Application prospects of synthetic bacterial communities with emergent functions in crop breeding

doi:10.12211/2096-8280.2023-073

Synthetic Biology Journal ›› 2024, Vol. 5 ›› Issue (1): 144-153.DOI: 10.12211/2096-8280.2023-073

• Invited Review • Previous Articles Next Articles

Application prospects of synthetic bacterial communities with emergent functions in crop breeding

Chunhui GAO¹, Ning YANG², Chuang WANG¹, Shiji HOU², Jianbing YAN²^,³, Jinshui ZHENG⁴, Jin LI¹, Chenliao WU¹, Peng CAI¹

^1.National Key Laboratory of Agricultural Microbiology，College of Resources and Environment，Huazhong Agricultural University，Wuhan 430070，Hubei，China
^2.National Key Laboratory of Crop Genetic Improvement，College of Plant Science and Technology，Huazhong Agricultural University，Wuhan 430070，Hubei，China
^3.Hongshan Laboratory of Hubei Province，Wuhan 430070，Hubei，China
^4.National Engineering Research Center of Microbial Pesticides，College of Informatics，Huazhong Agricultural University，Wuhan 430070，Hubei，China

Received:2023-10-10 Revised:2023-12-13 Online:2024-03-20 Published:2024-02-29
Contact: Peng CAI

有涌现性功能的合成菌群在作物育种上的应用前景

高春辉¹, 杨宁², 王创¹, 侯时季², 严建兵²^,³, 郑金水⁴, 李锦¹, 吴尘聊¹, 蔡鹏¹

^1.华中农业大学资源与环境学院，农业微生物资源发掘与利用全国重点实验室，湖北武汉 430070
^2.华中农业大学植物科学技术学院，作物遗传改良全国重点实验室，湖北武汉 430070
^3.湖北省洪山实验室，湖北武汉 430070
^4.华中农业大学信息学院，微生物农药国家工程研究中心，湖北武汉 430070

通讯作者: 蔡鹏
作者简介:高春辉（1986—），男，博士，副研究员，硕士生导师。研究方向为合成微生物群落的功能和调控机制。 E-mail：gaoch@mail.hzau.edu.cn
蔡鹏（1980—），男，教授，国家杰出青年基金和优秀青年基金获得者。研究方向为土壤生物膜与环境健康。 E-mail：cp@mail.hzau.edu.cn
基金资助:
国家自然科学基金(32100090);教育部产学合作项目(220903354200718)

Abstract

Abstract:

In agroecosystems, microorganisms have rich, diverse, and complex ecological functions, so-called emergent properties, which refer to novel characteristics that emerge in complicated systems as their complexity increases. Interestingly, although emergent functions originate from the joint action of multiple species, the number of species required for triggering such a phenomenon is not so large, typically less than ten. This not only provides the possibility of using synthetic bacterial communities (SynComs) to explore the generation of emergent functions, but also makes it possible to use SynComs to modify the symbiotic microbiota of plant hosts. Seed microbiome, which consists of the earliest microbial residents of a plant, has much simpler community structures compared with either rhizosphere or phyllosphere microbiome. Considering the priority effect, however, it is believed that the seed microbiome plays an important role in the evolution and assembly of plant symbiotic microbial communities, which is currently overlooked. Under particular conditions, even if the members of the seed microbiome have become rare species or disappeared in the later stage, they may still affect the development of plant symbiotic microbiome with legacy effect. Notably, limited by the dry and oligotrophic microhabitat conditions, biofilms should be the main morphology for the microbes existing on the surface of and inside seeds. Applying functional synthetic microbial communities as the seed coatings or biofilms may be the most effective intervention strategy for plant microbiome manipulations, as it targets the most critical period of the early development of plant-associated microbiota. In the context of smart agriculture, the integration of seed chip technologies and drone intelligent platforms could facilitate the high-throughput field characterization and application of SynComs, enabling the discovery of functional SynComs with specific emergent properties that work with plant seeds. Therefore, the application of synthetic bacterial biofilms, or coatings, provides a feasible approach, and is expected to bring breakthrough for the development of microbe-crop breeding technology.

