Making good on the promise of genomics in healthcare: the NSW Health perspective.

NSW Health is implementing genomics as a mainstream component of clinical care. The strategic, holistic approach is considering infrastructure, data governance and management, workforce, education, service planning and delivery. This work is generating insights about how to realise the promise of genomics in healthcare, highlighting the need for strong foundations, real-world application, accessibility and a focus on people using genomic information in clinical care.

A comparison of the lengths of androgen receptor triplet repeats in brain and blood in motor neuron diseases.

BACKGROUND: Expansions of triplet repeats are found in a number of neurodegenerative conditions, and different tissues in the same person can have varying repeat lengths. In Kennedy disease, motor neuron loss is due to expansion of the CAG repeat length in the androgen receptor gene (AR). We hypothesised that patients with other sporadic motor neuron diseases could have AR expansions that were restricted to CNS tissue. METHODS: We measured the AR triplet repeat length in DNA extracted from the brains of 23 patients with sporadic amyotrophic lateral sclerosis (SALS) and 3 with sporadic progressive muscular atrophy (SPMA). Paired blood samples were available in 15 patients to look for blood-brain differences in CAG repeat length. RESULTS: No CAG expansions in the Kennedy disease range were found in the SALS or SPMA brains. Furthermore, no brain-blood differences were found in the lengths of AR triplet repeats. Brain AR repeat length was not associated with the duration, or age or site of onset, of disease. CONCLUSIONS: The findings indicate that a brain-specific expansion of AR triplet repeats is unlikely to underlie motor neuron loss in SALS or SPMA.

Computer-assisted reading of DNA sequences.

DNA sequencing is increasingly used in a range of medical activities involving DNA diagnostics and research. This is the result of improving technology and cheaper costs. Paradoxically, a greater demand for DNA sequencing has placed additional work on the laboratory because sequencing profiles must be checked visually despite the availability of informatics-based tools in interpreting DNA sequence traces. In this environment it is essential to have more sophisticated software that will allow the sites of known and unknown DNA variants to be quickly identified, as well as providing an objective assessment of quality for the DNA sequence generated. This chapter describes the Applied Biosystems SeqScape software program (version 2.5) and how it has assisted in the interpretation of DNA sequencing in a DNA diagnostic laboratory.

Promoter hypermethylation of the O(6)-methylguanine DNA methyltransferase gene and microsatellite instability in metastatic melanoma.

Tumor spread to distant organs is the most serious consequence of melanoma, as only 10-20% of stage IV patients respond to current chemotherapies. Tumor sensitivity to alkylating agents is affected by the activity of cellular DNA repair proteins, such as O(6)-methylguanine DNA methyltransferase (MGMT) and the DNA mismatch repair proteins. Chemosensitivity may be enhanced by reduced MGMT activity, but the frequency of MGMT promoter silencing through hypermethylation is unknown in distant melanoma metastases. The frequency and significance of microsatellite instability (MSI) in metastatic melanoma is also unclear, and it has been suggested that MSI frequency increases during the metastatic process. We undertook an analysis of 84 melanoma metastases from 47 patients. MGMT methylation was detected using methylation-specific PCR in 26 of the 84 metastases (31%), but there was discordance between individual metastases from the same patient. Therefore, as a result of this variation, MGMT methylation may have only limited value as a predictor of chemosensitivity. High MSI involving mononucleotide repeat markers was not found. Low MSI was detected in five of 50 metastases (10%) and only one of the five metastases also had MGMT methylation. These results demonstrate that in contrast to some previous reports, these tumors have a low frequency of MSI.

Low microsatellite instability is associated with poor prognosis in stage C colon cancer.

