Chemistry and Biology of Non-canonical Nucleic Acids. Naoki Sugimoto. Читать онлайн. Newlib. NEWLIB.NET

Автор: Naoki Sugimoto
Издательство: John Wiley & Sons Limited
Серия:
Жанр произведения: Химия
Год издания: 0
isbn: 9783527817863
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of Z-DNA-binding proteins has been identified in various organisms including eukaryotes, prokaryotes, and viruses [10].

Schematic illustration of the structure of four-way junction to form cruciform and Holliday junction. (a) S-type and C-type pathways to form cruciform structure from long duplex. (b) Structure of Holliday junction formed by DNA strand with 5′-TCGGTACCGA-3′ sequence. Top view of four TA consecutive nucleobases at the region of interstrand exchange are shown above the structure.

      Among the multi-stranded nucleic acid structures, triplexes and tetraplexes composed of three and four strands, respectively, have been confirmed in not only aqueous solutions but also intracellular conditions and have attracted attention as non-canonical structures that contribute to gene regulations. Various studies have been conducted on the molecular mechanisms of their influence on the gene expressions from viewpoints of their thermodynamic stabilities and conformational dynamics. The structural characteristics and factors that contribute to the thermodynamic stabilities of triplex and representative tetraplexes, G-quadruplex and i-motif, are described in Chapter 3. The effects of these multi-stranded structures on gene expressions are explained in Chapters 58, focusing on DNA replication including telomeric regions, RNA transcription, and protein translation.

      RNA is transcribed from DNA as a single strand, whereas the natural DNA basically exists as a set of complementary strands. The information transformed into functional proteins as a sequence of amino acids is encoded on the primary sequence of RNA. On the other hand, information to modulate the gene expressions exists in their higher-order structures, which are dependent on the secondary and tertiary interactions.

      2.6.1 Basic Structure Distinctions of RNA

Schematic illustration of the typical structures of multi-stranded DNA helices. (a) Canonical duplex. (b) Triplex. (c) G-quadruplex. (d) i-motif. (e) DNA hexaplex. (f) DNA octaplex. Top views of nucleobase interactions that are located on coplanar region and important for the formation of multi-stranded helix are shown along with the structure. BrC indicates cytosine modified by bromine.

      2.6.2 Elements in RNA Secondary Structures

      Single-stranded RNAs basically form their structure based on Watson–Crick-type base pairing within the same strand. At that time, bases not involved in the base pairs remain as single-stranded loop. Depending on how the single-stranded loop region is formed, RNA forms various secondary structures.