Nucleotide sequence as key determinant driving insertions at influenza A virus hemagglutinin cleavage sites

Highly pathogenic avian influenza viruses (HPAIVs) emerge from H5 and H7 low pathogenic avian influenza viruses (LPAIVs), most frequently upon insertions of nucleotides coding for basic amino acids at the cleavage site (CS) of the hemagglutinin (HA). The exact molecular mechanism(s) underlying this genetic change and reasons underlying the restriction to H5 and H7 viruses remain unknown. Here, we developed a novel experimental system based on frame repair through insertions or deletions (indels) of HAs with single nucleotide deletions. Indels were readily detected in a consensus H5 LPAIV CS at low frequency, which was increased upon the introduction of only one substitution leading to a longer stretch of adenines at the CS. In contrast, we only detected indels in H6 when multiple nucleotide substitutions were introduced. These data show that nucleotide sequence is a key determinant of insertions in the HA CS, and reveal novel insights about the subtype-specificity of HPAIV emergence.</p

The role of M2 proteins of pneumoviruses in transcription regulation, prevention of hypermutation, and activation of the type I interferon pathway

Human metapneumovirus (HMPV) is an important causative agent of respiratory tract disease. Fundamental knowledge of the interaction between HMPV and the innate immune system could lead to the design of novel antiviral therapies. Previously, we demonstrated that HMPV M2-2 deletion mutants had hypermutated genomes and contained defective interfering particles (DIs), which are potent inducers of the IFN response. Here, we investigated the role of the HMPV M2-2 protein as IFN antagonist using chimeric HMPV expressing M2 proteins of other pneumoviruses: respiratory syncytial virus (RSV) and avian metapneumovirus type C (AMPV/C). Chimeric HMPVs expressing the M2 proteins of RSV or AMPV/C were attenuated in HEp-2 cells but did not activate the IFN response, and their genomes were not hypermutated. In contrast, chimeric HMPVs expressing the M2-2 proteins of RSV and AMPV/C, in combination with HMPV M2-1, did activate the IFN response, and their genomes were hypermutated. Investigation of the role of the pneumovirus M2 proteins in transcription regulation demonstrated that the M2-2 protein, only in concerted action with autologous M2-1 protein, acted as a transcription elongation factor. As a second approach, chimeric RSV in which the IFN antagonists NS1 and NS2 were replaced by the HMPV M2-2 gene failed to suppress an IFN response, indicating that the HMPV M2-2 protein is not a potent IFN antagonist. These data indicate that expression of autologous M2-1 and M2-2 proteins is important for the fidelity of the RNA-dependent RNA polymerase, necessary to prevent the accumulation of mutations, and possibly DIs, thereby preventing activation of the IFN responses.</p

Isolation of Human Metapneumovirus from clinical specimen in human organoid-derived bronchial cell cultures is superior to isolation in monolayer cell line cultures

Background: Human Metapneumovirus (HMPV) is a causative agent of respiratory tract infections (RTI) in children and adults. HMPV is a member of the Pneumoviridae family for which circulation of two serotypes, A and B, has been reported. HMPV isolation in standard monolayer cell lines is not always successful. Recently, it was shown that upon inoculation of human organoid-derived bronchial (ODB) cultures, HMPV primarily targeted the ciliated cells, similar as observed in experimentally infected animals. These observations lead to the hypothesis that isolation of virus from clinical specimen in this ODB model could be more successful than in standard monolayer cultures. Methods: This study compared the efficiency of isolation of HMPV from 36 clinical samples in human ODB cultures with that in monolayers of Vero-118 cells. Results: A total of 27 isolates (8 HMPV A and 19 HMPV B) were obtained in the ODB cultures, after one passage, whereas 21 isolates (9 HMPV A and 12 HMPV B) were obtained after one or two passages in Vero-118 cells. Conclusions: Overall, the isolation efficiency of serotype A HMPV was comparable in both models, while isolation of serotype B viruses was profoundly more efficient in the ODB cultures than in Vero-118 cells, suggesting that primary cultures expressing ciliated cells should be considered as a superior isolation method for HMPV from clinical specimens

Influenza A(H5N1) shedding in air corresponds to transmissibility in mammals

An increase in spillover events of highly pathogenic avian influenza A(H5N1) viruses to mammals suggests selection of viruses that transmit well in mammals. Here we use air-sampling devices to continuously sample infectious influenza viruses expelled by experimentally infected ferrets. The resulting quantitative virus shedding kinetics data resembled ferret-to-ferret transmission studies and indicated that the absence of transmission observed for earlier A(H5N1) viruses was due to a lack of infectious virus shedding in the air, rather than the absence of necessary mammalian adaptation mutations. Whereas infectious human A(H1N1pdm) virus was efficiently shed in the air, infectious 2005 zoonotic and 2024 bovine A(H5N1) viruses were not detected in the air. By contrast, shedding of infectious virus was observed for 1 out of 4 ferrets infected with a 2022 European polecat A(H5N1) virus and a 2024 A(H5N1) virus isolated from a dairy farm worker.</p

