：一种新兴的安第斯超级谷物的基因组。（原文表述不太完整规范，此译文根据现有内容尽量准确翻译）

The genome of : An emerging Andean super grain.

作者信息

Mangelson Hayley, Jarvis David E, Mollinedo Patricia, Rollano-Penaloza Oscar M, Palma-Encinas Valeria D, Gomez-Pando Luz Rayda, Jellen Eric N, Maughan Peter J

机构信息

Department of Plant and Wildlife Sciences Brigham Young University 5144 LSB Provo Utah 84602 USA.

Institute of Natural Product Research Universidad Mayor de San Andrés La Paz Bolivia.

出版信息

Appl Plant Sci. 2019 Nov 8;7(11):e11300. doi: 10.1002/aps3.11300. eCollection 2019 Nov.

DOI:10.1002/aps3.11300

PMID:31832282

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6858295/

Abstract

PREMISE

Cañahua is a semi-domesticated crop grown in high-altitude regions of the Andes. It is an A-genome diploid (2 = 2 = 18) relative of the allotetraploid (AABB) and shares many of its nutritional benefits. Cañahua seed contains a complete protein, a low glycemic index, and offers a wide variety of nutritionally important vitamins and minerals.

METHODS

The reference assembly was developed using a combination of short- and long-read sequencing techniques, including multiple rounds of Hi-C-based proximity-guided assembly.

RESULTS

The final assembly of the ~363-Mbp genome consists of 4633 scaffolds, with 96.6% of the assembly contained in nine scaffolds representing the nine haploid chromosomes of the species. Repetitive element analysis classified 52.3% of the assembly as repetitive, with the most common repeat identified as long terminal repeat retrotransposons. MAKER annotation of the final assembly yielded 22,832 putative gene models.

DISCUSSION

When compared with quinoa, strong patterns of synteny support the hypothesis that cañahua is a close A-genome diploid relative, and thus potentially a simplified model diploid species for genetic analysis and improvement of quinoa. Resequencing and phylogenetic analysis of a diversity panel of cañahua accessions suggests that coordinated efforts are needed to enhance genetic diversity conservation within ex situ germplasm collections.

摘要

前提

藜麦是一种在安第斯山脉高海拔地区种植的半驯化作物。它是异源四倍体（AABB）的A基因组二倍体（2n = 2x = 18），并具有许多相同的营养益处。藜麦种子含有完整的蛋白质、低血糖指数，还提供多种具有重要营养意义的维生素和矿物质。

方法

参考基因组组装采用了短读长和长读长测序技术相结合的方法，包括多轮基于Hi-C的邻近引导组装。

结果

约363兆碱基对基因组的最终组装由4633个支架组成，其中96.6%的组装序列包含在代表该物种九条单倍体染色体的九个支架中。重复元件分析将52.3%的组装序列归类为重复序列，最常见的重复序列被鉴定为长末端重复逆转座子。最终组装的MAKER注释产生了22,832个推定基因模型。

讨论

与藜麦相比，强烈的共线性模式支持了藜麦是密切相关的A基因组二倍体的假设，因此可能是用于藜麦遗传分析和改良的简化二倍体模型物种。对藜麦种质资源多样性面板的重测序和系统发育分析表明，需要共同努力加强异地种质资源库内的遗传多样性保护。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/422b/6858295/72ca79455a89/APS3-7-e11300-g001.jpg

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：一种新兴的安第斯超级谷物的基因组。 （原文表述不太完整规范，此译文根据现有内容尽量准确翻译）

The genome of : An emerging Andean super grain.

作者信息

机构信息

出版信息

PREMISE

METHODS

RESULTS

DISCUSSION

前提

方法

结果

讨论

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：一种新兴的安第斯超级谷物的基因组。（原文表述不太完整规范，此译文根据现有内容尽量准确翻译）