Project description:Wageningen University Common Carp Genome Assembly

Project description:In this experiment we evaluate the transcriptional responses of G pallida D383 1-2A to diverse hatching stimulations by pure Solanoeclepin A or by potato root exudate. We used cysts hydrated for 7 days in tap water for the experiment. Water for hydration was changed every day. After hydration approximately 13mg of cysts (50-100 cysts) were placed over Netwell inserts (Corning) with 74um mesh size. For this experiment we used 5 “technical” replicates, all performed in the same experiment. Worms underwent the treatment at the Laboratory of Nematology (WUR)(Spit lab) and RNA was extracted in the same lab using the Qiagen RNeasy Micro kit. RNA samples were measured by Nanodrop and Qubit and were sent to the Wageningen BioInformatics business unit. (Wageningen, The Netherlands, Dr. Sara Diaz Trivino’s team) on dry ice. Sequencing was performed by the DLO in Wageningen.

Project description:Porcine 60K BeadChip genotyping arrays (Illumina) are increasingly being applied in pig genomics to validate SNPs identified by re-sequencing or assembly-versus-assembly method. Here we report that more than 98% SNPs identified from the porcine 60K BeadChip genotyping array (Illumina) were consistent with the SNPs identified from the assembly-based method. This result demonstrates that whole-genome de novo assembly is a reliable approach to deriving accurate maps of SNPs.

Project description:Porcine 60K BeadChip genotyping arrays (Illumina) are increasingly being applied in pig genomics to validate SNPs identified by re-sequencing or assembly-versus-assembly method. Here we report that more than 98% SNPs identified from the porcine 60K BeadChip genotyping array (Illumina) were consistent with the SNPs identified from the assembly-based method. This result demonstrates that whole-genome de novo assembly is a reliable approach to deriving accurate maps of SNPs. To compare SNPs identified by genotyping arrays and de novo assembly method, we genotyped 10 pig breeds by porcine 60K BeadChip genotyping array (Illumina), including 1 berkshire pig, 1 hampshire pig, 1 landrace pig, 1 large white pig,1 piétrain pig, 1 bamei pig,1 jinhua pig, 1 meishan pig, 1 rongchang pig and 1 Tibetan wild boar.

Project description:Porcine satellite cells play a vital role in the construction, development, and self-renewal of skeletal muscle. In this study, porcine satellite cells were exposed to mimic viral infection poly (I:C) during proliferation and differentiation phases at 0h, 12h, 24h and 48h time points. The untreated and treated porcine satellite cells during proliferation and differentiation phases were further analyzed by RNA sequencing technology. In the proliferation and differentiation phases of porcine satellite cells grown under poly (I:C), 88, 119, 104 and 95 genes were differentially expressed in 0h – 12h treated, 12h – 24h treated, 0h – 24h treated and 24h – 48h untreated comparison libraries, respectively. The GO terms analysis results showed that in the proliferation phase of treated porcine satellite cells, the up-regulated genes related to the immune system were highly expressed. In addition, the gene expression associated with muscle structure development, response to growth factor emerged in the differentiation phase of untreated porcine satellite cells. The biological pathways associated with Influenza A, Toll-like signaling as well as chemokine signaling were revealed through poly (I:C) stimulation of porcine satellite cells. The differentially expressed genes were confirmed by quantitative real-time PCR. Our findings expanded the understanding of gene expression and signaling pathways about the infiltrated mechanism of the virus into porcine skeletal muscle satellite cells.

Project description:To maintain genomic stability, re-initiation of eukaryotic DNA replication within a single cell cycle is blocked by multiple mechanisms that inactivate or remove replication proteins after G1 phase. Consistent with the prevailing notion that these mechanisms are redundant, we previously showed that simultaneous deregulation of three replication proteins, ORC, Cdc6 and Mcm2-7, was necessary to cause detectable bulk re-replication in G2/M phase in Saccharomyces cerevisiae. In this study, we used microarray comparative genomic hybridization (CGH) to provide a more comprehensive and detailed analysis of re-replication. This genome-wide analysis suggests that re-initiation in G2/M phase primarily occurs at a subset of both active and latent origins, but is independent of chromosomal determinants that specify the use and timing of these origins in S phase. We demonstrate that re-replication can be induced within S phase, but differs in amount and location fr om re-replication in G2/M phase, illustrating the dynamic nature of DNA replication controls. Finally, we show that very limited re-replication can be detected by microarray CGH when only two replication proteins are deregulated, suggesting that the mechanisms blocking re-replication are not redundant. Therefore we propose that eukaryotic re-replication at levels below current detection limits may be more prevalent and a greater source of genomic instability than previously appreciated. Keywords: comparative genomic hybridization (CGH), DNA replication, re-replication

Project description:Wageningen University & Research Animal Breeding and Genomics FAANG data from three boars.

