Feline infectious peritonitis (FIP) is a coronavirus-induced disease of cats, in which the immune system is known to play a crucial, but complex, role in the pathogenesis. This role is still incompletely understood, with involvement of both host and viral factors. To evaluate differential gene expression and pathway involvement in feline coronavirus (FCoV) infection and FIP, we applied next-generation RNA-sequencing of the mesenteric lymph nodes from cats with naturally-acquired FIP, as well as those with systemic FCoV infection without FIP, and those with neither. Viral infection was associated with upregulation of viral defenses regardless of the disease state, but to a greater degree in FIP. FIP was associated with higher pro-inflammatory pathway enrichment, whilst non-FIP FCoV-positive cats showed lower enrichment of humoral immunity pathways, below that of uninfected cats in the case of immunoglobulin production pathways. This host response is presumed to be protective. In FIP, downregulation of T cell-related processes was observed, which did not occur in non-FIP FCoV-positive cats. These results emphasize the importance of the host’s immune balance in determining the outcome of the FCoV infection.
Background Alzheimer's disease is a common debilitating dementia with known heritability, for which 20 late onset susceptibility loci have been identified, but more remain to be discovered. This study sought to identify new susceptibility genes, using an alternative gene-wide analytical approach which tests for patterns of association within genes, in the powerful genome-wide association dataset of the International Genomics of Alzheimer's Project Consortium, comprising over 7 m genotypes from 25,580 Alzheimer's cases and 48,466 controls. Principal Findings In addition to earlier reported genes, we detected genome-wide significant loci on chromosomes 8 (TP53INP1, p = 1.4×10−6) and 14 (IGHV1-67 p = 7.9×10−8) which indexed novel susceptibility loci. Significance The additional genes identified in this study, have an array of functions previously implicated in Alzheimer's disease, including aspects of energy metabolism, protein degradation and the immune system and add further weight to these pathways as potential therapeutic targets in Alzheimer's disease.
Pimozide is a conventional antipsychotic drug largely used in the therapy for schizophrenia and Tourette's syndrome. Pimozide is assumed to inhibit synaptic transmission at the CNS by acting as a dopaminergic D2 receptor antagonist. Moreover, pimozide has been shown to block voltage-gated Ca2+ and K+ channels in different cells. Despite its widespread clinical use, pimozide can cause several adverse effects, including extrapyramidal symptoms and cardiac arrhythmias. Dizziness and loss of balance are among the most common side effects of pimozide. By using the patch-clamp whole-cell technique, we investigated the effect of pimozide [3 μM] on K+ channels expressed by chicken embryo vestibular type-II hair cells. We found that pimozide slightly blocks a transient outward rectifying A-type K+ current but substantially increases a delayed outward rectifying K+ current. The net result was a significant hyperpolarization of type-II hair cells at rest and a strong reduction of their response to depolarizing stimuli. Our findings are consistent with an inhibitory effect of pimozide on the afferent synaptic transmission by type-II hair cells. Moreover, they provide an additional key to understanding the beneficial/collateral pharmacological effects of pimozide. The finding that pimozide can act as a K+ channel opener provides a new perspective for the use of this drug.
Abstract Apple ( Malus × domestica ) is one of the most important fruit crops in terms of worldwide production. Due to its self-incompatibility system and the long juvenile period, breeding of new apple cultivars combining traits desired by growers (e.g. yield, pest and disease resistance) and consumers (e.g. fruit size, color, and flavor) is a long and complex process. Genomics-assisted breeding strategies can facilitate the selection of germplasm leading to new cultivars. While the most complete apple genome assemblies available to date are from anther-derived homozygous lines, de novo assembly of apple genomes encompassing the natural heterozygosity remains challenging. Using long- and short-read sequencing technologies in combination with optical mapping, we de novo assembled a diploid and heterozygous genome of the apple cultivar ‘Gala Galaxy’. This approach resulted in 154 hybrid scaffolds (N50 = 34.3 Mb) spanning 999.9 Mb and in 414.7 Mb of unscaffolded sequences. Anchoring 31 scaffolds with a genetic map was sufficient to represent an entire haploid genome of 17 pseudomolecules (719.4 Mb). The remaining sequences were assembled in a second set of 17 pseudomolecules, which spanned 601 Mb, leaving 80.6 Mb of unplaced sequences. A total of 41,264 genes were annotated using 74,900 transcripts derived from RNA sequencing of pooled leaf tissue samples. This study provides a high-quality diploid reference genome sequence encompassing the natural heterozygosity of the widely popular cultivar ‘Gala Galaxy’. The DNA sequence resources and the assembly described here will serve as a solid foundation for fundamental and applied apple breeding research.
OBJECTIVE The authors investigated the effects of recently identified genome-wide significant schizophrenia genetic risk variants on cognition and brain structure. METHOD A panel of six single-nucleotide polymorphisms (SNPs) was selected to represent genome-wide significant loci from three recent genome-wide association studies (GWAS) for schizophrenia and was tested for association with cognitive measures in 346 patients with schizophrenia and 2,342 healthy comparison subjects. Nominally significant results were evaluated for replication in an independent case-control sample. For SNPs showing evidence of association with cognition, associations with brain structural volumes were investigated in a large independent healthy comparison sample. RESULTS Five of the six SNPs showed no significant association with any cognitive measure. One marker in the major histocompatibility complex (MHC) region, rs6904071, showed independent, replicated evidence of association with delayed episodic memory and was significant when both samples were combined. In the combined sample of up to 3,100 individuals, this SNP was associated with widespread effects across cognitive domains, although these additional associations were no longer significant after adjusting for delayed episodic memory. In the large independent structural imaging sample, the same SNP was also associated with decreased hippocampal volume. CONCLUSIONS The authors identified a SNP in the MHC region that was associated with cognitive performance in patients with schizophrenia and healthy comparison subjects. This SNP, rs6904071, showed a replicated association with episodic memory and hippocampal volume. These findings implicate the MHC region in hippocampal structure and functioning, consistent with the role of MHC proteins in synaptic development and function. Follow-up of these results has the potential to provide insights into the pathophysiology of schizophrenia and cognition.
