多杀性巴氏杆菌毒素的细胞毒性模型及其组织学研究

IF 0.9 4区 材料科学 Science of Advanced Materials Pub Date : 2023-10-01 DOI:10.1166/sam.2023.4535
Heng Lu, Huanhuan Shen, Yong Huang
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引用次数: 0

摘要

在本研究中,我们研究了重组多体巴尔通体毒素rPMT损伤PK15细胞的分子机制。我们成功构建了原核表达载体pCold I-toxA,并确定了rPMT合适的表达和纯化条件。采用CCK8法建立细胞损伤模型,发现浓度为20 ug/mL的rPMT感染PK15细胞24 h后对PK15细胞有明显影响,流式细胞术实验显示rPMT诱导PK15细胞凋亡。为了进一步了解其潜在的机制,我们制备了一种有效的抗rPMT的小鼠多克隆抗体,并评估了其有效性(效价为1:1000)。在小鼠实验中,测定rPMT的LD50为0.460 ng/g。转录组测序数据表明,rPMT损伤PK15细胞导致炎症相关通路和基因的表达升高。此外,QPCR实验证实,与正常PK15细胞相比,rPMT损伤显著上调炎症相关因子的表达,包括NLRP3、IL-1 β、IL-6、IL-8和TNF- α。综上所述,本研究中使用的重组PMT毒素(rPMT)具有较高的生物活性,可能通过炎症验证效应对PK15细胞造成显著损伤。这些发现揭示了rpmt诱导细胞损伤的分子机制及其在炎症相关途径中的潜在作用。
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Cytotoxicity Modelling of Pasteurella multocida Toxin and Its Histological Study
In this study, we investigated the molecular mechanism by which the recombinant multicidal Bartonella toxin rPMT damages PK15 cells. We successfully constructed the prokaryotic expression vector pCold I-toxA and identified suitable expression and purification conditions for rPMT. Using the CCK8 assay, we established a cellular damage model and found that PK15 cells were significantly affected by rPMT infection at a concentration of 20 ug/mL for 24 h. Flow cytometry experiments revealed that rPMT induced apoptosis in PK15 cells. To further understand the underlying mechanism, we prepared a potent murine anti-polyclonal antibody against rPMT and evaluated its effectiveness (potency of 1:1000). In mouse experiments, the LD50 of rPMT was determined to be 0.460 ng/g. Transcriptome sequencing data indicated that rPMT injury to PK15 cells led to elevated expression of inflammation-related pathways and genes. Additionally, QPCR experiments confirmed that rPMT injury significantly upregulated the expression of inflammation-related factors, including NLRP3, IL-1 β , IL-6, IL-8, and TNF- α , compared to normal PK15 cells. In conclusion, the recombinant PMT toxin (rPMT) used in this study exhibited high biological activity and caused significant damage to PK15 cells, possibly through an inflammatory validation effect. These findings shed light on the molecular mechanisms underlying rPMT-induced cellular damage and its potential role in inflammation-related pathways.
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来源期刊
Science of Advanced Materials
Science of Advanced Materials NANOSCIENCE & NANOTECHNOLOGY-MATERIALS SCIENCE, MULTIDISCIPLINARY
自引率
11.10%
发文量
98
审稿时长
4.4 months
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