BIOMAT Database Logo BIOMAT Database Logo

The effects of DNA supercoiling on G-quadruplex formation. 2017

Doreen A T Sekibo, and Keith R Fox
Biological Sciences, Life Sciences Building 85, University of Southampton, Southampton SO17 1BJ, UK.

Guanine-rich DNAs can fold into four-stranded structures that contain stacks of G-quartets. Bioinformatics studies have revealed that G-rich sequences with the potential to adopt these structures are unevenly distributed throughout genomes, and are especially found in gene promoter regions. With the exception of the single-stranded telomeric DNA, all genomic G-rich sequences will always be present along with their C-rich complements, and quadruplex formation will be in competition with the corresponding Watson-Crick duplex. Quadruplex formation must therefore first require local dissociation (melting) of the duplex strands. Since negative supercoiling is known to facilitate the formation of alternative DNA structures, we have investigated G-quadruplex formation within negatively supercoiled DNA plasmids. Plasmids containing multiple copies of (G3T)n and (G3T4)n repeats, were probed with dimethylsulphate, potassium permanganate and S1 nuclease. While dimethylsulphate footprinting revealed some evidence for G-quadruplex formation in (G3T)n sequences, this was not affected by supercoiling, and permanganate failed to detect exposed thymines in the loop regions. (G3T4)n sequences were not protected from DMS and showed no reaction with permanganate. Similarly, both S1 nuclease and 2D gel electrophoresis of DNA topoisomers did not detect any supercoil-dependent structural transitions. These results suggest that negative supercoiling alone is not sufficient to drive G-quadruplex formation.

UI MeSH Term Description Entries
D011196 Potassium Permanganate Permanganic acid (HMnO4), potassium salt. A highly oxidative, water-soluble compound with purple crystals, and a sweet taste. (From McGraw-Hill Dictionary of Scientific and Technical Information, 4th ed) Permanganate, Potassium
D002942 Circular Dichroism A change from planar to elliptic polarization when an initially plane-polarized light wave traverses an optically active medium. (McGraw-Hill Dictionary of Scientific and Technical Terms, 4th ed) Circular Dichroism, Vibrational,Dichroism, Circular,Vibrational Circular Dichroism
D004278 DNA, Superhelical Circular duplex DNA isolated from viruses, bacteria and mitochondria in supercoiled or supertwisted form. This superhelical DNA is endowed with free energy. During transcription, the magnitude of RNA initiation is proportional to the DNA superhelicity. DNA, Supercoiled,DNA, Supertwisted,Supercoiled DNA,Superhelical DNA,Supertwisted DNA
D005656 Fungal Proteins Proteins found in any species of fungus. Fungal Gene Products,Fungal Gene Proteins,Fungal Peptides,Gene Products, Fungal,Yeast Proteins,Gene Proteins, Fungal,Peptides, Fungal,Proteins, Fungal
D013463 Sulfuric Acid Esters Organic esters of sulfuric acid. Sulfates, Organic,Thiosulfuric Acid Esters,Organic Sulfates,Esters, Sulfuric Acid,Esters, Thiosulfuric Acid
D015719 Single-Strand Specific DNA and RNA Endonucleases Enzymes that catalyze the endonucleolytic cleavage of single-stranded regions of DNA or RNA molecules while leaving the double-stranded regions intact. They are particularly useful in the laboratory for producing "blunt-ended" DNA molecules from DNA with single-stranded ends and for sensitive GENETIC TECHNIQUES such as NUCLEASE PROTECTION ASSAYS that involve the detection of single-stranded DNA and RNA. Single Strand Specific DNA and RNA Endonucleases
D054856 G-Quadruplexes Higher-order DNA and RNA structures formed from guanine-rich sequences. They are formed around a core of at least 2 stacked tetrads of hydrogen-bonded GUANINE bases. They can be formed from one two or four separate strands of DNA (or RNA) and can display a wide variety of topologies, which are a consequence of various combinations of strand direction, length, and sequence. (From Nucleic Acids Res. 2006;34(19):5402-15) DNA G-Quadruplexes,DNA, Quadruplex,G-Quadruplexes, DNA,G-Quadruplexes, RNA,Guanine-Quadruplexes,Guanine-Quartets,Guanine-Tetrads,Quadruplex DNA,RNA, G-Quadruplexes,Tetraplex DNA,DNA G Quadruplexes,DNA, Tetraplex,G Quadruplexes,G Quadruplexes, DNA,G Quadruplexes, RNA,G-Quadruplexes RNA,G-Quadruplexes RNAs,Guanine Quadruplexes,Guanine Quartets,Guanine Tetrads,Guanine-Quartet,Guanine-Tetrad,RNA G-Quadruplexes,RNA, G Quadruplexes,RNAs, G-Quadruplexes
D055029 Inverted Repeat Sequences Copies of nucleic acid sequence that are arranged in opposing orientation. They may lie adjacent to each other (tandem) or be separated by some sequence that is not part of the repeat (hyphenated). They may be true palindromic repeats, i.e. read the same backwards as forward, or complementary which reads as the base complement in the opposite orientation. Complementary inverted repeats have the potential to form hairpin loop or stem-loop structures which results in cruciform structures (such as CRUCIFORM DNA) when the complementary inverted repeats occur in double stranded regions. Hairpin Loop Sequence,Inverted Repeat Sequence,Inverted Tandem Repeats,Palindromic Repeat Sequences,Sequence Palindromes,Stem-Loop Sequence,Hairpin Loop Sequences,Inverted Tandem Repeat,Palindrome, Sequence,Palindromes, Sequence,Palindromic Repeat Sequence,Repeat Sequence, Inverted,Repeat Sequence, Palindromic,Repeat Sequences, Inverted,Repeat Sequences, Palindromic,Repeat, Inverted Tandem,Repeats, Inverted Tandem,Sequence Palindrome,Sequence, Hairpin Loop,Sequence, Inverted Repeat,Sequence, Palindromic Repeat,Sequence, Stem-Loop,Sequences, Hairpin Loop,Sequences, Inverted Repeat,Sequences, Palindromic Repeat,Sequences, Stem-Loop,Stem Loop Sequence,Stem-Loop Sequences,Tandem Repeat, Inverted,Tandem Repeats, Inverted

