Characterization of terminal chromosome anomalies using multisubtelomere FISH

Validation and implementation of array comparative genomic hybridisation as a first line test in place of postnatal karyotyping for genome imbalance

BACKGROUND

Several studies have demonstrated that array comparative genomic hybridisation (CGH) for genome-wide imbalance provides a substantial increase in diagnostic yield for patients traditionally referred for karyotyping by G-banded chromosome analysis. The purpose of this study was to demonstrate the feasibility of and strategies for, the use of array CGH in place of karyotyping for genome imbalance, and to report on the results of the implementation of this approach.

RESULTS

Following a validation period, an oligoarray platform was chosen. In order to minimise costs and increase efficiency, a patient/patient hybridisation strategy was used, and analysis criteria were set to optimise detection of pathogenic imbalance. A customised database application with direct links to a number of online resources was developed to allow efficient management and tracking of patient samples and facilitate interpretation of results. Following introduction into our routine diagnostic service for patients with suspected genome imbalance, array CGH as a follow-on test for patients with normal karyotypes (n = 1245) and as a first-line test (n = 1169) gave imbalance detection rates of 26% and 22% respectively (excluding common, benign variants). At least 89% of the abnormalities detected by first line testing would not have been detected by standard karyotype analysis. The average reporting time for first-line tests was 25 days from receipt of sample.

CONCLUSIONS

Array CGH can be used in a diagnostic service setting in place of G-banded chromosome analysis, providing a more comprehensive and objective test for patients with suspected genome imbalance. The increase in consumable costs can be minimised by employing appropriate hybridisation strategies; the use of robotics and a customised database application to process multiple samples reduces staffing costs and streamlines analysis, interpretation and reporting of results. Array CGH provides a substantially higher diagnostic yield than G-banded chromosome analysis, thereby alleviating the burden of further clinical investigations.

An oligonucleotide based array-CGH system for detection of genome wide copy number changes including subtelomeric regions for genetic evaluation of mental retardation

Developmental delay (DD) and mental retardation (MR) are important child heath issues with a one percent prevalence. Karyotyping with or without subtelomeric FISH (fluorescent in situ hybridization), unless the phenotype of the patient suggests a specific aberration for a specific FISH assay, is the most common procedure in cytogenetic evaluation of MR/DD. In addition, there are several platforms utilizing microarray based comparative genomic hybridization technology (array-CGH) for genetic testing. Array-CGH can detect deletions or duplications in very small segments of chromosomes and the use of this technology is expected to increase the diagnostic yield. The major limitation of the current BAC based array technologies is the low resolution ( approximately 1 Mb) of the chip and suboptimal coverage particularly in the subtelomeric regions. Our aim was to design a novel array-CGH chip with high-density of probes in the subtelomeric regions as well as to maintain sufficient density in other regions of the genome to provide comprehensive coverage for DD/MR. For this purpose, we used Human Genome CGH Microarray 44B chip (Agilent) as the template for the novel design. Using e-array 4.0 (Agilent), one third of the probes were randomly removed from the array and replaced by 14,000 subtelomeric probes. The average density of the probe coverage is 125 kb and 250-400 probes interrogate subtelomeric regions. To evaluate the array, we tested 15 samples (including subtelomeric aberrations and other microdeletion syndromes), which were previously analyzed by karyotyping and/or FISH. The concordance rate between array results and previous results is 100%. In addition we detected two novel aberrations that were not detected by karyotyping. These results demonstrate the utility of this format of array-CGH in detecting genome wide submicroscopic copy number changes as well as providing comprehensive coverage of all subteleomeric regions.

Detection of subtelomere imbalance using MLPA: validation, development of an analysis protocol, and application in a diagnostic centre

BACKGROUND

Commercial MLPA kits (MRC-Holland) are available for detecting imbalance at the subtelomere regions of chromosomes; each kit consists of one probe for each subtelomere.

METHODS

For validation of the kits, 208 patients were tested, of which 128 were known to be abnormal, corresponding to 8528 genomic regions overall. Validation samples included those with trisomy 13, 18 and 21, microscopically visible terminal deletions and duplications, sex chromosome abnormalities and submicroscopic abnormalities identified by multiprobe FISH. A robust and sensitive analysis system was developed to allow accurate interpretation of single probe results, which is essential as breakpoints may occur between MLPA probes.

RESULTS

The validation results showed that MLPA is a highly efficient technique for medium-throughput screening for subtelomere imbalance, with 95% confidence intervals for positive and negative predictive accuracies of 0.951-0.996 and 0.9996-1 respectively. A diagnostic testing strategy was established for subtelomere MLPA and any subsequent follow-up tests that may be required. The efficacy of this approach was demonstrated during 15 months of diagnostic testing when 455 patients were tested and 27 (5.9%) abnormal cases were detected.

CONCLUSION

The development of a robust, medium-throughput analysis system for the interpretation of results from subtelomere assays will be of benefit to other Centres wishing to implement such an MLPA-based service.

