Accelerated assembly of G-quadruplex structures by a small molecule.

In the presence of alkali cations, notably potassium and sodium, DNA oligomers that possess two G-rich repeats associate into either a tetrameric parallel G-quadruplex or a variety of dimeric antiparallel G-quadruplexes. The formation of such structures is normally a very slow process. Some proteins, such as the beta-subunit of the Oxytricha telomere-binding protein, promote the formation of G-quadruplex structures in a chaperone-like manner. In this report, we present data concerning the role of a perylene derivative, PIPER, in the assembly of G-quadruplex structures as the first example of a small ligand behaving as a driver in the assembly of polynucleotide secondary structures. Gel-shift experiments demonstrate that PIPER can dramatically accelerate the association of a DNA oligomer containing two tandem repeats of the human telomeric sequence (TTAGGG) into di- and tetrameric G-quadruplexes. In so doing, PIPER alters the oligomer dimerization kinetics from second to first order. The presence of 10 microM PIPER accelerates the assembly of varied dimeric G-quadruplexes an estimated 100-fold from 2 microM oligomer. These results imply that some biological effects elicited by G-quadruplex-interactive agents, such as the induction of anaphase bridges, may stem from the propensity such compounds have for assembling G-quadruplexes.     

Chemical genetics: a small molecule approach to neurobiology

Chemical genetics, or the specific modulation of cellular systems by small molecules, has complemented classical genetic analysis throughout the history of neurobiology. We outline several of its contributions to the understanding of ion channel biology, heat and cold signal transduction, sleep and diurnal rhythm regulation, effects of immunophilin ligands, and cell surface oligosaccharides with respect to neurobiology.     

Chemical conditionality: a genetic strategy to probe organelle assembly

The assembly of the Escherichia coli outer membrane (OM) is poorly understood. Although insight into fundamental cellular processes is often obtained from studying mutants, OM-defective mutants have not been very informative because they generally have nonspecific permeability defects. Here we show that toxic small molecules can be used in selections employing strains with permeability defects to create particular chemical conditions that demand specific suppressor mutations. Suppressor phenotypes are correlated with the physical properties of the small molecules, but the mutations are not in their target genes. Instead, mutations allow survival by partially restoring membrane impermeability. Using "chemical conditionality," we identified mutations in yfgL, and, here and in the accompanying paper by Wu et al. published in this issue of Cell (Wu et al., 2005), we show that YfgL is part of a multiprotein complex involved in the assembly of OM beta barrel proteins. We posit that panels of toxic small molecules will be useful for generating chemical conditionalities that enable identification of genes required for organelle assembly in other organisms.     

Chemical genetic approaches for the elucidation of signaling pathways

New chemical methods that use small molecules to perturb cellular function in ways analogous to genetics have recently been developed. These approaches include both synthetic methods for discovering small molecules capable of acting like genetic mutations, and techniques that combine the advantages of genetics and chemistry to optimize the potency and specificity of small-molecule inhibitors. Both approaches have been used to study protein function in vivo and have provided insights into complex signaling cascades.     

Probing spindle assembly mechanisms with monastrol, a small molecule inhibitor of the mitotic kinesin, Eg5

Monastrol, a cell-permeable small molecule inhibitor of the mitotic kinesin, Eg5, arrests cells in mitosis with monoastral spindles. Here, we use monastrol to probe mitotic mechanisms. We find that monastrol does not inhibit progression through S and G2 phases of the cell cycle or centrosome duplication. The mitotic arrest due to monastrol is also rapidly reversible. Chromosomes in monastrol-treated cells frequently have both sister kinetochores attached to microtubules extending to the center of the monoaster (syntelic orientation). Mitotic arrest-deficient protein 2 (Mad2) localizes to a subset of kinetochores, suggesting the activation of the spindle assembly checkpoint in these cells. Mad2 localizes to some kinetochores that have attached microtubules in monastrol-treated cells, indicating that kinetochore microtubule attachment alone may not satisfy the spindle assembly checkpoint. Monastrol also inhibits bipolar spindle formation in Xenopus egg extracts. However, it does not prevent the targeting of Eg5 to the monoastral spindles that form. Imaging bipolar spindles disassembling in the presence of monastrol allowed direct observations of outward directed forces in the spindle, orthogonal to the pole-to-pole axis. Monastrol is thus a useful tool to study mitotic processes, detection and correction of chromosome malorientation, and contributions of Eg5 to spindle assembly and maintenance.     

