Athlome Project Consortium: a concerted effort to discover genomic and other "omic" markers of athletic performance.

Despite numerous attempts to discover genetic variants associated with elite athletic performance, injury predisposition, and elite/world-class athletic status, there has been limited progress to date. Past reliance on candidate gene studies predominantly focusing on genotyping a limited number of single nucleotide polymorphisms or the insertion/deletion variants in small, often heterogeneous cohorts (i.e., made up of athletes of quite different sport specialties) have not generated the kind of results that could offer solid opportunities to bridge the gap between basic research in exercise sciences and deliverables in biomedicine. A retrospective view of genetic association studies with complex disease traits indicates that transition to hypothesis-free genome-wide approaches will be more fruitful. In studies of complex disease, it is well recognized that the magnitude of genetic association is often smaller than initially anticipated, and, as such, large sample sizes are required to identify the gene effects robustly. A symposium was held in Athens and on the Greek island of Santorini from 14-17 May 2015 to review the main findings in exercise genetics and genomics and to explore promising trends and possibilities. The symposium also offered a forum for the development of a position stand (the Santorini Declaration). Among the participants, many were involved in ongoing collaborative studies (e.g., ELITE, GAMES, Gene SMART, GENESIS, and POWERGENE). A consensus emerged among participants that it would be advantageous to bring together all current studies and those recently launched into one new large collaborative initiative, which was subsequently named the Athlome Project Consortium

Metabolismo do cálcio na fenilcetonúria Calcium metabolism in phenilke

A Fenilcetonúria é um erro inato do metabolismo do aminoácido fenilalanina. O tratamento é essencialmente dietético e envolve uma restrição severa no consumo de alimentos contendo aminoácido fenilalanina. Embora a alimentação seja complementada com fórmulas a fim de suprir as necessidades de vitaminas, minerais e aminoácidos essenciais, carências nutricionais ainda ocorrem. Isto se deve, principalmente, à restrição de fontes protéicas, que acarreta deficiência na ingestão de diversos nutrientes, dentre eles o cálcio. O cálcio possui importante relação com a formação mineral óssea. Estudos recentes demonstram que portadores de fenilcetonúria apresentam freqüentemente osteopenia e fraturas, sendo a maior incidência em crianças acima de 8 anos de idade. O rápido aumento da estatura, a dieta deficiente em cálcio e níveis de aminoácido fenilalanina elevados têm sido descritos como os principais fatores para a aquisição de massa óssea inadequada. A suplementação de cálcio em crianças saudáveis mostrou um efeito positivo sobre a aquisição de massa óssea na fase da pré-puberdade. Assim, torna-se relevante compreender a necessidade da suplementação de cálcio em pacientes fenilcetonúria, a fim de favorecer o desenvolvimento ósseo esperado.<br>Phenylketonuria is an inborn error of the metabolism of the amino acid phenylalanine. The treatment is essentially dietetic and involves a severe restriction in the consumption of foods containing aminoacid phenylalanine. Although the diet is complemented with supplements in order to meet the vitamin, mineral and essential amino acid requirements, nutritional deficiencies still occur. This is mainly due to restricting the consumption of protein sources, which results in low intake of several nutrients, including calcium. Calcium is strongly related to bone mineral formation. Recent studies have demonstrated that patients with phenylketonuria often present osteopenia and fractures, the greatest incidence being in children older than 8 years. Rapid growth, a calcium-deficient diet and elevated aminoacid phenylalanine plasma levels have been described as the principal factors responsible for inadequate bone formation. It has been shown that calcium-supplementation in healthy children had a positive effect on bone mass acquisition during prepuberty. Therefore, it is pertinent to understand the need of calcium-supplementation in phenylketonuria in order to promote full bone development

Phenylalanine hydroxylase deficiency: diagnosis and management guideline.

Phenylalanine hydroxylase deficiency, traditionally known as phenylketonuria, results in the accumulation of phenylalanine in the blood of affected individuals and was the first inborn error of metabolism to be identified through population screening. Early identification and treatment prevent the most dramatic clinical sequelae of the disorder, but new neurodevelopmental and psychological problems have emerged in individuals treated from birth. The additional unanticipated recognition of a toxic effect of elevated maternal phenylalanine on fetal development has added to a general call in the field for treatment for life. Two major conferences sponsored by the National Institutes of Health held \u3e10 years apart reviewed the state of knowledge in the field of phenylalanine hydroxylase deficiency, but there are no generally accepted recommendations for therapy. The purpose of this guideline is to review the strength of the medical literature relative to the treatment of phenylalanine hydroxylase deficiency and to develop recommendations for diagnosis and therapy of this disorder. Evidence review from the original National Institutes of Health consensus conference and a recent update by the Agency for Healthcare Research and Quality was used to address key questions in the diagnosis and treatment of phenylalanine hydroxylase deficiency by a working group established by the American College of Medical Genetics and Genomics. The group met by phone and in person over the course of a year to review these reports, develop recommendations, and identify key gaps in our knowledge of this disorder. Above all, treatment of phenylalanine hydroxylase deficiency must be life long, with a goal of maintaining blood phenylalanine in the range of 120-360 µmol/l. Treatment has predominantly been dietary manipulation, and use of low protein and phenylalanine medical foods is likely to remain a major component of therapy for the immediate future. Pharmacotherapy for phenylalanine hydroxylase deficiency is in early stages with one approved medication (sapropterin, a derivative of the natural cofactor of phenylalanine hydroxylase) and others under development. Eventually, treatment of phenylalanine hydroxylase deficiency will be individualized with multiple medications and alternative medical foods available to tailor therapy. The primary goal of therapy should be to lower blood phenylalanine, and any interventions, including medications, or combination of therapies that help to achieve that goal in an individual, without other negative consequences, should be considered appropriate therapy. Significant evidence gaps remain in our understanding of the optimum therapies for phenylalanine hydroxylase deficiency, nonphenylalanine effects of these therapies, and long-term sequelae of even well-treated disease in children and adults