Molecular Modeling Assisted Design and Synthesis of Unsymmetrical Anthracene Isoxazole Small Molecule Anti-tumor Agents

There are several isoxazoles in general medical practice and their metabolic fate and disposition is well known, and thus, this heterocyclic ring is often considered among the privileged scaffolds or templates for drug design and discovery. Many examples can be found of 3-aryl-isoxazoles which in theory have a chiral axis, yet actual experimental examples of direct determinations of isoxazole rotational barriers are few and far between. The dihedral angle of the 3-aryl to isoxazole bond in antibacterials of the oxacillin series increased with substitution in the 2- and 6- positions of the phenyl. Although his calculated barrier was low, this implied that atropisomers are possible for unsymmetrical substitution. The chirality of these systems differs from that of other compounds as their configuration is inverted by rotation about single bonds and can be accomplished by thermal equilibration. Thus, depending on the barrier to rotation, some of these atropisomers may only be isolated at low temperatures, if at all

NASA Tech Briefs, November 1993

Topics covered: Advanced Manufacturing; Electronic Components and Circuits; Electronic Systems; Physical Sciences; Materials; Computer Programs; Mechanics; Machinery; Fabrication Technology; Mathematics and Information Sciences; Life Sciences

Effect of Naturally Occurring DNA Modifications on DNA Structure and Packaging

In eukaryotes, the genomic double-stranded DNA (dsDNA) coils around histones to form nucleosomes. Arrays of these nucleosomes bundle together to generate chromatin. Most DNA-related processes require interactions between chromatin-protected DNA and cellular machinery. Access of cell machinery to genomic DNA is partially regulated by the position and stability of nucleosomes, which may be influenced by changes in nucleosomal DNA. DNA is composed of adenine (A), guanine (G), cytosine (C), thymine (T) nucleotides and their derivatives. It has been shown that some C derivatives participate in directing multiple biological processes, and aberrant modification patterns are often linked to diseases. It has been proposed that T derivatives exhibit similar effects. This thesis focuses on elucidating the effect of naturally occurring DNA modifications on the properties of dsDNA and nucleosomes. dsDNA sequences systematically modified with various T derivatives were characterized using classical biophysical techniques to assess the effect of these DNA modifications. The results indicate that in the sequence context studied, 5-hydroxymethyluracil modifications destabilize dsDNA, while dense symmetrical 5-formyluracil (fU) modifications alter the dsDNA structure. These effects may provide clues to the differential protein recruitment observed in previous research. In vitro studies on nucleosome occupancy and stability revealed that 5-formylcytosine (fC) modifications have positive effects on nucleosome formation and stability compared to the unmodified counterpart by influencing the intrinsic biochemical and biophysical properties of the nucleosomes. These results provide casual links for the observation in vivo between fC and the increased nucleosome occupancy and positioning. In order to further understand the positional effect of fC on the nucleosomes, a method was developed for quick and reliable incorporation of C derivatives into dsDNA at desired positions. The positive effect of fC modifications on nucleosome occupancy and stability observed here has necessitated further studies to gain deeper insights into the biological functions of fC in the nucleosome context. Cryo-EM can be used to elucidate the structural foundation for the changes fC posts to nucleosome, and protein interacting assays will identify the cellular machineries specifically recruited/repulsed by fC-modified nucleosomes. The effect of DNA modifications elucidated by the above studies advances our understanding on the role that DNA modifications play in regulating cellular processes.Chemicals were covered by Wellcome Trust (grant no. 099232/z/12/z) and the core funding from Cancer Research UK (C14303/A17197). Z.Li was also supported by a studentship from A*STAR (Singapore)

48th Rocky Mountain Conference on Analytical Chemistry

Final program, abstracts, and information about the 48th annual meeting of the Rocky Mountain Conference on Analytical Chemistry, co-endorsed by the Colorado Section of the American Chemical Society and the Rocky Mountain Section of the Society for Applied Spectroscopy. Held in Breckenridge, Colorado, July 23-27, 2006

Microbial Secondary Metabolites and Biotechnology

Many research teams are working to demonstrate that microorganisms can be our daily partners, due to the great diversity of biochemical transformations and molecules they are able to produce. This Special Issue highlights several facets of the production of microbial metabolites of interest. From the discovery of new strains or new bioactive molecules issued from novel environments, to the increase in their synthesis by traditional or innovative methods, different levels of biotechnological processes are addressed. Combining the new dimensions of "Omics" sciences, such as genomics, transcriptomics or metabolomics, microbial biotechnologies are opening up incredible opportunities for discovering and improving microorganisms and their production

Genes: Multigene Families, Control of Gene Expression, Genetic contributions to Human Diseases, including Chromosomal Fragile Sites and ‘Dynamic’ and ‘Non-self’ Mutations

The early work in this thesis utilizes the general approach of comparative analysis. In order to find out the relationship between entities (either functional or genetic) my colleagues and I have attempted to identify the important elements by detecting similarity between those entities that act in a similar manner. The philosophy behind this approach is simply that when two distinct objects perform a similar process then the requirements essential for that process will be revealed as similarities between those objects above a noise of difference between them. The use of comparative analysis in biological systems is an attempt to identify natural order from apparent chaos. This work includes but is not limited to :- 1. discovery of the family of kallikrein genes and exploration of their roles in biology, 2. identification of the DNA sequence elements required for hormonal and heavy metal control of metallothionein gene expression 3. discovery of at least some of the necessary and sufficient conditions for the appearance of fragile sites on chromosomes, and their consequent contributions to disease, 4. the molecular properties of repeat DNA sequence expansion that lead to dynamic mutation and consequent fragile site expression and / or disease pathogenesis. In a sense the use of genetic animal models in order to study gene function and pathogenesis follows similar logic of comparative analysis – the mutation of a single endogenous gene or the expression of a single introduced mutated gene in a (presumed) constant genetic background to enable the biological consequences of the genetic mutation or aberrant gene expression by comparing animals from the ‘wild-type’ or parent line with those that now carry the mutation or altered gene. This approach has been utilized in the most recent work contained herein as a means to determine gene function and / or to model human genetic disease pathogenesis, specifically pathogenic mechanisms of the protein WWOX in cancer and expanded repeat RNAs in neurodegenerative diseases. The culmination of this recent work is the development of an hypothesis – 4. that expanded repeat double-stranded RNA leads to neurodegeneration through its recognition by the RNA-binding pattern recognition receptors as a ‘non-self’ or foreign nucleic acid due to a paucity of RNA modification. The resultant pathogenic mechanism is therefore autoinflammatory disease. Given the wide range and variety of evidence of inflammatory activation in neurodegenerative diseases in general, this mechanism is therefore hypothesized to be the general causal mechanism for most (or all) of these diseases. A specific Introduction - highlighting the nature and significance of the work, and a Conclusion – of how this work has contributed to knowledge, are given at the start of each chapter, while the impact of the various components of this work is indicated by the number of citations for each of the included publications. Authorship contributions to each of the included publications in this work are also indicated with each specific reference.Thesis (DSc) -- University of Adelaide, School of Biological Sciences, 202

Federal Register

Daily publication of the U.S. Office of the Federal Register contains rules and regulations, proposed legislation and rule changes, and other notices, including "Presidential proclamations and Executive Orders, Federal agency documents having general applicability and legal effect, documents required to be published by act of Congress, and other Federal agency documents of public interest" (p. ii). Table of Contents starts on page iii