Project description:Cloned embryos produced by somatic cell nuclear transfer (SCNT) display a plethora of phenotypic characteristics that make them different from fertilized embryos, indicating defects in the process of nuclear reprogramming by the recipient ooplasm. To elucidate the extent and timing of nuclear reprogramming, we used microarrays to analyze the transcriptome of mouse SCNT embryos during the first two cell cycles. We identified a large number of genes mis-expressed in SCNT embryos. We found that genes involved in transcription and regulation of transcription are prominent among affected genes, and thus may be particularly difficult to reprogram, and these likely cause a ripple effect that alters the transcriptome of many other functions, including oxidative phosphorylation, transport across membrane, and mRNA transport and processing. Interestingly, we also uncovered widespread alterations in the maternal (i.e. non transcribed) mRNA population of SCNT embryos. We conclude that gene expression in early SCNT embryos is grossly abnormal, and that this is at least in part the result of incomplete reprogramming of transcription factor genes. Experiment Overall Design: for both 1 and 2 cell stage we analyzed 4 samples each of fertilized embryos cultured with and without a-amanitin, scnt embryos cultured with and without a-amanitin, and parthennogenic embryos.

Project description:Cloned embryos produced by somatic cell nuclear transfer (SCNT) display a plethora of phenotypic characteristics that make them different from fertilized embryos, indicating defects in the process of nuclear reprogramming by the recipient ooplasm. To elucidate the extent and timing of nuclear reprogramming, we used microarrays to analyze the transcriptome of mouse SCNT embryos during the first two cell cycles. We identified a large number of genes mis-expressed in SCNT embryos. We found that genes involved in transcription and regulation of transcription are prominent among affected genes, and thus may be particularly difficult to reprogram, and these likely cause a ripple effect that alters the transcriptome of many other functions, including oxidative phosphorylation, transport across membrane, and mRNA transport and processing. Interestingly, we also uncovered widespread alterations in the maternal (i.e. non transcribed) mRNA population of SCNT embryos. We conclude that gene expression in early SCNT embryos is grossly abnormal, and that this is at least in part the result of incomplete reprogramming of transcription factor genes. Keywords: embryo kind comparison

Project description:Transcriptiome analysis is an excellent approach to understand the mechanism underlying nuclear reprogramming in somatic-cell-cloned embryos. Analysis of the transcriptomic data from the oocyte to blastocyst stage revealed that specific genes were inappropriately reprogrammed at each stage. Sertoli cell-cloned embryos appear to develop normally because the progression of incorrect reprogramming is concealed throughout development. The time-lapse gene expression profiles provide valuable information for understanding reprogramming in SCNT embryos.

Project description:Transcriptiome analysis is an excellent approach to understand the mechanism underlying nuclear reprogramming in somatic-cell-cloned embryos. Analysis of the transcriptomic data from the oocyte to blastocyst stage revealed that specific genes were inappropriately reprogrammed at each stage. Sertoli cell-cloned embryos appear to develop normally because the progression of incorrect reprogramming is concealed throughout development. The time-lapse gene expression profiles provide valuable information for understanding reprogramming in SCNT embryos. Single mouse oocyte (MII metaphase), in vitro fertilized embryo (replicates = 3 / each stage) and Sertoli cell cloned embryo (replicates = 5 / each stage) from 1-cell stage to blastocyst stage (16, 32, 48, 62, 72, 84 hours after sperm addition or activation) was used for total RNA extraction. Totally 51 Affymetrix microarrays were used in the experiment.

Project description:Long non-coding RNAs (lncRNA) have been shown to play crucial roles in tumorigenesis. Little is known about lncRNA RAD51-AS1 in diseases. Here, we investigated the role of RAD51-AS1 in Epithelial ovarian cancer. Silencing RAD51-AS1 inhibited proliferation through cell cycle arrest and promotion in apoptosis, both in vitro and in vivo. But the mechanism of RAD51-AS1 downstream regulation remains unclear. In order to identify the downstream regulation of RAD51-AS1 in epithelial ovarian cancer, we used antisene oligotides targeting RAD51-AS1 / negative control to transfect Skov3.ip cells. Then, we used microarrays to identified differential expression genes and to look for possible target genes by knockdown RAD51-AS1 expression.

