John M. Dunn scite author profile

Previous studies of the pericentromeric region of the human X chromosome short arm (Xp) revealed an age gradient from ancient DNA that contains expressed genes to recent human-specific DNA at the functional centromere. We analyzed the finished sequence of this human genomic region to investigate its evolutionary history. Phylogenetic analysis of >1,500 alpha-satellite monomers from the region revealed the presence of five physical domains, each containing monomers from a distinct phylogenetic clade. The most distal domain contains long interspersed nucleotide element repeats that were active >35 million years ago, whereas the four proximal domains contain more recently active long interspersed nucleotide element repeats. An out-of-register, unequal recombination (i.e., crossover) detected at the edge of the X chromosomespecific alpha-satellite array (DXZ1) may reflect the most recent of a series of punctuating events during evolution that resulted in a proximal physical expansion of the X centromere. The first 18 kb of this array has 97-99% pairwise identity among all 2-kb repeat units. To perform more detailed evolutionary comparisons, we sequenced the junction between the ancient DNA of Xp and the primate-specific alpha satellite in chimpanzee, gorilla, orangutan, vervet, macaque, and baboon. The striking conservation found in all cases supports the ancestral nature of the alpha satellite at this location. These studies demonstrate that the primate X centromere appears to have evolved through repeated expansion events occurring within the central, active region of centromeric DNA, with the newly added sequences then conferring centromere function.evolution ͉ alpha satellite ͉ comparative genomics ͉ genome sequencing

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Genomic Environment Predicts Expression Patterns on the Human Inactive X Chromosome

Carrel

Park

Tyekucheva

et al. 2006

PLoS Genet

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What genomic landmarks render most genes silent while leaving others expressed on the inactive X chromosome in mammalian females? To date, signals determining expression status of genes on the inactive X remain enigmatic despite the availability of complete genomic sequences. Long interspersed repeats (L1s), particularly abundant on the X, are hypothesized to spread the inactivation signal and are enriched in the vicinity of inactive genes. However, both L1s and inactive genes are also more prevalent in ancient evolutionary strata. Did L1s accumulate there because of their role in inactivation or simply because they spent more time on the rarely recombining X? Here we utilize an experimentally derived inactivation profile of the entire human X chromosome to uncover sequences important for its inactivation, and to predict expression status of individual genes. Focusing on Xp22, where both inactive and active genes reside within evolutionarily young strata, we compare neighborhoods of genes with different inactivation states to identify enriched oligomers. Occurrences of such oligomers are then used as features to train a linear discriminant analysis classifier. Remarkably, expression status is correctly predicted for 84% and 91% of active and inactive genes, respectively, on the entire X, suggesting that oligomers enriched in Xp22 capture most of the genomic signal determining inactivation. To our surprise, the majority of oligomers associated with inactivated genes fall within L1 elements, even though L1 frequency in Xp22 is low. Moreover, these oligomers are enriched in parts of L1 sequences that are usually underrepresented in the genome. Thus, our results strongly support the role of L1s in X inactivation, yet indicate that a chromatin microenvironment composed of multiple genomic sequence elements determines expression status of X chromosome genes.

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Peer Tutors’ Effects on Activity Levels of Deaf Students in Inclusive Elementary Physical Education

Lieberman

Dunn

Mars

et al. 2000

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The purpose of this study was to analyze the effect of trained peer tutors on the physical activity levels of deaf students1 in inclusive elementary physical education classes. A single subject delayed multiple baseline design across 8 deaf participants (4 boys and 4 girls) ages 10 to 12 was used. Eight typically developing, trained peers of the same age and gender served as peer tutors following training in use of sign language and basic teaching strategies. The dependent variable was moderate to vigorous physical activity (MVPA) determined by McKenzie, Sallis and Nader’s (1991) System for Observing Fitness Instruction Time (SOFIT). The study included 3–4 sessions of baseline, 11–14 sessions of intervention, and 1–3 sessions of maintenance. Results revealed that after the introduction of peer tutoring, deaf students increased their MVPA from to 22% to 41.5%, and peer tutors increased their MVPA from 19% to 37.9%.

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John M. Dunn

Genetic Modifiers of Lung Disease in Cystic Fibrosis

Progressive proximal expansion of the primate X chromosome centromere

Genomic Environment Predicts Expression Patterns on the Human Inactive X Chromosome

Peer Tutors’ Effects on Activity Levels of Deaf Students in Inclusive Elementary Physical Education

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