Related Publications

Doreen A T Sekibo, and Keith R Fox
A new pathway of DNA G-quadruplex formation.
May 2014, Angewandte Chemie (International ed. in English),
Doreen A T Sekibo, and Keith R Fox
How to split a G-quadruplex for DNA detection: new insight into the formation of DNA split G-quadruplex.
August 2015, Chemical science,
Doreen A T Sekibo, and Keith R Fox
Light-induced formation of G-quadruplex DNA secondary structures.
November 2005, Chembiochem : a European journal of chemical biology,
Doreen A T Sekibo, and Keith R Fox
The role of G-Quadruplex DNA in Paraspeckle formation in cancer.
November 2021, Biochimie,
Doreen A T Sekibo, and Keith R Fox
G-quadruplex formation of entirely hydrophobic DNA in organic solvents.
June 2013, Chemical communications (Cambridge, England),
Doreen A T Sekibo, and Keith R Fox
A DNA Polymerase Stop Assay for Characterization of G-Quadruplex Formation and Identification of G-Quadruplex-Interactive Compounds.
January 2019, Methods in molecular biology (Clifton, N.J.),
Doreen A T Sekibo, and Keith R Fox
Quantification of Chemical and Mechanical Effects on the Formation of the G-Quadruplex and i-Motif in Duplex DNA.
September 2017, Biochemistry,
Doreen A T Sekibo, and Keith R Fox
Human telomeric DNA sequence-specific cleaving by G-quadruplex formation.
March 2009, Journal of the American Chemical Society,
Doreen A T Sekibo, and Keith R Fox
Machine learning model for sequence-driven DNA G-quadruplex formation.
November 2017, Scientific reports,
Doreen A T Sekibo, and Keith R Fox
The Importance of Phosphates for DNA G-Quadruplex Formation: Evaluation of Zwitterionic G-Rich Oligodeoxynucleotides.
September 2020, Chembiochem : a European journal of chemical biology,
Copied contents to your clipboard!