Chemical approaches to understanding biological mechanisms

A report on work with small-molecule inhibitors of cellular processes presented at the 39th Annual Meeting of the American Society for Cell Bilogy, Washington DC, December 11-15, 1999     

Synthetic biological approaches to natural product biosynthesis

Small molecules produced in Nature possess exquisite chemical diversity and continue to be an inspiration for the development of new therapeutic agents. In their host organisms, natural products are assembled and modified using dedicated biosynthetic pathways. By rationally reprogramming and manipulating these pathways, unnatural metabolites containing enhanced structural features that were otherwise inaccessible can be obtained. Additionally, new chemical entities can be synthesized by developing the enzymes that carry out these complicated chemical reactions into biocatalysts. In this review, we will discuss a variety of combinatorial biosynthetic strategies, their technical challenges, and highlight some recent (since 2007) examples of rationally designed metabolites, as well as platforms that have been established for the production and modification of clinically important pharmaceutical compounds.     

Quantitative imaging approaches to understanding biological processing of metal ions

Faster, more sensitive, and higher resolution quantitative instrumentation are aiding a deeper understanding of how inorganic chemistry regulates key biological processes. Researchers can now image and quantify metals with subcellular resolution, leading to a vast array of new discoveries in organismal development, pathology, and disease. Metals have recently been implicated in several diseases such as Parkinson's, Alzheimers, ischemic stroke, and colorectal cancer that would not be possible without these advancements. In this review, instead of focusing on instrumentation we focus on recent applications of label-free elemental imaging and quantification and how these tools can lead to a broader understanding of metals role in systems biology and human pathology.     

Synthetic approaches to kasugamine

Reactions are described that lead to an immediate, chemical precursor of kasugamine the amino-sugar component of the aminocyclitol antibiotic kasugamycin. The key reaction involved the introduction of a bromine atom by a stereoselective ring-opening of a benzylidene acetal.     

Systems and synthetic biology approaches in understanding biological oscillators

Background: Self-sustained oscillations are a ubiquitous and vital phenomenon in living systems. From primitive single-cellular bacteria to the most sophisticated organisms, periodicities have been observed in a broad spectrum of biological processes such as neuron firing, heart beats, cell cycles, circadian rhythms, etc. Defects in these oscillators can cause diseases from insomnia to cancer. Elucidating their fundamental mechanisms is of great significance to diseases, and yet challenging, due to the complexity and diversity of these oscillators. Results: Approaches in quantitative systems biology and synthetic biology have been most effective by simplifying the systems to contain only the most essential regulators. Here, we will review major progress that has been made in understanding biological oscillators using these approaches. The quantitative systems biology approach allows for identification of the essential components of an oscillator in an endogenous system. The synthetic biology approach makes use of the knowledge to design the simplest, de novo oscillators in both live cells and cell-free systems. These synthetic oscillators are tractable to further detailed analysis and manipulations. Conclusion: With the recent development of biological and computational tools, both approaches have made significant achievements.     

Global approaches to understanding ubiquitination

Ubiquitination - the linkage of one or more molecules of the protein ubiquitin to another protein - regulates a wide range of biological processes in all eukaryotes. We review the proteome-wide strategies that are being used to study aspects of ubiquitin biology, including substrates, components of the proteasome and ubiquitin ligases, and deubiquitination.     

Molecular approaches to understanding mycorrhizal symbioses

Molecular analyses of plant–microbe interactions have become common place in the last two decades. Although there are philosophical considerations about the application of a reductionist approach to some areas of research, the collaborative interface (e.g. molecular ecology) can provide specialised insight to the generalist, whilst adding broader relevance to the research of the specialist. However, the expense of this discipline has tended to restrict research to work on model host–microbe interactions. Molecular techniques were embraced early on by a few pioneers from the field of mycorrhizal research. Despite some high profile research, the number of molecular mycorrhizal publications has only recently begun to escalate. However the extent of literature now has exceeded the capacity for a comprehensive short review. In this paper we will briefly discuss the use of model species for molecular research and explore the range of questions that are being addressed using molecular techniques, whilst minimising use of specific jargon, to maximise the usefulness of this review to a non specialist audience. Our primary focus is on arbuscular mycorrhizal symbiosis, to complement the papers by Tagu et al., Podila et al. and Chalot et al. (all this volume), who have addressed aspects of research on ectomycorrhizal symbioses. Here we include specific citations from research groups around the world, along with reference to more detailed reviews, to provide a taste of the current excitement in this fundamental and rapidly evolving research field.     

