Actinomycin D and 7-aminoactinomycin D binding to single-stranded DNA

The potent RNA polymerase inhibitors actinomycin D and 7-aminoactinomycin D are shown to bind to single-stranded DNAs. The binding occurs with particular DNA sequences containing guanine residues and is characterized by hypochromic UV absorption changes similar to those observed in interactions of the drugs with double-stranded duplex DNAs. The most striking feature of the binding is the dramatic (ca. 37-fold) enhancement in fluorescence that occurs when the 7-aminoactinomycin is bound to certain single-stranded DNAs. This fluorescence of the complex is also characterized by a 40-nm hypsochromic shift in the emission spectrum of the drug and an increase in the emission anisotropy relative to the free drug or the drug bound to calf thymus DNA. The fluorescence lifetimes change in the presence of the single-stranded DNA in a manner compatible with the intensity difference. Thus, there is an increase in the fraction of the emission corresponding to a 2-ns lifetime component compared to the predominant approximately 0.5-ns lifetime of the free drug. The 7-aminoactinomycin D comigrates in polyacrylamide gels with the single-stranded DNAs, and the fluorescence of the bound drug can be visualized by excitation with 540-nm light. The binding interactions are characterized by association constants of 2.0 x 10(6) to 1.1 x 10(7) M-1.     

HDX‐MS reveals orthosteric and allosteric changes in apolipoprotein‐D structural dynamics upon binding of progesterone

Apolipoprotein‐D is a glycosylated tetrameric lipocalin that binds and transports small hydrophobic molecules such as progesterone and arachidonic acid. Like other lipocalins, apolipoprotein‐D adopts an eight‐stranded β‐barrel fold stabilized by two intramolecular disulphide bonds, with an adjacent α‐helix. Crystallography studies of recombinant apolipoprotein‐D demonstrated no major conformational changes upon progesterone binding. Amide hydrogen‐deuterium exchange mass spectrometry (HDX‐MS) reports structural changes of proteins in solution by monitoring exchange of amide hydrogens in the protein backbone with deuterium. HDX‐MS detects changes in conformation and structural dynamics in response to protein function such as ligand binding that may go undetected in X‐ray crystallography, making HDX‐MS an invaluable orthogonal technique. Here, we report an HDX‐MS protocol for apolipoprotein‐D that solved challenges of high protein rigidity and low pepsin cleavage using rigorous quenching conditions and longer deuteration times, yielding 85% sequence coverage and 50% deuterium exchange. The relative fractional deuterium exchange of ligand‐free apolipoprotein‐D revealed apolipoprotein‐D to be a highly structured protein. Progesterone binding was detected by significant reduction in deuterium exchange in eight peptides. Stabilization of apolipoprotein‐D dynamics can be interpreted as a combined orthosteric effect in the ligand binding pocket and allosteric effect at the N‐terminus and C‐terminus. Together, our experiments provide insight into apolipoprotein‐D structural dynamics and map the effects of progesterone binding that are relayed to distal parts of the protein. The observed stabilization of apolipoprotein‐D dynamics upon progesterone binding demonstrates a common behaviour in the lipocalin family and may have implications for interactions of apolipoprotein‐D with receptors or lipoprotein particles. Statement: We reveal for the first time how apolipoprotein‐D, which is protective in Alzheimer's disease, becomes more ordered when bound to a molecule of steroid hormone. These results significantly extend the understanding of apolipoprotein‐D structure from X‐ray crystallography studies by incorporating information on how protein motion changes over time. To achieve these results an improved protocol was developed, suitable for proteins similar to apolipoprotein‐D, to elucidate how proteins change flexibility when binding to small molecules.     

Footprinting reveals that nogalamycin and actinomycin shuffle between DNA binding sites.

The hypothesis that sequence-selective DNA-binding antibiotics locate their preferred binding sites by a process involving migration from nonspecific sites has been tested by footprinting with DNAase I. Footprinting patterns on the tyrT DNA fragment produced by nogalamycin and actinomycin change with time after mixing the antibiotic with the DNA. Sites of protection as well as enhanced cleavage are seen to develop in a fashion which is both temperature and concentration-dependent. At certain sites cutting is transiently enhanced, then blocked. Limited evidence for slow reaction with echinomycin and mithramycin is presented, but the kinetics of footprinting with daunomycin and distamycin appear instantaneous. The feasibility of adducing direct evidence for shuffling by footprinting seems to be governed by slow dissociation of the antibiotic-DNA complex. It may also be dependent upon the mode of binding, be it intercalative or non-intercalative in character.     

