鸭源H8N4亚型禽流感病毒的遗传演化及其部分生物学特性分析

doi:10.3864/j.issn.0578-1752.2026.07.015

摘要/Abstract

摘要：

【目的】通过对新分离的H8N4亚型禽流感病毒（avian influenza virus，AIV）的生物学特性分析，为禽流感疫情监测和综合防控提供依据。【方法】对2株分离自湖南省养鸭场的H8N4亚型禽流感病毒DK/HuN/S11158/2024（简称DK/S11158）和DK/HuN/S11301/2025（简称DK/S11301）株进行全基因组序列测定，并从GISAID数据库中下载与各片段同源性最高的参考毒株序列，利用MEGA7.0软件构建分离病毒株及参考毒株各基因片段的进化树，同时分析2株H8N4亚型AIV不同编码蛋白的关键氨基酸位点的变异。通过生物膜干涉技术评估病毒的受体结合特性差异，然后以10⁶EID₅₀的病毒剂量分别感染SPF鸡和BALB/c小鼠，评估2株H8N4亚型病毒对家禽及哺乳动物的感染及致病能力。【结果】BLAST比对结果显示DK/S11158株的PB1、PA和NA基因片段与韩国水禽来源的AIV相应基因片段具有核苷酸同源性最高，PB2、HA和NS基因片段与日本野鸟来源的AIV相应基因片段具有核苷酸同源性最高，M基因片段与伊朗鸭源AIV相应基因片段具有核苷酸同源性最高，NP基因片段则与我国野鸟来源的AIV核苷酸同源性最高。DK/S11301株的PB2、PB1、PA、NP、NS基因片段与日本野鸟及水禽来源的AIV相应基因片段具有核苷酸同源性最高，HA和NA基因片段与北美水禽来源的AIV相应基因片段具有核苷酸同源性最高，M基因片段与韩国野鸟来源的AIV具有核苷酸同源性最高。2株H8N4亚型AIV的HA蛋白裂解位点氨基酸序列均为PSIEPK↓GLF，仅含有1个碱性氨基酸，符合低致病性禽流感病毒（LPAIV）的分子特征；PB2蛋白出现89V、358E、389R，PB1蛋白出现3V、622G，PA蛋白出现37A、409S，NS1蛋白出现42S、106M等多个哺乳动物适应性突变位点。利用生物膜干涉技术评估病毒受体结合特性差异，结果显示2株病毒均可结合α-2,3-唾液酸和α-2,6-唾液酸受体，表现出双受体结合能力。病毒对鸡的感染性试验结果表明，DK/S11158和DK/S11301的感染组鸡的各个脏器及咽喉拭子和泄殖腔拭子中均未检测到病毒存在，接触传播组鸡的咽喉拭子和泄殖腔拭子中也未检测到病毒。14 d后对感染组和传播组鸡血清进行抗体水平检测，仅DK/S11158感染组的1只鸡出现血清抗体转阳。将2株病毒以10⁶EID₅₀/50μL剂量滴鼻感染BALB/c小鼠后，DK/S11158组小鼠鼻甲和肺脏病毒滴度分别为5.58 log₁₀EID₅₀/mL和2.75 log₁₀EID₅₀/mL；DK/S11301组小鼠鼻甲和肺脏的病毒滴度分别为6.25 log₁₀EID₅₀/mL和4.08 log₁₀EID₅₀/mL，并伴随一定程度的体重下降。【结论】2株H8N4亚型AIV为新型重组病毒，具有明显的遗传多样性，存在感染哺乳动物和人类的潜在风险，研究为禽流感的监测和综合防控提供了重要的数据支持。

关键词: 禽流感病毒, H8N4, 感染性, 受体结合特异性, 遗传进化

Abstract:

