The SARS-CoV-2 pandemic highlighted the potential of mRNA vaccines in rapidly responding to emerging pathogens. However, immunity induced by conventional mRNA vaccines wanes quickly, requiring frequent boosters. Self-amplifying RNA (saRNA) vaccines, which extend antigen expression via self-replication, offer a promising strategy to induce more durable immune responses. In this study, we developed an saRNA vaccine encoding Zika virus (ZIKV) membrane and envelope proteins and evaluated its efficacy in mice. A single vaccination elicited strong humoral and cellular immune responses and reduced viral loads but only for 28 days. By day 84, antibody titers and T cell responses had significantly declined, resulting in reduced efficacy. To address this, we evaluated agonist antibodies targeting the T cell costimulatory molecules OX40 and 4-1BB. Coadministration of agonist antibodies enhanced CD8+ T cell responses to vaccination, resulting in sustained immunity and reduced viral loads at day 84. Depletion and passive transfer studies verified that long-term antiviral immunity was primarily CD8+ T cell dependent, with minimal contributions from antibody responses. These findings suggest that agonists targeting members of the tumor necrosis receptor superfamily, such as OX40 and 4-1BB, might enhance the durability of saRNA vaccine-induced protection, addressing a key limitation of current mRNA vaccine platforms.

Chimeric antigen receptor (CAR) T cell immunotherapy relies on CAR targeting of tumor-associated antigens; however, heterogenous antigen expression, interpatient variation and off-tumor expression by healthy cells remain barriers. Here we develop synthetic antigens to sensitize solid tumors for recognition and elimination by CAR T cells. Unlike tumor-associated antigens, we design synthetic antigens that are orthogonal to endogenous proteins to eliminate off-tumor targeting and that have a small genetic footprint to facilitate efficient tumor delivery to tumors by lipid nanoparticles. Using a camelid single-domain antibody (VHH) as a synthetic antigen, we show that adoptive transfer of anti-VHH CAR T cells to female mice bearing VHH-expressing tumors reduced tumor burden in multiple syngeneic and xenograft models of cancer, improved survival, induced epitope spread, protected against tumor rechallenge and mitigated antigen escape in heterogenous tumors. Our work supports the in situ delivery of synthetic antigens to treat antigen-low or antigen-negative tumors with CAR T cells.

Chimeric antigen receptor (CAR)-engineered immune cell therapy represents an important advance in cancer treatments. However, the complex ex vivo cell manufacturing process and stringent patient selection criteria curtail its widespread use. In vivo CAR engineering is emerging as a promising off-the-shelf therapy, providing advantages such as streamlined production, elimination of patient-specific manufacturing, reduced costs and simplified logistics. A large set of preclinical findings has inspired further investigation into treatments for hard-to-treat diseases such as solid tumours and has facilitated the development of advanced products to enhance in vivo CAR engineering efficacy, the persistence of the cellular therapeutic and safety. In this Review, we summarize current in vivo CAR engineering strategies, including nanoparticle-based and viral delivery systems as well as bioinstructive implantable scaffolds, and discuss their advantages and disadvantages. Additionally, we provide a systematic comparison between in vivo and conventional ex vivo CAR engineering methods and address the challenges and future prospects of in vivo CAR engineering.

The COVID-19 pandemic has emphasized the potential of mRNA vaccines in fighting pandemics, owing to their rapid development, strong immunogenicity and adaptability. However, a drawback is their dose-limiting reactogenicity and inability to generate durable humoral immunity. Here we introduce a modular nucleotide vaccine platform combining the advantages of genetic and capsid virus-like-particle-based vaccines. This platform allows for the display of various antigens on different capsid virus-like particles, improving the magnitude, quality and longevity of the vaccine-induced immune responses. We applied this technology to enhance the immunogenicity of the Pfs25 antigen. Immunization with lipid-nanoparticle-formulated mRNA encoding Pfs25 capsid virus-like particles resulted in higher and potentially more durable anti-Pfs25 antibody responses, along with enhanced functional activity, compared with an mRNA vaccine encoding soluble Pfs25. By improving both humoral and cellular immune responses, this approach may reduce the dose and number of administrations required for effective protection. As a result, it can improve the feasibility of both DNA- and mRNA-based vaccines targeting pandemic and endemic infectious diseases.

Neurodegenerative diseases (NDD) are characterized by the progressive loss of neurons and the impairment of cellular functions. Messenger RNA (mRNA) has emerged as a promising therapy for treating NDD, as it can encode missing or dysfunctional proteins and anti-inflammatory cytokines or neuroprotective proteins to halt the progression of these diseases. However, effective mRNA delivery to the central nervous system (CNS) remains a significant challenge due to the limited penetration of the blood-brain barrier (BBB). Lipid nanoparticles (LNPs) offer an efficient solution by encapsulating and protecting mRNA, facilitating transfection and intracellular delivery. This review discusses the pathophysiological mechanisms of neurological disorders, including Parkinson's disease (PD), Alzheimer's disease (AD), multiple sclerosis (MS), Huntington's disease (HD), ischemic stroke, spinal cord injury, and Friedreich's ataxia. Additionally, it explores the potential of LNP-mediated mRNA delivery as a therapeutic strategy for these diseases. Various approaches to overcoming BBB-related challenges and enhancing the delivery and efficacy of mRNA-LNPs are discussed, including non-invasive methods with strong potential for clinical translation. With advancements in artificial intelligence (AI)-guided mRNA and LNP design, targeted delivery, gene editing, and CAR-T cell therapy, mRNA-LNPs could significantly transform the treatment landscape for NDD, paving the way for future clinical applications.

