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An enantiomer-dependent and modification-free DNA matrix as a novel adjuvant platform for subunit vaccines

ABSTRACT: We introduce a novel dynamic DNA supramolecular matrix material assembled from five unmodified, short DNA strands, serving as a safe and effective adjuvant platform. Our findings demonstrate that this DNA matrix material elicits robust humoral response in an enantiomer-dependent but CpG-independent manner, effectively generating potent neutralizing antibodies and conferring robust protection against diverse pathogen infections, including both SARS-CoV-2 and Streptococcus pneumoniae. Remarkably, DNA matrix exhibits minimal adverse effects in comparison to the commonly used aluminum material. In stark contrast to its soluble DNA components, the dynamic colloidal feature of DNA matrix material prolongs the in vivo retention of both DNA and antigen by spontaneously disintegrating into nanoparticles in hundreds of nanometers range, facilitating lymphatic-targeted transportation and accumulation. This process leads to a robust pro-inflammatory response in both vaccinated local tissue and draining lymph node (dLN), which in turn promotes the recruitment and activation of diverse immune cells, ultimately leading to a rapid and robust antigen-specific antibody response. Surprisingly, mechanistic investigation uncovers that the enhancing function of this DNA matrix material is not dependent on DNA-sensor machineries including cGAS, ZBP1, AIM2 and STING, relying instead on the TLR9-MyD88 signaling axis. Cell-lineage specific MyD88 knockout experiments underscore the critical role of this axis in DCs, but not in B cells and keratinocytes. Unexpectedly, the antibody-enhancing function of this DNA matrix material is also strongly dependent on the right-handed chirality of the building block DNA strands, forming D-DNA matrix. In marked contrast, the left-handed L-DNA matrix, despite inheriting identical physiochemical properties as a material and the ability to disintegrate into nanoparticles as D-DNA matrix, completely fails to promote immune activations in vitro and in vivo. Thus, this injectable, self-assembling, CpG- and modification-free DNA matrix material functions as a novel, all-in-one subunit vaccine adjuvant platform, opening up promising avenues in next-generation vaccine design.

ORGANISM(S): Mus musculus

PROVIDER: GSE290067 | GEO | 2025/04/04

REPOSITORIES: GEO

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Project description:Authorization of the Matrix-M-adjuvanted R21 vaccine by three countries and its subsequent endorsement by the World Health Organization (WHO) for malaria prevention in children is a milestone in the fight against malaria. Yet, to meet the unprecedented demand for malarial vaccines, there is a pressing need for additional adjuvants that induce robust and durable vaccine-induced immunity. Here, we performed a comparative assessment of three clinically relevant adjuvants (an alum formulation of the TLR7/8 agonist 3M-052 (3M-052+Alum), the TLR4 agonist GLA-LSQ (GLA in liposome QS-21 formulation), and Matrix-M, the currently approved adjuvant for R21) for their capacity to induce durable immune responses to the R21 malaria vaccine in non-human primates. Immunization of macaques with R21 adjuvanted with 3M-052+Alum on a 0, 8, and 24-week schedule elicited anti-circumsporozoite antibody responses comparable in magnitude to the R21/Matrix-M vaccine and persisted up to 72 weeks with a half-life of 337 (264 – 459) days. A booster dose at 72 weeks induced an antigen-specific recall response, similar to the R21/Matrix-M vaccination. In contrast, R21/GLA-LSQ immunization induced a considerably lower and short-lived response. Consistent with the durability of serum antibody responses, Matrix-M and 3M-052+Alum induced long-lived plasma cells in the bone marrow and other tissues, including the spleen, but GLA-LSQ stimulated only short-lived plasmablasts. Finally, we show distinct innate immune signatures early after vaccination with these adjuvants. While 3M-052+Alum stimulated potent and persistent antiviral transcriptional and cytokine signatures after primary and booster immunizations, Matrix-M induced an enhanced expression of interferon- and Th2-related signatures more highly after the booster vaccination. Collectively, these findings provide a comparative database on the immune responses of three clinically relevant adjuvants with R21 and highlight the promise of 3M-052+Alum as an additional adjuvant for the R21 malaria vaccine.

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An enantiomer-dependent and modification-free DNA matrix as a novel adjuvant platform for subunit vaccines

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