SQSTM1 downregulates avian metapneumovirus subgroup C replication via mediating selective autophagic degradation of viral M2-2 protein.

Avian metapneumovirus subgroup C (aMPV/C), an important pathogen causing acute respiratory infection in chickens and turkeys, contributes to substantial economic losses in the poultry industry worldwide. aMPV/C has been reported to induce autophagy, which is beneficial to virus replication. Sequestosome 1 (SQSTM1/P62), a selective autophagic receptor, plays a crucial role in viral replication by clearing ubiquitinated proteins. However, the relationship between SQSTM1-mediated selective autophagy and aMPV/C replication is unclear. In this study, we found that the expression of SQSTM1 negatively regulates aMPV/C replication by reducing viral protein expression and viral titers. Further studies revealed that the interaction between SQSTM1 and aMPV/C M2-2 protein is mediated via the Phox and Bem1 (PB1) domain of the former, which recognizes a ubiquitinated lysine at position 67 of the M2-2 protein, and finally degrades M2-2 via SQSTM1-mediated selective autophagy. Collectively, our results reveal that SQSTM1 degrades M2-2 via a process of selective autophagy to suppress aMPV/C replication, thereby providing novel insights for the prevention and control of aMPV/C infection.IMPORTANCEThe selective autophagy plays an important role in virus replication. As an emerging pathogen of avian respiratory virus, clarification of the effect of SQSTM1, a selective autophagic receptor, on aMPV/C replication in host cells enables us to better understand the viral pathogenesis. Previous study showed that aMPV/C infection reduced the SQSTM1 expression accompanied by virus proliferation, but the specific regulatory mechanism between them was still unclear. In this study, we demonstrated for the first time that SQSTM1 recognizes the 67th amino acid of M2-2 protein by the interaction between them, followed by M2-2 degradation via the SQSTM1-mediated selective autophagy, and finally inhibits aMPV/C replication. This information supplies the mechanism by which SQSTM1 negatively regulates viral replication, and provides new insights for preventing and controlling aMPV/C infection.

Epidemiological characteristics of human metapneumovirus among children in Nanjing, China.

PURPOSE: The objective of this study was to examine the molecular epidemiology and clinical characteristics of HMPV infection among children with ARIs in Nanjing. METHODS: The respiratory samples were collected from 2078 children (≤ 14 years) with acute respiratory infections and were tested for HMPV using real-time RT-PCR. Amplification and sequencing of the HMPV G gene were followed by phylogenetic analysis using MEGA 7.0. RESULT: The detection rate of HMPV among children was 4.7% (97/2078), with a concentration in those under 5 years of age. Notably, the peak season for HMPV prevalence was observed in winter. Among the 97 HMPV-positive samples, 51.5% (50/97) were available for characterization of the HMPV G protein gene. Phylogenetic analysis indicated that the sequenced HMPV strains were classified into three sublineages: A2c111nt - dup (84.0%), B1 (2.0%), and B2 (14.0%). CONCLUSION: There was an incidence of HMPV among hospitalized children during 2021-2022 in Nanjing with A2c111nt - dup being the dominant strain. This study demonstrated the molecular epidemiological characteristics of HMPV among children with respiratory infections in Nanjing, China.

[Genotype and epidemiological characteristics of human metapneumovirus among hospitalized cases of acute respiratory infection in children in Changchun City, Jilin Province from 2019 to 2023].

Objective: To investigate the genotype and epidemiological characteristics of human metapneumovirus (HMPV) among hospitalized cases with acute respiratory infections (ARI) in children in Changchun City, Jilin Province, China. Methods: From June 2019 to June 2023, throat swabs of ARI inpatients in Changchun Children's Hospital were collected, and their epidemiological and clinical information were also collected. Quantitative reverse transcription-PCR was used to identify HMPV-positive cases, followed by the amplification of the G gene and genetic analysis in the HMPV-positive cases. Results: A total of 3 311 children hospitalized with ARI were included in this study. Their age ranged from 0 to 17 years old, and the M (Q1, Q3) of age was 2 (1, 3) years. About 1 811 (54.70%) cases were males. A total of 167 HMPV-positive cases were detected with a positive rate of 5.04%, of which 92.81% (155/167) were children under 5 years old. The positive rate of HMPV in 2019 was 6.37% (30/471), which dropped to the lowest in 2020 (2.31%, 10/432). The HMPV-positive rate was then rebounded in 2021 (4.70%, 60/1 277) and 2022 (4.56%, 21/461), which increased to 6.87% (46/670) in 2023. The difference in HMPV-positive rate among each year was statistically significant (P<0.05). The prevalence peak of HMPV varied in different years, showing either a unimodal or bimodal distribution in one year. A total of 79 HMPV G gene sequences were obtained, of which subtype A and subtype B accounted for 48.10% and 51.90%, respectively. All of the subtype A sequences were clarified as A2c duplicated variants, and subtype B was mainly B2 genotype. Besides, subtypes A and B were prevalent alone or co-circulated in different years, and there was a subtype replacement pattern in HMPV. Conclusion: The positive rate of HMPV in hospitalized ARI cases in children is significantly different from 2019 to 2023 in Changchun City. Notably, there are certain switch patterns of HMPV subtypes A and B in different years.

