Polymorphisms in the IGF1 signalling pathway including the myostatin gene are associated with left ventricular mass in male athletes.

BACKGROUND: Athlete's heart as an adaptation to long-time and intensive endurance training can vary considerably between individuals. Genetic polymorphisms in the cardiological relevant insulin-like growth factor 1 (IGF1) signalling pathway seem to have an essential influence on the extent of physiological hypertrophy. OBJECTIVE: Analysis of polymorphisms in the genes of IGF1, IGF1 receptor (IGF1R) and the negative regulator of the cardiac IGF1 signalling pathway, myostatin (MSTN), and their relation to left ventricular mass (LVM) of endurance athletes. METHODS: In 110 elite endurance athletes or athletes with a high amount of endurance training (75 males and 35 females) and 27 male controls, which were examined by echocardiographic imaging methods and ergometric exercise-testing, the genotypes of a cytosine-adenine repeat polymorphism in the promoter region of the IGF1 gene and a G/A substitution at position 3174 in the IGF1R gene were determined. Additionally, a mutation screen of the MSTN gene was performed. RESULTS: The polymorphisms in the IGF1 and the IGF1R gene showed a significant relation to the LVM for male (IGF1: p=0.003; IGF1R: p=0.01), but not for female athletes. The same applies to a previously unnoticed polymorphism in the 1 intron of the MSTN gene, whose deletion allele (AAA→AA) appears to increase the myostatic effect (p=0.015). Moreover, combinations of the polymorphisms showed significant synergistic effects on the LVM of the male athletes. CONCLUSIONS: The authors' results argue for the importance of polymorphisms in the IGF1 signalling pathway in combination with MSTN on the variant degree of physiological hypertrophy of male athletes.

Human endogenous retrovirus HERV-K(HML-2) proviruses with Rec protein coding capacity and transcriptional activity.

The human endogenous retrovirus family HERV-K(HML-2) encodes the so-called Rec protein that displays functional similarities to the HIV(REV) protein. The number of proviruses producing Rec protein was hitherto unknown. We therefore analyzed the human genome sequence data and determined seven HERV-K(HML-2) proviruses potentially capable of producing Rec both on the mRNA and the protein level. We analyzed Rec mRNA expression in the Tera-1 cell line and in synovial tissue, and in the expressed sequence tag (EST) database. Diagnostic nucleotides assigned transcriptionally active and Rec-encoding proviruses to human chromosomes 6, 7, 11, and 12. Differently spliced mRNAs were also identified. The various active proviruses encode almost identical Rec proteins. Our study contributes to the understanding of the biology of HERV-K(HML-2) Rec protein. Our study further demonstrates that minor sequence differences among proviruses allow assigning HERV transcripts to particular proviral loci. Extended studies will eventually yield a more complete image of HERV transcription, regulation, and biological significance in diverse human tissues.