Experimental infection of chickens, ducks and quails with the highly pathogenic H5N1 avian influenza virus

Highly pathogenic avian influenza viruses (HPAIV) of the H5N1 subtype have spread since 2003 in poultry and wild birds in Asia, Europe and Africa. In Korea, the highly pathogenic H5N1 avian influenza outbreaks took place in 2003/2004, 2006/2007 and 2008. As the 2006/2007 isolates differ phylogenetically from the 2003/2004 isolates, we assessed the clinical responses of chickens, ducks and quails to intranasal inoculation of the 2006/2007 index case virus, A/chicken/Korea/IS/06. All the chickens and quails died on 3 days and 3-6 days post-inoculation (DPI), respectively, whilst the ducks only showed signs of mild depression. The uninoculated chickens and quails placed soon after with the inoculated flock died on 5.3 and 7.5 DPI, respectively. Both oropharyngeal and cloacal swabs were taken for all three species during various time intervals after inoculation. It was found that oropharyngeal swabs showed higher viral titers than in cloacal swabs applicable to all three avian species. The chickens and quails shed the virus until they died (up to 3 to 6 days after inoculation, respectively) whilst the ducks shed the virus on 2-4 DPI. The postmortem tissues collected from the chickens and quails on day 3 and days 4-5 and from clinically normal ducks that were euthanized on day 4 contained the virus. However, the ducks had significantly lower viral titers than the chickens or quails. Thus, the three avian species varied significantly in their clinical signs, mortality, tissue virus titers, and duration of virus shedding. Our observations suggest that duck and quail farms should be monitored particularly closely for the presence of HPAIV so that further virus transmission to other avian or mammalian hosts can be prevented.     

Highly pathogenic avian influenza virus subtype H5N1 in ducks in the Northern part of Cameroon

Highly pathogenic avian influenza (HPAI) virus was first detected in Cameroon in February 2006. Analysis of NA sequences of the virus demonstrated that it is closely related to the H5N1 isolates from Northern Nigeria, Sudan and Ivory Coast, suggesting a common virus ancestor.     

禽流感病毒H5N1变异株灭活疫苗(Re-4株)对鸡、鸭和鹅的免疫效果研究

为系统评估禽流感病毒(AIV)H5N1变异株灭活疫苗(Re-4株)对家禽的免疫效果,本研究将Re-4株油乳剂灭活疫苗免疫SPF鸡和商品蛋鸡、商品鸭及商品鹅。免疫后每周采集血清测定HI抗体,绘制抗体消长曲线,免疫SPF鸡在免疫后2周、3周和50周时以105EID50剂量的强毒株(CK/SX/2/06)进行攻毒。研究结果显示,该疫苗对蛋鸡、鸭、鹅均具有良好的免疫效果,而且SPF免疫鸡血清HI抗体在4log2以上时能够完全抵抗CK/SX/2/06强毒的攻击。因此,根据实验结果推荐该油乳剂灭活疫苗的对上述禽类的免疫程序:商品蛋鸡10日龄颈部皮下注射0.3mL,60日龄和110日龄(开产前)时依次胸肌注射0.5mL和1.0mL进行免疫;商品鸭、鹅在2周龄均以0.5mL首免,5周龄和4月龄左右时以1mL的剂量肌肉注射方式进行加强免疫。     

Assessing the risk of highly pathogenic avian influenza H5N1 transmission through poultry movements in Bali,Indonesia

Indonesia continues to report the highest number of human and poultry cases of highly pathogenic avian influenza H5N1. The disease is considered to be endemic on the island of Bali. Live bird markets are integral in the poultry supply chain on Bali and are important, nutritionally and culturally, for the rural and urban human populations. Due to the lack of biosecurity practiced along the supply chain from producer to live bird markets, there is a need to understand the risks associated with the spread of H5N1 through live bird movements for effective control. Resources to control H5N1 in Indonesia are very limited and cost effective strategies are needed. We assessed the probability a live bird market is infected through live poultry movements and assessed the effects of implementing two simple and low cost control measures on this risk. Results suggest there is a high risk a live bird market is infected (0.78), and risk mitigation strategies such as detecting and removing infected poultry from markets reduce this risk somewhat (range 0.67–0.76). The study demonstrates the key role live poultry movements play in transmitting H5N1 and the need to implement a variety of control measures to reduce disease spread.     

