WYMM Tour: Birmingham

Currently patients in England with monogenic developmental disorders will undergo NHS genetic testing including microarray and Whole Genome Sequencing (WGS) using short read sequencing (SRS) technology, with additional relevant genetic tests, such as methylation studies. Within this group a genetic diagnosis is made in about 30-40% of individuals. This means that a significant proportion of patients remain undiagnosed. We aim to evaluate the utility of Nanopore long read sequencing (LRS) as a tool to increase the diagnostic rate of suspected monogenic rare developmental disorders. Methods: We identified 28 individuals highly likely to have a monogenic disorder, who have no molecular genetic diagnosis, and have reached the ceiling of investigation within the NHS genomic medicine service. They were recruited as trios and quads (affected patient(s), and their parents) to Understanding the Genomic Basis for Human Disease (Ethics reference: 15/WM/0076, IRAS reference: 159499). Trio (or quad) WGS is performed using the Oxford Nanopore Promethion P24 instrument. We are using a range of existing software packages to study participants' genomes for potentially disease-causing variants including, sequence, copy number, methylation variants, and tandem repeats. Results: We have analysed the first 15 trio samples, identifying a diagnosis of Coffin Siris syndrome in one of these patients and identified the likely molecular cause of another family’s Familial Adenomatous Polyposis. We also will discuss the feasibility of implementation of Nanopore sequencing into clinical diagnostic testing pathway. Conclusion: Nanopore LRS has increased the diagnostic rate for patients with likely monogenic developmental disorders. Grants: Lifearc Pathfinder award and NIHR Research Scholarship

Currently patients in England with monogenic developmental disorders will undergo NHS genetic testing including microarray and Whole Genome Sequencing (WGS) using short read sequencing (SRS) technology, with additional relevant genetic tests, such as methylation studies. Within this group a genetic diagnosis is made in about 30-40% of individuals. This means that a significant proportion of patients remain undiagnosed. We aim to evaluate the utility of Nanopore long read sequencing (LRS) as a tool to increase the diagnostic rate of suspected monogenic rare developmental disorders. Methods: We identified 28 individuals highly likely to have a monogenic disorder, who have no molecular genetic diagnosis, and have reached the ceiling of investigation within the NHS genomic medicine service. They were recruited as trios and quads (affected patient(s), and their parents) to Understanding the Genomic Basis for Human Disease (Ethics reference: 15/WM/0076, IRAS reference: 159499). Trio (or quad) WGS is performed using the Oxford Nanopore Promethion P24 instrument. We are using a range of existing software packages to study participants' genomes for potentially disease-causing variants including, sequence, copy number, methylation variants, and tandem repeats. Results: We have analysed the first 15 trio samples, identifying a diagnosis of Coffin Siris syndrome in one of these patients and identified the likely molecular cause of another family’s Familial Adenomatous Polyposis. We also will discuss the feasibility of implementation of Nanopore sequencing into clinical diagnostic testing pathway. Conclusion: Nanopore LRS has increased the diagnostic rate for patients with likely monogenic developmental disorders. Grants: Lifearc Pathfinder award and NIHR Research Scholarship

Liquid biopsy and cell-free DNA have emerged as important biomarkers in oncology. Current approaches based on the sequencing of mutation or methylation markers recover a small fraction of events that makes cancer. Mining the multiple layers of omics (genomic, epigenomic, transcriptomic, fragmentomic) and analytes (cfDNA, cfRNA, extracellular vesicles) in blood samples from cancer patients have the potential to boost liquid biopsy and unlock new applications.

Neurodevelopmental disorders (NDDs), including schizophrenia, are associated with dysregulated alternative splicing. However, NDD risk genes tend to be lowly expressed and have complex gene models making their isoform identification and quantification challenging with current approaches. This severely impedes the functional interpretation of their variation across tissues, and conditions. We applied CaptureSeq target enrichment coupled with Oxford Nanopore sequencing to characterise and quantify RNA isoform profiles of 1221 protein-coding and lncRNA genes across 52 human post-mortem brain samples: cortex, caudate, and hippocampus from 20 individuals (adult and fetal controls, and 12 adults with a neuropsychiatric diagnosis). We identified 44,624 unique isoforms (88.4% previously unannotated) and revealed 228 significant changes in isoform proportions (i.e. switches) between control adult brain regions, and 257 between adult and fetal cortex, with some switches predicted to impact the coding potential and protein structure. The previously overlooked brain isoform diversity and expression patterns provide us with an opportunity to characterise the functional implications of genetic variation associated with NDDs.

We present ROBIN, a tool based upon PromethION nanopore sequencing technology that can provide both real-time, intraoperative methylome classification and next-day comprehensive molecular profiling within a single assay. We believe that our tool is a significant step change in the ability to apply nanopore adaptive sampling to classification problems and treatment implementation in patients.

We demonstrate classifier performance on 50 prospective intraoperative cases within the context of an NHS pathology laboratory, achieving a sample preparation time under 2 hours and generating robust tumour classifications within minutes of sequencing. Furthermore, ROBIN can detect single nucleotide variants, copy number variants and structural variants in real-time, and is able to inform a complete molecular profile within 24 hours. This greatly improves upon current standard of care turnaround times, with a potentially transformative impact in clinical practice.