Your search keyword '"Peeters, Maarten"' showing total 5 results

1. Identification and prioritization of NUAK1 and PPP1CC as positional candidate loci for skeletal muscle strength phenotypes.

Author

Windelinckx A, De Mars G, Huygens W, Peeters MW, Vincent B, Wijmenga C, Lambrechts D, Aerssens J, Vlietinck R, Beunen G, and Thomis MA

Subjects

Adolescent, Adult, Genotype, Humans, Male, Muscle Strength genetics, Muscle, Skeletal physiology, Polymorphism, Single Nucleotide genetics, Sarcoplasmic Reticulum Calcium-Transporting ATPases genetics, Young Adult, Muscle Strength physiology, Muscle, Skeletal metabolism, Protein Kinases genetics, Protein Phosphatase 1 genetics, Repressor Proteins genetics

Abstract

Muscle strength is an important determinant in elite sports performance as well as in the activities of daily living. Muscle metabolism also plays a role in the genesis, and therefore prevention, of common pathological conditions and chronic diseases. Even though heritability estimates between 31 and 78% suggest a significant genetic component in muscle strength, only a limited number of genes influencing muscle strength have been identified. This study aimed to identify and prioritize positional candidate genes within a skeletal muscle strength quantitative trait locus on chromosome 12q22-23 for follow-up. A two-staged gene-centered fine-mapping approach using 122 single nucleotide polymorphisms (SNPs) in stage 1 identified a family-based association (n=500) between several tagSNPs located in the ATPase, Ca2+ transporting, cardiac muscle, slow twitch 2 (ATP2A2; rs3026468), the NUAK family, SNF1-like kinase, 1 (NUAK1; rs10861553 and rs3741886), and the protein phosphatase 1, catalytic subunit, gamma isoform (PPP1CC; rs1050587 and rs7901769) genes and knee torque production (P values up to 0.00092). In stage 2, family-based association tests on additional putatively functional SNPs (e.g., exonic SNPs, SNPs in transcription factor binding sites or in conserved regions) in an enlarged sample (n=536; 464 individuals overlap with stage 1) did not identify additional associations with muscle strength characteristics. Further in-depth analyses will be necessary to elucidate the exact role of ATP2A2, PPP1CC, and NUAK1 in muscle strength and to find out which functional polymorphisms are at the base of the interindividual strength differences.

Published

2011

2. Comprehensive fine mapping of chr12q12-14 and follow-up replication identify activin receptor 1B (ACVR1B) as a muscle strength gene.

Author

Windelinckx A, De Mars G, Huygens W, Peeters MW, Vincent B, Wijmenga C, Lambrechts D, Delecluse C, Roth SM, Metter EJ, Ferrucci L, Aerssens J, Vlietinck R, Beunen GP, and Thomis MA

Subjects

Activin Receptors, Type I metabolism, Adolescent, Adult, Genetic Linkage, Genotype, Humans, Knee physiology, Male, Muscle, Skeletal physiology, Myostatin metabolism, Phenotype, Polymorphism, Single Nucleotide, Siblings, Transforming Growth Factor beta genetics, Transforming Growth Factor beta metabolism, White People genetics, Young Adult, Activin Receptors, Type I genetics, Chromosome Mapping methods, Chromosomes, Human, Pair 12 genetics, Genome-Wide Association Study methods, Muscle Strength genetics

Abstract

Muscle strength is important in functional activities of daily living and the prevention of common pathologies. We describe the two-staged fine mapping of a previously identified linkage peak for knee strength on chr12q12-14. First, 209 tagSNPs in/around 74 prioritized genes were genotyped in 500 Caucasian brothers from the Leuven Genes for Muscular Strength study (LGfMS). Combined linkage and family-based association analyses identified activin receptor 1B (ACVR1B) and inhibin β C (INHBC), part of the transforming growth factor β pathway regulating myostatin - a negative regulator of muscle mass - signaling, for follow-up. Second, 33 SNPs, selected in these genes based on their likelihood to functionally affect gene expression/function, were genotyped in an extended sample of 536 LGfMS siblings. Strong associations between ACVR1B genotypes and knee muscle strength (P-values up to 0.00002) were present. Of particular interest was the association with rs2854464, located in a putative miR-24-binding site, as miR-24 was implicated in the inhibition of skeletal muscle differentiation. Rs2854464 AA individuals were ∼2% stronger than G-allele carriers. The strength increasing effect of the A-allele was also observed in an independent replication sample (n=266) selected from the Baltimore Longitudinal Study of Aging and a Flemish Policy Research Centre Sport, Physical Activity and Health study. However, no genotype-related difference in ACVR1B mRNA expression in quadriceps muscle was observed. In conclusion, we applied a two-stage fine mapping approach, and are the first to identify and partially replicate genetic variants in the ACVR1B gene that account for genetic variation in human muscle strength.

