grant

Inducible HMGB1 antagonist for viral-induced acute lung injury.

Organization SIGMOVIR BIOSYSTEMS, INC.Location ROCKVILLE, UNITED STATESPosted 16 Aug 2023Deadline 31 Jul 2026
NIHUS FederalResearch GrantFY20242019 novel corona virus2019 novel coronavirus2019-nCoVARDSAcute Lung InjuryAcute Pulmonary InjuryAcute Respiratory DistressAcute Respiratory Distress SyndromeAd vectorAddressAdenoviral VectorAdenoviridaeAdenovirus VectorAdenovirusesAdult ARDSAdult RDSAdult Respiratory Distress SyndromeAgonistAirway infectionsAmphoterinAmphoterin GeneAnimal ModelAnimal Models and Related StudiesAutoregulationBacterial InfectionsBiological MarkersBody TissuesBreakbone Fever VirusCOVID crisisCOVID epidemicCOVID pandemicCOVID-19 associated cytokine stormCOVID-19 crisisCOVID-19 cytokine stormCOVID-19 epidemicCOVID-19 eraCOVID-19 exposureCOVID-19 global health crisisCOVID-19 global pandemicCOVID-19 health crisisCOVID-19 induced cytokine stormCOVID-19 infectionCOVID-19 pandemicCOVID-19 periodCOVID-19 public health crisisCOVID-19 related cytokine stormCOVID-19 virusCOVID-19 virus infectionCOVID-19 yearsCOVID19 infectionCOVID19 virusCell BodyCell Communication and SignalingCell SignalingCellsCellular injuryCessation of lifeChemotactic CytokinesChromosomal Protein, Nonhistone, HMG1Chromosomal Protein, Nonhistone, HMG1 GeneCoV-2CoV2Cotton RatsDENVDa Nang LungDataDeathDengue VirusDengue fever virusDevelopmentDimerizationDiseaseDisease ProgressionDisorderEBOVEbola virusEbola-like VirusesEngineeringExperimental Animal ModelFM1 Gene ProductFamilyGene ExpressionGoalsGrippeHMG-1HMG-1 GeneHMG-1 ProteinHMG1HMG1 GeneHMG3HMG3 GeneHMGB1HMGB1 ProteinHMGB1 geneHeparin-Binding Protein p30High Mobility Group Box Protein 1High Mobility Group Protein 1High Mobility Group Protein 1 GeneHigh-Mobility Group (Nonhistone Chromosomal) Protein 1High-Mobility Group (Nonhistone Chromosomal) Protein 1 GeneHigh-Mobility Group Box 1High-Mobility Group Box 1 GeneHomeostasisHomolog of Drosophila TOLLHomologous Chemotactic CytokinesHospital AdmissionHospitalizationHumanImmune responseImmunological responseInfectious AgentInflammationInflammation MediatorsInflammatoryInflammatory ResponseInfluenzaInjuryInnate Immune ResponseIntercrinesInterventionIntervention StrategiesIntracellular Communication and SignalingLifeLigandsLipopolysaccharidesLungLung InflammationLung Respiratory SystemMOF syndromeMediatingMediatorMiceMice MammalsModern ManMolecularMultiple Organ Dysfunction SyndromeMultiple Organ FailureMurineMusNonhistone Chromosomal Protein HGM1Nonhistone Chromosomal Protein HGM1 GenePathway interactionsPatientsPatternPattern recognition receptorPhasePhysiological HomeostasisPneumonitisPredispositionProcessProductionProtein DimerizationPublishingPulmonary InflammationReceptor ProteinReportingResearchResolutionRespiratory DiseaseRespiratory InfectionsRespiratory System DiseaseRespiratory System DisorderRespiratory Tract InfectionsRodent ModelSARS corona virus 2SARS-CO-V2SARS-COVID-2SARS-CoV-2SARS-CoV-2 associated cytokine stormSARS-CoV-2 cytokine stormSARS-CoV-2 epidemicSARS-CoV-2 exposureSARS-CoV-2 global health crisisSARS-CoV-2 global pandemicSARS-CoV-2 induced cytokine stormSARS-CoV-2 infectionSARS-CoV-2 pandemicSARS-CoV-2 related cytokine stormSARS-CoV2SARS-CoV2 exposureSARS-CoV2 infectionSARS-associated corona virus 2SARS-associated coronavirus 2SARS-coronavirus-2SARS-coronavirus-2 epidemicSARS-coronavirus-2 pandemicSARS-related corona virus 2SARS-related coronavirus 2SARSCoV2SBP-1SBP-1 GeneSIS cytokinesSTTRSepsisSevere Acute Respiratory Coronavirus 2Severe Acute Respiratory Distress Syndrome CoV 2Severe Acute Respiratory Distress Syndrome Corona Virus 2Severe Acute Respiratory Distress Syndrome Coronavirus 2Severe Acute Respiratory Syndrome CoV 2Severe Acute Respiratory Syndrome CoV 2 epidemicSevere Acute Respiratory Syndrome CoV 2 pandemicSevere Acute Respiratory Syndrome-associated coronavirus 2Severe Acute Respiratory Syndrome-related