Since 2021,clade 2.3.4.4b H5N1 highly pathogenic avian influenza viruses(AIVs)have become the dominant strain responsible for the ongoing panzootics in birds worldwide[1],causing unprecedented deathsofpoultry and wild...Since 2021,clade 2.3.4.4b H5N1 highly pathogenic avian influenza viruses(AIVs)have become the dominant strain responsible for the ongoing panzootics in birds worldwide[1],causing unprecedented deathsofpoultry and wild birds(https://wahis.-woah.org).Moreover,the H5N1 viruses have caused increasing infections in domestic and wild mammals[2].展开更多
Dear Editor,The highly pathogenic avian influenza viruses(HPAIVs)are important epizootic and zoonotic pathogens that cause significant economic losses to the poultry industry and pose a serious risk to veterinary and ...Dear Editor,The highly pathogenic avian influenza viruses(HPAIVs)are important epizootic and zoonotic pathogens that cause significant economic losses to the poultry industry and pose a serious risk to veterinary and public health.Wild birds have been recognized as the primary reservoirs for influenza A virus,and some species show little sign of clinical disease or even can be asymptomatic during long distance carriers of the virus(Lycett et al.,2019).Since it was first discovered in 1959,the H5Nx HPAIVs have spread globally and cause outbreaks in wild birds,poultry and sporadic human and other mammalian infections(Lycett et al.,2019).Due to the reassortant events of diverse strains facilitated by migratory waterfowl,the clade 2.3.4.4 of H5Nx viruses acquiring neuraminidase(NA)gene from other low pathogenicity avian influenza viruses(LPAIVs)emerged in 2014 and gradually became the dominant sub-clade(Lee et al.,2017).展开更多
Influenza,a highly contagious respiratory infectious disease caused by an influenza virus,is a threat to public health worldwide.Avian influenza viruses(AIVs)have the potential to cause the next pandemic by crossing t...Influenza,a highly contagious respiratory infectious disease caused by an influenza virus,is a threat to public health worldwide.Avian influenza viruses(AIVs)have the potential to cause the next pandemic by crossing the species barrier through mutation of viral genome.Here,we investigated the pathogenicity of AIVs obtained from South Korea and Mongolia during 2018–2019 by measuring viral titers in the lungs and extrapulmonary organs of mouse models.In addition,we assessed the pathogenicity of AIVs in ferret models.Moreover,we compared the ability of viruses to replicate in mammalian cells,as well as the receptor-binding preferences of AIV isolates.Genetic analyses were finally performed to identify the genetic relationships and amino acid substitutions between viral proteins during mammalian adaptation.Of the 24 AIV isolates tested,A/Mallard/South Korea/KNU2019-34/2019(KNU19-34;H1N1)caused severe bodyweight loss and high mortality in mice.The virus replicated in the lungs,kidneys,and heart.Importantly,KNU19-34-infected ferrets showed high viral loads in both nasal washes and lungs.KNU19-34 replicated rapidly in A549 and bound preferentially to human likeα2,6-linked sialic acids rather than to avian-likeα2,3-linked sialic acids,similar to the pandemic A/California/04/2009(H1N1)strain.Gene segments of KNU19-34 were distributed in Egypt and Asia lineages from 2015 to 2018,and the virus had several amino acid substitutions compared to H1N1 AIV isolates that were non-pathogenic in mice.Collectively,the data suggest that KNU19-34 has zoonotic potential and the possibility of new mutations responsible for mammalian adaptation.展开更多
In recent years,environmental DNA(e DNA)has garnered significant attention as a novel tool in biodiversity monitoring,recognized for its efficiency,convenience,and non-invasiveness.Despite its extensive application in...In recent years,environmental DNA(e DNA)has garnered significant attention as a novel tool in biodiversity monitoring,recognized for its efficiency,convenience,and non-invasiveness.Despite its extensive application in various ecological studies,such as conservation,invasion biology,biomonitoring and biodiversity survey assessment,its use in avian monitoring remains in its infancy.This review critically examines the potential and limitations of e DNA technology for avian monitoring,focusing on current advancements and ongoing challenges in this emerging field.Water and air are the primary environmental media for collecting avian e DNA,although other sources like spider webs and plant flowers have been explored as well.Notably,airborne e DNA has been reported to capture the highest diversity of avian species.While avian e DNA technology has shown promise for monitoring rare and endangered species and assessing avian diversity,significant challenges remain,particularly in sampling strategies,DNA extraction methodology,primer selection,and ascertain abundance.Additionally,we discussed the factors influencing the production,transportation,and degradation of avian e DNA in the environment.Finally,we suggested future research directions,including optimizing sampling strategies,developing avian-specific universal primers,expanding avian DNA barcode databases,enhancing e DNA detectability,and integrating environmental RNA(e RNA)and e DNA approaches.展开更多
Urbanization is one of the most extreme forms of land-use alteration that is advancing across the world with unprecedented speed.As the largest developing country,China has developed a unique path through its high spe...Urbanization is one of the most extreme forms of land-use alteration that is advancing across the world with unprecedented speed.As the largest developing country,China has developed a unique path through its high speed and large scale of urbanization,offering valuable research opportunities for avian ecology.However,a comprehensive review on how birds respond to urbanization in China is still lacking.Here,we systematically reviewed 274 studies published from 1962 to 2024 to determine the research trends,current insights,and future directions of avian response to urbanization in China.We synthesized research trends across four core avian response dimensions to urbanization—diversity,behavior,physiology,and life-history—and their applications in conservation strategy design.The number of publications in avian response to urbanization in China increased annually,and it is influenced by China's developing policies of urbanization.The results also showed an unbalanced geographical pattern of the publications,as the research preferences are relatively prevalent in the developed areas of eastern China.In contrast,there are insufficient studies in the emerging urbanizing areas in the western and northeastern China.Regarding the research contents,most existing studies are focusing on the patterns of bird diversity,while there are few studies on the underlying mechanisms,such as physiological adjustments and life-history strategies.In addition,passerines are the most frequent ones among the studied species.Integrating multidimensional urbanization indices and citizen science data are gradually becoming a new trend in recent years.Our study emphasizes that future studies should pay more attention to the response mechanism of birds in urbanizing processes,multidimensional and interdisciplinary studies,and the transformation of the research results into conservation practices.展开更多
