Project description: Not available

Project description:Andes virus (ANDV) is a rodent-borne zoonotic orthohantavirus endemic in South America that causes hantavirus pulmonary syndrome in humans, with up to a 40% case fatality rate. We developed ANDV mRNA vaccines based on the M segment of the viral genome that codes for glycoproteins Gn and Gc in a single open reading frame of glycoprotein precursor (GPC). We generated RNAs either with regular uridine (U-mRNA) or N1-methylpseudouridine (m1Ψ-mRNA). Mice immunized by either ANDV U-mRNA or m1Ψ-mRNA developed similar germinal center responses in lymph nodes. Single cell RNA and BCR sequencing of germinal center B cells from vaccinated mice demonstrated similar levels of activation, except an additional cluster of cells exhibiting strong interferon response that was present in animals vaccinated with U-mRNA but not m1Ψ-mRNA. Furthermore, similar immunoglobulin class-switching and somatic hypermutations were observed for the two vaccines. Golden Syrian hamsters were immunized intramuscularly with 2 doses of the vaccines on days 0 and 21. The titers of Gn/Gc-binding antibodies were moderately greater for U-mRNA construct than for m1Ψ-mRNA construct, however, the titers of ANDV-neutralizing antibodies were equivalent. Vaccinated animals were challenged with a lethal dose of ANDV at 21 days after the boost, along with the naïve control group. All control animals succumbed to infection whereas all vaccinated animals survived without any detectable disease or viral load. The data demonstrate the development of effective vaccines against ANDV and the lack of a significant effect of m1Ψ mRNA modification on immunogenicity and protection in the hamster model.

Project description:Andes virus (ANDV) is a rodent-borne zoonotic orthohantavirus endemic in South America that causes hantavirus pulmonary syndrome in humans, with up to a 40% case fatality rate. We developed ANDV mRNA vaccines based on the M segment of the viral genome that codes for glycoproteins Gn and Gc in a single open reading frame of glycoprotein precursor (GPC). We generated RNAs either with regular uridine (U-mRNA) or N1-methylpseudouridine (m1Ψ-mRNA). Mice immunized by either ANDV U-mRNA or m1Ψ-mRNA developed similar germinal center responses in lymph nodes. Single cell RNA and BCR sequencing of germinal center B cells from vaccinated mice demonstrated similar levels of activation, except an additional cluster of cells exhibiting strong interferon response that was present in animals vaccinated with U-mRNA but not m1Ψ-mRNA. Furthermore, similar immunoglobulin class-switching and somatic hypermutations were observed for the two vaccines. Golden Syrian hamsters were immunized intramuscularly with 2 doses of the vaccines on days 0 and 21. The titers of Gn/Gc-binding antibodies were moderately greater for U-mRNA construct than for m1Ψ-mRNA construct, however, the titers of ANDV-neutralizing antibodies were equivalent. Vaccinated animals were challenged with a lethal dose of ANDV at 21 days after the boost, along with the naïve control group. All control animals succumbed to infection whereas all vaccinated animals survived without any detectable disease or viral load. The data demonstrate the development of effective vaccines against ANDV and the lack of a significant effect of m1Ψ mRNA modification on immunogenicity and protection in the hamster model.

Project description:Since the approval of the lipid nanoparticles (LNP)-mRNA vaccines against the SARS-CoV-2 virus, there has been an increased interest in the delivery of mRNA through LNPs. However, current LNP formulations contain PEG lipids, which can stimulate the generation of anti-PEG antibodies. The presence of these antibodies can potentially cause adverse reactions and reduce therapeutic efficacy after administration. Given the widespread deployment of the COVID-19 vaccines, the increased exposure to PEG may necessitate the evaluation of alternative LNP formulations without PEG components. In this study, we investigated a series of polysarcosine (pSar) lipids as alternatives to the PEG lipids to determine whether pSar lipids could still provide the functionality of the PEG lipids in the ALC-0315 and SM-102 LNP systems. We found that complete replacement of the PEG lipid with a pSar lipid can increase or maintain mRNA delivery efficiency and exhibit similar safety profiles in vivo.

Project description:Image, graphical abstract.

