确定甲型流感病毒在 Madin-Darby 犬肾细胞系中不同时间点的脱落情况。

Determining influenza virus shedding at different time points in madin-darby canine kidney cell line.

机构信息

1. Department of Virology, Faculty of Medical Science, Tarbiat Modares University, Tehran, Iran.

出版信息

Cell J. 2013 Summer;15(2):130-5. Epub 2013 Jul 2.

PMID:23862114

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3712773/

Abstract

OBJECTIVE

Monitoring of influenza virus shedding and optimization of multiplicities of infection (MOI) is important in the investigation of a virus one step growth cycle and for obtaining a high yield of virus in vaccine development and conventional basic diagnostic methods. However, eluted infectious viruses may still be present immediately after virus inoculation and when cells are washed following virus cultivation which may lead to a false positive virus infectivity assay.

MATERIALS AND METHODS

In this experimental study, we investigated influenza virus progeny production in Madin-Darby canine kidney (MDCK) cells with five different MOI at determined time points. The results were analyzed by end point titration tests and immunofluorescence assay.

RESULTS

Higher titers of eluted virus were observed following a high MOI inoculation of virus in cell culture. Most probably, this was the result of sialic acid residues from viral hemagglutin in proteins that were cleaved by neuraminidase glycoproteins on the surface of the influenza virus, which promoted viral spread from the host cell to the culture supernatant or during endocytosis, where viruses recycle to the cell surface by recycling endosomes which culminated in virus shedding without replication.

CONCLUSION

We demonstrated that the pattern of influenza virus progeny production was dose-dependent and not uniform. This production was influenced by several factors, particularly MOI. Understanding the exact features of viral particle propagation has a major impact in producing high virus yields in the development of vaccines. Use of lower MOI (0.01) could result in accurate, precise quantitative assays in virus diagnosis and titration methods.

摘要

目的

监测流感病毒的脱落并优化感染复数（MOI）对于研究病毒的一步生长周期以及在疫苗开发和常规基本诊断方法中获得高产量的病毒非常重要。然而，在病毒接种后立即和在病毒培养后清洗细胞时，可能仍存在洗脱的传染性病毒，这可能导致病毒感染性测定出现假阳性。

材料和方法

在这项实验研究中，我们以五个不同的 MOI 在确定的时间点研究了流感病毒在犬肾细胞（MDCK）中的子代病毒产生情况。结果通过终点滴定试验和免疫荧光法进行分析。

结果

在细胞培养中高 MOI 接种病毒后，观察到洗脱病毒的滴度更高。很可能，这是由于病毒血凝素蛋白中的唾液酸残基被表面神经氨酸酶糖蛋白切割，从而促进了病毒从宿主细胞传播到培养上清液或内吞作用，在那里病毒通过再循环内体循环回到细胞表面，导致病毒脱落而不进行复制。

结论

我们证明了流感病毒子代产生的模式是剂量依赖性的，而不是均匀的。这种产生受到多种因素的影响，特别是 MOI。了解病毒粒子传播的确切特征对疫苗开发中产生高病毒产量有重大影响。使用较低的 MOI（0.01）可以在病毒诊断和滴定方法中产生准确、精确的定量测定。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6aa1/3712773/c54f7a1ffe4f/Cell-J-15-130-g01.jpg

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确定甲型流感病毒在 Madin-Darby 犬肾细胞系中不同时间点的脱落情况。

Determining influenza virus shedding at different time points in madin-darby canine kidney cell line.

机构信息

出版信息

OBJECTIVE

MATERIALS AND METHODS

RESULTS

CONCLUSION

目的

材料和方法

结果

结论

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