Key words: plant-microbiome interaction, seed microbiome, synthetic community, emergent property

摘要：

在农业生态系统中，微生物具有丰富多样的复杂生态学功能，这些功能的产生具有涌现性。所谓涌现性，指的是复杂系统中随着系统复杂性增加产生的新特性。有趣的是，虽然涌现性功能源于多物种的共同作用，但是所需物种数量通常较少。这不但为利用合成菌群探究涌现性功能的产生提供了可能，而且还为应用合成菌群改造植物菌群提供了抓手。种子菌群作为植物最早的微生物群落，其所包含的微生物具有多样性相对较低的特点。但是，其在植物共生菌群的演化过程中却具有重要作用。此外，受限于种子干燥、贫营养的微生境条件，生物膜是微生物在种子表面和内部存在的主要形式。因此，本文提出以有涌现性功能的合成微生物群落为种子包衣，或可成为在植物微生物组调控中最关键时间节点、最易于开展阶段的有效干预途径。在此基础上，分别从宿主和菌群角度介绍了调控种子菌群涌现性功能的潜在因素。在智慧农业的场景下，通过与种子芯片技术、无人智能化平台的结合，或可在农田中实现合成菌群的大规模施用和功能动态实时监测，为发掘具有特定功能的合成微生物群落、开展基于种子合成菌群生物膜包衣的应用提供可行途径，进而有望为微生物-作物联合育种技术的发展带来重大变革。

关键词: 植物-微生物互作, 种子菌群, 生物膜, 合成微生物群落, 涌现性

CLC Number:

Chunhui GAO, Ning YANG, Chuang WANG, Shiji HOU, Jianbing YAN, Jinshui ZHENG, Jin LI, Chenliao WU, Peng CAI. Application prospects of synthetic bacterial communities with emergent functions in crop breeding[J]. Synthetic Biology Journal, 2024, 5(1): 144-153.

高春辉, 杨宁, 王创, 侯时季, 严建兵, 郑金水, 李锦, 吴尘聊, 蔡鹏. 有涌现性功能的合成菌群在作物育种上的应用前景[J]. 合成生物学, 2024, 5(1): 144-153.

