Department of Animal Science, Purdue University, West Lafayette, Indiana, United States of America.
PLoS One. 2011;6(7):e22541. doi: 10.1371/journal.pone.0022541. Epub 2011 Jul 29.
Transcriptome analysis of bovine mammary development has provided insight into regulation of mammogenesis. However, previous studies primarily examined expression of epithelial and stromal tissues combined, and consequently did not account for tissue specific contribution to mammary development. Our objective was to identify differences in gene expression in epithelial and intralobular stromal compartments. Tissue was biopsied from non-lactating dairy cows 3 weeks prepartum, cut into explants and incubated for 2 hr with insulin and hydrocortisone. Epithelial and intralobular stromal tissues were isolated with laser capture microdissection. Global gene expression was measured with Bovine Affymetrix GeneChips, and data were preprocessed using RMA method. Moderated t-tests from gene-specific linear model analysis with cell type as a fixed effect showed more than 3,000 genes were differentially expressed between tissues (P<0.05; FDR<0.17). Analysis of epithelial and stromal transcriptomes using Database for Annotation, Visualization and Integrated Discovery (DAVID) and Ingenuity Pathways Analysis (IPA) showed that epithelial and stromal cells contributed distinct molecular signatures. Epithelial signatures were enriched with gene sets for protein synthesis, metabolism and secretion. Stromal signatures were enriched with genes that encoded molecules important to signaling, extracellular matrix composition and remodeling. Transcriptome differences also showed evidence for paracrine interactions between tissues in stimulation of IGF1 signaling pathway, stromal reaction, angiogenesis, neurogenesis, and immune response. Molecular signatures point to the dynamic role the stroma plays in prepartum mammogenesis and highlight the importance of examining the roles of cell types within the mammary gland when targeting therapies and studying mechanisms that affect milk production.
牛乳腺发育的转录组分析为乳腺发生的调控提供了深入的了解。然而,以前的研究主要考察了上皮和基质组织的联合表达,因此没有考虑到组织对乳腺发育的特定贡献。我们的目的是鉴定上皮组织和小叶内基质隔室中基因表达的差异。从产前 3 周的非泌乳奶牛中采集组织活检,切成组织块,并在胰岛素和氢化可的松存在的情况下用激光捕获微切割进行 2 小时孵育。通过激光捕获微切割分离上皮组织和小叶内基质组织。使用 Bovine Affymetrix GeneChips 测量全局基因表达,并用 RMA 方法对数据进行预处理。基于细胞类型的固定效应的基因特异性线性模型分析的调节 t 检验表明,组织间有 3000 多个基因表达差异(P<0.05; FDR<0.17)。使用数据库注释、可视化和综合发现(DAVID)和 Ingenuity 通路分析(IPA)对上皮和基质转录组进行分析,表明上皮和基质细胞具有独特的分子特征。上皮细胞的特征是富含与蛋白质合成、代谢和分泌相关的基因集。基质细胞的特征是富含编码对信号转导、细胞外基质组成和重塑重要的分子的基因。转录组差异还表明,在 IGF1 信号通路的刺激、基质反应、血管生成、神经发生和免疫反应中,组织之间存在旁分泌相互作用的证据。分子特征表明,基质在产前乳腺发生中起着动态作用,并强调了在靶向治疗和研究影响产奶量的机制时,研究细胞类型在乳腺中的作用的重要性。