【Objective】This study aimed to analyze the biological characteristics of the newly isolated H8N4 subtype avian influenza virus (AIV), so as to provide the basis for avian influenza surveillance and comprehensive prevention and control.【Method】The whole-genome sequencing of two strains of H8N4 subtype avian influenza virus DK/HuN/S11158/2024 (DK/S11158) and DK/HuN/S11301/2025 (DK/S11301) isolated from duck farms in Hunan Province were determined. Reference strain sequences with the highest homology to each segment were downloaded from the GISAID database. The phylogenetic trees for each gene segment of the isolated strains and reference strains were constructed using MEGA 7.0 software. The key amino acid residue variations in different encoded proteins of the two H8N4 subtype AIVs were analyzed. The differences in viral receptor-binding characteristics were assessed using bio-layer interferometry. SPF chickens and BALB/c mice were infected with a virus dose of 10⁶ EID₅₀ to evaluate the infection and pathogenicity of the two H8N4 subtype viruses in poultry and mammals.【Result】BLAST comparison results showed that for the DK/S11158 strain, the PB1, PA, and NA gene segments had the highest nucleotide homology with corresponding segments from AIVs of South Korean waterfowl origin; the PB2, HA, and NS gene segments had the highest homology with those from Japanese wild bird-origin AIVs; the M gene segment had the highest homology with a duck-origin AIV from Iran; the NP gene segment had the highest homology with a wild bird-origin AIV from China. For the DK/S11301 strain, the PB2, PB1, PA, NP, and NS gene segments showed the highest nucleotide homology with corresponding segments from Japanese wild bird and waterfowl-origin AIVs; the HA and NA gene segments had the highest homology with those from North American waterfowl-origin AIVs; the M gene segment had the highest homology with a South Korean wild bird-origin AIV. The amino acid sequence at the HA protein cleavage site of both H8N4 subtype AIVs was PSIEPK↓GLF, containing only a single basic amino acid, which was consistent with the molecular characteristics of low pathogenic avian influenza virus (LPAIV). Several mammalian adaptation mutation sites were identified, including 89V, 358E, 389R in the PB2 protein, 3V, 622G in the PB1 protein, 37A, 409S in the PA protein, and 42S, 106M in the NS1 protein. Assessment of viral receptor-binding characteristics using bio-layer interferometry revealed that both viruses could bind to both α-2,3-sialic acid and α-2,6-sialic acid receptors, demonstrating dual receptor-binding capability. Results from the infectivity experiment in chickens showed that no virus was detected in any organs, oropharyngeal swabs, or cloacal swabs of chickens in the DK/S11158 and DK/S11301 infection groups. No virus was detected in the oropharyngeal or cloacal swabs of chickens in the contact transmission groups either. Serological antibody level testing 14 days post-infection showed seroconversion in only one chicken from the DK/S11158 infection group. After intranasal infection of BALB/c mice with 10⁶ EID₅₀/50μL of virus, the viral titer in the nasal turbinates and lungs of the DK/S11158 group were 5.58 log₁₀EID₅₀/mL and 2.75 log₁₀EID₅₀/mL, respectively. The viral titers in the nasal turbinates and lungs of the DK/S11301 group were 6.25 log₁₀EID₅₀/mL and 4.08 log₁₀EID₅₀/mL, respectively, accompanied by a certain degree of weight loss.【Conclusion】The above results indicate that the two H8N4 subtype AIVs were novel recombinant viruses with significant genetic diversity and posed a potential risk of infecting mammals and humans. This study provided important data support for the surveillance and comprehensive prevention and control of avian influenza.

Key words: avian influenza virus, H8N4, infectivity, receptor-binding specificity, genetic evolution

缪葭皓, 崔鹏飞, 颜成, 王丛丛, 王燕, 陈源, 陈鹏, 施建忠, 邓国华, 陈化兰. 鸭源H8N4亚型禽流感病毒的遗传演化及其部分生物学特性分析[J]. 中国农业科学, 2026, 59(7): 1576-1586.

MIAO JiaHao, CUI PengFei, YAN Cheng, WANG CongCong, WANG Yan, CHEN Yuan, CHEN Peng, SHI JianZhong, DENG GuoHua, CHEN HuaLan. Genetic and Biological Characterization of Two H8N4 Subtype Avian Influenza Viruses Isolated from Duck[J]. Scientia Agricultura Sinica, 2026, 59(7): 1576-1586.

