Project description:<p>Chloroquine (CQ) is widely used in the therapy against malarial, tumor and recently the COVID-19 pandemic, as a lysosomotropic agent to inhibit the endolysosomal trafficking in the autophagy pathway. We previously reported that CQ (20 µM, 36 h) could reprogram transcriptome and impair multiple signaling pathways vital to porcine immature Sertoli cells (iSCs). However, whether CQ treatment could affect the metabolomic compositions of porcine iSCs remains unclear. Here, we showed that CQ (20 µM, 36 h) treatment of porcine iSCs induced significant changes of 63 metabolites (11 up and 52 down) by the metabolomics method, which were involved in different metabolic pathways. Caffeic acid and esculetin, the top two up-regulated metabolites, were validated by ELISA. Furthermore, esculetin treatment (53 nM, 36 h) significantly decreased the viability and proliferation, suppressed the mitochondrial function, whereas promoted the apoptosis of porcine iSCs, similar to those by CQ treatment (20 µM, 36 h). Collectively, our results showed that CQ treatment induces metabolic changes, and its effect on porcine iSCs could be partially mediated by esculetin.</p>

Project description:We investigated the comprehensive metabolic profiles of plasma among immature females, mature females ready to spawn, as well as already spawned breeders of blunt snout bream (Megalobrama amblycephala). The purpose of this study was to screen out potential biomarkers for sexual mature female M. amblycephala compared to immature female individuals and already spawned breeders. The three groups were set up in this study, including one year old immature females, 2 years old sexually mature females ready to spawning and successfully spawning females of M. amblycephala. The plasma samples were collected to investigate the comprehensive metabolic profiles through UPLC-MS/MS based metabolomics analysis method. According to multivariate and univariate statistical analysis, plasma metabolite profiles of three groups were obviously separated, and the plasma metabolite profiles of immature female M. amblycephala were much more different from mature females ready to spawn as well as already spawned breeders. The differential plasma metabolites from three hormone related pathways including GnRH signaling pathway, steroid hormone biosynthesis and steroid biosynthesis, were further analyzed. A total of 29 metabolites were identified as differential biomarkers associated with the female maturation status

Project description:MicroRNAs (miRNAs) are small non-coding regulatory RNAs that play key roles in many diverse biological processes such as spermatogenesis. However, no study has been performed on the miRNA transcriptome of developing porcine testes. Here, we employed Solexa deep sequencing technology to extend the repertoire of porcine testis miRNAs and extensively compare the expression patterns of the sexually immature and mature porcine testes. Solexa sequencing of two small RNA libraries derived from immature (30 days) and mature (180 days) pig testis samples yielded over 25 million high-quality reads. Overall, the two developmental stages had significantly different small RNA compositions. A custom data analysis pipeline identified 398 known and/or homologous conserved porcine miRNAs, 15 novel pig-specific miRNAs, and 56 novel candidate miRNAs. We further observed multiple mature miRNA variants (isomiRs) and identified a new bidirectional transcribed miRNA locus, ssc-mir-181a. One hundred twenty-two miRNAs were differentially expressed in the immature and mature testes, and 10 were validated using quantitative RT-PCR. Furthermore, GO and KEGG pathway analyses of the predicted miRNA targets further illustrate the likely roles for these differentially expressed miRNAs in spermatogenesis. This study is the first comparative profile of the miRNA transcriptome in immature and mature porcine testes using a deep sequencing approach, and it provides a useful resource for future studies on the role of miRNAs in spermatogenesis and male infertility treatment. microRNA profiling and discovery in two small RNA cDNA libraries derived from sexually immature (30-day) and mature (180-day) pig testes.

Project description:MicroRNAs (miRNAs) are small non-coding regulatory RNAs that play key roles in many diverse biological processes such as spermatogenesis. However, no study has been performed on the miRNA transcriptome of developing porcine testes. Here, we employed Solexa deep sequencing technology to extend the repertoire of porcine testis miRNAs and extensively compare the expression patterns of the sexually immature and mature porcine testes. Solexa sequencing of two small RNA libraries derived from immature (30 days) and mature (180 days) pig testis samples yielded over 25 million high-quality reads. Overall, the two developmental stages had significantly different small RNA compositions. A custom data analysis pipeline identified 398 known and/or homologous conserved porcine miRNAs, 15 novel pig-specific miRNAs, and 56 novel candidate miRNAs. We further observed multiple mature miRNA variants (isomiRs) and identified a new bidirectional transcribed miRNA locus, ssc-mir-181a. One hundred twenty-two miRNAs were differentially expressed in the immature and mature testes, and 10 were validated using quantitative RT-PCR. Furthermore, GO and KEGG pathway analyses of the predicted miRNA targets further illustrate the likely roles for these differentially expressed miRNAs in spermatogenesis. This study is the first comparative profile of the miRNA transcriptome in immature and mature porcine testes using a deep sequencing approach, and it provides a useful resource for future studies on the role of miRNAs in spermatogenesis and male infertility treatment.

