生物
线粒体DNA
基因
遗传学
核基因
基因组
系统发育树
进化生物学
GC含量
转移RNA
系统发育学
核DNA
分子进化
核糖核酸
作者
Cecilia Saccone,Carla De Giorgi,Carmela Gissi,Graziano Pesole,Aurelio Reyes
出处
期刊:Gene
[Elsevier BV]
日期:1999-09-01
卷期号:238 (1): 195-209
被引量:488
标识
DOI:10.1016/s0378-1119(99)00270-x
摘要
One of the most important aspects of mitochondrial (mt) genome evolution in Metazoa is constancy of size and gene content of mtDNA, whose plasticity is maintained through a great variety of gene rearrangements probably mediated by tRNA genes. The trend of mtDNA to maintain the same genetic structure within a phylum (e.g., Chordata) is generally accepted, although more recent reports show that a considerable number of transpositions are observed also between closely related organisms. Base composition of mtDNA is extremely variable. Genome GC content is often low and, when it increases, the two complementary bases distribute asymmetrically, creating, particularly in vertebrates, a negative GC-skew. In mammals, we have found coding strand base composition and average degree of gene conservation to be related to the asymmetric replication mechanism of mtDNA. A quantitative measurement of mtDNA evolutionary rate has revealed that each of the various components has a different evolutionary rate. Non-synonymous rates are gene specific and fall in a range comparable to that of nuclear genes, whereas synonymous rates are about 22-fold higher in mt than in nuclear genes. tRNA genes are among the most conserved but, when compared to their nuclear counterparts, they evolve 100 times faster. Finally, we describe some molecular phylogenetic reconstructions which have produced unexpected outcomes, and might change our vision of the classification of living organisms.
科研通智能强力驱动
Strongly Powered by AbleSci AI