grant

Development of Novel RhoA Nitration Inhibitory Peptides for the Treatment of Acute Lung Injury

Organization FLORIDA INTERNATIONAL UNIVERSITYLocation MIAMI, UNITED STATESPosted 1 Sept 2025Deadline 31 Jul 2027
NIHUS FederalResearch GrantFY20252019 novel corona virus2019 novel coronavirus2019-nCoV2019-nCoV S protein2019-nCoV spike glycoprotein2019-nCoV spike proteinARDSActin-Activated ATPaseAcuteAcute Lung InjuryAcute Pulmonary InjuryAcute Respiratory DistressAcute Respiratory Distress SyndromeAcute respiratory failureAdult ARDSAdult RDSAdult Respiratory Distress SyndromeAdverse effectsAlgorithmsAmino AcidsAnimal ModelAnimal Models and Related StudiesAntibodiesAssayAttenuatedBacteriaBioassayBiochemicalBiological AssayBreast CancerCOVID-19 S proteinCOVID-19 spikeCOVID-19 spike glycoproteinCOVID-19 spike proteinCOVID-19 virusCOVID19 virusCell BodyCell membraneCellsCharacteristicsChemicalsChemotactic CytokinesClinicalClinical ResearchClinical StudyCoV-2CoV2Cytoplasmic MembraneDa Nang LungDataDeath RateDevelopmentDrug KineticsDrug TherapyDrugsE coliE. coliEndotheliumEpitheliumEscherichia coliEventExcretory functionFamily suidaeGTP PhosphohydrolasesGTPasesGenerationsGuanosine Triphosphate PhosphohydrolasesGuanosinetriphosphatasesHalf-LifeHomologous Chemotactic CytokinesHumanImmune Cell ActivationImmunoblot AnalysisImmunoglobulin Enhancer-Binding ProteinIn VitroInfiltrationInflammationInflammatoryInflammatory ResponseIntercrinesIntermediary MetabolismInterventionInvestigationIsometric ExerciseIsometricsLeadLifeLinkLipopolysaccharidesLungLung InflammationLung Respiratory SystemLung damageMalignant Breast NeoplasmMalignant neoplasm of prostateMalignant prostatic tumorMechanical ventilationMedicalMedicationMedicinal ChemistryMetabolic ProcessesMetabolismMiceMice MammalsMitochondriaModelingModern ManModificationMonomeric G-ProteinsMonomeric GTP-Binding ProteinsMurineMusMuscle-Setting ExerciseMyosin ATPaseMyosin Adenosine TriphosphataseMyosin AdenosinetriphosphataseMyosinsNF-kBNF-kappa BNF-kappaBNFKBNHLBINational Heart, Lung, and Blood InstituteNitrogenNuclear Factor kappa BNuclear Transcription Factor NF-kBO elementO2 elementOutcomeOxygenPK/PDParentsPatientsPb elementPeptide SynthesisPeptidesPermeabilityPeroxonitritePharmaceutic ChemistryPharmaceutical ChemistryPharmaceutical PreparationsPharmacodynamicsPharmacokineticsPharmacological TreatmentPharmacotherapyPhasePigsPlasma MembranePneumonitisPropertyProstate CAProstate CancerProstate malignancyProtein CleavageProteinsProteolysisPublishingPulmonary InflammationRenal clearance functionRoleSARS corona virus 2SARS-CO-V2SARS-COVID-2SARS-CoV-2SARS-CoV-2 SSARS-CoV-2 S proteinSARS-CoV-2 spikeSARS-CoV-2 spike glycoproteinSARS-CoV-2 spike proteinSARS-CoV2SARS-associated corona virus 2SARS-associated coronavirus 2SARS-coronavirus-2SARS-related corona virus 2SARS-related coronavirus 2SARSCoV2SIS cytokinesSafetySepsisSepsis and ARDSSevere 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-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 S proteinSevere acute respiratory syndrome coronavirus 2 spike glycoproteinSevere acute respiratory syndrome coronavirus 2 spike proteinSevere acute respiratory syndrome related corona virus 2Shock LungSiteSmall G-ProteinsSmall GTPasesSolubilitySpecificityStatic ExerciseStiff lungStructureSuidaeSwineSyndromeTestingTherapeutic AgentsTherapeutic EffectTranscription Factor NF-kBUnited StatesValidationVascular PermeabilitiesWuhan coronavirusabsorptionacute respiratory distress syndrome caused by sepsisaminoacidattenuateattenuateschemoattractant cytokinechemokinecoronavirus disease 2019 S proteincoronavirus disease 2019 spike glycoproteincoronavirus disease 2019 spike proteincoronavirus disease 2019 viruscoronavirus disease-19 viruscytokinedenitrationdesigndesigningdevelopmentaldrug interventiondrug treatmentdrug/agenteffective therapyeffective treatmentexcretionguanosinetriphosphatasehCoV19heavy metal Pbheavy metal leadimmune activationimprovedin vitro Assayin vivokappa B Enhancer Binding Proteinlung injurylung microvascular endothelial cellslung vascular endothelial cellsmalignant breast tumormechanical respiratory assistmechanically ventilatedmitochondrialmodel of animalmortality ratemortality ratiomouse modelmurine modelnCoV2new drug classnew drug treatmentsnew drugsnew pharmacological therapeuticnew therapeutic approachnew therapeutic interventionnew therapeutic strategiesnew therapeuticsnew therapynew therapy approachesnew treatment approachnew treatment strategynext generation therapeuticsnitrationnovelnovel drug classnovel drug treatmentsnovel drugsnovel pharmaco-therapeuticnovel pharmacological therapeuticnovel therapeutic approachnovel therapeutic interventionnovel therapeutic strategiesnovel therapeuticsnovel therapynovel therapy approachnuclear factor kappa betaparentpeptide analogpeptide mimeticpeptide mimicpeptidomimeticsperoxynitritepharmaceutical interventionpharmacokinetics and pharmacodynamicspharmacologicpharmacological interventionpharmacological therapypharmacology interventionpharmacology treatmentpharmacophorepharmacotherapeuticspig modelpiglet modelplasmalemmapneumonia modelpneumonia modelspolypeptideporcineporcine modelpre-clinicalpreclinicalpreservationpreventpreventingpulmonary damagepulmonary injurypulmonary microvascular endothelial cellspulmonary tissue damagepulmonary tissue injurypulmonary vascular endothelial cellsrecruitrenal clearancerespiratory virusresponsesafety studysepsis ARDSsepsis acute respiratory distress syndromesepsis and acute respiratory distress syndromesepsis associated acute respiratory distress syndromesepsis induced ARDSsepsis induced acute respiratory distress syndromesepsis related acute respiratory distress syndromesocial rolespike proteins on SARS-CoV-2suidswine modeltherapeutic outcometherapeutic targettherapeutically effectivetherapy outcometreatment strategyvalidationswet lung
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Full Description