Species-specific emergence of H7 highly pathogenic avian influenza virus is driven by intrahost selection differences between chickens and ducks

Highly pathogenic avian influenza viruses (HPAIVs) cause severe hemorrhagic disease in terrestrial poultry and are a threat to the poultry industry, wild life, and human health. HPAIVs arise from low pathogenic avian influenza viruses (LPAIVs), which circulate in wild aquatic birds. HPAIV emergence is thought to occur in poultry and not wild aquatic birds, but the reason for this species-restriction is not known. We hypothesized that, due to species-specific tropism and replication, intrahost HPAIV selection is favored in poultry and disfavored in wild aquatic birds. We tested this hypothesis by co-inoculating chickens, representative of poultry, and ducks, representative of wild aquatic birds, with a mixture of H7N7 HPAIV and LPAIV, mimicking HPAIV emergence in an experimental setting. Virus selection was monitored in swabs and tissues by RT-qPCR and immunostaining of differential N-terminal epitope tags that were added to the hemagglutinin protein. HPAIV was selected in four of six co-inoculated chickens, whereas LPAIV remained the major population in co-inoculated ducks on the long-term, despite detection of infectious HPAIV in tissues at early time points. Collectively, our data support the hypothesis that HPAIVs are more likely to be selected at the intrahost level in poultry than in wild aquatic birds and point towards species-specific differences in HPAIV and LPAIV tropism and replication levels as possible explanations.</p

Transient RNA structures underlie highly pathogenic avian influenza virus genesis

Highly pathogenic avian influenza viruses (HPAIVs) cause severe disease and high fatality in poultry1. They emerge exclusively from H5 and H7 low pathogenic avian influenza viruses (LPAIVs)2. Although insertion of a furin-cleavable multibasic cleavage site (MBCS) in the hemagglutinin gene was identified decades ago as the genetic basis for LPAIV-to-HPAIV transition3,4, the exact mechanisms underlying said insertion have remained unknown. Here we used an innovative combination of bioinformatic models to predict RNA structures forming around the influenza virus RNA polymerase during replication, and circular sequencing5 to reliably detect nucleotide insertions. We show that transient H5 hemagglutinin RNA structures predicted to trap the polymerase on purine-rich sequences drive nucleotide insertions characteristic of MBCSs, providing the first strong empirical evidence of RNA structure involvement in MBCS acquisition. Insertion frequencies at the H5 cleavage site were strongly affected by substitutions in flanking genomic regions altering predicted transient RNA structures. Introduction of H5-like cleavage site sequences and structures into an H6 hemagglutinin resulted in MBCS-yielding insertions never observed before in H6 viruses. Our results demonstrate that nucleotide insertions that underlie H5 HPAIV emergence result from a previously unknown RNA-structure-driven diversity-generating mechanism, which could be shared with other RNA viruses

A vaccine central in A(H5) influenza antigenic space confers broad immunity

Highly pathogenic avian influenza A(H5) viruses globally impact wild and domestic birds, and have caused severe infections in mammals, including humans, underscoring their pandemic potential1, 2, 3, 4–5. The antigenic evolution of the A(H5) haemagglutinin (HA) poses challenges for pandemic preparedness and vaccine design6. Here the global antigenic evolution of the A(H5) HA was captured in a high-resolution antigenic map. The map was used to design immunogenic and antigenically central vaccine HA antigens, eliciting antibody responses that broadly cover the A(H5) antigenic space. In ferrets, a central antigen protected as well as homologous vaccines against heterologous infection with two antigenically distinct viruses. This work showcases the rational design of subtype-wide influenza A(H5) pre-pandemic vaccines and demonstrates the value of antigenic maps for the evaluation of vaccine-induced immune responses through antibody profiles.</p

A vaccine antigen central in influenza A(H5) virus antigenic space confers subtype-wide immunity

Highly pathogenic avian influenza A(H5) viruses globally impact wild and domestic birds, and mammals, including humans, underscoring their pandemic potential. The antigenic evolution of the A(H5) hemagglutinin (HA) poses challenges for pandemic preparedness and vaccine design. Here, the global antigenic evolution of the A(H5) HA was captured in a high-resolution antigenic map. The map was used to engineer immunogenic and antigenically central vaccine HA antigens, eliciting antibody responses that broadly cover the A(H5) antigenic space. In ferrets, a central antigen protected as well as homologous vaccines against heterologous infection with two antigenically distinct viruses. This work showcases the rational design of subtype-wide influenza A(H5) pre-pandemic vaccines and demonstrates the value of antigenic maps for the evaluation of vaccine-induced immune responses through antibody profiles.</p

