BGI Sequences Gingko Tree, Revealing Large, Highly Repetitive Genome
News Dec 03, 2016
A BGI led team of researchers has sequenced the Ginkgo biloba genome and found it to be full of repeats, as well as gene clusters that may explain the tree’s remarkable resilience. The gingko tree has changed little in the past 270 million years — and is the sole living representative of one lineage of gymnosperms. Researchers led by BGI’s Wenbin Chen, Song Ge from the Chinese Academy of Sciences, and Chengxin Fu from Zhejiang University, reported in GigaScience that they’ve sequenced the more than 10-gigabase ginkgo genome to find a high number of repetitive sequences as well as a number of gene clusters that appear to be involved in defense mechanisms.
“Ginkgo represents one of the five living groups of seed plants, and has no living relatives,” Zhejiang University’s Yunpeng Zhao, a study co-author, said in a statement. “Such a genome fills a major phylogenetic gap of land plants, and provides key genetic resources to address evolutionary questions like [the] phylogenetic relationships of gymnosperm lineages.” For their study, the researchers extracted genomic DNA from the endosperm tissue of a ginkgo seed for sequencing.
They generated paired-end and mate-pair libraries, all using DNA from the same seed. After sequencing on the Illumina HiSeq 2000 and HiSeq 4000 platforms, the researchers generated 189.84X coverage with raw sequencing reads. Using some of the mate-pair library reads as scaffolding, they assembled a draft ginkgo genome of some 10.6 gigabases in length. This, the researchers noted, is 80 times larger than the Arabidopsis thaliana genome as well as larger than the maize, orchid, and sorghum genomes.
“The large genome of ginkgo may have resulted from whole genome duplication and insertion of a remarkably high proportion of repetitive sequences,” BGI’s Chen said. More than three quarters of the G. biloba genome consists of repeats. This is a higher portion than what is found in other plant genomes, including the Norway spruce, orchid, and sorghum genomes. Long terminal repeat retrotransposons were also particularly common amongst the repeat sequences of ginkgo.
By analyzing the reverse transcriptase genes tacked on to those long terminal repeats and comparing them to those in other land plants, the researchers found evidence that some of these repeats were conserved. Though the repeats largely accumulated slowly in the ginkgo genome, there was a period of repeat expansion that the researchers traced to between 16 million and 24 million years ago. At the same time, the team reported that two whole-genome duplication events took place in ginkgo: one was an ancient duplication 515 million years to 735 million years ago that is common to seed plants, while the other was a more recent duplication specific to ginkgo.
Using protein sequence, transcriptome, and expressed sequence tag data from five other land plants — Selaginella moellendorffii, Picea abies, Pinus taeda, A. thaliana, and Oryza sativa — the researchers predicted gene models for ginkgo. Through this, they identified 41,840 ginkgo genes, of which 30,209 genes were assigned high confidence. Some 2,100 gene families were unique to ginkgo, and many of those that harbored expansions were enriched for stimuli response functions, including defense. The researchers noted that ginkgo’s defense mechanisms have been of interest to scientists as it employs multiple mechanisms to fend off insects and pathogens.
In particular, they uncovered a high level of gene duplications within the ginkgolide/bilobalide biosynthesis and flavonoid biosynthesis pathways, both of which produce defense metabolites — terpenic trilactones like ginkgolides and bilobalides, along with flavonoids, fend off herbivore attacks, they noted. These duplications, the researchers said, could have a dose effect that enhances resistance and adaptability.
Source: Story from BGI. Please note: The content above may have been edited to ensure it is in keeping with Technology Networks' style and length guidelines.
Reference: Guan, R., Zhao, Y., Zhang, H., Fan, G., Liu, X., Zhou, W., … Chen, W. (2016). Draft genome of the living fossil ginkgo biloba. GigaScience, 5(1), . doi:10.1186/s13742-016-0154-1
Previous work by the International Multiple Sclerosis Genetics Consortium (IMSGC) has identified 233 genetic risk variants. However, these only account for about 20% of overall disease risk, with the remaining genetic culprits proving elusive. A new study has tracked down four of these hard-to-find genes.READ MORE
Scientists at McGill have found the answer to a question that perplexed Charles Darwin; if natural selection works at the level of the individual, fighting for survival and reproduction, how can a single colony produce worker ants that are so dramatically different in size – from “minor” workers to large-headed soldiers with huge mandibles – especially if they are sterile?