335 research outputs found
Highly Improved Electrospray Ionization-Mass Spectrometry Detection of G-Quadruplex-Folded Oligonucleotides and Their Complexes with Small Molecules
G-quadruplexes are nucleic acids structures stabilized by physiological concentration of potassium ions. Because low stability G-quadruplexes are hardly detectable by mass spectrometry, we optimized solvent conditions: isopropanol in a triethylamine/hexafluoroisopropanol mixture highly increased G-quadruplex sensitivity with no modification of the physiological G-quadruplex conformation. G-quadruplexes/G-quadruplex-ligand complexes were also correctly detected at concentration as low as 40 nM. Detection of the physiological conformation of G4s and their complexes opens up the possibility to perform high-throughput screening of G-quadruplex ligands for the development of drug molecules effective against critical human diseases
The cellular protein nucleolin preferentially binds long-looped G-quadruplex nucleic acids
open5noBACKGROUND:
G-quadruplexes (G4s) are four-stranded nucleic acid structures that form in G-rich sequences. Nucleolin (NCL) is a cellular protein reported for its functions upon G4 recognition, such as induction of neurodegenerative diseases, tumor and virus mechanisms activation. We here aimed at defining NCL/G4 binding determinants.
METHODS:
Electrophoresis mobility shift assay was used to detect NCL/G4 binding; circular dichroism to assess G4 folding, topology and stability; dimethylsulfate footprinting to detect G bases involved in G4 folding.
RESULTS:
The purified full-length human NCL was initially tested on telomeric G4 target sequences to allow for modulation of loop, conformation, length, G-tract number, stability. G4s in promoter regions with more complex sequences were next employed. We found that NCL binding to G4s heavily relies on G4 loop length, independently of the conformation and oligonucleotide/loop sequence. Low stability G4s are preferred. When alternative G4 conformations are possible, those with longer loops are preferred upon binding to NCL, even if G-tracts need to be spared from G4 folding.
CONCLUSIONS:
Our data provide insight into how G4s and the associated proteins may control the ON/OFF molecular switch to several pathological processes, including neurodegeneration, tumor and virus activation. Understanding these regulatory determinants is the first step towards the development of targeted therapies.
GENERAL SIGNIFICANCE:
The indication that NCL binding preferentially stimulates and induces folding of G4s containing long loops suggests NCL ability to modify the overall structure and steric hindrance of the involved nucleic acid regions. This protein-induced modification of the G4 structure may represent a cellular mechanosensor mechanism to molecular signaling and disease pathogenesis.openLago, Sara; Tosoni, Elena; Nadai, Matteo; Palumbo, Manlio; Richter, Sara NLago, Sara; Tosoni, Elena; Nadai, Matteo; Palumbo, Manlio; Richter, Sar
Sequence-specific interactions of drugs interfering with the topoisomerase–DNA cleavage complex
AbstractDNA-processing enzymes, such as the topoisomerases (tops), represent major targets for potent anticancer (and antibacterial) agents. The drugs kill cells by poisoning the enzymes' catalytic cycle. Understanding the molecular details of top poisoning is a fundamental requisite for the rational development of novel, more effective antineoplastic drugs. In this connection, sequence-specific recognition of the top–DNA complex is a key step to preferentially direct the action of the drugs onto selected genomic sequences. In fact, the (reversible) interference of drugs with the top–DNA complex exhibits well-defined preferences for DNA bases in the proximity of the cleavage site, each drug showing peculiarities connected to its structural features. A second level of selectivity can be observed when chemically reactive groups are present in the structure of the top-directed drug. In this case, the enzyme recognizes or generates a unique site for covalent drug–DNA binding. This will further subtly modulate the drug's efficiency in stimulating DNA damage at selected sites. Finally, drugs can discriminate not only among different types of tops, but also among different isoenzymes, providing an additional level of specific selection. Once the molecular basis for DNA sequence-dependent recognition has been established, the above-mentioned modes to generate selectivity in drug poisoning can be rationally exploited, alone or in combination, to develop tailor-made drugs targeted at defined loci in cancer cells