Project description:RAD51, a multifunctional protein, plays a central role in DNA replication and homologous recombination repair, and is known to be involved in cancer development. We identified a novel role for RAD51 in innate immune response signaling. Defects in RAD51 lead to the accumulation of self-DNA in the cytoplasm, triggering a STING-mediated innate immune response after replication stress and DNA damage. Our data suggest that in addition to playing roles in homologous recombination-mediated DNA double-strand break repair and replication fork processing, RAD51 is also implicated in the suppression of innate immunity. Thus, our study reveals a previously uncharacterized role of RAD51 in initiating immune signaling, placing it at the hub of new interconnections between DNA replication, DNA repair, and immunity.

Project description:To investigate the role of RAD51 in HCC, we established Huh7 cell lines in which RAD51 has been knocked down(KD) by sgRNA,we performed RNA-seq for RAD51-KD Huh7 cells and parental Huh7 cells(control group,sgcon).

Project description:Transcription profiling of placentomes derived from somatic cell nuclear transfer (SCNT), in vitro fertilization (IVF) and artificial insemination (AI) at or near term development was performed in order to better understand why SCNT and IVF often result in placental defects, hydrops and large offspring syndrome (LOS). Multivariate analysis of variance was used to distinguish the effects of SCNT, IVF and AI on gene expression, taking into account the effects of parturition, sex of the fetus, breed of dam, breed of fetus and disease status of the offspring. The differential expression of 21 physiologically important genes was confirmed using quantitative PCR. The largest effect on placentome gene expression was attributable to whether placentae were collected at term or preterm (whether the collection was due to disease or to obtain matching case-controls) followed by placentome source (AI, IVF or SCNT). Gene expression in SCNT placentomes was dramatically different from AI (N=336 genes; 276 >2-fold) and from IVF (N=733 genes; 162 >2-fold) placentomes. Functional analysis of differentially expressed genes (DEG) showed that IVF has significant effects on genes associated with cellular metabolism. In contrast, DEG associated with SCNT are involved in multiple pathways, including cell cycle, cell death, gene expression, posttranslational modification, molecular transport and connective tissue development. Many DEG were shared between the gene lists for IVF and SCNT comparisons, suggesting that common pathways are affected by the embryo culture methods used for IVF and SCNT. However, the many unique gene functions and pathways affected by SCNT suggest that cloned fetuses may be starved and accumulating toxic wastes due to placental insufficiency caused by reprogramming errors. Many of these genes are candidates for hydrops and LOS. Keywords: gene expression; development; SCNT; cloning; nuclear transfer; IVF; AI

Project description:Genome stabilization by RAD51 stimulatory compound-1 enhances efficiency of somatic cell nuclear transfer-mediated reprogramming and full-term development of cloned mouse embryos

Project description:Early relapse after platinum chemotherapy in epithelial ovarian cancer (EOC) portends poor survival. A-priori identification of platinum-resistance is therefore crucial to improve on standard first-line carboplatin-paclitaxel treatment. The DNA repair pathway Homologous Recombination (HR) repairs platinum-induced damage, and the HR recombinase RAD51 is overexpressed in cancer. We therefore designed a REMARK-compliant study of pre-treatment RAD51 expression in EOC, using fluorescent quantitative immunohistochemistry (qIHC) to overcome challenges in quantitation of protein-expression in-situ. In a discovery cohort (n=284), RAD51-High tumours had shorter progression-free and overall survival compared to RAD51-Low cases in univariate and multivariate analyses. The association of RAD51 with relapse/survival was validated in a carboplatin-monotherapy SCOTROC4 clinical trial cohort (n=264), and was predominantly noted in HR-proficient cancers (Myriad HRDscore<42). Interestingly, overexpression of RAD51 modified expression of immune-regulatory pathways in-vitro, while high-RAD51 tumours showed exclusion of cytotoxic-T-cells in-situ. Our findings highlight RAD51 expression as a determinant of platinum resistance, and suggest possible roles for therapy to overcome immune exclusion in high-RAD51 EOC. The qIHC approach is generalizable to other proteins with a continuum instead of discrete/bimodal expression.