Project description:We sequenced 12 ATAC-Seq lbraries from four biological replicates before (T1) and after the onset of maturation (T2, T3, T4) from liver. To characterise changes in chromatin state following long light initiation, we defined differentially accessible regions (DARs) where mapping counts differed significantly between T1 and other time points. This revealed a strong early remodelling in the chromatin state landscape, as most DARs were observed at T2 (n=1501) before decreasing in stepwise fashion at T3 (n=477) and T4. The majority of DARs (n=1036 or 57%) exhibit reduced accessibility at T2 compared with T1 and subsequently remained unchanged at later time points (Fig. 5a; Supplementary Figure S14). Similarly, regions that gained accessibility at T2 (n=696 or 38%) also remained unchanged at later timepoints. This left less than 10% of DARs (n=99) that displayed an oscillating pattern following the onset of the maturation. Together, this revealed the ATAC-seq signatures were predominantly stable chromatin state changes.

Project description:Impact of antibiotics (T2) or antibiotics in combination with stress (T3) in early life on intestinal functioning in pigs on 8, 55, 176 days in jejunum and ileum (blood only day 8) and control pigs (T1) 4 pools consisting of 16 animals were generated per time-point (day 8, 55, 176 after birth) per treatment (T1;control, T2; antibiotics, T3; antibiotics+stress)

Project description:Impact of antibiotics (T2) or antibiotics in combination with stress (T3) in early life on intestinal functioning in pigs on 8, 55, 176 days in jejunum and ileum (blood only day 8) and control pigs (T1)

Project description:Hematopoietic stem cell transplantation (HSCT) induces significant alterations in the gut microbiome and metabolome, which influence transplant-related complications and surviv-al. This study longitudinally analyzed gut microbiota and metabolites at pre- (T1), peri- (T2), and post-transplant (T3) stages to identify key determinants of clinical outcomes. Lower microbiome diversity at T1 and T3 correlated with graft-versus-host disease (GVHD), progressive disease (PD), and reduced overall survival (OS). Short-chain fatty acids (SCFAs), particularly acetate, declined over time, with reductions at T2-T1 linked to GVHD, diarrhea, PD, and lower OS. Specific perspective metabolites (SPMs) such as elevated uric acid at T2 were associated with GVHD, while reduced 1-phenylethylamine correlated with diarrhea. Patients with enriched beneficial taxa (e.g., Lachnospiraceae, Ruminococcaceae) exhibited improved OS. These findings highlight the gut microbiome-metabolome axis as a predictive marker for HSCT outcomes. Identifying microbial and metabolic signatures may provide novel diagnostic and therapeutic targets for mitigating HSCT-related complications, enhancing patient prognosis.

Project description:mRNA was sampled during exponential growth phase (T1), beginning of stationary/production phase (T2), middle of production phase (T3-T4) and end of production phase (T5-T6) strains: Y. lipolytica Af4 - DHA producer (Gemperlein et al., 2019) and Y. lipolytica Po1h - wild type

Project description:The purpose of this study was to detect the expression profile of tsRNA during deep hypothermia circulatory arrest, and to find possible regulatory factors according to the changes in its expression level, in the hope of providing an effective organ protection strategy for this process.Three blood samples were collected from a central veins line into ethylenediaminetetraacetic acid (EDTA) tubes as follows: T1 (before starting circulatory arrest), T2 (15 min after initiation of DHCA), T3 (after declamping the left common carotid artery and before rewarming). A total of 286 commonly expressed tsRNAs were identified in the T1 and T2 groups, 68 tsRNAs specifically expressed in the T1 group, and 44 tsRNAs specifically expressed in the T2 group. A total of 290 commonly expressed tsRNAs were identified in the T2 and T3 groups, 64 tsRNAs specifically expressed in the T2 group, and 43 tsRNAs specifically expressed in the T3 group. Next, four tsRNAs were selected to be verified by qRT-PCR. In summary, this study innovatively proposed the correlation between the deep hypothermic circulatory arrest process and the expression profile of tsRNA, and evaluated the expression level and regulation mode of tsRNA. A preliminary exploration of its potential biological role in the process of deep hypothermic circulatory arrest has been carried out, which can provide a better basis and a more comprehensive explanation for the organ protection mechanism of deep hypothermic circulatory arrest. And in further research, we are expected to achieve targeted protection of organs by overexpressing or inhibiting the corresponding tsRNA.