Geographical Expansion of Avian Metapneumovirus Subtype B: First Detection and Molecular Characterization of Avian Metapneumovirus Subtype B in US Poultry.

Avian metapneumovirus (aMPV), classified within the Pneumoviridae family, wreaks havoc on poultry health. It typically causes upper respiratory tract and reproductive tract infections, mainly in turkeys, chickens, and ducks. Four subtypes of AMPV (A, B, C, D) and two unclassified subtypes have been identified, of which subtypes A and B are widely distributed across the world. In January 2024, an outbreak of severe respiratory disease occurred on turkey and chicken farms across different states in the US. Metagenomics sequencing of selected tissue and swab samples confirmed the presence of aMPV subtype B. Subsequently, all samples were screened using an aMPV subtype A and B multiplex real-time RT-PCR kit. Of the 221 farms, 124 (56%) were found to be positive for aMPV-B. All samples were negative for subtype A. Six whole genomes were assembled, five from turkeys and one from chickens; all six assembled genomes showed 99.29 to 99.98% nucleotide identity, indicating a clonal expansion event for aMPV-B within the country. In addition, all six sequences showed 97.74 to 98.58% nucleotide identity with previously reported subtype B sequences, e.g., VCO3/60616, Hungary/657/4, and BR/1890/E1/19. In comparison to these two reference strains, the study sequences showed unique 49-62 amino acid changes across the genome, with maximum changes in glycoprotein (G). One unique AA change from T (Threonine) to I (Isoleucine) at position 153 in G protein was reported only in the chicken aMPV sequence, which differentiated it from turkey sequences. The twelve unique AA changes along with change in polarity of the G protein may indicate that these unique changes played a role in the adaptation of this virus in the US poultry. This is the first documented report of aMPV subtype B in US poultry, highlighting the need for further investigations into its genotypic characterization, pathogenesis, and evolutionary dynamics.

Molecular Epidemiology of Human Metapneumovirus in East Japan before and after COVID-19, 2017-2022.

Human metapneumovirus (hMPV) is genetically classified into two major subgroups, A and B, based on attachment glycoprotein (G protein) gene sequences. The A2 subgroup is further separated into three subdivisions, A2a, A2b (A2b1), and A2c (A2b2). Subgroup A2c viruses carrying 180- or 111-nucleotide duplications in the G gene (A2c 180nt-dup or A2c 111nt-dup ) have been reported in Japan and Spain. The coronavirus disease 2019 (COVID-19) pandemic disrupted the epidemiological kinetics of other respiratory viruses, including hMPV. In this study, we analyzed the sequences of hMPV isolates in Tokyo and Fukushima obtained from 2017 to 2022, i.e., before and after the COVID-19 pandemic. Subgroup A hMPV strains were detected from 2017 to 2019, and most cases were A2c 111nt-dup, suggesting ongoing transmission of this clade, consistent with global transmission dynamics. Subgroup B viruses, but not subgroup A viruses, were detected in 2022 after the COVID-19 peak. Phylogenetic analysis showed that the subgroup B viruses were closely related to strains detected in Yokohama from 2013 to 2016, and strains detected in Fukushima in 2019, suggesting the reappearance of local endemic viruses in East Japan.

Genetic Diversity and Detection of Respiratory Viruses Excluding SARS-CoV-2 during the COVID-19 Pandemic in Gabon, 2020-2021.

Acute respiratory infections are a major global burden in resource-limited countries, including countries in Africa. Although COVID-19 has been well studied since the pandemic emerged in Gabon, Central Africa, less attention has been paid to other respiratory viral diseases, and very little data are available. Herein, we provide the first data on the genetic diversity and detection of 18 major respiratory viruses in Gabon during the COVID-19 pandemic. Of 582 nasopharyngeal swab specimens collected from March 2020 to July 2021, which were SARS-CoV-2 negative, 156 were positive (26%) for the following viruses: enterovirus (20.3%), human rhinovirus (HRV) (4.6%), human coronavirus OC43 (1.2%), human adenovirus (0.9%), human metapneumovirus (hMPV) (0.5%), influenza A virus (IAV) (0.3%), and human parainfluenza viruses (0.5%). To determine the genetic diversity and transmission route of the viruses, phylogenetic analyses were performed using genome sequences of the detected viruses. The IAV strain detected in this study was genetically similar to strains isolated in the USA, whereas the hMPV strain belonging to the A2b subtype formed a cluster with Kenyan strains. This study provides the first complete genomic sequences of HRV, IAV, and hMPV detected in Gabon, and provides insight into the circulation of respiratory viruses in the country.

