非洲猪瘟病毒多基因家族360和530基因影响宿主干扰素反应。
African swine fever virus multigene family 360 and 530 genes affect host interferon response.
作者信息
Afonso C L, Piccone M E, Zaffuto K M, Neilan J, Kutish G F, Lu Z, Balinsky C A, Gibb T R, Bean T J, Zsak L, Rock D L
机构信息
Plum Island Animal Disease Center, Agricultural Research Service, U.S. Department of Agriculture, Greenport, New York 11944, USA.
出版信息
J Virol. 2004 Feb;78(4):1858-64. doi: 10.1128/jvi.78.4.1858-1864.2004.
African swine fever virus (ASFV) multigene family 360 and 530 (MGF360/530) genes affect viral growth in macrophage cell cultures and virulence in pigs (L. Zsak, Z. Lu, T. G. Burrage, J. G. Neilan, G. F. Kutish, D. M. Moore, and D. L. Rock, J. Virol. 75:3066-3076, 2001). The mechanism by which these novel genes affect virus-host interactions is unknown. To define MGF360/530 gene function, we compared macrophage transcriptional responses following infection with parental ASFV (Pr4) and an MGF360/530 deletion mutant (Pr4 Delta 35). A swine cDNA microarray containing 7,712 macrophage cDNA clones was used to compare the transcriptional profiles of swine macrophages infected with Pr4 and Pr4 Delta 35 at 3 and 6 h postinfection (hpi). While at 3 hpi most (7,564) of the genes had similar expression levels in cells infected with either virus, 38 genes had significantly increased (>2.0-fold, P < 0.05) mRNA levels in Pr4 Delta 35-infected macrophages. Similar up-regulation of these genes was observed at 6 hpi. Viral infection was required for this induced transcriptional response. Most Pr Delta 35 up-regulated genes were part of a type I interferon (IFN) response or were genes that are normally induced by double-stranded RNA and/or viral infection. These included monocyte chemoattractant protein, transmembrane protein 3, tetratricopeptide repeat protein 1, a ubiquitin-like 17-kDa protein, ubiquitin-specific protease ISG43, an RNA helicase DEAD box protein, GTP-binding MX protein, the cytokine IP-10, and the PKR activator PACT. Differential expression of IFN early-response genes in Pr4 Delta 35 relative to Pr4 was confirmed by Northern blot analysis and real-time PCR. Analysis of IFN-alpha mRNA and secreted IFN-alpha levels at 3, 8, and 24 hpi revealed undetectable IFN-alpha in mock- and Pr4-infected macrophages but significant IFN-alpha levels at 24 hpi in Pr4 Delta 35-infected macrophages. The absence of IFN-alpha in Pr4-infected macrophages suggests that MGF360/530 genes either directly or indirectly suppress a type I IFN response. An inability to suppress host type I IFN responses may account for the growth defect of Pr4 Delta 35 in macrophages and its attenuation in swine.
非洲猪瘟病毒(ASFV)多基因家族360和530(MGF360/530)基因影响病毒在巨噬细胞培养物中的生长以及猪的毒力(L. Zsak、Z. Lu、T. G. Burrage、J. G. Neilan、G. F. Kutish、D. M. Moore和D. L. Rock,《病毒学杂志》75:3066 - 3076,2001年)。这些新基因影响病毒 - 宿主相互作用的机制尚不清楚。为了确定MGF360/530基因的功能,我们比较了用亲本ASFV(Pr4)和MGF360/530缺失突变体(Pr4 Delta 35)感染后巨噬细胞的转录反应。使用包含7712个巨噬细胞cDNA克隆的猪cDNA微阵列来比较在感染后3小时和6小时(hpi)感染Pr4和Pr4 Delta 35的猪巨噬细胞的转录谱。虽然在3 hpi时,大多数(7564个)基因在感染任何一种病毒的细胞中具有相似水平的表达,但有38个基因在Pr4 Delta 35感染的巨噬细胞中mRNA水平显著增加(>2.0倍,P < 0.05)。在6 hpi时观察到这些基因有类似的上调。这种诱导的转录反应需要病毒感染。大多数Pr Delta 35上调的基因是I型干扰素(IFN)反应的一部分,或者是通常由双链RNA和/或病毒感染诱导的基因。这些基因包括单核细胞趋化蛋白、跨膜蛋白3、四肽重复蛋白1、一种类泛素17 kDa蛋白、泛素特异性蛋白酶ISG43、一种RNA解旋酶DEAD盒蛋白、GTP结合MX蛋白、细胞因子IP - 10以及PKR激活剂PACT。通过Northern印迹分析和实时PCR证实了Pr4 Delta 35相对于Pr4中IFN早期反应基因的差异表达。在3、8和24 hpi时对IFN - α mRNA和分泌的IFN - α水平的分析显示,在模拟感染和Pr4感染的巨噬细胞中未检测到IFN - α,但在Pr4 Delta 35感染的巨噬细胞中在24 hpi时有显著的IFN - α水平。Pr4感染的巨噬细胞中缺乏IFN - α表明MGF360/530基因直接或间接抑制I型IFN反应。无法抑制宿主I型IFN反应可能解释了Pr4 Delta 35在巨噬细胞中的生长缺陷及其在猪中的减毒。
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