Assembled and annotated 26.5 Gbp coast redwood genome: a resource for estimating evolutionary adaptive potential and investigating hexaploid origin

Neale, David B.; Zimin, Aleksey V.; Zaman, Sumaira; Scott, Alison Dawn; Shrestha, Bikash; Workman, Rachael E.; Puiu, Daniela; Allen, Brian; Moore, Zane J; Sekhwal, Manoj Kumar; Torre, Amanda R. De La; McGuire, Patrick E.; Burns, Emily E.; Timp, Winston; Wegrzyn, Jill; Salzberg, Steven L.

doi:10.1093/g3journal/jkab380

Cited by 35 publications

(40 citation statements)

References 94 publications

(105 reference statements)

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“…Our results suggest a polygenic basis of drought tolerance, consistent with previous GWAS in other complex traits in conifer species, with candidate genes distributed in different chromosomes or scaffolds, and small to moderate effect sizes (Baison et al, 2020;De La Torre et al, 2021a;Weiss et al, 2020). The exact location of candidate genes in the SESE genome could only be determined at the scaffold level, as the current assembly of the reference genome is not chromosome-scale (Neale et al, 2021). Univariate methods identified 78 new significant associations for SESE, 27 of them were consistently found by all three univariate and multivariate GWAS methods in this study.…”

Section: Polygenic Basis Of Drought Tolerancesupporting

confidence: 88%

“…Here, we report notable phenotypic variation for several drought-related traits among natural populations (or groves) of both SEGI and SESE grown in a common garden. The development of genome-wide methods, gene identification, functional annotation, and location in the species genomes has only been possible due to the recent sequencing of reference genomes for both species (Neale et al, 2021;Scott et al, 2020).…”

Section: Discussionmentioning

confidence: 99%

“…For that purpose, SESE seedlings measured in this study have been planted in long-term common gardens in California, where different phenotypes can be evaluated as trees mature. This new resource, together with our newly sequenced reference genomes of SEGI and SESE (Neale et al, 2021;Scott et al, 2020) will help to develop future genomic studies in the species. A thorough knowledge of the interconnection among plasticity, genomics, and physiological processes is needed to predict species responses to future warmer conditions and to design conservation and management strategies.…”

Section: Functional Annotation Of Candidate Genesmentioning

confidence: 99%

“…Coast redwood (Sequoia sempervirens [D. Don] Endl.) (SESE) is also slow-growing and long-lived but differs from SEGI in that it is hexaploid (genome size is 26.5 Gbp; Neale et al, 2021) and often reproduces asexually. The species once had a nearly continuous distribution along the Pacific Coast in Oregon and California, but natural populations were severely reduced by intensive logging beginning in the nineteenth and twentieth centuries (Breidenbach et al, 2020;Burns et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

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Genome‐wide association identifies candidate genes for drought tolerance in coast redwood and giant sequoia

Torre

Sekhwal

Puiu³

et al. 2021

The Plant Journal

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Drought is a major limitation for survival and growth in plants. With more frequent and severe drought episodes occurring due to climate change, it is imperative to understand the genomic and physiological basis of drought tolerance to be able to predict how species will respond in the future. In this study, univariate and multitrait multivariate genome-wide association study methods were used to identify candidate genes in two iconic and ecosystem-dominating species of the western USA, coast redwood and giant sequoia, using 10 drought-related physiological and anatomical traits and genome-wide sequence-capture single nucleotide polymorphisms. Population-level phenotypic variation was found in carbon isotope discrimination, osmotic pressure at full turgor, xylem hydraulic diameter, and total area of transporting fibers in both species. Our study identified new 78 new marker 3 trait associations in coast redwood and six in giant sequoia, with genes involved in a range of metabolic, stress, and signaling pathways, among other functions. This study contributes to a better understanding of the genomic basis of drought tolerance in longgeneration conifers and helps guide current and future conservation efforts in the species.