Avian wings are central to their remarkable flight ability and diverse life history strategies,including behaviors such as fighting and mating.These multifaceted functions are intricately tied to wing shape,which vari...Avian wings are central to their remarkable flight ability and diverse life history strategies,including behaviors such as fighting and mating.These multifaceted functions are intricately tied to wing shape,which varies significantly across species because of the complex interplay of evolutionary and ecological pressures.Many indices have been developed to quantify wing characteristics to facilitate the study and comparison of avian wing morphology across species.This study provides a comprehensive overview of existing quantitative methods for analyzing avian wing shapes.We then constructed a new quantification framework through the beta distribution,which can generate indices reflecting the shape of avian wings(center,dispersion,skewness,and kurtosis).Next,we used the flight feathers of 613 bird species to perform different quantitative analyses and explore the relationships between various wing shape quantification methods and life history traits,which serve as proxies for the selective forces shaping wing morphology.We find that the wing shape indices are more strongly associated with ecological variables than with morphological variables,especially for migration,habitat and territoriality.This research guides the selection of appropriate methods for wing shape analysis,contributing to a deeper understanding of avian morphology and its evolutionary drivers.展开更多
Avian metapneumovirus(aMPV),a paramyxovirus,causes acute respiratory diseases in turkeys and swollen head syndrome in chickens.This study established a reverse genetics system for aMPV subtype B LN16-A strain based on...Avian metapneumovirus(aMPV),a paramyxovirus,causes acute respiratory diseases in turkeys and swollen head syndrome in chickens.This study established a reverse genetics system for aMPV subtype B LN16-A strain based on T7 RNA polymerase.Full-length cDNA of the LN16-A strain was constructed by assembling 5 cDNA fragments between the T7 promoter and hepatitis delta virus ribozyme.Transfection of this plasmid,along with the supporting plasmids encoding the N,P,M2-1,and L proteins of LN16-A into BSR-T7/5 cells,resulted in the recovery of aMPV subtype B.To identify an effective insertion site,the enhanced green fluorescent protein(EGFP)gene was inserted into different sites of the LN16-A genome to generate recombinant LN16-As.The results showed that the expression levels of EGFP at the site between the G and L genes of LN16-A were significantly higher than those at the other two sites(between the leader and N genes or replacing the SH gene).To verify the availability of the site between G and L for foreign gene expression,the VP2 gene of very virulent infectious bursal disease virus(vvIBDV)was inserted into this site,and recombinant LN16-A(rLN16A-vvVP2)was successfully rescued.Single immunization of specificpathogen-free chickens with rLN16A-vvVP2 induced high levels of neutralizing antibodies and provided 100%protection against the virulent aMPV subtype B and vvIBDV.Establishing a reverse genetics system here provides an important foundation for understanding aMPV pathogenesis and developing novel vector vaccines.展开更多
Avian influenza viruses(AIVs)represent an ongoing threat to global health due to their capacity for genetic evolution,zoonotic transmission,and pandemic emergence.This review highlights recent progress in understandin...Avian influenza viruses(AIVs)represent an ongoing threat to global health due to their capacity for genetic evolution,zoonotic transmission,and pandemic emergence.This review highlights recent progress in understanding the molecular mechanisms underlying AIV infection,including viral immune evasion strategies and host-virus interactions.It discusses recent outbreaks involving reassortant strains such as H5N1 and H9N2,and examines their public health co-nsequences.Advancements in antiviral therapy,including resistance patterns,and the development of next-generation vaccines such as messenger RNA and universal influenza vaccines are reviewed.The integration of genomic surveillance,artificial intelligence-driven prediction,and One Health approaches is emphasized as essential for pandemic preparedness.This comprehensive overview aims to provide researchers and policymakers with actionable insights for controlling the evolving threat of avian influenza.展开更多
The H4 subtype of avian influenza virus(AIV)is prevalent worldwide,but only receives little attention due to its low pathogenicity in poultry.Consequently,it remains largely unclear whether H4 AIVs pose a potential th...The H4 subtype of avian influenza virus(AIV)is prevalent worldwide,but only receives little attention due to its low pathogenicity in poultry.Consequently,it remains largely unclear whether H4 AIVs pose a potential threat to the poultry industry and public health.During the period from 2011 to 2022,we conducted an active surveillance programm.A total of 154,762 swab samples were collected across various provinces,and 427 H4 viruses were detected,resulting in a positivity rate of 0.28%.All H4 viruses were isolated from poultry,primarily from ducks in live poultry markets.We further investigated the genetic evolutionary characteristics and pathogenicity of 20 H4Nx viruses isolated in our program.Phylogenetic analysis revealed that the 20 H4Nx viruses belonged to the Eurasian lineage and exhibited significant genetic diversity,with 19 distinct genotypes identified.Molecular characterization indicated that these viruses were low-pathogenicity AIVs with limited binding affinity to human receptors,yet they contained mutations associated with enhanced viral replication and pathogenicity in mammals.Pathogenicity tests conducted in ducks demonstrated that H4 viruses were weakly pathogenic,exhibiting limited replication and transmission capabilities.However,some viruses were able to replicate effectively in mice and induce weight loss.For instance,DK/AH/AG61/11(H4N6)can replicate efficiently in MDCK cells,indicating a potential threat to mammals.These findings underscore the importance of ongoing surveillance of H4 AIVs to better understand their evolution and transmission dynamics and to prevent potential public health risks.展开更多
