Microbiome-based biosynthetic gene cluster data mining techniques and application potentials

doi:10.12211/2096-8280.2022-075

Abstract

Abstract:

Biosynthetic gene cluster (BGC) is an important type of gene set, which is commonly found in the genomes of various organisms, and plays important metabolic and regulatory roles. In terms of linear gene structure, the set of genes in a BGC is usually located in close proximity to each other in the genome, but for functions, genes in a BGC usually work synergistically and are responsible for a class of pathways that generate specific small molecules. Therefore, BGCs are vital in synthetic biology research as a highly promising source for elements. However, current BGC databases and analytical platforms are limited by the number and types of experimentally validated BGCs, as well as by the preliminary BGC data mining techniques. The establishment of data-driven systematic discovery of BGCs and their validation, as well as translational studies, are of great value in both fundamental research and practical applications. This article focuses on mining BGCs from big data with microbiome for synthetic biology research. We start with discussing the definition and significance of BGC mining, and summarize current data resources and methods for BGC mining: including MIBiG, antiSMASH and IMG-ABC for artificial intelligence (AI) enabled web services to accelerate BGC mining. Then, we compile a walk-through on how a typical BGC data mining could be conducted, with the history of BGC mining methods highlighted, which underlines the route build-up from traditional machine learning to deep learning. We also diagnose bottlenecks in BGC mining, and propose possible solutions. Furthermore, according to several BGC mining and validation experiments, we demonstrate the profound diversity and breadth of application scenarios with BGC discovery, as well as the importance of combining dry and wet lab experiments for validating newly discovered BGCs. Finally, we envision that the combination of advanced BGC mining methods and synthetic biology could broaden and deepen current synthetic biology research.

Key words: biosynthetic gene cluster, artificial intelligence, synthetic biology, microbiome

摘要：

生物合成基因簇（biosynthetic gene cluster， BGC）是一类非常重要的基因集合（gene set）类型。BGC普遍存在于各类生物基因组中，并且发挥着重要的代谢和调控作用。从线性结构上来说，一个BGC中的基因通常在基因组中处于相邻的位置；从基因功能上来说，一个BGC中的基因通常共同负责一类通路，生成特定的化合物小分子。因此，BGC作为极具潜力的元件来源，在合成生物学研究中极为重要。然而从序列模式上来说，一个BGC中的基因数量众多且序列差异度大，很难通过序列同源性发掘新类型的BGC。因此，建立生物合成基因簇的智能发掘策略，系统性地发掘BGC并进行验证和转化研究，不论在理论方面还是实际应用方面，都具有非常重要的价值。本文主要基于微生物组大数据，较全面地介绍了BGC挖掘的意义和瓶颈问题，系统性地总结了当前BGC发掘中的数据资源和挖掘方法，尤其是人工智能方法，指出了干湿结合方法对于验证新发掘BGC的重要价值，同时展示了新发掘BGC的多样性和广泛应用领域。最后，展望了结合现有BGC挖掘方法和合成生物学转化，将如何在广度和宽度方面扩展目前的合成生物学研究。

关键词: 生物合成基因簇, 人工智能, 合成生物学, 微生物组

CLC Number:

Qilong LAI, Shuai YAO, Yuguo ZHA, Hong BAI, Kang NING. Microbiome-based biosynthetic gene cluster data mining techniques and application potentials[J]. Synthetic Biology Journal, 2023, 4(3): 611-627.

赖奇龙, 姚帅, 查毓国, 白虹, 宁康. 微生物组生物合成基因簇发掘方法及应用前景[J]. 合成生物学, 2023, 4(3): 611-627.

Figures/Tables 9

Fig. 1 Schematic diagram for sequences and functions of BGC (with penicillin biosynthesis as an example)

Fig. 2 Overall process for BGC mining(This process includes the integration of metagenomic data, prediction of genes and potential BGC, endogenous or heterologous expression, identification of natural products, etc. The case chosen in this figure is Nostocyclopeptide A2, which is extracted from Nostoc sp. ATCC53789 isolated from lichen. It can be used as an inhibitor of 20S proteasome and exhibits anticancer activity[45].)