The Sudan virus (SUDV) outbreaks in Uganda in 2022 and 2025 created public health concerns in-country and the entire East African region. There are currently no licensed countermeasures against SUDV. We developed a SUDV vaccine candidate based on a nanocarrier (LIONTM) complexed with an alphavirus-based replicon RNA. Here, we compare the protective efficacy of the LION-SUDV vaccine either encoding the SUDV glycoprotein (GP) alone or in combination with the Ebola virus (EBOV) GP (LION-Combination). A LION-EBOV vaccine which is protective against EBOV was also included to determine the potential for cross-protection against SUDV infection. Single-dose vaccinations were conducted three weeks before challenge with a lethal dose of guinea pig-adapted SUDV using a female guinea pig disease model. We demonstrate 100% survival and protection with the LION-SUDV and the LION-Combination vaccines, while the LION-EBOV vaccine achieved 50% protection. Antigen-specific humoral responses correlate with decreased virus replication and survival. This result warrants further studies in larger animal species to ensure that protective efficacy is maintained with the single-dose LION-SUDV vaccine.

The use of modified nucleotides to suppress the interferon response and maintain translation of self-amplifying RNA (saRNA), which has been achieved for mRNA, has not yet succeeded. We identify modified nucleotides that, when substituted at 100% in saRNA, confer innate immune evasion and robust long-term protein expression, and when formulated as a vaccine, protect against lethal SARS-CoV-2 challenge in mice. This discovery advances saRNA therapeutics by enabling prolonged protein expression at low doses.

The rapid emergence and evolution of infectious pathogens, including the COVID-19 pandemic and recurring influenza outbreaks, underscore the need for universal vaccines capable of providing broad-spectrum immunity. Messenger ribonucleic acid (mRNA) vaccine technology has emerged as a transformative platform due to its rapid development, high immunogenicity, and adaptability to new variants. Unlike conventional vaccines, which rely on weakened or inactivated pathogens, mRNA vaccines instruct host cells to produce antigens that elicit robust immune responses. This paper explores the design principles, mechanisms of action, and advancements in mRNA-based universal vaccines, emphasizing their potential against influenza, coronaviruses, and antimicrobial-resistant pathogens. We discuss innovations such as self-amplifying mRNA (saRNA), nanoparticle-based delivery systems, and artificial intelligence (AI)-driven antigen selection. Additionally, challenges such as antigenic variability, immune evasion, stability issues, and global distribution barriers are addressed. With continued research and development, mRNA-based universal vaccines could play a critical role in pandemic preparedness and global health security.

Yellow fever (YFV) and Zika (ZIKV) viruses cause significant morbidity and mortality, despite the existence of an approved YFV vaccine and the development of multiple ZIKV vaccine candidates to date. New technologies may improve access to vaccines against these pathogens. We previously described a nanostructured lipid carrier (NLC)-delivered self-amplifying RNA (saRNA) vaccine platform with excellent thermostability and immunogenicity, appropriate for prevention of tropical infectious diseases.

YFV and ZIKV prM-E antigen-expressing saRNA constructs were created using a TC-83 strain Venezuelan equine encephalitis virus-based replicon and complexed with NLC by simple mixing. Monovalent and bivalent vaccine formulations were injected intramuscularly into C57BL/6 mice and Syrian golden hamsters, and the magnitude, durability, and protective efficacy of the resulting immune responses were then characterized.

Monovalent vaccines established durable neutralizing antibody responses to their respective flaviviral targets, with little evidence of cross-neutralization. Both vaccines additionally elicited robust antigen-reactive CD4+ and CD8+ T cell populations. Notably, humoral responses to YFV saRNA-NLC vaccination were comparable to those in YF-17D-vaccinated animals. Bivalent formulations established humoral and cellular responses against both viral targets, commensurate to those established by monovalent vaccines, without evidence of saRNA interference or immune competition. Finally, both monovalent and bivalent vaccines completely protected mice and hamsters against lethal ZIKV and YFV challenge. We present a bivalent saRNA-NLC vaccine against YFV and ZIKV capable of inducing robust and efficacious neutralizing antibody and cellular immune responses against both viruses. These data support the development of other multivalent saRNA-based vaccines against infectious diseases.

Messenger RNA (mRNA) vaccines have emerged as one of the most promising and rapidly evolving immunotherapeutic approaches due to their ease of production, demonstrated clinical efficacy, and high safety. The coronavirus disease 2019(COVID-19) pandemic has showcased the remarkable therapeutic potential of mRNA vaccines, prompting researchers to explore their use for cancer treatment. Preclinical studies and human clinical trials have indicated their substantial clinical applicability. However, current research faces several challenges, including the complexity of tumor antigen selection, vaccine stability, and the development of resistance. This review summarizes the optimization strategies for cancer mRNA vaccines in preclinical settings, the progress of clinical trials, and the challenges encountered while analyzing various delivery vehicle types, infusion methods, and application cases across different cancer types, highlighting key factors in vaccine design. The findings demonstrate that mRNA vaccines elicit specific immune responses and exhibit favorable safety and tolerability in clinical trials. Moreover, developing personalized neoantigen vaccines offers a novel direction for cancer immunotherapy. The unique contribution of this review lies in its comprehensive overview of the latest advancements in therapeutic mRNA vaccines for cancer treatment while identifying critical areas for future research to propel the field forward.