Single-molecule multiparameter fluorescence spectroscopy reveals directional MutS binding to mismatched bases in DNA

Mismatch repair (MMR) corrects replication errors such as mismatched bases and loops in DNA. The evolutionarily conserved dimeric MMR protein MutS recognizes mismatches by stacking a phenylalanine of one subunit against one base of the mismatched pair. In all crystal structures of G:T mismatch-bound MutS, phenylalanine is stacked against thymine. To explore whether these structures reflect directional mismatch recognition by MutS, we monitored the orientation of Escherichia coli MutS binding to mismatches by FRET and anisotropy with steady state, pre-steady state and single-molecule multiparameter fluorescence measurements in a solution. The results confirm that specifically bound MutS bends DNA at the mismatch. We found additional MutS-mismatch complexes with distinct conformations that may have functional relevance in MMR. The analysis of individual binding events reveal significant bias in MutS orientation on asymmetric mismatches (G:T versus T:G, A:C versus C:A), but not on symmetric mismatches (G:G). When MutS is blocked from binding a mismatch in the preferred orientation by positioning asymmetric mismatches near the ends of linear DNA substrates, its ability to authorize subsequent steps of MMR, such as MutH endonuclease activation, is almost abolished. These findings shed light on prerequisites for MutS interactions with other MMR proteins for repairing the appropriate DNA strand.     

Comparing binding site information to binding affinity reveals that Crp/DNA complexes have several distinct binding conformers

We show that the cAMP receptor protein (Crp) binds to DNA as several different conformers. This situation has precluded discovering a high correlation between any sequence property and binding affinity for proteins that bend DNA. Experimentally quantified affinities of Synechocystis sp. PCC 6803 cAMP receptor protein (SyCrp1), the Escherichia coli Crp (EcCrp, also CAP) and DNA were analyzed to mathematically describe, and make human-readable, the relationship of DNA sequence and binding affinity in a given system. Here, sequence logos and weight matrices were built to model SyCrp1 binding sequences. Comparing the weight matrix model to binding affinity revealed several distinct binding conformations. These Crp/DNA conformations were asymmetrical (non-palindromic).     

DNA interaction with DAPI fluorescent dye: Force spectroscopy decouples two different binding modes

In this work, we use force spectroscopy to investigate the interaction between the DAPI fluorescent dye and the λ ‐DNA molecule under high (174 mM) and low (34 mM) ionic strengths. Firstly, we have measured the changes on the mechanical properties (persistence and contour lengths) of the DNA‐DAPI complexes as a function of the dye concentration in the sample. Then, we use recently developed models in order to connect the behavior of both mechanical properties to the physical chemistry of the interaction. Such analysis has allowed us to identify and to decouple two main binding modes, determining the relevant physicochemical (binding) parameters for each of these modes: minor groove binding, which saturates at very low DAPI concentrations ( 0.50 μM) and presents equilibrium binding constants of the order of ～10⁷ M^?1 for the two ionic strengths studied; and intercalation, which starts to play a significant role only after the saturation of the first mode, presenting much smaller equilibrium binding constants (～10⁵ M^?1).     

A computational approach for inferring the cell wall properties that govern guard cell dynamics

Guard cells dynamically adjust their shape in order to regulate photosynthetic gas exchange, respiration rates and defend against pathogen entry. Cell shape changes are determined by the interplay of cell wall material properties and turgor pressure. To investigate this relationship between turgor pressure, cell wall properties and cell shape, we focused on kidney‐shaped stomata and developed a biomechanical model of a guard cell pair. Treating the cell wall as a composite of the pectin‐rich cell wall matrix embedded with cellulose microfibrils, we show that strong, circumferentially oriented fibres are critical for opening. We find that the opening dynamics are dictated by the mechanical stress response of the cell wall matrix, and as the turgor rises, the pectinaceous matrix stiffens. We validate these predictions with stomatal opening experiments in selected Arabidopsis cell wall mutants. Thus, using a computational framework that combines a 3D biomechanical model with parameter optimization, we demonstrate how to exploit subtle shape changes to infer cell wall material properties. Our findings reveal that proper stomatal dynamics are built on two key properties of the cell wall, namely anisotropy in the form of hoop reinforcement and strain stiffening.     

