Up to 88 percent of the mice in the study remained tumor-free, and the team are now turning their attention to human cancers.

What is the Rhesus system for blood classification? #rhesus #bloodtypes #antigens #redbloodcell

A research team has introduced a novel cancer immunotherapy strategy. This approach involves attaching "fake targets" to tumor cells to guide immune cell attacks, overcoming the limitations of conventional antibody-based therapies.

In a groundbreaking development that promises to reshape the landscape of influenza vaccination, researchers have unveiled a novel vaccine that occupies a central position within the antigenic space of the A(H5) influenza virus. This innovative vaccine formulation is engineered to confer broad immunity across diverse strains of the highly pathogenic avian influenza H5 subtype, potentially offering a crucial tool in the ongoing battle against the threat posed by influenza zoonosis and pandemics. The meticulous phylogenetic analyses that underpin this advancement were enabled by leveraging comprehensive HA nucleotide sequences sourced from extensive global databases, ensuring the vaccine’s design harmonizes with the genetic diversity of circulating H5 viruses. Central to this achievement is the integration of an unparalleled dataset comprising nearly 15,000 hemagglutinin sequences from numerous H5 isolates worldwide. By employing sophisticated bioinformatics pipelines—including sequence deduplication, alignment via advanced algorithms like MAFFT, and maximum-likelihood phylogenetic tree construction via IQ-Tree2—the team systematically delineated the antigenic relationships within the H5 subtype. This approach, combined with cutting-edge computational tools for clade prediction, allowed researchers to pinpoint a vaccine candidate uniquely positioned to bridge antigenic variations across clades, enhancing cross-protective potential.   The cultivation and maintenance of requisite cellular models such as 293T and MDCK cells supported the intricate manipulations necessary for recombinant virus production. Optimized culture conditions maintained under precisely controlled environments ensured high-fidelity replication of viral vectors employed in the reverse genetics system. The rigorous plasmid construction process involved cloning HA and NA gene segments sourced from in-house viral isolates or synthesized genes with strategically altered cleavage sites, highlighting the ingenuity in viral engineering designed to attenuate pathogenicity while preserving immunogenic features. An essential ethical and collaborative aspect of the research was the adherence to equitable benefit-sharing agreements facilitated through GISAID. By committing to openly share synthetic constructs, recombinant viruses, and ferret sera with all contributing laboratories globally, the researchers fostered an ecosystem of transparency and reciprocity critical during a time when global health challenges necessitate unified scientific responses. This commitment underscores the role of international cooperation in accelerating the translation of genomic data into actionable vaccine solutions. Strict biosafety protocols underscored every aspect of the research. Work involving recombinant viruses harboring attenuating mutations was conducted under BSL2 conditions, whereas wild-type highly pathogenic avian influenza isolates received handling within BSL3 and ABSL3+ facilities. Such meticulous adherence to biosafety practices ensured the containment of infectious agents while enabling experimental progression, particularly in ferret challenge studies that evaluated vaccine efficacy under realistic infection scenarios.   The generation of recombinant influenza viruses through reverse genetics was pivotal to vaccine development, necessitating precise transfections and virus propagation in both cell culture and embryonated egg systems. Virus titration methods employing MDCK cells and hemagglutination assays provided robust measures of viral infectivity and antigen content, facilitating rigorous standardization of vaccine stocks. Sequencing confirmation of viral segments ensured genetic fidelity of constructs, crucial for reproducibility and safety. Vaccine production hinged on advanced purification techniques that enriched viral antigens whilst eliminating extraneous components. Through ultracentrifugation with sucrose gradients and subsequent solubilization, researchers isolated and processed whole-inactivated and split-inactivated vaccines that retained native antigenic configurations critical for eliciting effective immune responses. The quantification of hemagglutinin content employed mass spectrometry with stable isotope-labeled peptides, a gold-standard approach ensuring precise antigen dosing vital for immunogenic consistency. The experimental design extended to animal models, specifically ferrets, which serve as the gold standard for assessing influenza vaccine performance due to their physiologic and immunologic similarity to humans in respiratory viral infections. Through carefully controlled prime-boost vaccination regimens and subsequent challenges with wild-type recombinant viruses, the study generated comprehensive data on immune protection, viral shedding, and pathogenesis. The deployment of implanted temperature loggers and standardized clinical scoring permitted detailed monitoring of disease progression and vaccine efficacy, with downstream histopathological and immunohistochemical analyses elucidating the interplay between viral replication and host immune response. Serological assays, including hemagglutination inhibition and virus neutralization tests, constituted the cornerstone for gauging antibody-mediated immunity. These assays, performed with stringent controls and blinded assessments, quantified functional antibody titers against a panel of recombinant and wild-type viruses, thereby mapping the breadth of vaccine-induced protection. The precision of these assays underpins the robust correlates of immunity necessary for licensure pathways and public health application.   Beyond conventional methods, the research leveraged antigenic cartography—a powerful computational technique that translates serological data into multidimensional spatial maps—to visualize and interpret the antigenic relationships among H5 viruses and vaccine-induced sera. This approach illuminates how vaccination shifts the humoral immune landscape, providing insights into antigenic drift, vaccine coverage, and potential gaps in immunity. Such granularity is instrumental in preemptively guiding vaccine strain updates in response to viral evolution. In a nuanced exploration of viral receptor specificity, the research incorporated assays using resialylated turkey red blood cells engineered to express distinct sialic acid linkages. This enabled precise characterization of viral hemagglutinin binding preferences, information pivotal for understanding host range and transmission potential. Validation using control viruses ensured assay fidelity, thereby solidifying conclusions on the biological behavior of vaccine strains. The data visualization and statistical analyses underpinning the study were executed with state-of-the-art bioinformatics tools and rigorous statistical frameworks. Employing packages within the R environment for visualization and hypothesis testing, the study provided transparent and reproducible analytic workflows. Statistical stringency through non-parametric tests and correction for multiple comparisons further assured the reliability of findings, reinforcing confidence in the vaccine’s broad immunogenicity claim. Collectively, this research represents a tour de force in influenza vaccinology, combining genomics, virology, immunology, and computational biology to deliver a vaccine candidate strategically situated at the heart of H5 antigenic diversity. Its broad immune coverage portends a significant advance in pandemic preparedness, particularly given the propensity of H5 viruses to undergo antigenic shifts that challenge existing vaccine paradigms. The methodologies and collaborative ethos exemplified herein herald a new era wherein vaccine design is as much a product of bioinformatics and global data sharing as it is of traditional virological expertise.   Research published in Nature (Oct. 15, 2025): https://doi.org/10.1038/s41586-025-09626-3   

Tackling infections