Chen Bingzi, Bohnert Tonika, Zhou Xinfeng, Dedon Peter C
Biological Engineering Division, Massachusetts Institute of Technology, 77 Massachusetts Avenue, Cambridge, Massachusetts 02139, USA.
Chem Res Toxicol. 2004 Nov;17(11):1406-13. doi: 10.1021/tx049818e.
Oxidation of deoxyribose in DNA leads to the formation of a spectrum of electrophilic products unique to each position in the sugar. For example, chemical reactions following abstraction of the C5'-hydrogen atom partition to form either a nucleoside 5'-aldehyde residue attached to the 5'-end of the DNA strand or a 5'-formyl phosphate residue attached to the 3'-end of the DNA strand that is accompanied by a four-carbon fragment on the 5'-end. We now present two approaches that both identify the latter fragment as 5'-(2-phosphoryl-1,4-dioxobutane) and provide a means to quantify the formation of this residue by different oxidizing agents. The first approach involves oxidation of DNA followed by reaction with O-benzylhydroxylamine to form stable dioxime derivatives of the putative 5'-(2-phosphoryl-1,4-dioxobutane) residues. The beta-elimination product of this dioxime proved to be the expected trans-1,4-dioxo-2-butene, as judged by gas chromatographic and mass spectrometric (GC/MS) comparison to authentic dioximes of cis- and trans-1,4-dioxo-2-butene, which revealed a unique pattern of three signals for each isomer, and by X-ray crystallography. Using a benzylhydroxylamine dioxime derivative of [2H4]-labeled cis-1,4-dioxo-2-butene as an internal standard, the dose-response for the formation of 5'-(2-phosphoryl-1,4-dioxobutane) was determined to be linear for gamma-radiation, with approximately 6 lesions per 10(6) nt per Gy, and nonlinear for Fe2+-EDTA. A comparison of 5'-(2-phosphoryl-1,4-dioxobutane) formation to total deoxyribose oxidation suggests that gamma-radiation produces approximately 0.04 lesions per deoxyribose oxidation event. As a positive control for 5'-oxidation of deoxyribose, the enediyne calicheamicin was observed to produce 5'-(2-phosphoryl-1,4-dioxobutane) at the rate of approximately 9 lesions per 10(6) nt per microM. A second approach to identifying and quantifying the sugar residue involved derivatization with hydrazine and beta-elimination to form pyridazine followed by quantification of the pyridazine by GC/MS. Using this approach, it was observed that the enediyne, neocarzinostatin, produced a linear dose-response for pyridazine formation, as expected given the ability of this oxidant to cause 1'-, 4'-, and 5'-oxidation of deoxyribose in DNA. The antitumor antibiotic, bleomycin, on the other hand, produced pyridazine at a 10-fold lower rate, which is consistent with 4'-chemistry as the predominant mode of deoxyribose oxidation by this agent. These results provide novel insights into the chemistry of deoxyribose oxidation in DNA and two approaches to quantifying the 5'-(2-phosphoryl-1,4-dioxobutane) precursor of trans-1,4-dioxo-2-butene, an electrophile known to react with nucleobases to form novel DNA adducts.
DNA中脱氧核糖的氧化会导致在糖的每个位置形成一系列独特的亲电产物。例如,C5'-氢原子被夺取后的化学反应会产生两种产物,一种是连接在DNA链5'-末端的核苷5'-醛残基,另一种是连接在DNA链3'-末端的5'-甲酰基磷酸残基,同时在5'-末端会伴随一个四碳片段。我们现在介绍两种方法,这两种方法都能确定后一种片段为5'-(2-磷酸基-1,4-二氧代丁烷),并提供了一种量化不同氧化剂形成该残基的方法。第一种方法是先氧化DNA,然后与O-苄基羟胺反应,形成假定的5'-(2-磷酸基-1,4-二氧代丁烷)残基的稳定二肟衍生物。通过气相色谱和质谱(GC/MS)与顺式和反式-1,4-二氧代-2-丁烯的真实二肟进行比较,以及通过X射线晶体学分析,证明该二肟的β-消除产物是预期的反式-1,4-二氧代-2-丁烯,每种异构体都有独特的三个信号模式。使用[2H4]-标记的顺式-1,4-二氧代-2-丁烯的苄基羟胺二肟衍生物作为内标物,确定γ射线辐射下5'-(2-磷酸基-1,4-二氧代丁烷)形成的剂量反应呈线性,每戈瑞每10(6)个核苷酸约有6个损伤位点,而Fe2+-EDTA的剂量反应是非线性的。将5'-(2-磷酸基-1,4-二氧代丁烷)的形成与总脱氧核糖氧化进行比较表明,γ射线辐射每发生一次脱氧核糖氧化事件约产生0.04个损伤位点。作为脱氧核糖5'-氧化的阳性对照,观察到烯二炔加利车霉素以每微摩尔每10(6)个核苷酸约9个损伤位点的速率产生5'-(2-磷酸基-1,4-二氧代丁烷)。鉴定和量化糖残基的第二种方法是用肼进行衍生化并进行β-消除以形成哒嗪,然后通过GC/MS对哒嗪进行量化。使用这种方法观察到,烯二炔新制癌菌素产生的哒嗪形成剂量反应呈线性,鉴于这种氧化剂能够导致DNA中脱氧核糖的1'-、4'-和5'-氧化,这是预期的结果。另一方面,抗肿瘤抗生素博来霉素产生哒嗪的速率低10倍,这与该试剂以4'-化学作为脱氧核糖氧化的主要模式一致。这些结果为DNA中脱氧核糖氧化的化学过程提供了新的见解,以及两种量化反式-1,4-二氧代-2-丁烯的5'-(2-磷酸基-1,4-二氧代丁烷)前体的方法,反式-1,4-二氧代-2-丁烯是一种已知会与核碱基反应形成新型DNA加合物的亲电试剂。