On January 30,2024,China announced the first human case of H10N5 influenza infection.Prior to this,human cases of H10N7 and H10N8 had been reported.It is now appropriate to re-examine the evolution and future epidemio...On January 30,2024,China announced the first human case of H10N5 influenza infection.Prior to this,human cases of H10N7 and H10N8 had been reported.It is now appropriate to re-examine the evolution and future epidemiological trends of the H10 and N5 subtypes of avian influenza viruses(AIVs).In this study,we analyzed the reassortment characteristics of the first human-derived H10N5 AIV(A/Zhejiang/ZJU01/2023),as well as the evolutionary dynamics of the wild bird-derived H10 and N5 subtypes of AIVs over the past decade.Our findings indicate that the human-derived H10N5 AIV exhibited low pathogenicity.A/bean_goose/Korea/KNU-10/2022(H10N7)and A/mallard/Novosibirsk_region/962k/2018(H12N5)were identified as the potential reassortment parents.The virus has existed since 2022 and several isolations have been reported in Bangladesh.Phylogenetic analysis showed that H10Ny and HxN5 AIVs in China are clustered differently based on the East Asian-Australian(eastern)and Central Asian-Indian(western)migratory flyways.The H10Ny and HxN5 AIV reassortant strains may cause human infections through accidental spillover.It is possible that another center of AIV evolution,mutation,and reassortment may be developing along the migratory flyways in northeastern Asia,distinct from Europe,the Americas,and China's Yangtze River Delta and Pearl River Delta,which should be closely monitored to ensure the safety of the public.展开更多
Dear Editor,Since 2024,the clade 2.3.4.4b highly pathogenic avian influenza(HPAI)H5N1 viruses have been identified in dairy cattle in the United States,raising global concerns about public health(Neumann and Kawaoka,2...Dear Editor,Since 2024,the clade 2.3.4.4b highly pathogenic avian influenza(HPAI)H5N1 viruses have been identified in dairy cattle in the United States,raising global concerns about public health(Neumann and Kawaoka,2024).As of December 18,2024,the U.S.Centers for Disease Control and Prevention(CDC)has reported over 61 confirmed cases of H5N1 infection in humans,predominantly associated with exposure to infected poultry or dairy cattle(U.S.Centers for Disease Control and Prevention,2024).Notably,the circulating 2.3.4.4b H5N1 clade has demonstrated continuous evolution in both wild and domestic birds globally,with expanding mammalian host tropism that now includes swine,cats,red foxes,harbor seals,and skunks(Peacock et al.,2024).These viruses have not only incurred substantial economic impacts but also posed dual threats to human health and ecological stability particularly during co-infections with other viruses(Abolnik,2024;Wang and Wang,2023).展开更多
The circulating avian influenza viruses in wild birds have a high possibility of spillover into domestic birds or mammals at the wild bird–domestic bird or bird–mammal interface. H8N4 viruses primarily circulate in ...The circulating avian influenza viruses in wild birds have a high possibility of spillover into domestic birds or mammals at the wild bird–domestic bird or bird–mammal interface. H8N4 viruses primarily circulate in migratory wild waterfowl and have rarely been identified in domestic birds. In this study, we summarized the spatial and temporal distribution of global H8 viruses, specified their natural reservoirs, and performed detailed evolutionary analysis onthe dominant H8N4 viruses. Here, we also report a novel H8N4 virus isolated from a Eurasian coot sample froma wetland in eastern China in 2022. Animal infection studies indicated that the wild bird-originated H8N4 virus can replicate and transmit efficiently in ducks but has not adapted to chickens. Additionally, this naturally isolated H8N4 virus can replicate in mice without prior adaptation. These results indicate that H8 viruses exist mainly in the wild duck reservoir and pose a high infection risk to domestic ducks. Therefore, the active surveillance of influenza viruses at the wild and domestic waterfowl interface will contribute to monitoring the circulation of these viruses.展开更多
TypeⅠinterferon(IFN)-mediated innate immune responses represent the first line of host defense against viral infection.However,the molecular mechanisms by which avian infuenza virus(AIV)inhibits typeⅠIFN production ...TypeⅠinterferon(IFN)-mediated innate immune responses represent the first line of host defense against viral infection.However,the molecular mechanisms by which avian infuenza virus(AIV)inhibits typeⅠIFN production in ducks are not well understood.Here,we frst found that the polymerase basic 2(PB2)protein of H5N1 subtype AIV inhibited the typeⅠIFN responses by targeting duck mitochondrial antiviral signaling protein(MAVS).We further demonstrated that H5N1-PB2 bound to theΔtransmembrane(ΔTM)domain of duck MAVS,and the polymerase basic 1(PB1)binding domain(PBD)and RNA binding nuclear import domain(RND)of H5N1-PB2 interacted with MAVS to inhibit typeⅠIFN expression in ducks.Collectively,our fndings contribute to understanding the molecular mechanism by which AIV proteins regulate the retinoic acid-inducible geneⅠ(RIG-Ⅰ)-like receptor(RLR)signaling pathway to evade host antiviral immune responses in ducks.展开更多
