Chan Cheong Xin, Bhattacharya Debashish
Department of Ecology, Evolution and Natural Resources; and Institute of Marine and Coastal Sciences; Rutgers University; New Brunswick, NJ USA.
Commun Integr Biol. 2011 May;4(3):361-3. doi: 10.4161/cib.4.3.15700. Epub 2011 May 1.
The power of eukaryote genomics relies strongly on taxon sampling. This point was underlined in a recent analysis of red algal genome evolution in which we tested the Plantae hypothesis that posits the monophyly of red, green (including plants) and glaucophyte algae. The inclusion of novel genome data from two mesophilic red algae enabled us to robustly demonstrate the sisterhood of red and green algae in the tree of life. Perhaps more exciting was the finding that >1,800 putative genes in the unicellular red alga Porphyridium cruentum showed evidence of gene-sharing with diverse lineages of eukaryotes and prokaryotes. Here we assessed the correlation between the putative functions of these shared genes and their susceptibility to transfer. It turns out that genes involved in complex interactive networks such as biological regulation and transcription/translation are less susceptible to endosymbiotic or horizontal gene transfer, when compared to genes with metabolic and transporter functions.
真核生物基因组学的力量在很大程度上依赖于分类群抽样。这一点在最近一项关于红藻基因组进化的分析中得到了强调,在该分析中我们检验了植物界假说,该假说假定红藻、绿藻(包括植物)和灰胞藻为单系类群。纳入来自两种嗜温红藻的新基因组数据使我们能够有力地证明红藻和绿藻在生命之树中的姐妹关系。也许更令人兴奋的是,单细胞红藻紫球藻中超过1800个推定基因显示出与真核生物和原核生物不同谱系存在基因共享的证据。在这里,我们评估了这些共享基因的推定功能与其转移易感性之间的相关性。结果发现,与具有代谢和转运功能的基因相比,参与复杂交互网络(如生物调控和转录/翻译)的基因更不易受到内共生或水平基因转移的影响。