Table 1 Summary for representative BGC databases

数据库名称	特色	网址	参考文献
antiSMASH	有关次生代谢物BGC的综合资源，集成各种分析工具	https://antismash.secondarymetabolites.org/	[22]
Bactibase	主要包括细菌及其产生的抗菌肽、细菌素等	http://bactibase.pfba-lab-tun.org/	[46]
BiG-FAM	将同源BGCs分组到基因簇家族	https://bigfam.bioinformatics.nl/	[47]
ClusterMine360	第一个已知产物的BGC数据库	http://www.clustermine360.ca/	[48]
CSDB(ClustScan Database)	主要内容为PKS、NRPS的BGC	http://csdb.bioserv.pbf.hr/csdb/ClustScanWeb.html	[49]
DoBISCUIT	提供由文献给出的PKS和NRPS的BGC	http://www.bio.nite.go.jp/pks/	[50]
IMG-ABC	最大的公开预测的BGC数据库	https://img.jgi.doe.gov/abc-public	[51]
MiBiG	存储BGC的最小信息	https://mibig.secondarymetabolites.org/	[19]
OrphanPKS	由软件自动提取的多模块PKS序列目录	http://sequence.stanford.edu/OrphanPKS/	[52]

Fig. 3 Overall flow for BGC analysis and mining[It mainly includes: BGC mining methods (sequence alignment, feature characterization, etc.) and BGC optimization methods (database searching, evolutionary analysis, etc.). Among them, the mining methods of BGC mainly include sequence alignment and feature characterization. Sequence alignment mainly uses BLAST and other methods, while feature characterization employs both traditional methods such as hidden Markov model (HMM) alignment and deep learning based on data model. The optimization methods of BGC mainly include database searching, evolutionary analysis, etc. Database searching includes the searching of BGC sequence database and BGC related small molecule mass spectrometry database, and the main purpose of evolutionary analysis is to analyze the evolution and variation patterns of BGC[54].]

Fig. 4 Analytical methods for establishing correlation between BGC and the production of secondary metabolites[58](a) Retro-biosynthesis: starting with a known compound but no related gene clusters identified, it is possible for predicting enzyme(s) to catalyze the synthesis of such a compound (backbone and tailoring enzymes), and with these predictions putative gene clusters matching the requirements can be found in the genome. The selected case in this figure is penicillin G[59]. (b) Homology searching: starting with a known compound produced by organism 1 and the same or similar compound produced by organism 2 with gene cluster identified, it is possible to use the known gene cluster from organism 2 to search for a similar gene cluster in the genome of organism 1, and thereby identify the gene cluster of interest. (c) Comparative genomics: starting with a group of organisms, some of which produce compounds of interest and some of which do not, it is possible to identify homologous gene clusters in the species that produce them and to screen on the basis of the absence of homologous genes in the species that does not produce them, thereby identifying candidate gene clusters.

Fig. 5 Types of sequence data and corresponding AI analysis methodsDNN— deep neural network; CNN— convolutional neural network; NN— neural network; TL— transfer learning; GCN— graph convolutional network; HMM— hidden markov model

Fig. 6 Status quo and trend of BGC mining using artificial intelligence(Starting from the data, data mining and model construction are carried out with artificial intelligence methods, thus serving the transformation research of synthetic biology, generating more multimodal data and forming a virtuous cycle.)

Fig. 7 Advantages, disadvantages and complementarities of artificial intelligence data mining and culturomics(The list of advantages and disadvantages of the relevant methods is based on the results of comparison with each other and with traditional molecular biological methods as well.)

Fig. 8 BGC's central role in systems biology and synthetic biology(Research on intelligent mining and verification transformation of biosynthetic gene clusters not only connects BGC database with entity database, but also connects artificial intelligence mining and culture experiment verification. Research on intelligent discovery and transformation verification for biosynthetic gene clusters can closely link systems biology and synthetic biology, and realize seamless transformation from data to model and from verification to application.)

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