基于转录组测序方法研究加替沙星对小鼠的肝损伤作用

目的： 探讨加替沙星（GAT）对小鼠肝脏的损伤作用及其机制。方法： 选取32只SPF级雄性昆明小鼠作为研究对象，随机分为4组：低、中、高剂量（分别为25、50、100 mg/kg） GAT组和对照组。给药体积按10 mL/kg，连续灌胃给药7 d，对照组给予对应体积的生理盐水。通过检测各组小鼠血清中的谷丙转氨酶（ALT）、谷草转氨酶（AST）、碱性磷酸酶（AKP）、肌酐（CRE）和甘油三酯（TG）浓度，初步评价加替沙星导致的小鼠肝组织损伤。进一步利用转录组测序技术检测各组小鼠肝脏的基因表达谱，筛选差异表达基因，对差异基因进行基因本体论（GO）功能分类，并采用京都基因与基因组百科全书（KEGG）数据库进行信号通路富集分析。结果： 与对照组比较，高剂量GAT组小鼠肝脏质量显著降低（P<0.01）；低、中剂量GAT组肝脏系数显著降低（P<0.01）；低、中剂量GAT组小鼠血清ALT浓度显著降低（P<0.05或0.01）；低剂量GAT组小鼠血清AST浓度显著降低（P<0.01）。与对照组比较，中剂量GAT组共筛选出27个差异表达基因（包括20个上调基因，7个下调基因）。GO功能分类提示这些基因主要富集在免疫系统、多细胞生物、多生物及生殖过程等17个生物过程中。KEGG通路分析提示差异基因主要富集于脂质代谢、萜类化合物和聚酮化合物的代谢等22条通路中。结论： GAT可导致小鼠肝功能发生变化，并通过影响小鼠肝脏内胆汁酸和胆固醇等内分泌系统和脂质代谢等的平衡，造成肝组织损伤。     

Multiomic analysis reveals conservation of cancer-associated fibroblast phenotypes across species and tissue of origin

1. Download : Download high-res image (241KB)
2. Download : Download full-size image

     

Key benefits of dexamethasone and antibody treatment in COVID-19 hamster models revealed by single-cell transcriptomics

1. Download : Download high-res image (199KB)
2. Download : Download full-size image

     

多组学联用在中药作用机制研究中的应用

组学技术的运用主要基于高通量分析检测技术,包括转录组学、蛋白质组学和代谢组学等。生物信息学的飞速发展,为探索中药治疗疾病的机制提供新的思路和方法。在过去的数十年间,组学技术广泛应用于中药作用机制的研究当中。中药具有多成分、多靶点的特点,单一通路研究难以诠释中药"整体观念"的治疗思想,而多组学联用研究与这一观点不谋而合。查阅近年文献,对转录组学、蛋白质组学、代谢组学及16S rRNA测序等联用在中药治疗疾病中发挥的作用进行综述。     

Using ‘collective omics data’ for biomedical research training

Systems‐scale molecular profiling data accumulating in public repositories may constitute a useful resource for immunologists. It is for instance likely that information relevant to their chosen line of research be found among the more than 90,000 data series available in the NCBI Gene Expression Omnibus. Such ‘collective omics data’ may also be employed as source material for training purposes. This is the case when training curricula aim at the development of bioinformatics skills necessary for the analysis, interpretation or visualization of data generated on global scales. But ‘collective omics data’ may also be reused for training purposes to foster the development of the skills and ‘mental habits’ underpinning traditional reductionist science approaches. This review describes a small‐scale initiative involving investigators, for the most part immunologists, having engaged in a range of training activities relying on ‘collective omics data’.     

Proteomics and transcriptomics of peripheral nerve tissue and cells unravel new aspects of the human Schwann cell repair phenotype

The remarkable feature of Schwann cells (SCs) to transform into a repair phenotype turned the spotlight on this powerful cell type. SCs provide the regenerative environment for axonal re‐growth after peripheral nerve injury (PNI) and play a vital role in differentiation of neuroblastic tumors into a benign subtype of neuroblastoma, a tumor originating from neural crest‐derived neuroblasts. Hence, understanding their mode‐of‐action is of utmost interest for new approaches in regenerative medicine, but also for neuroblastoma therapy. However, literature on human SCs is scarce and it is unknown to which extent human SC cultures reflect the SC repair phenotype developing after PNI in patients. We performed high‐resolution proteome profiling and RNA‐sequencing on highly enriched human SC and fibroblast cultures, control and ex vivo degenerated nerve explants to identify novel molecules and functional processes active in repair SCs. In fact, we found cultured SCs and degenerated nerves to share a similar repair SC‐associated expression signature, including the upregulation of JUN, as well as two prominent functions, i.e., myelin debris clearance and antigen presentation via MHCII. In addition to myelin degradation, cultured SCs were capable of actively taking up cell‐extrinsic components in functional phagocytosis and co‐cultivation assays. Moreover, in cultured SCs and degenerated nerve tissue MHCII was upregulated at the cellular level along with high expression of chemoattractants and co‐inhibitory rather than ‐stimulatory molecules. These results demonstrate human SC cultures to execute an inherent program of nerve repair and support two novel repair SC functions, debris clearance via phagocytosis‐related mechanisms and type II immune‐regulation. GLIA 2016;64:2133–2153