From March to May, 2004, we selected 8 typical parks or green lands in Shanghai downtown as the study sites to conduct a ornithological research. During this study, total 55 species of birds were recorded, which inclu...From March to May, 2004, we selected 8 typical parks or green lands in Shanghai downtown as the study sites to conduct a ornithological research. During this study, total 55 species of birds were recorded, which included 31 resident and 24 migratory species. With statistics methodology, we analyzed the avian communities with 10 major environmental factors covering the park area, water percentage, vegetation species, canopy cover, shrub cover, grass cover, hill number, location condition, human quantity, path width, the study results indicated that: (1) the following 7 environmental factors were important to impact the structures of the avian community, they were park area, vegetation species, shrub coverage, grass coverage, hill number, location condition of the parks and path width; (2) the avian community of theses urban parks tended to deteriorate in the bird number and diversity; the man-made lake which was currently promoted in the park designing and planning process would not be good to attract the birds.展开更多
Five monoclonal antibodies(Mabs) to nuclear protein of avain influenza virus(AIV) were developed by syncretizing SP 2/0 and the spleen cells from BALB of mice immuized with H9 subtype AIV. Specificity of these Mab...Five monoclonal antibodies(Mabs) to nuclear protein of avain influenza virus(AIV) were developed by syncretizing SP 2/0 and the spleen cells from BALB of mice immuized with H9 subtype AIV. Specificity of these Mabs were identified by immunofluorescent assay(IFA) and enzyme linked immunosorbent assay (ELISA). These five Mabs which were named as AIV-NP-2C3, AIV-NP-6A5, AIV-NP-3 H9, AIV-NP-7B4, AIV-NP-2H4 could react with all viruses of AIV-H9 strains in tests. The result of Western blotting showed that only the 60 ku protein antigen of AIV-H9 could be recognized by the Mabs but never recognized by New castle disease virus, REV and infectious bursa disease virus. The result of preliminary application showed that avian influenza viruses could be deetected bv Mabs in IFA and ELISA. All these Mabs will probably play important roles in preventing and monitoring avian influenza viruses.展开更多
[Objective] The research aimed to design primers that are suitable for detecting H5 and H7 subtypes of avian influenza virus (AIV) ; [Method] DNAStar was used to analyze the homology of the sequences of H5 and H7 su...[Objective] The research aimed to design primers that are suitable for detecting H5 and H7 subtypes of avian influenza virus (AIV) ; [Method] DNAStar was used to analyze the homology of the sequences of H5 and H7 subtypes of AIV accessed in GenBank, and design primers( by Primer Premier 5.0) on high homologous region of these sequences, and then amplified by RT-PCR. [Result] The multiplex RT-PCR amplification, agarose gel electrophoresis and sequencing results showed that the self-designed primers are successful for detecting AIV. [Conclusion] It is feasible to rapidly diagnose AIV through this method.展开更多
[Objective] The study aimed to investigate the genetic variation characters of entire sequences between two H9N2 subtype avian influenza virus strains and other reference strains.[Method] The entire sequences of 8 gen...[Objective] The study aimed to investigate the genetic variation characters of entire sequences between two H9N2 subtype avian influenza virus strains and other reference strains.[Method] The entire sequences of 8 genes were obtained by using RT-PCR,and these sequences were analyzed with that of six H9N2 subtype avian influenza isolates in homology comparison and genetic evolution relation.[Result] The results showed that the nucleotide sequence of entire gene of the strain shared 91.1%-95.4% homology with other seven reference strains,and PG08 shared the highest homology 91.3% with C/BJ/1/94;ZD06 shared the highest homology 92.3% with D/HK/Y280/97.HA cleavage sites of two H9N2 subtype avian influenza virus isolated strains were PARSSR/GLF,typical of mildly pathogenic avian influenza virus.[Conclusion] Phylogenetic tree for entire gene of eight strains showed that the genetic relationship was the closest between ZD06 and C/Pak/2/99 strains,which belonged to the Eurasian lineage;PG08 shared the highest homology 91.3% with ZD06,it may be the product of gene rearrangements of other sub-lines.展开更多
[ Objective] To determine the HA gene sequences of four H9N2 Avian influenza virus (AIV) strains and carry out comparative analysis so as to understand the difference and variation pattern of each strain from the an...[ Objective] To determine the HA gene sequences of four H9N2 Avian influenza virus (AIV) strains and carry out comparative analysis so as to understand the difference and variation pattern of each strain from the angle of molecular biology and to know the distribution and epidemic law of H9N2 AIV. [Method] One pair of primers was designed referring to HA gene sequences of H9N2 AIV. The HA genes of A/Chicken/Hebei/WD/98 (H9N2; WD98 for short), A/Chicken/Hebei/ZD/04 (H9N2; ZD04 for short)), A/Chicken/Beijing/MY/06 (H9N2; MY06 for short) ), and A/Chicken/Beijing/PG/08 (H9N2; PG08 for short)) were amplified, cloned and sequenced. Then the HA gene sequences of these strains were compared with that of 10 H9N2 AIV stains in GenBank. [Result] The ORF of HA genes of the four strains was 1 683 bp in size, encoding 516 amino acids. The HA gene sequences of the four strains, WD98, MY06, PG08, and ZD04, were 82.6% -95.1%, 83.0% -99.0%, 82.7% -95.5%, and 81.3% -95.7% homologous to that of the 10 H9N2 AIV stains, respectively. And the homology of amino acid was respectively 86.6% -96.3%, 86.6% -97.9%, 87.0% -97.1%, and 86.9% -97.3%. [ Conclusion] The HA gene has greatly high homology among different strains.展开更多
Ultrasonic communication in vertebrates is attracting increasing research interest.To determine if ultrasonic vocalization is common in birds,we recorded their vocalizations with ultrasound detectors in the Dongzhai N...Ultrasonic communication in vertebrates is attracting increasing research interest.To determine if ultrasonic vocalization is common in birds,we recorded their vocalizations with ultrasound detectors in the Dongzhai National Nature Reserve of Henan Province,China.We found varying degrees of high frequency components in the vocalizations of 14 species and in several of these species,the frequency of harmonics was up to the range of ultrasound.We suggest that more studies are required to determine whether the high frequency components in avian vocalizations have functions and what these functions are.In addition,the ability of birds to hear sounds in the high frequency range also requires re-examination.展开更多
基金supported by the National Natural Science Foundation (NSFC) Distinguished Young Scholar(32425053)the National KeyR&D Program of China(2023YFC2307500)+1 种基金the NSFC(32370166)the Beijing Research Center for Respiratory Infectious Diseases(BJRID2025-007).
