Vincent Wing-Sang Cheng scite author profile

Stem cell research has been developing rapidly in diverse areas such as the fields of genetics and molecular biology over the past decades. Genomic studies on both embryonic stem cells (ESCs) and terminally-differentiated cells illustrated that factors apart from their hereditary information disparity are associated with gene expression patterns of ESCs. Therefore, current research is trying to explore the effects of epigenetic processes in stem cell physiology and phenotypic changes. In-depth analyses of the molecular mechanisms underpinning such epigenetic-mediated functions have also been conducted. These findings suggest the importance of understanding the epigenetic influences in stem cell activities. Accordingly this review will describe the regulatory machineries of stem cells development targeting the two epigenetic processes: (1) DNA methylation and (2) histones modification. In addition, up-to-date findings concerning the functional roles of these processes in stem cells homeostasis will be covered.

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Vacuolar protein in apical and flower-petal cells

Shumway

Cheng

Ryan

1972

Planta

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Vegetative apices, floral apices and flower petals of five Solanaceae (potato, tomato, tobacco, petunia and nightshade) and of corn and Nigella were examined with an electron microscope for the presence of protein bodies in the cell vacuoles. Electron-dense bodies were found in vacuoles of all plants investigated but not in every tissue examined. The bodies observed in the apices are similar to the protein bodies previously found in tomato leaves where they appear to be related to the presence of chymotrypsin inhibitor I protein (Shumway et al., 1970). The bodies appeared in very young cells in small vacuoles, disappearing as the cell matured. They are apparently related to the growth and development of the new cells. The results suggest that plants may regulate specific proteins within the apical region through selective synthesis and degradation of proteins accompanied by compartmentalization in the vacuole.

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Phylogenetic and Structural Significance of Dihydrofolate Synthase (folC) Mutations in Drug-Resistant Mycobacterium tuberculosis

Cheng

Leung

Kwok

et al. 2016

Microbial Drug Resistance

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The aim of this study is to investigate the mutation pattern of the folC gene in drug-resistant Mycobacterium tuberculosis (MTB) clinical isolates of global and Hong Kong cohorts. The public sequence read archives of 1,124 MTB genomes from three independent studies were retrieved and folC mutations existing solely in drug-resistant MTB strains were identified. A phylogenetic tree was constructed to analyze the segregation of mutation-related amino acid residues in the FolC structure. These mutation sites were further supported by direct Sanger sequencing of the folC gene among 254 clinical MTB isolates in a Hong Kong cohort. Homology modeling of wild-type and mutated FolC was performed, and the predicted structures were docked with hydroxydihydropteroate, the metabolic derivative of para-aminosalicylic acid (PAS), to evaluate the resultant binding affinity changes. Combining the results of three previous cohorts and our cohort, E40, I43, S150, and E153 are the most frequently affected amino acid residues in resistant isolates. Based on the distribution of mutations in the genome-based phylogenetic tree, lineage-specific mutation patterns were observed. Regarding the segregation of affected amino acid residues, the four most frequently affected residues are all in close proximity of the binding pocket for the PAS derivative. Molecular modeling results showed that mutations at E40, I43, and S150 can alter the structure of FolC putative binding pocket, causing the PAS derivative to bind outside of the now deformed pocket. This might ablate the interaction between the protein and the PAS derivative. To conclude, this study is the first comprehensive mutation pattern and bioinformatics analysis of the folC gene in MTB drug-resistant isolates. The distribution of mutations in phylogenetic lineages and protein structure is reported, analyzed, and discussed.

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