{"database":"biostudies-literature","file_versions":[],"scores":null,"additional":{"submitter":["Mak CCY"],"funding":["NICHD NIH HHS"],"pagination":["105677"],"full_dataset_link":["https://www.ebi.ac.uk/biostudies/studies/S-EPMC12242594"],"repository":["biostudies-literature"],"omics_type":["Unknown"],"volume":["115"],"pubmed_abstract":["<h4>Background</h4>Decisions to split two or more phenotypic manifestations related to genetic variations within the same gene can be challenging, especially during the early stages of syndrome discovery. Genotype-based diagnostics with artificial intelligence (AI)-driven approaches using next-generation phenotyping (NGP) and DNA methylation (DNAm) can be utilized to expedite syndrome delineation within a single gene.<h4>Methods</h4>We utilized an expanded cohort of 56 patients (22 previously unpublished individuals) with truncating variants in the MN1 gene and attempted different methods to assess plausible strategies to objectively delineate phenotypic differences between the C-Terminal Truncation (CTT) and N-Terminal Truncation (NTT) groups. This involved transcriptomics analysis on available patient fibroblast samples and AI-assisted approaches, including a new statistical method of GestaltMatcher on facial photos and blood DNAm analysis using a support vector machine (SVM) model.<h4>Findings</h4>RNA-seq analysis was unable to show a significant difference in transcript expression despite our previous hypothesis that NTT variants would induce nonsense mediated decay. DNAm analysis on nine blood DNA samples revealed an episignature for the CTT group. In parallel, the new statistical method of GestaltMatcher objectively distinguished the CTT and NTT groups with a low requirement for cohort number. Validation of this approach was performed on syndromes with known DNAm signatures of SRCAP, SMARCA2 and ADNP to demonstrate the effectiveness of this approach.<h4>Interpretation</h4>We demonstrate the potential of using AI-based technologies to leverage genotype, phenotype and epigenetics data in facilitating splitting decisions in diagnosis of syndromes with minimal sample requirement.<h4>Funding</h4>The specific funding of this article is provided in the acknowledgements section."],"journal":["EBioMedicine"],"pubmed_title":["Artificial intelligence-driven genotype-epigenotype-phenotype approaches to resolve challenges in syndrome diagnostics."],"pmcid":["PMC12242594"],"funding_grant_id":["P50 HD103524","U54 HD083091"],"pubmed_authors":["Klinkhammer H","Amiel J","Hsieh TC","Lee M","Bernat JA","Faivre L","Low KJ","Dempsey JC","Sanchez-Lara PA","Willems M","Reko N","Bukowska-Olech E","Gordon CT","Canham N","Krawitz PM","Mau-Them FT","Vanlerberghe C","Lin AE","Palafoll IV","Doherty D","Zarate YA","Callewaert B","Sarkar A","Duncan L","Jamsheer A","Boute O","Gilard V","Mak CCY","Chui MMC","Goldenberg A","Pisan E","Choufani S","Isidor B","Chung BHY","Leduc F","Bombei HM","Stolerman E","Christman AK","Zankl A","Cogne B","Weksberg R"],"additional_accession":[]},"is_claimable":false,"name":"Artificial intelligence-driven genotype-epigenotype-phenotype approaches to resolve challenges in syndrome diagnostics.","description":"<h4>Background</h4>Decisions to split two or more phenotypic manifestations related to genetic variations within the same gene can be challenging, especially during the early stages of syndrome discovery. Genotype-based diagnostics with artificial intelligence (AI)-driven approaches using next-generation phenotyping (NGP) and DNA methylation (DNAm) can be utilized to expedite syndrome delineation within a single gene.<h4>Methods</h4>We utilized an expanded cohort of 56 patients (22 previously unpublished individuals) with truncating variants in the MN1 gene and attempted different methods to assess plausible strategies to objectively delineate phenotypic differences between the C-Terminal Truncation (CTT) and N-Terminal Truncation (NTT) groups. This involved transcriptomics analysis on available patient fibroblast samples and AI-assisted approaches, including a new statistical method of GestaltMatcher on facial photos and blood DNAm analysis using a support vector machine (SVM) model.<h4>Findings</h4>RNA-seq analysis was unable to show a significant difference in transcript expression despite our previous hypothesis that NTT variants would induce nonsense mediated decay. DNAm analysis on nine blood DNA samples revealed an episignature for the CTT group. In parallel, the new statistical method of GestaltMatcher objectively distinguished the CTT and NTT groups with a low requirement for cohort number. Validation of this approach was performed on syndromes with known DNAm signatures of SRCAP, SMARCA2 and ADNP to demonstrate the effectiveness of this approach.<h4>Interpretation</h4>We demonstrate the potential of using AI-based technologies to leverage genotype, phenotype and epigenetics data in facilitating splitting decisions in diagnosis of syndromes with minimal sample requirement.<h4>Funding</h4>The specific funding of this article is provided in the acknowledgements section.","dates":{"release":"2025-01-01T00:00:00Z","publication":"2025 May","modification":"2026-03-27T15:58:00.537Z","creation":"2025-08-27T03:07:03.795Z"},"accession":"S-EPMC12242594","cross_references":{"pubmed":["40280028"],"doi":["10.1016/j.ebiom.2025.105677"]}}