Nucleotides 3,’5’-phosphodiester bond

The 5 -phosphoryl group of a mononucleotide can es-terify a second —OH group, forming a phosphodi-ester. Most commonly, this second —OH group is the 3 -OH of the pentose of a second nucleotide. This forms a dinucleotide in which the pentose moieties are linked by a 3 —> 5 phosphodiester bond to form the backbone of RNA and DNA. 

Phosphodiester bonds link the 3 - and 5 -carbons of adjacent monomers. Each end of a nucleotide polymer thus is distinct. We therefore refer to the 5 - end or the 3 - end of polynucleotides, the 5 - end being the one with a free or phosphorylated 5 -hydroxyl. 

The process of RNA synthesis in bacteria—depicted in Figure 37-3—involves first the binding of the RNA holopolymerase molecule to the template at the promoter site to form a PIC. Binding is followed by a conformational change of the RNAP, and the first nucleotide (almost always a purine) then associates with the initiation site on the 3 subunit of the enzyme. In the presence of the appropriate nucleotide, the RNAP catalyzes the formation of a phosphodiester bond, and the nascent chain is now attached to the polymerization site on the P subunit of RNAP. (The analogy to the A and P sites on the ribosome should be noted see Figure... 

The nucleotides forming RNA or DNA molecules are linked together in phosphodiester bonds with sugar-phosphate repeating units. The esters are directionally linked between the 3 -hydroxyl... 

Nitrogenous base plus sugar moiety are called nucleosides. Ribonucleic acids (RNA) resemble DNA in that nucleoside monophosphates are joined through phosphodiester bonds. RNAs differ in that the sugars are p-D-ribose units and the pyrimidine uracil is found in place of thymine. Molecular structures and nomenclature for nitrogenous bases, nucleosides, and nucleotides are delineated in Table 2.2. 

In RNA, the base T found in DNA is replaced by uracil, which is similar in structure to T, but lacks the methyl group. The nucleotides in nucleic acids are linked by phosphodiester bonds between the 3 -hydroxyl of one nucleoside and the 5 -hydroxyl of the sugar of its neighbour in the sequence, as was first shown by Alexander Todd3 in 1952 (Figure 4.13). 

Nucleic acids are polymers of nucleotides joined by 3, 5 -phosphodiester bonds that is, a phosphate group links the 3 carbon of a sugar to the 5 carbon of the next sugar in the chain. Each strand has a distinct 5 end and 3 end, and thus has polarity. A phosphate group is often found at the 5 end, and a hydroxyl group is often found at the 3 end. 

Now that we have the monomers, which are pretty complex in this case, it remains to define how they are joined together to create the polymer. The amino acids in proteins are linked by peptide bonds. The nucleotides in nucleic acids are linked by phosphodiester bonds, as is shown in figure 12.2. These DNA phosphodiester bonds are very stable. Indeed, samples of largely intact DNA can be recovered from organisms that have been extinct for thousands of years. This remarkable stability should not come as a surprise the central importance of DNA in all forms of life requires that it be stable to various sorts of insults. 

Bacteria contain enzymes that catalyse the breaking of phosphodiester links between nucleotides in DNA at specific sites, to which the enzyme is directed by a short sequence of bases. These are known as restriction enzymes and they have resulted in remarkable progress in analysing sequences of DNA fragments. They are endonucleases, i.e., they cleave DNA at the phosphodiester bonds within, rather than at the ends, of DNA chains. They cleave bonds such that sequences of nucleotides, typically 4-8 base pairs, are produced. These are the restriction sequences. 

A nucleotide consists of a heterocyclic base linked to a sugar (ribose or deoxyribose) and a phosphate group also linked to the sugar (Figure 10.6). Nucleic acids are polymers of nucleotides linked together by phosphodiester bonds (Figure 10.7). The enzymes that catalyse the breakdown of nucleic acids to nucleotides are nucleases. 

The removal of introns from pre-messenger RNAs in eukaryotes is catalyzed by the spliceosome, which is a large ribonucleoprotein consisting of at least 70 proteins and five small nuclear RNAs (snRNA) [144]. This splicing pathway involves two phosphotransfer reactions. In the first step, the 5 splice site is attacked by a 2 hydroxy group of an adenosine nucleotide within the intron [indicated by A in Fig. 12] that corresponds to the branch point in the lariat intermediate (Fig. 12,middle). In the second step, the 3 -OH group of the free 5 exon attacks the phosphodiester bond between the intron and... 

The nucleic acid polymer is formed when the nucleotides attach to one another through phosphodiester bonds, which connect the 3 -OH group of one nucleotide to the 5 -OH group of another nucleotide through the phosphate group. The order of the nucleotides in the chain is the primary structure of the DNA or RNA molecule, and it can be represented in short-hand notation with only the base pair designation... 

First identified in 1986 as the catalytic active element in the replication cycle of certain viruses, the hammerhead ribozymes (HHRz) are the smallest known, naturally occurring RNA endonucleases They consist of a single RNA motif which catalyzes a reversible, site-specific cleavage of one of its own phosphodiester bonds . Truncation of this motif allowed a minimal HHRz to be constructed which was the very first ribozyme to be crystallized. HHRz minimal motifs are characterized by a core of eleven conserved nucleotides (bold font in Figure 20) from which three helices of variable length radiate. Selective mutation of any of these conserved residues results in a substantial loss of activity. In the absence of metal ions the structure is relaxed ( extended ), but upon addition of Mg +, hammerhead ribozymes spontaneously fold into a Y-shaped conformation (Figure 20 Color Plate 3). ... 

Phosphodiester Bonds Link Successive Nucleotides in Nucleic Acids... 

FIGURE 8-7 Phosphodiester linkages in the covalent backbone of DNA and RNA. The phosphodiester bonds (one of which is shaded in the DNA) link successive nucleotide units. The backbone of alternating pentose and phosphate groups in both types of nucleic acid is highly polar. The 5 end of the macromolecule lacks a nucleotide at the 5 position, and the 3 end lacks a nucleotide at the 3 position. 

The covalent backbone of DNA and RNA is subject to slow, nonenzymatic hydrolysis of the phosphodiester bonds. In the test tube, RNA is hydrolyzed rapidly under alkaline conditions, but DNA is not the 2 -hydroxyl groups in RNA (absent in DNA) are directly involved in the process. Cyclic 2, 3 -monophosphate nucleotides are the first products of the action of alkali on RNA and are rapidly hydrolyzed further to yield a mixture of 2 -and 3 -nucleoside monophosphates (Fig. 8-8). 

Some restriction endonucleases make staggered cuts on the two DNA strands, leaving two to four nucleotides of one strand unpaired at each resulting end. These unpaired strands are referred to as sticky ends (Fig. 9-3a), because they can base-pair with each other or with complementary sticky ends of other DNA fragments. Other restriction endonucleases cleave both strands of DNA at the opposing phosphodiester bonds, leaving no unpaired bases on the ends, often called blunt ends (Fig. 9-3b). 

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