As expected, caeca-derived samples showed an increase in the diversity indexes when compared to the ileum and crop and butyrate producers were detected in higher abundance. A lower microbial diversity in the crop was linked to lower growth performance regarding the supplementation of Ca. Hence, each dietary treatment affected the microbial communities; nevertheless, none of the dietary treatments displayed a consistent effect across the studied gut sections. Additionally, the effects of supplementing different proteases and one phytase on the microbial community of the ileum of broiler chickens was assessed. Thus, the specific aim of chapter 4 was to determine how enzyme supplementation affects the microbiota composition in the ileum of broilers and whether these effects were related to differences in pre-caecal AA digestibility. Three different protease sources at a low and high level were included. The microbial taxonomy was assessed through 16S rRNA gene Illumina amplicon sequencing. Performance results revealed a significant increase in growth and feed efficiency in broilers fed with phytase only and the high dosage of protease C, in comparison to the control. Most of the AA showed a significant difference between the control diet and protease C at high dosage and phytase diets. Effects on microbiota composition were observed at the genus level for some protease and phytase supplementations. The genera Streptococcus, Lactobacillus, and uncultured Clostridiaceae were responsible for these differences. This study demonstrates that effects of enzyme supplementation were evident in the terminal small intestine microbiota composition, and, to a lesser extent, in pc AA digestibility. However, the changes in microbiota composition and pc AA digestibility could not be correlated which may indicate the absence of a causal relationship. Finally, an outlook with metagenome sequencing is presented in chapter 5, to further characterize the result of feeding strategies. Metabolism information, essential to microbial activities registered 50% of abundant genes in the supplemented diets while being reduced to 40% in the control samples Phosphatases pathways and butyrate production increased in the supplemented diets while calcium signaling pathway was higher in the control. In conclusion, within this project a method of standardization to study the microbiota along the gastrointestinal tract of broiler chickens was successfully established. The obtained results revealed a significant impact of both, enzyme and mineral supplementation in the individual sections of the GIT. Also, it was proved that even if the GIT works as an interconnected system, its compartmentalization creates different environmental conditions which influence the microbiota. This study provides insights into the responses of the bacteria and their functionality which were stimulated by the feed supplementations.
  • Thumbnail Image
    Publication
    Toll-like Receptor 9 (TLR9) activation and the innate immune response to microbial and human DNA
    (2023) Hsu, Emily; Fricke, Florian W.
    The human Toll-like Receptor 9 (TLR9) is an endosomal Pattern Recognition Receptor (PRR) that recognizes DNA sequences containing the unmethylated Cytosine-Guanine (CpG) dimers, which are present in greater abundance in most bacterial genomes compared to those of vertebrates. Specific CpG-containing sequences are strongly stimulatory of human TLR9, as shown in published studies using synthetic oligonucleotides (ODN) and DNA from bacterial species of varying genomic CpG concentration. Human TLR9 activation was experimentally examined in this thesis using DNA extracted from different bacterial sources, human DNA from Caco-2 cells, known immunostimulatory ODN, and short ODN. In vitro assays using fragment length-standardized microbial genomic DNA on HEK-Dual TLR9 Cells and human peripheral blood mononuclear cells (PBMCs) revealed that TLR9 activation strongly correlated to CpG concentration of the input DNA, with an additional influence of CpG-containing 5-mer TCGTT concentration. When DNA of varying origins and fragment lengths were used together, however, complex dynamics of TLR9 activation, co-activation, and repression were observed, which were less predictable than expected from genomic CpG concentration alone. DNase I-treated microbial DNA fragments of less than 15 bp of length were non-activating on their own, but co-activated human TLR9 together with ODN-2006 in Ramos Blue (B) cells. Similarly, human DNA fragments at the length of 50-200 bp co-activated human TLR9 with both ODN-2006 and Escherichia coli DNA in HEK-dual TLR9 cells. In contrast, large human DNA fragments at over 10000 bp of length repressed TLR9 activation by ODN-2006 in Ramos Blue cells. Finally, a preliminary study was conducted in HT-29 cells on the effect of TLR9 activation on the invasion of Fusobacterium nucleatum, an opportunistic gut pathogen with a very low genomic CpG concentration at 0.296%, using ODN-2006 and human DNA as TLR9 activators. While increased presence of intracellular Fusobacterium nucleatum upon treatment with both ODN-2006 and human DNA was noted, more studies are needed to confirm TLR9 activation as a cause of greater bacterial invasion. The human colon is the location of the largest microbial population of the human body, which provides a rich source of non-human DNA in contact with human TLR9 present in intestinal epithelial cells, plasmacytoid dendritic cells (pDCs), and B lymphocytes. Additionally, the daily mass shedding and death of human intestinal epithelial cells provide large amounts of human DNA, which when combined with microbial DNA could result in co-activation and possible autoimmunity. The thesis thus provided an in vitro model of TLR9 activation by complex DNA of varying origins and fragment lengths likely to present in the human gut environment, and prepared a working basis for future studies of TLR9 activation by human fecal metagenomic DNA.