April 2025
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Highly pathogenic avian influenza virus (HPAIV) H5N1 clade 2.3.4.4b emerged in dairy cows in the United States in early 2024. Since then, this clade simultaneously circulates in wild birds, cattle and poultry with ongoing transmission into several mammalian species. Given the historical role of swine in influenza ecology, susceptibility of pigs to this virus is critical for animal and public health. To address this concern, Sinclair nanopigs were infected with a bovine clade 2.3.4.4b HPAIV H5N1 isolate by combined intranasal, intratracheal and oral administration mimicking possible natural exposure routes. Pigs were productively infected developing either subclinical or mild disease with seroconversion. Virus replication occurred mainly in respiratory tissues resulting in shedding from upper respiratory tract mucosae. Limited transmission to naïve contact cage mates was documented in a subset of transmission pairs. The combination of subclinical clade 2.3.4.4b HPAIV H5N1 replication and limited transmission draws an alarming scenario for One Health considering pigs are a favorable influenza mixing vessel enabling mammalian adaptation.
![Infection of JFB with EBOV or MARV does not cause overt clinical disease
A Depiction of challenge study of Jamaican fruit bats with EBOV-Mayinga (magenta) or MARV-Ozolin (purple) via subcutaneous (SC), intranasal (IN), and oral routes. Image created in BioRender [https://BioRender.com/a66b266]. B Change in body temperature of bats (n = 4) infected with EBOV followed through day 28. Two-way ANOVA with Dunnett’s multiple test comparison. Data plotted as mean ± S.D. P values for comparisons to baseline weight are indicated. *** <0.001, ** <0.01, * <0.05. C Percent body weight of bats (n = 4) infected with EBOV followed through day 28. Two-way ANOVA with Dunnett’s multiple test comparison. D Change in body temperature of bats (n = 4) infected with MARV followed through day 28. Two-way ANOVA with Dunnett’s multiple test comparison. Data plotted as mean ± S.D. E Percent body weight of bats (n = 4) infected with MARV followed through day 28. Two-way ANOVA with Dunnett’s multiple test comparison. F Number of circulating white blood cells (WBC), lymphocytes, neutrophils, and monocytes in EBOV-infected bats (n = 4) at baseline and at necropsies. A mixed-effects model with matching and Dunnett’s multiple comparison test was applied to evaluate change in each cell population at necropsy compared to the matched baseline value. G Number of circulating WBC, lymphocytes, neutrophils, and monocytes in MARV challenged bats (n = 4) at baseline and at necropsies. A mixed-effects model with matching and Dunnett’s multiple comparison test was applied to evaluate change in each cell population at necropsies compared to the matched baseline value.](https://www.researchgate.net/publication/390169917/figure/fig1/AS:11431281324193218@1742961298629/Infection-of-JFB-with-EBOV-or-MARV-does-not-cause-overt-clinical-disease-A-Depiction-of_Q320.jpg)
![Glycosylation at the F2 site on NiV-F impedes Fab92 binding. (A, left panel) mAb92 binding of NiV-F or HeV-F in the presence or absence of the F2 glycan (WT and F2 mut, respectively). 293T cells were transiently transfected to express the indicated HNV-F glycoprotein prior to flow cytometry with mAb92. Binding was normalized to two anti-HNV-F polyclonal antibodies, pAb2489 and pAb2490, previously shown to have equivalent cross-reactivity to NiV and HeV-F WT and mutant constructs (36), as indicated in Materials and Methods. The polyclonal antibodies were further normalized to WT NiV-F binding for further comparison. Presented are the results from three independent biological replicates with statistics determined by one-way ANOVA with Sidak's correction for multiple comparisons (****P < 0.0001). (A, right panel) mAb92 neutralization of HNV pseudotyped particles (HNVpp) infection on U87 MG glioblastoma cells HNVpp bearing WT-G and WT-F (F2 glycan present) or F2mut (F2 glycan absent) glycoproteins were produced with a VSV∆G-RLuc system as described in Materials and Methods. HNVpp input was optimized to give output within the dynamic range of the assay. A constant amount of the indicated HNVpp was used to infect permissive U87 cells in the presence or absence of a serial fivefold dilution of mAb92. Data presented are from three independent biological replicates, each with technical duplicates, and points are presented as the mean ± SE. Neutralization curves were constrained by artificially setting the lowest mAb concentration (x-axis) to maximum infection (y-axis) to represent neutralization in the absence of any mAb. The data were then analyzed using a variable slope model with a four-parameter