文摘Since 2021,clade 2.3.4.4b H5N1 highly pathogenic avian influenza viruses(AIVs)have become the dominant strain responsible for the ongoing panzootics in birds worldwide[1],causing unprecedented deathsofpoultry and wild birds(https://wahis.-woah.org).Moreover,the H5N1 viruses have caused increasing infections in domestic and wild mammals[2].
基金supported by Zhejiang Province Science and Technology Cooperation Project of“Three Rural and Nine Parties”(grant number 2023SNJF059).
文摘Dear Editor,The highly pathogenic avian influenza viruses(HPAIVs)are important epizootic and zoonotic pathogens that cause significant economic losses to the poultry industry and pose a serious risk to veterinary and public health.Wild birds have been recognized as the primary reservoirs for influenza A virus,and some species show little sign of clinical disease or even can be asymptomatic during long distance carriers of the virus(Lycett et al.,2019).Since it was first discovered in 1959,the H5Nx HPAIVs have spread globally and cause outbreaks in wild birds,poultry and sporadic human and other mammalian infections(Lycett et al.,2019).Due to the reassortant events of diverse strains facilitated by migratory waterfowl,the clade 2.3.4.4 of H5Nx viruses acquiring neuraminidase(NA)gene from other low pathogenicity avian influenza viruses(LPAIVs)emerged in 2014 and gradually became the dominant sub-clade(Lee et al.,2017).
基金funded by grants from the National Research Foundation of Korea(NRF)grant funded by the Korea government(2018M3A9H4055203 and 2023R1A2C2003679)from the Korea Health Technology R&D Project through the Korea Health Industry Development Institute(KHIDI),funded by the Ministry of Health&Welfare,Republic of Korea(HV23C1857)from KRIBB Research Initiative Program(KGM9942421).
文摘Influenza,a highly contagious respiratory infectious disease caused by an influenza virus,is a threat to public health worldwide.Avian influenza viruses(AIVs)have the potential to cause the next pandemic by crossing the species barrier through mutation of viral genome.Here,we investigated the pathogenicity of AIVs obtained from South Korea and Mongolia during 2018–2019 by measuring viral titers in the lungs and extrapulmonary organs of mouse models.In addition,we assessed the pathogenicity of AIVs in ferret models.Moreover,we compared the ability of viruses to replicate in mammalian cells,as well as the receptor-binding preferences of AIV isolates.Genetic analyses were finally performed to identify the genetic relationships and amino acid substitutions between viral proteins during mammalian adaptation.Of the 24 AIV isolates tested,A/Mallard/South Korea/KNU2019-34/2019(KNU19-34;H1N1)caused severe bodyweight loss and high mortality in mice.The virus replicated in the lungs,kidneys,and heart.Importantly,KNU19-34-infected ferrets showed high viral loads in both nasal washes and lungs.KNU19-34 replicated rapidly in A549 and bound preferentially to human likeα2,6-linked sialic acids rather than to avian-likeα2,3-linked sialic acids,similar to the pandemic A/California/04/2009(H1N1)strain.Gene segments of KNU19-34 were distributed in Egypt and Asia lineages from 2015 to 2018,and the virus had several amino acid substitutions compared to H1N1 AIV isolates that were non-pathogenic in mice.Collectively,the data suggest that KNU19-34 has zoonotic potential and the possibility of new mutations responsible for mammalian adaptation.
基金supported by the Key Research and Development Project of Tianjin,China(23YFZCSN00040)。
文摘In recent years,environmental DNA(e DNA)has garnered significant attention as a novel tool in biodiversity monitoring,recognized for its efficiency,convenience,and non-invasiveness.Despite its extensive application in various ecological studies,such as conservation,invasion biology,biomonitoring and biodiversity survey assessment,its use in avian monitoring remains in its infancy.This review critically examines the potential and limitations of e DNA technology for avian monitoring,focusing on current advancements and ongoing challenges in this emerging field.Water and air are the primary environmental media for collecting avian e DNA,although other sources like spider webs and plant flowers have been explored as well.Notably,airborne e DNA has been reported to capture the highest diversity of avian species.While avian e DNA technology has shown promise for monitoring rare and endangered species and assessing avian diversity,significant challenges remain,particularly in sampling strategies,DNA extraction methodology,primer selection,and ascertain abundance.Additionally,we discussed the factors influencing the production,transportation,and degradation of avian e DNA in the environment.Finally,we suggested future research directions,including optimizing sampling strategies,developing avian-specific universal primers,expanding avian DNA barcode databases,enhancing e DNA detectability,and integrating environmental RNA(e RNA)and e DNA approaches.