Figures/Tables 1

References 67

1	LI D Y, GAO C H, ZHANG F M, et al. Seven facts and five initiatives for gut microbiome research[J]. Protein & Cell, 2020, 11(6): 391-400.
2	BERENDSEN R L, PIETERSE C M J, BAKKER P A H M. The rhizosphere microbiome and plant health[J]. Trends in Plant Science, 2012, 17(8): 478-486.
3	FLEMMING H C, WINGENDER J, SZEWZYK U, et al. Biofilms: an emergent form of bacterial life[J]. Nature Reviews Microbiology, 2016, 14(9): 563-575.
4	VAN DEN BERG N I, MACHADO D, SANTOS S, et al. Ecological modelling approaches for predicting emergent properties in microbial communities[J]. Nature Ecology & Evolution, 2022, 6(7): 855-865.
5	SALEEM M, HU J E, JOUSSET A. More than the sum of its parts: microbiome biodiversity as a driver of plant growth and soil health[J]. Annual Review of Ecology, Evolution, and Systematics, 2019, 50: 145-168.
6	韦中, 沈宗专, 杨天杰, 等. 从抑病土壤到根际免疫:概念提出与发展思考[J]. 土壤学报, 2021, 58(4): 814-824.
	WEI Z, SHEN Z Z, YANG T J, et al. From suppressive soil to rhizosphere immunity: towards an ecosystem thinking for soil-borne pathogen control[J]. Acta Pedologica Sinica, 2021, 58(4): 814-824.
7	MENDES R, KRUIJT M, DE BRUIJN I, et al. Deciphering the rhizosphere microbiome for disease-suppressive bacteria[J]. Science, 2011, 332(6033): 1097-1100.
8	LI Z F, BAI X L, JIAO S, et al. A simplified synthetic community rescues Astragalus mongholicus from root rot disease by activating plant-induced systemic resistance[J]. Microbiome, 2021, 9(1): 217.
9	TRIVEDI P, LEACH J E, TRINGE S G, et al. Plant-microbiome interactions: from community assembly to plant health[J]. Nature Reviews Microbiology, 2020, 18(11): 607-621.
10	KE J, WANG B, YOSHIKUNI Y. Microbiome engineering: synthetic biology of plant-associated microbiomes in sustainable agriculture[J]. Trends in Biotechnology, 2021, 39(3): 244-261.
11	VRANCKEN G, GREGORY A C, HUYS G R B, et al. Synthetic ecology of the human gut microbiota[J]. Nature Reviews Microbiology, 2019, 17(12): 754-763.
12	VORHOLT J A, VOGEL C, CARLSTRÖM C I, et al. Establishing causality: opportunities of synthetic communities for plant microbiome research[J]. Cell Host & Microbe, 2017, 22(2): 142-155.
13	HU J L, AMOR D R, BARBIER M, et al. Emergent phases of ecological diversity and dynamics mapped in microcosms[J]. Science, 2022, 378(6615): 85-89.
14	NIU B, PAULSON J N, ZHENG X Q, et al. Simplified and representative bacterial community of maize roots[J]. Proceedings of the National Academy of Sciences of the United States of America, 2017, 114(12): E2450-E2459.
15	WAGNER M R, TANG C, SALVATO F, et al. Microbe-dependent heterosis in maize[J]. Proceedings of the National Academy of Sciences of the United States of America, 2021, 118(30): e2021965118.
16	YANG N, NESME J, RØDER H L, et al. Emergent bacterial community properties induce enhanced drought tolerance in Arabidopsis [J]. NPJ Biofilms and Microbiomes, 2021, 7: 82.
17	VOS M, WOLF A B, JENNINGS S J, et al. Micro-scale determinants of bacterial diversity in soil[J]. FEMS Microbiology Reviews, 2013, 37(6): 936-954.
18	YOUNG I M, CRAWFORD J W. Interactions and self-organization in the soil-microbe complex[J]. Science, 2004, 304(5677): 1634-1637.
19	CAI P, SUN X J, WU Y C, et al. Soil biofilms: microbial interactions, challenges, and advanced techniques for ex-situ characterization[J]. Soil Ecology Letters, 2019, 1(3/4): 85-93.
20	KUZYAKOV Y, BLAGODATSKAYA E. Microbial hotspots and hot moments in soil: concept & review[J]. Soil Biology and Biochemistry, 2015, 83: 184-199.
21	GOLDFORD J, LU N X, BAJIĆ D, et al. Emergent simplicity in microbial community assembly[J]. Science, 2018, 361: 469-474.
22	GAO C H, CAO H, JU F, et al. Emergent transcriptional adaption facilitates convergent succession within a synthetic community[J]. ISME Communications, 2021, 1: 46.
23	NUNAN N. The microbial habitat in soil: scale, heterogeneity and functional consequences[J]. Journal of Plant Nutrition and Soil Science, 2017, 180(4): 425-429.