dose-response curve (GraphPad PRISM), and statistical significance was tested with a two-way ANOVA with Dunnett's correction for multiple comparisons. (B) Models for Fab92 and NiV-F are shown in cartoon representation and colored gray and blue, respectively. The NiV-F protomer to which Fab92 is bound is colored dark blue and the neighboring protomers are colored light blue. Residues from CDR loops L1 (dark green), L3 (light green), and H2 (pink) contact the first GlcNAc residue of the F2 glycan on two protomers of NiV-F. The side chains of residues observed to interact with the first GlcNAc of the F2 glycan [as calculated by the PDBePISA server (47) are shown as sticks and colored according to CDR loop as described in Fig. 1]. The side chain of the F2 Asn67 residue is shown as blue sticks. The first F2 GlcNAc is shown as salmon sticks. (C) The complex glycan (shown as light orange sticks) from the structure PDB 4BYH (48) was modeled onto the F2 glycan site on two protomers of NiV-F by alignment onto the first GlcNAc that was observed in the cryo-EM-derived reconstruction. The black arrows indicate the direction of the F2 glycan extending outwards away from Fab92, allowing Fab92 to access its proteinaceous epitope. (D) To investigate if the presence of a full-length F2 glycan may interfere with Fab92 binding to adjacent protomers, Fab92 was superposed onto the binding site on the adjacent NiV-F protomers. The Fab92 modeled onto the adjacent protomer is colored gray. The modeled glycan at the F2 position is shown to clash with a modeled Fab92 bound to the adjacent protomer.](https://www.researchgate.net/publication/383826324/figure/fig3/AS:11431281285176011@1729605300632/Glycosylation-at-the-F2-site-on-NiV-F-impedes-Fab92-binding-A-left-panel-mAb92_Q320.jpg)
![Differences between NiV-F and HeV-F within the Fab92 binding footprint. (A) The residues on the NiV-F surface in the binding interface are colored according to the Fab92 chain involved in the contact. Residues contacted by the light chain are highlighted green, residues contacted by the heavy chain are highlighted pink, and those contacted by both chains are shown in gray. The NiV-F trimer is depicted with surface representation in white, with a single protomer that contains the Fab92 epitope in light blue for clarity. (Lower) Amino acid sequence alignment between NiV-F (Malaysia, AAV80428.1) and HeV-F (AEB21197.1) was generated by Multalin (49) and plotted by ESPript (50). Residues involved in the Fab92 interface are annotated with colored boxes below the alignment. Residues in the interface that differ between NiV-F and HeV-F are outlined by a red box. (B) Surface view of the NiV-F trimer shown in white, with the protomer with Fab92 bound shown in light blue. Residues contacted by Fab92 are colored dark blue. Residues in the epitope that are conserved between NiV-F and HeV-F are colored dark blue and those that differ are colored red. (C) Molecular interactions of Fab92 with NiV-F residue Gln70. Side chains of CDR H3 (hot pink) and Gln70 are shown as sticks. NiV-F is shown in dark blue. (D) A model for steric hinderance in Fab92 recognition of HeV-F imposed by Lys70. To better understand the interactions between Fab92 and HeV-F, the HeV-F structure [PDB ID 5EJB (13), cyan cartoon] was aligned to NiV-F using COOT. The lysine at position 70 is modeled as observed in the HeV-F crystal structure, as well as in possible rotamer configurations that introduce steric clashes with Fab92 residues Tyr33 (CDR H1, pink) and Tyr100B (CDR H3, hot pink). (E) mAb92 binding of NiV and HeV-F WT or mutant F proteins. 293T cells were transfected as described in Materials and Methods to express WT HNV-F, the double residue 70 and 74 mutant (70+74mut), the residue 70 only mutant (70mut), or the residue 74 only mutant (74mut). Data presented are the result of three independent biological replicates and are analyzed as described previously for Fig. 3A, left panel (ns, not significant, ****P < 0.0001). (F) mAb92 neutralization of HNVpp expressing WT or mutant F glycoproteins. HNVpp were produced as described in Materials and Methods to express WT G and the indicated NiV/HeV WT or mutant (70+74mut, 70mut, or 74mut) F glycoprotein. Neutralization curves were generated from three independent biological replicates done in technical duplicates. Data were analyzed as described above for Fig. 3A, right panel. WT data for binding and neutralization are repeated from Fig. 3A to facilitate interpretation of these findings in the context of the 70 and 74 double or individual mutants.](https://www.researchgate.net/publication/383826324/figure/fig4/AS:11431281285211840@1729605302598/Differences-between-NiV-F-and-HeV-F-within-the-Fab92-binding-footprint-A-The-residues_Q320.jpg)