Replicon RNA (RepRNA) represents a cutting-edge technology in the field of vaccinology, fundamentally transforming vaccine design and development. This innovative approach facilitates the induction of robust immune responses against a range of infectious diseases and cancers. RepRNA vaccines leverage the inherent capabilities of RNA-dependent RNA polymerase associated with self-replicating repRNA, allowing for extreme replication within host cells. This process enhances antigen production and subsequently stimulates adaptive immunity. Additionally, the generation of double-stranded RNA during RNA replication can activate innate immune responses. Numerous studies have demonstrated that repRNA vaccines elicit potent humoral and cellular immune responses that are broader and more durable than those generated by conventional mRNA vaccines. These significant immune responses have been shown to provide protection in various models for infectious diseases and cancers. This article will explore the design and delivery of RepRNA vaccines, the mechanisms of immune activation, preclinical studies addressing infectious diseases and tumors, and related clinical trials that focus on safety and immunogenicity.

A novel self-amplifying mRNA (samRNA) amplification mechanism was first discovered in the SARS-CoV-2 replication-transcription system and named replicase cycling reaction (RCR). In principle, RCR is a replicase-mediated transcription reaction driven by the SARS-CoV-2 RNA-dependent RNA polymerases (RdRPs), which amplify a specific samRNA construct consisting of an RNA/mRNA sequence flanked by a 5'-end RdRP-reverse-promoter (5'-RdRP-RP) and a 3'-end RdRP-forward-promoter (3'-RdRP-FP) on both sides. Based on this samRNA composition, we had not only successfully established the first in-vitro RCR reaction for directly amplifying the SARS-CoV-2 genomic and subgenomic RNAs but also further used it in a combined in-vitro-transcription and RCR (IVT-RCR) protocol to identify new functions of the SARS-CoV-2 NSP7, NSP8, and NSP12 proteins, leading to a fast diagnostic assay for measuring the SARS-CoV-2 RdRP activity. These findings may shed a new light on the molecular mechanisms of SARS-CoV-2 replication and transcription. As a result, in addition to the previously found primer-dependent RNA synthesis activity of the coronaviral RdRP complexes, we herein reported another new 5'/3'-promoter-dependent, primer-independent samRNA synthesis mechanism mediated by the SARS-CoV-2 RdRP complex. Based on this novel RCR mechanism, the associated samRNA composition is conceivably useful for facilitating the design and development of next-generation RNA/mRNA medicines and vaccines.

Messenger RNA (mRNA) delivered in lipid nanoparticles (LNPs) rose to the forefront of vaccine candidates during the COVID-19 pandemic due to scalability, adaptability, and potency. Yet, there remain critical areas for improvements of these vaccines in durability and breadth of humoral responses. In this work, we explore a modular strategy to target mRNA/LNPs to antigen-presenting cells with an injectable polymer-nanoparticle (PNP) hydrogel technology, which recruits key immune cells and forms an immunological niche in vivo. We characterize this niche on a single-cell level and find it is highly tunable through incorporation of adjuvants like MPLAs and 3M-052. Delivering commercially available severe acute respiratory syndrome coronavirus 2 mRNA vaccines in PNP hydrogels improves the durability and quality of germinal center reactions, and the magnitude, breadth, and durability of humoral responses. The tunable immune niche formed within PNP hydrogels effectively skews immune responses based on encapsulated adjuvants, creating opportunities to precisely modulate mRNA/LNP vaccines for various indications from infectious diseases to cancers.

Since the introduction of the first licensed mRNA-based vaccines against COVID-19, there has been significant interest in leveraging this technology for other vaccines. An unprecedented surge of mRNA vaccines has emerged in preclinical, clinical, and various research phases since 2020. The rapid development of mRNA formulations, delivery methods, and manufacturing processes has made this trend foreseeable. There is an urgent demand for effective and easily transportable vaccines in regions where the virus is prevalent, and mRNA technology shows promise in addressing this need.

The data was retrieved from various databases, including Google Scholar, PubMed, Science Direct, ClinicalTrials.gov, and government websites. The following terms were used in the search strategies: HIV, vaccines, mRNA vaccines, clinical trials, and preclinical trials. A total of 35 articles were identified and subsequently screened for data regarding mRNA vaccines for HIV.

mRNA vaccines are an effective solution for HIV treatment, as demonstrated by various research studies referenced in the article.

This review evaluates the current state of HIV-1 mRNA vaccine development, clarifies various targeting strategies, highlights recent research findings, and provides insights into the challenges and potential solutions associated with these issues. In this review, we have explored mRNA vaccines, focusing on their functional structure, design, manufacturing, and distribution methodologies.

Self-amplifying RNA (saRNA) technology is an emerging platform for vaccine development, offering significant advantages over conventional mRNA vaccines. By enabling intracellular amplification of RNA, saRNA facilitates robust antigen expression at lower doses, thereby enhancing both immunogenicity and cost-effectiveness. This review examines the latest advancements in saRNA vaccine development, highlighting its applications in combating infectious diseases. This includes viral pathogens such as SARS-CoV-2, influenza, and emerging zoonotic threats. We discuss the design and optimization of saRNA vectors to maximize antigen expression while minimizing adverse immune responses. Recent studies demonstrating the safety, efficacy, and scalability of saRNA-based vaccines in clinical settings are also discussed. We address challenges related to delivery systems, stability, and manufacturing, along with novel strategies being developed to mitigate these challenges. As the global demand for rapid, flexible, and scalable vaccine platforms grows, saRNA presents a promising solution with enhanced potency and durability. This review emphasizes the transformative potential of saRNA vaccines to shape the future of immunization strategies, particularly in response to pandemics and other global health threats.