基金supported by the National Natural Science Foundation of China(No.32271743)。
文摘Urbanization is one of the most extreme forms of land-use alteration that is advancing across the world with unprecedented speed.As the largest developing country,China has developed a unique path through its high speed and large scale of urbanization,offering valuable research opportunities for avian ecology.However,a comprehensive review on how birds respond to urbanization in China is still lacking.Here,we systematically reviewed 274 studies published from 1962 to 2024 to determine the research trends,current insights,and future directions of avian response to urbanization in China.We synthesized research trends across four core avian response dimensions to urbanization—diversity,behavior,physiology,and life-history—and their applications in conservation strategy design.The number of publications in avian response to urbanization in China increased annually,and it is influenced by China's developing policies of urbanization.The results also showed an unbalanced geographical pattern of the publications,as the research preferences are relatively prevalent in the developed areas of eastern China.In contrast,there are insufficient studies in the emerging urbanizing areas in the western and northeastern China.Regarding the research contents,most existing studies are focusing on the patterns of bird diversity,while there are few studies on the underlying mechanisms,such as physiological adjustments and life-history strategies.In addition,passerines are the most frequent ones among the studied species.Integrating multidimensional urbanization indices and citizen science data are gradually becoming a new trend in recent years.Our study emphasizes that future studies should pay more attention to the response mechanism of birds in urbanizing processes,multidimensional and interdisciplinary studies,and the transformation of the research results into conservation practices.
基金supported by the National Natural Science Foundation of China(No.32170491)the Scientific Research Team Project of the College of Life Sciences,Beijing Normal University in 2024。
文摘Avian wings are central to their remarkable flight ability and diverse life history strategies,including behaviors such as fighting and mating.These multifaceted functions are intricately tied to wing shape,which varies significantly across species because of the complex interplay of evolutionary and ecological pressures.Many indices have been developed to quantify wing characteristics to facilitate the study and comparison of avian wing morphology across species.This study provides a comprehensive overview of existing quantitative methods for analyzing avian wing shapes.We then constructed a new quantification framework through the beta distribution,which can generate indices reflecting the shape of avian wings(center,dispersion,skewness,and kurtosis).Next,we used the flight feathers of 613 bird species to perform different quantitative analyses and explore the relationships between various wing shape quantification methods and life history traits,which serve as proxies for the selective forces shaping wing morphology.We find that the wing shape indices are more strongly associated with ecological variables than with morphological variables,especially for migration,habitat and territoriality.This research guides the selection of appropriate methods for wing shape analysis,contributing to a deeper understanding of avian morphology and its evolutionary drivers.
基金supported by the grants from the National Key Research and Development Program of China(2022YFD1800604)the China Agriculture Research System(CARS-41)the Heilongjiang Touyan Innovation Team Program,China。
文摘Avian metapneumovirus(aMPV),a paramyxovirus,causes acute respiratory diseases in turkeys and swollen head syndrome in chickens.This study established a reverse genetics system for aMPV subtype B LN16-A strain based on T7 RNA polymerase.Full-length cDNA of the LN16-A strain was constructed by assembling 5 cDNA fragments between the T7 promoter and hepatitis delta virus ribozyme.Transfection of this plasmid,along with the supporting plasmids encoding the N,P,M2-1,and L proteins of LN16-A into BSR-T7/5 cells,resulted in the recovery of aMPV subtype B.To identify an effective insertion site,the enhanced green fluorescent protein(EGFP)gene was inserted into different sites of the LN16-A genome to generate recombinant LN16-As.The results showed that the expression levels of EGFP at the site between the G and L genes of LN16-A were significantly higher than those at the other two sites(between the leader and N genes or replacing the SH gene).To verify the availability of the site between G and L for foreign gene expression,the VP2 gene of very virulent infectious bursal disease virus(vvIBDV)was inserted into this site,and recombinant LN16-A(rLN16A-vvVP2)was successfully rescued.Single immunization of specificpathogen-free chickens with rLN16A-vvVP2 induced high levels of neutralizing antibodies and provided 100%protection against the virulent aMPV subtype B and vvIBDV.Establishing a reverse genetics system here provides an important foundation for understanding aMPV pathogenesis and developing novel vector vaccines.
文摘Avian influenza viruses(AIVs)represent an ongoing threat to global health due to their capacity for genetic evolution,zoonotic transmission,and pandemic emergence.This review highlights recent progress in understanding the molecular mechanisms underlying AIV infection,including viral immune evasion strategies and host-virus interactions.It discusses recent outbreaks involving reassortant strains such as H5N1 and H9N2,and examines their public health co-nsequences.Advancements in antiviral therapy,including resistance patterns,and the development of next-generation vaccines such as messenger RNA and universal influenza vaccines are reviewed.The integration of genomic surveillance,artificial intelligence-driven prediction,and One Health approaches is emphasized as essential for pandemic preparedness.This comprehensive overview aims to provide researchers and policymakers with actionable insights for controlling the evolving threat of avian influenza.
基金funded by the National Key Research and Development Program of China(Grant No.2021YFD1800201).
文摘The H4 subtype of avian influenza virus(AIV)is prevalent worldwide,but only receives little attention due to its low pathogenicity in poultry.Consequently,it remains largely unclear whether H4 AIVs pose a potential threat to the poultry industry and public health.During the period from 2011 to 2022,we conducted an active surveillance programm.A total of 154,762 swab samples were collected across various provinces,and 427 H4 viruses were detected,resulting in a positivity rate of 0.28%.All H4 viruses were isolated from poultry,primarily from ducks in live poultry markets.We further investigated the genetic evolutionary characteristics and pathogenicity of 20 H4Nx viruses isolated in our program.Phylogenetic analysis revealed that the 20 H4Nx viruses belonged to the Eurasian lineage and exhibited significant genetic diversity,with 19 distinct genotypes identified.Molecular characterization indicated that these viruses were low-pathogenicity AIVs with limited binding affinity to human receptors,yet they contained mutations associated with enhanced viral replication and pathogenicity in mammals.Pathogenicity tests conducted in ducks demonstrated that H4 viruses were weakly pathogenic,exhibiting limited replication and transmission capabilities.However,some viruses were able to replicate effectively in mice and induce weight loss.For instance,DK/AH/AG61/11(H4N6)can replicate efficiently in MDCK cells,indicating a potential threat to mammals.These findings underscore the importance of ongoing surveillance of H4 AIVs to better understand their evolution and transmission dynamics and to prevent potential public health risks.