Project description:B cells emerge from the bone marrow as transitional (TS) B cells that differentiate through T1, T2 and T3 stages to become naïve B cells. We have identified a bifurcation of human B cell maturation from the T1 stage forming IgMhi and IgMlo developmental trajectories. IgMhi T2 cells have higher expression of a4b7 integrin and lower expression of IL4 receptor (IL4R) compared to the IgMlo branch and are selectively recruited into gut-associated lymphoid tissue. IgMhi T2 cells also share transcriptomic features with marginal zone B cells (MZB). Lineage progression from T1 cells to MZB via an IgMhi trajectory is identified by pseudotime analysis of scRNA-sequencing data. Reduced frequency of IgMhi gut homing T2 cells is observed in severe SLE and is associated with reduction of MZB and their putative IgMhi precursors. The collapse of the gut-associated MZB maturational axis in severe SLE affirms its existence in health.

Project description:B cells emerge from the bone marrow as transitional (TS) B cells that differentiate through T1, T2 and T3 stages to become naïve B cells. We have identified a bifurcation of human B cell maturation from the T1 stage forming IgMhi and IgMlo developmental trajectories. IgMhi T2 cells have higher expression of a4b7 integrin and lower expression of IL4 receptor (IL4R) compared to the IgMlo branch and are selectively recruited into gut-associated lymphoid tissue. IgMhi T2 cells also share transcriptomic features with marginal zone B cells (MZB). Lineage progression from T1 cells to MZB via an IgMhi trajectory is identified by pseudotime analysis of scRNA-sequencing data. Reduced frequency of IgMhi gut homing T2 cells is observed in severe SLE and is associated with reduction of MZB and their putative IgMhi precursors. The collapse of the gut-associated MZB maturational axis in severe SLE affirms its existence in health.

Project description:Purpose: sRNA-sequencing of mature and intermediate gonadal tissue in order to identify the differential expression of miRNAs during male to female (i.e. protandrous) sex transition Methods: Total RNA was extracted and sRNA was purified. cDNA libraries were constructed using a high definition adapter protocol (Xu et al. 2015). 50 bp sequencing was performed on Illumina's HiSeq 2500 at the Earlham Institute, Norwich, UK. Sequenced data was trimmed for adapters and filtered to remove very short and low complexity sequences. miRBase animal miRNA precursor sequences were mapped against the Asian seabass genome in order to generate a set of putative miRNA precursors. Putative precursor molecules with aligning mature miRBase miRNA(s) and forming a valid pre-miRNA hairpin structure were annotated as valid precursor miRNAs. Novel precursor and mature miRNAs were annotated using a combination of published algorithms and manual checking to ensure consistency with canonical miRNA biogenesis criteria. The alignment of sequenced reads against a non-redundant miRNA precursor set was used to determine raw read counts of mature miRNAs. Differential expression analysis was performed in order to identify differentially expressed mature miRNAs between conditions. Results: We detect 156, 71, 122, 151, 171 and 155 differentially expressed miRNA for the testis -> T1/T2, T1/T2 -> T3/T4, T3/T4 -> ovary, testis -> T3/T4, T1/T2 -> ovary and the testis->ovary comparisons respectively Conclusions: There is substantial differential expression of miRNAs at every stage of gonadal change in the Asian seabass during the sex transition process