Idiopathic learning disability and genome imbalance

Learning disability (LD) is a very common, lifelong and disabling condition, affecting about 3% of the population. Despite this, it is only over the past 10-15 years that major progress has been made towards understanding the origins of LD. In particular, genetics driven advances in technology have led to the unequivocal demonstration of the importance of genome imbalance in the aetiology of idiopathic LD (ILD). In this review we provide an overview of these advances, discussing technologies such as multi-telomere FISH and array CGH that have already emerged as well as new approaches that show diagnostic potential for the future. The advances to date have highlighted new considerations such as copy number polymorphisms (CNPs) that can complicate the interpretation of genome imbalance and its relevance to ILD. More importantly though, they have provided a remarkable approximately 15-20% improvement in diagnostic capability as well as facilitating genotype/phenotype correlations and providing new avenues for the identification and understanding of genes involved in neurocognitive function.

A subterminal deletion of the long arm of chromosome 10: a clinical report and review

We report on a girl with mental retardation, dysmorphic features, and behavioral problems. A small terminal deletion of the long arm of chromosome 10 was detected by subtelomeric fluorescence in situ hybridization (FISH) studies in all analyzed metaphases. The deletion was shown to be a de novo terminal deletion of approximately 6.1 Mb, with the deletion breakpoint localized at band 10q26.2, between BAC probes RP11-498K22 and RP11-42K2. A subterminal 10q deletion as found in the present patient has, to our knowledge, only been reported in 15 patients (including 8 familial cases). We review the clinical and behavioral phenotype of these patients with "pure" subterminal 10q deletion.

The use of subtelomeric probes to study mental retardation

In this chapter, we focus on the genetic basis of mental retardation (MR), specifically the use of subtelomeric probes to provide new diagnoses in idiopathic MR. We discuss both the background to the clinical demand for diagnoses and the technological advances that culminated in the development of subtelomeric testing strategies. We explain the theory behind these strategies and briefly outline the protocols involved, giving the advantages, limitations, and pitfalls of the analyses. Finally, we give an overview of the MR subtelomeric studies to date and how subtelomeric testing has become a widely used tool in clinical diagnostic laboratories, particularly in the diagnosis of unexplained MR, but also in other fields of clinical medicine. The conclusion addresses the overall impact that subtelomeric testing has had on the diagnosis of MR, the implications for patients and their families, and future research avenues for exploring the genetic causes of MR and improving our overall understanding of neurocognitive development.

Clinical report of a pure subtelomeric 1qter deletion in a boy with mental retardation and multiple anomalies adds further evidence for a specific phenotype

Deletions of the 1q telomere have been reported in several studies screening for subtelomeric rearrangements. However, an adequate clinical description is available from only a few patients. We provide a clinical description of a patient with a subtelomeric deletion of chromosome 1q, previously detected by us in a screening study. Comparison of the clinical presentation of our patient with rare cases reported previously provides further evidence for a specific phenotype of 1q patients, including mental retardation, growth retardation, sometimes with prenatal onset, progressive microcephaly, seizures, hand and foot abnormalities and a variety of midline defects, including corpus callosum, cardiac, genital and gastro-esophageal abnormalities. This clinical presentation is reminiscent of that of patients with larger, microscopically visible deletions of chromosome 1q (>3 Mb) characterized by growth and mental retardation, coarse faces with thin upper lip, epilepsy, and variable other anomalies. In addition, the breakpoint region was mapped to a 26 kb region within the RGS7 gene. Among the 17 known genes in the candidate region, are zinc-finger genes. Other members of this gene family have been implicated in different forms of mental retardation.

Complexde novo cryptic subtelomeric rearrangements in a fetus with multiple ultrasonographic abnormalities and a normal karyotype at amniocentesis

OBJECTIVE

Prenatal diagnosis is usually offered to the majority of pregnancies with fetal structural abnormalities detected by prenatal ultrasound; however, only a small proportion show an abnormal karyotype. We wanted to detect cryptic subtelomeric rearrangements (CSTR) in a fetus with multiple abnormal ultrasonographic findings that revealed a normal karyotype at amniocentesis.

METHODS

Fetal chromosome analysis was performed from amniotic fluid cells. Parental chromosome analysis was done on PHA stimulated lymphocyte cultures. For fluorescence in situ hybridization (FISH) analysis, ToTelVysion multicolor DNA probe mixture was used to hybridize the p and q telomeres of each chromosome.

RESULTS

The amniotic fluid chromosome analysis revealed an apparently normal 46,XY karyotype. A follow-up FISH analysis showed three apparently balanced complex translocations involving (1) the chromosome 4p and 22q telomeres (2) 4q and 11q telomeres and (3) 8p, 20p and 20q telomeres. Parental chromosome and subtelomere FISH analysis was found to be normal.

CONCLUSION

To our knowledge, this is the first report of complex de novo cryptic translocations in an abnormal fetus. These CSTR identified by FISH with subtelomere-specific probes are not detected by other cytogenetic and/or molecular cytogenetic approaches. However, to confirm the balanced nature of CSTR, array-CGH can be helpful. Further studies are in progress to determine the frequency of CSTR and its significance in the etiology of fetal abnormalities.

Use of subtelomeric fluorescence in situ hybridization in cytogenetic diagnosis

During the last few years there has been an increasing number of reports of chromosomal abnormalities identified by subtelomeric fluorescence in situ hybridization testing in children with unexplained mental retardation. As more children are identified with subtelomeric deletions, duplications, and cryptic unbalanced rearrangements by this testing, questions have arisen regarding the appropriate use of this new technology. A review of current knowledge regarding the clinical phenotypes seen in these patients as well as of newer information regarding the use of this new cytogenetic test in areas outside clinical genetics may help to determine which patients would benefit from its use.