7-Azido-Actinomycin D: A Photoaffinity Probe of the Sequence Specificity of DNA Binding by Actinomycin D

Abstract

Actinomycin D (ActD) is a DNA-binding antitumor antibiotic that appears to act in vivo by inhibiting RNA polymerase. The mechanism of DNA binding of ActD has attracted much attention because of its strong preference for 5′-dGpdC-3′ sequences. Binding is thought to involve intercalation of the tricyclic aromatic phenoxazone ring into a GC step, with the two equivalent cyclic pentapeptide lactone substituents lying in the minor groove and making hydrogen bond contacts with the 2-amino groups of the nearest neighbor guanines. Recent studies have indicated, however, that binding is also influenced by next-nearest neighboring bases. We have examined this higher order specificity using 7-azido-actinomycin-D as a photoaffinity probe, and DNA sequencing techniques to quantitatively monitor sites of covalent photoaddition. We found that GC doublets were strongly preferred only if the 5′- flanking base was a pyrimidine and the 3′-flanking base was not cytosine. In addition we observed a previously unreported preference for binding at a GG doublet in the sequence 5′- TGGG-3′.     

Force spectroscopy of single DNA and RNA molecules

Experiments in which single molecules of RNA and DNA are stretched, and the resulting force as a function of extension is measured have yielded new information about the physical, chemical and biological properties of these important molecules. The behavior of both single-stranded and double-stranded nucleic acids under changing solution conditions, such as ionic strength, pH and temperature, has been studied in detail. There has also been progress in using these techniques to study both the kinetics and equilibrium thermodynamics of DNA-protein interactions. These studies generate unique insights into the functions of these proteins in the cell.     

Force spectroscopy reveals multiple "closed states" of the muscle thin filament

Tropomyosin (Tm) plays a critical role in regulating the contraction of striated muscle. The three-state model of activation posits that Tm exists in three positions on the thin filament: "blocked" in the absence of calcium when myosin cannot bind, "closed" when calcium binds troponin and Tm partially covers the myosin binding site, and "open" after myosin binding forces Tm completely off neighboring sites. However, we recently showed that actin filaments decorated with phosphorylated Tm are driven by myosin with greater force than bare actin filaments. This result cannot be explained by simple steric hindrance and suggests that Tm may have additional effects on actin-myosin interactions. We therefore tested the hypothesis that Tm and its phosphorylation state affect the rate at which single actin-myosin bonds form and rupture. Using a laser trap, we measured the time necessary for the first bond to form between actin and rigor heavy meromyosin and the load-dependent durations of those bonds. Measurements were repeated in the presence of subsaturating myosin-S1 to force Tm from the closed to the open state. Maximum bond lifetimes increased in the open state, but only when Tm was phosphorylated. While the frequency with which bonds formed was extremely low in the closed state, when a bond did form it took significantly less time to do so than with bare actin. These data suggest there are at least two closed states of the thin filament, and that Tm provides additional points of contact for myosin.     

A structural approach reveals how neighbouring C2H2 zinc fingers influence DNA binding specificity

Development of an accurate protein–DNA recognition code that can predict DNA specificity from protein sequence is a central problem in biology. C₂H₂ zinc fingers constitute by far the largest family of DNA binding domains and their binding specificity has been studied intensively. However, despite decades of research, accurate prediction of DNA specificity remains elusive. A major obstacle is thought to be the inability of current methods to account for the influence of neighbouring domains. Here we show that this problem can be addressed using a structural approach: we build structural models for all C₂H₂-ZF–DNA complexes with known binding motifs and find six distinct binding modes. Each mode changes the orientation of specificity residues with respect to the DNA, thereby modulating base preference. Most importantly, the structural analysis shows that residues at the domain interface strongly and predictably influence the binding mode, and hence specificity. Accounting for predicted binding mode significantly improves prediction accuracy of predicted motifs. This new insight into the fundamental behaviour of C₂H₂-ZFs has implications for both improving the prediction of natural zinc finger-binding sites, and for prioritizing further experiments to complete the code. It also provides a new design feature for zinc finger engineering.     