Metal ion and inter-domain interactions as functional networks in E. coli topoisomerase I
Escherichia coli topoisomerase I (EcTopoI) is a type IA bacterial topoisomerase which is receiving large attention due to its potential application as novel target for antibacterial therapeutics. Nevertheless, a detailed knowledge of its mechanism of action at molecular level is to some extent lacking. This is partly due to the requirement of several factors (metal ions, nucleic acid) to the proper progress of the enzyme catalytic cycle. Additionally, each of them can differently affect the protein structure. Here we assess the role of the different components (DNA, metal ions, protein domains) in a dynamic environment as in solution by monitoring the catalytic as well as the structural properties of EcTopoI. Our results clearly indicated the interaction among these components as functionally relevant and underlined their mutual involvement. Some similarities with other enzymes of the same family emerged (for example DNA prevents divalent metal ions coordination at non selective binding sites). Interestingly, same interactions (C- and N-terminal domain interaction) appear to be peculiar of this bacterial topoisomerase which suggest they could be favorably exploited to the design of selective inhibitors for this class of enzyme
Formation of a Unique Cluster of G-Quadruplex Structures in the HIV-1 nef Coding Region: Implications for Antiviral Activity
G-quadruplexes are tetraplex structures of nucleic acids that can form in G-rich sequences. Their presence and functional role have been established in telomeres, oncogene promoters and coding regions of the human chromosome. In particular, they have been proposed to be directly involved in gene regulation at the level of transcription. Because the HIV-1 Nef protein is a fundamental factor for efficient viral replication, infectivity and pathogenesis in vitro and in vivo, we investigated G-quadruplex formation in the HIV-1 nef gene to assess the potential for viral inhibition through G-quadruplex stabilization. A comprehensive computational analysis of the nef coding region of available strains showed the presence of three conserved sequences that were uniquely clustered. Biophysical testing proved that G-quadruplex conformations were efficiently stabilized or induced by G-quadruplex ligands in all three sequences. Upon incubation with a G-quadruplex ligand, Nef expression was reduced in a reporter gene assay and Nef-dependent enhancement of HIV-1 infectivity was significantly repressed in an antiviral assay. These data constitute the first evidence of the possibility to regulate HIV-1 gene expression and infectivity through G-quadruplex targeting and therefore open a new avenue for viral treatment. © 2013 Perrone et al
Clerocidin interacts with the cleavage complex of Streptococcus pneumoniae topoisomerase IV to induce selective irreversible DNA damage
Clerocidin (CL), a diterpenoid natural product, alkylates DNA through its epoxide moiety and exhibits both anticancer and antibacterial activities. We have examined CL action in the presence of topoisomerase IV from Streptococcus pneumoniae. CL promoted irreversible enzyme-mediated DNA cleavage leading to single- and double-stranded DNA breaks at specific sites. Reaction required the diterpenoid function: no cleavage was seen using a naphthalene-substituted analogue. Moreover, drug-induced DNA breakage was not observed using a mutant topoisomerase IV (ParC Y118F) unable to form a cleavage complex with DNA. Sequence analysis of 102 single-stranded DNA breaks and 79 double-stranded breaks revealed an overwhelming preference for G at the −1 position, i.e. immediately 5′ of the enzyme DNA scission site. This specificity contrasts with that of topoisomerase IV cleavage with antibacterial quinolones. Indeed, CL stimulated DNA breakage by a quinolone-resistant topoisomerase IV (ParC S79F). Overall, the results indicate that topoisomerase IV facilitates selective irreversible CL attack at guanine and that its cleavage complex differs markedly from that of mammalian topoisomerase II which promotes both irreversible and reversible CL attack at guanine and cytosine, respectively. The unique ability to form exclusively irreversible DNA breaks suggests topoisomerase IV may be a key intracellular target of CL in bacteria
