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Computational Study of Nucleosome Positioning Sequence Patterns and the Effects of the Nucleosome Positioning on the Availability of the Transcription Factor Binding Sites in Study Systems

Nucleosomes, the primary unit of chromatin structure, are positioned either statistically or specifically. The statistical positioning denotes the arbitrary positioning of nucleosomes on DNA agreeing with the nucleosome’s broad coverage of the genome—however, there is evidence that nucleosomes are also positioned specifically at controlled positions. DNA sequences determine the specific nucleosome positions, and the presence or depletion of nucleosomes affects the availability of the DNA region to other proteins. The DNA sequences of H2A and H2A.Z nucleosomes in Drosophila were analysed in search of nucleosome positioning patterns. Dinucleotide patterns with 10 bp periodicity were identified from the DNA sequences of H2A nucleosomes. Compared with the yeast patterns, the Drosophila patterns had the same periodicity but different dinucleotides near the dyad, which was related to the different H3 structure between them. The nucleosome positioning patterns from the H2A.Z nucleosomes implied the specific histone-DNA interaction as a result of the deviations of the patterns where the different amino acids of H2A and H2A.Z interact with the DNA. The Ly49 gene cluster was selected as a model system to study the interplay between nucleosomes and transcription factors. Ly49 proteins, the surface receptors on NK cells, display variegated expression patterns, and the bidirectional promoter Pro-1 is known as a key determinant of the stochastic expression of each Ly49 gene. The systematic analysis of nucleosome positions based on the genome sequences in the Ly49 gene cluster revealed that the repressing Pro-1 reverse promoters are open, while the activating forward Pro-1 promoters were covered by nucleosomes. Furthermore, specific nucleosome positions covered transcription factor binding sites. The covered factor binding sites were further examined by their periodic appearances on the nucleosome-covered sequences, which revealed the accessibility to the sites. The sequence analysis predicted that the regulation by the transcription factor AML-1 would be sensitive to the nucleosome coverage; the prediction was confirmed by cell line experiments. The 10 bp periodic nucleosome positioning patterns interact with histones specifically. The long nucleosome positioning patterns coexist with the short sequence motifs for transcription factor binding sites adding another layer of the control to the transcriptional regulation.

Identiferoai:union.ndltd.org:uottawa.ca/oai:ruor.uottawa.ca:10393/36580
Date January 2017
CreatorsYang, Doo Seok
ContributorsIoshikhes, Ilya
PublisherUniversité d'Ottawa / University of Ottawa
Source SetsUniversité d’Ottawa
LanguageEnglish
Detected LanguageEnglish
TypeThesis

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