Bacher A, Le Van Q, Keller P J, Floss H G
J Biol Chem. 1983 Nov 25;258(22):13431-7.
Growing cultures of Ashbya gossypii were supplemented with various 13C-labeled precursors including [1-13C]acetate, [2-13C]acetate, [1-13C]ribose, [1-13C]glucose, [6-13C]glucose, and [2-13C]glycerol. Riboflavin was isolated from the culture medium, chemically converted to riboflavin tetraacetate, and analyzed by 13C NMR spectroscopy. The xylene ring of riboflavin is formed by dismutation of 6,7-dimethyl-8-ribityllumazine, thus the 8 carbon atoms of the riboflavin xylene ring are composed of 4 biochemically different carbon atoms which are duplicated in the dismutation. The formation of the lumazine from a pyrimidine precursor requires the addition of these 4 carbon atoms which constitute C-6 alpha, C-6, C-7, and C-7 alpha of the lumazine. Results from the present work indicate that these 4 carbon atoms do not arise from acetate, diacetyl, acetoin, or a tetrose, nor from loss of 1 or 2 carbon atoms from either end of a pentose or hexose. Additionally, the data do not support the recent contention that these 4 atoms arise via a dismutation of the pyrimidine precursor of the lumazine. The findings show that there exists a close correspondence between the lumazine carbons 6 alpha, 6, and 7 with C-1, C-2, and C-3, respectively, of a pentose, while C-7 alpha corresponds to C-5 rather than C-4 of a pentose. This in conjunction with results reported earlier indicates an intramolecular rearrangement involving carbons 3, 4, and 5 of a pentose or its biochemical equivalent.
用包括[1-¹³C]乙酸盐、[2-¹³C]乙酸盐、[1-¹³C]核糖、[1-¹³C]葡萄糖、[6-¹³C]葡萄糖和[2-¹³C]甘油在内的各种¹³C标记前体对生长的棉阿舒囊霉培养物进行补充。从培养基中分离出核黄素,化学转化为核黄素四乙酸酯,并通过¹³C核磁共振光谱进行分析。核黄素的二甲苯环由6,7-二甲基-8-核糖基异咯嗪的歧化反应形成,因此核黄素二甲苯环的8个碳原子由4个生物化学上不同的碳原子组成,这些碳原子在歧化反应中会重复出现。从嘧啶前体形成异咯嗪需要添加这4个碳原子,它们构成了异咯嗪的C-6α、C-6、C-7和C-7α。本研究结果表明,这4个碳原子并非来自乙酸盐、双乙酰、乙偶姻或丁糖,也不是来自戊糖或己糖两端1个或2个碳原子的丢失。此外,数据不支持最近关于这4个原子通过异咯嗪嘧啶前体的歧化反应产生的观点。研究结果表明,异咯嗪的碳原子6α、6和7分别与戊糖的C-1、C-2和C-3密切对应,而C-7α对应于戊糖的C-5而非C-4。这与早期报道的结果相结合,表明涉及戊糖或其生物化学等效物的碳3、4和5的分子内重排。
