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Epigenomics Volume 16, 2024 - Issue 3
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Short Communication

Hypomethylation of Wnt Signaling Regulator Genes in Developmental Language Disorder

Mary Iype1 Dept. of Neurology, Institute for Communicative & Cognitive Neurosciences (ICCONS), Thiruvananthapuram, 695 011, Kerala, IndiaView further author information
,
Nisha Melempatt2 Dept. of Audiology & Speech Language Pathology, ICCONS, Shoranur, Palakkad, 679 523, Kerala, IndiaView further author information
,
Jesmy James3 Dept. of Neurogenetics, ICCONS, Shoranur, Palakkad, 679 523, Kerala, IndiaView further author information
,
Sanjeev V Thomas1 Dept. of Neurology, Institute for Communicative & Cognitive Neurosciences (ICCONS), Thiruvananthapuram, 695 011, Kerala, India;4 Dept. of Neurology, ICCONS, Shoranur, Palakkad, 679 523, Kerala, IndiaView further author information
&
Ayyappan Anitha3 Dept. of Neurogenetics, ICCONS, Shoranur, Palakkad, 679 523, Kerala, IndiaCorrespondence[email protected]
ORCID Iconhttps://orcid.org/0000-0001-6767-2694View further author information
ORCID Icon
Pages 137-146 | Received 03 Oct 2023, Accepted 08 Jan 2024, Published online: 24 Jan 2024