ABSTRACT
Acute lung injury (ALI) and acute respiratory distress syndrome (ARDS) manifest with acute lung inflammation
with increased vascular permeability. Treatment of ALI/ARDS patients with low-volume mechanical ventilation is
the only proven therapy for ALI/ARDS, and mortality rates remain unacceptable. Because the syndrome of acute
respiratory failure is so common in the United States and worldwide, especially in the face of relatively new
respiratory viruses such as SARS-CoV-2, ALI/ARDS is an unmet medical need. Novel pharmacological therapies
need to be developed to further improve clinical outcomes in ALI/ARDS patients. RhoA and Rac1 exert distinct
effects on epithelial and endothelial barrier function via selective structural and biochemical modulation of
junctional proteins. Rac1 and RhoA have antagonistic effects on endothelial barrier function in the lung. Rac1 is
required for the assembly and maturation of endothelial junctions, whereas RhoA destabilizes endothelial
junctions by increasing the isometric tension at the cell membrane, increasing myosin contractility. Our prior
studies have linked RhoA nitration at (Tyr (Y)34) with its activation, endothelial barrier disruption, the disruption
of mitochondrial network dynamics, mitochondrial function, and the activation of NF-kb dependent inflammation.
A strategy has been designed to shield RhoA from nitration at Y34, protect endothelial barrier function, preserve
mitochondrial function, and reduce inflammation during conditions that can cause ALI/ARDS. This strategy
identified a small peptide, NipR1, which protects RhoA from nitration at Y34 and prevents LPS-induced
peroxynitrite attack. NipR1 contains nine amino acids from 31–39 of RhoA fused with the cell-permeable TAT
sequence. Natural peptides have poor absorption, distribution, metabolism, and excretion (ADME) properties
with rapid clearance, short half-life, low permeability, and sometimes low solubility. Thus, in response to this
special NHLBI RFA, a chemical approach will be utilized to identify more potent peptidomimetics of NipR1.
In the R61 phase, we will generate ~100 compounds based on our newly identified pharmacophores and screen
them using both in vitro and in vivo assays in multiple mouse models of ALI. In the R33 phase, we will generate
two optimized NipR1 derivatives, conduct pharmacokinetics/pharmacodynamics (PK/PD) and safety studies,
and confirm therapeutic effects using a pig model of sepsis. We anticipate these studies will allow us to identify
a lead compound with desired in vitro and in vivo characteristics as a novel therapy for ALI/ARDS.

Grant Number: 1R61HL171783-01A1
NIH Institute/Center: NIH
Principal Investigator: Stephen Black

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