Over the past few decades, there has been significant advancement in the field of tumor immunotherapy. For many years vaccination against infectious diseases have been available. On the other hand very few cancer vaccines have been approved for human use. Ideal Cancer vaccines are biological response modifier work by stimulating both humoral and cellular immunity while overcoming the immunological suppression found in tumor. Two types of cancer vaccine: Prophylactic and therapeutic cancer vaccines are recommended for clinical use of individuals. HPV and HBV vaccines are the two widely used preventive vaccine used for treatment of cervical and hepatocellular carcinoma respectively and are approved by Food and Drug Administration (FDA). In therapeutic vaccine only three are approved: Sipuleucel T-cell vaccine for treatment refractory prostatic cancer, BCG vaccine for early bladder cancer and T-VEC for inoperable melanoma. Active ingredient in all cancer vaccines is an antigen. Antigens used for formulating cancer vaccines along with adjuvants optimizes immunogenicity in it. Heterogeneity within and between cancer types, screening and identifying suitable antigen specific to tumors and selection of vaccine delivery platforms are challenges in the development of vaccines. Adoptive cell therapy, Chimeric antigen receptor T cell therapy are recent breakthrough for cancer treatment.

mRNA therapeutics are emerging as a transformative approach in modern medicine, providing innovative, highly adaptable solutions for a wide range of diseases, from viral infections to cancer. Since the approval of the first mRNA therapeutic-the coronavirus disease 2019 vaccines in 2021-we have identified more than 70 current clinical trials utilizing mRNA for various diseases. We propose classifying mRNA therapeutics into four main categories: vaccines, protein replacement therapies, antibodies, and mRNA-based cell and gene therapies. Each category can be further divided into subcategories. Vaccines include those targeting viral antigens, bacterial or parasitic antigens, general and individualized cancer antigens, and self-antigens. Protein replacement therapies include maintenance therapeutics designed to treat genetic disorders and interventional therapeutics, where delivering therapeutic proteins could improve patient outcomes, such as vascular endothelial growth factor A for ischemic heart disease or proinflammatory cytokines in cancer. Therapeutic antibodies are based on mRNA sequences encoding the heavy and light chains of clinically relevant antibodies, enabling patient cells to produce them directly, bypassing the costly and complex process of manufacturing protein-ready antibodies. Another category of mRNA-based therapeutics encompasses cell and gene therapies, including CRISPR with mRNA-mediated delivery of Cas9 and the in vivo generation of cells expressing CAR through mRNA. We discuss examples of mRNA therapeutics currently in clinical trials within each category, providing a comprehensive overview of the field's progress and highlighting key advancements as of the end of 2024.

Vaccination strategies play a pivotal role in achieving broad and robust immune protection. With the advent of new technologies and challenges posed by emerging infectious diseases such as SARS-CoV-2, evaluating the efficacy of homologous (matching tracks) and heterologous (mixing paths) vaccination regimens is critical. This article explores mechanistic insights and empirical evidence on the benefits and limitations of these approaches.

mRNA vaccines utilize single-stranded linear DNA as a template for in vitro transcription. The mRNA is introduced into the cytoplasm via the corresponding delivery system to express the target protein, which then performs its relevant biological function. mRNA vaccines are beneficial in various fields, including cancer vaccines, infectious disease vaccines, protein replacement therapy, and treatment of rare diseases. They offer advantages such as a simple manufacturing process, a quick development cycle, and ease of industrialization. Additionally, mRNA vaccines afford flexibility in adjusting antigen designs and combining sequences of multiple variants, thereby addressing the issue of frequent mutations in pathogenic microorganisms. This paper aims to provide an extensive review of the global development and current research status of mRNA vaccines, with a focus on immunogenicity, classification, design, delivery vector development, stability, and biomedical application. Moreover, the study highlights current challenges and offers insights into future directions for development.

Oropouche virus (OROV), an emerging arbovirus, poses a significant public health challenge in tropical and subtropical regions, with no licensed vaccines or antiviral therapies currently available. This review explores recent advancements in therapeutic strategies and vaccine development for OROV, focusing on molecular mechanisms of viral replication, identification of potential antiviral targets, and the role of immunotherapy in managing infections. Promising antiviral candidates, including ribavirin, mycophenolic acid, and interferon, have demonstrated efficacy in in vitro studies, offering a foundation for further investigation. The challenges of preclinical and clinical development, such as high mutation rates, immune response variability, and vaccine delivery hurdles, are critically analyzed. By addressing the progress and remaining gaps, this article aims to provide a comprehensive overview to inform future research and facilitate the development of effective antiviral strategies and vaccines for OROV.