Identification and Characterization of Two Novel Syncytin-Like Retroviral Envelope Genes, Captured for a Possible role in the Atypical Structure of the Hyena Placenta and in the Emergence of the Non-Mammalian Mabuya Lizard Placenta a

Les syncytines sont des gènes d'enveloppes rétrovirales (env) capturés qui sont essentiels pour l'établissement du placenta chez les mammifères. Il a été proposé que la diversité des syncytines capturées explique pourquoi le placenta est l'organe le plus variable chez les mammifères. Ici nous avons employé deux approches pour étudier le lien entre la capture d'env et l'émergence et la diversité des structures placentaires. D'abord, nous avons étudié la placentation des Hyaenidae, les seuls carnivores à présenter un placenta très invasif hémochorial, comme l'humain. Comme tous les carnivores, les hyènes expriment la syncytin-Car1 précédemment décrite, mais nous avons identifié une nouvelle env, capturée uniquement chez ces dernières, que nous avons nommée Hyena-Env2. Ce nouveau gène est présent au même locus chez toutes les hyènes, ayant été capturé pendant la radiation de la famille. Il est non-fusiogène mais a néanmoins été conservé pendant plus de 10 millions d'années et est exprimé à l'interface materno-fœtale du placenta, ce qui en fait un gène candidat pour expliquer le passage à la placentation hémochoriale qui a eu lieu chez les Hyaenidae. Ensuite, nous avons cherché des gènes syncytine dans le genre non-mammifère Mabuya, des lézards vivipares présentant un type rare de placenta très complexe et proche de celui des mammifères. Nous avons identifié une env qui a été capturée et conservée dans ce genre depuis sa radiation, il y a 25 millions d'années. Ce gène, que nous avons appelé syncytin-Mab1, est capable d'induire la fusion cellule-cellule et est exprimé dans une couche de cellules fusionnées à l'interface materno-fœtale du placenta, deux propriétés canoniques de syncytine. Nous avons aussi identifié le récepteur de syncytin-Mab1, MPZL1, et avons montré que leur interaction induit son activation et sa phosphorylation. L'activation de MPZL1 a été liée à la migration et à l'invasion cellulaire, indiquant que cette interaction env-récepteur pourrait jouer un rôle dans l'invasion placentaire du tissu maternel observée chez les Mabuya. Pour conclure, la caractérisation de ces deux nouvelles env indique que les gènes de type syncytine ont pu jouer un rôle à la fois dans l'émergence du placenta de Mabuya et dans la structure atypique du placenta des hyènes, supportant la notion que la capture d'env est une force évolutive majeure.Syncytins are captured retroviral envelope genes (env) that are essential for the establishment of placental structures in mammals. The syncytins present in different mammalian families are highly diverse, resulting from distinct capture events, and it has been suggested that this might play a role in making the placenta the most diverse structure in mammals. Here we used two different approaches to investigate the links between env capture and emergence and diversity of placental structures. First, we investigated placentation in Hyaenidae, the only carnivorans that present a highly invasive hemochorial placenta, as is also found in humans. Hyenas express the previously identified syncytin-Car1 gene, as do all carnivorans, but we identified a new hyena-specific captured env that we named Hyena-Env2. This new gene is present at the same locus in all hyenas, having been captured during the radiation of this family. It is non-fusiogenic but still conserved over at least 10 million years of evolution and expressed at the materno-fetal interface in the hyena placenta, making it a candidate gene for explaining the endotheliochorial to hemochorial placental transition that occurred in Hyeanidae. Second, we searched for syncytin-like genes in the non-mammalian Mabuya lizards, which are viviparous and present a rare type of highly complex placenta that is very reminiscent of mammalian placentas. We identified an env gene that was captured and conserved in this genus since its radiation 25 million years ago. This gene, that we named syncytin-Mab1, is able to mediate cell-cell fusion in vitro and is expressed in a fused cell layer at the materno-fetal interface of the placenta in vivo, characteristic features of canonical mammalian syncytin genes. We also identified the cellular gene MPZL1 as the cognate receptor of syncytin-Mab1 and showed that their interaction induces activation and phosphorylation of the former. MPZL1 activation has been linked with cell migration and invasion, indicating that this env-receptor interaction could play a role in the placental invasion of maternal tissues observed in Mabuya. In conclusion, the characterization of these two novel env genes indicates that syncytin-like env might have played a role both in the emergence of the Mabuya placenta and the atypical placental structure of hyenas, reinforcing the notion that env capture is a major driving force in evolution