Aerobic and anaerobic oxidations of ammonium are core biological processes driving the nitrogen cycle in natural and engineered microbial ecosystems. These conversions are tailored in mixed-culture biotechnology to propel partial nitritation and anammox (PN/A) for a complete chemolithoautotrophic removal of nitrogen from wastewater at low resource and energey expenditures. Good practices of microbiome science and engineering are needed to design microbial PN/A systems and translate them to a spectrum of wastewater environments. Inter-disciplinary investigations of systems microbiology and engineering are paramount to harness the microbial compositions and metabolic performance of complex microbiomes. We propose “process ecogenomics” as an integration ground to combine community systems microbiology and microbial systems engineering by establishing a synergy between the life and physical sciences. It drives a high-resolution analysis, engineering and management of microbial communities and their metabolic performance in mixed-culture systems. While addressing the key underpinnings of the science and engineering of aerobic-anaerobic ammonium oxidations, we advocate the need to formulate targeted research questions in order to elucidate and manage microbial ecosystems in wastewater environments. We propose a systems-level roadmap to investigate and functional engineer technical microbiomes like PN/A, via: ( i ) quantitative biotechnological measurement of stoichiometry and kinetics of nitrogen turnovers; ( ii ) genome-centric metagenomic fingerprinting of the microbiome; ( ii ) ecophysiological examination of the main metabolizing lineages; ( iii ) multi-omics elucidation of expressed metabolic functionalities across the microbial network; and ( iv ) translation of microbial and functional ecology principles into physical designs.
Additional file 7. Table S15 MEMOTE [42] test results regarding the potential of gap-fill models (metaGEMs) initialized for the minimal medium to produce biomass (growth). The biomass production potential is indicated by the biomass production values > 0. Table S16The competition (given by MRO score) and cooperation (given by MIP score) potential for the community in each sample, predicted by SMETANA [43]. Table S17 The MAGs that interact in SMETANA simulation for the microbial community in the lower galleries. Table S18 The MAGs that interact in SMETANA simulation for the microbial community in the upper galleries. Table S19 Compounds exchanged that differed between upper and lower galleries according to Wilcoxon rank-sum test.
Necrotizing gingivitis (NG) is a necrotizing periodontal disease that differs from chronic gingivitis (CG). To date, both the microbiological causes and the involved host cytokine response of NG still remain unclear. Here, we investigated corresponding interdental plaque and serum samples from two groups of Chinese patients with CG (n = 21) or NG (n = 21). The microbiota were studied by 16S rRNA Illumina MiSeq sequencing of the microbial metagenome and by assessing quantitatively the abundance of the phylum Bacteroidetes, the genus Prevotella and the species T. forsythia, P. endodontalis, and P. gingivalis using fluorescence in situ hybridization (FISH). With respect to the associated host response, the levels of 30 inflammatory mediators were quantified by multiplex immunoassay analysis. Differential microbial abundance analysis of the two disease groups revealed at the phylum level that Proteobacteria accounted for 67% of the differentially abundant organisms, followed by organisms of Firmicutes (21%) and Actinobacteria (9%). At the species level, significant differences in abundance were seen for 75 species of which 58 species were significantly more abundant in CG patients. Notably, the FISH analysis revealed that Bacteroidetes was the most prevalent phylum in NG. The multiplex cytokine assay showed significant quantitative differences between the disease groups for eight analytes (GM-CSF, G-CSF, IFN-α, IL-4, IL-13, TNF-α, MIG, and HGF). The G-CSF was found to be the most significantly increased inflammatory protein marker in NG. The next-generation sequencing (NGS) data supported the understanding of NG as a multi-microbial infection with distinct differences to CG in regard to the microbial composition.
We recently described the 4.5-year time course of the enteric bacterial microbiota and virome of a patient cured from recurrent Clostridium difficile infection (rCDI) by fecal microbiota transplantation (FMT). Here, we extended the virome analyses and found the patient's phage population to exhibit highly donor-similar characteristics following FMT, which remained stable for the whole period tested (up to 7 months). Moreover, the detected viral populations of donor and patient exhibited comparable diversity and richness. These findings were unexpected since enteric viromes are normally highly variable, assumed to influence the bacterial host community and change with environmental conditions. In contrast to the virome, the bacterial microbiota varied indeed for more than 7 months with ongoing dysbiosis before it reached donor similarity. Our findings that are based on sequence information and protein domain analysis seem to suggest that stable phage properties correlate with successful FMT better than the changing bacterial communities. We speculate that we here preferentially detected a stable core virome, which dominated over a variable flexible virome that may have been too heterogeneous for experimental detection or was underrepresented in the databases. It will be interesting to analyze whether the enteric virome allows predictions for the clinical outcome of FMT for rCDI and other diseases such as inflammatory bowel disease or obesity.
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