Mapping Drug Interactions at the Covalent Topoisomerase II-DNA Complex by Bisantrene/Amsacrine Congeners *
To identify structural determinants for the sequence-specific recognition of covalent topoisomerase II-DNA complexes by anti-cancer drugs, we investigated a number of bisantrene congeners, including a 10-azabioisoster, bearing one or two 4, 5-dihydro-1H-imidazol-2-yl hydrazone side chains at positions 1, 4, or 9 of the anthracene ring system. The studied bisantrene/amsacrine (m-AMSA) hybrid and bisantrene isomers were able to poison DNA topoisomerase II with an intermediate activity between those of bisantrene and m-AMSA. Moving the side chain from the central to a lateral ring (from C-9 to C-1/C-4) only slightly modified the drug DNA affinity, whereas it dramatically affected local base preferences of poison-stimulated DNA cleavage. In contrast, switching the planar aromatic systems of bisantrene and m-AMSA did not substantially alter the sequence specificity of drug action. A computer-assisted steric and electrostatic alignment analysis of the test compounds was in agreement with the experimental data, since a common pharmacophore was shared by bisantrene, m-AMSA, and 9-substituted analogs, whereas the 1-substituted isomer showed a radically changed pharmacophoric structure. Thus, the relative space occupancy and electron distribution of putative DNA binding (aromatic rings) and enzyme binding (side chains) moieties are fundamental in directing the specific action of topoisomerase II poisons and in determining the poison pharmacophore
Hot-spot consensus of fluoroquinolone-mediated DNA cleavage by Gram-negative and Gram-positive type II DNA topoisomerases
Bacterial DNA gyrase and topoisomerase IV are selective targets of fluoroquinolones. Topoisomerase IV versus gyrase and Gram-positive versus Gram-negative behavior was studied based on the different recognition of DNA sequences by topoisomerase–quinolone complexes. A careful statistical analysis of preferred bases was performed on a large number (>400) of cleavage sites. We found discrete preferred sequences that were similar when using different enzymes (i.e. gyrase and topoisomerase IV) from the same bacterial source, but in part diverse when employing enzymes from different origins (i.e. Escherichia coli and Streptococcus pneumoniae). Subsequent analysis on the wild-type and mutated consensus sequences showed that: (i) Gn/Cn-rich sequences at and around the cleavage site are hot spots for quinolone-mediated strand breaks, especially for E. coli topoisomerases: we elucidated positions required for quinolone and enzyme recognition; (ii) for S. pneumoniae enzymes only, A and T at positions −2 and +6 are discriminating cleavage determinants; (iii) symmetry of the target sequence is a key trait to promote cleavage and (iv) the consensus sequence adopts a heteronomous A/B conformation, which may trigger DNA processing by the enzyme–drug complex
Screening of candidate G-quadruplex ligands for the human c-KIT promotorial region and their effects in multiple in-vitro models
Stabilization of G-quadruplex (G4) structures in promoters is a novel promising
strategy to regulate gene expression at transcriptional and translational levels. c-KIT
proto-oncogene encodes for a tyrosine kinase receptor. It is involved in several
physiological processes, but it is also dysregulated in many diseases, including cancer.
Two G-rich sequences able to fold into G4, have been identified in c-KIT proximal
promoter, thus representing suitable targets for anticancer intervention. Herein, we
screened an \u201cin house\u201d library of compounds for the recognition of these G4 elements
and we identified three promising ligands. Their G4-binding properties were analyzed
and related to their antiproliferative, transcriptional and post-transcriptional effects
in MCF7 and HGC27 cell lines. Besides c-KIT, the transcriptional analysis covered a
panel of oncogenes known to possess G4 in their promoters.
From these studies, an anthraquinone derivative (AQ1) was found to efficiently
downregulate c-KIT mRNA and protein in both cell lines. The targeted activity of AQ1
was confirmed using c-KIT\u2013dependent cell lines that present either c-KIT mutations
or promoter engineered (i.e., \u3b1155, HMC1.2 and ROSA cells).
Present results indicate AQ1 as a promising compound for the target therapy
of c-KIT-dependent tumors, worth of further and in depth molecular investigations
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