Integration of biological networks and pathways with genetic association studies

Millions of genetic variants have been assessed for their effects on the trait of interest in genome-wide association studies (GWAS). The complex traits are affected by a set of inter-related genes. However, the typical GWAS only examine the association of a single genetic variant at a time. The individual effects of a complex trait are usually small, and the simple sum of these individual effects may not reflect the holistic effect of the genetic system. High-throughput methods enable genomic studies to produce a large amount of data to expand the knowledge base of the biological systems. Biological networks and pathways are built to represent the functional or physical connectivity among genes. Integrated with GWAS data, the network- and pathway-based methods complement the approach of single genetic variant analysis, and may improve the power to identify trait-associated genes. Taking advantage of the biological knowledge, these approaches are valuable to interpret the functional role of the genetic variants, and to further understand the molecular mechanism influencing the traits. The network- and pathway-based methods have demonstrated their utilities, and will be increasingly important to address a number of challenges facing the mainstream GWAS.     

Chemical genetic interrogation of natural variation uncovers a molecule that is glycoactivated

Natural variation in human drug metabolism and target genes can cause pharmacogenetic or interindividual variation in drug sensitivity. We reasoned that natural pharmacogenetic variation in model organisms could be systematically exploited to facilitate the characterization of new small molecules. To test this, we subjected multiple Arabidopsis thaliana accessions to chemical genetic screens and discovered 12 accession-selective hit molecules. As a model for understanding this variation, we characterized natural resistance to hypostatin, a new inhibitor of cell expansion. Map-based cloning identified HYR1, a UDP glycosyltransferase (UGT), as causative for hypostatin resistance. Multiple lines of evidence demonstrate that HYR1 glucosylates hypostatin in vivo to form a bioactive glucoside. Additionally, we delineated a HYR1 substrate motif and used it to identify another molecule modulated by glucosylation. Our results demonstrate that natural variation can be exploited to inform the biology of new small molecules, and that UGT sequence variation affects xenobiotic sensitivity across biological kingdoms.     

Convergence of distinct pathways to heart patterning revealed by the small molecule concentramide and the mutation heart-and-soul

BACKGROUND: One of the earliest steps in heart formation is the generation of two chambers, as cardiogenic cells deployed in the epithelial sheet of mesoderm converge to form the nascent heart tube. What guides this transformation to organotypic form is not known. RESULTS: We have identified a small molecule, concentramide, and a genetic mutation called heart-and-soul (has) that disrupt heart patterning. Both cause the ventricle to form within the atrium. Here, we show that the has gene encodes PKC lambda. The effect of the has mutation is to disrupt epithelial cell-cell interactions in a broad range of tissues. Concentramide does not disrupt epithelial interactions, but rather shifts the converging heart field rostrally. What is shared between the concentramide and has effects is a reversal of the order of fusion of the anterior and posterior ends of the heart field. CONCLUSIONS: The polarity of cardiac tube assembly is a critical determinant of chamber orientation and is controlled by at least two distinct molecular pathways. Combined chemical/genetic dissection can identify nodal points in development, of special importance in understanding the complex patterning events of organogenesis.     

Amplified insert assembly: an optimized approach to standard assembly of BioBrickTM genetic circuits

A modified BioBrick? assembly method was developed with higher fidelity than current protocols. The method utilizes a PCR reaction with a standard primer set to amplify the inserted part. Background colonies are reduced by a combination of dephosphorylation and digestion with DpnI restriction endonuclease to reduce vector and insert background respectively. The molar ratio of the insert to vector in the ligation was also optimized, with the accuracy of the transformed construct approaching 100%.     