Project description:Vitamin C (ascorbic acid, AA), as essential micro-nutrient and antioxidant, can affect multiple cellular processes. Previously, we showed that Vitamin C supplement could promote the proliferation and suppress apoptosis of porcine Sertoli cells, via modulating the global nucleic acid methylation levels to alter transcriptome and proteomics. Due to the differences between pig and rodent species, here we investigated the effects of Vitamin C on mouse TM4 Sertoli cells. Vitamin C (250µM) treatment of mouse TM4 Sertoli cells for 36h could significantly increase cell viability, promote cell proliferation and decrease the cell percentage with early apoptosis. Vitamin C (250µM, 36h) also significantly decreased ROS level, elevated mitochondrial function, altered the levels of nucleic acid N6-methylation (m6A) and modified the levels of histone H3 trimethylation (H3K4me3, H3K9Me3 and H3K36me3) of mouse TM4 Sertoli cells. Vitamin C (250µM, 36h) promoted the secretion of anti-müllerian hormone and Estrodiol, but decreased lactate metabolite in mouse TM4 Sertoli cells. RNA-seq identified 112 differentially expressed genes (DEGs) (74 up- and 38 down-regulated) (P≤0.05, |log2Fold Change|≥1) as induced by Vitamin C in mouse TM4 Sertoli cells. Gene enrichment analysis found multiple significantly enriched biological terms or pathways, including GO terms of regulation of response to biotic stimulus, homeostasis of number of cells, positive regulation of tumor necrosis factor production, GTPase activity, calmodulin binding etc., and KEGG signal pathways of calcium signal pathway, cGMP-PKG signaling pathway, steroid biosynthesis, arginine biosynthesis etc. 9 DEGs were selected for RT-qPCR validation and 8 of them showed the change trend consistent to RNA-seq. Taken together, Vitamin C (250µM, 36h) could modulate the functions of mouse TM4 Sertoli cells, through modifying the transcriptome to affect multiple signal pathways.

Project description:Human monocyte-derived dendritic cells (moDCs) have been used as an in vitro model for studying tolerance and immunity. However, the underlying metabolic states of tolerogenic (dexamethasone and vitamin D3-treated), immature and immunogenic (mature, LPS-treated) moDCs have not been completely characterized. Through transcriptomic analyses, we determined that tolerogenic moDCs exhibit augmented catabolic pathways with respect to oxidative phosphorylation (OXPHOS), fatty acid oxidation (FAO) and glycolysis. Functionally, tolerogenic moDCs showed the highest mitochondrial membrane potential, production of reactive oxygen species and superoxide, and increased mitochondrial spare respiratory capacity. Tolerogenic and mature moDCs manifested differential FAO gene expression with FAO activity being significantly higher in tolerogenic and immature moDCs than in mature. In addition, tolerogenic and mature moDCs demonstrated similar levels of glycolytic rate, but not glycolytic capacity and reserve, which were more pronounced in tolerogenic and immature moDCs. Finally, tolerogenic and immature moDCs, but not mature moDCs, showed high plasticity to compensate the intracellular ATP content after inhibition of different energetic metabolic pathways. Overall, tolerogenic moDCs exhibit a metabolic signature of increased, stable OXPHOS programing and high plasticity for metabolic adaptation. These findings provide a framework for future research of metabolic properties of human DCs.

Project description:Progress in clinical translation of gene edited porcine kidney xenotransplantation is accelerating. However, kidney function entails more than removal of metabolic waste products and it is unknown if all endocrine functions will be faithfully reproduced by porcine kidneys in primate recipients. Seventeen cynomolgus macaques with survival >60days after life sustaining kidney xenotransplantation (LSKX) from gene edited Yucatan minipigs underwent measurement of xenograft growth and two kidney dependent endocrine pathways: renin-angiotensin-aldosterone-system (RAAS) and calcium-vitamin D-parathyroid-hormone. Clinical chemistries, plasma-renin-activity, Beta-C-terminal-telopeptide (CTx) assay, RNA-seq, single-cell RNA-seq, and serial ultrasonography were conducted and generalized linear models assessed statistical relationships. Xenografts transplanted from minipigs demonstrated only modest growth (estimated ~8.0% per year) and didn’t significantly contribute to recipient RAAS pathway. However, PTH-independent hypercalcemia and hypophosphatemia were observed and might be xenograft intrinsic suggesting close monitoring and timely intervention during the first month post-transplant. Further study of these phenotypes is warranted in designing prospective clinical trials.

