Arnott S, Chandrasekaran R, Banerjee A K, He R, Walker J K
Department of Biological Sciences, Purdue University, West Lafayette, IN 47907.
J Biomol Struct Dyn. 1983 Oct;1(2):437-52. doi: 10.1080/07391102.1983.10507453.
Most fibrous polynucleotides of general sequence exhibit secondary structures that are described adequately by regular helices with a repeated motif of only one nucleotide. Such helices exploit the fact that A:T, T:A, G:C, and C:G pairs are essentially isomorphous and have dyadically-related glycosylic bonds. Polynucleotides with regularly repeated base-sequences sometimes assume secondary structures with larger repeated motifs which reflect these base-sequences. The dinucleotide units of the Z-like forms of poly d(As4T):poly d(As4T), poly d(AC):poly d(GT) and poly d(GC):poly d(GC) are dramatic instances of this phenomenon. The wrinkled B and D forms of poly d(GC):poly d(GC) and poly d(AT):poly d(AT) are just as significant but more subtle examples. It is possible also to trap more exotic secondary structures in which the molecular asymmetric unit is even larger. There is, for example, a tetragonal form of poly d(AT):poly d(AT) which has unit cell dimensions a = b = 1.71nm, c = 7.40nm, gamma = 90 degrees. The c dimension corresponds to the pitch of a molecular helix which accommodates 24 successive nucleotide pairs arranged as a 4(3) helix of hexanucleotide duplexes. The great variety of nucleotide conformations which occur in these large asymmetric units has prompted us to describe them as pleiomeric, a term used in botany to describe whorls having more than the usual number of structures. Pleiomeric DNAs need not contain nucleotide conformations that are very different from one another. On the other hand, DNAs carrying nucleotides of very different conformation must be pleiomeric. This is because 4 nucleotides of different conformation are needed to join patches of secondary structure which are as different as A or B or Z. Differences in nucleotide structures may occur also between chains rather than within chains. In poly d(A):poly d(T), the purine nucleotides all contain C3'-endo furanose rings and the pyrimidine nucleotides C2'-endo rings. Analogous heteronomous structures may exist in DNA-RNA hybrids although these duplexes are also found to have symmetrical A-type conformations.
大多数具有一般序列的纤维状多核苷酸呈现出二级结构,这些二级结构可以用仅具有一个核苷酸重复基序的规则螺旋来充分描述。此类螺旋利用了A:T、T:A、G:C和C:G碱基对本质上同构且具有二元相关糖苷键这一事实。具有规则重复碱基序列的多核苷酸有时会呈现出具有更大重复基序的二级结构,这些基序反映了这些碱基序列。聚d(As4T):聚d(As4T)、聚d(AC):聚d(GT)和聚d(GC):聚d(GC)的Z样形式的二核苷酸单元就是这一现象的显著例子。聚d(GC):聚d(GC)和聚d(AT):聚d(AT)的皱缩B型和D型也是同样重要但更为微妙的例子。还可能捕获分子不对称单元甚至更大的更奇特的二级结构。例如,聚d(AT):聚d(AT)有一种四方晶型,其晶胞尺寸为a = b = 1.71nm,c = 7.40nm,γ = 90度。c维度对应于一个分子螺旋的螺距,该螺旋容纳24个连续的核苷酸对,排列成六核苷酸双链体的4(3)螺旋。在这些大的不对称单元中出现的各种各样的核苷酸构象促使我们将它们描述为多形的,这是植物学中用于描述具有比通常数量更多结构的轮状结构的一个术语。多形DNA不一定包含彼此非常不同的核苷酸构象。另一方面,携带构象非常不同的核苷酸的DNA必定是多形的。这是因为需要4个构象不同的核苷酸来连接像A或B或Z那样不同的二级结构片段。核苷酸结构的差异也可能发生在链之间而不是链内。在聚d(A):聚d(T)中,嘌呤核苷酸都含有C3'-内型呋喃糖环,嘧啶核苷酸含有C2'-内型环。DNA-RNA杂交体中可能存在类似的异源结构,尽管这些双链体也被发现具有对称的A型构象。
