Implementation of Long-read Sequencing for the Diagnosis of Rare Diseases.

Overview

Following on from the third national plan for rare diseases (PNMR3), the main objectives of the PNMR4 are to reduce diagnostic uncertainty and dead ends and to strengthen translational research to promote diagnosis and the development of new treatments in the field of rare diseases. To this end, the French Genomic Medicine Plan 2025 (PFMG2025) is organizing the rollout of whole genome sequencing (WGS) for diagnostic purposes. This technological milestone, covering regions outside the coding regions, has recently enabled the identification of variations in the RNU4-2 gene as a major cause of Intellectual Developmental Disorder (IDD), accounting for approximately 0.4% of cases. RNU4-2 is a gene encoding a small nuclear RNA (snRNA), which is not translated into protein, and whose variations are not accessible to exome sequencing techniques. However, based on current knowledge, these techniques are based on short-read sequencing technology and can diagnose up to 50% of patients. It is therefore necessary to develop new techniques to detect variations not identified by these techniques. In this context, the development of third-generation sequencing, particularly using Nanopore technology, now makes it possible to combine genomic and post-genomic approaches through long-read whole genome sequencing coupled with the detection of methylated cytosines on native DNA. This new approach therefore enables the simultaneous detection of point or structural genomic variants, methylation abnormalities, and haplotype reconstruction. Numerous studies have shown that this strategy improves the diagnosis rate of rare diseases and could become a first-line genetic test. DNA methylation is an epigenetic modification that does not cause changes in the genomic sequence but regulates the transcription (RNA synthesis) of genes and therefore their expression. Methylation studies are performed either to establish an episignature or to search for methylation abnormalities. An episignature is the result of a variation in a gene known to regulate methylation marks. Methylation abnormalities are already known and sought after in targeted analysis for certain diseases such as Prader-Willi/Angelman syndromes and Beckwith-Wiedemann/Silver-Russell syndromes. The contribution of methylation analysis to the diagnosis of other diseases has recently been demonstrated. For example, in methylmalonic aciduria and homocystinuria type cblC associated with the autosomal recessive gene MMACHC, promoter methylation analysis revealed hypermethylation linked to the presence of an intronic variant of the PRDX1 gene. This intronic variant leads to the synthesis of an aberrant antisense RNA overlapping the promoter of the MMACHC gene, causing its hypermethylation. In 2024, combined whole-genome and methylation analysis in patients with porokeratosis led to the discovery of the FDFT1 gene. In general, the study of methylation profiles has shown its value in reducing diagnostic uncertainty in patients with rare diseases who have not been diagnosed after genome analysis. The search for methylation abnormalities (or epimutation) at the pan-genomic level in the context of molecular diagnosis of rare diseases remains largely inaccessible and poorly described in the literature. The techniques routinely used for their detection are most often based on bisulfite treatment and PCR amplification. The disadvantages of bisulfite treatment are that it degrades DNA, preventing long-read applications, that it does not distinguish between 5mC and 5hmC methylation, and that failure to treat unmethylated cytosines can lead to false positives . In addition, phase determination with a genomic variant identified in short reads requires complementary techniques such as SNP arrays. This approach therefore appears to be a major technological advance in the fight against diagnostic uncertainty in rare diseases and is part of the move towards precision medicine for patients. As part of our Reference Center for Developmental Anomalies and Malformation Syndromes of Southwest Occitanie Réunion (CRMR ADSOOR) at Bordeaux University Hospital, we have developed clinical and molecular expertise, particularly in the field of developmental anomalies with intellectual development disorders (particularly chromatinopathies and Rubinstein Taybi syndrome and albinism. In 2024, 2,300 consultations were carried out at the CRMR. In addition, 243 and 228 genome or exome analyses were interpreted in our molecular biology laboratory for albinism and intellectual development disorder and malformation syndrome, respectively. Our expertise in these two areas therefore represents the best starting point for the development of this pilot project using this innovative approach at Bordeaux University Hospital.