Sequence of the Sugar Pine Megagenome

Abstract: Until very recently, complete characterization of the megagenomes of conifers has remained elusive. The diploid genome of sugar pine (Pinus lambertiana Dougl.) has a highly repetitive, 31 billion bp genome. It is the largest genome sequenced and assembled to date, and the first from the subgenus Strobus, or white pines, a group that is notable for having the largest genomes among the pines. The genome represents a unique opportunity to investigate genome "obesity" in conifers and white pines. Comparative analy… Show more

“…The genome of this species is considered to have retained many features that were likely to have been present in the ancestral angiosperm genome 22 . It is notable that its repeat content 13 and lower abundance of intact LTR-RTs (solo LTR/intact LTR ratio = 2.43/1.0; Supplementary Table 10) is similar to that observed in G. montanum. These observations suggest that neither A. trichopoda nor G. montanum genomes have experienced recent, extensive (retro) transposon activity, although they continue to eliminate repetitive sequences.…”

“…So far, the availability of whole genome sequences for gymnosperms has been limited to conifers (specifically to Pinaceae) [10][11][12][13] and G. biloba 14 , with no whole genome assemblies available for the two remaining major seed plant lineages-cycads and gnetophytes. This deficiency, together with the conflicting phylogenetic evidence for relationships among these groups, is impeding our understanding of genome evolution across all seed plants.…”

“…A BUSCO (Benchmarking Universal Single-Copy Orthologs) analysis to assess the quality of the genome and annotation completeness suggested that 81% of the genes have been recovered (Supplementary Table 6). Unlike conifer genomes, which contain numerous pseudogenes 15 (for example,8,328 in Picea abies,13,550 in Pinus taeda), many fewer were found in the G. montanum genome (3,122, Supplementary Information). The read depth distribution across genic regions ( Supplementary Fig.…”

“…Repetitive sequences have been shown to account for the major component of all gymnosperm genomes that have been sequenced to date [11][12][13][14] , with diverse and ancient transposable elements (TEs), especially LTR retrotransposons (LTR-RTs), being particularly prevalent. Overall, the repetitive element content of G. montanum was also high (85.9%) and dominated by LTR-RTs (especially gypsy-like Table 8 and Supplementary Information).…”

“…Consequently, several possible hypotheses have been put forward that place gnetophytes as sister to (1) Pinaceae ('Gnepine' hypothesis); (2) cupressophytes ('Gnecup' hypothesis); (3) all conifers ('Gnetifer' hypothesis); (4) all other gymnosperms; or (5) all seed plants 9 . Currently, the emerging consensus, based on both older and more recent studies, and recently released data from the 1KP initiative (see https://sites.google.com/a/ualberta.ca/onekp/, and Wickett et al 8 ), indicates that gnetophytes are sister to, or within, the conifers.So far, the availability of whole genome sequences for gymnosperms has been limited to conifers (specifically to Pinaceae) [10][11][12][13] and G. biloba 14 , with no whole genome assemblies available for the two remaining major seed plant lineages-cycads and gnetophytes. This deficiency, together with the conflicting phylogenetic evidence for relationships among these groups, is impeding our understanding of genome evolution across all seed plants.…”

A genome for gnetophytes and early evolution of seed plants

“…The genome of this species is considered to have retained many features that were likely to have been present in the ancestral angiosperm genome 22 . It is notable that its repeat content 13 and lower abundance of intact LTR-RTs (solo LTR/intact LTR ratio = 2.43/1.0; Supplementary Table 10) is similar to that observed in G. montanum. These observations suggest that neither A. trichopoda nor G. montanum genomes have experienced recent, extensive (retro) transposon activity, although they continue to eliminate repetitive sequences.…”

“…So far, the availability of whole genome sequences for gymnosperms has been limited to conifers (specifically to Pinaceae) [10][11][12][13] and G. biloba 14 , with no whole genome assemblies available for the two remaining major seed plant lineages-cycads and gnetophytes. This deficiency, together with the conflicting phylogenetic evidence for relationships among these groups, is impeding our understanding of genome evolution across all seed plants.…”

“…A BUSCO (Benchmarking Universal Single-Copy Orthologs) analysis to assess the quality of the genome and annotation completeness suggested that 81% of the genes have been recovered (Supplementary Table 6). Unlike conifer genomes, which contain numerous pseudogenes 15 (for example,8,328 in Picea abies,13,550 in Pinus taeda), many fewer were found in the G. montanum genome (3,122, Supplementary Information). The read depth distribution across genic regions ( Supplementary Fig.…”

“…Repetitive sequences have been shown to account for the major component of all gymnosperm genomes that have been sequenced to date [11][12][13][14] , with diverse and ancient transposable elements (TEs), especially LTR retrotransposons (LTR-RTs), being particularly prevalent. Overall, the repetitive element content of G. montanum was also high (85.9%) and dominated by LTR-RTs (especially gypsy-like Table 8 and Supplementary Information).…”

“…Consequently, several possible hypotheses have been put forward that place gnetophytes as sister to (1) Pinaceae ('Gnepine' hypothesis); (2) cupressophytes ('Gnecup' hypothesis); (3) all conifers ('Gnetifer' hypothesis); (4) all other gymnosperms; or (5) all seed plants 9 . Currently, the emerging consensus, based on both older and more recent studies, and recently released data from the 1KP initiative (see https://sites.google.com/a/ualberta.ca/onekp/, and Wickett et al 8 ), indicates that gnetophytes are sister to, or within, the conifers.So far, the availability of whole genome sequences for gymnosperms has been limited to conifers (specifically to Pinaceae) [10][11][12][13] and G. biloba 14 , with no whole genome assemblies available for the two remaining major seed plant lineages-cycads and gnetophytes. This deficiency, together with the conflicting phylogenetic evidence for relationships among these groups, is impeding our understanding of genome evolution across all seed plants.…”

A genome for gnetophytes and early evolution of seed plants

Tree of Life: Genomes ( II )

References