Reverse Genetics Vaccine Seeds for Influenza: Mechanisms that drive the co-segregation of PB1 with antigenic proteins

Funder

Organizational Unit

Publications

NS1 protein as a novel anti-influenza target: Map-and-mutate antiviral rationale reveals new putative druggable hot spots with an important role on viral replication

Publication . Trigueiro-Louro, João; Santos, Luís A.; Almeida, Filipe; Correia, Vanessa; Brito, Rui M.M.; Rebelo-de-Andrade, Helena

Influenza NS1 is a promising anti-influenza target, considering its conserved and druggable structure, and key function in influenza replication and pathogenesis. Notwithstanding, target identification and validation, strengthened by experimental data, are lacking. Here, we further explored our previously designed structure-based antiviral rationale directed to highly conserved druggable NS1 regions across a broad spectrum of influenza A viruses. We aimed to identify NS1-mutated viruses exhibiting a reduced growth phenotype and/or an altered cell apoptosis profile. We found that NS1 mutations Y171A, K175A (consensus druggable pocket 1), W102A (consensus druggable pocket 3), Q121A and G184P (multiple consensus druggable pockets) - located at hot spots amenable for pharmacological modulation - significantly impaired A(H1N1)pdm09 virus replication, in vitro. This is the first time that NS1-K175A, -W102A, and -Q121A mutations are characterized. Our map-and-mutate strategy provides the basis to establish the NS1 as a promising target using a rationale with a higher resilience to resistance development.

2022-01-02Journal article

Restricted access

Optimization of A(H1N1)pdm09 vaccine seed viruses: The source of PB1 and HA vRNA as a major determinant for antigen yield

Publication . Almeida, Filipe; Santos, Luís A.; Trigueiro-Louro, João M.; Rebelo-de-Andrade, Helena

Vaccination prevents and reduces the severity of influenza virus infections. Continuous evolution of influenza hemagglutinin (HA) and neuraminidase (NA) supports the virus to evade pre-existing immunity, which demands vaccines to be reformulated every year. Incorporation of polymerase basic protein 1 (PB1) viral RNA (vRNA) of the same origin of HA and NA vRNA has been observed in previous pandemic viruses and occasionally reported for influenza A vaccine prototype strains of prior seasons. At this point, it remains to be explored whether this phenomenon translates into an improved growth phenotype. In this work, we showed that the HA vRNA of A(H1N1)pdm09 is generally incorporated with the PB1 vRNA of the same origin, establishing the beneficial effect of the presence of PB1 and the pattern of the PB1-HA co-incorporation in the A(H1N1)pdm09 model. We further investigated the putative interplay between PB1 and antigenic proteins regarding the vRNA composition of the progeny and observed that vRNA segregation does not appear to be mainly determined by protein-protein interactions; while vRNA-vRNA interactions can be suggested as the main driving force. Our data also indicate an increase in the hemagglutination capacity and neuraminidase activity due to incorporation of PB1, HA and NA from A(H1N1)pdm09, in comparison with the recombinant virus incorporating only HA and NA from A(H1N1)pdm09 - which have the potential to improve current limitations regarding antigenicity and immunogenicity of influenza vaccines. Further knowledge of the complex vRNA-vRNA interaction network between PB1 and HA will additionally contribute to improve current vaccine formulation, and to gradually optimize the production of A(H1N1)pdm09 reverse genetics vaccine seed virus towards a higher cost-effectiveness.

2022-07-02Journal article

Restricted access

Adaptive evolution of PB1 from influenza A(H1N1)pdm09 virus towards an enhanced fitness

Publication . Santos, Luís A.; Almeida, Filipe; Gíria, Marta; Trigueiro-Louro, João; Rebelo-de-Andrade, Helena

PB1 influenza virus retain traces of interspecies transmission and adaptation. Previous phylogenetic analyses highlighted mutations L298I, R386K and I517V in PB1 to have putatively ameliorated the A(H1N1)pdm09 adaptation to the human host. This study aimed to evaluate the reversal of these mutations and infer the role of these residues in the virus overall fitness and adaptation. We generate PB1-mutated viruses introducing I298L, K386R and V517I mutations in PB1 and evaluate their phenotypic impact on viral growth and on antigen yield. We observed a decrease in viral growth accompanied by a reduction in hemagglutination titer and neuraminidase activity, in comparison with wt. Our data indicate that the adaptive evolution occurred in the PB1 leads to an improved overall viral fitness; and such biologic advantaged has the potential to be applied to the optimization of influenza vaccine seed prototypes.

2022-11-17Journal article

Restricted access

Unlocking COVID therapeutic targets: A structure-based rationale against SARS-CoV-2, SARS-CoV and MERS-CoV Spike

Publication . Trigueiro-Louro, João; Correia, Vanessa; Figueiredo-Nunes, Inês; Gíria, Marta; Rebelo-de-Andrade, Helena

There are no approved target therapeutics against SARS-CoV-2 or other beta-CoVs. The beta-CoV Spike protein is a promising target considering the critical role in viral infection and pathogenesis and its surface exposed features. We performed a structure-based strategy targeting highly conserved druggable regions resulting from a comprehensive large-scale sequence analysis and structural characterization of Spike domains across SARSr- and MERSr-CoVs. We have disclosed 28 main consensus druggable pockets within the Spike. The RBD and SD1 (S1 subunit); and the CR, HR1 and CH (S2 subunit) represent the most promising conserved druggable regions. Additionally, we have identified 181 new potential hot spot residues for the hSARSr-CoVs and 72 new hot spot residues for the SARSr- and MERSr-CoVs, which have not been described before in the literature. These sites/residues exhibit advantageous structural features for targeted molecular and pharmacological modulation. This study establishes the Spike as a promising anti-CoV target using an approach with a potential higher resilience to resistance development and directed to a broad spectrum of Beta-CoVs, including the new SARS-CoV-2 responsible for COVID-19. This research also provides a structure-based rationale for the design and discovery of chemical inhibitors, antibodies or other therapeutic modalities successfully targeting the Beta-CoV Spike protein.

2020-07-31Journal article

Open access