Project description:Goal :<br> Detection of unknown degradation products of the nitrification inhibitors DMPP (SNI) and MBOA (BNI) in three different soils (Wieselburg, Marchfeld, and Linz).<br> <br> List of samples:<br> Same labeling scheme for all three soils (L, MF, WB)<br> Sample NR | Timepoint | Treatment | weighed soil [g] | Which medium is it stored in<br> 1 | T0 (same day) | DMPP | 0.25 | HPLC-eluent<br> 5 | T0 (same day) | DMPP | 0.25 | HPLC-eluent<br> 6 | T0 (same day) | DMPP - stable isotope | 0.25 | HPLC-eluent<br> 10 | T0 (same day) | DMPP - stable isotope | 0.25 | HPLC-eluent<br> 11 | T0 (same day) | MBOA | 0.25 | Acetonirile<br> 15 | T0 (same day) | MBOA | 0.25 | Acetonirile<br> 16 | T0 (same day) | MBOA - stable isotope | 0.25 | Acetonirile<br> 20 | T0 (same day) | MBOA - stable isotope | 0.25 | Acetonirile<br> 21 | T0 (same day) | Control | 0.25 | HPLC-eluent<br> 25 | T0 (same day) | Control | 0.25 | Acetonirile<br> 26 | T1 (after 3 days) | DMPP | 0.25 | HPLC-eluent<br> 30 | T1 (after 3 days) | DMPP | 0.25 | HPLC-eluent<br> 31 | T1 (after 3 days) | DMPP - stable isotope | 0.25 | HPLC-eluent<br> 35 | T1 (after 3 days) | DMPP - stable isotope | 0.25 | HPLC-eluent<br> 36 | T1 (after 3 days) | MBOA | 0.25 | Acetonirile<br> 40 | T1 (after 3 days) | MBOA | 0.25 | Acetonirile<br> 41 | T1 (after 3 days) | MBOA - stable isotope | 0.25 | Acetonirile<br> 45 | T1 (after 3 days) | MBOA - stable isotope | 0.25 | Acetonirile<br> 46 | T1 (after 3 days) | Control | 0.25 | Acetonirile<br> 50 | T1 (after 3 days) | Control | 0.25 | HPLC-eluent<br> 51 | T2 (after 10 days) | DMPP | 0.25 | HPLC-eluent<br> 55 | T2 (after 10 days) | DMPP | 0.25 | HPLC-eluent<br> 56 | T2 (after 10 days) | DMPP - stable isotope | 0.25 | HPLC-eluent<br> 60 | T2 (after 10 days) | DMPP - stable isotope | 0.25 | HPLC-eluent<br> 61 | T2 (after 10 days) | MBOA | 0.25 | Acetonirile<br> 65 | T2 (after 10 days) | MBOA | 0.25 | Acetonirile<br> 66 | T2 (after 10 days) | MBOA - stable isotope | 0.25 | Acetonirile<br> 70 | T2 (after 10 days) | MBOA - stable isotope | 0.25 | Acetonirile<br> 71 | T2 (after 10 days) | Control | 0.25 | HPLC-eluent<br> 75 | T2 (after 10 days) | Control | 0.25 | Acetonirile<br> 76 | T3 (after 14 days) | DMPP | 0.25 | HPLC-eluent<br> 80 | T3 (after 14 days) | DMPP | 0.25 | HPLC-eluent<br> 81 | T3 (after 14 days) | DMPP - stable isotope | 0.25 | HPLC-eluent<br> 85 | T3 (after 14 days) | DMPP - stable isotope | 0.25 | HPLC-eluent<br> 86 | T3 (after 14 days) | MBOA | 0.25 | Acetonirile<br> 90 | T3 (after 14 days) | MBOA | 0.25 | Acetonirile<br> 91 | T3 (after 14 days) | MBOA - stable isotope | 0.25 | Acetonirile<br> 95 | T3 (after 14 days) | MBOA - stable isotope | 0.25 | Acetonirile<br> 96 | T3 (after 14 days) | Control | 0.25 | Acetonirile<br> 100 | T3 (after 14 days) | Control | 0.25 | HPLC-eluent<br> <br> Concentrations:<br> all smaples have 130ug of (NH4)2SO4<br> DMPP samples have 1,3ug of DMPP per 1 g soil<br> MBOA samples have 300ug of MBOA per 1 g soil<br> for samples that are isotopically labeled the amount of Inhibitor was split between the unlabeled and labeled compound<br> 5ul of the respective solution was added to the sample.<br> <br> Measurements according to 10.1021/ac503290j, but with an Q Exactive HF instrument<br> <br> Results: <br> D patterns unfortunately also always show up in the T0 controls --> so it's unlikely to be biological breakdown/degradation products<br> <br>