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1. Novel HIV-1 fusion peptide immunogens using glycan-engineered alphavirus-like particles

   https://doi.org/10.1101/2025.05.02.651772  

   Oh, Seo-Ho; Gudipati, Dedeepya R; Shi, Wei; Zhao, Peng; Wu, Winston; Boyington, Jeffrey C; Nariya, Hardik K; McGhee, Emily G; Azzam, Tala; Raghunathan, Vedhika; et al (May 2025, bioRxiv)

   Summary Immunofocusing on conserved, subdominant epitopes is critical for vaccines against highly diverse viruses such as HIV-1, influenza, and SARS-CoV-2. The eight-residue N-terminus of the HIV-1 fusion peptide (FP) is one such example of a promising yet small target. We developed new FP immunogens using three alphavirus-like particles (VLPs) and introduced additional glycans to mask shared carrier-specific epitopes. In two independent guinea pig studies, sequential immunization with heterologous carriers enhanced FP-directed antibody titers, which were further improved with glycan engineering. Separately, using diverse FP variants sharing the same N-terminal six amino acids increased neutralizing antibody titers. When combined, these two strategies led to higher FP-directed titers and, after Env trimer boosting, induced FP-directed neutralizing antibodies against multi-clade wild-type HIV-1 in nearly all animals. These findings established the importance of minimizing recurrent off-target epitopes across immunizations and support the engineered VLPs as a promising platform for peptide immunization. HighlightsNovel HIV-1 fusion peptide immunogens using glycan-engineered alphavirus-like particlesImproved FP-directed response by minimizing recurrent carrier-specific epitopes across immunizationsImproved neutralizing response by sequential immunization with diverse FP variantsFP-directed antibodies neutralizing multi-clade wildtype viruses in nearly all animals 

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2. Probabilities of developing HIV-1 bNAb sequence features in uninfected and chronically infected individuals

   https://doi.org/10.1038/s41467-023-42906-y  

   Kreer, Christoph; Lupo, Cosimo; Ercanoglu, Meryem S; Gieselmann, Lutz; Spisak, Natanael; Grossbach, Jan; Schlotz, Maike; Schommers, Philipp; Gruell, Henning; Dold, Leona; et al (December 2023, Nature Communications)

   Abstract HIV-1 broadly neutralizing antibodies (bNAbs) are able to suppress viremia and prevent infection. Their induction by vaccination is therefore a major goal. However, in contrast to antibodies that neutralize other pathogens, HIV-1-specific bNAbs frequently carry uncommon molecular characteristics that might prevent their induction. Here, we perform unbiased sequence analyses of B cell receptor repertoires from 57 uninfected and 46 chronically HIV-1- or HCV-infected individuals and learn probabilistic models to predict the likelihood of bNAb development. We formally show that lower probabilities for bNAbs are predictive of higher HIV-1 neutralization activity. Moreover, ranking bNAbs by their probabilities allows to identify highly potent antibodies with superior generation probabilities as preferential targets for vaccination approaches. Importantly, we find equal bNAb probabilities across infected and uninfected individuals. This implies that chronic infection is not a prerequisite for the generation of bNAbs, fostering the hope that HIV-1 vaccines can induce bNAb development in uninfected people. 

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3. Minimal framework for optimizing vaccination protocols targeting highly mutable pathogens

   https://doi.org/10.1103/PhysRevE.110.064137  

   Mahdisoltani, Saeed; Murugan, Pranav; Chakraborty, Arup K; Kardar, Mehran (December 2024, Physical Review E)

   A persistent public health challenge is identifying immunization schemes that are effective against highly mutable pathogens such as HIV and influenza viruses. To address this, we analyze a simplified model of affinity maturation, the Darwinian evolutionary process B cells undergo during immunization. The vaccination protocol determines the selection forces that steer affinity maturation to generate antibodies. We focus on identifying the optimal selection forces exerted by a generic time-dependent vaccination protocol to maximize the production of broadly neutralizing antibodies (bnAbs) that can protect against a broad spectrum of pathogen strains. The model utilizes a path integral representation and operator approximations within a mean-field limit and provides guiding principles for optimizing time-dependent vaccine-induced selection forces to enhance bnAb generation. We compare our analytical mean-field results with the outcomes of stochastic simulations, and we discuss their similarities and differences. 

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4. Design of an optimal combination therapy with broadly neutralizing antibodies to suppress HIV-1

   https://doi.org/10.7554/eLife.76004  

   LaMont, Colin; Otwinowski, Jakub; Vanshylla, Kanika; Gruell, Henning; Klein, Florian; Nourmohammad, Armita (July 2022, eLife)

   Infusion of broadly neutralizing antibodies (bNAbs) has shown promise as an alternative to anti-retroviral therapy against HIV. A key challenge is to suppress viral escape, which is more effectively achieved with a combination of bNAbs. Here, we propose a computational approach to predict the efficacy of a bNAb therapy based on the population genetics of HIV escape, which we parametrize using high-throughput HIV sequence data from bNAb-naive patients. By quantifying the mutational target size and the fitness cost of HIV-1 escape from bNAbs, we predict the distribution of rebound times in three clinical trials. We show that a cocktail of three bNAbs is necessary to effectively suppress viral escape, and predict the optimal composition of such bNAb cocktail. Our results offer a rational therapy design for HIV, and show how genetic data can be used to predict treatment outcomes and design new approaches to pathogenic control. 

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5. Combination adjuvant improves influenza virus immunity by downregulation of immune homeostasis genes in lymphocytes

   https://doi.org/10.1093/immhor/vlae007  

   Dollinger, Emmanuel; Hernandez-Davies, Jenny; Felgner, Jiin; Jain, Aarti; Hwang, Michael; Strahsburger, Erwin; Nakajima, Rie; Jasinskas, Algimantas; Nie, Qing; Pone, Egest James; et al (January 2025, ImmunoHorizons)

   Abstract Adjuvants play a central role in enhancing the immunogenicity of otherwise poorly immunogenic vaccine antigens. Combining adjuvants has the potential to enhance vaccine immunogenicity compared with single adjuvants, although the cellular and molecular mechanisms of combination adjuvants are not well understood. Using the influenza virus hemagglutinin H5 antigen, we define the immunological landscape of combining CpG and MPLA (TLR-9 and TLR-4 agonists, respectively) with a squalene nanoemulsion (AddaVax) using immunologic and transcriptomic profiling. Mice immunized and boosted with recombinant H5 in AddaVax, CpG+MPLA, or AddaVax plus CpG+MPLA (IVAX-1) produced comparable levels of neutralizing antibodies and were equally well protected against the H5N1 challenge. However, after challenge with H5N1 virus, H5/IVAX-1–immunized mice had 100- to 300-fold lower virus lung titers than mice receiving H5 in AddaVax or CpG+MPLA separately. Consistent with enhanced viral clearance, unsupervised expression analysis of draining lymph node cells revealed the combination adjuvant IVAX-1 significantly downregulated immune homeostasis genes, and induced higher numbers of antibody-producing plasmablasts than either AddaVax or CpG+MPLA. IVAX-1 was also more effective after single-dose administration than either AddaVax or CpG+MPLA. These data reveal a novel molecular framework for understanding the mechanisms of combination adjuvants, such as IVAX-1, and highlight their potential for the development of more effective vaccines against respiratory viruses. 

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