coronavirus 2Severe acute respiratory syndrome associated corona virus 2Severe acute respiratory syndrome coronavirus 2Severe acute respiratory syndrome coronavirus 2 epidemicSevere acute respiratory syndrome coronavirus 2 exposureSevere acute respiratory syndrome coronavirus 2 infectionSevere acute respiratory syndrome coronavirus 2 pandemicSevere acute respiratory syndrome related corona virus 2Severity of illnessShock LungSigmodonSignal PathwaySignal TransductionSignal Transduction SystemsSignalingSmall Business Technology Transfer ResearchSterilityStiff lungStructureSulfoglucuronyl Carbohydrate Binding ProteinSulfoglucuronyl Carbohydrate Binding Protein GeneSusceptibilitySymptomsSystemTLR proteinTLR4TLR4 geneTestingTherapeuticTherapeutic InterventionTissuesToll HomologueToll-Like Receptor Family GeneToll-like receptorsTreatment EfficacyViralVirusWorkWuhan coronavirusadeno vectoradenovectorantagonismantagonistbacteria infectionbacterial diseasebio-markersbiologic markerbiological signal transductionbiomarkerblood infectionbloodstream infectioncell damagecell injurycellular damagechemoattractant cytokinechemokineclinical relevanceclinically relevantcoronavirus disease 2019 associated cytokine stormcoronavirus disease 2019 crisiscoronavirus disease 2019 cytokine stormcoronavirus disease 2019 epidemiccoronavirus disease 2019 exposurecoronavirus disease 2019 global health crisiscoronavirus disease 2019 global pandemiccoronavirus disease 2019 health crisiscoronavirus disease 2019 induced cytokine stormcoronavirus disease 2019 infectioncoronavirus disease 2019 pandemiccoronavirus disease 2019 public health crisiscoronavirus disease 2019 related cytokine stormcoronavirus disease 2019 viruscoronavirus disease crisiscoronavirus disease epidemiccoronavirus disease pandemiccoronavirus disease-19 global pandemiccoronavirus disease-19 pandemiccoronavirus disease-19 viruscytokinecytokine release syndromecytokine stormdamage to cellsdevelopmentaldisease severityefficacy testingexposure to COVID-19exposure to SARS-CoV-2exposure to SARS-CoV2exposure to Severe acute respiratory syndrome coronavirus 2exposure to coronavirus disease 2019flu infectionflu serotypeflu strainflu subtypeflu viral strainflu virus infectionflu virus strainhCoV19host responsehuman diseasehuman pathogenimmune system responseimmunoresponseinfected with COVID-19infected with COVID19infected with SARS-CoV-2infected with SARS-CoV2infected with coronavirus disease 2019infected with fluinfected with flu virusinfected with influenzainfected with influenza virusinfected with severe acute respiratory syndrome coronavirus 2infectious organisminflammatory lung diseaseinflammatory mediatorinfluenza infectioninfluenza serotypeinfluenza straininfluenza subtypeinfluenza viral straininfluenza virus infectioninfluenza virus straininhibitorinjuriesinjury to cellsinnovateinnovationinnovativeinsightintervention efficacyintervention therapyinterventional strategymicrobial interactionmicroorganism interactionmodel of animalmouse modelmultiorgan failuremultiple organ system failuremurine modelnCoV2new approachesnovelnovel approachesnovel strategiesnovel strategypathogenpathwaypre-clinicalpreclinicalprototypepulmonaryreceptorresolutionsrespiratory virusresponsesevere acute respiratory syndrome coronavirus 2 associated cytokine stormsevere acute respiratory syndrome coronavirus 2 cytokine stormsevere acute respiratory syndrome coronavirus 2 global health crisissevere acute respiratory syndrome coronavirus 2 global pandemicsevere acute respiratory syndrome coronavirus 2 induced cytokine stormsevere acute respiratory syndrome coronavirus 2 related cytokine stormsmall moleculesteriletherapeutic agent developmenttherapeutic developmenttherapeutic efficacytherapeutic targettherapeutically effectivetherapy efficacytoll-like receptor 4tooltranslational therapeuticstranslational therapywet lung
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Full Description

