MiR-186-5p对3T3-L1前脂肪细胞增殖分化的影响研究 *

目的 探究miR-186-5p对小鼠3T3-L1前脂肪细胞增殖,分化的影响及其潜在的分子机制.方法: qRT-PCR检测miR-186-5p在不同周龄小鼠白色脂肪组织及3T3-L1前脂肪细胞增殖分化过程中的表达变化;通过脂质体将miR-186-5p mimics,inhibitors转染入增殖液或分化液培养的3T3-L1细胞后,利用CCK-8,EdU和qRT-PCR检测3T3-L1前脂肪细胞增殖变化,油红O染色观察其脂滴形态;通过生物信息软件TargetScan和双荧光报告系统分别对miR-186-5p靶基因进行预测和确认.结果: (1)miR-186-5p在1~6周龄小鼠的白色脂肪组织及3T3-L1前脂肪细胞自然分化过程中表达量均逐渐上调.(2)与阴性对照相比,mimics或inhibitors转染分别显著地促进或抑制了miR-186-5p的表达.(3)过表达miR-186-5p后,3T3-L1前脂肪细胞的增殖速率减慢,脂滴增大增多;而抑制miR-186-5p后,3T3-L1前脂肪细胞增殖速率增快,脂滴数量减少,且粒径变小.其中过表达miR-186-5p显著地降低了野生型Wnt5a和Mapk1 3'-UTR活性,而突变相应的绑定位点可解除该抑制作用.结论: miR-186-5p可抑制3T3-L1前脂肪细胞增殖,且通过直接靶向Wnt5a和Mapk1以促进其分化为成熟脂肪细胞.     

Emerging Roles and Research Tools of Atypical Ubiquitination

Ubiquitination is a posttranslational modification characterized by the covalent attachment of ubiquitin molecules to protein substrates. The ubiquitination modification process is reversible, dynamic, and involved in the regulation of various biological processes, such as autophagy, inflammatory responses, and DNA damage responses. The forms of ubiquitin modification are very diverse, incorporating either a single ubiquitin molecule or a complicated ubiquitin polymer, and different types of ubiquitination usually elicit corresponding cellular responses. The development of research tools and strategies has afforded more detailed insight into atypical ubiquitin signaling pathways that were previously poorly understood. Here, an update on the understanding of atypical ubiquitin chain signaling pathways is provided and the recent development of representative research tools for ubiquitin systems is discussed. In addition, the future challenges in ubiquitin research are reflected on and summarized.     

PDMS Microwell Stencil Based Multiplexed Single‐Cell Secretion Analysis

Multiplexed single‐cell protein secretion analysis provides an in‐depth understanding of cellular heterogeneity in intercellular communications mediated by secreted proteins in both fundamental and clinical research. However, it has been challenging to increase the proteomic parameters co‐profiled from every single cell in a facile way. Herein, a simple method to improve the multiplexed proteomic parameters of PDMS microwell based single‐cell secretion analysis platform by sandwiching PDMS stencil in between two antibody‐coated glass slides is introduced. Two different antibody panels can be immobilized easily by static coating, without using sophisticated fluid handling or bulky equipment. 5‐plexed, 3‐fluorescence color single‐cell secretion assay is demonstrated with this platform to investigate human monocytic U937 cells in response to lipopolysaccharide and phorbol myristate acetate stimulation, which identified the existence of functional subsets dictated by different cytokine profiles. The technology introduced here is simple, easy to operate, which holds great potential to become a powerful tool for profiling multiplexed single‐cell cytokine secretion at high throughput to dissect cellular heterogeneity in secretome signatures.     

Scale‐down simulators for mammalian cell culture as tools to access the impact of inhomogeneities occurring in large‐scale bioreactors

During the scale‐up of a bioprocess, not all characteristics of the process can be kept constant throughout the different scales. This typically results in increased mixing times with increasing reactor volumes. The poor mixing leads in turn to the formation of concentration gradients throughout the reactor and exposes cells to varying external conditions based on their location in the bioreactor. This can affect process performance and complicate process scale‐up. Scale‐down simulators, which aim at replicating the large‐scale environment, expose the cells to changing environmental conditions. This has the potential to reveal adaptation mechanisms, which cells are using to adjust to rapidly fluctuating environmental conditions and can identify possible root causes for difficulties maintaining similar process performance at different scales. This understanding is of utmost importance in process validation. Additionally, these simulators also have the potential to be used for selecting cells, which are most robust when encountering changing extracellular conditions. The aim of this review is to summarize recent work in this interesting and promising area with the focus on mammalian bioprocesses, since microbial processes have been extensively reviewed.     