基金funded by the National Natural Science Foundation of China(81872673)the Shanghai New Three-year Action Plan for Public Health(GWVI-11.1-03).
文摘On January 30,2024,China announced the first human case of H10N5 influenza infection.Prior to this,human cases of H10N7 and H10N8 had been reported.It is now appropriate to re-examine the evolution and future epidemiological trends of the H10 and N5 subtypes of avian influenza viruses(AIVs).In this study,we analyzed the reassortment characteristics of the first human-derived H10N5 AIV(A/Zhejiang/ZJU01/2023),as well as the evolutionary dynamics of the wild bird-derived H10 and N5 subtypes of AIVs over the past decade.Our findings indicate that the human-derived H10N5 AIV exhibited low pathogenicity.A/bean_goose/Korea/KNU-10/2022(H10N7)and A/mallard/Novosibirsk_region/962k/2018(H12N5)were identified as the potential reassortment parents.The virus has existed since 2022 and several isolations have been reported in Bangladesh.Phylogenetic analysis showed that H10Ny and HxN5 AIVs in China are clustered differently based on the East Asian-Australian(eastern)and Central Asian-Indian(western)migratory flyways.The H10Ny and HxN5 AIV reassortant strains may cause human infections through accidental spillover.It is possible that another center of AIV evolution,mutation,and reassortment may be developing along the migratory flyways in northeastern Asia,distinct from Europe,the Americas,and China's Yangtze River Delta and Pearl River Delta,which should be closely monitored to ensure the safety of the public.
文摘Dear Editor,Since 2024,the clade 2.3.4.4b highly pathogenic avian influenza(HPAI)H5N1 viruses have been identified in dairy cattle in the United States,raising global concerns about public health(Neumann and Kawaoka,2024).As of December 18,2024,the U.S.Centers for Disease Control and Prevention(CDC)has reported over 61 confirmed cases of H5N1 infection in humans,predominantly associated with exposure to infected poultry or dairy cattle(U.S.Centers for Disease Control and Prevention,2024).Notably,the circulating 2.3.4.4b H5N1 clade has demonstrated continuous evolution in both wild and domestic birds globally,with expanding mammalian host tropism that now includes swine,cats,red foxes,harbor seals,and skunks(Peacock et al.,2024).These viruses have not only incurred substantial economic impacts but also posed dual threats to human health and ecological stability particularly during co-infections with other viruses(Abolnik,2024;Wang and Wang,2023).
基金supported by the National Key Research and Development Program of China (2021YFD1800200)the Natural Science Foundation of Shandong Province, China (ZR2021MC087)the State Key Laboratory of Veterinary Biotechnology, China (SKLVBF202201)。
文摘The circulating avian influenza viruses in wild birds have a high possibility of spillover into domestic birds or mammals at the wild bird–domestic bird or bird–mammal interface. H8N4 viruses primarily circulate in migratory wild waterfowl and have rarely been identified in domestic birds. In this study, we summarized the spatial and temporal distribution of global H8 viruses, specified their natural reservoirs, and performed detailed evolutionary analysis onthe dominant H8N4 viruses. Here, we also report a novel H8N4 virus isolated from a Eurasian coot sample froma wetland in eastern China in 2022. Animal infection studies indicated that the wild bird-originated H8N4 virus can replicate and transmit efficiently in ducks but has not adapted to chickens. Additionally, this naturally isolated H8N4 virus can replicate in mice without prior adaptation. These results indicate that H8 viruses exist mainly in the wild duck reservoir and pose a high infection risk to domestic ducks. Therefore, the active surveillance of influenza viruses at the wild and domestic waterfowl interface will contribute to monitoring the circulation of these viruses.
基金supported by the grants from the National Natural Science Foundation of China(31872497 and 32072844)the National Key Research and Development Program of China(2021YFD1800200 and 2016YFD0500207)the Laboratory of Lingnan Modern Agriculture Project,China(NT2021007)。
文摘TypeⅠinterferon(IFN)-mediated innate immune responses represent the first line of host defense against viral infection.However,the molecular mechanisms by which avian infuenza virus(AIV)inhibits typeⅠIFN production in ducks are not well understood.Here,we frst found that the polymerase basic 2(PB2)protein of H5N1 subtype AIV inhibited the typeⅠIFN responses by targeting duck mitochondrial antiviral signaling protein(MAVS).We further demonstrated that H5N1-PB2 bound to theΔtransmembrane(ΔTM)domain of duck MAVS,and the polymerase basic 1(PB1)binding domain(PBD)and RNA binding nuclear import domain(RND)of H5N1-PB2 interacted with MAVS to inhibit typeⅠIFN expression in ducks.Collectively,our fndings contribute to understanding the molecular mechanism by which AIV proteins regulate the retinoic acid-inducible geneⅠ(RIG-Ⅰ)-like receptor(RLR)signaling pathway to evade host antiviral immune responses in ducks.