Project description:Rapid and specific detection of single nucleotide polymorphisms (SNPs) related to drug resistance in infectious diseases is crucial for accurate prognostics, therapeutics and disease management at point-of-care. Here, we present a novel amplification method and provide universal guidelines for the detection of SNPs at isothermal conditions. This method, called USS-sbLAMP, consists of SNP-based loop-mediated isothermal amplification (sbLAMP) primers and unmodified self-stabilizing (USS) competitive primers that robustly delay or prevent unspecific amplification. Both sets of primers are incorporated into the same reaction mixture, but always targeting different alleles; one set specific to the wild type allele and the other to the mutant allele. The mechanism of action relies on thermodynamically favored hybridization of totally complementary primers, enabling allele-specific amplification. We successfully validate our method by detecting SNPs, C580Y and Y493H, in the Plasmodium falciparum kelch 13 gene that are responsible for resistance to artemisinin-based combination therapies currently used globally in the treatment of malaria. USS-sbLAMP primers can efficiently discriminate between SNPs with high sensitivity (limit of detection of 5 × 101 copies per reaction), efficiency, specificity and rapidness (<35 min) with the capability of quantitative measurements for point-of-care diagnosis, treatment guidance, and epidemiological reporting of drug-resistance.

Project description:The focus of most current HIV-1 vaccine development is on antibody-based approaches. This is because certain antibody responses correlated with protection from HIV-1 acquisition in the RV144 phase III trial, and because a series of potent and broad spectrum neutralizing antibodies have been isolated from infected individuals. Taken together, these two findings suggest ways forward to develop a neutralizing antibody-based vaccine. However, understanding of the correlates of protection from disease in HIV-1 and other infections strongly suggests that we should not ignore CTL-based research. Here we review recent progress in the field and highlight the challenges implicit in HIV-1 vaccine design and some potential solutions.

Project description:Some studies have shown that lyophilization significantly improves the stability of mRNA-LNPs and enables long-term storage at 2-8 °C. However, there is little research on the lyophilization process of mRNA-lipid nanoparticles (LNPs). Most previous studies have used empirical lyophilization with only a single lyoprotectant, resulting in low lyophilization efficiency, often requiring 40-100 h. In the present study, an efficient lyophilization method suitable for mRNA-LNPs was designed and optimized, shortening the total length of the lyophilization process to 8-18 h, which significantly reduced energy consumption and production costs. When the mixed lyoprotectant composed of sucrose, trehalose, and mannitol was added to mRNA-LNPs, the eutectic point and collapse temperature of the system were increased. The lyophilized product had a ginger root-shaped rigid structure with large porosity, which tolerated rapid temperature increases and efficiently removed water. In addition, the lyophilized mRNA-LNPs rapidly rehydrated and had good particle size distribution, encapsulation rate, and mRNA integrity. The lyophilized mRNA-LNPs were stable at 2-8 °C, and they did not reduce immunogenicity in vivo or in vitro. Molecular dynamics simulation was used to compare the phospholipid molecular layer with the lyoprotectant in aqueous and anhydrous environments to elucidate the mechanism of lyophilization to improve the stability of mRNA-LNPs. This efficient lyophilization platform significantly improves the accessibility of mRNA-LNPs.

Project description:The role of HPV as the causative factor in cervical cancer has led to the development of the HPV vaccines Gardasil and Cervarix. These vaccines effectively protect against two HPV types associated with 70% of cervical cancer cases. Despite this success, researchers continue to develop second-generation HPV vaccines to protect against more HPV types and allow increased uptake in developing countries. While a reformulated vaccine based on the current technology is currently in clinical trials, another strategy consists of targeting highly conserved epitopes in the minor capsid protein of HPV, L2. Vaccines targeting L2 induce broadly neutralizing antibodies, capable of blocking infection by a wide range of HPV types. Several vaccine designs have been developed to optimize the display of L2 epitopes to the immune system and to reduce the cost of manufacture and distribution. L2-based vaccines show considerable promise as a potential next-generation HPV vaccine.

Project description:Increases in the world's population and population density promote the spread of emerging pathogens. Vaccines are the most cost-effective means of preventing this spread. Traditional methods used to identify and produce new vaccines are not adequate, in most instances, to ensure global protection. New technologies are urgently needed to expedite large scale vaccine development. mRNA-based vaccines promise to meet this need. mRNA-based vaccines exhibit a number of potential advantages relative to conventional vaccines, namely they (1) involve neither infectious elements nor a risk of stable integration into the host cell genome; (2) generate humoral and cell-mediated immunity; (3) are well-tolerated by healthy individuals; and (4) are less expensive and produced more rapidly by processes that are readily standardized and scaled-up, improving responsiveness to large emerging outbreaks. Multiple mRNA vaccine platforms have demonstrated efficacy in preventing infectious diseases and treating several types of cancers in humans as well as animal models. This review describes the factors that contribute to maximizing the production of effective mRNA vaccine transcripts and delivery systems, and the clinical applications are discussed in detail.