24	陈沫先, 韦中, 田亮, 等. 合成微生物群落的构建与应用[J]. 科学通报, 2021, 66(3): 273-283.
	CHEN M X, WEI Z, TIAN L, et al. Design and application of synthetic microbial communities[J]. Chinese Science Bulletin, 2021, 66(3): 273-283.
25	韦中, 杨天杰, 任鹏, 等. 合成菌群在根际免疫研究中的现状与未来[J]. 南京农业大学学报, 2021, 44(4): 597-603.
	WEI Z, YANG T J, REN P, et al. Advances and perspectives on synthetic microbial community in the study of rhizosphere immunity[J]. Journal of Nanjing Agricultural University, 2021, 44(4): 597-603.
26	SIMONIN M, BRIAND M, CHESNEAU G, et al. Seed microbiota revealed by a large-scale meta-analysis including 50 plant species[J]. New Phytologist, 2022, 234(4): 1448-1463.
27	DEBRAY R, HERBERT R A, JAFFE A L, et al. Priority effects in microbiome assembly[J]. Nature Reviews Microbiology, 2022, 20(2): 109-121.
28	WANG M Y, EYRE A W, THON M R, et al. Dynamic changes in the microbiome of rice during shoot and root growth derived from seeds[J]. Frontiers in Microbiology, 2020, 11: 559728.
29	FORT T, PAUVERT C, ZANNE A, et al. Maternal effects shape the seed mycobiome in Quercus petraea [J]. New Phytologist, 2021, 230(4): 1594-1608.
30	WEI Z, GU Y A, FRIMAN V P, et al. Initial soil microbiome composition and functioning predetermine future plant health[J]. Science Advances, 2019, 5(9): eaaw0759.
31	WALSH C M, BECKER-UNCAPHER I, CARLSON M, et al. Variable influences of soil and seed-associated bacterial communities on the assembly of seedling microbiomes[J]. The ISME Journal, 2021, 15(9): 2748-2762.
32	YU P, HE X M, BAER M, et al. Plant flavones enrich rhizosphere Oxalobacteraceae to improve maize performance under nitrogen deprivation[J]. Nature Plants, 2021, 7(4): 481-499.
33	HE D X, SINGH S K, PENG L, et al. Flavonoid-attracted Aeromonas sp. from the Arabidopsis root microbiome enhances plant dehydration resistance[J]. The ISME Journal, 2022, 16(11): 2622-2632.
34	LIU X Y, MATSUMOTO H, LV T X, et al. Phyllosphere microbiome induces host metabolic defence against rice false-smut disease[J]. Nature Microbiology, 2023, 8(8): 1419-1433.
35	HERPELL J B, ALICKOVIC A, DIALLO B, et al. Phyllosphere symbiont promotes plant growth through ACC deaminase production[J]. The ISME Journal, 2023, 17(8): 1267-1277.
36	LYNCH J M, WHIPPS J M. Substrate flow in the rhizosphere[J]. Plant and Soil, 1990, 129(1): 1-10.
37	BADRI D V, VIVANCO J M. Regulation and function of root exudates[J]. Plant, Cell & Environment, 2009, 32(6): 666-681.
38	ZHALNINA K, LOUIE K B, HAO Z, et al. Dynamic root exudate chemistry and microbial substrate preferences drive patterns in rhizosphere microbial community assembly[J]. Nature Microbiology, 2018, 3(4): 470-480.
39	HARBORT C J, HASHIMOTO M, INOUE H, et al. Root-secreted coumarins and the microbiota interact to improve iron nutrition in Arabidopsis [J]. Cell Host & Microbe, 2020, 28(6): 825-837.e6.
40	SONG Y, WILSON A J, ZHANG X C, et al. FERONIA restricts Pseudomonas in the rhizosphere microbiome via regulation of reactive oxygen species[J]. Nature Plants, 2021, 7(5): 644-654.
41	YANG K M, FU R X, FENG H C, et al. RIN enhances plant disease resistance via root exudate-mediated assembly of disease-suppressive rhizosphere microbiota[J]. Molecular Plant, 2023, 16(9): 1379-1395.
42	KWAK M J, KONG H G, CHOI K H, et al. Rhizosphere microbiome structure alters to enable wilt resistance in tomato[J]. Nature Biotechnology, 2018, 36(11): 1100-1109.
43	BERNAOLA L, COSME M, SCHNEIDER R W, et al. Belowground inoculation with arbuscular mycorrhizal fungi increases local and systemic susceptibility of rice plants to different pest organisms[J]. Frontiers in Plant Science, 2018, 9: 747.
44	CORDOVEZ V, DINI-ANDREOTE F, CARRIÓN V J, et al. Ecology and evolution of plant microbiomes[J]. Annual Review of Microbiology, 2019, 73: 69-88.
45	TOJU H, PEAY K G, YAMAMICHI M, et al. Core microbiomes for sustainable agroecosystems[J]. Nature Plants, 2018, 4(5): 247-257.
46	BALDRIAN P. Forest microbiome: diversity, complexity and dynamics[J]. FEMS Microbiology Reviews, 2017, 41(2): 109-130.
