Khushwant Singh, M. Huff, Jianyang Liu, Jong-Won Park, Tara Rickman, Manjunath Keremane, Robert R. Krueger, Madhurababu Kunta, Mikeal L. Roose, Chris Dardick, Margaret Staton, Chandrika Ramadugu
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引用次数: 0
摘要
黄龙病(HLB)是世界上一种严重的柑橘病害。澳大利亚野生酸橙,如 Citrus australasica、C. inodora 和 C. glauca,具有有益的抗 HLB 性状。十多年来,这三个类群的单株树被广泛用于育种计划,将抗性性状导入商业品质的柑橘种质中。我们利用 PacBio 长线程测序技术生成了这三种澳大利亚酸橙的高质量、分阶段、从头开始的基因组组装。确定了 C. australasica(337 Mb/335 Mb)、C. inodora(304 Mb/299 Mb)和 C. glauca(376 Mb/379 Mb)的主要单倍型和候补单倍型的基因组组装大小。九个染色体尺度的支架包括了所生成基因组序列的 86-91%。据估计,组装基因组的完整性和完备性为 97.2%-98.8%。基因注释研究在 C. australasica 中发现了 25,461 个基因,在 C. inodora 中发现了 27,665 个基因,在 C. glauca 中发现了 30,067 个基因。与所分析的其他柑橘基因组相比,澳大利亚酸橙基因组中属于 118 个正交组的基因具有特异性。与 C. australasica(576 个)、C. clementina(579 个)和 C. sinensis(651 个)相比,在 C. inodora 和 C. glauca 中发现的典型抗性(R)基因明显较少(分别为 319 个和 449 个)。与潜在 HLB 抗性相关的其他基因家族也观察到类似的模式,包括澳大利亚酸橙基因组中预测的叶绿体蛋白 2(PP2)和 Callose 合酶(CalS)基因。本研究开发的澳大利亚酸橙基因组信息将有助于了解 HLB 抗性的遗传基础。
Chromosome-Scale, De Novo, Phased Genome Assemblies of Three Australian Limes: Citrus australasica, C. inodora, and C. glauca
Huanglongbing (HLB) is a severe citrus disease worldwide. Wild Australian limes like Citrus australasica, C. inodora, and C. glauca possess beneficial HLB resistance traits. Individual trees of the three taxa were extensively used in a breeding program for over a decade to introgress resistance traits into commercial-quality citrus germplasm. We generated high-quality, phased, de novo genome assemblies of the three Australian limes using PacBio long-read sequencing. The genome assembly sizes of the primary and alternate haplotypes were determined for C. australasica (337 Mb/335 Mb), C. inodora (304 Mb/299 Mb), and C. glauca (376 Mb/379 Mb). The nine chromosome-scale scaffolds included 86–91% of the genome sequences generated. The integrity and completeness of the assembled genomes were estimated to be at 97.2–98.8%. Gene annotation studies identified 25,461 genes in C. australasica, 27,665 in C. inodora, and 30,067 in C. glauca. Genes belonging to 118 orthogroups were specific to Australian lime genomes compared to other citrus genomes analyzed. Significantly fewer canonical resistance (R) genes were found in C. inodora and C. glauca (319 and 449, respectively) compared to C. australasica (576), C. clementina (579), and C. sinensis (651). Similar patterns were observed for other gene families associated with potential HLB resistance, including Phloem protein 2 (PP2) and Callose synthase (CalS) genes predicted in the Australian lime genomes. The genomic information on Australian limes developed in the present study will help understand the genetic basis of HLB resistance.
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