Development,characterization, and application of a 2‐Compartment system to investigate the impact of pH inhomogeneities in large‐scale CHO‐based processes

Large‐scale bioreactors for the production of monoclonal antibodies reach volumes of up to 25 000 L. With increasing bioreactor size, mixing is however affected negatively, resulting in the formation of gradients throughout the reactor. These gradients can adversely affect process performance at large scale. Since mammalian cells are sensitive to changes in pH, this study investigated the effects of pH gradients on process performance. A 2‐Compartment System was established for this purpose to expose only a fraction of the cell population to pH excursions and thereby mimicking a large‐scale bioreactor. Cells were exposed to repeated pH amplitudes of 0.4 units (pH 7.3), which resulted in decreased viable cell counts, as well as the inhibition of the lactate metabolic shift. These effects were furthermore accompanied by increased absolute lactate levels. Continuous assessment of molecular attributes of the expressed target protein revealed that subunit assembly or N‐glycosylation patterns were only slightly influenced by the pH excursions. The exposure of more cells to the same pH amplitudes further impaired process performance, indicating this is an important factor, which influences the impact of pH inhomogeneity. This knowledge can aid in the design of pH control strategies to minimize the effects of pH inhomogeneity in large‐scale bioreactors.     

Microflow system promotes acetaminophen crystal nucleation

It is known that interfaces have various impacts on crystallization from a solution. Here, we describe crystallization of acetaminophen using a microflow channel, in which two liquids meet and form a liquid–liquid interface due to laminar flow, resulting in uniform mixing of solvents on the molecular scale. In the anti‐solvent method, the microflow mixing promoted the crystallization more than bulk mixing. Furthermore, increased flow rate encouraged crystal formation, and a metastable form appeared under a certain flow condition. This means that interface management by the microchannel could be a beneficial tool for crystallization and polymorph control.     

成纤维细胞生长因子5的研究进展 *

成纤维细胞生长因子5(fibroblast growth factor 5,FGF5)是成纤维细胞生长因子家族(FGFs)的成员之一,在哺乳动物毛囊,神经系统,睾丸等多个部位及胚胎发育过程中均有表达.研究发现,FGF5具有广泛的生物学活性,如作为毛发生长重要的调节因子其编码基因突变将导致毛发异常生长,作为丝裂原在干细胞增殖,血管生成和肢体肌发育等方面发挥重要作用,以及在高血压,肿瘤等方面具有重要的生物学功能.目前,FGF5在多种疾病中的功能和作用机制尚需进一步深入研究,但其在毛发生长,干细胞增殖及在心血管疾病等方面的生物学作用具有重大的意义和临床应用价值.总结了近些年FGF5的研究进展,系统阐述了FGF5在毛发生长,干细胞增殖分化,心血管疾病及癌症等方面的相关作用机制,为进一步深入研究FGF5在疾病治疗中的作用和开发利用提供参考.     

Tumour‐derived exosomal miR‐3473b promotes lung tumour cell intrapulmonary colonization by activating the nuclear factor‐κB of local fibroblasts

Tumour‐derived exosomes have been shown to induce pre‐metastatic niche formation, favoring metastatic colonization of tumour cells, but the underlying molecular mechanism is still not fully understood. In this study, we showed that exosomes derived from the LLC cells could indeed significantly enhance their intrapulmonary colonization. Circulating LLC‐derived exosomes were mainly engulfed by lung fibroblasts and led to the NF‐κB signalling activation. Further studies indicated that the exosomal miR‐3473b was responsible for that by hindering the NFKB inhibitor delta's (NFKBID) function. Blocking miR‐3473b could reverse the exosome‐mediated NF‐κB activation of fibroblasts and decrease intrapulmonary colonization of lung tumour cells. Together, this study demonstrated that the miR‐3473b in exosomes could mediate the interaction of lung tumour cells and local fibroblasts in metastatic sites and, therefore, enhance the metastasis of lung tumour cells.