47	KELVIN LEE K W, HOONG YAM J K, MUKHERJEE M, et al. Interspecific diversity reduces and functionally substitutes for intraspecific variation in biofilm communities[J]. The ISME Journal, 2016, 10(4): 846-857.
48	VAN ELSAS J D, CHIURAZZI M, MALLON C A, et al. Microbial diversity determines the invasion of soil by a bacterial pathogen[J]. Proceedings of the National Academy of Sciences of the United States of America, 2012, 109(4): 1159-1164.
49	XU X H, ZARECKI R, MEDINA S, et al. Modeling microbial communities from atrazine contaminated soils promotes the development of biostimulation solutions[J]. The ISME Journal, 2019, 13(2): 494-508.
50	NIU B, WANG W X, YUAN Z B, et al. Microbial interactions within multiple-strain biological control agents impact soil-borne plant disease[J]. Frontiers in Microbiology, 2020, 11: 585404.
51	JIANG M T, DELGADO-BAQUERIZO M, YUAN M, et al. Home-based microbial solution to boost crop growth in low-fertility soil[J]. New Phytologist, 2023, 239(2): 752-765.
52	DURÁN P, THIERGART T, GARRIDO-OTER R, et al. Microbial interkingdom interactions in roots promote Arabidopsis survival[J]. Cell, 2018, 175(4): 973-983.e14.
53	LI M, WEI Z, WANG J N, et al. Facilitation promotes invasions in plant-associated microbial communities[J]. Ecology Letters, 2019, 22(1): 149-158.
54	GU S H, WEI Z, SHAO Z Y, et al. Competition for iron drives phytopathogen control by natural rhizosphere microbiomes[J]. Nature Microbiology, 2020, 5(8): 1002-1010.
55	LI M, POMMIER T, YIN Y, et al. Indirect reduction of Ralstonia solanacearum via pathogen helper inhibition[J]. The ISME Journal, 2022, 16(3): 868-875.
56	SUN X J, CAI P, SØRENSEN S J, et al. Interspecific interactions in dual-species biofilms of soil bacteria: effects of fertilization practices[J]. Journal of Soils and Sediments, 2020, 20(3): 1494-1501.
57	GAO C H, ZHANG M, WU Y C, et al. Divergent influence to a pathogen invader by resident bacteria with different social interactions[J]. Microbial Ecology, 2019, 77(1): 76-86.
58	FLEMMING H C, WUERTZ S. Bacteria and archaea on Earth and their abundance in biofilms[J]. Nature Reviews Microbiology, 2019, 17(4): 247-260.
59	PAPENFORT K, BASSLER B L. Quorum sensing signal-response systems in Gram-negative bacteria[J]. Nature Reviews Microbiology, 2016, 14(9): 576-588.
60	MA W T, PENG D H, WALKER S L, et al. Bacillus subtilis biofilm development in the presence of soil clay minerals and iron oxides[J]. NPJ Biofilms and Microbiomes, 2017, 3: 4.
61	BOYD C D, O'TOOLE G A. Second messenger regulation of biofilm formation: breakthroughs in understanding c-di-GMP effector systems[J]. Annual Review of Cell and Developmental Biology, 2012, 28: 439-462.
62	SUN X L, XU Z H, XIE J Y, et al. Bacillus velezensis stimulates resident rhizosphere Pseudomonas stutzeri for plant health through metabolic interactions[J]. The ISME Journal, 2022, 16(3): 774-787.
63	BANERJEE S, SCHLAEPPI K, VAN DER HEIJDEN M G A. Keystone taxa as drivers of microbiome structure and functioning[J]. Nature Reviews Microbiology, 2018, 16(9): 567-576.
64	FINKEL O M, SALAS-GONZÁLEZ I, CASTRILLO G, et al. A single bacterial genus maintains root growth in a complex microbiome[J]. Nature, 2020, 587(7832): 103-108.
65	XIA L M, MIAO Y Z, CAO A L, et al. Biosynthetic gene cluster profiling predicts the positive association between antagonism and phylogeny in Bacillus [J]. Nature Communications, 2022, 13: 1023.
66	KRAMER J, ÖZKAYA Ö, KÜMMERLI R. Bacterial siderophores in community and host interactions[J]. Nature Reviews Microbiology, 2020, 18(3): 152-163.
67	ARNAOUTELI S, BAMFORD N C, STANLEY-WALL N R, et al. Bacillus subtilis biofilm formation and social interactions[J]. Nature Reviews Microbiology, 2021, 19(9): 600-614.

Application prospects of synthetic bacterial communities with emergent functions in crop breeding

有涌现性功能的合成菌群在作物育种上的应用前景

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