全球高致病性禽流感风险评估

H5N1高致病性禽流感暴发的风险管理需要对不同的风险因素进行综合评估,这些因素影响不同地理区域传染病的传播和持续时间。禽流感灾害风险评估的关键是制定风险路径,然后用它来发展一种定性或定量的风险评估模型。本文建立在风险分析模型框架基础之上,利用FAO、WHO以及OIE等国际组织和有关国家政府可公开获得的数据和信息,利用ArcGIS对H5N1高致病性禽流感进行风险评估,并对野生鸟类和家禽贸易在H5N1高致病性禽流感传播中的重要性进行分析。     

The indirect immunofluorescence assay using cardiac tissue from chickens, quails and ducks for identification of influenza A virus during an outbreak of highly pathogenic avian influenza virus (H5N1): a rapid and simple screening tool for limited resource settings

Here we describe the diagnostic utility of the indirect immunofluorescence assay (IFA) during a recent outbreak of highly pathogenic avian influenza (HPAI) subtype H5N1 virus in southern Thailand and demonstrate the usefulness of the cardiac tissue from infected chickens, quail, and ducks for diagnosis. The most reliable sample for IFA diagnosis of influenza A virus was cardiac tissue (83.0%; 44/53) which when divided by species (chicken, quail and duck cardiac tissues) gave respective positivity rates of 88% (22/25), 88.9% (16/18) and 60.0% (6/10). Cardiac tissue also gave the highest IFA intensity for the three species. We believe that the IFA method has wide applicability in developing countries or remote settings where clinically similar avian diseases with high morbidity and mortality such as Newcastle disease and fowl cholera are common and could be rapidly excluded thereby conserving valuable reference laboratory capacity for true HPAI outbreaks.     

H5N1亚型禽流感变异株灭活疫苗种毒Re-4株的生物学特性及免疫原性研究

本实验对经反向遗传方法构建的重组禽流感H5N1亚型变异株灭活疫苗种毒Re-4株的生物学特性及免疫效力进行研究.将Re-4株接种SPF鸡胚后37℃培养72 h,鸡胚存活,无病变,HA滴度达29;以0.1 mL(106.0EID50/0.1 mE)的剂量鼻腔感染4周龄SPF鸡7 d后血清HI抗体转阳,无任何症状,也不排毒;SPF鸡静脉致病指数(IVPI)为0;以Re-4重组株为种毒制备灭活疫苗,免疫SPF鸡后,3周后平均HI抗体效价达8.75 log2:免疫鸡对亲本强毒株CKSX/06,以及变异株CKNX/06和流行株GSGD/96攻击提供完全保护.以上结果表明变异株灭活疫苗种毒Re-4株对SPF鸡胚和SPF鸡无致病性、适合鸡胚增殖、抗原针对性强,并且以该毒株制备的灭活疫苗具有良好的免疫效力,是研制预防H5N1亚型禽流感病毒山西变异株的理想疫苗种毒株.     

Molecular and phylogenetic analysis of the H5N1 avian influenza virus caused the first highly pathogenic avian influenza outbreak in poultry in the Czech Republic in 2007

On 19th July 2007 re-occurrence of the H5N1 highly pathogenic avian influenza (HPAI) virus was noticed in Europe. The index strain of this novel H5N1 lineage was identified in the Czech Republic where it caused historically the first HPAI outbreak in commercial poultry. In the present study we performed molecular and phylogenetic analysis of the index strain of the re-emerging H5N1 virus lineage along with the Czech and the Slovak H5N1 strains collected in 2006 and established the evolutionary relationships to additional viruses circulated in Europe in 2005-2006. Our analysis revealed that the Czech and the Slovak H5N1 viruses collected during 2006 were separated into two sub-clades 2.2.1 and 2.2.2, which predominated in Europe during 2005-2006. On the contrary the newly emerged H5N1 viruses belonged to a clearly distinguishable sub-clade 2.2.3. Within the sub-clade 2.2.3 the Czech H5N1 strains showed the closest relationships to the simultaneously circulated viruses from Germany, Romania and Russia (Krasnodar) in 2007 and were further clustered with the viruses from Afghanistan and Mongolia circulated in 2006. The origin of the Czech 2007 H5N1 HPAI strains was also discussed.     

