ABSTRACT The risk of a respiratory viral pandemic is significant, including from the now widespread panzootic H5N1 influenza virus, highlighting the need for effective, stable, and inexpensive vaccine technologies that elicit strongly protective immunity. Intranasal vaccines can stimulate local immune responses at the site of natural respiratory viral infection, a key characteristic that can not only reduce morbidity and mortality caused by respiratory viruses but also potentially reduce viral transmissibility to limit outbreaks. Nucleic acid vaccines are now a valuable tool in pandemic responses, with high potency and rapid adaptability to target circulating or emerging viral strains; however, data are limited on which vaccine attributes are needed for efficient transmucosal delivery and immune stimulation following intranasal delivery. To demonstrate proof of concept, here we have developed a replicon vaccine expressing an H5 influenza antigen that uses a nanostructured lipid carrier (NLC) delivery system. A relationship was established between the molar ratio of positive charges on the NLC to the negative charges on the nucleic acid (N:P ratio) and the immunogenicity of the vaccine formulations, with higher N:P ratios resulting in an increase in vaccine immunogenicity. We demonstrated the ability of this replicon vaccine to be administered via intramuscular and intranasal routes with a singular vaccine formulation. The vaccine induced systemic immunity when dosed intramuscularly or intranasally in an immunocompetent mouse model, whereas intranasal dosing uniquely stimulated a strong mucosal immune response. Moreover, a mixed intramuscular/intranasal dosing strategy using this unified formulation stimulated a balanced systemic and mucosal immune response. Finally, we demonstrated the protective efficacy of this intranasally and intramuscularly/intranasally delivered H5 replicon-NLC vaccine against morbidity and mortality in a lethal H5N1 influenza challenge ferret model. This work establishes the replicon-NLC vaccine platform as a potential novel intranasal technology for rapid pandemic response.

As part of our work to develop small-molecule inhibitors (SMIs) of the CD40-CD40L(CD154) costimulatory protein-protein interaction, here, we describe the ability of two of our most promising SMIs, DRI-C21041 and DRI-C21095, to prolong the survival and function of islet allografts in two murine models of islet transplantation (under the kidney capsule and in the anterior chamber of the eye) and to prevent autoimmune type 1 diabetes (T1D) onset in NOD mice. In both transplant models, a significant portion of islet allografts (50%-80%) remained intact and functional long after terminating treatment, suggesting the possibility of inducing operational immune tolerance via inhibition of the CD40-CD40L axis. SMI-treated mice maintained the structural integrity and function of their islet allografts with concomitant reduction in immune cell infiltration as evidenced by direct longitudinal imaging in situ. Furthermore, in female NODs, three-month SMI treatment reduced the incidence of diabetes from 80% to 60% (DRI-C21041) and 25% (DRI-C21095). These results (i) demonstrate the susceptibility of this TNF superfamily protein-protein interaction to small-molecule inhibition, (ii) confirm the in vivo therapeutic potential of these SMIs of a critical immune checkpoint, and (iii) reaffirm the therapeutic promise of CD40-CD40L blockade in islet transplantation and T1D prevention. Thus, CD40L-targeting SMIs could ultimately lead to alternative immunomodulatory therapeutics for transplant recipients and prevention of autoimmune diseases that are safer, less immunogenic, more controllable (shorter half-lives), and more patient-friendly (i.e., suitable for oral administration, which makes them easier to administer) than corresponding antibody-based interventions.
Copyright © 2024 Chuang, Alcazar, Watts, Abdulreda and Buchwald.

Influenza viruses pose a threat to public health as evidenced by severe morbidity and mortality in humans on a yearly basis. Given the constant changes in the viral glycoproteins owing to antigenic drift, seasonal influenza vaccines need to be updated periodically and effectiveness often drops due to mismatches between vaccine and circulating strains. In addition, seasonal influenza vaccines are not protective against antigenically shifted influenza viruses with pandemic potential. Here, we have developed a highly immunogenic vaccination regimen based on live-attenuated influenza vaccines (LAIVs) comprised of an attenuated virus backbone lacking non-structural protein 1 (ΔNS1), the primary host interferon antagonist of influenza viruses, with chimeric hemagglutinins (cHA) composed of exotic avian head domains with a highly conserved stalk domain, to redirect the humoral response towards the HA stalk. In this study, we showed that cHA-LAIV vaccines induce robust serum and mucosal responses against group 1 stalk and confer antibody-dependent cell cytotoxicity activity. Mice that intranasally received cH8/1-ΔNS1 followed by a cH11/1-ΔNS1 heterologous booster had robust humoral responses for influenza A virus group 1 HAs and were protected from seasonal H1N1 influenza virus and heterologous highly pathogenic avian H5N1 lethal challenges. When compared with mice immunized with the standard of care or cold-adapted cHA-LAIV, cHA-ΔNS1 immunized mice had robust antigen-specific CD8+ T-cell responses which also correlated with markedly reduced lung pathology post-challenge. These observations support the development of a trivalent universal influenza vaccine for the protection against group 1 and group 2 influenza A viruses and influenza B viruses.
© 2024. The Author(s).

The intake of dietary phosphate far exceeds recommended levels; however, the long-term health consequences remain relatively unknown. Here, the chronic physiological response to sustained elevated and reduced dietary phosphate consumption was investigated in mice. Although serum phosphate levels were brought into homeostatic balance, the prolonged intake of a high-phosphate diet dramatically and negatively impacted bone volume; generated a sustained increase in the phosphate responsive circulating factors FGF23, PTH, osteopontin and osteocalcin; and produced a chronic low-grade inflammatory state in the BM, marked by increased numbers of T cells expressing IL-17a, RANKL, and TNF-α. In contrast, a low-phosphate diet preserved trabecular bone while increasing cortical bone volume over time, and it reduced inflammatory T cell populations. Cell-based studies identified a direct response of T cells to elevated extracellular phosphate. Neutralizing antibodies against proosteoclastic cytokines RANKL, TNF-α, and IL-17a blunted the high-phosphate diet-induced bone loss identifying bone resorption as a regulatory mechanism. Collectively, this study illuminates that habitual consumption of a high-phosphate diet in mice induces chronic inflammation in bone, even in the absence of elevated serum phosphate. Furthermore, the study supports the concept that a reduced phosphate diet may be a simple yet effective strategy to reduce inflammation and improve bone health during aging.

While mRNA vaccines have been highly effective over the past 2 years in combating severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), waning of vaccine-induced antibody responses and lack of induction of respiratory tract immunity contribute to ongoing infection and transmission. However, intranasally (i.n.) administered vaccines may induce mucosal immunity at the site of respiratory virus infection and may thus boost protection. In this work, we present an i.n. administered SARS-CoV-2 self-amplifying RNA (saRNA) vaccine, delivered by a nanostructured lipid carrier (NLC), which induces both potent respiratory mucosal and systemic immune responses. Following prime-boost immunization in C57BL/6 mice, i.n. vaccination induces serum neutralizing antibody titers, bone marrow resident IgG-secreting cells, and robust systemic polyfunctional T cells, similar to intramuscular (i.m.) vaccination. The intranasal vaccine additionally induces key SARS-CoV-2-reactive lung-resident polyfunctional memory and lung-homing T cell populations. As a booster following i.m. administration, the i.n. vaccine also elicits robust mucosal and systemic immunity, exceeding an i.m. booster, durable for at least 4 months. This i.n. saRNA vaccine’s potent mucosal and systemic immunogenicity may be key for combating SARS-CoV-2 and other respiratory pathogens.