Sequence Alignment Algorithm Based on Combined minimizer Seeds on Pan-Genome Graph

doi:10.19678/j.issn.1000-3428.0069237

Abstract

Abstract:

With advancements in sequencing technology, human genome analysis has shifted from individual analysis to population analysis. To better demonstrate the genetic variation information between different samples within a population, the pan-genome graph model has replaced the traditional linear multi-sequence reference genome model, and sequence-to-graph alignment has become a key issue in biological sequence analyses. Existing alignment algorithms employ seed-and-extend strategies. However, owing to the numerous paths formed by graph combinations, localization and verification phases become time-consuming, necessitating further optimization and improvement of single-seed selection methods. To address this issue, this paper proposes a sequence alignment algorithm based on a combined minimizer seed. In the localization phase, the algorithm enhances the coverage range of a single seed through the combined hashing of minimizer seeds. Simultaneously, seeds are located through both sequence and relative position information, which significantly reducing the number of false-positive matching positions, thus lowering the workload of the subsequent filtering and verification processes. Experimental results demonstrate that the proposed algorithm can reduce candidate positions by approximately 80%, optimize time performance by one to three times, and have index memory and precise comparison capabilities comparable to mainstream alignment algorithms.

Key words: pan-genome graph, sequence alignment, seed-and-extend strategy, minimizer seed

摘要：

随着测序技术的发展和应用，人类基因组序列的研究已从个体分析逐步扩展到群体分析。为更好地展示种群不同样本之间的遗传变异信息，泛基因组图模型开始取代传统的线性多序列参考基因组模型，序列到图的比对成为生物序列分析的关键问题之一。现有比对算法通常采用种子与扩展策略，但由于图中组合的路径较多，定位和验证阶段的时间成本高，需要进一步优化单种子选取方法，减少候选位置的数量。为此，提出一种基于组合minimizer种子的序列比对算法，在定位阶段通过对minimizer种子的组合hash，扩展单个种子的覆盖范围。同时，通过序列和相对位置两方面信息查找种子，减少假阳性匹配位置的数量，从而降低后续筛选和验证的工作量。实验结果表明，与主流算法相比，该算法能够减少约80%的候选位置，时间性能提升1~3倍，同时保持相当的索引内存占用和精确比对能力。

关键词: 泛基因组图, 序列比对, 种子与扩展策略, minimizer种子

GAO Jia, XU Yun. Sequence Alignment Algorithm Based on Combined minimizer Seeds on Pan-Genome Graph[J]. Computer Engineering, 2025, 51(8): 53-61.

高佳, 徐云. 基于组合minimizer种子的泛基因组图序列比对算法[J]. 计算机工程, 2025, 51(8): 53-61.