Engineered disulfide reveals structural dynamics of locked SARS-CoV-2 spike

The spike (S) protein of SARS-CoV-2 has been observed in three distinct pre-fusion conformations: locked, closed and open. Of these, the function of the locked conformation remains poorly understood. Here we engineered a SARS-CoV-2 S protein construct “S-R/x3” to arrest SARS-CoV-2 spikes in the locked conformation by a disulfide bond. Using this construct we determined high-resolution structures confirming that the x3 disulfide bond has the ability to stabilize the otherwise transient locked conformations. Structural analyses reveal that wild-type SARS-CoV-2 spike can adopt two distinct locked-1 and locked-2 conformations. For the D614G spike, based on which all variants of concern were evolved, only the locked-2 conformation was observed. Analysis of the structures suggests that rigidified domain D in the locked conformations interacts with the hinge to domain C and thereby restrains RBD movement. Structural change in domain D correlates with spike conformational change. We propose that the locked-1 and locked-2 conformations of S are present in the acidic high-lipid cellular compartments during virus assembly and egress. In this model, release of the virion into the neutral pH extracellular space would favour transition to the closed or open conformations. The dynamics of this transition can be altered by mutations that modulate domain D structure, as is the case for the D614G mutation, leading to changes in viral fitness. The S-R/x3 construct provides a tool for the further structural and functional characterization of the locked conformations of S, as well as how sequence changes might alter S assembly and regulation of receptor binding domain dynamics.     

Binding dynamics of structural nucleoporins govern nuclear pore complex permeability and may mediate channel gating

The nuclear pore complex (NPC) is a permeable sieve that can dilate to facilitate the bidirectional translocation of a wide size range of receptor-cargo complexes. The binding of receptors to FG nucleoporin docking sites triggers channel gating by an unknown mechanism. Previously, we used deoxyglucose and chilling treatments to implicate Nup170p and Nup188p in the control of NPC sieving in Saccharomyces cerevisiae. Here, we report that aliphatic alcohols increase the permeability of wild-type and nup170Delta NPCs. In conjunction with increases in permeability, aliphatic alcohols, deoxyglucose, and chilling trigger the reversible dissociation of several nucleoporins from nup170Delta NPCs. These results are consistent with the hypothesis that NPC gating occurs when molecular latches composed of FG repeats and structural nucleoporins dissociate.     

Actinomycin D complexes with oligonucleotides as models for the binding of the drug to DNA. Paramagnetic induced relaxation experiments on drug-nucleic acid complexes.

Mn(II) ions have been used as a paramagnetic probe to investigate the geometry of drug-oligonucleotide complexes. Nuclear magnetic resonance and electron spin resonance experiments show that Mn(II) ions bind approximately two orders of magnitude stronger to the 5'-terminal phosphate group than to the 3'-5' phosphodiester linkage of deoxydinucleotides. By using mixtures of nucleotides in which only one nucleotide contains a terminal phosphate group, the location of the Mn(II) ion in the drug-nucleotide-Mn(II) complexes may be preselected. The paramagnetic induced relaxation of the nuclear spin systems in these complexes has been used to investigate the geometry of these complexes. These data confirm that actinomycin D is able to recognize and preferentially bind guanine (as opposed to adenine) nucleotides in the quinoid portion of the phenoxazone ring, while both adenine and guanine will bind to the benzenoid portion of the phenoxazone ring. These results suggest that stacking forces are primarily responsible for the general requirement of a guanine base when actinomycin D binds to DNA.     

Force spectroscopy reveals the presence of structurally modified dimers in transthyretin amyloid annular oligomers

Toxicity in amyloidogenic protein misfolding disorders is thought to involve intermediate states of aggregation associated with the formation of amyloid fibrils. Despite their relevance, the heterogeneity and transience of these oligomers have placed great barriers in our understanding of their structural properties. Among amyloid intermediates, annular oligomers or annular protofibrils have raised considerable interest because they may contribute to a mechanism of cellular toxicity via membrane permeation. Here we investigated, by using AFM force spectroscopy, the structural detail of amyloid annular oligomers from transthyretin (TTR), a protein involved in systemic and neurodegenerative amyloidogenic disorders. Manipulation was performed in situ , in the absence of molecular handles and using persistence length‐fit values to select relevant curves. Force curves reveal the presence of dimers in TTR annular oligomers that unfold via a series of structural intermediates. This is in contrast with the manipulation of native TTR that was more often manipulated over length scales compatible with a TTR monomer and without unfolding intermediates. Imaging and force spectroscopy data suggest that dimers are formed by the assembly of monomers in a head‐to‐head orientation with a nonnative interface along their β‐strands. Furthermore, these dimers stack through nonnative contacts that may enhance the stability of the misfolded structure.