PURPOSE: The significance of low microsatellite instability (MSI-L) in colorectal cancer is poorly understood. No clear biologic distinction has been found between MSI-L and microsatellite stable (MSS) colorectal cancer, and these two phenotypes are usually combined when analyzed against the well-defined high MSI (MSI-H) phenotype. Evidence is emerging that an O(6)-methylguanine DNA methyltransferase (MGMT) gene defect is associated with MSI-L. Therefore, to further define this phenotype, we undertook a detailed analysis of the prognostic significance of MSI-L and loss of MGMT expression in colon cancer. PATIENTS AND METHODS: The study cohort was 183 patients with clinicopathologic stage C colon cancer who had not received adjuvant therapy. We analyzed MSI status, MGMT, and mismatch repair protein expression, as well as MGMT and p16 promoter hypermethylation. RESULTS: We showed that MSI-L defines a group of patients with poorer survival (P = .026) than MSS patients, and that MSI-L was an independent prognostic indicator (P = .005) in stage C colon cancer. Loss of MGMT protein expression was associated with the MSI-L phenotype but was not a prognostic factor for overall survival in colon cancer. p16 methylation was significantly less frequent in MSI-L than in MSI-H and MSS tumors and was not associated with survival. CONCLUSION: MSI-L characterizes a distinct subgroup of stage C colon cancer patients, including the MSI-L subset of proximal colon cancer, who have a poorer outcome. Neither the MGMT defect nor p16 methylation are likely to contribute to the worse prognosis of the MSI-L phenotype.

Genome-wide significance for a modifier of age at neurological onset in Huntington's disease at 6q23-24: the HD MAPS study.

BACKGROUND: Age at onset of Huntington's disease (HD) is correlated with the size of the abnormal CAG repeat expansion in the HD gene; however, several studies have indicated that other genetic factors also contribute to the variability in HD age at onset. To identify modifier genes, we recently reported a whole-genome scan in a sample of 629 affected sibling pairs from 295 pedigrees, in which six genomic regions provided suggestive evidence for quantitative trait loci (QTL), modifying age at onset in HD. METHODS: In order to test the replication of this finding, eighteen microsatellite markers, three from each of the six genomic regions, were genotyped in 102 newly recruited sibling pairs from 69 pedigrees, and data were analyzed, using a multipoint linkage variance component method, in the follow-up sample and the combined sample of 352 pedigrees with 753 sibling pairs. RESULTS: Suggestive evidence for linkage at 6q23-24 in the follow-up sample (LOD = 1.87, p = 0.002) increased to genome-wide significance for linkage in the combined sample (LOD = 4.05, p = 0.00001), while suggestive evidence for linkage was observed at 18q22, in both the follow-up sample (LOD = 0.79, p = 0.03) and the combined sample (LOD = 1.78, p = 0.002). Epistatic analysis indicated that there is no interaction between 6q23-24 and other loci. CONCLUSION: In this replication study, linkage for modifier of age at onset in HD was confirmed at 6q23-24. Evidence for linkage was also found at 18q22. The demonstration of statistically significant linkage to a potential modifier locus opens the path to location cloning of a gene capable of altering HD pathogenesis, which could provide a validated target for therapeutic development in the human patient.

Challenges for clinical genetic DNA testing.

DNA testing was first used in the late 1970s. Today, the indications for a DNA test have expanded to include predicting the development of genetic disorders, screening populations, confirming clinical diagnoses, prenatal testing and DNA testing to individualize medical treatment. Apart from the wide range of indications, the next few years will see a great expansion in the number of DNA tests. This will be driven by information generated from the Human Genome Project. Improved technology will make DNA testing more accessible. In this climate, the challenges will be considerable, particularly in relation to education. The avoidance of ethical, legal and social dilemmas will require informed and wise input from professionals and the community.

Are enteroviral receptors different in sporadic motor neuron disease?

Enteroviruses have been suspected to play a part in the pathogenesis of sporadic motor neuron disease (SMND). Intercellular adhesion molecule type-1 (ICAM1) and coxsackie and adenovirus receptor (CAR) act as receptors for a number of enteroviruses. We therefore examined the viral binding domains of ICAM1 and CAR to see if any changes could be found that might predispose to enteroviral infections. Single nucleotide polymorphisms in the ICAM1 viral binding domain, the adjacent intron and a region implicated in other neurological disorders, as well as the CAR viral binding regions in exons 2-5, were compared in 139 SMND patients and 139 matched controls. The distribution of the polymorphisms was similar in both groups. Therefore, based on linkage disequilibrium and genotype it is unlikely that either ICAM1 or CAR is implicated in SMND.

Diagnosis of the haemoglobinopathies.

