Schistosomiasis is a neglected tropical disease that infects 240 million
people. With no vaccines and only one drug available, new therapeutic
targets are needed. The causative agents, schistosomes, are intravascular
flatworm parasites that feed on blood and lay eggs, resulting in pathology.
The function of the parasite’s various tissues in successful parasitism are
poorly understood, hindering identification of therapeutic targets. Using
single-cell RNA sequencing (RNA-seq), we characterize 43,642 cells from the
adult schistosome and identify 68 distinct cell populations, including
specialized stem cells that maintain the parasite’s blood-digesting gut.
These stem cells express the gene hnf4, which is
required for gut maintenance, blood feeding, and pathology in vivo.
Together, these data provide molecular insights into the organ systems of
this important pathogen and identify potential therapeutic targets.
Achondroplasia (ACH) is a short-limbed dwarfism resulting from gain-of-function mutations in fibroblast growth factor receptor 3 (FGFR3). Previous studies have shown that ACH patients have impaired chondrogenesis, but the effects of FGFR3 on bone formation and bone remodeling at adult stages of ACH have not been fully investigated. Using micro-computed tomography and histomorphometric analyses, we found that 2-month-old Fgfr3 G369C/1 mice (mouse model mimicking human ACH) showed decreased bone mass due to reduced trabecular bone volume and bone mineral density, defect in bone mineralization and increased osteoclast numbers and activity. Compared with primary cultures of bone marrow stromal cells (BMSCs) from wild-type mice, Fgfr3 G369C/1 cultures showed decreased cell proliferation, increased osteogenic differentiation including up-regulation of alkaline phosphatase activity and expressions of osteoblast marker genes, and reduced bone matrix mineralization. Furthermore, our studies also suggest that decreased cell proliferation and enhanced osteogenic differentiation observed in Fgfr3 G369C/1 BMSCs are caused by upregulation of p38 phosphorylation and that enhanced Erk1/2 activity is responsible for the impaired bone matrix mineralization. In addition, in vitro osteoclast formation and bone resorption assays demonstrated that osteoclast numbers and bone resorption area were increased in cultured bone marrow cells derived from Fgfr3 G369C/1 mice. These findings demonstrate that gain-of-function mutation in FGFR3 leads to decreased bone mass by regulating both osteoblast and osteoclast activities. Our studies provide new insight into the mechanism underlying the development of ACH.
Background
Anthocyanins determinate the flower color of many plants. Tobacco is a model plant for studying the molecular regulation of flower coloration. We investigated the mechanism underlying flower coloration in tobacco by profiling flavonoid metabolites,expression of anthocyanin biosynthetic structural genes and their regulator genes in the pink-flowered tobacco cultivar Yunyan 87 and white-flowered Yunyan 87 mutant.
Result
Significant down-accumulation of anthocyanins, including cyanidin 3-O-glucoside, cyanin, cyanidin 3-O-rutinoside, pelargonidin 3-O-beta-D-glucoside, cyanidin O-syringic acid, pelargonin, and pelargonidin 3-O-malonylhexoside (log2 fold change < − 10), endowed the flower color mutation in Yunyan 87 mutant. Transcriptome analysis showed that the coordinately down-regulated anthocyanin biosynthetic genes including chalcone isomerase, naringenin 3-dioxygenase, dihydroflavonol 4-reductase and UDP-glucose:flavonoid 3-O-glucosyltransferase played critical roles in suppressing the formation of the aforesaid anthocyanins. Several genes encoding MYB and bHLH transcription factors were also found down-regulated, and probably the reason for the suppression of structural genes.
Conclusion
This is the first study of tobacco flower coloration combining metabolome and transcriptome analyses, and the results shed a light on the systematic regulation mechanisms of flower coloration in tobacco. The obtained information will aid in developing strategies to modify flower color through genetic transformation.
Fibroblast growth factor receptor 3 (FGFR3), highly conserved in both humans and murine, is one of key tyrosine kinase receptors for FGF. FGFR3 is expressed in different tissues, including cartilage, brain, kidney, and intestine at different development stages. Conventional knockout of Fgfr3 alleles leads to short life span, and overgrowth of bone. In clinic, human FGFR3 mutations are responsible for three different types of chondrodysplasia syndromes including achondroplasia (ACH), hypochondroplasia (HCH) and thanatophoric dysplasia (TD). For better understanding of the roles of FGFR3 in different tissues at different stages of development and in pathological conditions, we generated Fgfr3 conditional knockout mice in which loxp sites flank exons 9-10 in the Fgfr3 allele. We also demonstrated that Cre-mediated recombination using Col2a1-Cre, a Cre line expressed in chondrocyte during bone development, results in specific deletion of the gene in tissues containing cartilage. This animal model will be useful to study distinct roles of FGFR3 in different tissues at different ages.
Schistosomiasis is an ancient and chronic neglected tropical disease that infects over 240 million people and kills over 200,000 of the world’s poorest people every year1, 2. There are no vaccines and because there is only one drug available, the need for new therapeutics is great. The causative agents of this disease are flatworm parasites that dwell inside the host’s circulation, often for decades, where they feed on blood and lay eggs which are primarily responsible for disease pathology. As metazoans comprised of multiple tissue types, understanding the schistosome’s tissues on a molecular level and their functions during what can be decades of successful parasitism could suggest novel therapeutic strategies. Here, we employ single-cell RNAseq to characterize 43,642 cells from the pathogenic (adult) stage of the schistosome lifecycle. From these data, we characterize 68 molecularly distinct cell populations that comprise nearly all tissues described morphologically, including the nervous and reproductive systems. We further uncover a lineage of somatic stem cells responsible for producing and maintaining the parasite’s gut – the primary tissue responsible for digestion of host blood. Finally, we show that a homologue of hepatocyte nuclear factor 4 (hnf4) is expressed in this gut lineage and required for gut maintenance, blood feeding and inducing egg-associated pathology in vivo. Together, the data highlight the utility of this single-cell RNAseq atlas to understand schistosome biology and identify potential therapeutic interventions.
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