文摘From March to May, 2004, we selected 8 typical parks or green lands in Shanghai downtown as the study sites to conduct a ornithological research. During this study, total 55 species of birds were recorded, which included 31 resident and 24 migratory species. With statistics methodology, we analyzed the avian communities with 10 major environmental factors covering the park area, water percentage, vegetation species, canopy cover, shrub cover, grass cover, hill number, location condition, human quantity, path width, the study results indicated that: (1) the following 7 environmental factors were important to impact the structures of the avian community, they were park area, vegetation species, shrub coverage, grass coverage, hill number, location condition of the parks and path width; (2) the avian community of theses urban parks tended to deteriorate in the bird number and diversity; the man-made lake which was currently promoted in the park designing and planning process would not be good to attract the birds.
基金Supported by the National Key Technologies Research and Develop-ment Program of China during the 10th Five-Year Plan Period(2004BA519A05)Technologies Research and Development Program of China during the 10th Five-Year Plan Period in Jiangsu Province(BE2002346).~~
文摘Five monoclonal antibodies(Mabs) to nuclear protein of avain influenza virus(AIV) were developed by syncretizing SP 2/0 and the spleen cells from BALB of mice immuized with H9 subtype AIV. Specificity of these Mabs were identified by immunofluorescent assay(IFA) and enzyme linked immunosorbent assay (ELISA). These five Mabs which were named as AIV-NP-2C3, AIV-NP-6A5, AIV-NP-3 H9, AIV-NP-7B4, AIV-NP-2H4 could react with all viruses of AIV-H9 strains in tests. The result of Western blotting showed that only the 60 ku protein antigen of AIV-H9 could be recognized by the Mabs but never recognized by New castle disease virus, REV and infectious bursa disease virus. The result of preliminary application showed that avian influenza viruses could be deetected bv Mabs in IFA and ELISA. All these Mabs will probably play important roles in preventing and monitoring avian influenza viruses.
基金Supported by Important Project of Jinlin Provincial Science and Technology Department(20065020)~~
文摘[Objective] The research aimed to design primers that are suitable for detecting H5 and H7 subtypes of avian influenza virus (AIV) ; [Method] DNAStar was used to analyze the homology of the sequences of H5 and H7 subtypes of AIV accessed in GenBank, and design primers( by Primer Premier 5.0) on high homologous region of these sequences, and then amplified by RT-PCR. [Result] The multiplex RT-PCR amplification, agarose gel electrophoresis and sequencing results showed that the self-designed primers are successful for detecting AIV. [Conclusion] It is feasible to rapidly diagnose AIV through this method.
基金Supported by a Sub-project of 973 Program of China(2005CB523001)~~
文摘[Objective] The study aimed to investigate the genetic variation characters of entire sequences between two H9N2 subtype avian influenza virus strains and other reference strains.[Method] The entire sequences of 8 genes were obtained by using RT-PCR,and these sequences were analyzed with that of six H9N2 subtype avian influenza isolates in homology comparison and genetic evolution relation.[Result] The results showed that the nucleotide sequence of entire gene of the strain shared 91.1%-95.4% homology with other seven reference strains,and PG08 shared the highest homology 91.3% with C/BJ/1/94;ZD06 shared the highest homology 92.3% with D/HK/Y280/97.HA cleavage sites of two H9N2 subtype avian influenza virus isolated strains were PARSSR/GLF,typical of mildly pathogenic avian influenza virus.[Conclusion] Phylogenetic tree for entire gene of eight strains showed that the genetic relationship was the closest between ZD06 and C/Pak/2/99 strains,which belonged to the Eurasian lineage;PG08 shared the highest homology 91.3% with ZD06,it may be the product of gene rearrangements of other sub-lines.
基金Supported by subproject of Major State Basic Research Development Program of China (2005CB523001)~~
文摘[ Objective] To determine the HA gene sequences of four H9N2 Avian influenza virus (AIV) strains and carry out comparative analysis so as to understand the difference and variation pattern of each strain from the angle of molecular biology and to know the distribution and epidemic law of H9N2 AIV. [Method] One pair of primers was designed referring to HA gene sequences of H9N2 AIV. The HA genes of A/Chicken/Hebei/WD/98 (H9N2; WD98 for short), A/Chicken/Hebei/ZD/04 (H9N2; ZD04 for short)), A/Chicken/Beijing/MY/06 (H9N2; MY06 for short) ), and A/Chicken/Beijing/PG/08 (H9N2; PG08 for short)) were amplified, cloned and sequenced. Then the HA gene sequences of these strains were compared with that of 10 H9N2 AIV stains in GenBank. [Result] The ORF of HA genes of the four strains was 1 683 bp in size, encoding 516 amino acids. The HA gene sequences of the four strains, WD98, MY06, PG08, and ZD04, were 82.6% -95.1%, 83.0% -99.0%, 82.7% -95.5%, and 81.3% -95.7% homologous to that of the 10 H9N2 AIV stains, respectively. And the homology of amino acid was respectively 86.6% -96.3%, 86.6% -97.9%, 87.0% -97.1%, and 86.9% -97.3%. [ Conclusion] The HA gene has greatly high homology among different strains.
基金supported by the National Basic Research Program of China(No.2007CB411606)
文摘Ultrasonic communication in vertebrates is attracting increasing research interest.To determine if ultrasonic vocalization is common in birds,we recorded their vocalizations with ultrasound detectors in the Dongzhai National Nature Reserve of Henan Province,China.We found varying degrees of high frequency components in the vocalizations of 14 species and in several of these species,the frequency of harmonics was up to the range of ultrasound.We suggest that more studies are required to determine whether the high frequency components in avian vocalizations have functions and what these functions are.In addition,the ability of birds to hear sounds in the high frequency range also requires re-examination.