Nanotechnology involves the utilization of materials with exceptional properties at the nanoscale. Over the past few years, nanotechnologies have demonstrated significant potential in improving human health, particularly in medical treatments. The self-assembly characteristic of RNA is a highly effective method for designing and constructing nanostructures using a combination of biological, chemical, and physical techniques from different fields. There is great potential for the application of RNA nanotechnology in therapeutics. This review explores various nano-based drug delivery systems and their unique features through the impressive progress of the RNA field and their significant therapeutic promises due to their unique performance in the COVID-19 pandemic. However, a significant hurdle in fully harnessing the power of RNA drugs lies in effectively delivering RNA to precise organs and tissues, a critical factor for achieving therapeutic effectiveness, minimizing side effects, and optimizing treatment outcomes. There have been many efforts to pursue targeting, but the clinical translation of RNA drugs has been hindered by the lack of clear guidelines and shared understanding. A comprehensive understanding of various principles is essential to develop vaccines using nucleic acids and nanomedicine successfully. These include mechanisms of immune responses, functions of nucleic acids, nanotechnology, and vaccinations. Regarding this matter, the aim of this review is to revisit the fundamental principles of the immune system's function, vaccination, nanotechnology, and drug delivery in relation to the creation and manufacturing of vaccines utilizing nanotechnology and nucleic acids. RNA drugs have demonstrated significant potential in treating a wide range of diseases in both clinical and preclinical research. One of the reasons is their capacity to regulate gene expression and manage protein production efficiently. Different methods, like modifying chemicals, connecting ligands, and utilizing nanotechnology, have been essential in enabling the effective use of RNA-based treatments in medical environments. The article reviews stimuli-responsive nanotechnologies for RNA delivery and their potential in RNA medicines. It emphasizes the notable benefits of these technologies in improving the effectiveness of RNA and targeting specific cells and organs. This review offers a comprehensive analysis of different RNA drugs and how they work to produce therapeutic benefits. Recent progress in using RNA-based drugs, especially mRNA treatments, has shown that targeted delivery methods work well in medical treatments.

Generating antibodies targeting native membrane proteins presents various challenges because these proteins are often embedded in the lipid bilayer, possess various extracellular and intracellular domains, and undergo post-translational modifications. These properties of MPs make it challenging to preserve their stable native conformations for immunization or antibody generation outside of the membranes. In addition, MPs are often hydrophobic due to their membrane-spanning regions, making them difficult to solubilize and purify in their native form. Therefore, employing purified MPs for immunogen preparation may result in denaturation or the loss of native structure, rendering them inadequate for producing antibodies recognizing native conformations. Despite these obstacles, various new approaches have emerged to address these problems. We outline recent advancements in designing and preparing immunogens to produce antibodies targeting MPs. Strategies outlined here are relevant for producing antibodies for research, diagnostics, and therapies and designing immunogens for vaccination purposes.

Self-amplifying RNA (saRNA) vectors are a next-generation RNA technology that extends the expression of heterologous genes. Clinical trials have shown the dose-sparing capacity of saRNA vectors in a vaccine context compared with conventional messenger RNA. However, saRNA vectors have historically been based on a limited number of alphaviruses, and only the Venezuelan equine encephalitis virus-based saRNA vaccines have been used clinically. Here, we designed genotypically distinct alphaviral saRNA vectors and characterized their performance in mammalian cell lines, human skin explants and mice. Five of the 12 vectors had substantial luciferase expression in mice with variable pharmacokinetics, enabling modulation of both the magnitude and duration of protein expression. Additionally, we demonstrated that the alphaviral genotype of the saRNA significantly impacts the immunogenicity of saRNA vaccines, including the humoral and cellular responses in mice. Given the differences in RNA reactogenicity and expression between mice and humans, we assessed the saRNA vectors in human skin explants obtained from patients and observed high transgene expression. saRNA bioluminescence and immunogenicity in different mice strains were highly correlative, while minimal correlation was observed when compared with human explants and mammalian cell lines. This work demonstrates that efficacious saRNA vaccines and therapies can be produced by adapting genetically diverse alphaviruses into vectors.

Respiratory syncytial virus (RSV) represents a significant threat, being a primary cause of critical lower respiratory tract infections and fatalities among infants and the elderly worldwide, and poses a challenge to global public health. This urgent public health challenge necessitates the swift development of safe and effective vaccines capable of eliciting robust immune responses at low doses. Addressing this need, our study investigated five self-amplifying mRNA (sa-mRNA) candidate vaccines that encode the various pre-fusion conformations of the RSV fusion protein. When administered via low-dose intramuscular injection to 8-month-old elderly mice, these vaccines triggered potent humoral reactions and T helper type 1-biased cellular immunity. A prime-boost strategy followed by challenge with a lethal, mouse-adapted RSV strain showed that three of these sa-mRNA candidates achieved greater than 80% survival rates. An immune correlates of protection analysis contrasting immunized survivors with non-survivors suggest that the titers of IgG and neutralizing antibody are associated with vaccine-mediated protection from RSV infection. Our results highlight the usefulness of sa-mRNA vaccines to play a crucial role in forging an effective defense against RSV, addressing a critical need in protecting vulnerable populations against this virus.

Although messenger RNA (mRNA) has proved effective as a vaccine, its potential as a general therapeutic modality is limited by its instability and low translation capacity. To increase the duration and level of protein expression from mRNA, we designed and synthesized topologically and chemically modified mRNAs with multiple synthetic poly(A) tails. Here we demonstrate that the optimized multitailed mRNA yielded ~4.7-19.5-fold higher luminescence signals than the control mRNA from 24 to 72 h post transfection in cellulo and 14 days detectable signal versus <7 days signal from the control in vivo. We further achieve efficient multiplexed genome editing of the clinically relevant genes Pcsk9 and Angptl3 in mouse liver at a minimal mRNA dosage. Taken together, these results provide a generalizable approach to synthesize capped branched mRNA with markedly enhanced translation capacity.