Despite having been extensively studied at both the biochemical, haematological and molecular levels, the haemoglobinopathies continue to provide a diagnostic challenge particularly in the multiethnic communities seen in Australia. Early detection and characterisation of the haemoglobinopathies is essential so that appropriate counselling can be provided to couples and families who may be at risk of severe haematological consequences. Although DNA diagnostics have made a major impact on our understanding and detection of the haemoglobinopathies, DNA mutation testing should never be considered a short cut or the test of first choice in the workup of a haemoglobinopathy. A careful three tier approach involving: (1) Full blood count (2) Special haematological tests, followed by (3) DNA mutation analysis, provides the most effective way in which to detect primary gene mutations as well as gene-gene interactions that can influence the overall phenotype. Just as important as the laboratory investigations is the family work up. Often, the first and most helpful clue to gene gene interactions comes from the family study. In Australia, there are many different forms of alpha and beta thalassaemia. Increasingly, different Hb Variants are being detected, and their effects per se, or in combination with the thalassaemias, provide additional diagnostic challenges.

Oversight and monitoring of clinical research with gene therapy in Australia.

The NHMRC has set up the Gene and related Therapies Research Advisory Panel (GTRAP) to oversee gene therapy research.

The "new genetics" and clinical practice.

A "new genetics" has emerged driven by knowledge gained at the DNA level. In clinical practice, a practical application of the new genetics is DNA testing, which can be expected to expand with the completion of the Human Genome Project as the functions of new genes are discovered. Genetic DNA testing scenarios include diagnostic DNA testing, prenatal DNA testing, predictive (presymptomatic) DNA testing and screening DNA testing. The challenge for genetic DNA testing and clinical practice will be to define the roles to be played by the general practitioner, the specialist, and other healthcare professionals. From the patients' and families' perspective, the new genetics will best be implemented if a planned approach is adopted in the ordering of DNA tests and the associated counselling and support processes.

Evidence for a modifier of onset age in Huntington disease linked to the HD gene in 4p16.

Huntington disease (HD) is a neurodegenerative disorder caused by the abnormal expansion of CAG repeats in the HD gene on chromosome 4p16.3. A recent genome scan for genetic modifiers of age at onset of motor symptoms (AO) in HD suggests that one modifier may reside in the region close to the HD gene itself. We used data from 535 HD participants of the New England Huntington cohort and the HD MAPS cohort to assess whether AO was influenced by any of the three markers in the 4p16 region: MSX1 (Drosophila homeo box homologue 1, formerly known as homeo box 7, HOX7), Delta2642 (within the HD coding sequence), and BJ56 ( D4S127). Suggestive evidence for an association was seen between MSX1 alleles and AO, after adjustment for normal CAG repeat, expanded repeat, and their product term (model P value 0.079). Of the variance of AO that was not accounted for by HD and normal CAG repeats, 0.8% could be attributed to the MSX1 genotype. Individuals with MSX1 genotype 3/3 tended to have younger AO. No association was found between Delta2642 (P=0.44) and BJ56 (P=0.73) and AO. This study supports previous studies suggesting that there may be a significant genetic modifier for AO in HD in the 4p16 region. Furthermore, the modifier may be present on both HD and normal chromosomes bearing the 3 allele of the MSX1 marker.

A genome scan for modifiers of age at onset in Huntington disease: The HD MAPS study.

Huntington disease (HD) is caused by the expansion of a CAG repeat within the coding region of a novel gene on 4p16.3. Although the variation in age at onset is partly explained by the size of the expanded repeat, the unexplained variation in age at onset is strongly heritable (h2=0.56), which suggests that other genes modify the age at onset of HD. To identify these modifier loci, we performed a 10-cM density genomewide scan in 629 affected sibling pairs (295 pedigrees and 695 individuals), using ages at onset adjusted for the expanded and normal CAG repeat sizes. Because all those studied were HD affected, estimates of allele sharing identical by descent at and around the HD locus were adjusted by a positionally weighted method to correct for the increased allele sharing at 4p. Suggestive evidence for linkage was found at 4p16 (LOD=1.93), 6p21-23 (LOD=2.29), and 6q24-26 (LOD=2.28), which may be useful for investigation of genes that modify age at onset of HD.