The effects of elevated atmospheric CO(2) (560 p.p.m.) and subsequent plant responses on the soil microbial community composition associated with trembling aspen was assessed through the classification of 6996 complete ribosomal DNA sequences amplified from the Rhinelander WI free-air CO(2) and O(3) enrichment (FACE) experiments microbial community metagenome. This in-depth comparative analysis provides an unprecedented, detailed and deep branching profile of population changes incurred as a response to this environmental perturbation. Total bacterial and eukaryotic abundance does not change; however, an increase in heterotrophic decomposers and ectomycorrhizal fungi is observed. Nitrate reducers of the domain bacteria and archaea, of the phylum Crenarchaea, potentially implicated in ammonium oxidation, significantly decreased with elevated CO(2). These changes in soil biota are evidence for altered interactions between trembling aspen and the microorganisms in its surrounding soil, and support the theory that greater plant detritus production under elevated CO(2) significantly alters soil microbial community composition.
Proteome and transcriptome analysis, combined with mutagenesis, were used to better understand the response of Cupriavidus metallidurans CH34 against lead(II). Structural Pb(II)-resistance genes of the pMOL30-encoded pbrUTRABCD operon formed the major line of defense against Pb(II). However, several general stress response mechanisms under the control of alternative sigma factors such as sigma24/rpoK, sigma32/rpoH and sigma28/fliA were also induced. In addition, the expression of the pbrR(2) cadA pbrC(2) operon of the CMGI-1 region and the chromosomally encoded zntA were clearly induced in the presence of Pb(II), although their respective gene products were not detected via proteomics. After inactivation of the pbrA, pbrB or pbrD genes, the expression of the pbrR(2) cadA pbrC(2) operon went up considerably. This points towards synergistic interactions between pbrUTRABCD and pbrR(2) cadA pbrC(2) to maintain a low intracellular Pb(II) concentration, where pbrR(2) cadA pbrC(2) gene functions can complement and compensate for the mutations in the pbrA and pbrD genes. This role of zntA and cadA to complement for the loss of pbrA was further confirmed by mutation analysis. The pbrB:: colonsTn(Km2) mutation resulted in the most significant decrease of Pb(II) resistance, indicating that Pb(II) sequestration, avoiding re-entry of this toxic metal ion, forms a critical step in the pbr-encoded Pb(II) resistance mechanism.
The transcription factors HNF1B and Pax2, co-expressed in the Wolffian duct and ureteric bud epithelia, play essential roles during the early steps of mouse kidney development. In humans, heterozygous mutations in these genes display a number of common kidney phenotypes, including hypoplasia and multicystic hypoplastic kidneys. Moreover, a high prevalence of mutations either in HNF1B or PAX2 has been observed in children with renal hypodysplasia. To gain a better understanding of Hnf1b and Pax2 interactions in vivo, we generated compound heterozygous mice for Hnf1b and Pax2 null alleles. We show here that compound heterozygous mutants display phenotypes similar to severe congenital anomalies of the kidney and the urinary tract (CAKUT), including strong hypoplasia of the kidneys, caudal ectopic aborted ureter buds, duplex kidneys, megaureters and hydronephrosis. At a molecular level, compound mutants show a delay in nephron segment and medullar interstitial differentiation, increased apoptosis and a transient decrease in Lim1 and Wnt4 expression. We also observe a perturbation of smooth muscle differentiation around the ureter associated with a local down-regulation in transcript levels of Bmp4 and Tbx18, two key regulators involved in ureter smooth muscle formation, thus explaining, at least in part, megaureters. These results together uncover a novel role of Hnf1b as a modifier of the Pax2 haplo-insufficient phenotype and show that these two transcription factors operate in common pathways governing both kidney morphogenesis and ureter differentiation. This mouse model should provide new insights into the pathogenic mechanisms of human CAKUT, the most frequent developmental defect identified in newborns.