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病毒 Virus	基因 Gene	与GISAID数据库中同源性最高的病毒 The highest homologous strains in the GISAID database	同源性 Identity	登录号 Segment-ID
DK/HuN/S11158/ 2024(H8N4)	PB2	A/environment/Japan/KU-4h/2021(H3N8)	99.4%	EPI2596070
	PB1	A/Spot-billed duck/South Korea/KNU2022-73/2022(H4N6)	99.3%	EPI19109827
	PA	A/duck/Korea/H678/2022(H5N1)	99.4%	EPI19453475
	HA	A/bird/Japan/NIES-0000009/2022(H8N4)	98.4%	EPI2628718
	NP	A/wild bird/Guangdong/ZJ476/2022(H4N6)	98.9%	EPI4313854
	NA	A/mallard/Korea/KNU-8/2023(H10N4)	99.3%	EPI2873264
	M	A/duck/Ilan/15WB3315-46-50/2015 (H6N1)	99.0%	EPI3407222
	NS	A/environment/Kagoshima/KU-24-G12/2024(H4N6)	99.4%	EPI4323141
DK/HuN/S11301/ 2025(H8N4)	PB2	A/Eastern buzzard/Fukushima/0703A001/2025(H5N1)	99.1%	EPI4264867
	PB1	A/chicken/Niigata/22A10C/2022(H5N1)	99.2%	EPI2751889
	PA	A/Hooded crane/Kagoshima/KU-24-24/2024(H5N1)	99.5%	EPI3872674
	HA	A/mallard/Alaska/AH0176804/2021(H8N4)	97.3%	EPI1933012
	NP	A/environment/Kagoshima/KU-G5/2022(H5N1)	99.1%	EPI2789439
	NA	A/Mallard/Ohio/19OS0172/2019(H10N4)	97.5%	EPI1778889
	M	A/A/Wild bird/South Korea/Q23-324-4/2023(H3N8)	99.8%	EPI3040266
	NS	A/goose/Tottori/NK2F2/2022(H1N8)	99.2%	EPI3327150

病毒名称 Virus name	病毒感染SPF鸡复制情况（阳性数/总数） Replication of viral infection in SPF chickens (positive number/total number)
病毒名称 Virus name	脑 Brain	气管 Trachea	胸腺 Thymus	肺脏 Lung	肾脏 Kidney	脾脏 Spleen	胰腺 Pancreas	心脏 Heart	肝脏 Liver	法氏囊 Bursa of Fabricius	盲肠 Cecum
DK/S11158	0/3	0/3	0/3	0/3	0/3	0/3	0/3	0/3	0/3	0/3	0/3
DK/S11301	0/3	0/3	0/3	0/3	0/3	0/3	0/3	0/3	0/3	0/3	0/3

病毒名称 Virus name	感染组 Inoculated group									接触组 Contact group
	咽喉拭子（阳性数/总数） Oropharyngeal swab (positive number/total number)				泄殖腔拭子（阳性数/总数） Cloacal swab (positive number/total number)				血清转阳 Seroconversion	咽喉拭子（阳性数/总数） Oropharyngeal swab (positive number/total number)				泄殖腔拭子（阳性数/总数） Cloacal swab (positive number/total number)				血清转阳 Seroconversion
	3d	5d	7d	9d	3d	5d	7d	9d		3d	5d	7d	9d	3d	5d	7d	9d	血清转阳 Seroconversion
DK/S11158	0/8	0/8	0/8	0/8	0/8	0/8	0/8	0/8	1/8	0/2	0/2	0/2	0/2	0/2	0/2	0/2	0/2	0/2
DK/S11301	0/8	0/8	0/8	0/8	0/8	0/8	0/8	0/8	0/8	0/2	0/2	0/2	0/2	0/2	0/2	0/2	0/2	0/2