grant

Development of genetically encoded sex hormone biosensors to understand neuroactive steroid signaling dynamics in vivo

Organization UNIVERSITY OF WASHINGTONLocation SEATTLE, UNITED STATESPosted 1 Sept 2025Deadline 31 Aug 2027
NIHUS FederalResearch GrantFY20252-photonAccelerationAddressAffective DisordersAffinityAgingAndrogen ReceptorAndrogenic AgentsAndrogenic CompoundsAndrogensAnimal ModelAnimal Models and Related StudiesAnimalsAquadiolAreaBehaviorBehavioralBenchmarkingBest Practice AnalysisBiosensorBody TissuesBrainBrain Nervous SystemBreast CancerCell BodyCell Communication and SignalingCell SignalingCellsCognitionCorrelation StudiesDegenerative Neurologic DisordersDetectionDevelopmentDimenformonDiogynDiogynetsDiseaseDisorderELISAERalphaERαESR1ESR1 geneEncephalonEndocrineEndocrine Gland SecretionEngineeringEnzyme-Linked Immunosorbent AssayEstraceEstradiolEstradiol Receptor alphaEstradiol Receptor αEstradiol-17 betaEstradiol-17betaEstraldineEstrogen Receptor 1Estrogen Receptor alphaEstrogen Receptor αEstrogen ReceptorsEstrogensFP593FemaleFiberFutureGene ExpressionGenomicsGoalsGonadal Steroid HormonesHealthHigh Throughput AssayHormone useHormonesHumanHypothalamic structureHypothalamusIn vivo two-photon calcium imagingInterventionIntracellular Communication and SignalingKnowledgeLigand BindingLigandsLiquid substanceMalignant Breast NeoplasmMalignant neoplasm of prostateMalignant prostatic tumorMammalian CellMass Photometry/Spectrum AnalysisMass SpectrometryMass SpectroscopyMass SpectrumMass Spectrum AnalysesMass Spectrum AnalysisMeasurementMental HealthMental HygieneMethodsMiceMice MammalsModern ManMolecular ConfigurationMolecular ConformationMolecular StereochemistryMonitorMood DisordersMoodsMurineMusNR3A1Nerve CellsNerve Impulse TransmissionNerve TransmissionNerve UnitNervous System Degenerative DiseasesNeural CellNeural Degenerative DiseasesNeural degenerative DisordersNeurocyteNeurodegenerative DiseasesNeurodegenerative DisordersNeurologic Degenerative ConditionsNeuronal TransmissionNeuronsNoiseNuclear ReceptorsOutcomeOvocyclinOvocylinPhasePhotometryPhysiologicPhysiologicalPhysiologyPopulationProgynonProstate CAProstate CancerProstate malignancyProteinsPsychological HealthRadioimmunoassayRadioimmunoassay ImmunologicRapid screeningReceptor ProteinReporterReproductive BehaviorReproductive HealthReproductive MedicineResearchResolutionRoleSamplingSex HormonesSex Steroid HormonesSignal TransductionSignal Transduction SystemsSignalingSpecific qualifier valueSpecifiedStatistical CorrelationSteroid CompoundSteroidsStructureTechnologyTherapeuticTherapeutic AndrogenTherapeutic EstradiolTherapeutic EstrogenTherapeutic HormoneTherapeutic InterventionTherapeutic Steroid HormoneTimeTissuesVariantVariationWorkanti-cancer researchawakeaxon signalingaxon-glial signalingaxonal signalingbenchmarkbiological sensorbiological signal transductionbrain cellcancer researchcardiovascular healthcell typeconformationconformationalconformational stateconformationallyconformationsdegenerative diseases of motor and sensory neuronsdegenerative neurological diseasesdesigndesigningdevelopmentaldrFP583ds red proteindsFP593enzyme linked immunoassayexperimentexperimental researchexperimental studyexperimentsfluidfluorophoreglia signalingglial signalinggonadal steroidshigh throughput screeninghormonal signalshormone signalshypothalamicimaging in vivoimprovedin vivoin vivo calcium imagingin vivo imagingin vivo monitoringinnovateinnovationinnovativeinnovative technologiesinsightintervention therapylenslensesliquidmalemalignant breast tumormodel of animalmotivated behaviornerve signalingneuralneural circuitneural circuitryneural signalingneuroactive steroidsneurocircuitryneurodegenerative illnessneuronalneuronal excitabilityneuronal signalingneurosteroidsneurotransmissionnovelpersonalization of treatmentpersonalized medicinepersonalized therapypersonalized treatmentpreventpreventingprototypereal time monitoringrealtime monitoringreceptorred fluorescent proteinredshiftresolutionsresponsescreeningscreeningssensorsexsex steroidsocial rolespatial and temporalspatial temporalspatiotemporalsteroid hormonesynaptic circuitsynaptic circuitrytargeted drug therapytargeted drug treatmentstargeted therapeutictargeted therapeutic agentstargeted therapytargeted treatmenttemporal measurementtemporal resolutiontime measurementtooltwo-photon
Sign up free to applyApply link · pipeline · email alerts
— or —

