Mayer F, Mazaitis A J, Pühler A
J Virol. 1975 Mar;15(3):585-98. doi: 10.1128/JVI.15.3.585-598.1975.
After isolation, the DNA of simian virus 40 appeared as a negative supertwist (form I) or as an open circle with at least one single-strand scission (form II). Under the denaturation conditions usually applied, such as heating in the presence of formaldehyde or application of alkali, form I molecules could appear as "relaxed" circles without single-strand scissions (form I') containing denatured sites not visible under the electron microscope. Form II molecules, under these denaturation conditions, showed partial or complete strand separations allowing the construction of denaturation maps. By using a modified denaturation procedure, i.e., heating of isolated SV40 DNA in the presence of dimethyl sulfoxide and formaldehyde followed by keeping the DNA in this denaturation solution at room temperature for periods up to 3 weeks, partially denatured relaxed circles without single-strand scissions were produced (form I'D) in addition to completely denatured form II molecules. The absence of single-strand scissions in form I'D molecules was demonstrated by a second heat treatment, which did not change the configuration of this molecular form. Form I'D molecules, in contrast to form I', contained denatured sites clearly discerible under the electron microscope. This combined application of two subsequent denaturation steps (denaturation by heating followed by denaturation at room temperature and neutral pH) showed that the molecular configuration I'D originated in two steps. The heating procedure produced molecules not distinquishable by electron microscopy from form I. In contrast to form I, these molecules were assumed to possess "preformed" denaturation sites (form I). Further treatment of form I molecules with denaturation solution at room temperature finally transformed them into convalently closed, relaxed, partially denatured circles exhibiting strand separations easily measurable on electron micrographs (form I'D). Denaturation maps of form I'D molecules were constructed by computer and compared with denaturation maps derived from partially denatured form II molecules. From these denaturation maps it can be concluded that the melting of base pairs occurring during the transition of simian virus 40 DNA form I into form I'D also preferentially happened at sites rich in the bases adenosine and thymine.
分离后,猿猴病毒40的DNA呈现为负超螺旋(I型)或带有至少一个单链断裂的开环(II型)。在通常采用的变性条件下,如在甲醛存在下加热或施加碱,I型分子可能呈现为无单链断裂的“松弛”环(I'型),其中包含在电子显微镜下不可见的变性位点。在这些变性条件下,II型分子显示出部分或完全的链分离,从而可以构建变性图谱。通过使用改良的变性程序,即在二甲基亚砜和甲醛存在下加热分离的SV40 DNA,然后将DNA在该变性溶液中于室温下保持长达3周,除了完全变性的II型分子外,还产生了没有单链断裂的部分变性松弛环(I'D型)。通过第二次热处理证明了I'D型分子中不存在单链断裂,该热处理不会改变这种分子形式的构型。与I'型相比,I'D型分子包含在电子显微镜下清晰可辨的变性位点。这两个后续变性步骤(加热变性,然后在室温及中性pH下变性)的联合应用表明,分子构型I'D是分两步形成的。加热程序产生的分子在电子显微镜下与I型无法区分。与I型不同,这些分子被认为具有“预形成”的变性位点(I型)。在室温下用变性溶液对I型分子进行进一步处理,最终将它们转化为共价闭合、松弛、部分变性的环,在电子显微镜照片上显示出易于测量的链分离(I'D型)。通过计算机构建I'D型分子的变性图谱,并与从部分变性的II型分子获得的变性图谱进行比较。从这些变性图谱可以得出结论,猿猴病毒40 DNA从I型转变为I'D型过程中发生的碱基对解链也优先发生在富含腺嘌呤和胸腺嘧啶的位点。