Kinetic studies of small molecule interactions with protein kinases using biosensor technology

Protein kinases are among the most commonly targeted groups of molecules in drug discovery today. Despite this, there are few examples of using surface plasmon resonance (SPR) for kinase inhibitor interaction studies, probably reflecting the need for better developed assays for these proteins. In this article, we present a general methodology that uses biosensor technology to study small molecule binding to eight different serine/threonine and tyrosine kinases. Mild immobilization conditions and a carefully composed assay buffer were identified as key success factors. The methodology package consists of direct binding studies of compounds to immobilized kinases, kinase activity assays to confirm inhibitory effects, detailed kinetic analyses of inhibitor binding, and competition assays with ATP for identification of competitive inhibitors. The kinetic assays resolve affinity into the rates of inhibitor binding and dissociation. Therefore, more detailed information on the relation between inhibitor structure and function is obtained. This might be of key importance for the development of effective kinase inhibitors.     

Acquisition of the covalent quaternary structure of an immunoglobulin G molecule. Reoxidative assembly in vitro.

We recently reported results of an investigation of the reoxidation of a human, monoclonal immunoglobulin G, following selective reduction of its interchain disulfides by dithiothreitol (Sears, D.W., et al. (1975), Proc. Natl. Acad. Sci. U.S.A. 72, 353). In that work, we described the reoxidative behavior of the molecule under nondissociating conditions. In the present paper, results are presented of the reoxidation of heavy (H) and light (L) chains of this protein alone, or mixed in varying proportions after separation, or mixed with the L chains modified prior to recombination and reoxidation. The overall reoxidative asembly patterns in experiments with H and L separated prior to recombination are similar to those observed when the chains remain noncovalently associated throughout. With equimolar mixtures of H and L, the reoxidation rates also are similar to those of unseparated chains. However, when L chains are present in excess, the overall in vitro rates of covalent assembly are generally diminished, probably indicating transient nonproductive interactions. At the highest molar excesses of L (3:1), the assembly pathways may also be modified. In all experiments with excess L chains, covalent L2 dimers form at rates which are comparatively slow relative to the H2L2 assembly rates. Two kinds of reoxidation experiments with modified L chains are described here for the first time. In the first, the free half-cystine of L is irreversibly blocked by reaction with iodoacetamide, and the alkylated L chains are recombined with reduced H chains. This experiment isolates the reactions in which H2 disulfides are formed without the accompanying formation of HL bonds. Although the alkylated L chains do not play a direct role in the reoxidation, their presence is required to inhibit aggregation and precipitation of high-molecular-weight products which otherwise ensue; this suggests a possible biological role for excess L in vivo. In the second kind of experiment, covalent L2 dimers are mixed with reduced H chains. L2 rapidly disappears with the concurrent appearance of HL, H2L, and fully assembled H2L. H2 dimers are also reactive in this process. Special procedures were developed for analyzing the data from these experiments. A complete format is given for the quantitative determination of the concentration of each of the molecular components directly from spectroscopic scans of the gels. The computational methods solve the general analytical problem posed when staining is not proportional to mass and are applicable to a wide variety of systems utilizing gel electrophoresis to study subunit interactions. A theoretical analysis of pathway and kinetic cooperatively in this system is presented in the following paper (Sears, D.W., and Beychok, S. (1977), Biochemistry 16 (following paper in this issue)).     

The evolution and structural anatomy of the small molecule metabolic pathways in Escherichia coli