References

  • Hulme C , Snowling MJ . Developmental Disorders of Language Learning and Cognition. Wiley Blackwell, West Sussex, UK (2009).
  • Kraljevic JK . Can prevalence data help us identify developmental language disorder? Lancet Reg. Health West. Pac. 34, 100714 (2023).
  • Flax JF , Realpe-Bonilla T , Hirsch LS , Brzustowicz LM , Bartlett CW , Tallal P . Specific language impairment in families: evidence for co-occurrence with reading impairments. J. Speech Lang. Hear. Res. 46(3), 530–543 (2003).
  • Webster RI , Shevell MI . Neurobiology of specific language impairment. J. Child Neurol. 19(7), 471–481 (2004).
  • Jernigan TL , Hesselink JR , Sowell E , Tallal PA . Cerebral structure on magnetic resonance imaging in language- and learning-impaired children. Arch. Neurol. 48(5), 539–545 (1991).
  • Plante E , Swisher L , Vance R , Rapcsak S . MRI findings in boys with specific language impairment. Brain Lang. 41(1), 52–66 (1991).
  • Gauger LM , Lombardino LJ , Leonard CM . Brain morphology in children with specific language impairment. J. Speech Lang. Hear. Res. 40(6), 1272–1284 (1997).
  • Ors M , Lindgren M , Blennow G , Nettelbladt U , Sahlen B , Rosén I . Auditory event-related brain potentials in children with specific language impairment. Eur. J. Paediatr. Neurol. 6(1), 47–62 (2002).
  • Stanton-Chapman TL , Chapman DA , Bainbridge NL , Scott KG . Identification of early risk factors for language impairment. Res. Dev. Disabil. 23(6), 390–405 (2002).
  • Bishop DV , North T , Donlan C . Genetic basis of specific language impairment: evidence from a twin study. Dev. Med. Child Neurol. 37(1), 56–71 (1995).
  • Bishop DV . How does the brain learn language? Insights from the study of children with and without language impairment. Dev. Med. Child Neurol. 42(2), 133–142 (2000).
  • Bae B , Jayaraman D , Walsh CA . Genetic changes shaping the human brain. Dev. Cell 32(4), 423–434 (2015).
  • Kang HJ , Kawasawa YI , Cheng F et al. Spatio-temporal transcriptome of the human brain. Nature 478(7370), 483–489 (2011).
  • Fagiolini M , Jensen CL , Champagne FA . Epigenetic influences on brain development and plasticity. Curr. Opin. Neurobiol. 19(2), 207–212 (2009).
  • Smith ZD , Meissner A . DNA methylation: roles in mammalian development. Nat. Rev. Genet. 14(3), 204–220 (2013).
  • Spiers H , Hannon E , Schalkwyk LC et al. Methylomic trajectories across human fetal brain development. Genome Res. 25(3), 338–352 (2015).
  • Aryee MJ , Jaffe AE , Corrada-Bravo H et al. Minfi: a flexible and comprehensive Bioconductor package for the analysis of Infinium DNA methylation microarrays. Bioinformatics 30(10), 1363–1369 (2014).
  • Morris TJ , Butcher LM , Feber A et al. ChAMP: 450k chip analysis methylation pipeline. Bioinformatics 30(3), 428–430 (2014).
  • Müller F , Scherer M , Assenov Y et al. RnBeads 2.0: comprehensive analysis of DNA methylation data. Genome Biol. 20(1), 55 (2019).
  • Assenov Y , Müller F , Lutsik P , Walter J , Lengauer T , Bock C . Comprehensive analysis of DNA methylation data with RnBeads. Nat. Methods 11(11), 1138–1140 (2014).
  • Aleksander SA , Balhoff J , Gene Ontology Consortium et al. The Gene Ontology knowledgebase in 2023. Genetics 224(1), iyad031 (2023).
  • Parkinson H , Kapushesky M , Shojatalab M et al. ArrayExpress – a public database of microarray experiments and gene expression profiles. Nucleic Acids Res. 35(Database issue), D747–750 (2007).
  • Alejandra Auza B . Language development as an objective indicator of neurodevelopment. Schol. J. Otolaryngol. 3(2), doi: 10.32474/SJO.2019.03.000158 (2019).
  • Kraft SJ , DeThorne LS . The brave new world of epigenetics: embracing complexity in the study of speech and language disorders. Curr. Dev. Disord. Rep. 1(3), 207–214 (2014).
  • Sriganesh R , Ponniah RJ . Genetics of language and its implications on language interventions. J. Genet. 97(5), 1485–1491 (2018).
  • Stromswold K . The heritability of language: a review and metaanalysis of twin, adoption, and linkage studies. Language 77(4), 647–723 (2001).
  • Badcock NA , Bishop DVM , Hardiman MJ , Barry JG , Watkins KE . Co-localisation of abnormal brain structure and function in specific language impairment. Brain Lang. 120(3), 310–320 (2012).
  • Lee JC , Dick AS , Tomblin JB . Altered brain structures in the dorsal and ventral language pathways in individuals with and without developmental language disorder (DLD). Brain Imaging Behav. 14(6), 2569–2586 (2020).
  • Simmonds AJ , Leech R , Iverson P , Wise RJS . The response of the anterior striatum during adult human vocal learning. J. Neurophysiol. 112(4), 792–801 (2014).
  • Krishnan S , Cler GJ , Smith HJ et al. Quantitative MRI reveals differences in striatal myelin in children with DLD. eLife 11, e74242 (2022).
  • de Faria O , Gonsalvez DG , Nicholson M , Xiao J . Activity-dependent central nervous system myelination throughout life. J. Neurochem. 148(4), 447–461 (2019).
  • Mulligan KA , Cheyette BNR . Neurodevelopmental perspectives on Wnt signaling in psychiatry. Mol. Neuropsychiatry 2(4), 219–246 (2017).
  • Mulligan KA , Cheyette BNR . Wnt signaling in vertebrate neural development and function. J. Neuroimmune Pharmacol. 7(4), 774–787 (2012).
  • Tawk M , Makoukji J , Belle M et al. Wnt/β-catenin signaling is an essential and direct driver of myelin gene expression and myelinogenesis. J. Neurosci. 31(10), 3729–3742 (2011).
  • Fancy SPJ , Baranzini SE , Zhao C et al. Dysregulation of the Wnt pathway inhibits timely myelination and remyelination in the mammalian CNS. Genes Dev. 23(13), 1571–1585 (2009).
  • Kwan V , Unda BK , Singh KK . Wnt signaling networks in autism spectrum disorder and intellectual disability. J. Neurodev. Disord. 8, 45 (2016).
  • Zhang Y , Yuan X , Wang Z , Li R . The canonical Wnt signaling pathway in autism. CNS Neurol. Disord. Drug Targets 13(5), 765–770 (2014).
  • Shimomura Y , Agalliu D , Vonica A et al. APCDD1 is a novel Wnt inhibitor mutated in hereditary hypotrichosis simplex. Nature 464(7291), 1043–1047 (2010).
  • Vonica A , Bhat N , Phan K et al. APCDD1 is a dual BMP/Wnt inhibitor in the developing nervous system and skin. Dev. Biol. 464(1), 71 (2020).
  • Ren Q , Chen J , Liu Y . LRP5 and LRP6 in Wnt signaling: similarity and divergence. Front. Cell Dev. Biol. 9, 670960 (2021).
  • Huang Y , Zhang Q , Song N-N et al. Lrp5/6 are required for cerebellar development and for suppressing TH expression in Purkinje cells via β-catenin. Mol. Brain 9, 7 (2016).
  • Grünblatt E , Nemoda Z , Werling AM et al. The involvement of the canonical Wnt-signaling receptor LRP5 and LRP6 gene variants with ADHD and sexual dimorphism: association study and meta-analysis. Am. J. Med. Genet. B Neuropsychiatr. Genet. 180(6), 365–376 (2019).
  • Willems B , Tao S , Yu T , Huysseune A , Witten PE , Winkler C . The Wnt co-receptor Lrp5 is required for cranial neural crest cell migration in zebrafish. PLoS ONE 10(6), e0131768 (2015).
  • Tsukiyama T , Yamaguchi TP . Mice lacking Wnt2b are viable and display a postnatal olfactory bulb phenotype. Neurosci. Lett. 512(1), 48–52 (2012).
  • Abu-Khalil A , Fu L , Grove EA , Zecevic N , Geschwind DH . Wnt genes define distinct boundaries in the developing human brain: implications for human forebrain patterning. J. Comp. Neurol. 474(2), 276–288 (2004).
  • Zandi PP , Belmonte PL , Willour VL et al. Association study of Wnt signaling pathway genes in bipolar disorder. Arch. Gen. Psychiatry 65(7), 785–793 (2008).

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