Dybvig K, Voelker L L
Department of Comparative Medicine, University of Alabama at Birmingham 35294, USA.
Annu Rev Microbiol. 1996;50:25-57. doi: 10.1146/annurev.micro.50.1.25.
Although mycoplasmas lack cell walls, they are in many respects similar to the gram-positive bacteria with which they share a common ancestor. The molecular biology of mycoplasmas is intriguing because the chromosome is uniquely small (< 600 kb in some species) and extremely A-T rich (as high as 75 mol% in some species). Perhaps to accommodate DNA with a lower G + C content, most mycoplasmas do not have the "universal" genetic code. In these species, TGA is not a stop codon; instead it encodes tryptophan at a frequency 10 times greater than TGG, the usual codon for this amino acid. Because of the presence of TGA codons, the translation of mycoplasmal proteins terminates prematurely when cloned genes are expressed in other eubacteria, such as Escherichia coli. Many mycoplasmas possess strikingly dynamic chromosomes in which high-frequency changes result from errors in DNA repair or replication and from highly active recombination systems. Often, high-frequency changes in the mycoplasmal chromosome are associated with antigenic and phase variation, which regulate the production of factors critical to disease pathogenesis.
虽然支原体没有细胞壁,但在许多方面它们与革兰氏阳性菌相似,有着共同的祖先。支原体的分子生物学很有趣,因为其染色体特别小(某些物种中小于600 kb)且富含A - T(某些物种中高达75摩尔%)。也许是为了容纳低G + C含量的DNA,大多数支原体没有“通用”遗传密码。在这些物种中,TGA不是终止密码子;相反,它编码色氨酸的频率比该氨基酸通常的密码子TGG高10倍。由于存在TGA密码子,当克隆基因在其他真细菌(如大肠杆菌)中表达时,支原体蛋白质的翻译会过早终止。许多支原体拥有显著动态的染色体,其中高频变化源于DNA修复或复制中的错误以及高度活跃的重组系统。通常,支原体染色体的高频变化与抗原性和相变有关,这调节了对疾病发病机制至关重要的因子的产生。