The 106 small molecule metabolic (SMM) pathways in Escherichia coli are formed by the protein products of 581 genes. We can define 722 domains, nearly all of which are homologous to proteins of known structure, that form all or part of 510 of these proteins. This information allows us to answer general questions on the structural anatomy of the SMM pathway proteins and to trace family relationships and recruitment events within and across pathways. Half the gene products contain a single domain and half are formed by combinations of between two and six domains. The 722 domains belong to one of 213 families that have between one and 51 members. Family members usually conserve their catalytic or cofactor binding properties; substrate recognition is rarely conserved. Of the 213 families, members of only a quarter occur in isolation, i.e. they form single-domain proteins. Most members of the other families combine with domains from just one or two other families and a few more versatile families can combine with several different partners.Excluding isoenzymes, more than twice as many homologues are distributed across pathways as within pathways. However, serial recruitment, with two consecutive enzymes both being recruited to another pathway, is rare and recruitment of three consecutive enzymes is not observed. Only eight of the 106 pathways have a high number of homologues. Homology between consecutive pairs of enzymes with conservation of the main substrate-binding site but change in catalytic mechanism (which would support a simple model of retrograde pathway evolution) occurs only six times in the whole set of enzymes. Most of the domains that form SMM pathways have homologues in non-SMM pathways. Taken together, these results imply a pervasive "mosaic" model for the formation of protein repertoires and pathways.     

Light-scattering studies on deoxyribonucleic acid flexibility. The solution properties of a small circular deoxyribonucleic acid molecule

Previous investigations on the persistence length of DNA in solution have revealed large discrepancies between hydrodynamic results and those from light-scattering techniques which have potentially a greater resolving power. The information obtained from experiments on a small circular DNA molecule has resolved these discrepancies. The non-superhelical circular double-stranded DNA molecule from bacteriophage [unk]X174-infected cells is small enough to permit accurate light-scattering extrapolations, and its solutions have negligible anisotropy. The persistence length obtained from experimental investigations on this molecule is comparable with that obtained by hydrodynamic techniques, even with variation of the excluded-volume factor.     

A small molecule with differential effects on the PTS1 and PTS2 peroxisome matrix import pathways

The use of small molecules has great power to dissect biological processes. This study presents the identification and characterisation of an inhibitor of peroxisome matrix protein import. A mini-screen was carried out to identify molecules that cause alteration in peroxisome morphology, or mislocalization of a peroxisome targeted fluorescent reporter protein. A benzimidazole lead compound (LDS-003655) was identified that resulted in reduced GFP fluorescence in peroxisomes and cytosolic GFP accumulation. The effect of the compound was specific to peroxisomes as Golgi bodies, endoplasmic reticulum and the actin cytoskeleton were unaffected even at 25 μM, whereas peroxisome import via the PTS1 pathway was compromised at 100 nM. When seedlings were grown on 25 μM LDS-003655 they displayed morphology typical of seedlings grown in the presence of auxin, and expression of the auxin reporter DR5::GFP was induced. Analysis of a focussed library of LDS-003655 derivatives in comparison with known auxins led to the conclusion that the auxin-like activity of LDS-003655 is attributable to its in situ hydrolysis giving rise to 2,5-dichlorobenzoic acid, whereas the import inhibiting activity of LDS-003655 requires the whole molecule. None of the auxins tested had any effect on peroxisome protein import. Matrix import by the PTS2 import pathway was relatively insensitive to LDS-003655 and its active analogues, with effects only seen after prolonged incubation on high concentrations. Steady-state protein levels of PEX5, the PTS1 import pathway receptor, were reduced in the presence of 100 nM LDS-003655, suggesting a possible mechanism for the import inhibition.     

Screening for small molecule inhibitors of embryonic pathways: sometimes you gotta crack a few eggs

Extract prepared from Xenopus eggs represents a cell-free system that has been shown to recapitulate a multitude of cellular processes, including cell cycle regulation, DNA replication/repair, and cytoskeletal dynamics. In addition, this system has been used to successfully reconstitute the Wnt pathway. Xenopus egg extract, which can be biochemically manipulated, offers an ideal medium in which small molecule screening can be performed in near native milieu. Thus, the use of Xenopus egg extract for small molecule screening represents an ideal bridge between targeted and phenotypic screening approaches. This review focuses on the use of this system for small molecules modulators of major signal transduction pathways (Notch, Hedgehog, and Wnt) that are critical for the development of the early Xenopus embryo. We describe the properties of Xenopus egg extract and our own high throughput screen for small molecules that modulate the Wnt pathway using this cell-free system. We propose that Xenopus egg extract could similarly be adapted for screening for modulators of the Notch and Hedgehog pathways.