Clustered regularly interspaced short palindromic repeats-associated protein 13 (CRISPR-Cas13), an RNA editing technology, has shown potential in combating RNA viruses by degrading viral RNA within mammalian cells. In this study, we demonstrate the effective inhibition of porcine epidemic diarrhoea virus (PEDV) replication and spread using CRISPR-Cas13. We analysed the sequence similarity of the pseudoknot region between PEDV and severe acute respiratory syndrome coronavirus 2, both belonging to the Coronaviridae family, as well as the similarity of the RNA-dependent RNA polymerase (RdRp) gene region among three different strains of the PED virus. Based on this analysis, we synthesized three CRISPR RNAs (crRNAs) targeting the pseudoknot region and the nonpseudoknot region, each for comparison. In cells treated with crRNA #3 targeting the pseudoknot region, RdRp gene expression decreased by 95%, membrane (M) gene expression by 89% and infectious PEDV titre within the cells reduced by over 95%. Additionally, PED viral nucleocapsid (N) and M protein expression levels decreased by 83 and 98%, respectively. The optimal concentration for high antiviral efficacy without cytotoxicity was determined. Treating cells with 1.5 µg of Cas13b mRNA and 0.5 µg of crRNA resulted in no cytotoxicity while achieving over 95% inhibition of PEDV replication. The Cas13b mRNA therapeutics approach was validated as significantly more effective through a comparative study with merafloxacin, a drug targeting the pseudoknot region of the viral genome. Our results indicate that the pseudoknot region plays a crucial role in the degradation of the PEDV genome through the CRISPR-Cas13 system. Therefore, targeting Cas13b to the pseudoknot offers a promising new approach for treating coronavirus infections.

High grade gliomas (HGG) are a group of CNS tumors refractory to currently existing therapies, which routinely leads to early recurrence and a dismal prognosis. Recent advancements in nucleic acid-based therapy using a wide variety of different molecular targets and non-viral nanocarrier systems suggest that this approach holds significant potential to meet the urgent demand for improved therapeutic options for the treatment of these tumors. This review provides a comprehensive and up-to-date overview on the current landscape and progress of preclinical and clinical developments in this rapidly evolving and exciting field of research, including optimized nanocarrier delivery systems, promising therapeutic targets and tailor-made therapeutic strategies for individualized HGG patient treatment.

Cancer vaccines are promising as an effective means of stimulating the immune system to clear tumors as well as to establish immune surveillance. In this paper, we discuss the main platforms and current status of cancer vaccines and propose a new cancer vaccine platform, the cytosolic vesicle vaccine. This vaccine has a unique structure that can integrate antigen and adjuvant carriers to improve the delivery efficiency and immune activation ability, which brings new ideas for cancer vaccine design. Tumor exosomes carry antigens and MHC-peptide complexes, which can provide tumor antigens to antigen-processing cells and increase the chances of recognition of tumor antigens by immune cells. DEVs play a role in amplifying the immune response by acting as carriers for the dissemination of antigenic substances in dendritic cells. OMVs, with their natural adjuvant properties, are one of the advantages for the preparation of antitumor vaccines. This paper presents the advantages of these three bacteria/extracellular vesicles as cancer vaccines and discusses the potential applications of functionally modified extracellular vesicles as cancer vaccines after cellular engineering or genetic engineering, as well as current clinical trials of extracellular vesicle vaccines. In summary, extracellular vesicle vaccines are a promising direction for cancer vaccine research.

Due to their widespread geographic distribution and frequent outbreaks, mosquito-borne flaviviruses, such as DENV (DENV), Zika virus (ZIKV), Japanese encephalitis virus (JEV), yellow fever virus (YFV), and West Nile virus (WNV), are considered significant global public health threats and contribute to dramatic socioeconomic imbalances worldwide. The global prevalence of these viruses is largely driven by extensive international travels and ecological disruptions that create favorable conditions for the breeding of Aedes and Culex species, the mosquito vectors responsible for the spread of these pathogens. Currently, vaccines are available for only DENV, YFV, and JEV, but these face several challenges, including safety concerns, lengthy production processes, and logistical difficulties in distribution, especially in resource-limited regions, highlighting the urgent need for innovative vaccine approaches. Nucleic acid-based platforms, including DNA and mRNA vaccines, have emerged as promising alternatives due to their ability to elicit strong immune responses, facilitate rapid development, and support scalable manufacturing. This review provides a comprehensive update on the progress of DNA and mRNA vaccine development against mosquito-borne flaviviruses, detailing early efforts and current strategies that have produced candidates with remarkable protective efficacy and strong immunogenicity in preclinical models. Furthermore, we explore future directions for advancing nucleic acid vaccine candidates, which hold transformative potential for enhancing global public health.

In this study, we developed two plasmid constructs, pJHL270 and pJHL305, for the dual expression of Severe Fever with Thrombocytopenia Syndrome Virus (SFTSV) Gn and Gc glycoproteins in both prokaryotic and eukaryotic systems. The constructs feature a prokaryotic expression controlled by the Ptrc promoter and a eukaryotic expression driven by the cytomegalovirus promoter and Semliki Forest Virus RNA-dependent RNA polymerase. The Gn/Gc antigenic epitope was derived from consensus sequences of 12 SFTSV M segments collected in South Korea and designed for optimal antigen expression. The full antigen was expressed eukaryotically for post-translational modifications, while the epitope construct was expressed prokaryotically. These constructs were electroporated into an attenuated Salmonella Typhimurium strain (JOL2500) for plasmid delivery, resulting in JOL3042 and JOL3045. Successful expression was confirmed via qRT-PCR and western blot analysis. Mice immunized with JOL3042 showed antibody responses as early as two weeks, while JOL3045 elicited responses at six weeks, skewed toward a Th1 response initially, later balancing with Th2. Flow cytometry revealed significant CD3+CD4+ and CD3+CD8+ T-cell responses. Both constructs generated neutralizing antibodies, and a challenge study indicated significant reductions in viral loads in the serum, liver, and spleen of vaccinated mice, demonstrating the effectiveness of the Salmonella-mediated delivery system against SFTSV infection. The outcome of the current study may pave the way to develop a safer and more effective Salmonella-mediated vaccine against lethal SFTSV infection in vulnerable populations.