Project description:China Agricultural University Porcine Whole-Genome resequencing

Project description:Background The domestic pig is an important livestock species for meat production worldwide and is becoming an established biomedical research model. As a result, there is a strong interest in the factors that affect the efficient production of viable embryos and offspring in this species using either in vivo or in vitro production methods. A limited understanding of the molecular mechanisms involved in this critical physiological process has inhibited our ability to fully elucidate these factors. The use of next generation deep sequencing and microarray technology are powerful tools for delineation of molecular pathways during early embryonic development of mammals. Here, we report on the assessment of a porcine-embryo-specific microarray platform created from a large expressed sequence tag (EST) analysis generated by Roche/454 next-generation sequencing of cDNAs constructed from critical stages of in vivo or in vitro porcine preimplantation embryos. Results Two cDNA libraries constructed from in vitro and in vivo produced preimplantation porcine embryos were normalized and sequenced using the 454 Titanium pyrosequencing technology. Treatment of cDNA libraries with BAL 31 nuclease digestion resulted in a 2 fold improvement of sequencing quality compared with untreated libraries. Over one million high quality EST sequences were obtained from this process and used to create an augmented porcine genome catalogue. Using the resulting dataset the EMbryogene Porcine Version 1 (EMPV1) microarray was developed and is composed of 43,795 probes printed onto a 4 × 44 K Agilent array. Based on the initial probe sequences annotation, the EMPV1 featured 17,409 protein-coding, 473 pseudogenes, 46 retrotransposed, 2,359 non-coding RNA (snRNA, snoRNA, etc.), 4,121 splice variants in 2,862 genes and a total of 12,324 Novel Transcript Regions (NTR). After re-annotation, the total unique genes increased from 11,961 to 16,281 and 1.9% of them belonged to a large olfactory receptor (OR) gene family. Quality control of EMPV1 was performed using porcine cumulus–oocyte complexes (COC) as well as early developmental stages of embryos. This revealed an even distribution of ten clusters of spike-in control spots and array to array (dye-swap) correction was 0.97. Further bioinformatics analysis revealed that our microarray probes hybridized with more developmental related transcripts from embryonic labelled targets when compared to COC. Conclusions Using next-generation deep sequencing we have produced a large EST dataset to provide the selection of probe sequences for the development of the EMPV1 microarray platform. The quality of this embryo- specific array was confirmed with the high level of reproducibility using current Agilent microarray technology. Despite the current limitations for full NTR annotation, due to the incomplete porcine genome sequencing project, a significant number of NTR were annotated using Version 10 of porcine genome and human RefSeq RNA database to enrich the orthologous genes with unique gene symbol (GS) for Gene Ontology (GO) search. GO terms confirmed that many are related relevant developmental processes. With more than an estimated 20 thousands unique genes represented on the EMPV1, this platform will provide the foundation for future research into the in vivo and in vitro factors that affect the viability of the porcine embryos, as well as the effects of these factors on the live offspring that result from these embryos. Two biological samples.

Project description:The pig is important for agriculture and as an animal model in human and veterinary medicine, yet, despite over 20 years of effort, it has proved a difficult species from which to generate pluripotent stem cells analogous to those derived from mouse embryos. Here we report the production of LIF-dependent, so called naïve type, pluripotent stem cells from the inner cell mass of porcine blastocysts by up-regulating expression of KLF4 and POU5F1. These cells resemble mouse ES cells and are distinct from the FGF2-dependent, induced pluripotent cell type derived from porcine somatic cells. Transcript profiling utilized Affymetrix porcine microarrays were conducted to compare the gene expressions associated with pluripotency in the two LIF-dependent pESK lines (pESK I & II, passage 14 & 5, respectively) with a naïve phenotype and two porcine iPSC lines (ID4 & ID6, both passage 7, GSE15472) with a primed phenotype that re-programming of porcine fetal fibroblasts (EGFP-PFF, GSE15472). The pESK lines clustered separately from the porcine iPSC lines, EGFP-PFF and primary cultures established from explants of porine umbilical cord (PUC).