/ Recommend / Download Citations

URL: https://www.ecice06.com/EN/10.19678/j.issn.1000-3428.0069237

https://www.ecice06.com/EN/Y2025/V51/I8/53

Figures/Tables 10

Fig.1 Pan-genome graph model example

Fig.2 Example of (3, 4)-minimizer seed selection method

Fig.3 Procedure of sequencing sequence alignment algorithm

Fig.4 Schematic diagram of combined minimizer seed index

Fig.5 Average number of seeds for read

Fig.6 Average number of clusters for read

Fig.7 Index memory result under each dataset

Fig.8 Alignment time for graphs of different complexity

References 27

1	QUAN W , GUAN D F , QUAN G R , et al. Short read alignment based on maximal approximate match seeds. Frontiers in Molecular Biosciences, 2020, 7, 572934. doi: 10.3389/fmolb.2020.572934
2	罗静初. 双序列比对基础和应用实例. 生物信息学, 2023, 21 (1): 1- 19.
	LUO J C . Basics of pairwise sequence alignment and some application examples. Chinese Journal of Bioinformatics, 2023, 21 (1): 1- 19.
3	TETTELIN H , MASIGNANI V , CIESLEWICZ M J , et al. Genome analysis of multiple pathogenic isolates of Streptococcus agalactiae: implications for the microbial "pan-genome". Proceedings of the National Academy of Sciences of the United States of America, 2005, 102 (39): 13950- 13955.
4	BRANDT D Y C , AGUIAR V R C , BITARELLO B D , et al. Mapping bias overestimates reference allele frequencies at the HLA genes in the 1000 genomes project phase Ⅰ data. G3: Genes, Genomes, Genetics, 2015, 5 (5): 931- 941. doi: 10.1534/g3.114.015784
5	OUTTEN J , WARREN A . Methods and developments in graphical pangenomics. Journal of the Indian Institute of Science, 2021, 101 (3): 485- 498. doi: 10.1007/s41745-021-00255-z
6	吴家睿. 泛基因组: 观察生物多样性和统一性的新视窗. 生命科学, 2023, 35 (9): 1115- 1119.
	WU J R . Pan-genome: a new window to observe biodiversity and unity. Chinese Bulletin of Life Sciences, 2023, 35 (9): 1115- 1119.
7	WILBUR W J , LIPMAN D J . Rapid similarity searches of nucleic acid and protein data banks. Proceedings of the National Academy of Sciences of the United States of America, 1983, 80 (3): 726- 730.
8	SMITH T F , WATERMAN M S . Identification of common molecular subsequences. Journal of Molecular Biology, 1981, 147 (1): 195- 197. doi: 10.1016/0022-2836(81)90087-5
9	NEEDLEMAN S B , WUNSCH C D . A general method applicable to the search for similarities in the amino acid sequence of two proteins. Journal of Molecular Biology, 1970, 48 (3): 443- 453. doi: 10.1016/0022-2836(70)90057-4
10	DELCHER A L , KASIF S , FLEISCHMANN R D , et al. Alignment of whole genomes. Nucleic Acids Research, 1999, 27 (11): 2369- 2376. doi: 10.1093/nar/27.11.2369
11	DELCHER A L , PHILLIPPY A , CARLTON J , et al. Fast algorithms for large-scale genome alignment and comparison. Nucleic Acids Research, 2002, 30 (11): 2478- 2483. doi: 10.1093/nar/30.11.2478
12	SIRÉN J , MONLONG J , CHANG X , et al. Pangenomics enables genotyping of known structural variants in 5202 diverse genomes. Science, 2021, 374 (6574): 8871. doi: 10.1126/science.abg8871
13	RAUTIAINEN M , MARSCHALL T . GraphAligner: rapid and versatile sequence-to-graph alignment. Genome Biology, 2020, 21 (1): 253. doi: 10.1186/s13059-020-02157-2
14	ROBERTS M , HAYES W , HUNT B R , et al. Reducing storage requirements for biological sequence comparison. Bioinformatics, 2004, 20 (18): 3363- 3369. doi: 10.1093/bioinformatics/bth408
15	JAIN C , RHIE A , ZHANG H W , et al. Weighted minimizer sampling improves long read mapping. Bioinformatics, 2020, 36, 111- 118. doi: 10.1093/bioinformatics/btaa435
16	LI H . Minimap2: pairwise alignment for nucleotide sequences. Bioinformatics, 2018, 34 (18): 3094- 3100. doi: 10.1093/bioinformatics/bty191
17	LI H , FENG X W , CHU C . The design and construction of reference pangenome graphs with minigraph. Genome Biology, 2020, 21 (1): 265. doi: 10.1186/s13059-020-02168-z
18	MA J , CÁCERES M , SALMELA L , et al. GraphChainer: co-linear chaining for accurate alignment of long reads to variation graphs. Bioinformatics, 2023, 39 (8): 475. doi: 10.1093/bioinformatics/btad475
19	CHANDRA G, JAIN C. Sequence to graph alignment using gap-sensitive co-linear chaining[C]//Proceedings of the 27th Annual International Conference on Research in Computational Molecular Biology. Berlin, Germany: Springer, 2023: 58-73.
20	JOUDAKI A , METEREZ A , MUSTAFA H , et al. Aligning distant sequences to graphs using long seed sketches. Genome Research, 2023, 33 (7): 1208- 1217.
21	HOANG M , ZHENG H Y , KINGSFORD C . Differentiable learning of sequence-specific minimizer schemes with DeepMinimizer. Journal of Computational Biology, 2022, 29 (12): 1288- 1304. doi: 10.1089/cmb.2022.0275
22	蒋宏博. 面向泛基因组的压缩图索引方法研究[D]. 西安: 西安电子科技大学, 2022.
	JIANG H B. Research on index method of compressed graph for pan-genome[D]. Xi'an: Xidian University, 2022. (in Chinese)
23	ALTSCHUL S F , GISH W , MILLER W , et al. Basic local alignment search tool. Journal of Molecular Biology, 1990, 215 (3): 403- 410. doi: 10.1016/S0022-2836(05)80360-2
24	ŠOŠIĆM, ŠIKIĆM. Edlib: a C/C++ library for fast, exact sequence alignment using edit distance. Bioinformatics, 2017, 33 (9): 1394- 1395.
25	ONO Y , ASAI K , HAMADA M . PBSIM: PacBio reads simulator—toward accurate genome assembly. Bioinformatics, 2013, 29 (1): 119- 121. doi: 10.1093/bioinformatics/bts649
26	GARRISON E , SIRÉN J , NOVAK A M , et al. Variation graph toolkit improves read mapping by representing genetic variation in the reference. Nature Biotechnology, 2018, 36 (9): 875- 879. doi: 10.1038/nbt.4227
27	MOKVELD T , LINTHORST J , AL-ARS Z , et al. CHOP: haplotype-aware path indexing in population graphs. Genome Biology, 2020, 21 (1): 65. doi: 10.1186/s13059-020-01963-y