Heterozygous mutations in HNF1B cause the complex syndrome Renal Cysts and Diabetes (RCAD), characterized by developmental abnormalities of the kidneys, genital tracts and pancreas, and a variety of renal, pancreas and liver dysfunctions. The pathogenesis underlying this syndrome remains unclear as mice with heterozygous null mutations have no phenotype, while constitutive/conditional Hnf1b-ablation leads to more severe phenotypes.We generated a novel mouse model carrying an identified human mutation at the intron-2 splice donor-site. Unlike heterozygous previously characterized, heterozygous for the splicing mutation exhibited decreased HNF1B protein levels and bilateral renal cysts from embryonic stage E15, originated from glomeruli, early proximal tubules (PT) and intermediate nephron segments, concurrently with a delayed PT differentiation, hydronephrosis and rare genital tract anomalies.Consistently, mRNA-sequencing showed that most down-regulated genes in embryonic kidneys were primarily expressed in early PTs and Henle's Loop and involved in ion/drug transport, organic acid and lipid metabolic processes, while the expression of previously identified targets upon Hnf1b-ablation, including cystic disease genes was weakly or not affected. Postnatal analyses revealed renal abnormalities, ranging from glomerular cysts to hydronephrosis and rarely multicystic dysplasia. Urinary proteomics uncovered a particular profile predictive of progressive decline in kidney function and fibrosis, and displayed common features with a recently reported urine proteome in a RCAD pediatric cohort. Altogether our results show that HNF1B reduced levels lead to developmental disease phenotypes associated with the deregulation of a subset of its targets. They further suggest that this model represents a unique clinical/pathological viable model of the RCAD disease.
BackgroundNon-carbonated natural mineral waters contain microorganisms that regularly grow after bottling despite low concentrations of dissolved organic matter (DOM). Yet, the compositions of bottled water microbiota and organic substrates that fuel microbial activity, and how both change after bottling, are still largely unknown.ResultsWe performed a multifaceted analysis of microbiota and DOM diversity in 12 natural mineral waters from six European countries. 16S rRNA gene-based analyses showed that less than 10 species-level operational taxonomic units (OTUs) dominated the bacterial communities in the water phase and associated with the bottle wall after a short phase of post-bottling growth. Members of the betaproteobacterial genera Curvibacter, Aquabacterium, and Polaromonas (Comamonadaceae) grew in most waters and represent ubiquitous, mesophilic, heterotrophic aerobes in bottled waters. Ultrahigh-resolution mass spectrometry of DOM in bottled waters and their corresponding source waters identified thousands of molecular formulae characteristic of mostly refractory, soil-derived DOM.ConclusionsThe bottle environment, including source water physicochemistry, selected for growth of a similar low-diversity microbiota across various bottled waters. Relative abundance changes of hundreds of multi-carbon molecules were related to growth of less than ten abundant OTUs. We thus speculate that individual bacteria cope with oligotrophic conditions by simultaneously consuming diverse DOM molecules.Electronic supplementary materialThe online version of this article (10.1186/s40168-017-0344-9) contains supplementary material, which is available to authorized users.
We developed single-point genome signature tags (SP-GSTs), a generally applicable, high-throughput sequencing-based method that targets specific genes to generate identifier tags from well-defined points in a genome. The technique yields identifier tags that can distinguish between closely related bacterial strains and allow for the identification of microbial community members. SP-GSTs are determined by three parameters: (i) the primer designed to recognize a conserved gene sequence, (ii) the anchoring enzyme recognition sequence, and (iii) the type IIS restriction enzyme which defines the tag length. We evaluated the SP-GST method in silico for bacterial identification using the genes rpoC, uvrB, and recA and the 16S rRNA gene. The best distinguishing tags were obtained with the restriction enzyme Csp6I upstream of the 16S rRNA gene, which discriminated all organisms in our data set to at least the genus level and most organisms to the species level. The method was successfully used to generate Csp6I-based tags upstream of the 16S rRNA gene and allowed us to discriminate between closely related strains of Bacillus cereus and Bacillus anthracis. This concept was further used successfully to identify the individual members of a defined microbial community.
BackgroundNon-carbonated natural mineral waters contain microorganisms that regularly grow after bottling despite low concentrations of dissolved organic matter (DOM). Yet, the compositions of bottled water microbiota and organic substrates that fuel microbial activity, and how both change after bottling, are still largely unknown.ResultsWe performed a multifaceted analysis of microbiota and DOM diversity in twelve natural mineral waters from six European countries. 16S rRNA gene-based analyses showed that less than ten species-level operational taxonomic units (OTUs) dominated the bacterial communities in the water phase and associated with the bottle wall after a short phase of post-bottling growth. Members of the betaproteobacterial genera Curvibacter, Aquabacterium, and Polaromonas (Comamonadaceae) grew in most waters and represent ubiquitous, mesophilic, heterotrophic aerobes in bottled waters. Ultrahigh-resolution mass spectrometry of DOM in bottled waters and their corresponding source waters identified thousands of molecular formulae characteristic of mostly refractory, soil-derived DOM.ConclusionsThe bottle environment, including source water physicochemistry, selected for growth of a similar low-diversity microbiota across various bottled waters. Relative abundance changes of hundreds of multi-carbon molecules were related to growth of less than ten abundant OTUs. We thus speculate that individual bacteria cope with oligotrophic conditions by simultaneously consuming diverse DOM molecules.
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