Aplicação da técnica de RT-PCR para metapneumovírus aviário (aMPV) / Application of RT-PCR technique for avian metapneumovirus (aMPV) / Aplicación de la técnica RT-PCR para metapneumovirus aviario (aMPV)

Os principais hospedeiros do Metapneumovírus aviário (aMPV) são os frangos de corte e perus. O vírus acomete o trato respiratório superior dos perus desencadeando a Rinotraqueíte Viral dos Perus (RVP). O principal objetivo deste trabalho foi padronizar uma técnica de RT-PCR para a detecção do aMPV, por meio do uso do kit AccessQuick™ RT-PCR system (Promega®). Foram utilizados amostras de suabes de traqueia e pulmão de 38 perus comerciais com sintomatologia respiratória e dois suabes oculares de faisão. O RNA viral foi extraído utilizando-se o kit RTP® DNA/RNA Virus Mini Kit (STRATEC Molecular). Em seguida as amostras foram submetidas à RT-PCR One Step, utilizando o kit AccessQuick™ RT-PCR system (Promega®). Todas as 40 amostras testadas por RT-PCR foram negativas, exceto a amostra vacinal que foi utilizada como controle positivo. O aMPV não causa latência em frangos de corte ou perus, logo a excreção viral é limitada. Dessa forma, a ausência da detecção de genoma viral neste estudo pode ser justificada devido à idade que as amostras foram coletadas em perus, com 140 dias no abatedouro, impossibilitando dessa maneira a amplificação do genoma do aMPV. Porém, esse estudo também mostra que a RT-PCR se mostrou eficaz para detectar o genoma viral do aMPV, podendo dessa forma ser utilizado como uma ferramenta de diagnóstico rápido para investigação e estudo de casos de aMPV em rebanho de perus.

The main hosts of Avian metapneumovirus (aMPV) are broilers and turkeys. This virus affects the upper respiratory tract of turkeys, triggering Turkey Rhinotracheitis (TRT). The aim of this study was to optimize a RT-PCR technique in order to detect aMPV using the AccessQuick™ RT-PCR system (Promega®) kit. Tracheal and lung swab samples from 38 commercial turkeys with respiratory symptoms and two ocular swabs from pheasants were analyzed. Viral RNA was extracted using RTP® DNA/RNA Virus Mini Kit (Molecular STRATEC) kit. All 40 samples tested were negative in the RT-PCR. The only positive sample was a vaccine strain, used as the positive control. The aMPV does not cause latency in broilers, chickens or turkeys, thus, the viral excretion is limited. However, the absence of viral genome detection in this study may be justified due to the age the samples were collected, since they were collected in turkeys with about 140 days in the slaughterhouse, thus preventing the amplification of the aMPV genome. This study shows that the RT-PCR is effective to detect aMPV viral genome and may be used as a rapid diagnostic tool for research and for the studying of aMPV cases in turkey flocks in Brazil.

Los principales anfitriones de Metapneumovirus aviario (aMPV) son los pollos de engorde y pavos. El virus afecta el tracto respiratorio superior de los pavos desencadenando la Rinotraqueitis Viral de los pavos (RVP). El principal objetivo de ese estudio fue estandarizar una técnica de RT-PCR para la detección del aMPV, a través del uso del kit AccessQuick™-PCRsystem (Promega®). Se utilizaron muestras de hisopos traqueales y pulmonares de 38 pavos comerciales con síntomas respiratorios y dos hisopos oculares de faisán. El RNA viral se extrajo utilizando el kit DNA RTP® DNA/RNA Virus Mini Kit (STRATEC Molecular). A continuación, las muestras se sometieron a la RT-PCR OneStep utilizando el kit AccessQuick™ RT-PCR (Promega®). Todas las 40 muestras analizadas por RT-PCR fueron negativas, excepto la muestra de vacuna que se utilizó como control positivo. El aMPV no causa latencia en pollos de engorde o pavos, por lo que la excreción viral es limitada. Así, la ausencia de la detección de genoma viral en este estudio puede ser justificada debido a la edad que se recogieron las muestras en los pavos, con 140 días en el matadero, imposibilitando de este modo la amplificación del genoma del aMPV. Sin embargo, ese estudio también muestra que la RT-PCR se ha demostrado eficaz para detectar el genoma viral del aMPV, pudiendo así ser utilizado como una herramienta de diagnóstico rápido para investigación y estudio de casos de aMPV en bandada de pavos.