[1]	MA Manfu, ZHANG Kaixuan, LI Yong, WANG Changqing, ZHANG Qiang. Research on Behavioral Similarity among Online Homologous Users in Virtual Space [J]. Computer Engineering, 2021, 47(5): 65-72.
[2]	HE Zhongqiao,XU Yun. Research on Multi-genome Index and Its Improved Sequence Alignment Algorithm [J]. Computer Engineering, 2018, 44(3): 42-46.
[3]	ZHAO Yanan,XU Yun,CHENG Haoyu. Research on BW Transform Index Technology in Sequence Alignment Algorithm and Its Improvement [J]. Computer Engineering, 2016, 42(1): 282-286.
[4]	MA Hai-Chen, HUI Gang, TUN Bai-Feng. Fast Alignment of Biological Sequences Based on General Purpose Graphic Processor Unit [J]. Computer Engineering, 2012, 38(04): 241-244.
[5]	LIU Ai, MENG Zhen, LIU Yong, DONG Hui, LIN Xiao-Guang, GAO Yan-Beng, ZHOU Wan-Chun, LI Jian-Hui. Data Cleaning and Quality Control Scheme Based on BLAST [J]. Computer Engineering, 2011, 37(4): 73-75.
[6]	NIU Bei-fang; ZHANG Xi-guang; LIU Tao; LANG Xian-yu; LU Zhong-hua; CHI Xue-bin. Alignment and Assembly Algorithm Based on New Sequencing Technique [J]. Computer Engineering, 2009, 35(20): 4-6.
[7]	YIN Shu-ming; YAN Qu; NIE Kun-kun; GAO Jian. Masquerading Intrusion Detection Technique Based on Sequence Alignment Algorithm [J]. Computer Engineering, 2007, 33(24): 177-180.
[8]	LI Yugang; LIU Zhiyong. Parallel Optimization of the Smith-Waterman Algorithm Based on HPM Model [J]. Computer Engineering, 2007, 33(01): 56-58.
[9]	DENG Yangyang, LI Jianqi, WU Songfeng, ZHU Yunping, CHEN Yaowen, HE Fuchu. 通过用NCBI 的blastp 程序对nr 数据库与IPI 数据库中属于人类的蛋白质序列进行比较，论证了nr 数据库整合到蛋白质注释系统中的必要性。并在此基础上，设计方案实现了nr 数据库的本地化，对nr 数据库的记录进行了统计分析，提供了数据库的内部访问，为蛋白质注释系统整合nr 数据库做好了第一步工作。 [J]. Computer Engineering, 2006, 32(5): 71-73，76.
[10]	DENG Weilin, HU Guiwu, ZHENG Qilun, PENG Hong, HU Jinsong. A Refining Algorithm Based on Extreme Genetic Algorithm for Multiple Sequence Alignment [J]. Computer Engineering, 2006, 32(2): 200-202.
[11]	ZHAO Youjie; CAO Yongzhong; ZHANG Jianfeng; LU Wanghong. Cluster of Nucleic Acid Sequences Based on Density K-medoids Method [J]. Computer Engineering, 2006, 32(19): 280-282.

Please choose a citation manager

Content to export