Investigation Of Human Promoter Cpg Content And Methylation Profiles At Different Conservation Levels

Demiralay, Burak

01 September 2012

Methylation of CpG islands located at the promoter regions is a mechanism which controls gene silencing and expression. Hyper or hypo methylation of these sites on promoter sequences have been associated with many diseases, like cancer. Even though promoter CpG islands and their methylation profiles are important regulators of gene expression, the exact mechanism of gene silencing through methylation is not known. Here, we have investigated the status of promoter CpG methylation under various evolutionary pressures by calculating the differences in promoter CpG content and methylation profiles at different pass points. In order to determine the list of genes under each category we have analyzed and compared the orthologs among 58 genomes available through ENSEMBL. The total number of CpG dinucleotides at the promoter regions of all groups of genes have been calculated and compared. Additionally, we have compared the experimentally determined methylation profiles of these CpG&#039 / s between human blood cells and fibroblast cells. While the promoter CpG content changed through common to newer genes, the number of the CpG units methylated found to be consistent. Here, we present the functional level analysis of common gene lists at different pass points and report the differences of the promoter CpG content and the methylation profiles among these groups with distinct evolutionary conservation status. We have also observed the conservation status of individual methylated CpG units on the low and high methylated genes. Our analysis revealed that the surrounding methylation content had a positive effect on the conservation of individual CpG&rsquo / s.

QH Mutations 460-469

Analysis Of Self-processing Mechanism Of Galactose Oxidase By Site-directed Mutagenesis And Heterologous Expression In Escherichia Coli

Gencer, Burcak

01 December 2005

In this study, self-catalytic maturation of heterologously expressed pro-galactose oxidase was analysed in E.coli by altering some amino acids which were supposed to play a crucial role in pro-peptide removal. Galactose oxidase (GOase / EC 1.1.3.9) from Fusarium graminearum / having a molecular mass of 68kDa, is a monomeric, copper containing enzyme with an unusual thioether bond. The enzyme is produced as a precursor with an additional 8 amino acid pre- and a 17- amino acid pro-sequence at the N terminus. Previous work has shown that the pre-peptide is removed possibly by a protease during secretion, whereas the 17 amino acid pro-peptide is removed autocatalytically by the aerobic addition of Cu2+ to the precursor, preceding the formation of the thioether bond at the active site. The pro-gao gene was on ProGON1 and ProGOMN1 constructs which were previously established on pET101/D/lacZ vector in England by directed evolution. ProGON1 contains silent mutations at the N-terminus different from native galactose oxidase whereas ProGOMN1 has six further mutations within the mature enzyme, providing high expression. The cleavage site mutations R-1P/A1P, R-1X/A1X, S2A, and the H522A mutation just against the cleavage site in the three dimensional configuration, were carried out by site-directed mutagenesis. Those and some extra mutations were confirmed by DNA sequence analysis. Next, mutant galactose oxidases were expressed in E. coli BL21 Star (DE3), and were purified by Strep-Tactin&reg / Sepharose&reg / column, operating on the basis of affinity chromatography. Subsequently, SDS-PAGE was performed to analyze self-processing by detecting molecular mass difference of protein bands resulting from pro-sequence removal or existence. When the bands obtained in SDS-PAGE were compared, it was seen that the products of original recombinant plasmids, i.e. ProGON1, ProGOMN1 / and the mutational variants showed no difference in band size, all slightly above 70kDa / indicating pro-sequence presence on all constructs. Non-mutants and some of the mutants showed galactose oxidase activity, signifying proper active site construction by thioether bond formation. ProGOMN1 was submitted for N-terminal amino acid sequencing to be able to assert that a size above 70kDa is not solely due to the existence of a 1 kDa Strep-tag II at C-terminus. Sequencing data affirmed the presence of both the pre-peptide and the pro-preptide showing that processing has not occurred at the N-terminus. Accordingly, in this study, it was shown for the first time that the existence of a pre-pro-peptide at the N-terminus of galactose oxidase does not prevent thioether bond formation at the active site. Furthermore, since the pro-peptide is cleaved autocatalytically, the lack of removal of the pre-peptide in E.coli in the presence of Cu 2+ and oxygen is very likely to be the cause of lack of pro-peptide cleavage. In future studies the region corresponding to the pre-peptide will be deleted to prove this hypothesis.

QH Mutations 460-469