grant

Why do Down Syndrome patients have high risk of Hirschsprung disease?

Organization NEW YORK UNIVERSITY SCHOOL OF MEDICINELocation NEW YORK, UNITED STATESPosted 15 Sept 2022Deadline 31 Jul 2027
NIHUS FederalResearch GrantFY20253' Untranslated Regions3'UTRAffectAganglionic MegacolonAlimentary CanalAllelesAllelomorphsAneuploidAneuploidyAssayBindingBioassayBiochemicalBiological AssayBlood SampleBlood specimenCDHF12CardiovascularCardiovascular Body SystemCardiovascular Organ SystemCardiovascular systemCell BodyCell DifferentiationCell Differentiation processCell Growth in NumberCell LineCell MultiplicationCell ProliferationCellLineCellsCellular ProliferationChromosome 21CodeCoding SystemColonic AganglionosisComplementary DNACongenital MegacolonDataDefectDiathesisDigestive TractDiseaseDisease susceptibilityDisorderDissociationDown SyndromeEmbryoEmbryonicEngineeringEnhancersEnteralEntericEnteric Nervous SystemExonsFamilyGI TractGastrointestinal TractGastrointestinal tract structureGene ExpressionGene PoolGene Rearranged During TransfectionGenesGeneticGenetic Non-DisjunctionGenetic NondisjunctionGenetic ScreeningHaplotypesHeart VascularHirschsprung DiseaseHumanHuman EngineeringHuman GeneticsIRESImmuneImmunesImmunofluorescenceImmunofluorescence ImmunologicIn Situ HybridizationIndividualIndividuals with down syndromeInternal Ribosome Entry SegmentInternal Ribosome Entry SiteJointsLangdon Down syndromeLeadLinkMeiosisMethodsMiceMice MammalsModern ManMolecular AnalysisMolecular InteractionMongolismMurineMusMusculoskeletalNerve CellsNerve UnitNeural CellNeural Crest CellNeurocyteNeurologicNeurologicalNeuronsNon-Polyadenylated RNAOrganParentsPathologyPathway interactionsPb elementPhenotypePlayPluripotent Stem CellsPopulationProteinsProteomeRET geneRET51RNARNA Gene ProductsRNA SeqRNA sequencingRNAseqRibonucleic AcidRibosome Entry SiteRiskRoleSOD-1SOD-1 proteinSOD1SOD1 geneSOD1 gene productSiteStatistical Data AnalysesStatistical Data AnalysisStatistical Data InterpretationStrains Cell LinesStressSystemTestingTotal Colonic AganglionosisTransmissionTrisomyTrisomy 21ValidationVariantVariationaganglionosisalimentary tractcDNAcellular differentiationchromosome 21 trisomychromosome 21 trisomy syndromechromosome losscirculatory systemcongenital acromicria syndromecultured cell linedifferentiation of pluripotent stem cellsdigestive canaldisease riskdisorder riskdosagedown syndrome individualsdown syndrome patientsfunctional genomicsgain of functiongene networkgene regulatory networkgene testinggene-based testinggenetic associationgenetic testingheavy metal Pbheavy metal leadhigh riskiPSiPSCiPSCsin situ Hybridization Geneticsin situ Hybridization Staining Methodinduced pluripotent cellinduced pluripotent stem cellinducible pluripotent cellinducible pluripotent stem cellliability to diseaseloss of functionmeioticmorbus Downmouse modelmurine modelneurogenesisneuronalnon-disjunctionnondisjunctionnoveloverexpressoverexpressionparentpathwaypatients with down syndromepelvirectal achalasiapeople with down syndromepluripotent progenitorpluripotent stem cell differentiationprobandprogenitor cell modelprogenitor modelpseudohypertrophic progressive muscular dystrophyscRNA sequencingscRNA-seqsingle cell RNA-seqsingle cell RNAseqsingle cell expression profilingsingle cell transcriptomic profilingsingle-cell RNA sequencingsocial rolespatial and temporalspatial temporalspatiotemporalstatistical analysisstem and progenitor cell modelstem cell based modelstem cell derived modelstem cell modelsuperoxide dismutase 1traittranscriptome sequencingtranscriptomic sequencingtransmission processtrisomy 21 syndromevalidations
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Full Description

ABSTRACT:
Down syndrome (DS), resulting from trisomy 21 (T21), has many associated defects, a hallmark being the 100-
fold higher risk of Hirschsprung disease (HSCR or congenital colonic aganglionosis). The mechanism of this
association is elusive, but a critical clue is that a common RET enhancer variant, associated with non-
syndromic HSCR, is also associated with DS cases with HSCR but not DS cases without. These data suggest
that the association is from increased dosage of chromosome 21 (HSA21) genes dysregulating the RET-EDNRB
gene regulatory network (GRN) to increase HSCR risk, a mechanism likely explaining other DS traits. One
specific HSA21 candidate is SOD1, a putative negative regulator of RET, that can further reduce RET
expression in DS cases with RET deficiency enhancer alleles. Further, aneuploidy-specific protein imbalance
can also affect cell proliferation and HSCR. Here, we propose three aims investigating human genetics,
functional genomics in engineered pluripotent stem cells (iPSC) and mouse models of HSA21 genes and RET,
to understand the mechanisms by which HSA21 gene-specific and T21-specific genetic effects lead to HSCR-
associated DS.

Grant Number: 4R01DK135089-02
NIH Institute/Center: NIH
Principal Investigator: ARAVINDA CHAKRAVARTI

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