RESUMO
Public health relies on technologies to produce and analyse data, as well as effectively develop and implement policies and practices. An example is the public health practice of epidemiology, which relies on computational technology to monitor the health status of populations, identify disadvantaged or at risk population groups and thereby inform health policy and priority setting. Critical to achieving health improvements for the underserved population of people living with rare diseases is early diagnosis and best care. In the rare diseases field, the vast majority of diseases are caused by destructive but previously difficult to identify protein-coding gene mutations. The reduction in cost of genetic testing and advances in the clinical use of genome sequencing, data science and imaging are converging to provide more precise understandings of the 'person-time-place' triad. That is: who is affected (people); when the disease is occurring (time); and where the disease is occurring (place). Consequently we are witnessing a paradigm shift in public health policy and practice towards 'precision public health'.Patient and stakeholder engagement has informed the need for a national public health policy framework for rare diseases. The engagement approach in different countries has produced highly comparable outcomes and objectives. Knowledge and experience sharing across the international rare diseases networks and partnerships has informed the development of the Western Australian Rare Diseases Strategic Framework 2015-2018 (RD Framework) and Australian government health briefings on the need for a National plan.The RD Framework is guiding the translation of genomic and other technologies into the Western Australian health system, leading to greater precision in diagnostic pathways and care, and is an example of how a precision public health framework can improve health outcomes for the rare diseases population.Five vignettes are used to illustrate how policy decisions provide the scaffolding for translation of new genomics knowledge, and catalyze transformative change in delivery of clinical services. The vignettes presented here are from an Australian perspective and are not intended to be comprehensive, but rather to provide insights into how a new and emerging 'precision public health' paradigm can improve the experiences of patients living with rare diseases, their caregivers and families.The conclusion is that genomic public health is informed by the individual and family needs, and the population health imperatives of an early and accurate diagnosis; which is the portal to best practice care. Knowledge sharing is critical for public health policy development and improving the lives of people living with rare diseases.
Assuntos
Genômica/métodos , Política de Saúde , Medicina de Precisão , Saúde Pública , Doenças Raras/terapia , Predisposição Genética para Doença , Genômica/organização & administração , Política de Saúde/legislação & jurisprudência , Humanos , Fenótipo , Formulação de Políticas , Valor Preditivo dos Testes , Prognóstico , Desenvolvimento de Programas , Avaliação de Programas e Projetos de Saúde , Saúde Pública/legislação & jurisprudência , Doenças Raras/diagnóstico , Doenças Raras/epidemiologia , Doenças Raras/genéticaRESUMO
The International Cancer Genome Consortium (ICGC) was launched to coordinate large-scale cancer genome studies in tumours from 50 different cancer types and/or subtypes that are of clinical and societal importance across the globe. Systematic studies of more than 25,000 cancer genomes at the genomic, epigenomic and transcriptomic levels will reveal the repertoire of oncogenic mutations, uncover traces of the mutagenic influences, define clinically relevant subtypes for prognosis and therapeutic management, and enable the development of new cancer therapies.
Assuntos
Genética Médica/organização & administração , Genoma Humano/genética , Genômica/organização & administração , Cooperação Internacional , Neoplasias/genética , Metilação de DNA , Análise Mutacional de DNA/tendências , Bases de Dados Genéticas , Genes Neoplásicos/genética , Genética Médica/tendências , Genômica/tendências , Humanos , Propriedade Intelectual , Mutação , Neoplasias/classificação , Neoplasias/patologia , Neoplasias/terapiaRESUMO
Capillary malformation (CM; 'port-wine stain'), is a common vascular malformation affecting cutaneous capillary vessels in 0.3% of newborns. Increased incidence of lesions in first-degree relatives of these patients and several reported familial cases suggest that genetic factors may play a role in the pathogenesis of CM. We report the first genome-wide linkage analysis of familial CM. In the non-parametric linkage analysis, strong evidence of linkage (peak Z-score 6.72, P-value 0.000136) was obtained in an interval of 69 cM between markers D5S407 and D5S2098, corresponding to 5q11-5q23. Parametric linkage analysis gave a maximum combined HLOD score of 4.84 (alpha-value 0.67) at marker D5S2044 on 5q15, and analysis using only the linked families, defined a smaller, statistically significant locus CMC1 of 23 cM (peak LOD score 7.22) between markers D5S1962 and D5S652 corresponding to 5q13-5q15. Interesting candidate genes implicated in vascular and neural development, such as MEF2C, RASA1, and THBS4, are in this locus.
Assuntos
Cromossomos Humanos Par 5 , Predisposição Genética para Doença , Mancha Vinho do Porto/genética , Mapeamento Cromossômico , Feminino , Genes Dominantes , Humanos , Masculino , Linhagem , Mancha Vinho do Porto/patologiaRESUMO
Capillary malformation (CM), or "port-wine stain," is a common cutaneous vascular anomaly that initially appears as a red macular stain that darkens over years. CM also occurs in several combined vascular anomalies that exhibit hypertrophy, such as Sturge-Weber syndrome, Klippel-Trenaunay syndrome, and Parkes Weber syndrome. Occasional familial segregation of CM suggests that there is genetic susceptibility, underscored by the identification of a large locus, CMC1, on chromosome 5q. We used genetic fine mapping with polymorphic markers to reduce the size of the CMC1 locus. A positional candidate gene, RASA1, encoding p120-RasGAP, was screened for mutations in 17 families. Heterozygous inactivating RASA1 mutations were detected in six families manifesting atypical CMs that were multiple, small, round to oval in shape, and pinkish red in color. In addition to CM, either arteriovenous malformation, arteriovenous fistula, or Parkes Weber syndrome was documented in all the families with a mutation. We named this newly identified association caused by RASA1 mutations "CM-AVM," for capillary malformation-arteriovenous malformation. The phenotypic variability can be explained by the involvement of p120-RasGAP in signaling for various growth factor receptors that control proliferation, migration, and survival of several cell types, including vascular endothelial cells.