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Medium Chain Fatty Acids (MCFAs) for Enhanced Bacterial Infection Treatment
MCFAs provide a synergistic bactericidal effect in combination with antibiotics and bacteriophages to effectively treat antibiotic-resistant bacterial infections.
dimerLight
Researchers at the University of California, Davis have developed an innovative platform for creating genetically encoded fluorescent biosensors capable of 1) assessing the formation of GPCR homo and heterodimers, and 2) determining how dimerization impacts protomer conformation in response to ligands.The UC Davis IPN has developed a suite of ~24 biosensors based on GPCR dimers.Collectively called, dimerLights, these modular biosensors have the ability to identify novel dimeric drug targets and assess the impact of ligands on their conformations.In addition to the ~24 biosensors that UC Davis has already developed, the modular platform in principle can easily be adapted to enable the discovery and evaluation of broader GPCR homo/heterodimers than have been tested so far.
Advanced Combination Therapy for HIV using Bioactive Lipids with ART
Researchers at the University of California, Davis have developed a therapy that combines bioactive lipids with antiretroviral drugs to accelerate viral suppression and promote gut mucosal repair in HIV treatment.
Persistent Memory T-Cell Responses to Cancer and Infectious-disease Antigens by Manipulation of Amino Acid-catabolism Pathways
Researchers at the University of California, Davis, have created a technology that uses engineered polynucleotides to deliver both an antigen and an enzyme that breaks down amino acids. This approach is designed to boost long-lasting memory T-cell responses, providing stronger protection against infectious diseases and cancer.
Serum-Stable Peptide Linkers for Protease-Activated Antibiotic Prodrugs Targeting Multidrug-Resistant Bacteria
Brief description not available
CBASS Inhibitor: Unlocking Next-Generation Phage Therapy to Combat Antimicrobial Resistance and Immunological Diseases
Optimized RNA-Seq Protocol for Pathogen Detection and Diagnostic Innovation
Novel [13C]CO2 Breath Test for Rapid, Non-Invasive Detection of Bone and Joint Infections
RocASO: A Breakthrough Platform to Silence Undruggable RNA Targets and Transform Therapeutics
AI-Driven RNA Gene Host Response Panel and Biomarker Platform for Differential Diagnosis of Lyme Disease and Tickborne Infections
Neisserial Surface Protein A Vaccine Antigens With Decreased Binding To Human Complement Factor H
Techniques For Predicting Immunization Responses
Soluble CD30 As A Surrogate Marker Of HIV-1 RNA
Metagenomic Next-Generation Sequencing (mNGS) Assay for Detection of Respiratory Pathogens
Induced Synthetic Intracellular Cytokine And Growth Factor Circuits For Cell Autonomous Control Of Cell Signaling, Proliferation, Survival And Cell State
Inhibitors Of Viral Proteases
Derepression Of Interferon Stimulated Genes For Enhancing Protection In Autoinflammatory Reactions Including Those During Respiratory Infections.
Inhibitors Of Viral Macrodomains
A Covalent Protein Inhibitor For Sars-Cov-2
Using Class I Lasso Peptides to Inhibit the Bacterial Type III Secretion System
Antibiotic resistance is a major issue in infectious disease treatment and prevention. In bacteria, the type III secretion system (T3SS) secretes effector proteins in the host cell, allowing the pathogen to infect. The T3SS is largely found on pathogens and not beneficial bacteria, so targeting the T3SS might have an advantage over using classic antibiotics, which disturb the beneficial human microbiome.
Vaccines Using Macrophage Suppression
Researchers at the University of California, Davis have developed a technology that introduces vaccines that express macrophage-suppressing molecules to significantly enhance inflammatory T-cell functions for improved immune responses.
Silyl-lipid N-acyl L-homoserine Lactones (AHLs) as Quorum Sensing Molecules (for Biofilms)
Researchers at the University of California, Davis have developed a potential therapeutic strategy aiming at disrupting intercellular communication of pathogens using quorum sensing molecules and silicon-based pharmacophores.
Antigen-Specific T Cell Receptor Discovery For Treating Progressive Multifocal Leukoencephalopathy
Progressive Multifocal Leukoencephalopathy (PML) is a devastating and often fatal demyelinating disease of the central nervous system caused by the reactivation of the JC virus (JCV). In immunocompromised patients, the absence of effective T cell surveillance allows the virus to infect and lyse oligodendrocytes, leading to irreversible neurological damage. UC Berkeley researchers have developed a method for discovering and engineering antigen-specific T cell receptors (TCRs) that specifically target JCV.
Hydrogelated Bacteria as Antibacterial Vaccines
Researchers at the University of California, Davis have developed a vaccine platform utilizing non-replicating, metabolically active Cyborg Bacterial Pathogens to combat multi-antibiotic-resistant bacteria.
Method for Detection of Virus Transmission Enhancing Mutations Using Population Samples of Genomic Sequences
Researchers at the University of California, Davis have developed a computer-implemented method to identify viral mutations that enhance transmission and predict their prevalence in populations over time.