Bladder cancer (BC) accounts for about 4% of all malignancies. Non-muscle-invasive BC, 75% of cases, is treated with transurethral resection and adjuvant intravesical instillation, while muscle-invasive BC warrants cisplatin-based perioperative chemotherapy. Although immune-checkpoint inhibitors, antibody drug conjugates and targeted agents have provided dramatic advances, metastatic BC remains a generally incurable disease and clinical trials continue to vigorously evaluate novel molecules. Cancer vaccines aim at activating the patient's immune system against tumor cells. Several means of delivering neoantigens have been developed, including peptides, antigen-presenting cells, virus, or nucleic acids. Various improvements are constantly being explored, such as adjuvants use and combination strategies. Nucleic acids-based vaccines are increasingly gaining attention in recent years, with promising results in other malignancies. However, despite the recent advantages, numerous obstacles persist. This review is aimed at describing the different types of cancer vaccines, their evaluations in UC patients and the more recent innovations in this field.

Rabies, primarily transmitted to humans by dogs (accounting for 99% of cases). Once rabies occurs, its mortality rate is approximately 100%. Post-exposure prophylaxis (PEP) is critical for preventing the onset of rabies after exposure to rabid animals, and vaccination is a pivotal element of PEP. However, high costs and complex immunization protocols have led to poor adherence to rabies vaccinations. Consequently, there is an urgent need to develop new rabies vaccines that are safe, highly immunogenic, and cost-effective to improve compliance and effectively prevent rabies. In recent years, mRNA vaccines have made significant progress in the structural modification and optimization of delivery systems. Various mRNA vaccines are currently undergoing clinical trials, positioning them as viable alternatives to the traditional rabies vaccines. In this article, we discuss a novel mRNA rabies vaccine currently undergoing clinical and preclinical testing, and evaluate its potential to replace existing vaccines.

The COVID-19 pandemic, caused by the Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2), is in its sixth year and is being maintained by the inability of current spike-alone-based COVID-19 vaccines to prevent transmission leading to the continuous emergence of variants and sub-variants of concern (VOCs). This underscores the critical need for next-generation broad-spectrum pan-Coronavirus vaccines (pan-CoV vaccine) to break this cycle and end the pandemic. The development of a pan-CoV vaccine offering protection against a wide array of VOCs requires two key elements: (1) identifying protective antigens that are highly conserved between passed, current, and future VOCs; and (2) developing a safe and efficient antigen delivery system for induction of broad-based and long-lasting B- and T-cell immunity. This review will (1) present the current state of antigen delivery platforms involving a multifaceted approach, including bioinformatics, molecular and structural biology, immunology, and advanced computational methods; (2) discuss the challenges facing the development of safe and effective antigen delivery platforms; and (3) highlight the potential of nucleoside-modified mRNA encapsulated in lipid nanoparticles (LNP) as the platform that is well suited to the needs of a next-generation pan-CoV vaccine, such as the ability to induce broad-based immunity and amenable to large-scale manufacturing to safely provide durable protective immunity against current and future Coronavirus threats.

HPV-associated dermatological diseases include benign lesions like cutaneous warts and external genital warts. In addition, HPV infection is associated with the development of epithelial skin cancers, in particular cutaneous squamous cell carcinoma (cSCC). In contrast to anogenital and oropharyngeal cancers caused by mucosal HPV types of genus alpha papillomavirus, cSCC-associated HPV types belong to the genus beta papillomavirus. Currently available HPV vaccines that target mucosal HPV types associated with anogenital cancer and genital warts are type-specific and provide no cross-protection against beta HPV. When implementing vaccination to beta HPV to prevent skin tumors, it must be considered that acquisition of these HPV types occurs early in childhood and that the risk for cSCC increases with growing age and decreasing immune surveillance. Thus, individuals considered for beta HPV vaccination usually have pre-existing infection and are largely immunocompromised. On the other hand, worldwide increasing incidence rates of epithelial skin cancer reflect an urgent need for skin cancer prevention measures. Based on the pathogenic involvement of beta HPV, vaccination may represent a promising prevention strategy. Indeed, various procedures of prophylactic and therapeutic vaccination have been developed, and some of them have shown efficiency in animal models. Thus far, however, none of these vaccine candidates has been approved for application in humans.

Messenger RNA (mRNA) delivered in lipid nanoparticles (LNPs) rose to the forefront of vaccine candidates during the COVID-19 pandemic due in part to scalability, adaptability, and potency. Yet there remain critical areas for improvements of these vaccines in durability and breadth of humoral responses. In this work, we explore a modular strategy to target mRNA/LNPs to antigen presenting cells with an injectable polymer-nanoparticle (PNP) hydrogel depot technology which recruits key immune cells and forms an immunological niche in vivo. We characterize this niche on a single cell level and find it is highly tunable through incorporation of adjuvants like MPLAs and 3M-052. Delivering commercially available SARS-CoV-2 mRNA vaccines in PNP hydrogels improves the durability and quality of germinal center reactions, and the magnitude, breadth, and durability of humoral responses. The tunable immune niche formed within PNP hydrogels effectively skews immune responses based on encapsulated adjuvants, creating opportunities to precisely modulate mRNA/LNP vaccines for various indications from infectious diseases to cancers.