H5N1亚型禽流感病毒对鸭的致病性研究

为评估H5N1亚型禽流感病毒(AIV)在实验室环境下对鸭的致病力,本研究以无特殊病原(SPF)鸭为模型,对我国近年分离的7株病毒进行了致病力分析。结果发现其中4株病毒对鸭致死率为100%,2株病毒对鸭的致死率分别为60%和80%,另外1株病毒,A/goose/Hubei/51/05(GS/HB/51/05),对鸭无致病力。本研究还发现,与高致病力毒株一样,GS/HB/51/05也可在鸭体内呈全身性复制,并且可通过喉头和泻殖腔向外排泄。我们推测GS/HB/51/05可能是中国南方出现的其他对鸭呈高致病力的H5N1病毒的祖先,对这些病毒的系统研究,可揭示H5N1亚型AIV对鸭的致病力遗传机制。     

Novel reassortant H5N6 highly pathogenic influenza A viruses in Vietnamese quail outbreaks

Avian influenza A H5N6 virus is a highly contagious infectious agent that affects domestic poultry and humans in South Asian countries. Vietnam may be an evolutionary hotspot for influenza viruses and therefore could serve as a source of pandemic strains. In 2015, two novel reassortant H5N6 influenza viruses designated as A/quail/Vietnam/CVVI01/2015 and A/quail/Vietnam/CVVI03/2015 were isolated from dead quails during avian influenza outbreaks in central Vietnam, and the whole genome sequences were analyzed. The genetic analysis indicated that hemagglutinin, neuraminidase, and polymerase basic protein 2 genes of the two H5N6 viruses are most closely related to an H5N2 virus (A/chicken/Zhejiang/727079/2014) and H10N6 virus (A/chicken/Jiangxi/12782/2014) from China and an H6N6 virus (A/duck/Yamagata/061004/2014) from Japan. The HA gene of the isolates belongs to clade 2.3.4.4, which caused human fatalities in China during 2014–2016. The five other internal genes showed high identity to an H5N2 virus (A/chicken/Heilongjiang/S7/2014) from China. A whole-genome phylogenetic analysis revealed that these two outbreak strains are novel H6N6-like PB2 gene reassortants that are most closely related to influenza virus strain A/environment/Guangdong/ZS558/2015, which was detected in a live poultry market in China. This report describes the first detection of novel H5N6 reassortants in poultry during an outbreak as well as genetic characterization of these strains to better understand the antigenic evolution of influenza viruses.     

新型H5N1亚型禽流感灭活疫苗对鸭、鹅及鸽免疫原性研究

本研究就反基因操作分子修饰致弱种毒株制备新型H5N1亚型禽流感灭活疫苗对鸭、鹅和鸽子的免疫原性进行了系统评估.结果表明该疫苗对水禽及鸽子具有良好免疫原性.根据实验结果,初步推荐该禽流感灭活疫苗对上述禽类的免疫程序,即鸭:2周龄0.5mL皮下注射,3月龄1.0mL肌肉注射二免,9月龄1.0mL肌肉注射三免;鹅:10日龄0.5 mL皮下注射,3～4周龄1.5 mL肌肉注射加强免疫,4月龄1.5 mL进行第3次免疫;鸽子:2周龄以0.3 mL首免,4周龄以0.5 mL加强免疫,6月龄以0.5 mL第3次免疫.     

Pathogenicity and transmission of H5N1 avian influenza viruses in different birds

In this study, we selected three H5N1 highly pathogenic avian influenza viruses (HPAIVs), A/Goose/Guangdong/1/1996 (clades 0), A/Duck/Guangdong/E35/2012 (clade 2.3.2.1) and A/Chicken/Henan/B30/2012 (clade 7.2) isolated from different birds in China, to investigate the pathogenicity and transmission of the viruses in terrestrial birds and waterfowl. To observe the replication and shedding of the H5N1 HPAIVs in birds, the chickens were inoculated intranasally with 10⁶ EID₅₀ of GSGD/1/96, 10³ EID₅₀ of DkE35 and CkB30, and the ducks and geese were inoculated intranasally with 10⁶ EID₅₀ of each virus. Meanwhile, the naive contact groups were set up to detect the transmission of the viruses in tested birds. Our results showed that DkE35 was highly pathogenic to chickens and geese, but not fatal to ducks. It could be detected from all the tested organs, oropharyngeal and cloacal swabs, and could transmit to the naive contact birds. GSGD/1/96 could infect chickens, ducks and geese, but only caused death in chickens. It could transmit to the chickens and ducks, but was not transmittable to geese. CkB30 was highly pathogenic to chickens, low pathogenic to ducks and not pathogenic to geese. It could be transmitted to the naive contact chickens, but not to the ducks or geese. Our findings suggested that H5N1 HPAIVs from different birds show different host ranges and tissue tropisms. Therefore, we should enhance serological and virological surveillance of H5N1 HPAIVs, and pay more attention to the pathogenic and antigenic evolution of these viruses.     