Identification et caractérisation de deux nouveaux gènes d'enveloppes rétrovirales de type syncytine, capturés pour un possible rôle dans la structure atypique du placenta de hyène et l'émergence du placenta non-mammifère des lézards Mabuya

Syncytins are captured retroviral envelope genes (env) that are essential for the establishment of placental structures in mammals. The syncytins present in different mammalian families are highly diverse, resulting from distinct capture events, and it has been suggested that this might play a role in making the placenta the most diverse structure in mammals. Here we used two different approaches to investigate the links between env capture and emergence and diversity of placental structures. First, we investigated placentation in Hyaenidae, the only carnivorans that present a highly invasive hemochorial placenta, as is also found in humans. Hyenas express the previously identified syncytin-Car1 gene, as do all carnivorans, but we identified a new hyena-specific captured env that we named Hyena-Env2. This new gene is present at the same locus in all hyenas, having been captured during the radiation of this family. It is non-fusiogenic but still conserved over at least 10 million years of evolution and expressed at the materno-fetal interface in the hyena placenta, making it a candidate gene for explaining the endotheliochorial to hemochorial placental transition that occurred in Hyeanidae. Second, we searched for syncytin-like genes in the non-mammalian Mabuya lizards, which are viviparous and present a rare type of highly complex placenta that is very reminiscent of mammalian placentas. We identified an env gene that was captured and conserved in this genus since its radiation 25 million years ago. This gene, that we named syncytin-Mab1, is able to mediate cell-cell fusion in vitro and is expressed in a fused cell layer at the materno-fetal interface of the placenta in vivo, characteristic features of canonical mammalian syncytin genes. We also identified the cellular gene MPZL1 as the cognate receptor of syncytin-Mab1 and showed that their interaction induces activation and phosphorylation of the former. MPZL1 activation has been linked with cell migration and invasion, indicating that this env-receptor interaction could play a role in the placental invasion of maternal tissues observed in Mabuya. In conclusion, the characterization of these two novel env genes indicates that syncytin-like env might have played a role both in the emergence of the Mabuya placenta and the atypical placental structure of hyenas, reinforcing the notion that env capture is a major driving force in evolution.Les syncytines sont des gènes d'enveloppes rétrovirales (env) capturés qui sont essentiels pour l'établissement du placenta chez les mammifères. Il a été proposé que la diversité des syncytines capturées explique pourquoi le placenta est l'organe le plus variable chez les mammifères. Ici nous avons employé deux approches pour étudier le lien entre la capture d'env et l'émergence et la diversité des structures placentaires. D'abord, nous avons étudié la placentation des Hyaenidae, les seuls carnivores à présenter un placenta très invasif hémochorial, comme l'humain. Comme tous les carnivores, les hyènes expriment la syncytin-Car1 précédemment décrite, mais nous avons identifié une nouvelle env, capturée uniquement chez ces dernières, que nous avons nommée Hyena-Env2. Ce nouveau gène est présent au même locus chez toutes les hyènes, ayant été capturé pendant la radiation de la famille. Il est non-fusiogène mais a néanmoins été conservé pendant plus de 10 millions d'années et est exprimé à l'interface materno-fœtale du placenta, ce qui en fait un gène candidat pour expliquer le passage à la placentation hémochoriale qui a eu lieu chez les Hyaenidae. Ensuite, nous avons cherché des gènes syncytine dans le genre non-mammifère Mabuya, des lézards vivipares présentant un type rare de placenta très complexe et proche de celui des mammifères. Nous avons identifié une env qui a été capturée et conservée dans ce genre depuis sa radiation, il y a 25 millions d'années. Ce gène, que nous avons appelé syncytin-Mab1, est capable d'induire la fusion cellule-cellule et est exprimé dans une couche de cellules fusionnées à l'interface materno-fœtale du placenta, deux propriétés canoniques de syncytine. Nous avons aussi identifié le récepteur de syncytin-Mab1, MPZL1, et avons montré que leur interaction induit son activation et sa phosphorylation. L'activation de MPZL1 a été liée à la migration et à l'invasion cellulaire, indiquant que cette interaction env-récepteur pourrait jouer un rôle dans l'invasion placentaire du tissu maternel observée chez les Mabuya. Pour conclure, la caractérisation de ces deux nouvelles env indique que les gènes de type syncytine ont pu jouer un rôle à la fois dans l'émergence du placenta de Mabuya et dans la structure atypique du placenta des hyènes, supportant la notion que la capture d'env est une force évolutive majeure