Watson-Crick helix

In closed circular DNA the value of Wr is usually negative, the secondary structure being a fully formed Watson-Crick helix but with right-handed interwound superhelical turns or left-handed toroidal superhelical turns. The helix is said to be underwound (Lk < Tw). 

This K is considerably smaller than that of the single-strand polymer at neutral pH, and suggests that the molecules have a rather thick structure. Adopting the interrupted-helix model, we may apply Eq. (97) as in the case of poly-L-proline. Noting that the unit translation distance b0 is 1.70 A for the double-stranded Watson-Crick helix (263 ) [i. e., a distance of 3.40 A for two residues, one in each chain], and taking Mu = 328 for poly(adenylic acid), we obtain r = 22 residues per helical... 

The duplexes differed only by the presence or absence of an abasic site at position X. In the absence of an abasic site, X becomes T, and the two strands can associate to form a fully paired Watson-Crick helix (referred to as thc/W duplex). Three abasic derivatives were created by placing different moieties in site X, each containing a synthetically modified 2-deoxyribose moiety (modified with either a tetrahydrofuran group, A F an ethyl group, A E or a propyl group, A P). HSDSC measurements showed that the A T duplex indicated a transition centered around... 

The central strand of the triplex must be purine rich since a pyrimidine does not have two hydrogen bonding surfaces with more than one hydrogen bond. Thus triple-stranded DNA requires a homopurine homopyrimidine region of DNA. If the third strand is purine rich, it forms reverse Hoogsteen hydrogen bonds in an antiparallel orientation with the purine strand of the Watson-Crick helix. If the third strand is pyrimidine rich, it forms Hoogsteen bonds in a parallel orientation with the Watson-Crick paired purine strand. 

Primary and Secondary Structure. The DNA double helix was first identified by Watson and Crick in 1953 (4). Not only was the Watson-Crick model consistent with the known physical and chemical properties of DNA, but it also suggested how genetic information could be organized and rephcated, thus providing a foundation for modem molecular biology. 

In 1953, James Watson and Francis Crick made their classic proposal for the secondary structure of DNA. According to the Watson-Crick model, DNA under physiological conditions consists of two polynucleotide strands, running in opposite directions and coiled around each other in a double helix like the handrails on a spiral staircase. The two strands are complementary rather than identical and are held together by hydrogen bonds between specific pairs of... 

This behavior is readily explained by the double helix an A molecule in one strand is always hydrogen-bonded to a T molecule in the second strand. Similarly, a C molecule in one strand is situated properly to form a hydrogen bond with a G molecule in the other strand. In 1962, Watson, Crick, and Wilkins received the Nobel Prize in medicine (Franklin died in 1958). 

This is consistent with there not being enough space (20 °) for two purines to fit within the helix and too much space for two pyrimidines to get close enough to each other to form hydrogen bonds between them. These relationships are often called the rules of Watson-Crick base pairing. 

The amino acid sequence of our first aPNA (which we termed backbone 1 or bl) was designed based on this amphipathic hehx sequence (Fig. 5.3 B). Specifically, this aPNA backbone included hydrophobic amino acids (Ala and Aib), internal salt bridges (Glu-(aa)3-Lys-(aa)3-Glu), a macrodipole (Asp-(aa)i5-Lys), and an N-ace-tyl cap to favor a-helix formation. The C-termini of these aPNA modules end in a carboxamide function to preclude any potential intramolecular end effects. Each aPNA module incorporates five nucleobases for Watson-Crick base pairing to a target nucleic acid sequence. 

The DNA double heUx illustrates the contribution of multiple forces to the structure of biomolecules. While each individual DNA strand is held together by covalent bonds, the two strands of the helix are held together exclusively by noncovalent interactions. These noncovalent interactions include hydrogen bonds between nucleotide bases (Watson-Crick base pairing) and van der Waals interactions between the stacked purine and pyrimidine bases. The hehx presents the charged phosphate groups and polar ribose sugars of... 

C2 Z = 4 Dx = 1.41 R = 0.102 for 4,115 intensities. The structure is a 3 2 complex of proflavine and CpG. The asymmetrical unit contains one CpG molecule, 1.5 proflavine molecules, 0.5 sulfate ion, and 11 5 water molecules. Two CpG molecules form an antiparallel, Watson-Crick, miniature duplex, with a proflavine intercalated between the base pairs through the wide groove. The double helix has exact (crystallographic), two-fold symmetry, and the crystallographic, two-fold axis passes through the C-9-N-10 vector of the intercalated proflavine. A second and a third molecule of proflavine are stacked on top of the C - G pairs ... 

A -DNA The Watson-Crick model of DNA is based on the x-ray diffraction patterns of B-DNA. Most DNA is B-DNA however, DNA may take on two other conformations, A-DNA and Z-DNA. These conformations are greatly favored by the base sequence or by bound proteins. When B-DNA is slightly dehydrated in the laboratory, it takes on the A conformation. A-DNA is very similar to B-DNA except that the base pairs are not stacked perpendicular to the helix axis rather, they are tilted because the deoxyribose moiety puckers differently. An A-DNA helix is wider and shorter than the B-DNA helix. 

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