猪干扰素复合物及其在驯化后病毒压力增加下的共同进化。

Porcine Interferon Complex and Co-Evolution with Increasing Viral Pressure after Domestication.

机构信息

Department of Agricultural and Environmental Sciences, College of Agriculture, Tennessee State University, Nashville, TN 37209, USA.

出版信息

Viruses. 2019 Jun 15;11(6):555. doi: 10.3390/v11060555.

DOI:10.3390/v11060555

PMID:31208045

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6631851/

Abstract

Consisting of nearly 60 functional genes, porcine interferon (IFN)-complex represents an evolutionary surge of IFN evolution in domestic ungulate species. To compare with humans and mice, each of these species contains about 20 IFN functional genes, which are better characterized using the conventional IFN-α/β subtypes as examples. Porcine IFN-complex thus represents an optimal model for studying IFN evolution that resulted from increasing viral pressure during domestication and industrialization. We hypothesize and justify that porcine IFN-complex may extend its functionality in antiviral and immunomodulatory activity due to its superior molecular diversity. Furthermore, these unconventional IFNs could even confer some functional and signaling novelty beyond that of the well-studied IFN-α/β subtypes. Investigations into porcine IFN-complex will further our understanding of IFN biology and promote IFN-based therapeutic designs to confront swine viral diseases.

摘要

由近 60 个功能基因组成，猪干扰素（IFN）复合物代表了家畜物种中 IFN 进化的一次进化飞跃。为了与人和小鼠进行比较，这些物种中的每一种都含有大约 20 个 IFN 功能基因，这些基因可以使用常规的 IFN-α/β亚型更好地进行特征描述。因此，猪 IFN 复合物是研究由于驯化和工业化过程中病毒压力增加而导致的 IFN 进化的理想模型。我们假设并证明，由于其优异的分子多样性，猪 IFN 复合物可能会在抗病毒和免疫调节活性方面扩展其功能。此外，这些非常规 IFN 甚至可能赋予比研究充分的 IFN-α/β亚型更多的功能和信号新颖性。对猪 IFN 复合物的研究将增进我们对 IFN 生物学的理解，并促进基于 IFN 的治疗设计以应对猪病毒性疾病。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3b09/6631851/00afc485df9f/viruses-11-00555-g002.jpg

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猪干扰素复合物及其在驯化后病毒压力增加下的共同进化。

Porcine Interferon Complex and Co-Evolution with Increasing Viral Pressure after Domestication.

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