Studies on the methylation of cytidine

Kader, Harvey A. (Harvey Abraham)

January 1982

No description available.

Methylation.

Cytidine.

Nucleosides.

Pathogenetic role of aberrant promoter methylation in lung cancer

Chan, Ching, Eunice,

January 2007

Thesis (Ph. D.)--University of Hong Kong, 2007. / Also available in print.

Lungs Methylation. Genetic regulation.

Assessment of mercury methylation and demethylation with focus on chemical speciation and biological processes

Bystrom, Elza.

January 2008

Thesis (M. S.)--Civil and Environmental Engineering, Georgia Institute of Technology, 2008. / Committee Chair: Michael Saunders; Committee Member: Ching-Hua Huang; Committee Member: Marc Frischer.

Methylation in colorectal cancer

Chan, On-on, Annie.

January 2002

Thesis (M.D.)--University of Hong Kong, 2002. / Title from title frame.

Methylation. Colon (Anatomy) Rectum

Study of gene promoter methylation in acute promyelocytic leukaemia

Chim, Chor-sang, James.

January 2002

Thesis (M.D.)--University of Hong Kong, 2002. / Title from title frame. Includes bibliographical references (leaves 186-223).

Methylation. Acute myeloid leukemia

Methylation studies from fine needle aspirates of breast lesions

Koo, Wai-tak, Kelvin.

January 2002

Thesis (M.Med.Sc.)--University of Hong Kong, 2002. / Includes bibliographical references (leaves 71-78). Also available in print.

Methylation. Needle biopsy. Breast

Analysis of 14-3-3 [sigma] protein in nasopharyngeal tissues

Yeung, Shu-wai.

January 2003

Thesis (M.Med.Sc.)--University of Hong Kong, 2003. / Includes bibliographical references (leaves 55-66). Also available in print.

Nasopharynx Proteins Methylation.

Methylation and demethylation of methyl-accepting chemotaxis proteins in Escherichia coli

Toews, Myron Lee.

January 1979

Thesis--University of Wisconsin--Madison. / Typescript. Vita. Description based on print version record. Includes bibliographical references.

Genome defence in hypomethylated developmental contexts

Playfoot, Christopher James

January 2017

Retrotransposons constitute around 40% of the mammalian genome and their aberrant activation can have wide ranging detrimental consequences, both throughout development and into somatic lineages. DNA methylation is one of the major epigenetic mechanisms in mammals, and is essential in repressing retrotransposons throughout mammalian development. Yet during normal mouse embryonic development some cell lineages become extensively DNA hypomethylated and it is not clear how these cells maintain retrotransposon silencing in a globally hypomethylated genomic context. In this thesis I determine that hypomethylation in multiple contexts results in the consistent activation of only one gene in the mouse genome - Tex19.1. Thus if a generic compensatory mechanism for loss of DNA methylation exists in mice, it must function through this gene. Tex19.1-/- mice de-repress retrotransposons in the hypomethylated component of the placenta and in the mouse germline, and have developmental defects in these tissues. In this thesis I examine the mechanism of TEX19.1 mediated genome defence and the developmental consequences upon its removal. I show that TEX19.1 functions in repressing retrotransposons, at least in part, through physically interacting with the transcriptional co-repressor, KAP1. Tex19.1-/- ES cells have reduced levels of KAP1 bound retrotransposon chromatin and reduced levels of the repressive H3K9me3 modification at these loci. Furthermore, these subsets of retrotransposon loci are de-repressed in Tex19.1-/- placentas. Thus, my data indicates that mouse cells respond to hypomethylation by activating expression of Tex19.1, which in turn augments compensatory, repressive histone modifications at retrotransposon sequences, thereby helping developmentally hypomethylated cells to maintain genome stability. I next aimed to further elucidate the role of Tex19.1 in the developing hypomethylated placenta. I determine that Tex19.1-/- placental defects precede intrauterine growth restriction of the embryo and that alterations in mRNA abundance in E12.5 Tex19.1-/- placentas is likely in part due to genic transcriptional changes. De-repression of LINE- 1 is evident in these placentas and elements of the de-repressed subfamily are associated with significantly downregulated genes. If retrotransposon de-repression is contributing to developmental defects by interfering with gene expression remains to be determined, however I identify a further possible mechanism leading to placental developmental defects. I determine that Tex19.1-/- placentas have an increased innate immune response and I propose that this is contributing to the developmental defects observed. Developmental defects and retrotransposon de-repression are also observed in spermatogenesis in Tex19.1-/- testes, the molecular basis for which is unclear. I therefore investigate the possibility that the TEX19.1 interacting partners, the E3 ubiquitin ligase proteins, may be contributing to the phenotypes observed in Tex19.1- /- testes. I show that repression of MMERVK10C in the testes is dependent on UBR2, alongside TEX19.1. Furthermore, I have identified a novel role for the TEX19.1 interacting partner, UBR5, in spermatogenesis, whose roles are distinct from those of TEX19.1. The work carried out during the course of this thesis provides mechanistic insights into TEX19.1 mediated genome defence and highlights the importance of protecting the genome from aberrant retrotransposon expression.

SYMBIONT REGULATED HOST DNA METHYLATION IN EUPRYMNA SCOLOPES – VIBRIO FISCHERI SYMBIOSIS

Xiao, Rui

01 May 2018

Advancement in the study of host-microbe interactions has shown that microbes can induce and maintain long lasting changes in gene expression in host cells to facilitate beneficial symbiosis through changes in methylation of the host’s genomic DNA. The beneficial symbiosis between Hawaiian Bobtail squid, Euprymna scolopes and Gram negative bioluminescent bacteria Vibrio fischeri provides an excellent system for studying beneficial microbes’ effect on host DNA methylation. The symbiosis is highly specific, in that only V. fischeri colonizes the squid’s symbiotic organ from a background of 106 diverse bacteria per mL of sea water. DNA methylation (DNAm) refers to the covalent addition of methyl (CH3) groups to the nucleotides of organism’s genomic DNA. The most well researched DNA methylation type is 5- methyl cytosine methylation (5mC). Previous publications show DNAm provides an extra tier of regulation for organisms to control their gene expression, without altering their DNA sequences. Two types of DNAm have been discovered in invertebrate systems: gene promoter methylation and gene body methylation. The amount of methylated cytosine on gene bodies is positively correlated with the specific gene’s expression state. We hypothesize that V. fischeri plays an important role in regulating host DNA methylation during both colonization of the animals (juvenile) and maintenance of the symbiosis I (adult). To start to address this hypothesis, our specific aims are (1) validate DNA methylation in E. scolopes; (2) identify DNA methylation machinery genes in squid at the transcript level and quantify the level of their expression based on state of symbiosis; (3) analyze squid DNA methylation at the whole genome level as well as gene specific level.

Epigenetics

Methylation

RNASeq

Symbiosis