Get email alerts for similar roles

Weekly digest · no password needed · unsubscribe any time

Full Description

ABSTRACT/SUMMARY
Understanding the role of sex steroids like estrogens and androgens within the brain is crucial for elucidating
their impact on various brain functions, including mood, cognition, and reproductive behavior. However, our
current understanding of how these steroids modulate neuronal physiology and behavior in vivo remains limited,
largely due to the absence of technologies capable of monitoring these hormones in real time within the brain.
The goal of this project is to bridge this gap by developing a suite of genetically encoded fluorescent biosensors
for steroid hormones. These biosensors will enable cell-specific monitoring of steroid hormone levels in awake
and behaving animals, providing unprecedented insights into the dynamic roles of neuroactive steroids derived
from endocrine tissues or synthesized within the brain.
Our central goal is to engineer green fluorescent biosensors for estrogens and androgens based on their nuclear
receptors. By incorporating fluorescent reporters into receptor regions that change conformation upon ligand
binding, we aim to create sensors with enhanced ligand affinity and signal strength through structure-guided
engineering and high-throughput screening. Additionally, we plan to develop far-red shifted sensors for
multiplexed applications, extending our innovative approach to a broader spectrum of steroid hormones.
Our project is innovative because it employs structure-guided design and a high-throughput engineering platform
to rapidly screen thousands of protein variants. This approach significantly accelerates the development of
biosensors capable of real-time steroid hormone monitoring in vivo. Furthermore, by applying these sensors to
study the rapid effects of steroid signaling on neural activity in the hypothalamus of behaving mice, we aim to
dissect the temporal dynamics of steroid action beyond their genomic effects.
This research is significant because it addresses a critical gap in our ability to study steroid hormones in live
animals. By providing tools for real-time monitoring of steroid hormone signaling within genetically specified brain
cell types, we pave the way for a deeper understanding of how steroids influence brain circuit function and
behavior. The successful completion of this project will not only advance our knowledge of steroid hormone
dynamics but also offer new avenues for therapeutic intervention in steroid-related disorders.

Grant Number: 1R21MH139056-01A1
NIH Institute/Center: NIH
Principal Investigator: Andre Berndt

Sign up free to get the apply link, save to pipeline, and set email alerts.

Sign up free →

Agency Plan

7-day free trial

Unlock procurement & grants

Upgrade to access active tenders from World Bank, UNDP, ADB and more — with email alerts and pipeline tracking.

$29.99 / month

  • 🔔Email alerts for new matching tenders
  • 🗂️Track tenders in your pipeline
  • 💰Filter by contract value
  • 📥Export results to CSV
  • 📌Save searches with one click
Start 7-day free trial →

Explore more

📍 More grants in UNITED STATES🏷 More NIH opportunities🏷 More US Federal opportunities🏷 More Research Grant opportunities🏢 All nih_reporter opportunities