Transcriptomic profile of genes encoding proteins responsible for regulation of cells differentiation and neurogenesis in vivo and in vitro – an oocyte model approach

Q4 Biochemistry, Genetics and Molecular Biology

Medical Journal of Cell Biology Pub Date : 2020-03-01 DOI:10.2478/acb-2020-0001

Lisa Moncrieff, I. Kocherova, A. Bryja, W. Kranc, Joanna Perek, M. Kulus, M. Ješeta, C. Dompe, Greg Hutchings, Krzysztof Janowicz, P. Celichowski, M. Bruska, M. Zabel, B. Kempisty, P. Mozdziak

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引用次数: 1

Abstract

Abstract The growth and development of the oocyte is essential for the ovarian follicle. Cumulus cells (CCs) - a population of granulosa cells - exchange metabolites, proteins and oocyte-derived paracrine factors with the oocyte through gap junctions, to contribute to the competency and health of the oocyte. This bi-directional communication of the cumulus-oocyte complex could be better understood through the micro-analysis of a porcine oocyte gene expression before in vitro maturation (IVM) and after. Additionally, the study of the somatic and gamete cells differentiation capability into neuronal lineage would be promising for future stem cell research as granulosa cells are easily accessible waste material from in vitro fertilization (IVF) procedures. Therefore, in this study, the oocytes of 45 pubertal Landrace gilts were isolated and the protein expression of the COCs were analyzed through micro-analysis techniques. Genes belonging to two ontological groups: neuron differentiation and negative regulation of cell differentiation have been identified which have roles in proliferation, migration and differentiation. Twenty identified porcine oocyte genes (VEGFA, BTG2, MCOLN3, EGR2, TGFBR3, GJA1, FST, CTNNA2, RTN4, MDGA1, KIT, RYK, NOTCH2, RORA, SMAD4, ITGB1, SEMA5A, SMARCA1, WWTR1 and APP) were found to be down-regulated after the transition of IVM compared to in vitro. These results could be applied as gene markers for the proliferation, migration and differentiation occurring in the bi-directional communication between the oocyte and CCs. Running title: Differentiation and neurogenesis in oocyte cells

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编码负责体内外细胞分化和神经发生调控的蛋白质的基因转录组学图谱——卵母细胞模型方法

摘要卵母细胞的生长发育对卵泡发育至关重要。Cumulus细胞（CC）是一组颗粒细胞，通过间隙连接与卵母细胞交换代谢产物、蛋白质和卵母细胞衍生的旁分泌因子，以促进卵母细胞的能力和健康。卵丘-卵母细胞复合体的这种双向交流可以通过对体外成熟（IVM）前后猪卵母细胞基因表达的微观分析来更好地理解。此外，体细胞和配子细胞分化为神经元谱系的能力的研究将为未来的干细胞研究带来希望，因为颗粒细胞是体外受精（IVF）过程中容易获得的废物。因此，在本研究中，分离了45只青春期长白猪的卵母细胞，并通过显微分析技术分析了这些卵母细胞的蛋白质表达。已鉴定出两类本体论基因：神经元分化和细胞分化负调控，它们在增殖、迁移和分化中发挥作用。与体外相比，发现20个已鉴定的猪卵母细胞基因（VEGFA、BTG2、MCOLN3、EGR2、TGFBR3、GJA1、FST、CTNNA2、RTN4、MDGA1、KIT、RYK、NOTCH2、RORA、SMAD4、ITGB1、SEMA5A、SMARCA1、WWTR1和APP）在IVM转换后下调。这些结果可作为卵母细胞和CC之间双向通讯中发生的增殖、迁移和分化的基因标记。运行标题：卵母细胞的分化和神经发生

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Medical Journal of Cell Biology Biochemistry, Genetics and Molecular Biology-Cell Biology

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