Genetic approaches to understanding sugar-response pathways

Plants as photoautotrophic organisms are able to produce the carbohydrates they require and have developed mechanisms to co-ordinate carbohydrate production and its metabolism. Carbohydrate-derived signals regulate the expression of genes involved in both photosynthesis and metabolism, and control carbohydrate partitioning. A number of genetic approaches have been initiated to understand sugar-response pathways in plants and identify the components involved. Screening strategies to date have been based on the effects of high sugar media on early seedling development or on changes in the enzyme activity or expression of sugar-responsive genes. These screens have established roles for plant hormones in sugar-response pathways, in particular for abscisic acid. The present emphasis on the role of plant hormones in sugar responses is due to the fact that mutants could be readily identified as belonging to these established pathways, but also results from the nature of the mutant screens in use. Progress is being made on the identification of mutants and genes that may be specific to sugar-signalling pathways. It is also expected that the modification of existing screens may target sugar-signalling pathways more directly. Genetic approaches may be especially useful in identifying components of novel signalling pathways unique to plants, and their combination with genomic and molecular approaches will guide future research.     

Synthetic approaches to a carboranyl thiouracil

Thiouracil is selectively incorporated into melanotic murine melanomas during melanin synthesis. This selectivity makes thiouracil a likely vehicle for boron in the diagnosis and therapy of melanoma. Several synthetic routes to thiouracils bearing an alkyl decacarboranyl group attached to various positions on the ring have been investigated. The successful syntheses of three new alkynyl thiouracils and the conversion of one of them into a carboranyl thiouracil are described.     

Modelling the past: new generation approaches to understanding biological patterns in the fossil record

The history of life on this planet is gleaned from analysing how fossils are distributed through time and space. While these patterns are now rather securely known, at least for well-studied parts of the world, their interpretation remains far from simple. Fossils preserve only partial data from which to reconstruct their biology and the geological record is incomplete and biased, so that taxonomic ranges and palaeocommunity structure are imperfectly known. To better understand the often highly complex deep-time processes that gave rise to the empirical fossil record, palaeontologists have turned to modelling the past. Here, we summarize a series of 11 papers that showcase where modelling the past is being applied to advance our understanding across a wide spectrum of current palaeontological endeavours.     

Molecular genetic approaches to understanding disease.

Molecular genetics has greatly increased the understanding of diseases in which there is a single gene defect such as cystic fibrosis. Discovering the gene responsible and its function not only helps determine the pathogenesis of the disease but also offers a possible treatment-gene therapy. Polygenic disorders such as diabetes may soon yield their secrets to the same approach. Animal models of genetic diseases are proving useful research tools, and transgenesis has made xenografting possible. Furthermore, antisense technology allows specific inhibition of undesirably overexpressed genes such as those driving unwanted vascular cell proliferation and restenosis after angioplasty. The completion of the human genome project should make the search for "disease" gene much quicker and will increase still further the importance of these gene based approaches toward diseases.     

Information theoretic approaches to understanding circuit function

The analysis of stimulus/response patterns using information theoretic approaches requires the full probability distribution of stimuli and response. Recent progress in using information-based tools to understand circuit function has advanced understanding of neural coding at the single cell and population level. In advances over traditional reverse correlation approaches, the determination of receptive fields using information as a metric has allowed novel insights into stimulus representation and transformation. The application of maximum entropy methods to population codes has opened a rich exploration of the internal structure of these codes, revealing stimulus-driven functional connectivity. We speculate about the prospects and limitations of information as a general tool for dissecting neural circuits and relating their structure and function.     

Synthetic approaches to the 2010 new drugs

New drugs are introduced to the market every year and each represents a privileged structure for its biological target. These new chemical entities (NCEs) provide insights into molecular recognition and also serve as leads for designing future new drugs. This review covers the synthesis of 15 NCEs that were launched anywhere in the world in 2010.     

Synthetic approaches to the 2012 new drugs

New drugs introduced to the market every year represent a privileged structure for a particular biological target. These new chemical entities (NCEs) provide insights into molecular recognition and also serve as leads for designing future new drugs. This review covers the synthesis of twenty-six NCEs that were launched or approved worldwide in 2012 and two additional drugs which were launched at the end of 2011.     

Synthetic approaches to the 2011 new drugs

New drugs are introduced to the market every year and each represents a privileged structure for its biological target. These new chemical entities (NCEs) provide insights into molecular recognition and also serve as leads for designing future new drugs. This review covers the synthesis of 26 NCEs that were launched in the world in 2011.