Skeletal dysplasia is an umbrella term that includes more than 200 individual inherited conditions that affect bone and cartilage growth. It is typically characterised with short stature and legs, arms, trunk or skull can be of abnormal size and shape. The estimated incidence is 1 in 5000 live births with the most common type being achondroplasia1. If untreated, skeletal dysplasia can lead to difficulty breathing, including apnea, spinal problems, fluid build-up around the brain, chronic ear infections, and obesity.
Hundreds of genes have now been associated with skeletal dysplasia. Using a hand-curated gene list from our development partners at Emory University, the CytoSure® Skeletal Dysplasia Research array contains probes targeting 234 medically-relevant genes.
Inherited genetic disorders can be caused by a variety of chromosomal aberrations, including point mutations and small CNVs (Figure 1). Different methodologies are combined to accurately detect these changes, with one of the most successful combinations being targeted NGS and array comparative genomic hybridisation (aCGH)2. Using highly-targeted, exon-focused arrays as part of this combined approach has been shown to detect small CNVs (Figure 2).
The concept of using highly targeted gene-focused arrays to screen specific loci has been developed in collaboration with leading molecular genetics experts at Emory University and has now been implemented in multiple labs worldwide.
Figure 1: The mutation spectrum of molecular disorders includes point mutations and deletions and duplications. The prevalence of each type of variant is highly dependent on the disease studied.
Figure 2: CytoSure Interpret Software enables easy detection and visualisation of small aberrations. Shown here is a 801bp micro-aberration causing partial deletion of exon 6 in the PAH gene (which in conjunction with a point mutation is causative of phenlyketonuria). Data kindly provided by Madhuri Hegde, Ph.D., FACMG, Emory University.
To detect these micro aberrations, highly optimised probes are required. The probes have been selected from OGT’s proprietary Oligome™ database — a database of over 25 million in silico optimised oligonucleotide probes. CytoSure arrays utilise 60-mer oligonucleotide probes, which have been shown to offer higher signal-to-noise ratios through increased specificity and sensitivity3. To further improve performance, during the design process multiple probes are designed for each of the target regions. These probes are tested in competitive hybridisation experiments and ranked based on technical performance — with only the best performing probes being chosen for the final array design. In addition, further experimental validation using clinical research samples has been performed by Emory University who collaborated in the design and optimisation of CytoSure Disease- Focused Research arrays.
Genetic analysis is typically done in batches to ensure cost-effective processing. However, collecting sufficient samples for rare disorders can significantly delay time to reporting. Through combining informative probes for multiple molecular disorders on a single array, CytoSure Disease-Focused Research arrays allow immediate and accurate processing of diverse samples, thereby reducing both time-to-results and cost.
Each CytoSure Disease-Focused Research array can be modified to create bespoke custom arrays, to suit your specific requirements. The customisation process is made easy with a dedicated project manager from our team of experienced computational biologists assigned to each new project. Additional content, specific to your research interest, can easily be selected from any existing array, our Oligome™ database of pre-optimised probes, or designed de novo to your specifications using our proprietary probe design pipeline. Delivery of your custom array only occurs once you are completely satisfied with the design. A number of array formats are available to suit your design and throughput requirements, with the most typical being 8x60k or 4x180k.
All CytoSure arrays are provided with CytoSure Interpret Software which is a powerful, easy-to-use package for the analysis of aCGH data. Innovative features such as the Accelerate Workflow enable standardised and automated data analysis, including automatic aberration detection and classification. In addition, extensive annotation tracks covering syndromes, genes, exons, CNV and recombination hotspots — each of which link to publicly available databases — can be used to provide results in context (Figure 3).
All CytoSure arrays have been validated using CytoSure Genomic DNA Labelling Kits; these labelling kits have been developed and optimised to enable rapid delivery of high-quality results with excellent signal-to-noise ratios. The kits offer faster and simpler DNA labelling and clean-up than alternative enzymatic labelling procedures with improved data quality. Two kit formats are available; the CytoSure Genomic DNA Labelling Kit for 24 samples processed in tubes or the CytoSure HT Genomic DNA Labelling Kit for plate-based processing of up to 96 samples. For best results, CytoSure Genomic DNA Labelling Kits should be used with all CytoSure arrays to give the best derivative log ratio spread (DLRS) values and signal-to-noise ratios ensuring accurate detection of even the smallest aberration.
Increasing numbers of aCGH samples combined with higher-throughput array formats means that it is imperative to track samples throughout the labelling, hybridisation and analysis process to maintain sample identity. CytoSure Sample Tracking Spike-ins are uniquely designed to enable reliable sample tracking and easy identification of sample mix-up using OGT’s CytoSure Disease-Focused Research arrays and class-leading CytoSure Interpret Software.
OGT has the experience and expertise required to optimise the design of microarrays, which is why we chose to partner with them.
Dr Madhuri Hegde
Executive Director, Emory Genetics Lab, USA