For more than a decade, our work has focused on development of therapeutic interventions for viral- and
bacterial-induced acute lung injury (ALI) and the more severe acute respiratory distress syndrome (ARDS).
Significantly, we identified the Toll-like receptor 4 (TLR4) signaling pathway as key to the host response to
influenza and secondary bacterial infection following influenza. We also identified High Mobility Group Box 1
(HMGB1), a host-derived “danger-associated molecular pattern” (DAMP), as a biomarker of disease severity for
multiple respiratory viruses and detected greatly elevated levels in sera from patients hospitalized for severe
influenza and SARS-CoV-2 infections. Importantly, our data indicate that HMGB1 is a central mediator of
influenza-induced respiratory disease that acts by stimulating TLR4/MD-2 to elicit the potent inflammatory
response associated with ALI/ARDS. Therapeutic administration of TLR4 antagonists (e.g., Eritoran and many
others), as well as small molecule HMGB1 antagonists, mitigate the life-threatening pulmonary manifestations
of acute lung injury (ALI) and lethality in preclinical rodent models. The identification of these promising
therapeutic targets has led us to the central hypothesis that our findings may well be applicable to other ALI-
inducing agents. Indeed, since our earliest reports of the efficacy of the TLR4 antagonist, Eritoran, in influenza-
induced disease in both mice and cotton rats (Sigmodon hispidus, a species uniquely susceptible to non-adapted
human viruses), this agent has been reported to blunt disease in animal models of Ebola virus and Dengue virus,
leading to a reduction in cytokine and chemokine production and reduced disease symptoms. Given the clinical
relevance of ALI and ARDS that has been exposed by the SARS-CoV-2 pandemic, and the striking similarities
between influenza- and SARS-Cov-2-induced ALI/ARDS caused by a cytokine storm leading to loss of
homeostasis and, ultimately, multiorgan failure and death, we propose, as the central goal of this phase I STTR,
to evaluate the therapeutic efficacy of our newly developed, inflammation-inducible, adenoviral vector encoding
the HMGB1 antagonist, “HMGB1 Box A,” to ameliorate severe influenza-induced inflammation. We will test the
efficacy of our intervention in murine models of LPS-induced lung inflammation and mouse-adapted influenza
infection, and in cotton rats challenged with non-adapted human influenza strains for which we have correlated
HMGB1 levels with disease severity. We predict that our innovative strategy will provide a novel approach to
treatment of inflammatory lung disease that is mediated by multiple non-infectious and infectious agents that
cause ALI/ARDS.

Grant Number: 3R41HL167254-02S1
NIH Institute/Center: NIH
Principal Investigator: JORGE BLANCO

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