Genome assembly, from practice to theory: safe, complete and linear-time

IF 0.9 3区 计算机科学 Q3 COMPUTER SCIENCE, THEORY & METHODS ACM Transactions on Algorithms Pub Date : 2023-11-08 DOI:10.1145/3632176
Massimo Cairo, Romeo Rizzi, Alexandru I. Tomescu, Elia C. Zirondelli
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引用次数: 11

Abstract

Genome assembly asks to reconstruct an unknown string from many shorter substrings of it. Even though it is one of the key problems in Bioinformatics, it is generally lacking major theoretical advances. Its hardness stems both from practical issues (size and errors of real data), and from the fact that problem formulations inherently admit multiple solutions. Given these, at their core, most state-of-the-art assemblers are based on finding non-branching paths (unitigs) in an assembly graph. While such paths constitute only partial assemblies, they are likely to be correct. More precisely, if one defines a genome assembly solution as a closed arc-covering walk of the graph, then unitigs appear in all solutions, being thus safe partial solutions. Until recently, it was open what are all the safe walks of an assembly graph. Tomescu and Medvedev (RECOMB 2016) characterized all such safe walks (omnitigs), thus giving the first safe and complete genome assembly algorithm. Even though maximal omnitig finding was later improved to quadratic time by Cairo et al. (ACM Trans. Algorithms 2019), it remained open whether the crucial linear-time feature of finding unitigs can be attained with omnitigs. We answer this question affirmatively, by describing a surprising O(m)-time algorithm to identify all maximal omnitigs of a graph with n nodes and m arcs, notwithstanding the existence of families of graphs with Θ(mn) total maximal omnitig size. This is based on the discovery of a family of walks (macrotigs) with the property that all the non-trivial omnitigs are univocal extensions of subwalks of a macrotig. This has two consequences: (1) A linear-time output-sensitive algorithm enumerating all maximal omnitigs. (2) A compact O(m) representation of all maximal omnitigs, which allows, e.g., for O(m)-time computation of various statistics on them. Our results close a long-standing theoretical question inspired by practical genome assemblers, originating with the use of unitigs in 1995. We envision our results to be at the core of a reverse transfer from theory to practical and complete genome assembly programs, as has been the case for other key Bioinformatics problems.
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基因组组装,从实践到理论:安全,完整和线性时间
基因组组装要求从许多较短的子串中重建一个未知的字符串。尽管它是生物信息学中的关键问题之一,但通常缺乏重大的理论进展。它的困难来自于实际问题(真实数据的大小和误差),也来自于问题表述本质上承认多种解决方案的事实。考虑到这些,在其核心,大多数最先进的汇编程序都是基于在汇编图中找到非分支路径(单元)。虽然这样的路径只构成部分程序集,但它们可能是正确的。更准确地说,如果将基因组组装解定义为图的闭合弧覆盖行走,则单位出现在所有解中,因此是安全的部分解。直到最近,它都是开放的,什么是一个组装图的所有安全行走。Tomescu和Medvedev (RECOMB 2016)描述了所有这些安全行走(omnitigs),从而给出了第一个安全完整的基因组组装算法。尽管后来Cairo等人将最大全向发现改进为二次时间。算法(2019),寻找单位的关键线性时间特征是否可以通过全集获得仍然是开放的。我们肯定地回答了这个问题,通过描述一个惊人的O (m)时间算法来识别具有n个节点和m条弧的图的所有最大全图,尽管存在具有Θ (mn)总最大全图大小的图族。这是基于一个行走族(macrotigs)的发现,其性质是所有非平凡的全行走都是一个宏行走的子行走的唯一扩展。这有两个结果:(1)一个线性时间输出敏感的算法枚举所有最大的全集。(2)所有极大全群的紧凑的O (m)表示,它允许,例如,在O (m)时间内计算各种统计量。我们的研究结果解决了一个长期存在的理论问题,这个问题是由1995年开始使用单位的实际基因组组装者启发的。我们设想我们的结果是从理论到实际和完整基因组组装程序的反向转移的核心,就像其他关键生物信息学问题一样。
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来源期刊
ACM Transactions on Algorithms
ACM Transactions on Algorithms COMPUTER SCIENCE, THEORY & METHODS-MATHEMATICS, APPLIED
CiteScore
3.30
自引率
0.00%
发文量
50
审稿时长
6-12 weeks
期刊介绍: ACM Transactions on Algorithms welcomes submissions of original research of the highest quality dealing with algorithms that are inherently discrete and finite, and having mathematical content in a natural way, either in the objective or in the analysis. Most welcome are new algorithms and data structures, new and improved analyses, and complexity results. Specific areas of computation covered by the journal include combinatorial searches and objects; counting; discrete optimization and approximation; randomization and quantum computation; parallel and distributed computation; algorithms for graphs, geometry, arithmetic, number theory, strings; on-line analysis; cryptography; coding; data compression; learning algorithms; methods of algorithmic analysis; discrete algorithms for application areas such as biology, economics, game theory, communication, computer systems and architecture, hardware design, scientific computing
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