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Section: Polygenic Basis Of Drought Tolerancesupporting

confidence: 88%

Section: Discussionmentioning

confidence: 99%

Section: Functional Annotation Of Candidate Genesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Genome‐wide association identifies candidate genes for drought tolerance in coast redwood and giant sequoia

Torre

Sekhwal

Puiu³

et al. 2021

The Plant Journal

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“…Assembled plant genome sizes range from 61 Mbp ( Genlisea tuberosa , bladderwort [63]) to 26,454 Gbp ( Sequoia sempervirens , coast redwood [64]). The ALO assembly falls into this range, and a combination of ONT, Illumina and Hi-C sequence approaches was essential for the high continuity chromosome level assemblies with high presence of core genes, as is for many important crop genomes, particularly cereals, with genomes larger than 2 Gbp (barley [65]; wheat [66, 67]).…”

Section: Discussionmentioning

confidence: 99%

Chromosome-scale genome assembly of the diploid oat Avena longiglumis reveals the landscape of repetitive sequences, genes and chromosome evolution in grasses

Liu

Yuan

Li³

et al. 2022

Preprint

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Background: Oat (Avena sativa, 2n=6x=42) is an important crop, and with its wild relatives including A. longiglumis (ALO, 2n=6x=14), has advantageous agronomic and nutritional traits. A de-novo chromosome-level ALO genome assembly was made to investigate diversity and structural genome variation between Avena species and other Poaceae in an evolutionary context, and develop genomic resources to identify the pangenome and economic traits within Pooideae. Results: The 3.85 gigabase ALO genome (seven pseudo-chromosomes), contained 40,845 protein-coding genes and 87% repetitive sequences (84.21% transposable elements). An LTR retrotransposon family was abundant at all chromosome centromeres, and genes were distributed without major terminal clusters. Comparisons of synteny with A. eriantha and A. strigosa showed evolutionary translocations of terminal segments including many genes. Comparison with rice (x=12) and the ancestral grass karyotype showed synteny and features of chromosome evolution including fusions, translocations and insertions of syntenic blocks across Pooideae species. With a genome size 10 times larger than rice, ALO showed relatively uniform expansion along the chromosome arms, with few gene-poor regions along arms, and no major duplications nor deletions. Linked gene networks were identified (mixed-linkage glucans and cellulose synthase genes), and CYP450 genes may be related to salt-tolerance. Conclusions: The high-continuity genome assembly shows gene, chromosomal structural and copy number variation, providing a reference for the Avena pangenome, defining the full spectrum of diversity. Chromosomal rearrangements and genome expansion demonstrate features of evolution across the genus and grass BOP-clade, contributing to exploitation of gene and genome diversity through precision breeding.

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Integrating genomics and conservation to safeguard plant diversity

Schneider

2023

Integrative Conservation

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Conserving genetic diversity has been increasingly recognized as a keystone towards the protection of biodiversity and natural resources for future generations of humankind. In turn, the ongoing genomic revolution provides us with the technical innovations and expanded knowledge required to establish programs to integrate genomic approaches into programs to protect plant diversity and its genetic diversity. Although obtaining whole genomes of all organisms is still a far‐fetched dream, rapid progress in assembling whole genomes across the plant tree‐of‐life has provided access to reference genomes for many plants but, unfortunately, not all lineages of the plant tree‐of‐life. Addressing the existing taxon gaps is arguably best achieved by focusing on the genomes of plant species that experience high extinction threats or play a crucial role in ecosystem restoration. This review summarizes not only the recent progress in plant genomics with an emphasis on their importance to the conservation of plant diversity but also outlines steps to integrate genomics into plant conservation. Given the complexity of threats driving plant extinction, such as reduced genetic diversity, enhanced genome erosion, and loss of species integrity by hybridization, the integration of genomic research into our conservation efforts is crucial to understand extinction processes and, most importantly, to support the targets set to achieve “Harmony with Nature.”

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Assembled and annotated 26.5 Gbp coast redwood genome: a resource for estimating evolutionary adaptive potential and investigating hexaploid origin

Cited by 35 publications

References 94 publications

Genome‐wide association identifies candidate genes for drought tolerance in coast redwood and giant sequoia

Genome‐wide association identifies candidate genes for drought tolerance in coast redwood and giant sequoia

Chromosome-scale genome assembly of the diploid oat Avena longiglumis reveals the landscape of repetitive sequences, genes and chromosome evolution in grasses

Integrating genomics and conservation to safeguard plant diversity

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