Project description:Progress in clinical translation of gene edited porcine kidney xenotransplantation is accelerating. However, kidney function entails more than removal of metabolic waste products and it is unknown if all endocrine functions will be faithfully reproduced by porcine kidneys in primate recipients. Seventeen cynomolgus macaques with survival >60days after life sustaining kidney xenotransplantation (LSKX) from gene edited Yucatan minipigs underwent measurement of xenograft growth and two kidney dependent endocrine pathways: renin-angiotensin-aldosterone-system (RAAS) and calcium-vitamin D-parathyroid-hormone. Clinical chemistries, plasma-renin-activity, Beta-C-terminal-telopeptide (CTx) assay, RNA-seq, single-cell RNA-seq, and serial ultrasonography were conducted and generalized linear models assessed statistical relationships. Xenografts transplanted from minipigs demonstrated only modest growth (estimated ~8.0% per year) and didn’t significantly contribute to recipient RAAS pathway. However, PTH-independent hypercalcemia and hypophosphatemia were observed and might be xenograft intrinsic suggesting close monitoring and timely intervention during the first month post-transplant. Further study of these phenotypes is warranted in designing prospective clinical trials.

Project description:Vitamin D3 is a steroid hormone that has been shown to prevent tumor growth in prostate cells. Not having enough vitamin D3 in the blood has been linked to advanced prostate cancer and mortality, especially in African American men. We wanted to understand how vitamin D affected pathways that keep prostate cells from becoming cancerous, which could lead to new therapeutic targets and treatments, especially for African American men who tend to be more prone to being vitamin D deficient compared to European men. Here, we studied a non-cancerous African American prostate cell line treated with the active form of vitamin D with a concentration similar to what is found in the body for 24 h. Using RNA whole-transcriptome sequencing, we compared these treated cells with untreated cells to assess genes and pathways significantly changed due to treatment. We found that vitamin D affected the activity of 1600 genes, mainly suppressing pathways linked to prostate cell movement, growth, and viability. Only two genes, ANLN and ECT2, were strongly correlated with prostate cancer prognosis. Downregulation of ANLN and ECT2 was also shown to repress signaling pathways involved in prostate cell movement, growth, malignant transformation, and viability. In further validation utilizing prostate cancer cohorts comprised of African American and European American men, patients tended to have better sur-vival rates when these genes were less active. Our results suggest that vitamin D decreases the activity of these genes and could be important for preventing prostate cancer, especially for African American men. This could lead to the development of new treatments targeting specific genes and pathways involved in prostate cancer growth.

Project description:One striking observation is that a large portion of the inter-person variation in serum 25-hydroxyvitamin D (25(OH)D) levels is unexplained. In vitro and in vivo studies indicate vitamin D synthesizing and metabolizing enzymes are Mg-dependent. Magnesium (Mg) supplementation substantially reversed the resistance to vitamin D treatment in patients with magnesium-dependent vitamin-D-resistant rickets. The investigators reported in 2013 from observational studies conducted in the general US population that Mg intake significantly interacted with vitamin D intake in affecting vitamin D status as well as interacted with serum 25(OH)D in risk of cardiovascular disease mortality and, maybe, colorectal cancer mortality. The potential interaction between Mg and vitamin D was supported by two subsequent studies, including a Finnish cohort study and a mouse study. In the parent study (Personalized Prevention of Colorectal Cancer Trial, NCT01105169), the investigators proposed to measure blood concentration of total 25(OH)D as a secondary aim using Elisa approach. However, following the novel finding of Mg-vitamin D interaction published by the investigators in 2013, they submitted a separate grant application to NCI which was funded in 2014. In the new study, the investigators proposed to use a LC-MS approach, which is more accurate and specific than an Elisa method, to measure 5 vitamin D metabolites. This new ancillary study allows the investigators to evaluate whether Mg supplementation differentially affects vitamin D synthesis and metabolism dependent on baseline serum 25(OH)D levels using existing biospecimens collected in our double-blind placebo-controlled randomized chemoprevention trial.