Published

2011

3. Genome-wide linkage scan for contraction velocity characteristics of knee musculature in the Leuven Genes for Muscular Strength Study.

Author

De Mars G, Windelinckx A, Huygens W, Peeters MW, Beunen GP, Aerssens J, Vlietinck R, and Thomis MA

Subjects

Adolescent, Adult, Genetic Variation, Humans, Male, Muscle Contraction genetics, Torque, Genetic Linkage, Genome, Human, Knee Joint physiology, Muscle Strength genetics

Abstract

The torque-velocity relationship is known to be affected by ageing, decreasing its protective role in the prevention of falls. Interindividual variability in this torque-velocity relationship is partly determined by genetic factors (h(2): 44-67%). As a first attempt, this genome-wide linkage study aimed to identify chromosomal regions linked to the torque-velocity relationship of the knee flexors and extensors. A selection of 283 informative male siblings (17-36 yr), belonging to 105 families, was used to conduct a genome-wide SNP-based (Illumina Linkage IVb panel) multipoint linkage analysis for the torque-velocity relationship of the knee flexors and extensors. The strongest evidence for linkage was found at 15q23 for the torque-velocity slope of the knee extensors (TVSE). Other interesting linkage regions with LOD scores >2 were found at 7p12.3 [logarithm of the odds ratio (LOD) = 2.03, P = 0.0011] for the torque-velocity ratio of the knee flexors (TVRF), at 2q14.3 (LOD = 2.25, P = 0.0006) for TVSE, and at 4p14 and 18q23 for the torque-velocity ratio of the knee extensors TVRE (LOD = 2.23 and 2.08; P = 0.0007 and 0.001, respectively). We conclude that many small contributing genes are involved in causing variation in the torque-velocity relationship of the knee flexor and extensor muscles. Several earlier reported candidate genes for muscle strength and muscle mass and new candidates are harbored within or in close vicinity of the linkage regions reported in the present study.

Published

2008

4. Timing of Adolescent Somatic Maturity and Midlife Muscle Function: A 34-yr Follow-Up.

Author

Beunen, Gaston P., Peeters, Maarten W., Matton, Lynn, Claessens, Albrecht L., Thomis, Martine A., and Lefevre, Johan A.

Subjects

*RESEARCH, *MUSCLE strength, *MIDDLE age, *MATURATION (Psychology), *ADOLESCENCE, *BODY mass index, *HUMAN growth hormone, *ADULTS, *DEVELOPMENTAL psychology

Abstract

The article presents a study that evaluates whether late maturation during adolescence is associated with better muscle function at middle-age. The study found that late-maturing males have better muscle function such as isometric strength and power at middle age than their early-maturing peers. The study notes that this finding suggests that specific attention should be given to improve the muscle function of the early- and the average-maturing middle-aged males. The study did not identify the associations between adolescent biological maturity and muscle function.

Published

2009

5. Genetic and environmental determination of tracking in static strength during adolescence.

Author

Peeters, Maarten W., Thomis, Martine A., Maes, Hermine H. M., Beunen, Gaston P., Loos, Ruth J. F., Claessens, Albrecht L., and Vlietinck, Robert

Subjects

ADOLESCENCE, GENETICS, TEENAGERS, MUSCLE strength, PHENOTYPES, GENOTYPE-environment interaction

Abstract

The purpose of this study was to determine whether the observed phenotypic stability in static strength during adolescence, as measured by interage correlations in arm pull, is mainly caused by genetic and/or environmental factors. Subjects were from the Leuven Longitudinal Twin Study (n = 105 pairs, equally divided over 5 zygosity groups). Arm-pull data were aligned on age at peak height velocity to attenuate the temporal fluctuations in interage correlations caused by differences in timing of the adolescent growth spurt. Developmental genetic models were fitted using structural equation modeling. After the data were aligned on age at peak height velocity, the annual interage correlations conformed to a quasi-simplex structure over a 4-yr interval. The best-fitting models included additive genetic and unique environmental sources of variation. Additive genetic factors that already explained a significant amount of variation at previous measurement occasions explained 44.3 and 22.5% of the total variation at the last measurement occasion in boys and girls, respectively. Corresponding values for unique environmental sources of variance are 31.2 and 44.5%, respectively. In conclusion, the observed stability of static strength during adolescence is caused by both stable genetic influences and stable unique environmental influences in boys and girls. Additive genetic factors seem to be the most important source of stability in boys, whereas unique environmental factors appear to be more predominant in girls. [ABSTRACT FROM AUTHOR]

Published

2005