grant

Defining Human Cytochrome P450 7B1 Structure and Function to Understand Spastic Paraplegia Type 5 Disease

Organization UNIVERSITY OF MICHIGAN AT ANN ARBORLocation ANN ARBOR, UNITED STATESPosted 1 Jan 2025Deadline 31 Dec 2027
NIHUS FederalResearch GrantFY20252-dimensional21+ years old25-hydroxycholesterol27-hydroxycholesterol5-cholestene-3 beta,27-diolAbnormal gaitAcidsActive SitesActivities of Daily LivingActivities of everyday lifeAddressAdultAdult HumanAffectAgeAllelesAllelomorphsAmentiaAssayBile Acid BiosynthesisBile Acid Biosynthesis PathwayBile AcidsBindingBioassayBiochemicalBiologicalBiological AssayBlood PlasmaBrainBrain Nervous SystemCatalysisCerebellar AtaxiaCerebellar IncoordinationCerebrospinal FluidChaperoneChenic AcidChenique AcidChenodeoxycholic AcidChenodesoxycholic acidChenodiolCoupledCystic FibrosisCytochrome P-450Cytochrome P-450 Enzyme SystemCytochrome P450Cytochrome P450 Family GeneCytochrome aDNA TherapyDNA mutationDefectDegenerative Neurologic DisordersDementiaDevelopmentDiseaseDisorderEncephalonEnvironmentEnzyme GeneEnzymesErb syndromeErb-Charcot syndromeFerroprotoporphyrinFutureGait abnormalityGait disorderGait disturbancesGait dysfunctionGait impairmentGallodesoxycholic AcidGene Transfer ClinicalGenesGenetic ChangeGenetic InterventionGenetic defectGenetic mutationGoalsHemeHenoholHomology ModelingHumanHydroxylasesHydroxylationImpairmentInvestmentsKnowledgeLeadLigand BindingLiverLower ExtremityLower LimbMembraneMembrum inferiusMicrosomesMissense MutationMixed Function OxidasesMixed Function OxygenasesModern ManMolecularMolecular ChaperonesMolecular InteractionMonooxygenasesMotor CellMotor NeuronsMucoviscidosisMuscle AtrophyMuscular AtrophyMutationNerve DegenerationNervous System Degenerative DiseasesNervous System DiseasesNervous System DisorderNeural Degenerative DiseasesNeural degenerative DisordersNeurodegenerative DiseasesNeurodegenerative DisordersNeurologicNeurologic Degenerative ConditionsNeurologic DisordersNeurologicalNeurological DisordersNeuron DegenerationOutcomeOxidation-ReductionP450PalsyParalysedPathway interactionsPatientsPb elementPlasmaPlasma SerumPlegiaProcessPropertyProteinsProtohemeRecombinantsRedoxResearchReticuloendothelial System, Serum, PlasmaRoentgen RaysRoleSeveritiesSingle Crystal DiffractionSpastic ParaplegiaStructureSymptomsTherapeuticToxic effectToxicitiesWalking impairmentX Ray CrystallographiesX-RadiationX-Ray CrystallographyX-Ray Diffraction CrystallographyX-Ray RadiationX-Ray/Neutron CrystallographyX-rayXrayXray Crystallographyadulthoodagesautosomebile acid anabolismbile acid biosynthetic processbile acid formationbile acid synthesisbiologiccerebral spinal fluidcholest-5-ene-3 beta,25-diolcholest-5-ene-3 beta,27-dioldaily living functiondaily living functionalitydeafnessdegenerative diseases of motor and sensory neuronsdegenerative neurological diseasesdevelopmentalearly childhoodferrohemefunctional abilityfunctional capacitygene repair therapygene therapygene-based therapygenetic therapygenome mutationgenomic therapyheavy metal Pbheavy metal leadhepatic body systemhepatic organ systemimprovedinsightmembrane structuremissense single nucleotide polymorphismmissense single nucleotide variantmissense variantmotoneuronmuscle breakdownmuscle degradationmuscle deteriorationmuscle lossmuscle wastingmutantneural degenerationneurodegenerationneurodegenerativeneurodegenerative illnessneurological degenerationneurological diseaseneuronal degenerationneurotoxicoxidation reduction reactionparalysisparalysis spinalis spasticaparalyticparaplegia spasticapathwayprotein foldingprotein functionprotein structureprotein structuresproteins structurerestorationsmall moleculesocial rolespastic spinal paralysisspasticityspinal fluidtwo-dimensionalvisual dysfunction
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Full Description

PROPOSAL ABSTRACT
Human membrane cytochrome P450 7B1 (CYP7B1) is a steroidogenic heme-containing
monooxygenase primarily expressed in liver and brain. CYP7B1 performs 7α-hydroxylation of 25- and
27-hydroxycholesterol to ultimately generate the primary bile acid chenodeoxycholic acid. Biallelic,
missense mutations in CYP7B1 can result in the loss of enzymatic function, causing accumulation of
25-hydroxycholesterol and 27-hydroxycholesterol in plasma and 27-hydroxycholesterol in
cerebrospinal fluid. These mutations cause a neurological disorder called spastic paraplegia type 5
(SPG5). SPG5 patients suffer from severe progressive spasticity and weakness of the lower limbs due
to the degeneration of their lower motor neurons. To date, there are no curative or disease-modifying
treatments available for SPG5 patients, and little is known about how CYP7B1 mutations affect protein
function and cause disease. This proposal takes a first step toward addressing this knowledge gap by
determining wild type CYP7B1 interactions with its substrates and functional defects produced by
common SPG5-causing missense mutations. First, a CYP7B1 X-ray structure will identify active site
residues involved in binding 25-hydroxycholesterol and 27-hydroxycholesterol. Preliminary investment
has yielded highly purified CYP7B1 protein and 2-dimensional plate crystals with 25-
hydroxycholesterol, substantial progress towards an X-ray structure. Second, common SPG5-causing
missense mutations will be assessed to determine protein folding and heme incorporation, ligand
binding capacity, and product formation to understand mutation impact and severity. Preliminary results
reveal a variety of unpredicted effects, including issues with folding and heme incorporation and
reduced substrate binding capacity. Overall, this information will provide the first human CYP7B1
protein structure, permitting identification of active site residues involved in normal substrate binding
and will provide the biological roles of CYP7B1 mutants commonly known to cause SPG5. This
characterization is a first step in advancing our molecular understanding of SPG5 defects, and has the
potential to support future therapeutic treatments for SPG5 patients.

Grant Number: 1F31GM155958-01A1
NIH Institute/Center: NIH
Principal Investigator: Alexandria Chabez

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