Infectious dose‐dependent accumulation of live highly pathogenic avian influenza H5N1 virus in chicken skeletal muscle—implications for public health

Highly pathogenic avian influenza viruses (HPAIV) of H5N1 subtype are a major global threat to poultry and public health. Export of poultry products, such as chicken and duck meat, is a known source for the cross‐boundary spread of HPAI H5N1 viruses. Humans get infected with HPAI H5N1 viruses either by close contact with infected poultry or through consumption of fresh/undercooked poultry meat. Skeletal muscle is the largest soft tissue in chicken that has been shown to contain virus during systemic HPAIV infection and supports productive virus infection. However, the time between infection of a chicken with H5N1 virus and presence of virus in muscle tissue is not yet known. Further, it is also not clear whether chicken infected with low doses of H5N1 virus that cause non‐fatal subclinical infections continue to accumulate virus in skeletal muscle. We investigated the amount and duration of virus detection in skeletal muscle of chicken experimentally infected with different doses (10², 10³ and 10⁴ EID₅₀) of a HPAI H5N1 virus. Influenza viral antigen could be detected as early as 6 hr after infection and live virus was recovered from 48 hr after infection. Notably, chicken infected with lower levels of HPAI H5N1 virus (i.e., 10² EID₅₀) did not die acutely, but continued to accumulate high levels of H5N1 virus in skeletal muscle until 6 days post‐infection. Our data suggest that there is a potential risk of human exposure to H5N1 virus through meat from clinically healthy chicken infected with a low dose of virus. Our results highlight the need to implement rigorous monitoring systems to screen poultry meat from H5N1 endemic countries to limit the global spread of H5N1 viruses.     

Evolution of highly pathogenic H7N3 avian influenza viruses in Mexico

Highly pathogenic H7N3 influenza A viruses have persisted in poultry in Mexico since 2012, diversifying into multiple lineages that have spread to three Mexican states, as of 2016. The H7N3 viruses segregate into three distinct clades that are geographically structured. All 2016 viruses are resistant to adamantane antiviral drugs and have an extended 24‐nucleotide insertion at the HA cleavage site that was acquired from host 28S ribosomal RNA.     

The first specific detection of a highly pathogenic avian influenza virus (H5N1) in Ivory Coast

The Virology Laboratory of the Central Laboratory of Animal Diseases in Ivory Coast at Bingerville received samples of wild and domestic avian species between February and December 2006. An RT-PCR technique was used to test for avian influenza (AI) and highly pathogenic AI subtype viruses. Among 2125 samples, 16 were type A positive; of which, 12 were later confirmed to be H5N1. Fifteen of these 16 type A positive samples were inoculated into the chorioallantoic cavity of 11-day-old embryonated hens' eggs for virus isolation. Eight produced virus with hemagglutination titres from 1/64 to 1/512. The 4/16 M-RT-PCR positive samples, which were H5N1 negative, were shown to be H7 subtype negative. The diagnostic efficiency of the laboratory for the surveillance of H5N1 in Ivory Coast was demonstrated. The positive cases of H5N1 were from a sparrowhawk (Accipter nisus); live market poultry and in free-range poultry, where the mortality rate was approximately 20% (2/10) and 96.7% (29/30) respectively. Currently, investigations into intensive poultry farms have proved negative for H5N1. No human cases have been reported this time.     