Interstitial lung disease (ILD) is characterized by chronic inflammation and scarring of the lungs, of which idiopathic pulmonary fibrosis (IPF) is the most devastating pathologic form. Idiopathic pulmonary fibrosis pathogenesis leads to loss of lung function and eventual death in 50% of patients, making it the leading cause of ILD-associated mortality worldwide. Persistent and subclinical microbial infections are implicated in the acute exacerbation of chronic lung diseases. However, while epidemiological studies have highlighted pollutants, gastric aspirate, and microbial infections as major causes for the progression and exacerbation of IPF, the role of persistent microbial infections in the pathogenesis of IPF remains unclear. In this review, we have focused on the role of persistent microbial infections, including viral, bacterial, and fungal infections, and their mechanisms of action in the pathogenesis of IPF. In particular, the mechanisms and pathogenesis of the Gram-negative bacteria Non-typeable Haemophilus influenzae (NTHi) in ILDs are discussed, along with growing evidence of its role in IPF, given its unique ability to establish persistent intracellular infections by leveraging its non-capsulated nature to evade host defenses. While antibiotic treatments are presumably beneficial to target the extracellular, interstitial, and systemic burden of pathogens, their effects are significantly reduced in combating pathogens that reside in the intracellular compartments. The review also includes recent clinical trials, which center on combinatorial treatments involving antimicrobials and immunosuppressants, along with antifibrotic drugs that help mitigate disease progression in IPF patients. Finally, future directions focus on mRNA-based therapeutics, given their demonstrated effectiveness across a wide range of clinical applications and feasibility in targeting intracellular pathogens.

In vitro transcription (IVT) using T7 RNA polymerase (RNAP) is integral to RNA research, yet producing this enzyme in E. coli presents challenges regarding endotoxins and animal-sourced toxins. This study demonstrates the viable production and characterization of T7 RNAP using ClearColi BL21(DE3) (an endotoxin-free E. coli strain) and animal-free media. Compared to BL21(DE3) with animal-free medium, soluble T7 RNAP expression is ~50% lower in ClearColi BL21(DE3). Optimal soluble T7 RNAP expression in flask fermentation is achieved through the design of experiments (DoE). Specification and functional testing showed that the endotoxin-free T7 RNAP has comparable activity to conventional T7 RNAP. After Ni-NTA purification, endotoxin levels were approximately 109-fold lower than T7 RNAP from BL21(DE3) with animal-free medium. Furthermore, a full factorial DoE created an optimal IVT system that maximized mRNA yield from the endotoxin-free and animal-free T7 RNAP. This work addresses critical challenges in recombinant T7 RNAP production through innovative host and medium combinations, avoided endotoxin risks and animal-derived toxins. Together with an optimized IVT reaction system, this study represents a significant advance for safe and reliable reagent manufacturing and RNA therapeutics. KEY POINTS: • Optimized IVT system maximizes mRNA yields, enabling the synthesis of long RNAs. • Novel production method yields endotoxin-free and animal-free T7 RNAP. • The T7 RNAP has equivalent specifications and function to conventional T7 RNAP.

Over the last two decades, lipid nanoparticles (LNPs) have evolved as an effective biocompatible and biodegradable RNA delivery platform in the fields of nanomedicine, biotechnology, and drug delivery. They are novel bionanomaterials that can be used to encapsulate a wide range of biomolecules, such as mRNA, as demonstrated by the current successes of COVID-19 mRNA vaccines. Therefore, it is important to provide a perspective on LNPs for RNA delivery, which further offers useful guidance for researchers who want to work in the RNA-based LNP field. This perspective first summarizes the approaches for the preparation of LNPs, followed by the introduction of the key characterization parameters. Then, the in vitro cell experiments to study LNP performance, including cell selection, cell viability, cellular association/uptake, endosomal escape, and their efficacy, were summarized. Finally, the in vivo animal experiments in the aspects of animal selection, administration, dosing and safety, and their therapeutic efficacy were discussed. The authors hope this perspective can offer valuable guidance to researchers who enter the field of RNA-based LNPs and help them understand the crucial parameters that RNA-based LNPs demand.

Over the past years, gene therapeutics have held great promise for treating many inherited and acquired diseases. The increasing number of approved gene therapeutics and developing clinical pipelines demonstrate the potential to treat diseases by modifying their genetic blueprints in vivo. Compared with conventional treatments targeting proteins rather than underlying causes, gene therapeutics can achieve enduring or curative effects via gene activation, inhibition, and editing. However, the delivery of DNA/RNA to the target cell to alter the gene expression is a complex process that involves, crossing numerous barriers in both the extracellular and intracellular environment. Generally, the delivery strategies can be divided into viral-based and non-viral-based vectors. This review summarizes various bioanalysis strategies that support the non-virus-based gene therapeutics research, including pharmacokinetics (PK)/toxicokinetics (TK), biodistribution, immunogenicity evaluations for the gene cargo, vector, and possible expressed protein, and highlights the challenges and future perspectives of bioanalysis strategies in non-virus-based gene therapeutics. This review may provide new insights and directions for the development of emerging bioanalytical methods, offering technical support and a research foundation for innovative gene therapy treatments.