The spread of highly pathogenic avian influenza (subtype H5N1) clades in Bangladesh, 2010 and 2011

Since the global spread of highly pathogenic avian influenza H5N1 during 2005–2006, control programs have been successfully implemented in most affected countries. HPAI H5N1 was first reported in Bangladesh in 2007, and since then 546 outbreaks have been reported to the OIE. The disease has apparently become endemic in Bangladesh. Spatio-temporal information on 177 outbreaks of HPAI H5N1 occurring between February 2010 and April 2011 in Bangladesh, and 37 of these outbreaks in which isolated H5N1 viruses were phylogenetically characterized to clade, were analyzed.     

Association between outbreaks of highly pathogenic avian influenza subtype H5N1 and migratory waterfowl (family Anatidae) populations

Highly pathogenic avian influenza (HPAI) virus subtype H5N1 threatens poultry production and human health. Understanding the role that migratory waterfowl play in introducing and maintaining this infection is critical to control the outbreaks. A study was conducted to determine if the occurrence of HPAI subtype H5N1 outbreaks in village poultry in Romania, 2005-2006, was associated with proximity to populations of migratory waterfowl. Reported outbreaks--which could be grouped into three epidemic phases--and migratory waterfowl sites were mapped. The migratory waterfowl site closest to each outbreak was identified. The distances between outbreaks occurring in phase 1 and 2 of the epidemic and the closest migratory waterfowl site were significantly (P<0.001) less than in phase 3, but these distances were only useful in predicting when outbreaks occurred during phase 1 (October-December, 2005) of the epidemic. A spatial lag (rho=0.408, P=0.041) model best fit the data, using distance and [distance]*[distance] as predictors (R2=0.425). The correlation between when outbreaks were predicted to occur and when they were observed to occur was 0.55 (P=0.006). Results support the hypothesis that HPAI virus subtype H5N1 infections of village poultry in Romania during the autumn of 2005 might have occurred via exposure to migratory populations of waterfowl.     

重组H5N1亚型禽流感疫苗免疫孔雀后的抗体消长规律及免疫程序的研究

为了探讨孔雀对H5高致病性禽流感灭活疫苗的免疫原性,做好孔雀禽流感的防控,采用哈尔滨兽医研究所研制的重组H5N1亚型高致病性禽流感疫苗,不同剂量免疫孔雀后,跟踪其抗体消长规律。检测结果显示:小孔雀母源抗体能维持约6周;首免0.5 mL/羽颈部皮下注射,有效抗体能维持18周以上;1.0,1.5,2.0 mL/羽3个剂量组肌肉注射进行二免,以1.5 mL/羽组效果最好,有效抗体能维持10个月左右;成年孔雀1.5 mL/羽进行三免,有效抗体能维持1年以上。而且孔雀产生的抗体均一性良好,抗体阳性率均在75%以上。根据抗体消长规律,推荐了孔雀的免疫程序。     

Isolation and characterization of influenza A virus (subtype H5N1) that caused the first highly pathogenic avian influenza outbreak in chicken in Bhutan

We characterized Influenza A/H5N1 virus that caused the first outbreak of highly pathogenic avian influenza (HPAI) in chickens in Bhutan in 2010. The virus was highly virulent to chicken, killing them within two days of the experimental inoculation with an intravenous pathogenicity index (IVPI) of 2.88. For genetic and phylogenetic analyses, complete genome sequencing of 4 viral isolates was carried out. The isolates revealed multiple basic amino acids at their hemagglutinin (HA) cleavage site, similar to other "Qinghai-like" H5N1 isolates. The receptor-binding site of HA molecule contained avian-like amino acids ((222)Q and (224)G). The isolates also contained amino acid residue K at position 627 of the PB2 protein, and other markers in NS 1 and PB1 proteins, highlighting the risk to mammals. However, the isolates were sensitive to influenza drugs presently available in the market. The sequence analysis indicated that the Bhutan viruses shared 99.1-100% nucleotide homology in all the eight genes among themselves and 2010 chicken isolate from Bangladesh (A/chicken/Bangladesh/1151-11/2010) indicating common progenitor virus. The phylogenetic analysis indicated that the Bhutan isolates belonged to sub-clade 2.2.3 (EMA 3) and shared common progenitor virus with the 2010 Bangladesh virus. Based on the evidence of phylogeny and molecular markers, it could be concluded that the outbreaks in Bhutan and Bangladesh in 2010 were due to independent introductions of the virus probably through migratory birds.